Exploring The Impact of a Largescale Diagnostic Science ...
Transcript of Exploring The Impact of a Largescale Diagnostic Science ...
EXPLORINGTHEIMPACTOFALARGE-
SCALEDIAGNOSTICSCIENCETESTAND
FORMATIVEPRACTICES.Amixed-
methodsstudy.
JamesScottMEd
DoctorofPhilosophyC02041
UniversityofTechnologySydney
FacultyofArtsandSocialSciences
©JamesScott2018
ii
Certificateoforiginalauthorship
I,JamesScottdeclarethatthisthesis,issubmittedinfulfilmentoftherequirements
fortheawardofDoctorofPhilosophybyThesisintheFacultyofArtsandSocial
SciencesattheUniversityofTechnologySydney.
Thisthesisiswhollymyownworkunlessotherwisereferencedoracknowledged.
Inaddition,Icertifythatallinformationsourcesandliteratureusedareindicated
inthethesis.
Thisdocumenthasnotbeensubmittedforqualificationsatanyotheracademic
institution.
29August2018
Production Note:
Signature removed prior to publication.
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Acknowledgments
Thisthesiswouldnothavehappenedwithoutinsights,supportand
encouragementfromanumberofpeople.
MythankstoDagmarMcCloughan,ESSATeamLeader,fortheopportunitytobe
involvedwiththeESSAprogramintheearlyyearsofitsdevelopmentand
implementation.Also,mythankstoProfessorJohnPegg(UniversityofNew
England)andAssociateProfessorDebraPanizzon(thenfromtheUniversityof
NewEngland)fortheopportunitytobeapartoftheresearchteaminvestigating
thepotentialofSOLOasatoolforimprovingassessmentforlearning.Afterthat
initialinvolvement,bothprovidedmewiththeiradvice,encouragementand
supportwhichIsoughtatdifferenttimeswhilstIworkedonthisthesis.
IwouldliketoacknowledgeDoctorGeoffBarneswhoencouragedmetorunwith
theideathattheresidualfromaregressionprocedurewasameasureofareal
effectofteaching.MythanksalsototheNSWDepartmentofEducationfor
providingmewithaccesstoESSAandNAPLANdatainaformthatIcouldusefor
thepurposesofthisthesis.ParticularthanksinthisregardareduetoDoctor
NadineSmithandformercolleagueanddearfriendGerryMcCloughan.
AssociateProfessorsNickHopwoodandTapanRaifromtheUniversityof
TechnologySydneyhavemygratitudeforthetimeandadvicetheyprovidedasI
developedtheapproachIwantedtotakewiththeresearchmodelandanalysisof
data.
Iamextremelygratefultothescienceteacherswhorespondedtothesurveyabout
theirpracticeandparticularlysototheteacherswhomadethemselvesavailableto
participateinthecasestudies.Ihaveundertakentoprovidethemwiththeresults
ofmyworkinaformthatIhopewillbeusefultothem.
Ihadthesupportandadviceoftwoexcellentsupervisors,bothattheUniversityof
TechnologySydney,forthisthesis.ProfessorPeterAubussonwhoencouragedme
toundertakethisprojectinthefirstinstanceandAssociateProfessorMatthew
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Kearneywhotookoverinthelaterstagestoassistmebringittoaconclusion.My
gratitudeandthankstobothfortheirpatience,adviceandsupport.
ThisthesisalsohadthebenefitoftheconsiderableeditingskillsofDoctorTerry
FitzgeraldwhoisalsoattheUniversityofTechnologySydney.
Finally,IwanttoacknowledgetheforbearanceofDaunemywifewho,intheend,
waitedpatientlyandsupportivelyformetocompletethisprojectsothatwecould
resumeourlivestogether.
Thesisformat
Thisisaconventionalthesiscomprisedoftitle,frontmatter,glossaries(acronyms
andtermsused),tableofcontents,listoffigures,listoftables,abstract,six
chapters,appendicesandreferencesconsultedinthepreparationofthisthesis.
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ListofAcronyms
AAS AustralianAcademyofScience
ABS AustralianBureauofStatistics
ACARA AustralianCurriculumAssessmentandReporting
Authority
ACCI AustralianChamberofCommerceandIndustry
ACER AustralianCouncilforEducationalResearch
AE AtExpectation(seealsoWAEandWBE)
ANOVA AnalysisofVariance
AQF AustralianQualificationsFramework
ARG AssessmentReformGroup
BCA BusinessCouncilofAustralia
BOS BoardofStudies
BOSTES BoardofStudies,TeachingandEducational
Standards
CC CurriculumCorporation
CCII CentreforContinuousInstructionalImprovement
DEC NSWDepartmentofEducationandCommunities
DET NSWDepartmentofEducationandTraining
DofE DepartmentofEducation
ESA EducationServicesAustralia
ESSA EssentialSecondaryScienceAssessment
EV AcronymfortheacronymsESSAandVALID.
F TheFoundationorentrylevelforschooling(seeK).
HSC HigherSchoolCertificate
ICSEA IndexofCommunitySocio-EducationalAdvantage
K Kindergartenorentrylevelforschooling(seeF).
NAP-SL NationalAssessmentPlan-ScientificLiteracy
NAPLAN NationalAssessmentPlanLiteracyAndNumeracy
NESA NewSouthWalesEducationStandardsAuthority
NGSS NextGenerationScienceStandards(US)
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NSES NationalScienceEducationStandards(US)
OECD OrganisationforEconomicCo-operationand
Development
PCK PedagogicalContentKnowledge
PIRLS ProgressinInternationalReadingLiteracyStudy
PISA ProgrammeforInternationalStudentAssessment
SEA Socio-EducationalAdvantage
SEAR ScienceEducationAssessmentResource
SET Science,EngineeringandTechnology
SLPM ScientificLiteracyProgressMap
SMART SchoolsMeasurementAssessmentandReporting
Toolkit
SME Science,MathematicsandEngineering
SOLO StructureoftheObservedLearningOutcome
SPSS StatisticalPackagefortheSocialSciences
STEM Science,Technology,EngineeringandMathematics
TIMSS TrendsInMathematicsandScienceStudy
US UnitedStatesofAmerica
VALID ValidationofAssessmentforLearningandIndividual
Development
VET VocationalEducationandTraining
WAE WellAboveExpectation(seealsoAEandWBE)
WBE WellBelowExpectation(seealsoAEandWAE)
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Glossaryoftermsasusedinthisthesis
artifact Somethingmadebyhumaneffort,inthiscontext
relatedtoeducationalassessment.
assessmentaslearning Assessmentaslearningoccurswhenstudentsare
theirownassessors.Studentsmonitortheirown
learning,askquestionsandusearangeofstrategies
todecidewhattheyknowandcando,andhowtouse
assessmentfornewlearning.(NESA,2018)
assessmentforlearning Assessmentforlearninginvolvesteachersusing
evidenceaboutstudents'knowledge,understanding
andskillstoinformtheirteaching.Sometimes
referredtoas'formativeassessment',itusually
occursthroughouttheteachingandlearningprocess
toclarifystudentlearningandunderstanding.(NESA,
2018)
assessmentoflearning Theuseofevidenceoflearningtomakeasummative
judgmentofachievementagainstoutcomesand
standards.Sometimesreferredtoas'summative
assessment'.Itusuallyoccursafteraperiodof
instruction.Thejudgmentisoftenexpressedasa
mark,percentageorgrade.Theusefulnessofthe
gradeormarkdependsonvalidityandreliabilityof
theprocessesusedtogatherandassignvaluetothe
evidencegathered.(NESA,2018)
assessment-relatedwork Isthepurposefulcollectingofevidenceoflearning,
creatingthemeansbywhichthatevidencewas
obtained(ifnotbydirectobservationofbehaviour),
theassumptionsusedtointerpretthatevidence,the
choiceoftextformsusedtorepresentand
communicateresultsofassessment,andsubsequent
usesforthoseresults.
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capabilities Ameasureoftheability,capacity,powerorpotential
todosomething.TheAustralianCurriculum,Science
includessevengeneralcapabilitiesallstudentsare
expectedtoacquireastheyprogressthrough
schooling.
CurriculumCorporation Anationaleducationalsupportentitycreatedbythe
Federal,stateandterritorygovernmentsinAustralia
toproduceeducationalresourcesforAustralian
Schools.ItwasreplacedbyEducationServices
Australia(ESA)from2010.
competencies Seecapabilities.
curriculum Thedocumentsteachersusetoinformthelearning
activitiestheyplananddelivertostudents.
diagnosticassessment Gatheringevidenceoflearningtoidentifygaps,
strengthsandweaknessesinstudentlearning.
educationjurisdiction StatesandterritoriesinAustraliamanagethe
deliveryofeducationalservicestostudentsin
Australia.Theyprovideforregistrationand
regulationofpublicandprivateschoolsintheir
geographicareasofjurisdiction.
educationalstandards Arethelearninggoalsstudentsareexpectedto
achieve,usuallyaftersetperiodsofinstruction
typicallyassociatedwithYearorGradelevels.
feedback Informationprovidedbyanagentregardingaspects
ofone'sperformanceorunderstanding.
formativeassessment Seeassessmentforlearning.
formativepractices Instructioninformedbyformativefeedback.
highstakesassessment Anyassessmentwheretheresultshave
consequencesfortherecipientofthoseresults.
keycompetencies Asetofcompetenciesrelatedtoequippingstudents
forwork.
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lowstakesassessment Theuseofevidenceoflearninginwaysthatreduces
toaminimumunintended,usuallynegative,
consequencesforthelearner.
outcomes Measurableorobservablebehavioursintendedasa
resultofinstruction.
PrimaryConnections Asetofcurriculummaterialsproducedbythe
AustralianAcademyofSciencedesignedtoassistK-6
teacherstoteachscience.
proficiencyareas Areasofskillorexpertise.
proficiencylevels Descriptionsofresponsefeaturesthatdifferentiate
betweenlevelsofskillorexpertise.
regression Regressionisastatisticalprocessforestimatingthe
relationshipsbetweenvariables.
SciencebyDoing Acurriculumsupportresourceproducedfor
secondaryscienceteachersbytheAustralian
AcademyofScience.
scientificliteracy Scientificliteracyistheabilitytoengagewith
science-relatedissues,andwiththeideasofscience,
asareflectivecitizen(OECD).Itisalsothespecialized
literaciesthatdistinguishscienceliteracyfrom
generalliteracyandnumeracy.
SEAquarters Socio-EducationalAdvantage(SEA)proportions,
relativetoAustralia,inschoolpopulations.(ACARA
MySchoolwebsite)
SEAscore Socio-EducationalAdvantage(SEA)scoreisa
compositemeasureofsocio-educationaladvantage
generatedforthepurposesofthisproject.
selectiveentryschools AcategoryofschoolinNSW,entrytowhichis
determinedbystudentresultsintestsofreading,
mathematics,generalabilityandwriting.
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self-regulatedlearners Studentswhocanplantheirownlearning,monitor
theirperformanceandthenreflectontheoutcomeof
thatlearning.
Skills,cognitive Includeremembering,thinkinglogicallyand
reasoning,explaininganddescribing.
Skills,employability Skillsrelatedtocommunicating,workinginteams,
problemsolving,initiativeandenterprise,planning
andorganisingandself-management.
Skills,generic Groupsofskillsvariouslydescribedas
basic/fundamental,people-related,
conceptual/thinking,personalskillsandattributes,
skillsrelatedtothebusinessworldandskillsrelated
tothecommunity.
SOLOmodel StructureoftheObservedLearningOutcome(SOLO)
theorythatinvolvestwolearningcycleswithina
modeofthinking
SOLOtaxonomy StructureoftheObservedLearningOutcome(SOLO)
theorythatdescribesasinglelearningcyclewithina
modeofthinking
standardsframework Descriptionsoflevelsofperformanceinanumberof
categoriesrelatingtocurriculum,teachingorother
profession.
statisticallysignificant Istheprobabilityoffindingagivendeviationfroma
nullhypothesis,oramoreextremeone,inasample.
(SPSSdefinition)
STEMsystem Science,Technology,EngineeringandMathematics
institutionsinacountryorlargergroupthat
preparespeopleforworkin,andincluding,the
institutionsthatproduceSTEMoutputsinsociety
andrelatedeconomies.
summativeassessment Seeassessmentoflearning.
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syllabus AdetailedcurriculumthatinNSWmaybeusedto
definethescopeofanexternaltest.
TheBoard AgenerictermforthestatutoryauthorityinNSW
withresponsibilityfordeterminingthecurriculum
andrelatedassessmentrequirementsschoolsneedto
complywithsothatstudentssatisfyrequirementsfor
receiptofcredentials.Inthecourseofthisproject
thatauthoritybeganastheNSWBoardofStudies
(BOS),becametheNSWBoardofStudiesTeaching
andEducationalStandards(BOSTES)before
becomingtheNSWEducationStandardsAuthority
(NESA)in2017.
TheDepartment AgenerictermcoveringtheNSWgovernment
authorityresponsiblefordeliveringpubliceducation
servicestostudentsinNSW.Itwentfrombeingatthe
beginningofthisproject(2012)theNSW
DepartmentofEducationandTraining(DET)tothe
DepartmentofEducationandCommunities(DEC)to
theNSWDepartmentofEducation(DofE).
Year8 TheyearofschoolinginAustralia(Gradeinother
places);inthiscasetheninthyearofschooling.
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Tableofcontents
ListofAcronyms................................................................................................................v
Glossaryoftermsasusedinthisthesis..................................................................vii
Tableofcontents............................................................................................................xii
ListofFigures...............................................................................................................xviii
ListofTables....................................................................................................................xix
Abstract.............................................................................................................................xxi
CHAPTERONE:OUTLINEOFMYPROJECT....................................................................1
1.1Introduction................................................................................................................1
1.2Thetwoinitiatives.....................................................................................................3
1.3Researchquestionsandmethodology................................................................7
1.4Overviewoffindings..............................................................................................11
1.5Importanceoftheresearch.................................................................................14
1.6Theresearcher........................................................................................................15
1.7Structureofthisthesis..........................................................................................18
CHAPTER2:LITERATUREREVIEW..............................................................................20
2.1Introduction.............................................................................................................20
2.2Acurriculum,teachingandassessmentforthetwenty-firstcentury...21
2.3Assessmentandassessmentsystems..............................................................28
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2.4Thepurposesforassessment.............................................................................37
2.4.1Threepurposesforassessment?..............................................................................39
2.4.2Theoriesoflearning,cognitionandassessment................................................43
2.4.3Criteriaforevaluatingthecredibilityofassessments.....................................49
2.5Measurementandsummativeandevaluativeassessment......................57
2.6Formativeassessmentandformativepractices...........................................65
2.6.1Supportforformativeassessment...........................................................................67
2.6.2Teachersmakethedifference....................................................................................71
2.6.3Weightofevidencesupportingformativepractices........................................72
2.6.4FormativePractice..........................................................................................................74
2.6.5Formativepracticeandself-regulatedlearning.................................................76
2.7SOLOandtheESSA-VALID(EV)programinNSW.........................................80
2.7.1TheSOLOTaxonomy......................................................................................................80
2.7.2TheSOLOmodel...............................................................................................................86
2.7.3TheESSA-VALID(EV)assessmentframework...................................................88
2.7.4TheEVtest:“fitforpurpose”?....................................................................................91
2.7.5SOLOandassessmentinAustralasia......................................................................94
2.8Themesfromtheliteraturereviewandtheirrelevancetothisthesis.95
CHAPTERTHREE:RESEARCHDESIGN,METHODOLOGY,METHODS...............102
3.1Introduction...........................................................................................................102
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3.2Mixedmethodresearch,casestudiesandresearchdesign...................104
3.3PhaseOne:selectingthesampleofschoolstoworkwith.......................107
3.3.1Selectingthesampleofschoolstoworkwith..................................................108
3.3.2Regressionresidualasbothmeasureofcollectivescientificliteracyand
‘effectsize’ofscienceteaching..........................................................................................110
3.4Phasetwo:onlinesurveyforscienceteachers...........................................113
3.4.1Surveydesign.................................................................................................................113
3.4.2Analysisofsurveyresponses..................................................................................116
3.5Phasethree:casestudiesandsciencedepartmentassessmentrelated
narratives.......................................................................................................................118
3.5.1Audio-recordedsemi-structuredinterviews:purposeanddevelopment
.........................................................................................................................................................118
3.5.2Artifactsofassessmentpractice:purpose.........................................................123
3.5.3Casestudyschooldata:purpose............................................................................124
3.5.4Defininglaterachievementinscience.................................................................126
3.5.5Definingengagementwithscience.......................................................................127
3.6Comparableschoolsandthreepredictions.................................................130
3.7Limitations..............................................................................................................133
3.7.1Trustworthinessofqualitativeresearch............................................................133
3.7.2Validityandreliabilityofquantitativedata......................................................136
3.7.3Summaryoflimitationsaffectingthisstudy’sfindings................................137
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3.8Researchapprovals..............................................................................................141
CHAPTERFOUR:FINDINGSFROMPHASETWO......................................................142
4.1Introduction...........................................................................................................143
4.2Findingsfromanalysisofthescienceteachersurveyreturns..............146
4.2.1Setoneresults:TeacherengagementwithEVresources(survey
questions1to5)......................................................................................................................147
4.2.2Settworesults:SOLOandextentofteacherengagementwithit(survey
questions6to8)......................................................................................................................158
4.2.3Setthreeresults:Formativepractices(Questions9to15).......................165
4.2.4Setfourresults:RespondentData.........................................................................189
4.3Otherfindings........................................................................................................191
4.3.1Teacherexperienceandstudentachievement................................................191
4.3.2TeacheruseofEVstudentsurveyfeedback.....................................................191
4.4Keyfindingsfromthesurveyanalysis...........................................................193
4.5Summaryoffindingsinrelationtoscienceteacheruseofformative
practices..........................................................................................................................197
CHAPTERFIVE:PHASETHREE-COMPARINGCASESTUDYSCHOOLS..............198
5.1Thecasestudyschools........................................................................................201
5.2Threepredictionsandthecasestudyschools............................................207
5.2.1Predictionone:Year8achievementandengagement.................................207
5.2.2Predictiontwo:Year10achievement.................................................................209
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5.2.3Predictionthree:Year12engagement...............................................................210
5.3Comparedcasestudyschools...........................................................................211
5.3.1PairONE:PCWAE1andMCWAE1.........................................................................212
5.3.2PairTWO:MCAE2andMCWBE3...........................................................................217
5.3.3PairTHREE:PCWAE2andMCWBE5...................................................................220
5.3.4PairFOUR:MGFSAE2andMGFSWBE1...............................................................226
5.3.5PairFIVE:PCWAE2andPCWAE3.........................................................................232
5.4Correlationandstrengthofassociationsbetweenschoolvariables..241
5.4.1Correlations:fullyselectiveentrycasestudyschools(n=3)...................243
5.5.2Correlations:non-selectiveentrycasestudyschools(n=11).................244
5.5.3Correlations:provincialcasestudyschools(n=3).......................................246
5.5Summary..................................................................................................................248
CHAPTER6:DISCUSSIONANDFUTUREDIRECTIONS...........................................253
6.1Introduction...........................................................................................................253
6.2Discussionoffindingsaddressingresearchquestionone......................255
6.2.1TeachersandtheEVprogram................................................................................256
6.2.2TeachersandSOLO......................................................................................................265
6.3Discussionoffindingsaddressingresearchquestiontwo......................267
6.3.1Sciencedepartmentassessmentpractices........................................................267
6.3.2Formativeclassroompractices..............................................................................270
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6.4Discussionoffindingsaddressingresearchquestionthree..................279
6.5Suggestionsforfurtherresearch.....................................................................282
6.6Recommendations................................................................................................286
6.7Conclusion...............................................................................................................292
APPENDICES.......................................................................................................................296
AppendixA:Competencies,BasicSkills,GenericSkillsandKey
Competencies................................................................................................................296
AppendixB:GoalsforSchooling(1989–2008)................................................298
AppendixC:Ateachingsequenceexemplifyingdifferentviewsoflearning
............................................................................................................................................300
AppendixD:FiveexamplesinvolvingaspectsoftheSOLOmodel..............302
AppendixE:Proformaforcasestudyschoolstocomplete............................320
AppendixF:Scienceteachersurveyquestions..................................................322
AppendixG:Interviewquestionsforcasestudyschoolparticipants(final)
............................................................................................................................................328
AppendixH.Assessmentrelatednarrativesforcasestudyschoolsusedto
makepairwisecomparisons...................................................................................330
AppendixI:Datatablesforpairedschoolcomparisons.................................384
AppendixJ:Surveydescriptivestatistics.............................................................390
REFERENCES..................................................................................................................429
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ListofFigures
Figure Page2.1 Componentsofanevaluationandassessmentframework... 33
2.2 Selectedschooldataforagovernment,metropolitan,Years7-12school…………………………………………………………………….. 61
2.3 Effect-sizesofdifferencesbetweenExpertandExperiencedTeachers……………………………………………………. 72
2.4 Thethreeinteractingdomainsofpedagogy(instruction)…. 77
2.5 RepresentationoftheBiggs&Collis(1991)SOLOTaxonomy……………………………………………………………………… 82
2.6 RepresentationofthetwocycleswithinamodeSOLOmodel……………………………………………………………………………. 87
3.1 Regressionof2014EVresultsoveraNAPLAN-basedpredictor………………………………………………………………………... 109
4.1 MeansplotsforQ1&Q2combined………………………………..... 149
4.2 EVcategorymeansshowntobestatisticallysignificantlydifferent…………………………………………………………………………. 152
4.3 Teacherself-ratingfortheirunderstandingoftheEVprogram(n=85)……………………………………………………………. 155
4.4 MeansplotsforQ6…………………………………………………………. 1594.5 FrequencyVlevelofengagement(zerototen)………………… 1614.6 MeansplotsforQ7self-reportedunderstandingofSOLO…. 162
4.7 S7Frequency(n=85)verseslevelofunderstanding(onetofive)……………………………………………………………………………. 163
4.8 NKUAgraphicalrepresentationofmeans……………………….... 1664.9 MeansplotsforQ9–Q15……………………………………………….... 167
4.10 Surveyquestionssortedtoshowteacherorstudentastheleadactor……….………………………………………………………………. 169
4.11 Formativepracticemeansforallitems,teacheritemsandstudentitems(n=84)…………………………………………………….. 171
4.12 LISCmeansplots…………………………….………………………………. 1754.13 CDELcombined,TCDEL,SCDELmeansplots……………………. 1774.14 FTALcombined,TFTAL,SFTALmeansplots…………………….. 1814.15 ASIRmeansplots……………………………………………………………. 1844.16 ASTLcombined,TASTL&SASTLmeans…………………….…….. 186
4.17 Frequencyversesitemsetsforstudentsurvey(nonetothree)……………………………………………………………………………... 192
5.1Graphicalrepresentationofdescriptivestatisticsforidentified(ID)andcasestudy(CS)schoolscombinedandcasestudy(CS)schoolsseparately………………………………….. 205
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ListofTables
Table Page2.1 Summaryofneededchangestoteachingandassessment………….. 25
2.2 Issues to resolvewhenplanning and constructing assessmentsandhowtousethem………………………………………………………………... 49
2.3 Messick’saspectsofconstructvalidity……………………………..………. 512.4 Influencesonlearningandeffectsizes……………………………………… 74
2.5 The concept of evaporation through modes and levels (SOLOTaxonomy)…………………………………………………….………………………... 83
2.6 Selected outcomes and related SOLO levels in the 2011 EVassessmentframework…………………………………………………………..... 90
3.1 Structureofonlinesurveyforscienceteachers…………………………. 115
4.1 Defining populations from which to invite researchparticipants……………………………………………………………………………... 143
4.2 DescriptivestatisticsforQ1&2(n=85)…………………………………... 1494.3 ResultsofparametricANOVAforeightEVcategories………………... 1514.4 DescriptivestatisticsforQ3(n=85)………………………………………… 1544.5 SummaryofEVpurposes…………………………………………………………. 1564.6 DescriptivestatisticsforQ6(n=85)………………………………………… 1584.7 ParametricANOVA(n=85)forSOLOquestions(Q6&7)…............. 1604.8 Q6SOLOcategorycounts(n=85)………………………………………….….. 1604.9 DescriptivestatisticsforQ7(n=84)……………………………………….... 1624.10 Q8summaryofsourcesforlearningaboutSOLO…………………...….. 1644.11 MeansforNKUAoption(n=85)………………………………………………. 1664.12 DescriptivestatsforQ9-15(n=84)…………………………………………. 167
4.13 TestfornormalityandhomogeneityofvarianceforallitemsQs9-15(n=84)……………………………………………………………………........... 168
4.14 Sample items fromtheonlinesurveywitha teacherorstudentfocus………………………………………………………………………………….…… 170
4.15 DescriptivestatisticsforTAFL&SFAL(n=84)...…………………….... 171
4.16 Testsfornormalityandhomogeneityofvarianceonassessmentforlearning(AFL)responsesdatasets(n=84)………………………… 172
4.17 NonparametricANOVAonAFLALL,AFLteachersandAFLstudentmeans(n=84)……………………………………………………………. 173
4.18 Welchstatisticsforrobustequalityofmeans…………...…………..….... 1744.19 LISCcombinedmeans(n=84)…………………..…………………………….. 1754.20 CDELcombined,TCDEL&SCDELmeans………………………….……..... 177
4.21 TestsfornormalityandhomogeneityofvarianceonCDELresponsesdatasets(n=84)…………………................................................. 178
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4.22 ParametricANOVA:ALLCDEL,CDELteacherandCDELstudentmeans(n=84)………………………………………………………..….. 178
4.23 TCDEL&SCDELGames-Howellmultiplecomparisonstests………. 1794.24 FTALcombined,TFTAL&SFTALmeans…………………………………… 180
4.25 TestsfornormalityandhomogeneityofvarianceFTALresponsesdatasets(n=84)…………………………………........................... 181
4.26 NonparametricANOVAonFTALALL,FTALteacherandFTALstudentmeans(n=84)………………………………….……………………….... 182
4.27 TFTAL&SFTALGames-Howellmultiplecomparisonstest(n=84)………………………………………………………………………………………….. 182
4.28 ASIRcombined,TASIR&SASIRmeans……………………………………… 1844.29 ASTLcombined,TASTL&SASTLmeans……………………………………. 186
4.30 TestsfornormalityandhomogeneityofvarianceonASTLdatasets(n=83)………………………………………………..….... 187
4.31 NonparametricANOVAonASTLALL,ASTLteacherandASTLstudentmeans(n=84)…………………………………….................................. 188
4.32 TASTL&SASTLGames-Howellmultiplecomparisonstests(n=83)………………………………………………………….………………………………. 188
4.33 Dataaboutrespondentsandtheirschools………………………………… 1904.34 YEScountsforstudentsurveyitems…………………………………...……. 192
5.1 Schoolsthatidentifiedthemselvesincludingcasestudyschools(shaded)…………………………………………………………………………………. 202
5.2 MeanstandardisedresidualsandSEAscores……………………………. 2045.3 PairONEselectedstatistics……………………..…………………………….… 2135.4 Year12sciencecoursecompletions(2013-2015averages)………. 2155.5 PairTWOselectedstatistics…………………………………………………..… 2185.6 Year12sciencecoursecompletions(2013-2015averages)………. 2205.7 PairTHREEselectedstatistics………………………………………………….. 2225.8 Year12sciencecoursecompletions(2013-2015averages)………. 2245.9 PairFOURselectedstatistics……………………………………………….…… 2285.10 Year12sciencecoursecompletions(2013-2015averages)………. 2305.11 PairFIVEselectedstatistics……………………………………………………… 2345.12 PCWAE2andPCWAE3Year8EVresults…………………………………... 235
5.13 Casestudyschoolranksbasedonstudentscoresforthesixitemsfromthestudentsurvey....................................................................... 236
5.14 Year12sciencecoursecompletions(2013-2015averages)…….... 238
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Abstract
ResearchersworkingwithschoolsintheUKandelsewherearefindingthat
explicitlyteachingstudentsthe“fivestrategiesofformativeassessment”(Black
andWiliam,2009,p.8)ishelpingtore-engagestudentswithscience.Thisthesis
presentsfindingsabouttheimpactoftwomajorinterventionsontheassessment-
relatedworkofjuniorsecondaryscienceteachersintheNewSouthWales
governmentschoolsystem(thelargestinAustralia)andonstudentscienceresults.
Thefirstinterventiontooktheformofadvicetoteachersaboutformative
assessmentintheofficialsciencecurriculum(introducedin2003),whereitis
calledassessmentforlearning.Thesecondtooktheformofamandatorylow-
stakes,large-scale,test-baseddiagnosticassessmentprograminvolvingYear8
students.ThisprogramwasfullyimplementedacrossNSWfrom2007.The
assessmentframeworkusedtoinformthedevelopmentoftestitemsandtasksand
thatinformsthecomprehensivefeedbackprovidedtostudents,parentsand
teachersisunderpinnedbyStructureoftheObservedLearningOutcome(SOLO)
theory.Threeresearchquestionsguideddatacollection.Theresearchdesign
employedmixedmethods,includingbothquantitativeandqualitativemethodsas
wellascasestudiesinvolvingsixteenpurposivelychosenschoolsites.Descriptive
andinferentialstatisticswereappliedtotheanalysisofbothstate-wideand
school-specific,teacher-providedsurveydataabouttheirpracticesandschool-
leveltestresults.Aninterpretiveapproachwasusedtogenerateassessment-
relatedworknarrativesfromaudio-recordedinterviewsandartefactsof
assessmentpracticeprovidedtotheresearcherbyvolunteeringscienceteachers
inthecasestudyschools.Thefindingsshowthatteacheruseofthreeoffive
dimensionsofformativepracticeandanexplicitfocusonteachingstudentsthe
skillsofwritingtolearnscienceproducedsciencetestresultsthatwereabove
expectation.Lesscertainwasthehoped-forfindingthatstudentswerealso
acquiringtheskillsoflearninghowtolearn.Anunexpectedfindingwasthat
studentsinregionalschoolswherescienceresultswerewellaboveexpectation
werelesspositiveabouttheirschoolscienceexperiencethantheirmetropolitan
counterparts.
1
CHAPTERONE:OUTLINEOFMYPROJECT
1.1Introduction
ThisthesisreportsinsixchaptershowIusedamixedmethodsresearchdesignto
exploretheimpactoftwoassessmentinitiativesonteachers’assessment-related
workandstudentresultsinthelargestgovernment-runschoolsysteminAustralia.
Thefindingsarethenusedtoargueinthefinalchapterfortheretentionofboth
initiativesandtosupportrecommendationstoenhancetheirfutureeffectiveness.
EducationinAustraliaistheresponsibilityoftheeightstatesandterritoriesthat
makeuptheCommonwealthofAustralia(CommonwealthofAustralia
ConstitutionAct,1901).Thestateandterritorygovernmentsinthosejurisdictions
haveestablishedgovernment(orpublic)schoolsystemswhicharemanagedby
educationdepartmentsresponsibletothosegovernments.Educationdepartments
allocateandmanagethehumanandphysicalresourcesprovidedbygovernments
todelivereducationalservicestostudentsinthegovernmentschoolsystem.
Studentsenrolledinthegovernmentschoolsystemareentitledtofreeeducation
fromage5to17years.
Privateinterestshavealsoestablishedschoolsineachofthestateandterritory
jurisdictions.Themajorityofthoseschoolsareaffiliatedwithorganizedreligions.
TheCatholicChurchsupportsthelargestnumberofschoolsaffiliatedtoareligious
organization.Privateschoolswithacommonphilosophyorreligiousaffiliation
haveformedthemselvesintosystemsforthepurposesofefficientandeffectiveuse
ofresources.Parentspayschoolfeesdirectlytoprivateschoolstosendtheir
studentsthere.However,allschoolsystemsinAustraliareceivemoneycollected
bygovernmenttaxsystems.
Thegovernmentsoftheeightstatesandterritorieshaveestablishedautonomous
authoritiestomanagetheregistrationandaccreditationofschoolsestablishedby
bothgovernmentandprivateinterests.Registrationensuresthecommunitythat
theirchildrenareeducatedinappropriatephysicalsurroundingsandprovided
2
withadequatehumanandotherresourcestosupporttheirlearning.Accreditation
ensuresthatstudentshaveaccesstoeducationalprogramsbasedonahigh-quality
curriculumandrelatedassessmentandcredentialingprocesses.Registrationand
accreditationprocessesaredeterminedandmanagedindependentlyofdirect
governmentinfluence.Inrecenttimesstateandterritorygovernmentshaveadded
registrationofteachersandaccreditationoftertiaryeducationcoursespreparing
peopleforteachingtotheresponsibilitiesofthoseautonomouseducation
authorities.
Overthepastfourdecades,theeightstateandterritorygovernments,with
supportfromthenationalgovernment,havebeenworkingtowardashared
nationalpolicyagendaforeducationinAustralia.In2008,bycooperative
agreementofthenationalandallstateandterritorygovernments,theAustralian
CurriculumAssessmentandReportingAuthority(ACARA)wasestablishedto
performthefollowingfunctions“developmentofnationalcurriculum,
administrationofnationalassessmentsandassociatedreportingonschoolingin
Australia”(ACARA,2016a).ACARAisresponsibletotheCouncilofAustralian
Governments(COAG)EducationCouncil.
NewSouthWales(NSW)isthemostpopulousstateinAustraliaandaround20%
ofallsecondaryschoolstudentsinAustraliaattendagovernmentschoolinNSW
(ABS,2018).It’sDepartmentofEducation(“theDepartment”inthisthesis)
managesthelargestgovernmentschoolsystemofalleightstatesandterritories.
TheautonomouseducationauthorityinNSWisatthetimeofwritingthistheNSW
EducationStandardsAuthority(NESA)andisreferredtoas“theBoard”inthis
thesis.ItwasvariouslytheNSWBoardofStudies(BOS)thentheNSWBoardof
Studies,TeachingandEducationalStandards(BOSTES)beforebecomingNESAon
January1,2017.DatausedinthisresearchwasprovidedtomebytheDepartment
andbyscienceteachersworkingingovernmentsecondaryschoolsacrossNSW.It
wassupplementedbyschooldataavailableonthenationalMySchoolwebsite
managedbyACARA.
3
Thefollowingsection,Section1.2,willoutlinethetwoassessmentinitiativesthat
arethefocusofinterestforthisthesis.Section1.3willoutlinetheresearch
questionsandmethodology.Section1.4willprovideanoverviewofthefindings.
Section1.5explainstheimportanceoftheresearch.Section1.6willexplainmy
interestinthetwoinitiativesandSection1.7,thefinalsectioninthischapter,will
outlinethestructureofmythesis.
1.2Thetwoinitiatives
Thephrase‘formativepractices’inthetitleofthisthesisistakenfromapaperby
tworesearchers,BlackandWiliam(2009)titledDevelopingthetheoryofformative
assessment.Theyusedthephrasetocovertheorizingaboutinstructioninformed
byfeedbackfromassessment.Thepaperhaditsoriginsinworkthepairhadbeen
commissionedtodosomethirteenyearsearlierbytheUKbasedAssessment
ReformGroup(ARG)withfundingfromtheNuffieldFoundation.BlackandWiliam
werecommissionedtoreviewtheliteratureontheuseofassessmenttosupport
learning,alsoknownasformativeassessment.Theresultsofthatreviewwere
publishedinabookletforteacherscalledInsidetheBlackBox(Black&Wiliam,
1998b).
TheARGhadusedthephrase“assessmentforlearning”(ARG,2002a,p.3)to
differentiateitfrom“assessmentoflearning”(ARG,2002a,p.3).Afullexplanation
ofthedistinctionsbetweenthetwowillbeprovidedinChapterTwo,theliterature
reviewforthisthesis.Thisthesiswillexploretheassessment-relatedworkof
teachersintheearlyyearsofsecondaryschoolingtofindouttheextenttowhich
thatworkcouldbedescribedas“formative”inBlackandWiliam’s(2009,p.8)
theoryofformativeassessment.Inotherwords,theextenttowhichinstructionor
teachingisexplicitlyinformedbytheresultsofassessment-relatedworkof
teachers.
Assessment-relatedworkofscienceteachersisdefinedhereasthepurposeful
collectingofevidenceoflearning,creatingthemeansbywhichthatevidencewas
obtained(ifnotbydirectobservationofbehaviour),theassumptionsusedto
interpretthatevidence,thechoiceoftextformsusedtorepresentand
4
communicateresultsofassessment,andsubsequentusesforthoseresults.
‘Studentresults’asusedinthetitlereferstotherepresentationofthejudgment
madebyteachersaboutthevalueoftheteachercollectedevidenceofstudent
learning.Itistypicallyrepresentedbyagrade,amark(sometimesexpressedasa
percentage)oralevel(inthisproject,sixlevelswerecommon).Thisformofresult
iswhatismeantbyassessmentoflearning.Itbecomesassessmentforlearning
whenitisusedtoinformthenextstepinteachingorinstruction(feedback)while
itishappening.
Thefirstoftheinitiativesusedinthisstudywasassessmentadviceforscience
teacherstitled:“AssessmentforLearning?”(BOS,2003,p.70).Itwasembeddedin
the2003releaseoftheofficialsciencecurriculumdocumentsthatsecondary
scienceteachersareexpectedtousewhenpreparingteachingandlearning
programsfortheirstudents.Theinitiativetooktheformofadvicetoteachers
abouthowtogatheranduseevidenceoflearningtoinformthenextstepsin
instructionasitwashappening.Inotherplaces‘assessmentforlearning’is
referredtoas“classroomassessment”byShepard(2001,p.2)or“formative
practices”byBlack&Wiliam(2009,p.6)intheirpaperonthetheoryofformative
assessment.Thecurriculumdocument(alsoreferredtoasasyllabusinNSW)
summarisesthescopeofassessmentforlearningforscienceteachersinthese
terms.It:
1. isanessentialandintegratedpartofteachingandlearning
2. reflectsabeliefthatallstudentscanimprove
3. involvessettinglearninggoalswithstudents
4. helpsstudentsknowandrecognisethestandardstheyareaimingfor
5. involvesstudentsinself-assessmentandpeer-assessment
6. providesfeedbackthathelpsstudentsunderstandthenextstepsinlearning
andplanhowtoachievethem
7. involvesteachers,studentsandparentsinreflectingonassessmentdata.
(BOS,2003,p.70)
5
Thefocusonassessmentforlearninginofficialcurriculumdocumentswasa
strongsignaltoteachersabouttheneedtoshifttheemphasisfromusingevidence
oflearningforreportingachievementafterinstructiontoimprovinginstruction
itself.Otherimplicationsarethatcurriculumintentions,instructionand
assessmentshouldbealignedandthatstudentsandthewiderschoolcommunity
needtobemoreinvolvedmore.Thecurrentcurriculumdocuments(BOSTES,
2012)continuewiththatemphasisandhaveextendedittoincludeadviceon
“assessmentaslearning”aswellas“assessmentofandforlearning”(NESA,2018).
Allthreewillbediscussedfurtherintheliteraturereview(ChapterTwo).The
current(2018)curriculumforscienceinNSWreplacedthe2003curriculum
beginningwithYear7and9in2014.
Thesecondinitiativewasatest-basedinterventioncalledatthetimeofits
introductiontheEssentialSecondaryScienceAssessment(ESSA)program.The
testwasdeliveredtostudentsatthemidpointofamandatoryfour-yearscience
coursecommencingintheirfirstyearofsecondaryschooling(Years7to10in
Australia).Afterpiloting(2005)andtrialing(2006),thefirsttestforthefullcohort
ofYear8studentswasin2007.Initsinitialform,itwasapen-and-papertestwith
thesame‘lookandfeel’asotherpen-and-papertestsstudentswereusedtodoing.
Itwassubsequentlydeliveredonlinefrom2010andcontinuestobedeliveredthis
way.Itwasthefirstcohorttesttobedeliveredonlinebyaneducationjurisdiction
inAustralia.
Thetestwasdesignedtodomuchmorethanprovideareporttoparentson
studentachievementatthemidpointofafour-yearsciencecourse.Itwasdesigned
as“adiagnostictooltoidentifywhatstudentsknowandcandoandwhere
teachingneedstobedirectedtoenhancescientificunderstanding”(Panizzon,
Arthur,&Pegg,2006,p.1).Tobettersupportthatgoal,theassessmentframework
wasinformedbytheStructureoftheObservedLearningOutcome(SOLO)model.
SOLOisa“cognitivestructuralmodel”(Panizzon,2003,p.1428)developedfrom
empiricalstudiesofthestructureandsophisticationofthelanguageusedby
studentsintheirresponsestotestitemsandtasks.TheSOLOmodelusedinNSWis
6
basedontheSOLOtaxonomyoriginallypublishedbyBiggsandCollis(1982,
1991).
TheassessmentframeworkdevelopedfortheESSAprogramenabledamaptobe
createdthatputssyllabusexpectationsalongoneaxisandlevelsofunderstanding
aboutthoseexpectationsalongasecondaxis.Howthisworkswillbeexplained
furtherinChapterTwo.Thetestwasalsoaccompaniedbyasurveydesignedto
findoutwhatstudentsthoughtaboutscience,theirschoolscienceexperienceand
thetestitself.Theresultsofthesurveyanalysiswereprovidedtoscienceteachers
alongwithdetailedfeedbackaboutstudentresponsestoeveryitemandtaskinthe
test.
TheESSAprogramwascompulsoryforallYear8studentsinthegovernment
schoolsystemandforYear8studentsinnon-governmentschoolsthathadopted
intotheprogram.Theprogramwasexpandedin2015toincludeatestforYear6
andYear10studentsandrenamedValidationofAssessmentforLearningand
IndividualDevelopment(VALID).Theadditionoftwoextratestsprovidedschools
withawayofmappingtheprogressionofstudentlearninginsciencefromYears6
toYear8andthenYear10.
VALID8remainedcompulsoryforallgovernmentschools,butthenewVALID6and
VALID10testswere(andstillare)optionalforbothgovernment(andnon-
governmentschoolswantingtoparticipate).Astheprogramnamechangetook
placebeforedatacollectionbeganinthisproject(secondhalfof2016)andschools
werealreadycallingittheVALIDprogram,IchosetousetheacronymEVinthis
thesistoreflectboththeoriginal(ESSA)andnew(VALID)acronyms.Iwillreferto
theEVprogramorEVtestfromthispointonwards(unlessitismoreappropriate
torefertoeitherESSAorVALID).
Theperiodofinterestforthisprojectisfrom2011to2014inclusivewhichwere
thelastfouryearsofdatalinkedtoteachers’workusingthe2003curriculum.The
EVprogramisappropriatelydescribedasanexternal,large-scale,low-stakes,
diagnosticintervention.‘External’referstothesourceofthetest,whichisexternal
totheschool.‘Large-scale’referstothesizeoftheprogram,whichincludesall
7
NSWgovernmentschoolswithYear8students(465schoolsatthetimeofthis
research).ThestudentcohortsizeinYear8from2010to2015numberedaround
47,000students.Thestatisticsquotedforthesizeofthegovernmentschool
systemandthesizeoftheEVprogramweresourcedfromtheNSWDepartmentof
Education.
‘Low-stakes’isarelativedescriptorfortheimpactoftheEVprogramonstudents,
theirparentsandtheirteachersasexplainedfurtherinChapterTwo.
Diagnosticassessmentreferstotheintendeduseofassessmentresultstoidentify
strengthsandweaknessesinstudentlearning(Goodrum,Rennie,&Hackling,
2001;Hackling,2004;Masters,2013;Millar&Hames,2003;Treagust,2006).
Thewidercontextforthetwoinitiativesdescribedinthissectionwillbedescribed
inthefirstsectionoftheliteraturereview.
1.3Researchquestionsandmethodology
Thissectionoutlinesthespecificresearchquestions,theresearchdesignand
relatedmethodologiesusedtoguidethisresearchproject.Afullaccountofthe
methodologywillbeprovidedinChapterThree.
Theobjectiveofthisstudyistoanswerthemotivatingquestionofwhatimpactare
thetwoinitiativesofformativeassessmentandthediagnosticEVtesthavingon
theassessment-relatedworkofscienceteachersinNSWgovernmentschoolsand
whyitmatters?
Threeresearchquestionsprovidethefocusforthisresearch:
1. WhatusearescienceteachersmakingoftheEVprogramincludingSOLO
andwhyisitusedornotused?
2. Whatformativepracticesareevidentintheworkofscienceteachersand
whyaretheyusedornotused?
8
3. Istheuseofformativepracticesbyteacherslinkedtoimprovementin
students’EVresultsandlaterachievementinandengagementwith
science?
ThefirstquestionisaboutidentifyingtheextenttowhichEVtests,EVresultsor
relatedresources(includingSOLOtheory,studentsurveyresultsandprofessional
learningopportunities)havebeenaccessedandusedbyscienceteacherstoinform
assessment-relatedworkattheirschools.
Thesecondquestionisabouttheextenttowhichformativepracticesareevidentin
teachers’assessment-relatedwork.ChapterTwowillelaboratethetheoretical
frameworkoffivedimensionsofformativepracticeusedinthatexplorationof
teachers’work.“Formativepractices”isaphraseusedbyBlackandWiliam(2009,
p.8)intheirdiscussionofthetheoryofformativeassessment.Inthatdiscussion
BlackandWiliamexplorethelinksbetweenwhattheycallthefivestrategiesof
formativeassessmentandtheirrelationshipstopedagogyorinstruction.Idecided
touseBlackandWiliam’sphraseandinvented“fivedimensions”offormative
practiceasthebasisforcharacterisingteachers’responsestoitemsinanonline
surveyabouttheirwork.Thefivedimensionswerebasedonthefivestrategiesof
formativeassessmentasarticulatedbyBlackandWiliam(2009)intheirpaper.
Thethirdquestionisaboutinvestigatingtheassociationbetweenformative
practicesandachievement(asmeasuredbyEVresultsandotherassessmentsin
science)andlatertake-upofsciencecoursesinthesenioryearsofsecondary
schooling(ameasureofongoingorlaterengagement).
Alsoexploredinrelationtothethirdquestionwastheextenttowhichthe
formativepracticesobservedintheassessment-relatedworkofscienceteachers
mayhaveassistedlearners’acquisitionofself-regulation(Boekaerts&Corno,
2005).Self-regulationdescribesstudentswhoaregoodmanagersoftheirlearning,
likelearningandcontinuetheirinvolvementinlearning.Theexpectationthat
somestudentshaddevelopedthoseattributesasaresultofexposuretoformative
practicesusedbyscienceteacherswasbasedontheworkbeingdoneintheUKby
Black,McCormick,JamesandPedder(2006),andJamesetal.(2007).
9
Threepredictionsweremadetotesttheassumptionofacquisitionofself-
regulationbysomestudents.Confirmationofthethreepredictionswouldbetaken
asevidencethattheassumptionofself-regulationforsomeofthestudentswas
reasonable.Thethreepredictionsandthethinkingbehindthemisdiscussedin
ChapterThree.Analysisofdataprovidedbycasestudyschoolsarereportedin
ChapterFive.16schoolsidentifiedthemselvesaswillingtobeinvolvedinacase
studyasoutlinedbelowandfullyinChapterThree.
Thecapacitytomanageone’slearningisanessentialskillinthecontextofthe
knowledgesocietyandrelatedeconomywherethecapacitytolearnnewskillsand
adapttochangeisincreasinglyimportantformaintainingajobandwiderlife
satisfaction(UNESCO,2005,p.27).ChapterTwodescribessomeoftheworkbeing
donetoteachstudentsthestrategiesofformativeassessmentasonemeansfor
producingstudentself-regulation.Itisforthisreasonthathelpingteachersto
adoptformativepracticeastheirdefaultpedagogy“matters”(seethemotivating
questionforthisresearchprojectstatedatthebeginningofthissection).
Theresearchdesigninvolvedmixedmethodsexecutedinthreephases.Anoutline
ofthephasesfollows.FulldetailswillbeprovidedinChapterThreeand
subsequentchapters.
ThefirstphaseemployedaquantitativeinferentialstatisticsprocedurewhereEV
resultswereregressedoveranEVresultpredictorandtheresidualsfromthat
regressionwereusedtoidentifythreegroupsofschools.Onegrouphadschools
withlargepositiveresiduals,asecondgroupwithzeroorclosetozeroresiduals
andathirdgroupwithlargenegativeresiduals.AswillbeexplainedinChapter
Three,schoolsinthesethreegroupsareassociatedwithEVresultsthatwerewell
above,atorwellbelowexpectationrespectively.
ExpectationwasrelativetotheEVresultpredictor.TheEVresultpredictorwas
developedfromacombinationofreadingandnumeracyresultsobtainedby
studentsinnationaltestinginYear7andagaininYear9.Thereasoningforusing
suchapredictorisexplainedinChapterThree.
10
TheDepartmentaccesseditsrecordsoftestresultsforschoolswith10ormore
studentsinYear8whohadsattheEVtestinfoursuccessiveyearsfrom2011to
2014inclusive.ItalsomatchedthosestudentswiththeirYear7andYear9reading
andnumeracyresultsfromnationaltestingandretainedthoseresultsforstudents
whohadsatthetestsatthesameschoolinsuccessiveyears.Readingand
numeracyresultswereusedtogeneratefourpredictorsofEVresultsforthe10or
morestudentsineachschool.IntheendtheDepartmentprovidedmewithfour
setsofregressionresidualsfrom394schools(outofapotential465).
Usingoneofthefoursetsofresiduals,Iidentifiedthreegroupsofbetween80-90
schoolsusingthesizeandpolarityoftheirresidualsasthebasisforallocationto
oneofthethreegroups.Scienceteachersattheselectedschoolswereinvitedto
completeananonymousonlinesurveyabouttheirteachingandassessment
practices.Responseswerecollatedaccordingtotheschoolgroupthescience
teachershadbeenassignedto.
Thesecondphaseemployedaquantitativemethodtoanalyseteacherresponsesin
eachofthethreegroupsandthentocomparetheresultsfromeachgroupfor
statisticallysignificantdifferences.TheprocedureusedwasAnalysisofVariance
(ANOVA).Itspurposewastofindoutwhethertherewerestatisticallysignificant
differencesinassessment-relatedpracticesofteachersineachofthethreegroups.
Analysisandfindingsfromthefirstandsecondphaseoftheresearchwere
reportedinChapterFour.
Thedefaultpositionforresponsestotheonlinesurveywasrespondentanonymity.
However,respondentswhowishedtobeconsideredforinvolvementinacase
study(thethirdphaseoftheresearchdesign)wereinvitedtoidentifythemselves
andtheirschool.Teachersat36schoolsspreadacrossthethreegroupsidentified
themselves.Betweenfourandsixoftheidentifiedschoolsfromeachofthethree
groupswereinvitedandsubsequentlyparticipatedincasestudies.
TeachersatcasestudyschoolswereinvitedtoprovideschoollevelEVandYear10
results,numbersofstudentscompletingYear12sciencecoursesandartifactsof
11
teacher-producedassessment-relatedworkconsideredbythemtobeexemplary
practice(includingtestorassignmentitemsandtasks,relatedmarkingrubrics,
sampleschoolreports,assessmentplansorsciencedepartmentprogramswhere
assessmentwasexplicitlydescribed).Teacherswereaskedtobringtheartifactsto
asemi-structuredinterviewattheschoolwhichwasplannedtotakeupanhourof
theirtime.Theinterviewswithteacherswereaudiorecorded.Accesstostudents
wasnotpartoftheresearchdesign.
CasestudyschoolsprovidedYear8,Year10resultsandYear12completiondata.I
sourcedandcollectedcasestudyschools’socio-educationaladvantageprofiledata
fromtheACARAmanagedMySchoolwebsite.Thatdataandtheresidual(from
phaseone)werecollatedandanalysedusinginferentialstatisticstoestablishthe
strengthofcorrelationstoconfirm(ordisconfirm)threepredicationsrelevantto
answeringthethirdresearchquestion.Interviewsandartifactswerequalitatively
analysedandassessment-relatedworknarrativesweredevelopedfromthat
analysisforeachofthecasestudyschoolsaswell.
Thepropositionthatinstructionconsistentwithformativepracticesmayhave
supportedstudents’self-regulatedpracticeswasalsotestedinthecontextof
answeringresearchquestionthree.
Findingsfromquantitativeanalysesperformedinthecasestudythird,phaseofthe
researchalongwithsupportingevidenceandexamplesfromtheassessment-
relatedworknarrativesforthoseschoolswerereportedinChapterFive.
Anonymityforparticipatingteachersandtheirschoolswasguaranteedforthis
research.Thestepstakentoprotecttheidentitiesofparticipatingschools,dataand
teachersaredescribedinChapterThree.
1.4Overviewoffindings
Intermsofthemethodology,thereading-numeracypredictorchosenaccounted
for89.2%oftheexplainedvariationaveragedoverthefouryears(2011-2014)of
results.Thisisaverystrongcorrelationgiventhatotherlarge-scaletesting
12
programsinvolvingpredictorsandregressionanalysis,suchasACARA’sIndexof
CommunitySocio-EducationalAdvantage(ICSEA),accountedfor81%ofexplained
variationin2013NAPLANresults(ACARA,2014b)and80%ofthe2014results
(ACARA,2015).WhenRowe(2006)analysedthe2003PISAresultsforthe
Australiansampleof15year-oldstudents,hefoundthattheboys(n=6335)
readingresultsaccountedfor77.4%oftheexplainedvariationintheirscience
results;thecomparablefigureforgirls(n=6216)was75.3%(Rowe,2006,p.8).
Thesamestudentssatboththereadingandthesciencetests.
Whentheresidualsforallschoolsanddifferentschoolcategorieswereanalysed,it
wasfoundthatEVresults“werebetterthanexpected”(i.e.theresidualwas
positive)in:
• 53%ofthe394schoolsinthestudy;
• 67%oftheprovincialschools(n=anestimated90schools);
• 68%ofthefullyselectiveentryschoolsschools(n=19);and
• 23%ofthepartiallyselectiveentryschools(n=24).
InrelationtothefirstresearchquestionaboutteacheruseofEVresourcesand
SOLO,somefindingswerethat:
• 67%ofscienceteachersmadeuseofEVresourcestosupporttheir
assessmentprogramsandin-classwork;
• 25%ofteachersratedtheirunderstandingofSOLOasgoodorverygood;
and
• 18%ofteacherssaidtheyusedSOLOasabasisforfeedbacktostudentson
theirlearning.
Whenitcametostudentsurveyresults(thesurveyaccompaniedtheEVtestanda
newfeatureofexternaltestinginNSW):
• 67%ofscienceteacherssaidtheyhadlookedattheresults
• 49%haddiscussedtheresultswiththeircolleagues;and
• 18%ofteacherssaidtheyhaddiscussedtheresultswiththeirstudents.
13
Inrelationtothesecondquestion,therewerestatisticallysignificantdifferencesin
theusebyteachersofthreeofthefivedimensionsofformativepractice.The
teachersatschoolswhereresultshadbeenidentifiedasbeing“wellabove
expectation”(orWBEschools,comparedtotheircolleaguesintheothertwo
groupsofschools,weremorefrequentusersofactivitiesinvolving:
• discoursethatelicitsevidenceoflearning;
• theprovisionoffeedbackknowntoprogresslearning;and
• theuseandmodelingof“goodlearningbehaviours”(Boyle,Fahey,
Loughran&Mitchell,2001,p.200).
Forthethirdresearchquestion,theanswertothefirstpartofthequestion(Isthe
useofformativepracticesbyteacherslinkedtoimprovementinstudents’EV
results…)wasastrongyes.WhenitcametoextrapolatingthatresultbeyondYear
8toYear10achievement(…laterachievement),uncertaintyaboutthe
comparabilityofYear10dataacrossschoolswastoogreattohavereasonable
confidenceinbetweenschoolcomparisons.ThewithinschoolcorrelationsforYear
8andYear12sciencecoursecompletionsandYear10achievementandYear12
sciencecoursecompletionswashighlypositiveandstatisticallysignificant.
Theassumptionthatschoolswhereresultswere‘wellaboveexpectation’would
havemoreself-regulatedstudentsthanotherschoolswasthebasisforthree
predictionsaboutlaterachievementandlaterengagement.Thetermsachievement
andengagementasusedinthisprojectaredefinedinChapterThree.The
predictionsrelatedtocomparableschools(schoolswiththesamesocio-
educationaladvantage).Noneofthepredictionscouldbeconfirmedbeyond
reasonabledoubtwhichinturnrenderedtheunderlyingassumptionofself-
regulationdoubtfulaswell.
Contributingtotheuncertaintyaboutself-regulationwasthefindingthatstudents
atthethreeprovincialcasestudyschoolsthathad‘wellaboveexpected’EVresults
werelesspositiveabouttheirschoolscienceexperiencethanstudentsinthe
metropolitancasestudyschools,mostofwhomwereinschoolswhereEVscores
were‘at’or‘wellbelowexpectation’.
14
1.5Importanceoftheresearch
Twoclaimsabouttheimportanceofthisthesisaremade.Thefirstclaimisthatthis
projectwasthefirstlargescalestudyinAustraliausingtheresultsfroman
externalsciencetesttoprovideconfirmationthatformativeassessmentand
relatedinstruction(formativepractices)areassociatedwithbetterlearning
outcomesinscience.
Here“better”meansthattheschool’soverallscienceresultshadahighermean
thanthescienceresultsoftheschoolitwasbeingcomparedto.Inthiscontext
‘comparable’meansaschoolorschoolswiththesamesocio-educationaladvantage
score(ameasureofthecollectivelearningpotentialofstudentsataschool;its
derivationisexplainedinChapterThree).
Thewordingoftheclaimandthenotionofcomparableschoolsrelatetothe
methodologyinvolvedinproducingtheevidencefortheclaimedassociation
betweenteacheruseofformativepracticesandstudentlearning.
Asaresult,thisstudyaddstothegrowingbodyofevidencefromaroundtheworld
abouttheeffectivenessofformativepractices.Asynthesisofkeyliteraturelinking
formativepracticestobetterlearningoutcomesispresentedinChapterTwo,the
literaturereview.
Specifically,myresearchshowedthatstudentsattainedbetterresultsinthose
schoolswhereteachersprovidedstudentsmorefrequentlywith‘science-rich’
activitiesinvolvingthreeofthefivedimensionsofformativepractice(Black&
Wiliam,2009).Thedimensionswere:classroomdiscourseelicitingevidenceof
learning;teacherfeedbackknowntoprogresslearningofthatcontentandteacher
useandmodelingof“goodlearningbehaviours”.
Thesecondclaimforimportancerelatestothestudy’smethodology.The
methodologyinvolvestakingastudent’sresultsfromnationalliteracyand
numeracytestingtogenerateapredictorfortheirresultinasciencetest.Aswas
discussedinthesectionabove,theregressionofsciencetestresultsoverthesame
15
students’setofsciencepredictorscoresproducedaschoolsetofindividual
residuals.Theclaimhereisthattheresidualisameasureoftherealanddirect
contributionofscienceteachingtothesciencelearningofstudentsatthatschool.A
positiveresidualmeansthatastudenthaslearnedmoresciencethanexpected;a
negativeresidualmeansstudentshavelearnedlessthanexpected.When
individualresidualsaresummedandaveraged,theindividualstudentresiduals
produceaschoolscore.
Whentheresidualsfromallschoolswherethisprocesshasbeenappliedare
standardizedtheycanbecompared.Schoolswithlargerpositiveresidualshave
donemoreforstudentscientificliteracythanthosewheretheresidualsarelarge
andnegative.TheprocessfromresidualtocomparingactualschoolEVresults
commencesinChapterThreeandthefindingsreportedinChapterFour.
Anunanticipatedfindingwasthatscienceteachinginprovincialschoolshad
producedbetterthanexpectedresultsbutthat(forhighperformingcasestudy
provincialschoolsatleast)studentswerenotenjoyingtheirschoolscience
experiences.Thislastfindingwasanimportantconsiderationinconcludingthatan
assumptionofself-regulationasacontributortolaterachievementandlater
engagementwasnotwarranted.
1.6Theresearcher
Ibeganmycareerinscienceeducationasasecondaryschoolscienceteacher
(1967to1979)beforetakingontheroleofheadteacher,scienceintheNSW
governmentschoolsystem(1980to1993).Iacceptedtheroleofseniorscience
managerinthethennewlycreatedcurriculumsupportdirectorateoftheNSW
DepartmentofEducation(1994to2005).Inthatrole,Iprovidedcurriculum
supporttoscienceteachersingovernmentschoolsacrossNSW,managedthe
developmentofanumberofsciencecurriculumsupportresources,provided
policyadviceonscienceeducationtoseniormanagementintheDepartmentand
ledprofessionaldevelopmentforastatewidenetworkofscienceconsultants.
16
IrepresentedtheDepartmentatthenationallevelasamemberofsteering
committeesandasacontributortonational,scienceteaching,curriculum,
assessment,professionalstandardsandcurriculumsupportreviewsandprojects.I
alsoparticipatedregularlyintheannualconferencesoftheAustralianScience
TeachersAssociationandAustralasianScienceEducationResearchAssociation.
Commencinginthemid-1970s,IhadanumberofroleswiththeNSWcurriculum
andassessmentauthorityasasciencecurriculumwriter,curriculumpolicyofficer
onsecondmentfromschool(1987to1990).Iwasamember,thenchair,ofthe
authority’ssciencecurriculumcommittee,aHSCexaminationmarker,chairofa
HSCexaminationcommitteeandsupervisorofmarkingforaHSCsciencecourse.
LaterIhadarolewithACARAasbothacurriculumwriterfortheF-10Australian
sciencecurriculumandsubsequentlyasanofficerassistingwithdevelopmentof
theseniorChemistryandPhysicscurriculumdocuments.
IjoinedtheScienceTeachersAssociationofNSWin1967andwaselectedVice-
Presidentontwoseparateoccasions.Iwasalsoaconvenoroftheirprofessional
developmentcommitteeandannualconferences,contributortothoseconferences
andtheseniorjudgeandmarkingtrainerfortheirYoungScientistAward.Ialso
representedSTANSWasamemberoftheteamengagedbyASTAtowritetheir
professionalstandardsdocumentforHighlyAccomplishedTeachers(ofscience)
whichbecameamodelforlaterprofessionalstandardsdocuments.Iwasawarded
anhonorarylifemembershipofSTANSWin1997.
IbecameacasuallecturerandthencoordinatorfortheBachelorsandMasterspre-
servicescienceteachercoursesattheUniversityofTechnologySydney(2004to
2015).Iwasalsoamemberofteamsthatresearched,developed,piloted,trialed
andmarkedthefirstEVtests.Duringthattime(2005to2008)Iledthetrainingfor
markersoftheextendedresponsetasksaswellasbeingthekeyliaisonperson
betweentheDepartmentandtheagencycontractedtomanagetheonlinemarking
oftheextendedresponsetasks.
Thisthesisistheculminationformeoffivedecadesofworkinscienceeducation,
startingwithpart-timedegreesatMacquarieUniversity(BAmajoringin
17
CurriculumandGeophysics,completedin1974)andTheUniversityofSydney
(MEdmajoringinCurriculum,awardedin1991).
Itismyintentiontousetheresultsfromthisstudytosatisfycriteriafortheaward
ofaPhDandforfutureadvocacywork.ThelatterwillbeachievedwhenIprovide
feedbackfromthisstudytoparticipantschoolsandpolicyadvicetothe
DepartmentofEducation,NSW.Totheextentthatmyadvocacyproducessupport
fromtheDepartmentforteacherprofessionaldevelopmentleadingtomore
confidentandaccomplisheduptakeofformativepractices,thenthetransformative
intentofthisstudywillberealised.Inaddition,Iwillbeofferingmysupporttothe
schoolsthatparticipatedinthisstudy,shouldteacherstherewishtoimplement
adviceprovidedinmyfeedbacktothem.
FromtheaboveresuméitisappropriatetosaythatIbringbothaninsiderand
outsiderperspectivetothisdoctoralstudy(Fensham,2013).Iwasaninsiderinthe
followingways:
• asaresearchparticipantintheinitialevaluationofthesuitabilityofthe
SOLOmodelininformingthedevelopment,implementationandmarkingof
theEVextendedresponsetasksinthefirstfouryearsofitslife;
• asamemberofreferencegroupsforthereviewintothestatusandquality
ofschoolscienceinAustralia(Goodrumetal.,2001),forthereviewof
optionsforanationaltestforprimaryscience(Ball,Rae,&Tognolini,2000)
andfortheScienceEducationAssessmentResources(SEAR)project(ACER,
2004a)
• asawriterofbothstateandnationalsciencecurriculumdocuments(BOS,
2003;ACARA,2014c).
Myoutsiderperspectiveis“likethatofotherinterestedscienceeducators[who
access]projects’reportsoftheirfindingsandtotheiraftermathinfluence(insofar
asfindingsarepublished)onthepolicyandpracticeofscienceeducation”
(Fensham,2013,p.13).
18
IhavetitledthisfirstchapterOutlineofMyProjectandwrittenitinthefirstperson
toensurethatreadersrecognisewhatIbringtothisstudy.Subsequentchapters
arewritteninthepassivevoice.Thisunderpinsmywishtobeseenasan
independentresearcherwhohastakenappropriatesteps(seesection3.7in
ChapterThree)toconducttheresearchinthefullknowledgeofissuesrelatedto
participantresearchers/observersthatariseinthecontextofqualitativeresearch
ineducationandpsychology(seeDenzin&Lincoln,2011andHammersley,2008).
Mylastinvolvementwithteachersinthecontextofsupportingtheir
implementationofthesyllabus(BOS,2003)wasin2004andtheEVprogramwas
in2008.Datacollectionincasestudyschoolsforthisprojecttookplacein2016.I
hadpreviouslyworkedwithoneofthecasestudyteacherssome12yearspriorto
that.Hewasthenaparticipantataone-dayworkshopIwasrunningatthattime.
Hisschoolwasinvitedtoparticipateasacasestudyschoolin2016becauseitmet
thecriteriaforinclusionasanoutcomeofthephaseonequantitativemethodology.
1.7Structureofthisthesis
ChapterTwoexplorestheresearchandotherliteratureconsultedforthisthesis.It
providesthetheoryforconceptualisingfivedimensionsofformativepractice,that
comprisetheframeworkforinvestigatingtheimpactofassessmentforlearning
adviceandtheEVprogramonassessment-relatedworkofscienceteachers.
ChapterThreeexplainsthethree-phase,mixedmethodsdesignusedtoinvestigate
theimpactofthetwoinitiatives(theEVtestandexpectationsforgreateruseof
assessmentforlearning)onassessment-relatedworkofscienceteachersinthe
NSWgovernmentschoolsystem.Thefivedimensionsofformativepractice,which
istheframeworkagainstwhichimpactwillbeinvestigated,aredescribedthere.
ChapterFourreportsthefindingsfromthefirstandsecondphasesofthestudy.
ThefirstphaseusedanEVresultpredictortoidentifyschoolswhereEVresults
werewellabove,atandwellbelowexpectation(relativetothepredictor).
Teachersinthoseschoolswereinvitedtocompleteanonlinesurveyabouttheir
19
work.Thesecondphaseinvolvedtheanalysisofsurveyresponsestofindout
whetherbetterthanexpectedEVresultswereassociatedwithformativepractices.
ChapterFivereportsfindingsfromthethirdphaseoftheproject.Thethirdphase
involvedtesting(bothquantitativelyandqualitatively)thepropositionsthat
studentsatcomparableschools(schoolswiththesamesocioeducational
advantagescores)whohadmorefrequentexposuretoformativepractices,
comparedtostudentsatschoolsnotsoexposed,wouldhave
• betterYear8EVresults
• betterYear10results
• morestudents(asaproportionoftheYear12cohort)completesenior
sciencecourses.
ChapterSixsummarisesthestudy’sfindingsandprovidesqualifiedconfirmation
fortheclaimsmadeabouttheimportanceoftheresearch.Italsoprovidessome
suggestions,supportedbyfindingsinthisproject,forfutureresearchand
recommendationstorelevanteducationauthoritiesaboutchangestoenhancethe
ongoingeffectivenessofthetwointerventions.
20
CHAPTER2:LITERATUREREVIEW
2.1Introduction
Australiaisoneofthemostadvantagedandadvancedcountriesintheworld
(OECD,2018;UNDP,2018).ThereviewscommissionedbysuccessiveAustralian
andothergovernmentsaroundtheworld,researchandrelatedagencies(See
section2.2)havearguedthatthebestwaytoretainthisadvantageistodevelop
thecreativityandcognitiveskillsofitspeople,withaparticularemphasison
Science,Technology,EngineeringandMathematicsorSTEMasitisalsoknownas
(JFF,2007;DES,2003;OCS,2014)andtoaimforworld’sbestpracticeindoingso.
ThatAustralia’saspirationsareglobalisevidencedbyitsmembershipofand
activeparticipationinOECDprojectsrelatedtoassessment,forexample,
• ongoingparticipationinitsProgrammeforInternationalStudent
Assessment(PISA)sinceitsinceptionin2000(OECD,2014);
• casestudiesofclassroompracticeinQueenslandschoolswereincludedin
theirWhatWorksseriesofpublications,forexample,astudyonFormative
Assessment(CERI,2005,pp.191-204);and
• participationintheOECDReviewsofEvaluationandAssessmentinEducation
series(OECD,2011).
Section2.3reviewstheresearchliteratureonassessmentanddiscussestheidea
thatschoolsareenmeshedinacomplexwebwhichisappropriatelycalledan
assessmentsystem.
Section2.4discussesthepurposesofassessmentandhowtheoriesoflearningand
cognitionimpactwhatandhowweassess.
Section2.5examinestheconceptofassessmentasmeasurementandexploresthat
ideainrelationtosummativeandevaluativepurposesforassessment.
21
Section2.6looksatthenewemphasisbeinggiventoformativeassessmentandits
contextualisationinteachingknownasformativepracticeandwhythismaybethe
keytohelpingstudentsbecomelife-longlearners.
Section2.7describestheevolutionoftheSOLOmodelandpositionsitasageneric,
developmentallearningprogressionthatenhancesthefeedbackpotentialof
summativetestssuchastheEVtest.
Section2.8reviewsthemainideasdiscussedaboveandthathaveinformedthis
study.
2.2Acurriculum,teachingandassessmentforthetwenty-firstcentury
InApril2005,CarmelTebbutt,theMinisterforEducationinNewSouthWales
(NSW),Australia,announcedtotheNSWParliament:
Thereisnodoubtthatscienceandtechnologyareintegraltoourmodern
society[and]wemustdoallwecantoencouragestudentstotakeup
scienceandtocontinueitsstudyinyears11and12.TheGovernmentis
introducingforyear8anessentialsecondaryscienceassessmenttohelp
improvelearningoutcomesandgeneratestudentinterestinstudying
science(Tebbutt,2005,p.14956).
Thefirstsentencefromthisquoteisastrongstatementoftheneed,atleastinthe
eyesofthethenNSWgovernment,toensurethatmorestudentsengagewith
scienceuntiltheendoftheirseniorsecondaryschooling.Thebasisforthisclaim
willbeoutlinedlaterinthissection.ThesecondsentenceisareferencetotheEV
programdescribedinChapterOne.Aswillbeexplainedlaterinthischapter,
imposingatestisatoolusedbygovernmentstosignaltothecommunitythe
importanceplacedbygovernmentonaspectsofthecurriculum,inthiscase
science(alongwithliteracyandnumeracyaswillalsobeexplainedbelow).
InherspeechannouncingtheintroductionoftheEVprogram,ministerCarmel
Tebbutt,explicitlyreferredtoareportfromareviewintoinnovation,science,
technologyandmathematicsteachingandteachereducationinAustralia(CRTTE,
22
2003),alsoknownastheDowReport.Thatreviewwasacontributiontothethen
nationalgovernment’sbroaderagendato
promoteresearch,developmentandinnovation[becausetheAustralian
economywastransitioningfromonebasedon]land,labourandcapitalto
onebasedonhumanandintellectualcapacity.(Australia,2001,p.4).
Thisemergingneweconomywasreferredtoastheknowledgeeconomyinmany
ofthereportspreparedforgovernmentsinAustraliasuchastheDowreport
referredtoabove(CRTTE,2003)andaroundthedevelopedworldatthattime
(OECD,1996).Allwereanxioustoensurethatallcontinuedtoprosperintothe
future.
Inonesuchreport,thethenchiefscientistforAustralia,RobinBatterham,wrote:
“Science,engineeringandtechnologyunderpinsourfutureasathriving,cultured
andresponsiblecommunity”(Batterham,2000,p.9).Hisreportidentifiedthat
moreinvestmentmustbemadeinpeopleandculture,ideasandcommercialisation
ifAustraliawastokeepupwiththerestofthedevelopedworld.His
recommendationsfordoingsowerebasedonhisanalysisof“initiativesand
consequentialstructuralchangesunderway…inOECDandAsiancountries”(p.41),
includingtheUnitedStates,theUnitedKingdom,Canada,Japan,Finland,Ireland,
SingaporeandThePeople’sRepublicofChina.
Batterham’sproposedstrategiesandrecommendationsforkeepingupwiththe
changesgoingonintheworldeconomywereaimedatensuringthatagrowing
numberofstudentswerepreparedforscience,engineeringandtechnology(SET)
relatedwork.Amongthestrategiesheidentifiedwere:makinglifelonglearninga
keystrategyforeducationprovidersandemployees,inspiringstudentstostudy
SET-basedsubjects,rewardingexcellentSETteachers,providingspecialist
intensivetrainingforteachers,andprovidingopportunitiesforSETgraduates
alreadyintheworkforcetoentertheteachingsystem.Theneedformorestudents
inAustraliatoengagewithSTEMinthelateryearsofschoolandbeyondwas
affirmedintheDowreport(CRTTE,2003)referredtoaboveand,infact,mostof
23
thestrategiesandrelatedrecommendationsfromBatterham’sreportwere
repeatedandendorsedintheDowreport(CRTTE,2003).
ThenationalAustralianEducationCouncilwaspursuinganagendatobroadenthe
school’scurriculumtobetterequipthegrowingnumberofstudentscompletingsix
yearsofsecondaryschoolingwithskillsthatbetterpreparethemforworkaswell
assuccessintertiarystudies.TheMattersandCurtis(2008)reporttothe
AustralianGovernmentDepartmentofEducation,EmploymentandWorkplace
Relations(DEEWR)describedhowfivecompetencesfirstproposedbytheKarmel
review(QERC,1985)endedupas“KeyCompetencies”(AECRC,1992)whichwere
thenhandedovertostateandterritoryeducationsystems.AsummaryofthisKey
CompetencyworkisincludedinAppendixA.
TherewasatrialofthekeycompetenciesinNSWschools,TAFEinstitutesand
workplaces,whichweredefinedas“theintegratedapplicationofknowledge,skills
andunderstandings”(Ryan,1997,p.5).Thetrialinginschoolswasfoundtobe
“broadlysupportedbypractitionersinvolvedinthefieldtesting[…buttherewas]
littlesupportforaseparateadditionallayerofassessmentandreportingthat
focusesonkeycompetencies”.(Ryan,1997,p.7)Aswillbeapparentfroma
readingofthefourthsectionoftheTableinAppendixA,thekeycompetencies
werelaterwrittenintotheNSWsciencesyllabus(BOS,2003)whichcontainedthe
curriculumofinterestforthisproject.Thereafter,theextentofKeyCompetency
acquisitionwasassessedbyteachersinthecontextofcontentandskillsrelatedto
theseparatelearningareasyllabuses,includingscience.
Ofnotetoowasthesyllabusexpectationthatafterfouryearsofscienceteachingin
NSW,studentswouldemergeasindependentlearnerswhowere“creative,
responsible,scientificallyliterate,confident,[and]readytotaketheirplaceasa
memberofsociety.”(BOS,2003,p.10)Thisaspirationwasmentionedinthe
AdelaideDeclaration(seeAppendixB)aswellasinBatterham’s(2000)report.
Thepushfromemployersandgovernmenttobroadenthecurriculum’spurpose
frompreparationfortertiarystudy(Connell,1985)topreparationforlifeinthe
twenty-firstcenturywasexpressedinthreeagreementsbetweenthenational,
24
stateandterritoryeducationministersaboutnationalgoalsforeducationwhich
weresubsequentlyendorsedbygovernments.ThefirstofthesewastheHobart
Declaration(MCEETYA,1998)withtenCommonandAgreedNationalGoalsfor
Schoolingreleasedin1989.Thegoalsweresubsequentlyrevisedandendorsedin
theAdelaideDeclaration(MCEETYA,1998)whichwasreleasedin1998.Following
areviewsometenyearslaterafurtheriterationwaspublishedintheMelbourne
Declaration(MCEETYA,2008).EachDeclarationwasaccompaniedbyanaction
plan.ACARAwascreatedasaconsequenceofgovernmentcommitmentstothe
actionplanattachedtotheMelbourneDeclaration.Thethreesetsofgoalsare
includedasAppendixB.
Theaboveoutlinestheinfluencesbeingbroughttobearonthecurriculumfor
schooling,includingthesciencecurriculum.TheDowreport(CRTTE,2003)also
includedreferencetoarecentlycompletedcomprehensivereviewintoscience
teachinginAustralianschoolstitledTheStatusandQualityofTeachingand
LearningofScienceinAustralianSchools(Goodrumetal.,2001).
Goodrumetal.(2001)includedatableadaptedfromtheUSANationalScience
EducationStandards(NRC,1996).Thetablesummarisedtraditionalscience
teachingpracticesfoundaroundtheworldandinAustralia(lefthandcolumn)
withpracticessupportedbytheresearchliteratureasbeingmoreeffective(right
handcolumn).ThetablefromthereviewispublishedhereasTable2.1.Themore
effectiveapproachesaresummarizedintheright-handcolumn.Threeofthelast
fourpointsintherighthandcolumnareitalicizedandboldedbythethesiswriter
tohighlightspecificreferencestoassessmentandhowitneedstochangewhen
comparedtomodalpractices(seecorrespondingpointsintheleft-handcolumn)at
thattime.
25
Table 2.1 Summary of needed changes to teaching and assessment Teaching for scientific literacy requires:
Less emphasis on: More emphasis on:
memorising the name and definitions of scientific terms covering many science topics theoretical, abstract topics
presenting science by talk, text and demonstration asking for recitation of acquired knowledge
individuals completing routine assignments
activities that demonstrate and verify science content providing answers to teacher’s questions about content science being interesting for only some students assessing what is easily measured
assessing recall of scientific terms and facts
end-of-topic multiple choice tests for grading and reporting
learning science mainly from textbooks provided to students
learning broader concepts that can be applied in new situations studying a few fundamental concepts content that is meaningful to the student’s experience and interest guiding students in active and extended student inquiry providing opportunities for scientific discussion among students groups working cooperatively to investigate problems or issues open-ended activities that investigate relevant science questions communicating the findings of student investigations science being interesting for all students
assessing learning outcomes that are most valued assessing understanding and its application to new situations, and skills of investigation, data analysis and communication ongoing assessment of work and the provision of feedback that assists learning learning science actively by seeking understanding from multiple sources of information, including books, Internet, media reports, discussion, and hands-on investigations
Source: Figure 7.1 in Goodrum et al.,2001, p. 168.
26
IntheAustraliancontext,Goodrumetal.(2001)hadidentifiedthat
mostsecondaryscienceteachersareconcernedaboutthefinalassessments
forstudentswhichdetermineaccesstotertiaryeducationandtheyregard
coveringthecontentlikelytobeassessedasofparamountimportance,the
repercussionsofwhichechorightdowntotheearlyyearsofhighschool(p.
145).
Thereviewerswereconcernedaboutthatfocuson“finalassessments”andtheir
recommendationsforchangeidentifiedassessmentasanareaforreform.Threeof
thelastfourpointsintheright-handcolumnareaboutassessment.Thethirdone
receivedspecialmentionintheirrecommendations.
Recommendation7:ItisrecommendedthattheCommonwealthassist
educationaljurisdictionstoreformassessmentpracticesothatassessment
moreeffectivelyservesthepurposeofimprovinglearning.Assessment
mustfocusonthelearningoutcomesassociatedwithscientificliteracy.
(Goodrumetal.,2001,p.xiii)
Subsequently,twoofthereviewreportauthorswerecommissionedtopreparea
five-yearactionplan(2008to2012)tomanagethecontinuingimplementationof
recommendationsfromthatinitialreport.(Goodrum&Rennie,2007)Assessment
wasoneofeightareasforaction.Theoverridingobjectiveofassessmentreform,
theywrote,wasto“improvethequalityofstudentassessmentbyensuringthatit
wasalignedwithintendedlearningoutcomes.”(p.15).
Twopriorityactionstoachievethisobjectiveweredescribedintheirreport.The
firstwasfor“effective[useof]diagnostic,formativeandsummativeassessment
approaches”(p.16)tobeembeddedincurriculumresourcesdevelopedtosupport
scienceteaching.Thesecondwasto“monitorperformanceinscienceatthe
nationallevel”(p.16).Goodrumetal.(2001)recommendedthatthelatterbedone
bynationalsampletestingofstudents.
27
Inresponsetothefirstproposedaction,twomajorAustraliancurriculumsupport
initiativessubsequentlymodelledtheuseofassessmentfordiagnostic,formative
andsummativepurposesasrecommended.ThesewerePrimaryConnections(AAS,
2016),whichprovidescomprehensivesupportmaterialsforscienceteachingin
theK-6years,andSciencebyDoing(AAS,2017),whichprovidessimilarsupport
forjuniorsecondaryscienceteaching.
Theproposalfornationalmonitoringofscienceperformancewas,ineffect,an
endorsementofcurrentprogramsusingexistingsampletestingprograms,onean
Australianinitiativeandtheothertwowereinternationalinorigin.These
programstestsamplesofNSWstudentsinYears4,6,8,9and10(fifteen-year-
olds)andwillbedescribedfurtherinthischapter.
(Broadfoot,2009)observesthataroundtheworldexternallyset,test-based
assessmentsarebeingused
ubiquitouslytoprovideforselection,forcertification,foraccountabilityand
forinternationalcomparisonsofeducationalstandards.Theadventofthe
21stcenturyalsoheraldedtheearlystagesofamovementtopromotethe
useofassessmentasatooltosupportlearningitself.(p.vii)
TheNSWsyllabusbeingusedatthetimeofthisprojectwithitsemphasison
assessmentforlearningwasanexampleofthelater,aswastheintroductionofthe
EVprogramandtheQualityTeachinginNSWpublicschools(QT)initiative.TheQT
initiativewasaprofessionallearninginitiativeoftheDepartmenttosupportand
improveteachingandassessmentingovernmentschools.TheQTinitiativewasa
professionaldevelopmentprogramwidelysupportedinNSWschoolsinthefirst
decadeafter2000.Thesyllabusmessageaboutassessmentforlearningwas
reinforcedintheDepartment’sQTinitiative.
Assessmentistheprocessofidentifying,gatheringandinterpreting
informationaboutstudents’learning.Thecentralpurposeofassessmentis
toprovideinformationonstudentachievementandprogressandtosetthe
directionforongoingteachingandlearning.(DET,2006,p.5)
28
InadditiontoNSWresourcessupportingassessmentforlearning,threenational
projectshadadditionalresourcesonlineforscienceteachersby2005,including:
• materialaboutassessmentforlearning(CC,n.d.);
• arangeofdiagnosticassessmentitemsandtasksforscience(ACER,2004a);
and
• onlinelearningobjectsspecificallytargetingsciencelearningthatcouldbe
usedbyteachersandstudentsfordiagnosticpurposesaswellastosupport
sciencelearningmoregenerally.
Elementsofthesethreeprogramsareevidentinteachingandlearningsupport
resourcescurrentlyavailabletoschoolsonEducationServicesAustraliamanaged
websites(ESA,n.d.),includingImproveandScootle(ESA,2012).
By2010,scienceteachersinNSWshouldhavebeenveryawareofexpectationsfor
theiruseofassessmentforlearningstrategiesandresources,includingtheuseof
assessmentdatafromtheEVprogram.AsexplainedinChapterOne,NSWhas
chosentoretainandexpanditsEVtestfromYear8toincludebothYear6andYear
10,thoughfornowthelattertwotestsarenotmandatory.(DET,2015)While
thereisconsiderableevidencethatsummativetestscontributetodisengagement
withlearning(Darling-Hammond,2003;Harlen&Deakin-Crick,2002;Osborne&
Dillon,2008;Stiggins,2007;Tytler,2007),thisthesisusesthecontextoftheEV
programtoprovideimportantinsightsintohowlarge-scale,summative,externally
designedtestsarebeingusedtoimprovebothachievementinandengagement
withlearning.
2.3Assessmentandassessmentsystems
Somedefinitionsofassessmentandassessmentsystemsareprovidedtointroduce
thissection.Thesewillbefollowedbyadiscussionoftheliteraturerelatingto
threecommonpurposesforschoolassessment.Theimpactofcurrent
understandingsaboutlearningandcognitiononassessmentandtheneedto
ensurethatwhatisdoneinthenameofassessmentisfitforpurposecompletethe
section.
29
Thefollowingfivedefinitionsofassessmentarefoundintheliterature.
Thefirstis:
Thetermseducationalmeasurement,assessment,andtestingareused
almostinterchangeablyintheresearchliteraturetorefertoaprocessby
whicheducatorsusestudents’responsestospeciallycreatedornaturally
occurringstimulitodrawinferencesaboutthestudents’knowledgeand
skills.(PophamcitedinNRC,2001,p.20,italicsinoriginal)
Thesecondis:
[Assessmentis]theprocessofgatheringandinterpretinginformationabout
theprogressofstudents’learning.(Hackling,2004,p.127)
Thethirdis:
Assessmentisatermthatcoversanyactivityinwhichevidenceoflearning
iscollectedinaplannedandsystematicwayandisusedtomakea
judgmentaboutlearning.(Harlen&Deakin-Crick,2002,p.1)
Thefourthissciencespecific:
[Assessmentis]thecollectionandinterpretationofinformationabout
learners’knowledge,understandings,skillsandattitudesrelatingtothe
scienceoutcomes.(Goodrumetal.,2001,p.20)
Thefifthhasalternativenamesforassessment,dependingonwhatisbeing
assessed:
[Assessmentsare]judgementsonindividualprogressandachievementof
learninggoals[from]classroom-basedassessments,aswellaslargescale,
externalassessmentsandexaminations…appraisalreferstojudgements
ontheperformanceofschool-levelprofessionals,e.g.teachers,school
leaders…evaluationreferstojudgementsontheeffectivenessofschools,
30
schoolsystems,policiesandprogrammes.(Nusche,Radinger,Santiago,&
Shewbridge,2013,p.59)
Thelastdefinitionrelatestothesystemofassessmentsthatschoolsareexpected
toparticipatein.Theassessmentsinvolvecollectingevidenceoflearningand
evidenceofperformancethatgoeswellbeyondwritingresponsestopenand
papertestitems.
Participantsinanydiscussionaboutassessmentneedtounderstandmorethanthe
literalinterpretationsofthewords“evidenceoflearning”.Twoexamplesillustrate
this:ThefirstistheNSWDepartmentofEducationandTraining’sQualityTeaching
(QT)initiative(DET,2003)mentionedabove.Itsuggestsfourquestions.
1. Whatdoyouwantthestudentstolearn?
2. Whydoesthatlearningmatter?
3. Whatareyougoingtogetthestudentstodo(ortoproduce)?
4. Howwelldoyouexpectthemtodoit?(DET,2006,p.10)
Amoresophisticatedversionofthecontextforassessmentisprovidedina
NationalResearchCouncil(NRC,2001)report.TheNRCmanagessevenprograms
fortheUSAcademiesofScienceandEngineering,includingtheirBehaviouraland
SocialSciencesandEducationprograms.Itdrawsonexpertisefromwithinand
outsidetheacademiesasneeded.FortheNRC
Assessmentisalwaysaprocessofreasoningfromevidence…[and]is
imprecisetosomedegree[andassessments]areonlyestimatesofwhata
studentknowsandcando.(p.2)
Everyassessmentinvolvesthreefoundationalelements(whichthewriterscallthe
verticesofanassessmenttriangle):
amodelofhowstudentsrepresentknowledgeanddevelopcompetenceinthe
subjectdomain[cognition];tasksorsituationsthatallowonetoobserve
student’sperformance[observation]andaninterpretationmethodfor
drawinginferencesfromtheperformanceevidencethusobtained
31
[interpretation]…Thesethreeelements—cognition,observation,and
interpretation—mustbeexplicitlyconnectedanddesignedasacoordinated
whole.(p.2,italicsintheoriginal)
AfundamentalpremiseoftheNRC(2001)reportis:
Mostwidelyusedassessmentsofacademicachievementarebasedon
highlyrestrictivebeliefsaboutlearningandcompetencenotfullyinkeeping
withcurrentknowledgeabouthumancognitionandlearning.Likewise,the
observationandinterpretationelementsunderlyingmostcurrent
assessmentswerecreatedtofitpriorconceptionsoflearningandneed
enhancementtosupportthekindsofinferencespeoplenowwanttodraw
aboutstudentachievement.(pp.2-3)
TheNRC(2001)reportmakesthisobservationaboutassessmenttoo.
Muchgreatervalueandcredibility[isattributed]toexternalassessmentsof
individualsandprogramsthantoclassroomassessmentdesignedtoassist
learning…Moreoftheresearch,development,andtraininginvestmentmust
beshiftedtowardtheclassroom,whereteachingandlearningoccur.(p.9,
italicsintheoriginal).
ThislastsentimentwasechoedintheGoodrumetal.(2001)reviewand
recommendationsmentionedintheprevioussection.
Sincethebeginningofthe1990s,studentsinAustraliahavebeenaskedtosittests
imposedbyeducationauthoritiesoutsidetheimmediateschoolbeforetheirfinal
yearofschooling.InYears7and9allstudentssitliteracyandnumeracytestsonce
satbystateandterritoryeducationauthorities.ACARAinthecontextofits
NationalAssessmentPlanLiteracyandNumeracy(NAPLAN)programhastaken
overmanagementofthetestssince2008.Year8studentsinNSWgovernment
schoolsatleastsitEVtestsforscience.Inmanyschools,sciencedepartmentbuy
testsdevelopedbyprivatetestingcompanies(suchasICASsciencetestsproduced
byEducationAssessmentAustralia(EAA).(EAA,2018)TheseICAStestsprovide
32
independentfeedbackonthelevelofscienceprocessskillsstudentspossessatthe
timetheysitthetest.TheAustralianCouncilforEducationalResearch(ACER)also
providescomparabletestsforsciencethatschoolscanpurchasetosupporttheir
teachingandlearningprograms(Masters,2009).
Itisalsopossible,butlesslikely,thatstudentscouldbeaskedtosittestsproduced
bytwointernationalagenciesinreadingliteracy,numeracyandscientificliteracy.
ThefirstorganisationtobringtheseteststoAustralia(in1995)wasthe
InternationalAssociationfortheEvaluationofEducationalAchievement(IEA)
(IEA,2013).Theseprovidetestingandreportinginreadingliteracy(PIRLS)overa
pentennialcycleandinmathematicsandscience(TIMSS)inaquadrennialcycle.
TheTIMSStestsarecurrentlysatbyYear4andYear8students;onlyYear4
studentssitPIRLStests.
ThesecondprogramistheOECD’sProgrammeforInternationalAssessmentof
Students(PISA),whichprovidestestsinliteracy,numeracyandscientificliteracy
overatriennialcyclefor15-year-oldstudents(OECD,2014).Australiahas
participatedinPISAsinceitbeganin2000.TheACERmanagesthetestprocesses
inAustraliafortheIEAandOECDanditwritesthereportsforAustraliafromtheir
analysisoftheresultsandrelatedsurveys(Thomson,DeBortoli,&Underwood,
2017;Thomson,Wernert,O'Grady,&Rodrigues,2017).
Figure2.1isarepresentationthatNuscheetal.(2013)usedtoexamineandreport
againstintheirexplorationoftheassessmentsystemsofparticipatingOECD
members,includingAustralia.Thefigureshowsthecomplexityoftheassessment
systemschoolsarenowenmeshedin.
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Inrelationtothatsystem,theNRC(2001)reportsays:
Aspectsoflearningthatareassessedandemphasizedintheclassroom
shouldideallybeconsistentwith(thoughnotnecessarilythesameas)the
aspectsoflearningtargetedbylarge-scaleassessments.(NRC,2001,p.3).
Thisisacallforverticalalignmentofassessmentintent.Theclaimhereisthat
classroomassessmentsandexternallyimposedtestsshouldallbedefensiblein
termsofthenationalorstateorterritorygoalsthetestsaresupposedtobe
providingevidenceoflearningabout.
TheNRC(2001)reportalsoasserts:“Educationalassessmentdoesnotexistin
isolationbutmustbealignedwithcurriculumandinstructionifitistosupport
learning”(p.3,italicsintheoriginal).Thisisacallforthehorizontalalignmentof
assessmentpractices,learningexpectations(asdescribedinthecurriculum)and
instruction.OthersexpressingasimilarviewincludeBiggs(1999),Mansell,James
&theARG(2009)andMasters(2013).Alignmentmeansthatwhatisintendedto
belearnt(curriculum)andhowitisacquired(instruction)anddemonstratedas
beingacquired(assessment)areconnectedbyacoherentandconsistentviewof
learningandcognition.TheTrendsinMathematicsandScienceStudy(TIMSS)
assessmentmodelcollectsdatabasedonthepremiseofhorizontalalignment.
(Mullis,Martin,Ruddock,O'Sullivan,&Preuschoff,2009)
ItisthesealignmentsthattheNRC(2001)saysareoftenmissingintherealworld
ofpractice.ThereportbytheCounciloftheGreatCitySchoolsintheUSprovides
examplesoftheconsequenceswhenthosealignmentsareweakormissing(CGCS,
2015).TheCGCS(2015)reportfindingsarelistedundersixheadings:assessments
requiredofallstudentsinagivengrade;sampleandoptionalassessments;
assessmentsforspecialpopulations;lookingattestinginadistrictcontext;costsof
testinginasampledistrict;andparents.Asummaryof23separatepointsincludes
thefollowing:mandated,externaltestingofGrade8studentstookupatleast
2.34%oftheschoolyear;therewasnocorrelationbetweentheamountof
mandatedtestingtimeandthereadingandmathscoresingradesfourandeighton
theNationalAssessmentofEducationalProgress(NAEP)testprogram;sometests
35
arenotwellalignedtoeachotherorcollegeorcareerreadingstandardsandoften
donotassessstudentmasteryofanyspecificcontent;and,parentssupport
replacingcurrenttestswith“better”tests.Despitetheseissues,82%oftheschool
parentspolledexpressedsupportorstrongsupportfor“[having]anaccurate
measureofwhatmychildknows”(pp.9-11).
Broadfoot(2009)describesafour-dimensionalcharacterisationofassessment
systemsforanalysingthelinksbetweentheassessmentsystemandthesocial
contextinwhichitisembedded.Thecomponentsarepurposes;mode(meansused
togatherevidenceoflearning);content(whatisbeingassessed);andorganisation
(howassessmentsareconducted).Shearguesthattheprevailingsocialcontextin
Westernsocietiesattheendofthe20thcenturywasdominatedbyenlightenment
andmodernistsentimentstodowith“individualrightsandresponsibility,
rationalityandscientificprogress”(p.vi).Therewasalsoenormousinvestment
madeduringthe20thcenturyinto“thepursuitofmaximumaccuracyin
educationalmeasurement”(p.vii).
Broadfootseesmeasurementasthepurposeofassessmentinthissocialcontext.
Thehigherthescorethemoresocialmeritwasbestowedonthatperson,who
then,presumably,couldgoontobeanythingtheywantedtobeinlife(scientist,
doctor,lawyer,pilotandanyotherhighsocialstatusjobtheydesired).Thecontent
tobeassessedwasthecurriculumcontentthatcouldbemeasured.Thedominant
modeofassessmentwasby‘paperandpencil’testing.Theevidenceoflearningit
deliveredrangedfromaletterrepresentingthebestresponse(fromseveral
optionsprovided)towritingafewwordsortheresultofacalculation,oran
extendedresponseinvolving(one,some,orallof)calculations,annotatedgraphic
representations(flowcharts,diagrams,tablesandgraphs)andtexttypes
characterisingdescription,explanation,justificationoracreativesynthesis.TIMSS,
PISAandNAPLANtestsuseamixofshortresponseitemsandextendedresponse
tasks;thebalancebeinginfavourofshortresponseitems(typicallybetween60-
80%).Correctresponseswerecountedandsummed.Inthiscontextthebiggerthe
numberthebettertheresult.
36
Thetypicalorganisationforexternal,standardisedtestsassumesresponseswillbe
fromindividualsandprovidedwithinastrictlyimposedtimelimit,andthatthe
testandanswerbookletswouldbeproduced,printed,delivered,collected,collated
andcodedinprocessesmanagedbytheagencyresponsibleforthetest(ortheir
delegate).Large-scaletestscores(rawscores)onceobtainedwouldoftenbe
standardisedinavarietyofwaysusingstatisticalprocedurestoensureafairbasis
forcomparability.
Manyteachersandothersinthecommunitybeyondschoolsbelievethatthismode
ofassessmentprovidesanobjective,unbiasedandthusfairassessmentof
individualperformanceatthetimethetestistaken.Supportforthisgeneralisation
hasbeenexpressedininternationalandlocal(AustralianandNSW)reportsand
researchpapersreviewinglarge-scaleassessmentprograms,suchasthose
mentionedaboveandtherecentlyabandonedYear10testsinNSW.Examples
includeCooney(2006),Smith(2005)andWasson(2009)inrespectoftheNSW
literacyandnumeracytests;BOS(2011)forthenowabandonedYear10testsin
NSW;andThomson,Wernert,etal.(2017)andThomson,DeBortoli,etal.(2017)
forthelatestTIMSSandPISAreportsrespectively.IntheUS,theNRC(2001)
supportstheNAEP(2011)testmodel.
Broadfoot(2009)goesontoidentifyachangedevelopinginhowtheeducation
communityviewsassessmentthatsheassociatedwithpost-modernism.
[This]movementseesassessmentasatooltosupportlearning…
involvementofhumanbeingsineveryaspectofitsdesign,executionand
usemakes[testing]irrevocablyasocialprojectandthussubjecttoallthe
vagariesthatanykindofhumanactivityimplies…assessmentinthe21st
centuryshowssignsofagrowingpreoccupationwith‘fitnessforpurpose’
andimpactonlearning.(p.vii)
Thisemergingviewsupportsthemoveawayfromseeingassessmentasa
summativeprogramtoaformativeone(asevidencedintheNSWSciencesyllabus
ofinteresthere).TheEVprogramisanattemptedshiftinthatdirection.Itusesa
summativetesttoprovidefeedbackonlearningwiththeexpectationthattest
37
resultsbeusedformativelybyteacherstoimprovesciencelearningand
engagement.HowthishasworkedoutinpracticeinNSWisreportedoninthe
concludingchapterofthisthesis.
TheOECD’s(2011)reportandrecommendationsontheAustralianevaluationand
assessmentsystemmentionedatthebeginningofthischapterwasbasedon
Australia’ssubmissiontotheOECDreviewprocessandtheobservationsofan
independentOECDpanelthatvisitedAustraliainJune2010.Thepanelconcluded:
Theoverallevaluationandassessmentframework[inAustralia]appearsas
highlysophisticatedandwellconceptualised,especiallyatitstoplevel
(nationalandsystemiclevels).However,thereisalesscleararticulationof
waysforthenationalagendatogenerateimprovementsinclassroom
practicethroughtheassessmentandevaluationprocedureswhichare
closertotheplaceoflearning.(OECD,2011,p.9)
Ofinterestthough,istheinclusionoftwoAustraliancasestudiesofformative
assessmentinoneoftheOECD’sWhatWorkspublicationsonformative
assessment(CERI,2005).Theselocalexamplesofgoodclassroomassessmentand
schoolsupportforassessmentaremodelsthatcouldbeappliedmorewidelyin
Australiatoaddressthepanel’sconclusions.
2.4Thepurposesforassessment
Thelocusofinterestforthisstudyisteachers’assessment-relatedwork.The
followingdiscussionaboutpurposesforassessmentwillfocusonclassroomand
schoolassessment-relatedwork.
TheNRC(2001)reportpositsthreepurposesforassessment:
1. toassistlearning
2. tomeasureindividualachievement
3. toevaluateprograms.(p.3)
38
TheNRC(2001)saysthatthesethreepurposesholdforclassroomandlarge-scale
testsaswell.
IntheUK,TheEconomicandSocialResearchCouncil’s(ESRC)report,Assessment
inSchools.Fitforpurpose?ACommentarybytheTeachingandLearningResearch
Programme(Manselletal.,2009),identifiedthesamethreeuses(orpurposes)for
assessment:
1. tohelpbuildpupils’understanding,withinday-to-daylessons
2. toprovideinformationonpupils’achievementstothoseontheoutsideof
thepupil-teacherrelationship:toparents(onthebasisofin-class
judgmentsbyteachers,andtestandexaminationresults)andtofurtherand
highereducationinstitutionsandemployers(throughtestandexamination
results)
3. toholdindividualsandinstitutionstoaccount,includingthroughthe
publicationofresultswhichencourageoutsiderstomakeajudgmentonthe
qualityofthosebeingheldtoaccount.(p.8)
Thefirstpurposeinbothreportsisalsoreferredtointheliteratureas:
• classroomassessment(Black&Wiliam,1998b;Brookhart,2003;Cowie,
2005,2013;Marzano,2000;Ruiz-Primo&Li,2012;Shepard,2001;Stiggins,
2004)
• formativeassessment(Bell&Cowie,2002;Black&Wiliam,2009;Heritage,
2010;Panizzon,Callingham,Wright,&Pegg,2007;Sadler,1998;Stiggins&
DuFour,2009)
• assessmentforlearning(ARG,2002a;Biggs&Collis,1982;Hargreaves,
2005;Stiggins,2002;Wiliam,2011b)
• embeddedassessment(mainlyintheUS)(Wiliam,2011a;Wilson&Sloane,
2000).
Thesecondpurposeinbothreportsisoftenreferredtoassummativeassessment
(Biggs,1998;Harlen&Deakin-Crick,2002;Harlen,2005)orassessmentof
learning(ARG,2006;Hackling,2004).Historically,summativeassessmentattracts
39
considerableindividualand/orpublicattentionwhenresultsthathavereal
consequencesforthosereceivingthemarepublicised,delivered,usedorrecorded
forlateruse.Forthatreason,summativeassessmentisalsocalledhigh-stakes
assessment(Au,2007;Broadfoot&Black,2004;Dulfer,Polesel,&Rice,2012;
Gipps,1999;Klenowski&Wyatt-Smith,2012;Lim,TanEngThye,&KangLu-Ming,
2009).ThelastcitationrelatestoSingapore’seducationsystemrequirements.
Thethirdpurposerelatestoaccountability.Oftentheresultsofsummative
assessmentsarethebasisformonitoringtheperformanceofaschoolorschool
system.Theissuesrelatedtohigh-stakesassessmentarediscussedbyresearchers
listedforsummativeassessmentalsoapplyinthiscontext.
2.4.1Threepurposesforassessment?
Inaneditorialreviewingthefirst10yearsoftheUKjournalAssessmentin
Education:Principles,Policy&Practice,BroadfootandBlack(2004)asserted:
Educationalassessmentmustbeunderstoodasasocialpractice,anartasmuchas
ascience,ahumanisticprojectwithallthechallengesthisimpliesandwithallthe
potentialscopeforbothgoodandillinthebusinessofeducation.(p.8)
Theeditorsgoontoidentifyfromthepaperspublishedinthoseyearsa“subsetof
subtlepurposes,whichservetounderlinethepervasive[social]powerof
assessmenttodefineandshapeeveryaspectofeducationallife”(pp.11-12),
including:
• asamechanismforcontrollingclassbehaviourandattention(thethreatof
poorresults!)
• todescribeachievementstandardsintermsofqualitativechangesinthe
responsecapabilitiesofstudentsovertime.Thiswasareferencetowork
doneinAustraliainthefirsthalfofthe1990stodevelopsubject‘Profiles’
foranationalcurriculum(Rowe&Hill,1996)
• theuseofassessmenttoencourage‘deep’ratherthan‘surface’learning
40
• encouragingownership(bybothteachersandstudents)ofassessmentas
aninfluenceontheircapacityandmotivationtolearn
• thegrowingusebypolicymakersofthesocialpowerofassessmentin
attemptstoraiseachievementlevels,changethefocusofcurriculum
priorities,inperformancemanagementforteachers,institutionalquality
assuranceandcontroland,defining‘standards’throughthepublicationof
leaguetables.
MattersandCurtis(2008)refertoattemptsbypolicymakerstochangethefocus
ofcurriculumprioritiesas“signalling”(p.17).Thewritersusetheterminthe
contextofgovernmenteffortstohavekeycompetenciesembeddedinschoollevel
curriculumdocumentsassessedbyteachers.Themessagefromgovernmentwas
thatthiscontentwasofequalvaluetotheothercontentin,say,theNSWscience
syllabus.InitsimposingoftheEVprogramonschools,theNSWgovernmentwas
signallingtostudents,teachersandthewidercommunityitsviewoftherelative
importanceofscienceinthecurriculum(seethequotationopeningSection2.2).
ThesamecouldbesaidofthedecisiontointroducesampletestingofYear6
studentsinscienceliteracyeverythreeyears(Ball,Rae,&Tognolini,2000)andthe
decisiontoparticipateininternationaltestingofscience.
Thesecond,thirdandfourthpurposesarelinkedtoformativeassessmentandwill
beexploredinSection2.6.Thefifthclusterofpurposesidentifiedhererelates
easilytothethirdpurposeofassessmentidentifiedbyboththeNRC(2001)report
andManselletal.(2009)commentary.
Itisevidentthatdiscussionsaboutassessmentandmeaningsofrelatedtermscan
beasourceofconfusion.Newton(2007)isaUK-basedexpertandresearcherwith
wideexperienceinassessment.Basedonhisexperienceofdiscourseabout
assessmentpurposes,hereportsthatthephrase‘assessmentpurposes’maybe
interpretedinatleastthreeways.Thefirstisareferencetothetechnicalaimofthe
assessment,whichistomakea“judgment”(p.150)thatistypicallyreferredtoas
theresult(thishecallsthefirstorjudgmentlevel).“Judgment”andtheNRC’s
(2001)“interpretation”inthecontextofthe“assessmenttriangle”(NRC,2001,pp.
41
2-3)areequivalent,butitisworthobservingthattheword“judgment”hasmoral
overtones.“Interpretation”isaneutral,objective,technicalword.Theword
judgmentisperhapsanintended,ifimplicit,reminderofthesocialpowervestedin
assessment.(Broadfoot&Black,2004)
Newton(2007)analysedhistoricalpublicationsaboutassessmenttoexplainhow
firstleveljudgmentsmightbebetterexpressedtoclarifythevariousforms
assessmentmighttake.Todothisheresortedtotechnicaldescriptionsofthe
variousjudgmentsaprofessionalworkingintheassessmentareamightuse.He
distinguishedbetweenquantitative,summativejudgmentsinvolvingappraisal,
andqualitative,descriptivejudgmentsinvolvinganalysisatthetwoendsofa
judgmentdipole.Theformermightbeeitherself-referencedornorm-referenced
judgments.Thelattermaybeeitherconcept-referencedjudgmentsor
performance-referenced.
Thesecondwayisabouttheusetowhichtheassessmentresultisput(the
decisionlevel).Newton(2010)producedalistof22“categoriesofusesfor
assessments”,includingsocialevaluation,formativeassessment,diagnosis,
screening,segregating,guidance,programevaluation,andinstitutionalmonitoring.
TheManselletal.(2009)commentaryreferencetousesforassessmentrather
thanpurposesacknowledgedNewton’sworkinthisarea.
Thesamesetoftestresultsaresometimesusedformultiplepurposes,often
inappropriately(James,2009;Newton,2007).TheNRC(2001)reportmakesthe
sameobservation.ComparethiswithJames’s(2009)observationthat“twenty
yearsago…testandexaminationresultswerepredominantlymeanttoserveas
indicatorsofwhatapupilknewandunderstoodaboutasubject”(p.8).Multiple
usesforthesamesetofresultswereacknowledgedinevidencetoaUKHouseof
CommonsSelectCommittee(SCCS&F,2008)alongwithanacknowledgmentthe
sametestwasnotalwaysthemostappropriateforallpurposes.
Newton’s(2007)thirdwayofinterpreting‘assessmentpurposes’relatestothe
intendedimpactoftesting,whichistosignaltheimportanceofthelearning(so
importantthatitwillbetested!).Newton(2007)alsorecognisesunintended,
42
negativeimpactsforbothsecond-andthird-levelusesandintentions.Thenotionof
impactisanexplicitrecognitionofthe‘principle’thatassessmentisasocialact
becauseassessmentresultsbothconveyinformationandinfluencewhatpeopledo
(Manselletal.,2009).
PutanotherwayFenshamandRennie(2013),JonesandBuntting(2013),and
Millar(2013)allagreethatwhatisassessedhasapowerfulinfluenceonwhatis
taught(ornottaught).Anexampleisschoolreportingofachievementinscienceat
theendofYear10totheNSWBoardofStudies.Schoolsareadvisedthatthe
resultsshouldnotincludeanyconsiderationofachievementofsyllabusoutcomes
relatedtovaluesandattitudes.Ontheotherhand,theadvicerelatingto
investigationskillsisexplicitaboutwhatistobeincluded(BOS,n.d.).
Somewritershavesoughttoframeassessmentintermsoffunctionsratherthan
purposes.ForHattie(2003a),assessmentisnotaboutthetestitself,itisthe
functionthatmatters.Testresults,heasserts,functionasfeedbackto
…teachersand/orstudents…whichtheyneedtointerpretwhenanswering
thethreefeedbackquestions:WhereamIgoing?,HowamIgoing?and,
Wheretonext?Specifically,feedbackisactionsorinformationprovidedby
anagent(e.g.teacher,peer,writtenreport,book,parent,experience)that
providesinformationregardingaspectsofone’sperformanceor
understanding.(p.2)
Hattiearguesthatthesethreequestionsworkforalllevelsoftheassessment
system,andfeedbackcombinesjudgmentandaction(eitherproposedoractual).
Masters(2013,p.2)proposesthattheoverridingfunctionofassessmentisto
provideunderstanding,notjudgment.Heusestheanalogyofadoctor-patient
consultationwherethedoctoristryingtoelicitthesymptomsfromapatientin
ordertodiagnosetheillnessandthenproposeactionstocurethepatient.
Extendingthisanalogy,hesays,“Thefundamentalpurposeofassessmentisto
establishwherelearnersareintheirlearningatthetimeoftheassessment”
(Masters,2013,pp.5-6,italicsintheoriginal).
43
InthisscenarioMasterswantstoremovethepejorativejudgment(ofpassorfail)
andreplaceitwithunderstandingasthebasisforfurtheraction.BothHattieand
Mastersshareaviewoflearningasacontinuousprocessthatcanbeassistedbya
timelydiagnosisandappropriateintervention.Bothresearchersseetheprimary
roleforassessmentasimprovingstudentlearning.
2.4.2Theoriesoflearning,cognitionandassessment
Atthebeginningofthissection,anoverviewofwhatareaderneededtobringtoa
productivediscussionaboutassessmentwasoutlined.Whatastakeholderin
educationunderstandsaboutlearningandcognitioninformswhattheybelieveis
importanttolearnandhowtheyexplainwhyitmatters.Italsoinformsthe
constructionorchoiceoftaskstoprovokeresponsesfromstudents,the
interpretationofthoseresponses(intermsoftheassessorsunderstandingof
curriculumintentions),andtherepresentationandexplanationofthejudgment
(theresult)aboutlearninginferredfromtheresponsestoassessmenttasks.
Twoexamplesofwhereteachersfoundtheoriesoflearningandcognitionhelpful
follow.Inthefirst,Black,Harrison,Lee,Marshall,andWiliam(2004)foundthatUK
secondaryscience,mathematicsandEnglishteacherstheresearcherswere
workingwithinanefforttoimproveformativeassessmentpracticeswantedto
knowmoreabout“thepsychologyoflearning”(p.16).Teacherswantedamodelof
howstudentslearnthatwouldbeusefulforprovidingfeedbacktostudents.Inthe
secondexample,Panizzonetal.(2007)foundthatwhenparticipatingteachers
weregiventheSOLOtheoryofcognition,teachersfounditusefulforplanning
assessmenttasksandrestructuringsciencelearningprogrammestoreflectthe
developmentalchangesanticipatedbytheSOLOmodel.
Adiscussionoflearningtheoriesandtheirrelationshipswithassessmentfollows.
AccordingtotheNRC(2001)report,
Mostcurrenttests,andindeedmanyaspectsofthescienceofeducational
measurement,havetheoreticalrootsinthedifferentialandbehaviorist
44
traditions.Themorerecentperspectives—thecognitiveandthesituative—
arenotwellreflectedintraditionalassessments.(p.60)
Biggs(1995)wrote:
Twobasicconceptionsofthenatureoflearningexistinoureducational
thinking,quantitativeandqualitative…thequantitativetraditionhasthe
longesthistory[andstemsfrom]thepositivisttraditioninthesocial
sciences…Thequalitativetraditionhasitsrootsinnineteenthcentury
phenomenology[and]Gestaltpsychology.[Bothofwhichlatercontributed
toafamilyoflearningtheoriesunderpinnedby]constructivism.(pp.2-5,
italicsintheoriginal).
Thequantitativeassessmenttraditionisassociatedwithbehaviouristtheoriesof
psychologistssuchasEdwardL.ThorndikeandB.F.Skinnerwhoconceive
learningasacquiring
discretequantaofdeclarativeorproceduralknowledge;asfaras
assessmentwasconcerned,anyonequantumistreatedasfunctionally
independentofanyother.Thecurriculumbecomesineffectalistofdiscrete
units:facts,skills,competencies,behaviouralobjectives,performance
indicators,andthelikeandassessmentamatterofhowmany.(Biggs,1995,
p.2)
Fromthisperspective,teachingorinstructionis
conceivedastransmittingknowledgefromteachertolearner…theteacher’s
taskistoknowthesubjectandexpounditclearly,thelearner’storeceiveit
accurately[and]assessment[involvesthe]correctunitsbeingsummedto
giveanaccuratescorethatyieldsanindexofcompetenceinwhatis
learned.(Biggs,1995,p.2)
Thequantitativeassessmentinstrumentofchoicewasthemultiple-choicetest.If
essayswereused,themarkingrubricidentifiedunitsthatwouldbeconsidered
correctoracceptableand‘fullmarks’wouldbeawardedwhenenoughcorrect
45
unitswereevidenced.Agoodtestwouldhavearangeofunitsatvaryinglevelsof
cognitivedifficultybuttheunitswouldallbetreatedashaving“mutual
equivalence,independence,andadditivity.”(Biggs,1995,p.3)
Thebehaviouristperspectiveemergedinthe1930s“aboutthesametimethat
theoriesofindividualdifferencesinintellectualabilitieswerematuring”(NRC,
2001,p.61).AccordingtobehaviouristssuchasThorndike(citedinNRC,2001),
Peoplelearnbyacquiringsimplecomponentsofaskill,thenacquiringmore
complicatedunitsthatcombineordifferentiatethesimplerones.Stimulus-
responseassociationscanbestrengthenedbyreinforcementorweakened
byinattention.Whenpeoplearemotivatedbyrewards,punishments,or
other(mainlyextrinsic)factors,theyattendtorelevantaspectsofa
situation,andthisfavorstheformationofnewassociationsandskills.(p.
61)
Bycontrast,thequalitative,constructivistorcognitiveperspectivecomprises
afamilyoftheoriesratherthananyone,accordingtowhichstudentsare
assumedtolearncumulatively,activelyinterpretingandincorporatingnew
materialwithwhattheyalreadyknow.Differenttheoriesvariously
emphasizetheindividual,social,cognitive,saccadic,contextualoremergent
naturesoflearning,butallagreeonanactivelearnerseekingmeaningby
constructingknowledgeratherthanbyreceivingandstoringknowledge.
(Biggs,1995,pp.3-4)
Inthisperspective,theteacher’sroleistohelpstudents“constructunderstandings
thatareprogressivelymorematureandcongruentwithacceptedthinking”(p.4).
Theteachershouldalsorecognisethatstudentseverydayexperiencesandprior
learningwillinevitablyleadtonaïveoralternativeconceptions(Driver&Easley,
1978)ofhowtheworldworks,andtheseneedtobechallengedandreorientedto
betterreflectthescientificviewpoint.Aconstructivistmodelofteachingand
learningisthe5Esapproach,asadvocatedintheSciencebyDoingcurriculum
supportmaterialsproducedbytheAustralianAcademyofScience(AAS,2017).
46
Fromthequalitativeperspective,assessment
impliesaggregatingunitsoflearningtakencross-sectionallywithrespectto
time,thatfromthequalitativetraditionimplieschartinglongitudinal
growthovertime,fromrelativeignorancetorelativecompetence…Ifthat
growthincompetencecanbedescribedinrecognizablestagesthenso
muchthebetter,becausethesestagescanthenbecomeassessmenttargets.
(Biggs,1995,p.4)
Biggs(1995)thendescribestwokindsofassessmentthathaveemergedfrom
constructivistthinking.Onehedescribesasecological,whichappearstoequate
withwhatothershavecalledperformanceorauthenticassessment(Frey&
Schmitt,2007);theotherhedescribesasdevelopmentalassessment.Itisthelatter
thathegoesontoelaborateas“ageneralizedmodelofqualitativeassessment”(p.
6)andassociatewiththeSOLOTaxonomy(Biggs&Collis,1982).TheSOLO
TaxonomyandSOLOmodelwillbedescribedlaterinthischapter.WhilstBiggs
(1995)positionstheSOLOtaxonomyasaqualitativedevelopmentalmodel,the
laterSOLOmodelhasbeenvalidatedbothempiricallyandinmeasurementmodel
termsaswell(Panizzon&Bond,2007).
Thesituativeviewoflearningprovidessupportforthosearguingthatassessment
shouldbeauthentic,suchasDarling-Hammond(2003);FenshamandRennie
(2013);Hackling(2004);Tytler(2007);andWiggins(1998).TheNRC(2001)
writerssayofthisperspective:
Muchknowledgeisembeddedwithinsystemsofrepresentation,discourse,
andphysicalactivity.Moreover,communitiesofpracticesaresitesfor
developingidentity—oneiswhatonepractices,tosomeextent.(p.89)
Inaddition,standardassessmentmodelstakeaviewofknowledgeas
“disembodiedandincorporeal[andit]capturesonlyasmallportionoftheskills
actuallyusedinmanylearningcommunities”(NRC,2001,p.89).
47
Thesituativeviewoflearningsupportsrecenteffortstoprovidecontextsforboth
thelearningofscienceinthesyllabusofinterestforthisproject(BOS,2003)and
theframingofscienceasahumanendeavour,andtoengagestudentswithscience
andencouragethemtoseethemselvesdoingSTEMwork,post-school.
Vygotsky’s(1978)conceptofthezoneofproximaldevelopmenthasbeen
influentialinthesituativeorsocio-culturalviewoflearning.Shayer(2003)
providesacommentaryonbothPiaget’sandVygotsky’sviewsofcognitive
developmentinchildrentosupporthisparticularinterventionaimedat
acceleratingcognitivedevelopment.
Anothercontributiontothediscussionaboutlearningandrelatedconceptionsof
assessmentisthatbySfard(1998).Hercontributionbridgesbehaviouristand
cognitive(constructivist)andsocio-culturalviewsoflearning.Shesuggeststhat
twometaphorsareusefulforunderstandinglearning:thelearningasacquisition
metaphor(AM)–weacquireconceptsorknowledge;andthelearningas
participationmetaphor(PM).InthecontextofAM,assessmentisaboutthe
quantityofwhathasbeenacquired.InPM,assessmentisaboutaprocessof
knowing,withthepermanenceofhavinggivingwaytotheconstantfluxofdoing.
Thismetaphorimpliesthatlearningasubjectisabout“becomingamemberofa
certaincommunity”(p.6).AMisabouttheindividual;PMisaboutthesocial.
Millar(2013)stronglyadvocatesthatbothcurriculumintention(whathastobe
done)andtheassessmenttask(theconditionsunderwhichitistobedoneasa
demonstrationoftheacquiredlearning)shouldbeprovidedincurriculum
documents.“Theassessmentinstrumentbecomesanoperationaldefinitionofthe
[sciencelearning]objective”(p.56).Also,doingthatwouldrequireteachersto
acknowledge(ifthetaskinvolvedperformance)aviewoflearningthat
acknowledgesbothAMandPM(Sfard,1998).
Anexampleofateachingsequencethatdemonstratesaviewoflearningwhere
bothAMandPMareacknowledgedisprovidedasAppendixC
48
Thecognitivistperspectiveandrelateddevelopmentalapproachestoassessment
haveinformedworkbeingdonetoelucidatelearningprogressionsthatspanthe
yearsofschoolingandspanatopicofworklastingfromfivetotenweeks.TheNRC
(2001)reporthasacomprehensiveanddetaileddiscussionaboutdevelopmental
assessmentandrelatedterms,includingprogressmaps,progressvariables,
developmentalcontinua,progressionsofdevelopingcompetence,andprofile
strands(p.137).
Ofprogressmapsingeneral,theNRC(2001)reportsays
TheDevelopmentalAssessmentapproachrepresentsanotableattemptto
measuregrowthincompetenceandtoconveythenatureofstudent
achievementinwaysthatcanbenefitteachingandlearning.(p.190)
RoweandHill(1996)drawonbothbehaviouristandconstructivistviewsof
learningtoprovideaninsightintothedevelopmentoftheAustraliansubject
curriculumprofiles((CURASS,1994)andoutlinetheirstrengthsandweaknesses
fromadevelopmentalperspective.
TomCorcoran’steamattheCentreonContinuousInstructionalImprovement(CCII)
(Corcoran,Mosher,&Rogat,2009)workonsciencelearningprogressionsinthe
US.TheteamrefertothedefinitionintheNRC-fundedschoolsciencetextbook
TakingSciencetoSchooleditedbyDuschl,Schweingruber,&Shouse(2007),which
iswidelyusedintheUS:
Learningprogressionsaredescriptionsofthesuccessivelymore
sophisticatedwaysofthinkingaboutatopicthatcanfollowoneanotheras
childrenlearnaboutandinvestigateatopicoverabroadspanoftime(e.g.6
to8years).Theyarecruciallydependentoninstructionalpracticesifthey
aretooccur(p.214).
Corcoranetal.(2009)usetheterm“adaptiveinstruction[tocapturethesenseof]
formativeassessmentinaction”(p.8).Thisappearstobesynonymouswiththe
phraseassessmentforlearningthatappearsinthesyllabusrelevanttothisstudy
49
(BOS,2003)andwithwhatBlackandWiliam(2009)call“formativepractice”(p.
8).
2.4.3Criteriaforevaluatingthecredibilityofassessments
Inthecontextofexplaininghowtoensurethequalityandcredibilityof
assessments,researchersreferredtoanumberofcriteriathatneedtobe
addressed.FourexamplesoflistsofcriteriaareprovidedinTable2.2.Thecriteria
applyfromthelevelofclassroomassessmenttolargescaleexternalassessment.
Table 2.2 Issues to resolve when planning, constructing and using assessments
NRC (2001) Harlen (2005) Matters and Curtis (2008)
Ruiz-Primo (2009)
Identification of the targets for assessment Item and test design Validation Reporting Fairness
Validity Reliability Dependability
Validity and related constructs Reliability and related constructs Objectivity Feasibility Usability Credibility
Choose an approach to science instruction (eg inquiry… Identify the critical skills Define assessment purposes Define an appropriate approach for: Validity Reliability Fairness Issues of practicality
Thechangeofstateexample(describedinAppendixC)considerthe“constructs”
(NRC,2001,p.112)ofphysicalandchemicalchange.Anassessmenttaskrelatedto
thatexamplemightinvolveprovidingstudentswithaccesstoaseriesofshort
videoclipsshowingnaturaland‘made’changes.Thetaskistoidentifyineachclip
aprocesswhereeitheraphysicalorchemicalchangeisoccurringandtojustifythe
choice.
Thefirstconsiderationisvalidity(seeTable2.2forthelistofcriteria).Dothevideo
clipscontainexamplesofthetwotypesofchanges?Dotheimagesshowaspects
50
(constructdimensions)ofthephenomenathatareactualpointersorindicatorsof
thechangestoberecognisedandassociatedwitheitheraphysicalorchemical
changeandnotsomethingelse?Isthereevidenceofotherimportantlearningthat
couldbethesubjectofassessment(suchasthepracticalvalueoftheknowledge
forsafeuseofmaterialsandchemicalsthatcouldbeinferredfromthecontextson
displayinthevideofootage)?
Mansell,James&theARG(2009)summarisetheissueofvalidityinthecontextof
teachers’summativeassessmentsas“aboutwhethertheassessmentmeasuresall
thatitmightbefeltimportanttomeasure”(p.12).Intheaboveexample,choices
havetobemadeaboutwhetherthefocusisontheprocessesofchemicalchangein
isolationorwhetherstudentsshouldbepromptedtosaysomethingaboutits
usefulnessaswell.
Messick’s(1995)viewsonvalidityarewidelycitedintheresearchliterature(e.g.
BroadfootandBlack,(2004);Hattie,Jaeger,&Bond(1999);Masters,(2013);NRC
(2001);Shepard(1993).Messick(1995)definesvalidityinthecontextof
psychologicalandeducationalassessmentas
nothinglessthananevaluativesummaryofboththeevidenceforandthe
actual-aswellaspotential-consequencesofscoreinterpretationanduse
(i.e.,constructvalidityconceivedcomprehensively).Thiscomprehensive
viewofvalidityintegratesconsiderationsofcontent,criteria,and
consequencesintoaconstructframeworkforempiricallytestingrational
hypothesesaboutscoremeaningandutility.(p.742)
Hecontraststhismorecomprehensiveapproachtoscoreinterpretationwiththe
historical
primaryemphasisinconstructvalidation…oninternalandexternaltest
structures—thatis,ontheappraisaloftheoreticallyexpectedpatternsof
relationshipsamongitemscoresorbetweentestscoresandother
measures.(p.743)
51
Inessence,Messick(1995)issayingthattheoriginalconstructforvaliditywas
locatedinthemeasurementparadigmforassessment(Biggs,1995;Broadfoot,
2009)andhebroadenedittoencompasstheconcepts(constructs)thatclassroom
teachersengagewitheverydayandarelookingtoassessinthecontextof
performances.Messicksaysthisbroaderviewofconstructvalidity(seeTable2.3)
dependsonanappraisalofsixaspectsheidentfiesas“content,substantive,
structural,generalizability,external,andconsequential”(pp.744-745).
Table 2.3 Messick’s aspects of construct validity
content includes evidence of content relevance, representativeness, and technicaI quality
substantive refers to theoretical rationales for the observed consistencies in test responses, including process models of task performance, along with empirical evidence that the theoretical processes are actually engaged by respondents in the assessment tasks
structural appraises the fidelity of the scoring structure to the structure of the construct domain at issue
generalizability examines the extent to which score properties and interpretations generalize to and across population groups, settings, and tasks including validity generalization of test criterion relationships
external includes convergent and discriminant evidence from multitrait-multimethod comparisons as well as evidence of criterion relevance and applied utility
consequential appraises the value implications of score interpretation as a basis for action as well as the actual and potential consequences of test use, especially in regard to sources of invalidity related to issues of bias, fairness, and distributive justice
Source: Messick, 1995, pp. 744-5
Mislevy(2008)drawsattentiontoresearchworkthatattemptstoreconcile
currentpsychometricmodelsofassessmentandrecentviewsofcognitionthat
includebothcognitivistandsocioculturalorsituativeperspectives.
Cognition,inthisview,isnotjustsomethingthathappensinside
individuals’heads,butacoordinatedinterplayofactionswithinandamong
peopleinasocially-structuredspace.(p.6)
52
Mislevy(2008)explorestheimpactofsocioculturalviewsoflearningonthe
traditionalmeasurementmodelsbasedoncognitivistviewsoflearningand
concludesthat(latent)traitoritemresponsetheory“stillholdsundera
sociocognitivemetaphor,butwithaninterpretationquitedifferentthanthatofthe
strictmeasurementmetaphor”(p.13).Latenttraittheoryascribesarangeof
consistentbehaviouralresponsestounderlying,invisiblebutstablemental
constructssuchasability,aptitude,expertiseandintelligence.Healsoreportsthat
anotherlineofinquiryisfindingthat
Modelsadaptingfeaturesofgeneralizabilitytheory,cognitivediagnosis,and
standardmeasurementmodelswouldseemtobeasuitablestartingpoint
forapsychometricstosupportassessmentunderthesociocognitive
metaphor.(p.13)
ThesecondcriterioninTable2.2isreliability.Woulddifferentassessorsscore
studentresponsesthesameway?Wouldthesameassessorscoreacomparable
responsethesameway?Wouldastudentansweringacomparablequestionona
differentdayanswerthesameway?Andwhatdoescomparablemeaninanycase?
Well-constructedmarkingcriteriaandrubricshelptoensureconsistencyof
marking(anaspectofreliability),aswouldsomepriorpracticeusingthembefore
markingactuallycommenced.Aswell,check-markingbyanotherassessorofa
randomsampleofalreadymarkedscriptsisanotherwayofensuringinter-marker
reliability.
Fairness(seeTable2.2)isensuringthatstudentshavehadopportunitiesbefore
thetesttolearnaboutphysicalandchemicalchangesandthedifferencesbetween
them.Atonelevel,thiscanbeanissueinGrade/Yearcohorttestinginschools
wheremorethanoneclassofstudentssitacommontest.Itcanalsobeanissue
withexternaltestingwhenthecurriculumusedtoprepareforthetestisdifferent
acrossthevarioussitestakingthetest.IntheUKandAustralia,externaltestingis
basedonnationalcurriculumsthatdescribestandardsandrelatedcontentthat
studentstakingthetesthave(orshouldhave)been“taught”.IntheUS,curriculum
choicerestswithindividualschooldistrictboards.Large-scaleexternaltestinghas
53
tobemoreaboutgeneralcapabilitieslinkedtoassumed,commondomain-specific
knowledgethatmayormaynothavebeen“taught”(Ruiz-Primo,Shavelson,
Hamilton,&Klein,2002).
Anotherconsiderationisthechoiceofassessmenttaskandtheopportunitiesit
providesfordifferentstudents(sayfromabackgroundwhereEnglishisnot
spokenathome)torespond.Returningtoourchemicalchange/physicalchange
example,wouldadeaforblindstudentbeabletoscorethesameasastudentwith
normalhearingandvision,giventhatthetesteesarenotabletoobserveall
possibleevidence?(e.g.adeafstudentwouldnothearheatedcornpopping,anda
blindstudentwouldnotseeit).Somestudentsmaynothavehadanyexperienceof
pop-cornatall.Dotesteesneedtowritearesponseorsimplytelltheassessor
whatisgoingon?Howmanycorrectresponsesisrequiredtodemonstrate
proficiency?Thefairnessandequityofassessmentissuesraisedhereareall
relatedtoassessmentvalidity(Messick,1995).
Dependability(seeTable2.2)involvesmakingadefensibletrade-offbetween
validityandreliability.Inthecontextofteachersummativeassessment,Harlen
(2005)says:
Dependabilityisacombinationofthetwo,definedinthisinstanceasthe
extenttowhichreliabilityisoptimizedwhileensuringvalidity.This
definitionprioritizesvalidity,sinceamainreasonforusingteachers’
assessmentratherthandependingentirelyontestsforexternalsummative
assessmentistoincreasetheconstructvalidityoftheassessment.(p.213)
Inassessingstudentresponsestotheabovetask(distinguishingbetweenphysical
andchemicalchanges),shortresponseitems(orevenmultiple-choiceoptions)
mayincreasereliability,butoptionsforextendedresponsescouldinclude
applicationsandreasonsforchoosingeitherchemicalorphysicalchange.The
latteroptionsimprovevaliditybutarehardertoscorereliably.
ObjectivityismentionedbyMattersandCurtis(2008)asitisoftenraisedasthe
bulwarkforfairness.However,iftheassessmentiscomplex,suchasmarkingan
54
essay,itmightbeworthattendingtothe“objectivityandfairnessofthosewho
assessstudentwork”(p.15).Theconcernhereismarkerbiasandhowtoensureit
doesnotaffectordistorttheapplicationoftheassessmentcriteria(seediscussion
aboutreliabilityanddependabilityabove).
Feasibility/practicality(Table2.2)alsoneedstobetakenintoaccount.According
toMattersandCurtis(2008),“Feasibilitymeanscapableofbeingdone,withthe
connotationofconvenienceandpracticabilityinthedoing.Whilemanythingsare
“doable,fewerarefeasible”(p.15).Inthecontextofanationalprogram,cost-and
time-effectivenessareimportantconsiderations,andinaschoolcontext,resources
andtimefactorsareconsiderations.
Intheexampleprovidedabove,shouldtheteacherprovidethevideoclipsand
questionsonaUSBdriveorallowstudentstoaccessthemviatheschool’s
intranet?Thehigherthecostintermsoftimeandresources,themoreimportantit
istoexplainthebenefitsofwhatisbeingdone.Inlarge-scaletestingofsciencein
theAustraliancontext,performancetasksinvolvinganinvestigationwereincluded
inthenationalsampletestsforYear6science(NationalAssessmentProgram-
ScientificLiteracy(NAP-SL)tests(ACARA,2014a)butwerereplacedbyanonline
simulationforthe2015test(ACARA,2017).ThePISA,TIMSSorEVtestshaveno
includedperformancetasks(theEVtesthasasimulatedinvestigationasoneofthe
extendedresponsetasks).Some(e.g.Fensham&Rennie,2013)wouldarguethat
thisreducesthevalidityoftestscoresrelatingtoscience.
Usability(inTable2.2)isanotherissueMattersandCurtis(2008)raise:
Theusabilityofassessmentandreportingmethodsinvolvesthecapacityof
theassessmentandreportingsystemtobeinformativetostakeholdersin
meetingtheirdiverseneeds…Anapproachwillberegardedaspracticableif
itworksandimposesajustifiableyetlimitedloaduponparticipantsand
yieldsvaluableinformationtostakeholders.(p.16)
Theresearchersdiscussthenotionthatgoodassessmentprovidesbothsummative
andformativefeedbackandiscredible.Credibility(seeTable2.2)inheresinthe
55
soundnessoftheassessmentregimeandthereputationoftheissuingauthority,
which(forthepurposesofemployabilityskillcredentials)maybetheschoolsor
theestablishedstateandterritorycurriculumandassessmentbodies.
Educationauthoritiespubliciseresultsfrominternationaltestsandschool-level
aggregationsofnationaltestresults.InAustralia,resultsfrominternationaltests
(TIMSSandPISA),NAPassessmentsandNSWYear12externalschoolexit
examinationsarepublishedforalltosee.Somemediaoutletsusetheresultsto
publishorderedlistsofschoolsusingwhatevercriteriathereportersbelieve
supportsthepointtheywanttomakeaboutassessmentresults.Privatecoaching
collegesalsousetheresultsintheiradvertisementstoattractclients.
Poorresultscanencourageteacherstoteachtothetest(Au,2007)asamistaken
responsetosocialpressureforgoodresults.Thereceiptbystudentsof
consistentlypoorassessmentscandiscourageparticipationandengagementin
learningwhoalreadyhavepoorlearninghistories(ARG,2002b).Testingor
assessmentthatisconsequentialforstakeholdershasbeenlabelled‘highstakes’in
theliterature(e.g.Gipps(1999);Harlen&Deakin-Crick(2002);NRC(2001);
Polesel,Dulfer,&Turnbull(2012)).
Messick(1995)insiststhattheimpactofassessmentresultsonindividualsmust
betakenintoaccountwheninterpretingassessmentscores.Onthatbasis,itis
entirelyappropriateforACARAtoexplainthelimitationsoftheinformationit
providesaboutschoolsontheMySchoolwebsitethatitknowspeopleaccessto
compareschools.TIMSSandPISAtestinginvolvesthecollectingofcontextual
informationtoassistwithinterpretingthetestscoresPISAofficialspublishfor
eachcountry(Thomson,Wernert,etal.,2017;Thomson,DeBortoli,etal.,2017).
TheNRC(2001)reportidentifiedfoursetsofconcernsabouttheadequacyof
assessmentsthatwereevidentatthattime:
1. thevalidityofevidenceusedtoproduceresults
2. thereliabilityofinferencesaboutthelevelofcompetenceandoverall
proficiencydemonstrated
56
3. thepublishers’silenceaboutinterventionslikelytoimproveachievement
orperformance
4. issueswithequityandfairness.(seepp.26–29)
Growingrecognitionoftheseconcernshaspromptededucationauthoritiesto
betteralignlargescaleassessmentwithcurriculumstandardsandtodevelop
assessmentsforknowledgeandskillsnotwelladdressedbyexistingtestitemsand
tasksthatmakeupmoststandardisedtestscurrentlyinwidespreaduse(suchas
aptitudetestsusedtomoderateindividualschooltestresultsinAustraliaandin
theUS).Performanceassessmenthasbeenanotherresponse.Studentsare
presentedwith“open-endedtasksthatcallupon[them]toapplytheirknowledge
andskillstocreateaproductorsolveaproblem”(NRC,2001,p.30).
Harlen(2005),inworkfortheUK-basedAssessmentReformGroup(ARG),
exploredtheissuesteachershavetoreconcilewhenattemptingtouseclassroom
assessmentsandresultsfromtests,includinglarge-scaleexternaltestsforboth
formativeandsummativepurposes.Broadlyspeakingthetradeoffthathastobe
madeisbetweenvalidityandreliability,whichwasdiscussedaboveinthecontext
ofDependability.ThediscussioninherpaperisapplicabletotheNSWcontext
whereteachersarebeingaskedtouseassessmentsforbothsummativeand
formativepurposes(theEVprogram).
AmajorreportonhighstakestestinginAustraliawaspublishedintwopartsby
theWhitlamInstitutein2012.Theliteraturereviewpart(Poleseletal.,2012)
considered“whethertheteststhemselvesarereliable,validanddesirableontheir
owntermsasameansofassessment”(p.8)andcitedresearchchallengingthe
testsasabasisforeducationaldecisionmakingundertheheadingsofreliability,
studenthealthandwell-being,learning,teachingandcurriculum.
Thereportitself(Dulferetal.,2012)drewontheliteraturereviewandresponses
(N=8353)totheverylargeonlinenationalsurveytoprovidean“educators
perspective”(inthereporttitle)andconcluded:
57
NAPLANisviewedbytheteachingprofessionas‘highstakestesting’;
findings…suggestthatNAPLANmaybehavingadetrimentaleffectinareas
suchascurriculumbreadth,pedagogy,staffmorale,schools’capacityto
attractandretainstudentsandstudentwell-being;and,concerns
expressed…suggestthatfurtherresearchisrequiredtoexaminecarefully
theuses,effectsandimpactsofNAPLAN(p.9)
WhilstthetestsreviewedintheWhitlamInstitute-sponsoredresearchareabout
literacyandnumeracytesting,thetechnicalissuesrelatedtovalidity,reliability,
desirabilityandfairnessapplytoanyone-offsummativetest,suchasthenational
Year6sciencetest,theEVtests,thenowabandonedYear10testsinNSWand
currentYear12schoolexittestsinAustraliaandotherpartsoftheworld,aswell
astestsdevisedbyteachersforstudentsattheirschools.
2.5Measurementandsummativeandevaluativeassessment
Thissectionwilldescribesummativeassessmentmodels–“thegenerationof
summativedata”(Broadfoot,2009,p.x)–thatepitomisetherigorousapproachto
measurementthatunderpinstheTIMSS,PISA,NAP-SLandNAPLANtests.Itwill
includeexamplesfromtheMySchoolwebsite.
Discussionoftheabovetestsisrelevanttothisthesisforthreereasons.Thefirstis
togetasenseofwhatisbeingmeasured.Thesecondistoobtainasenseof
whethertestresultscanbeusedforformativepurposesand,ifyes,atwhatlevel/s
(individual/class/school/schoolsystem(governmentorprivate)/stateor
territory/national/internationalmighttheinformationtheyprovidebeuseful?
Thethirdreasonistounderstandwhatinformationaboutschoolsisavailableon
theMySchoolwebsiteandtoexplainhowitwasusedinthisresearchproject.
Inthecontextofaschool,teachers’summativeassessment(ofindividual’s
achievements)usuallyhappensattheendofanepisodeofteaching.Thephrase
summativeassessmentrefersto
58
[the]processbywhichteachersgatherevidenceinaplannedand
systematicwayinordertodrawinferencesabouttheirstudents’learning,
basedontheirprofessionaljudgement,andtoreportataparticulartimeon
theirstudents’achievements.(Harlen,2005,p.247)
Atthispoint,itisperhapsworthrecallinghowevidenceisgatheredandusedto
informreportstoparents.
Humanscanonlyprovideevidenceintheformofwhattheywrite,make,do
andsayanditisfromthesefourobservableactionsthatalllearningis
inferred.Thisisthebasicandfundamentalroleofassessment—tohelp
interpretobservationsandinferlearning.Themoreskillsareobserved,the
moreaccuratelygeneralisedlearningcanbeinferred.Hence,thereisaneed
todocumentthediscreteobservableskillsandfindawaytoblendthem
intocohesiveevidencesets(Griffin,2009,p.195)
Griffin(2009)couldequallyhavecompletedtheabovequotewiththefollowing
addendum:“andinterprettheminaconventionalwaytoreportprogressin
learning”.InNSW,reportingconventionsforstudentsfromYearsKto10are
describedontheBoard’swebsite(NESA,2017,Awardinggrades).Information
aboutassessmentandrelatedreportingproceduresinthesenioryearsforNSW
andotherAustralianstatesandterritoriesisavailableontheAustralasian
Curriculum,AssessmentandCertificationAuthoritieswebsite(ACACA,2018).
Theassignmentofagradeforreportingpurposesisbasedonateacher’sjudgment
oftheaccumulatedevidenceoflearninggatheredsincethelastreport.NSW
governmentschoolsarerequiredtoformallyreporttoparentstwiceayear.What
istobelearnedandassessedaresyllabusoutcomesandrelatedcontentthat
definestheminimumexpectationsforachievingtheoutcome/s.Thislearning
mattersbecauseithasbeendeemedappropriatebythoseempoweredtocreate
thesyllabusforstudentsattheageandstageoflearningforwhichtheproposed
summativeassessmentistobedone.Theexpectationisthatteacherswillhave
providedstudentswithaccesstothecontentthatwillbethetargetofthe
assessment.
59
AswillbeshowninChapterFive,evidenceoflearning(inscience)inthe16case
studyschoolswastypicallycollectedusingpen-and-papertests,responsesto
practicalactivitiesandresearchprojectsforwhichwrittenreportsoranswersto
specificquestionsand/ororalpresentationsarerequired.Typically,taskswere
assessedinthecourseoftheschoolyearandamarkawardedtoeachbasedon
criteriaderivedfromtheoutcome/stargetedandits/theirrelatedcontent.The
marksarerecordedandthenusedasthebasisformakingan‘on-balance’,holistic
judgmentthatisthenrepresentedasagradefromAtoE.Itisthegradethatis
reportedtostudents,parentsandinterestedothersatpredeterminedtimesinthe
yearoverthesuccessiveyearsofschooling.
Inmakingthisjudgment,teachersareassistedbytheDepartment(officialpolicy
andsupportmaterialontheDepartment’sintranetforgovernmentschool
teachers)andtheNSWBoardofStudiespublicwebsitededicatedtoassessment
support(BOS,2013).TheBoard’swebsiteincludestheCommonGradeScale(CGS)
andrelatedadviceabouthowtomakeagradejudgment.Foraparticularstage
(e.g.Stage4coveringschoolYears7and8)anAgradewouldbeawardedtoa
studentwho
hasanextensiveknowledgeandunderstandingofthecontentandcan
readilyapplythisknowledge.Inaddition,thestudenthasachievedavery
highlevelofcompetenceintheprocessesandskillsandcanapplythese
skillstonewsituations.(BOS,2013,TheCommonGradeScale)
Bycomparison,anEgradewouldbeawardedforworkjudgedtodemonstrate
anelementaryknowledgeandunderstandinginfewareasofthecontent
andhasachievedverylimitedcompetenceinsomeoftheprocessesand
skills.(BOS,2013,TheCommonGradeScale)
Thescopeforjudgmentabouttheappropriategradetoapplyisconstrainedto
studentdemonstrationsofknowledgeandunderstanding;abilitytoapplythat
knowledgeandunderstandinginnewsituations;andthelevelofskillsand
processesrelatedtoscience.Depthisarelativetermranginginthecaseofskills
60
andprocessesfromveryhightoverylimited.Thecapacitytoapplythoseskillsin
newsituationsgoesfromanimplied“almostall”to“most”foraBgrade,thennot
mentionedafterthat.Thus,ifthereisnoevidenceoftransfer,thebestastudent
canachieveisaCgrade.Judgmentsaboutsyllabus-describedValuesandAttitudes
(BOS,2003,p.11)werenottobeincludedintheseassessments.
Theassignmentofthegradeisbasedonaholisticon-balancejudgmentapplyingto
alloftheoutcomesassessedorfordifferent“areas”ofgroupedoutcomes.For
Stage5science,theBoardrecommendsreportingachievementforsixareas:
Knowingandunderstanding;Questioningandpredicting;Planningandconducting
investigations;Processingandanalysingdataandinformation;Problem-solving
andCommunicating(BOS,n.d.).
Giventhemethodologyforcollectingandscoringevidenceoflearningrelativeto
syllabusstandards,reportingingradesappearstobeanappropriatetrade-off
prioritisingconstructvalidityoverreliability.Theawardofagradeinvolves
differentiatingbetweenfivelevelsascomparedtothedubiousreliabilityofan
implieddifferentiationifresultswerereportedaspercentiles.
Thenextexamplerelatestothewaysresultsfromlargescalenationaltestingin
literacyandnumeracyofeveryeligiblestudentinYears3,5,7and9inAustralian
schoolsarereported.Thereferencetoliteracyandnumeracytestingandthe
MySchoolwebsiteisincludedinthissectionofthethesisbecausebothNAPLAN
dataandotherpubliclyavailabledataontheMySchoolwebsitepertainingtothe
casestudyschoolsinvolvedwasaccessedfordatarelevanttoaddressingthe
researchquestionsattheheartofthisthesis.Thoseuseswillbeexplainedin
subsequentchapters.
StandardisedNAPLANresultsforindividualsarecollatedintoschoolsetsandused
togeneratereportsforparentsandschools.Aggregatedschoolleveldatais
publishedontheMySchoolwebsiteintheformofalevelrelatedtoascalethathas
beenestablishedtocovertherangeofexpectedperformancesforthegreat
majorityofstudentssittingthetestsuptoYear9.Thescaleincludes10
performanceBands.Year3students’performanceisreportedagainstBands1to6;
61
Year9students’resultsarereportedagainstBands5to10(ACARA,2013c),
Resultsandreports).Theschoolwebsitesincludearangeofotherinformationthat
isupdatedannuallyforthe9450schools(ABS,2018)acrossAustralia.Information
abouteachschoolispublishedontheschoolwebsite(ACARA,2016a,About).
Anextractoftheschooldataforagovernment,metropolitan,comprehensive
schoolwithsomeunclassifiedstudents(educationallydisadvantaged)andarange
ofstudentsfromYears7to12isshowninFigure2.2.
Figure 2.2 Selected school data for a government, metropolitan, Years 7-12 school. Source: MySchool website (ACARA, 2017)
62
InadditiontousingNAPLANdata,schoolsocioeducationaladvantage(SEA)profile
(whichisreferencedtothenationalquartileprofile)wasusedtofindcomparable
schools,aswillbeexplainedinChaptersThreeandFive.
ACARAproducesanannualreporttitledtheNationalReportonSchoolingin
Australia,whichisavailablefromtheACARAwebsite(ACARA,2016c,Reporting).
TheReport’smainpurposeistoreportprogresstowardachievingthetwo
“EducationalGoalsforYoungAustralians”(seeAppendixB).ACARAdoesthisby
“collecting,managing,analysing,evaluatingandreportingstatisticalandrelated
informationabouteducationaloutcomesfromdomainsoflearningdeemed
importantbythenationalEducationCouncil”(ACARA,2016d,Nationaldata
collectionandreporting).Thescopeofthisworkcurrentlyincludesliteracy,
numeracy,scienceliteracy,ICT,andcivicsandcitizenship.ScienceliteracyofYear
6students,forexample,hasbeenmonitoredtrienniallysince2003;thelatesttest
cyclewascompletedin2015.
Thethirdexampleofsummativetestingtobediscussedinvolvesinternational
comparativetestingandthewaysresultsfromthosetestsareused,bywhomand
forwhatpurposes.ThetwotestsofinterestherearetheTIMSSandPISAtests
describedabove.Thetestsprovidesummativeassessmentsofperformancesby
studentcohortsinschoolschosenbyastratified,randomsamplingmethodologyto
deliverasampleofstudentsfortesting.Thesamplehastoberepresentativeofall
targetedstateandterritorystudentpopulationsinAustraliaaswellastheirschool
sectorsandimportantdemographicgroupsrelatedtoassessingequityand
excellence(nationalGoal1).
Thetestsareofliteracy,numeracyandscientificliteracy,butwhatisassessed
withinthedomainconstructshastobeaccessibleandcomparableincognitive
demandforallparticipantsacrossthejurisdictionstakingpartinthetesting.
Evidenceoflearningiscollectedbypen-and-papertestsandother,related,
contextualinformationfromsurveyscompletedbystudents,teachers,principals
andeducationauthorityofficers.
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DetailedreportsonAustralianstudents’performanceintheinternationaltestsand
ontheirconsiderableinfluenceareavailableontheACERwebsite.Theintended
audiencefortheresultsfromtheseinternationaltestsarehigh-leveleducation
policyofficers,educationadviserstogovernmentandthemedia,andeducation
researchers.Datasetsfromthetestsareavailablefordownloadandindependent
analysis.
ACERhaspublishedabookforteachersaboutPISA(Thomson,Hillman,&De
Bortoli,2013)thatexplainsthetestanditspurposesaswellasprovidingsome
examplesofassessmenttasks.BothFensham(2013)andMillar(2013)arguethat
thisisaveryworthwhileinitiativebecauseitprovidesgoodmodelsforassessment
itemsthatteachersshoulduseandreplicateinthecontextoftheirownschool-
basedassessment.
Scientificliteracywasthedomainofmajorfocusforassessmentin2015(asitwas
inthe2006roundoftesting).In2006theconstructsinterestinscienceandsupport
forsciencewereincludedforassessmentinthetest.Athirdconstruct,
responsibilitytowardsresourcesandenvironments,wasincludedinthestudent
questionnaire.Atthattime,theinclusionofattitudestowardscienceinthissortof
testwasgroundbreaking.Itwasretainedin2015butwereaddressedinthe
studentquestionnaire.
OfparticularinteresttothisthesisisthePISA2015assessmentframework,which
includedthenewfeatureofcognitivedemand“withintheassessmentofscientific
literacyandacrossallthreecompetenciesoftheframework”(OECD,2017,p.40).
Thetestdevelopersdistinguishcognitivedifficultyfromempiricalitemdifficulty.
Thelatteris“estimatedfromtheproportionoftest-takerswhosolvetheitem
correctly”(p.40).
Cognitivedifficultyrelatestothetypeandlevelofmentalprocessesdemonstrated
inresponsestoaquestion.Ofrelevancetothisthesisistheinternational
acknowledgmentthatthelevelofthinkingdemonstratedbyastudentisan
importantaspectofthecompetenciesthatdefinescientificliteracy.Fromits
inceptionin2005,theEVprogramhasincludedthemeasurementofcognitive
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difficulty(levelsofthinking).TheinclusionofcognitivedifficultyinthePISA2015
assessmentframeworkisbelatedvindicationofitsincorporationintotheEV
program.
BeforeWebb’s(1997)DepthofKnowledge(DOK)approachwaschosenasthebest
tomeasurecognitivedifficultyforthepurposesofPISA2015,anumberofother
theoreticalframeworkswereconsidered,includingtheSOLOTaxonomy(Biggs&
Collis,1982).IntheviewofPISAdevelopers,DOK“isasimplerbutmore
operationalversionoftheSOLOTaxonomy”(OECD,2017,p.40).TheEVprogram
inNSWusestheSOLOmodel(Panizzonetal.,2006)asthebasisformeasuring
levelsofthinking.ThereasonsforusingSOLOforthiswillbediscussedinSection
2.6.
Giventhehighstakesinvolvedhereforthecountriesparticipatinginthese
internationaltests,theassessmentframeworksaresubjectedtoscrutinyandneed
tobedefensible.Stateoftheartpsychometricsareutilisedtoensuredependability
ofscores(theappropriatetrade-offbetweenconstructvalidityandreliability).For
theseinternationaltests,giventhediversityofcurriculaacrossthecountries
involvedandtheabsenceofanyinternationalagreementaboutwhattotest,
“reliability[is]thedominantstatisticintheseinternationaltests”(Fensham,2013,
p.14).
Fensham’s(2013)maincriticismofTIMSSandPISArelatetothefactthatpen-and-
papertestingcannotassesstheincreasinglyimportantexpectationsforscience
andtechnologylearning,suchas
practicalperformanceinscience…decisionmakingaboutsocio-scientific
issues,context-basedscienceandscienceprojectworkinandoutside
school…NeitherTIMSSnorPISAacknowledgestheabsenceofanytestingof
thesciencelearningsassociatedwiththesenewergoals.Suchhigh-status
silencecaneasilybeinterpretedassuggestingtheyarenotofworth.(p.18)
Despiteacknowledgingvalidityissues,overtimeTIMSSandPISAtestshave
providedimportantreliable(inthestatisticalsense)feedbacktoeducation
65
authoritiesaroundtheworldonissuestodowithgenderequityintermsofscience
achievement,theimpactofsocio-economicbackgroundonachievement,and
whetherthegapbetweentopandbottomperformersisgettingwiderornarrower.
InAustralia,thesamplesizeisdeliberatelylargeenoughtoprovidereliabledata
onachievementofstudentsinthedifferentstatesandterritoriesandschool
sectors(governmentschool,catholicschoolandotherindependentschool)aswell.
TheAustraliandatashowsgirlsandboysdoequallywellinscience;thesocio-
economicstatusofparentsispositivelylinkedtoachievement;andstudentsof
Indigenousbackgroundandstudentswhoareeducatedingeographicallyisolated
placesdomuchworseinsciencethantheirmetropolitancounterparts.Inshort,
thesetestsprovideapictureovertimeofstudentprogressinrelationtothe
“EducationalGoalsforYoungAustralians.”
2.6Formativeassessmentandformativepractices
TheNSWsciencesyllabusofrelevancetothisproject(BOS,2003)refersto
assessmentofandforlearning(pp.70-75).Thecurrentsyllabus(BOSTES,2012)
talksaboutassessmentaslearning,aswellasbeingofandforlearning(p.171).In
theliterature,assessmentaslearning(Dann,2002;Earl&Giles,2011;Hickey,
Taasoobshirazi,&Cross,2012)islinkedto“assessmentforlearning”(Black&
Wiliam,2009,p.8)whentheresearcherstalkaboutactivatingstudentsasthe
ownersoftheirownlearning.Advocatesofassessmentaslearningacceptthat
studentsshouldbevaluedparticipantsintheirownlearning,anticipatereceiving
andutilisingconstructivefeedbackandfeed-forwardandbeabletoidentifytheir
ownlearninggapsandsolvetheirlearningneeds,withteacherassistance.Through
thispracticestudentscandevelopskillsforlife-longlearningandbeself-motivated
bylearningselfandpeerassessmentstrategies.(Earl&Giles,2011,p.13)
Someresearchershavewarnedthatasimplisticviewofassessmentaslearning
couldbemisconstruedasendorsingteachingtothetest,coachingtoimprovetest
answeringskills,andthenotionthattestingcountsaslearning(e.g.Sadler,2007;
Torrance,2007).Assessmentaslearningisalsolinkedtoself-regulatedlearning
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(Boekaerts&Corno,2005;Clark,2012;Nicol&Macfarlane-Dick,2006;Schraw,
Crippen,&Hartley,2006).
Thisthesiswillattendprimarilytoformativeassessment,self-regulatedlearning,
learninghowtolearn,andlearningindependenceorautonomy.becausethe
researchliteraturefortheseismoreextensive.InChapterThreethisliteraturehas
beenusedtodevelopthedimensionsofformativepractice,whichconstitutethe
theoreticalframeworkusedforexploringtheimpactofassessmentforlearning
andtheEVprogramonassessment-relatedworkofscienceteachers.Thiswillbe
explainedinsubsequentsectionsandinChapter3.
AccordingtoBlack,McCormick,James,andPedder(2006),self-regulatedlearning
isthekeyto“learninghowtolearn”,whichtheseresearchersdistinguishfrom
learningtolearn.Self-regulatedlearningunderpinsthecapacityfor“life-long
learning”(Blacketal.,2006,pp.120-121).Theimportancetoindividualsof
acquiringthecapacityforindependent,life-longlearninghasbeenidentifiedasan
importantgoalforpreparingstudentsforlifeintheknowledgesocietyandits
relatedknowledgeeconomy.Itwastheover-ridinggoalforscienceeducationin
NSWintheperiodofinterestforthisproject(BOS,2003).
Assessmentforlearningorformativeassessmentisattractingalotofattention
becauseitisperceivedtobeperhapsthesinglemostimportantkeytoimproving
engagementwithlearningandrelatedachievementinscience.Ifitisproperly
implemented,studentsshouldbegraduatingfromschoolwellontheirwayto
beingself-managinglearners.Therearethreereasonsformakingthesestrong
claims.
Thefirstreasonisthewaveofsupportforformativeassessmentandits
pedagogicaloffspring,formativepractices,sparkedbytwopublicationsbyBlack
andWiliamin1998:AssessmentandClassroomLearning(Black&Wiliam,1998a)
andInsidetheBlackBox:RaisingStandardsThroughClassroomAssessment.(Black
&Wiliam,1998b).Thelatterwaswrittenwithscienceandotherteachersinmind.
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Thesecondreasonisthestrongandgrowingconfirmationthattheteacheris
“…thegreatestsourceofvariancethatcanmakethedifference[inachievement]”
(Hattie,2003b,p.3).Inhiscalculationsofeffectsizesforalargearrayofclassroom
interventions,Hattieidentifies14influencesofteachers,allbutthreeofwhichare
linkedtowhattheteacherdoesintheclassroomwithstudents.
Thethirdreasonisthatananalysisofwhatteachersdointheclassroomthat
makesthemostdifferencetoachievement,arealllinkedto“formativepractices”
(socalledbyBlack&Wiliam,2009,p.8).Eachofthesethreereasonswillbedealt
withinseparatesubsections.
2.6.1Supportforformativeassessment
TheARGwithsponsorshipfromtheNuffieldFoundationhadcommissionedBlack
andWiliamin1995toreviewtheliteratureonformativeassessment.Theirreport
waspublishedin1998(Black&Wiliam,1998a).Subsequently,theARGpublished
abrochuredescribingtenprinciplesofAssessmentforLearningandgavestrong
endorsementfortwopublicationsaboutassessmentforlearningarisingfromthat
reviewandlaterwork(ARG,2002a).TheARGdefinedassessmentforlearningas
Theprocessofseekingandinterpretingevidenceforusebylearnersand
theirteacherstodecidewherelearnersareintheirlearning,wherethey
needtogoandhowbesttogetthere.(ARG,2002a,p.2)
Inasecondpublication,WorkingInsidetheBlackBox,Blacketal.(2004)reprised
thethreequestionstheBlackandWilliam(1998b)reviewhadsetouttoanswer:
1. Isthereevidencethatimprovingformativeassessmentraisesstandards?
2. Isthereevidencethatthereisroomforimprovement[informative
assessmentpractices]?
3. Isthereevidenceabouthowtoimproveformativeassessment?
Theresearchreportedin1998hadsaidyestothefirsttwoquestions.Blacketal.
(2004)providedananswerintheaffirmativeforquestionthree.Itreportedthe
resultsofatwo-year,school-basedprojectinvolvingtheresearchersworkingwith
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science,mathematicsand,later,Englishteacherstoimproveformativeassessment
practicesandtodevelopnewones.
AssessmentforlearningwasacknowledgedintheUSpublication(NRC,2001)as
“assessmenttoassistlearning,orformativeassessment.”(p.38,italicsinthe
original).TheNRC(2001)reportreferencedthe1998Black&Wiliampaper:
[Black&Wiliam]alsoreport…thatthecharacteristicsofhigh-quality
formativeassessmentarenotwellunderstoodbyteachersandthat
formativeassessmentisweakinpractice.(p.227)
TheNRC(2001)reportappearstoacknowledgethiswasanissueintheUSaswell
becauseitsRecommendation11said:
Thebalanceofmandatesandresourcesshouldbeshiftedfromanemphasis
onexternalformsofassessmenttoanincreasedemphasisonclassroom
formativeassessmentdesignedtoassistlearning.(p.14)
TheOECDpublicationonformativeassessmenttitledFormativeAssessment:
Improvinglearninginsecondaryclassrooms(OECD,2005)citedajournalversionof
theWorkinginsidetheBlackBoxnarrative(Black&Wiliam,2005).TheOECDused
thejournalversionasthemainreferentfromtheEnglish-speakingworldand
linkedittoeightcasestudiesofformativeassessmentinpracticefromaroundthe
world,includingQueensland,asindicatedearlierinthischapter.Offormative
assessment,theOECDreportsays:
Studiesshowthatformativeassessmentisoneofthemosteffectivestrategiesfor
promotinghighstudentperformance.Itisalsoimportantforimprovingtheequity
ofstudentoutcomesanddevelopingstudents’“learningtolearn”skills.(CERI,
2005,p.13)
InAustralia,thewritersofTheStatusandQualityofTeachingandLearningof
Science(Goodrumet.al.,2001)endorsedBlack&William’s(1998a)supportfor
theprovisionofmeaningfulfeedbacktoachieveimprovementsinlearning
outcomes.
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Assessmentforlearning,asdistinctfromassessmentoflearning,impliesan
importantshiftintheownershipofassessment.Theoverwhelmingmessageabout
assessmentoflearningisthatitisdonetosomeone(students?)bysomeoneelse(a
teacher?)andtheperson‘doneto’wearsthejudgmentlabelassignedthem
(Newton,2007).ThelanguageIamusingisdeliberatelypejorativetosignalthata
properunderstandingofassessmentinvolvesrecognisingitasasocialact(Gipps,
1999;Broadfoot&Black,2004)
Insciencelearning,theteacher’sroleistohelpstudentsidentifyandowna
progressioninsciencelearningappropriatetotheirneedsasstudentsinascience
course.Intheprocessofdoingthat,theteachershouldprovidestudentswiththe
cognitivetoolstoconstructtheirownlearningmaps,whichtheycanuseto
navigatethroughlifeasasciencestudentatschoolandinlifegenerally.Thegoal
forteachersistomakethemselvesredundant(Sadler,1998).
BellandCowie(1997)wroteareportfortheLearninginScienceProject
(Assessment)whichranin1995and1996.Republishedin2002(Bell&Cowie,
2002),thereportsuggested:
1. Pen-and-papertestscannotprovidedataformanyofthevaluedoutcomes
inscience(suchasinquirytasksorworkinginteams).
2. Therearemanypurposesforassessment(cf.Newton,2007).
3. Iflearningisownedbythestudent,theteacherneedstobeabletomonitor
studentconceptualdevelopmentandsupporttheprocessbyhavinga
theoryoflearningthatcanbeusedtosupportthatprogress.
4. Formativeassessmentcanprovideevidenceoflearningforthegapsin
assessmentcoverage(thusimprovingthedependabilityoftheassessment)
foradiversityofpurposesanduses,andbetterqualityfeedbacktosupport
theprogressingconceptualdevelopmentfromnaïvetosophisticated
understandingsofscience.
CowieandBell(1999)definedformativeassessmentas“theprocessusedby
teachersandstudentstorecogniseandrespondtostudentlearninginorderto
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enhancethatlearning,duringthelearning”(p.101).Wiliam(2011b)
acknowledgedtheCowieandBell(1999)qualification“duringthelearning”.
Wiliam(2011b)creditsStigginswithpopularisingtheuseofthephrase
‘assessmentforlearning’.HealsoattributestoStigginstheidentificationoffour
conditionsthathavetobesatisfiedforformativeintenttoberealisedandfor
studentstoremainengagedwiththelearningprocessevenwhentheassessment
resultisnotwhattheywouldwanttoreceive(Stiggins&Chappius,2005).Wiliam
(2011a)alsoelaboratestheprinciplesofformativeassessment,goingwellbeyond
whatwasprovidedinthepaperbyBlack&Wiliam(2009).
WilsonandSloane(2000)describedasystemofembeddedassessments—theso-
calledBEAR(BerkeleyEvaluationandAssessmentResearch)AssessmentSystem,
orBAS.TheBAS“isacomprehensive,integratedsystemforassessing,interpreting,
andmonitoringstudentperformance”(p.182).Itstoolsenableteachersto:
• assessstudentperformanceoncentralconceptsandskillsinthecurriculum
• setstandardsofstudentperformance
• trackstudentprogressovertheyearonthecentralconcepts
• providefeedback(tothemselves,students,administrators,parents,or
otheraudiences)onstudentprogressandontheeffectivenessofthe
instructionalmaterialsandtheclassroominstruction.(p.182)
Theprinciplesbehindthedesignofthisclassroom-basedassessmentsystemare:
1. Itshouldbebasedonadevelopmentalperspectiveofstudentlearning(ie
thatthereisadefinablepathwayastudentfollowsastheyworkthrough
thetopic[…]alearningprogressionthatdescribesintendedlearningsina
curriculumdefinedlearningarea,suchasscience.
2. Theremustbeamatchbetweenwhatistaughtandwhatisassessed(which
meansthatothermethodsforassessingperformanceapartfromresponses
topenandpapertestsmustbeused).
3. Teachersmustbethemanagersofthesystem(iftheyaretousetheresults
aseffectivefeedback).
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4. Tobeacceptablebeyondtheschool,assessmentshavetobeseenasfair,
validandreliablemeasuresoftheexpectedlearning(evidenceofhigh
quality).
2.6.2Teachersmakethedifference
Hattie(2003b)hassummarisedthefindingsfrommanystudies,usingHierarchical
LinearModelling(HLM)(p.1),whichattributesthevariationinstudent
achievementatschooltosixmaininfluencesasmeasuredbytheresultsfromlarge
scaleexternaltesting.Thelastfouraregroupedas“combinedeffects”sometimes
referredtoasschoolenvironmentfactors.HLMalsoassignstherelativeweight
eachhasonachievement.Thethreecontributorstovariationare:
1. whatstudentsbringtoschoolintheformofabilityandsocialcapital(50%);
2. theexpertiseoftheteacher(30%)
3. thecombinedeffectsofschool-principal,homeandpeereffects(20%).
Hattie(2003b)arguesthatsupportingteacherswouldbethemostproductiveway
toimproveachievement.Hemadethatpointbycomparingtheeffectsize
differencesof16influencesonachievement(assessedusingtheSOLOTaxonomy)
attributedtoexpertasopposedtoexperienced(whichhedefinesinhispaper)
teachers(seeFigure2.3).
Giventhateffectsizesabove0.40(verticalaxisFigure2.3graph)arevalueadding
abovetheaverage,teacherexpertiseisaveryusefulcontributortolearning.
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Figure 2.3 Effect-sizes of differences between Expert and Experienced Teachers.
Source: Hattie, 2003b, p. 14.
Whenyoudrilldownintothedimensionsofexpertisethatprovidethegreatest
effectsize,theabilitytouseaspectsofformativeassessmentfeaturehighly.
Examplesgivenincludetheuseoffeedback,thecapacitytomanageclassroom
discussionsproductively,andworkingwithstudentsinwaysthatenhancetheir
capacityforself-regulation.
2.6.3Weightofevidencesupportingformativepractices
Thesheerweightofevidencethatemergedfrommeta-analysesofthehugebodyof
researchfindingsaboutinterventionsandstrategiesusedbyteacherstoimprove
achievementisperhapsthemostcompellingreasonforsupportingformative
practices.Meta-analysisisastatisticalprocessthatprovidesacomparable
measureofeffectsizeforinterventionstriedandtestedinresearchprojectswhere
beforeandafterstudiesproducedaresult.JohnHattie’s(2009)VisibleLearning,
Distinguishing Expert Teachers from Novice and Experienced Teachers. 14
Percentage of Student Work classified as Surface or Deep
0
10
20
30
40
50
60
70
80
Experienced Experts
SurfaceSurface Deep
Deep
A more effective method for demonstrating the magnitude or importance of the differences in means is to graph the effect-size (difference in means divided by the pooled standard deviation). The effect-sizes (the of each of the 16 dimensions can be seen in the next Figure.
Deep R
epres
entat
ions
Problem
Solving
Anticipate
and Plan
Better
Decisio
n mak
ers
Classro
om C
limate
Multid
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Sensit
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to Con
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k & M
onito
ring L
earn
ingTest
Hyp
othesi
sAutom
aticit
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Respect
for S
tudents
Passion
Engage
in le
arning
Set ch
allen
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asks
Positiv
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ence
on ac
hievem
ent
Enhance
surfa
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arning
Effect-size0
0.2
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1
1.2
Effect-sizes of differences between Expert and Experienced Teachers
Essential Representations
Guiding learningMonitoring and
FeedbackAffective attributes Influencing Student
Outcomes
Copyright Professional Learning and Leadership Development, NSW DET
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Tomorrow’sSchools,TheMindsetsthatmakethedifferenceinEducationis
extraordinaryfortworeasons.
Thefirstreasonisthehugenumberofresearchpapersheanalysedtoproducethe
effectsizesfordifferentinterventions.Thesnapshotoftheresearchprojects
includedforpublicationnumberedmorethan800meta-analysesofsome50,000
studiesinvolvingmorethan200millionstudents.
Thesecondwasitsrevelationofconsistentlyhigheffectsizesattributableto
interventionsassociatedwithformativepractices(thiswillbeexplainedlaterin
thissection).Theaverageeffectsize(ES)ofallinterventionsHattiereviewedwas
0.40.Basedonevidencefromlarge-scaletestingintheUS,theUK,NewZealand
andAustralia,Hattie(2012)saysthisistheaverageESonachievementofone
yearsteaching.Tohaveanimpactonachievementabovethat,teachingneedsto
involvepracticeswithanES>.40.
Eachoftheinfluencesisdiscussedandexplainedinthebodyofthetextreferenced
inTable2.4,whichliststhe21mostpowerfulinfluencesofstudentachievementas
of2012.
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Table 2.4 Influences on learning and effect sizes
Influence ES Influence ES Influence ES Self-reported grades / Student expectations (STE)
1.44 Comprehensive interventions for learning disabled students (TGE)
0.77 Acceleration (SLE)
0.68
Piagetian programs (STE)
1.28 Teacher clarity (TRE) 0.75 Classroom behavioural (SLE)
0.68
Response to intervention (STE)
1.07 Feedback (TRE) 0.75 Vocabulary programs (CME)
0.67
Teacher credibility (in the eyes of the student) (TRE)
0.90 Reciprocal teaching (TGE) 0.74 Repeated reading programs (CME)
0.67
Providing formative evaluation (TGE)
0.90 Teacher-student relationships (TRE)
0.72 Creativity programs on achievement (TGE)
0.65
Micro-teaching (TRE) 0.88 Spaced vs mass practice (TGE)
0.71 Prior achievement (STE)
0.65
Classroom discussion (TGE)
0.82 Metacognitive strategies (TGE)
0..69 Self-verbalization and self-questioning (STE)
0.64
Source: Hattie, 2012, p. 266 / ES = Effect Size / STE = student effect / TRE = teacher effect / TGE = teaching effect / SLE = school effects / CME = curriculum effect
ElevenoftheinfluencesinTable2.4withthehighestESarelinkedtoteacheruse
offormativepractices(e.g.providingformativeevaluation,classroomdiscussion,
feedback,reciprocalteaching,andmetacognitivestrategies).Localvariationsofthe
curriculumeffect(CME)influenceswereobservedintheprogramsinsomeofthe
casestudyschoolsvisitedforthisproject.
2.6.4FormativePractice
AconsistentthemeinBlackandWiliam’sworkistheirinterestinestablishinga
theoryofformativeassessment“toprovideaunifyingbasisforthediverse
practicesthataresaidtobeformative”(BlackandWiliam,2009,p.7).Theirfirst
propositionisthatboththeteacherandstudentareresponsiblefortheoutcomes
fromthreekeyprocessesinteachingandlearning:
• establishingwherethelearnersareintheirlearning
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• establishingwheretheyaregoing
• establishingwhatneedstobedonetogetthemthere.
BlackandWiliambringthethreeprocessesandtherolesoftheagents(teachers,
peersandthestudentsthemselves)togetheronagridtogeneratefivekey
strategiesforconceptualisingformativeassessment:
• clarifyingandsharinglearningintentionsandcriteriaforsuccess
• engineeringeffectiveclassroomdiscussionsandotherlearningtasksthat
elicitevidenceofstudentunderstanding
• providingfeedbackthatmoveslearnersforward
• activatingstudentsasinstructionalresourcesforoneanotherandtheir
teacher
• activatingstudentsastheownersoftheirownlearning.(Black&Wiliam,
2009,p.8)
Theresearchersalsoprovideanupdateddefinitionofformativeassessmentthat
conflatesitwithinstruction:
Practiceinaclassroomisformativetotheextentthatevidenceabout
studentachievementiselicited,interpreted,andusedbyteachers,learners,
ortheirpeers,tomakedecisionsaboutthenextstepsininstructionthatare
likelytobebetter,orbetterfounded,thanthedecisionstheywouldhave
takenintheabsenceoftheevidencethatwaselicited.(Black&Wiliam,
2009,p.9)
Theresearchersexplainthatinstructionmeansteachingandlearningactivities
and,becausetheeffectof“decisionsaboutthenextstepsininstruction”isnot
certain,thequalificationof“likelytobebetterorbetterfounded”isanappropriate
qualificationforthosedecisionsandrelatedactionstoimprovelearning.
Forthepurposesofthisstudy,Ihavelinkedtogetherinthefollowingequation
eachofBlackandWiliam’s(2009)fivestrategiesofformativeassessmentand
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scienceteachingandcallthecombination,dimensionsofformativepractice.
Five Dimensions of Formative practice
= Formative assessment activity
+ Instruction in science
Thefirstdimensionofformativepracticeinvolvesactivitiesthatfocusonclarifying
andsharinglearningintentionsandsuccesscriteriarelatedtolearningscience
(LISC).
Theseconddimensioninvolvesclassroomdiscourseinsciencecontextsthatelicits
evidenceoflearning(CDEL).
Thethirddimensionfocusesonfeedbackused(byeitherorboththeteacheror
student)toprogressthelearningofscience(FTAL).
Thefourthdimensionisaboutactivatingstudentsasinstructionalresourcesfor
eachotherandtheteacherinsupportofsciencelearningandincludingpeer
assessment(ASIR).
Thefifthdimensioninvolvesactivatingstudents(andteachers)asownersoftheir
ownlearninginscienceandincludingself-assessment(ASTL).
Inthemethodologysectionofthisthesis(ChapterThree),theactivitiesrelatedto
eachdimensionarefurtherdifferentiatedintoteacherorstudent
focus/emphasis/agency.Thereasonforthisdifferentiationistoprovidean
operationaldefinitionforself-regulatedlearningconstructedintermsoftheextent
ofstudentagencywiththefivedimensionsofformativepractice.
2.6.5Formativepracticeandself-regulatedlearning
Black&Wiliam(2009)assignagencyforassessmenttoteachers,peers,and
individuallearners,saying,“Formativeassessmentisconcernedwiththecreation
of,andcapitalizationupon,‘momentsofcontingency’ininstructionforthe
purposeofregulationoflearningprocesses”(p.10).Anarrowfocusdistinguished
77
theformativeassessmentcomponentininstructionfromactsthatfollow,acts
drawingfromtheteachers’knowledgeof“instructionaldesign,curriculum,
pedagogyandepistemology.”(p.10).These‘momentsofcontingency’maybe
synchronous(immediatelyactedupon)orasynchronous(delayedaction).Tobe
effective,formativeinteractionshavetoresultinlearning.BlackandWiliam
(2009)citeSadler’sdefinitionoflearningas“theactivityofclosingthegap
betweenalearner’spresentstateofmindandthestateimpliedbythelearning
aim”(p.12).
Thefeedbackbyateachermaynotdoitsintendedjob(changecognition)unless
theteacherhassomeinsightorunderstandingofhow“studentsapproachproblem
solving,andhowtheyargue,evaluate,create,analyseandsynthesise”(Sadler,
1998,p.81).Thisreferstowhatteachersunderstandabouttheprocessesof
metacognitionthattheyandthestudentbringtotheprocessofmediation
occurringinthemiddlesectionofFigure2.4.
Figure 2.4 The three interacting domains of pedagogy (or instruction) Source: Black & William, 2009, p. 11
‘exit passes’), to plan a subsequent lesson. They might also include responses towork from the students from whom the data were collected, or from other students,or insights learned from the previous lesson or from a previous year.
The responses of teachers can be one-to-one or group-based; responses to astudent’s written work is usually one-on-one, but in classroom discussions, thefeedback will be in relation to the needs of the subject-classroom as a whole, andmay be an immediate intervention in the flow of classroom discussion, or a decisionabout how to begin the next lesson.
A formative interaction is one in which an interactive situation influencescognition, i.e., it is an interaction between external stimulus and feedback, andinternal production by the individual learner. This involves looking at the threeaspects, the external, the internal and their interactions. Figure 2 below serves toillustrate the sequence of the argument. The teacher addresses to the learner a task,perhaps in the form of a question, the learner responds to this, and the teacher thencomposes a further intervention, in the light of that response. This basic structure hasbeen described as initiation–response–evaluation or I-R-E (Mehan 1979), but thisstructure could represent either a genuinely dialogical process, or one in whichstudents are relegated to a supporting role.
Frequently, the teacher’s use of the I-R-E format involves the teacher askingstudents to supply missing words or phrases in the teacher’s exposition of thematerial—a form of extended ‘cloze’ procedure. During such interaction, theteacher’s attention is focused on the correctness of the student’s response—whatDavis (1997) terms “evaluative listening”, and subsequent teacher ‘moves’ are aimedat getting the student to make a correct response, through such encouragingresponses as, “Almost” or “Nearly”. There is ample evidence that this form ofinteraction is the norm in most classrooms (Applebee et al. 2003; Hardman et al.2003; Smith et al. 2004).
The model is meant to apply to more than one-on-one tutoring (which Bloom1984, regarded as the most effective model of instruction): the shaded area in thecentre stands for the classroom where many learners are involved, through hearingthe exchange, perhaps by joining in, so there would be many arrows in all directionsin this area. This aspect will feature in our later sections.
The process represented in Fig. 2 may be decomposed into several steps: one stepis the teacher’s interpretation of the pupils’ responses - this will be discussed inSection 4. The next is to decide on the best response: such decision is first of all astrategic one, in that it can only be taken in the light of the overall purpose for which
Teacher
Controller
Or
Conductor
Learners
Passive
Or
Involved
Fig. 2 The three interactingdomains of pedagogy
Educ Asse Eval Acc (2009) 21:5–31 11
78
Toexplaintheirtheoreticalmodelsofmediation,BlackandWiliam(2009)begin
byprovidingthedefinitionofself-regulatedlearningusedbyBoekaerts,Maes,and
Karoly(2005)whohadcompletedageneralreviewofthisfield:
Self-regulationcanbedefinedasamulti-component,multi-level,iterative
self-steeringprocessthattargetsone’sowncognitions,affectsandaction,as
wellasfeaturesoftheenvironmentformodulationintheserviceofone’s
goals.(p.150)
BoekaertsandCorno(2005)describea
dualprocessingself-regulationmodelwherelearninggoalsinteractwith
well-beinggoals[…]whenstudentshaveaccesstowell-refinedvolitional
strategiesmanifestedasgoodworkhabits,theyaremorelikelytoinvest
effortinlearningandgetoffthewell-beingtrackwhenastressorblocks
learning.(p.1)
Twopossibilitiesoperateinthiscontext.Oneisdescribedasatop-downSRor
growthoptionpathwaywhich
hasafocusonlearning[…]thestudentpursuesthepurposeofachieving
learninggoalsthatincreaseresources,i.e.knowledgeandbothcognitive
andsocialskills.Theprocessismotivatedandsteeredbypersonalinterest,
valuesandexpectedsatisfactionandrewards.(p.14)
Theotherpathwayisdescribedasthewell-beingoption,whichmaymanifestitself
asthelearnerchoosing
competitiveperformancegoalsorprioritis[ing]friendshipwithpeers,
whichafocusonlearninggoalsmayputatrisk.[It]maybetriggeredby[…]
sometypesofclassroomfeedbackandreward,ormerelybyboredom.
Whencuesfromtheenvironmenthavethiseffect,thissecondoptionis
adopted—thatofgivingprioritytowell-being.(p.14)
79
Inthecourseofalearningepisode,studentsmayseekoneorotherofthese
optionsandchooseattimestoswitchfromonetotheother.Thechoiceofoptionis
alsoinfluencedbythestudents“awarenessofandaccesstovolitionalstrategies
(metacognitiveknowledgetointerpretstrategyfailureandknowledgeofhowto
buckledowntowork)helplessness,andfailureofemotionalcontrol”(Vermeer,
Boekaerts,&Seegers,citedinBlack&Wiliam,2009,p.14).
2.6.6Learninghowtolearn,self-regulatedlearningandlife-longlearning
InLearningHowtoLearnandAssessmentforLearning:atheoreticalinquiry,Black
etal.(2006)write:
Theoverallconclusionisthatemphasisshouldbeplacedonpracticesthat
havepotentialtopromoteautonomyinlearning,acommonthemeinthe
literatureatalllevels,andonereflectedinourempiricalworkonteachers'
attitudesandpractices.(p.119)
Itisimportanttounderstandthatthenotionoflearninghowtolearnisalso
consistentwiththeeducationagendarelatedtoemployerswantingemployees
withskillsforwork(andlifemorebroadly)intheknowledgesociety.(OECD,
2003;CERI,2008).
Blacket.al.’s(2006)paperisanattempttobuildabridgebetweenwhatweknow
aboutteachingandlearningthatmightputstudentsinchargeoftheirown
learning.SeealsoDeakin-Crick,Broadfoot,andClaxton(2004);James(2006);
Jamesetal.(2007);Manselletal.(2009)andPellegrino(2009).
InthecontextofscienceeducationinAustralia,TheProjectforEnhancingEffective
Learning(PEEL),foundedin1985,anticipatedtheworkreportedonabove.Inthe
Australiancontext
PEELisaboutmakingsignificantchangesinhowstudentslearn—
generatinglearningthatismoreinformed,purposeful,independent,
interactive,andmetacognitive.(Mitchell,Mitchell,&Lumb,2009,p.1)
80
ThePEEL(2009)publicationPrinciplesofTeachingforQualityLearningdescribes
12principlesthatteachersusetoinstilgoodlearningbehaviours.Goodlearning
behavioursarethosethatoperationalisemetacognitionandself-assessment,
whicharepowerfulcontributorstolearninghowtolearn.Thelistofactivitiesand
theideasdevelopedbyscienceteachersandpublishedinPEELSEEDS(PEEL,
2009)aresimilarintypetothelistofactivitiesintheKing’s-Medway-Oxfordshire-
FormativeAssessmentProject(KMOFAP)(Black&Wiliam,2005).Thelistof
procedures(usingaPEELtermforlearningactivities)includes:
• sharingsuccesscriteriawithlearners
• classroomquestioning
• comment-onlymarking
• peer-andself-assessment
• formativeuseofsummativetests.
ThepointofdrawingattentiontoPEEListhatitisanexistingnetworkthatholdsa
considerablebodyofworkthatteacherscanaccessthemselvesastheytryto
improvestudentlearningbehaviourandautonomy.
2.7SOLOandtheESSA-VALID(EV)programinNSW
ThissectionwilldiscussSOLOasalearningprogression.Itwillexplainthe
thinkinginvolvedinitscreation,itsuseinscienceassessmentanditscontribution
totheEVprograminNSW.
2.7.1TheSOLOTaxonomy
TheSOLOTaxonomy(Biggs&Collis,1982)anditssuccessorSOLOmodel
(Panizzon,Arthur,&Pegg,2006)areexamplesofdevelopmentallearning
progressionsinthecognitivetradition(NRC,2001).TheoriginalSOLOTaxonomy
waspublishedbyBiggsandCollis(1982).Itwasdevelopedtoassistteachers
differentiatebetweenquantityandqualityinstudentresponsestoclosed,
classroomtestquestions.IntheiroriginalconstructfortheTaxonomy,learning
81
progressesthroughfivelevels,eachonerepresentingahigherleveloflearningas
explainedbelow.
Biggs&Collis(1982)wereconcernedthatstudentscouldscorehighlybysimply
writingdownanumberofrelevantresponses(quantity)withoutanyweighting
beinggiventowhetherthethinkingondisplaywasofahigherorder(whichBiggs
andCollisdescribedasquality)thansimplerecallofrelatedbitsofinformation.
BiggsandCollisexaminedBloom’soriginaltaxonomy(Bloom,Engelhart,Furst,
Hill,&Krathwohl,1956),Piaget’shypothecatedcognitivestructures(Ginsberg&
Opper,1979)andotherpost-Piagetianmodels(suchasthoseputforwardby
Marton&Säljö(1976);Schroder,Driver&Streufert(1967)andShayer(1976)as
thebasisfordescribingquality.
IntheendBiggsandCollis(1982)proposedanddevelopedanempiricalmodel
thatclassifiedanswersinlevelsaccordingtotheincreasingstructuralcomplexity
evidentintheanswers.Afterworkingwiththousandsofstudentwrittenresponses
totestitems,theydefinedcomplexityasincluding
progressionfromconcretetoabstract;usinganincreasingnumberof
organizingdimensions;increasingconsistencywithintheresponse;theuse
oforganizingorrelatingprincipleswithhypotheticalorself-generated
principlesbeingusedatthemostcomplexend.(p.14)
ThefirstversionofSOLOwasdevelopedandpublishedwithoutreferencetoa
traditionalsciencesubjectsuchasbiologyorchemistry(theclosestsubjectwas
geography).In1991BiggsandCollispublishedanupdatedversionofthe
Taxonomythattookintoaccountworkdoneonacademicandeveryday
intelligence,andonideasrelatedtomultipleintelligences,novice-expertresearch
andformsofknowledge(Biggs&Collis,1991).
BiggsandCollisthenshowedhowthisversionofSOLOcouldbeappliedto
categorisingrepresentationsprovidedbystudentsattemptingto“explain
phenomenawithasyetinadequatelydeveloped[scientific]constructsbyusing
alternativeframeworkstothoseusedbyscientists”(p.71).TheyusedBeveridge’s
82
(1985)workonevaporation,supplementedwitholderstudents’responsesto
identifythestructuralelementsinanswersthatexemplifiedthedifferentlevelsin
theSOLOTaxonomy.Figure2.5representsthisupdatedSOLOTaxonomy.
Figure 2.5 Representation of the Biggs & Collis (1991) SOLO Taxonomy (Source: Pegg, J., slide for a presentation at the ACER research conference, August 2010, in Melbourne)
FeaturesoftheSOLOTaxonomyincludemodesofrepresentation/thinking
(verticalaxis)thatareassociatedwithage-relatedchanges(horizontalaxis)in
studentcognitivefunctioning.Thesechangesenablestudentstoconstruct
differentlevelsofresponse(denotedbythelettersU-M-Rwithinamode)to
questionsusingtheknowledgeformsassociatedwiththatmodeofthinking(right-
handsidelabelswithinthemodes).
Table2.5includestheexamplesusedbyBiggsandCollis(1991)toillustratehow
thefeaturesofstudentresponseschangewithage(column2)andthefivelevelsof
learningdescriptorsstudentresponsesweremappedto.
0 112 6 16 21
Sensori-Motor
Ikonic
ConcreteSymbolic
Formal
Post Formal
– Uni-modal development Tacit
Intuitive
Declarative
Theoretical
Theoretical
Age (years not to scale)
Mode
Modes, Learning Cycles and Forms of Knowledge
Forms of Knowledge
Hig
her
Ord
er L
earn
ing
Low
er O
rder
Lea
rnin
g
U M
R
U M
R
U M
R
U M
R
83
Table 2.5 The concept of evaporation through modes of thinking and levels of thinking (SOLO Taxonomy) Mode Concept of evaporation Level of learning Postformal
U (EA) Developing and testing a new theory.
Formal
R Working understanding of the discipline of physics M Other physical concepts involving principles of energy, matter U (EA)The heat energy supplied speeds particles so that water changes state into steam. The latent heat is the amount of energy supplied
5. Extended abstract (EA)-generalizes the structure to take in new and more abstract features representing a new and higher mode of operation
Concrete symbolic
R The heat turns the water into steam and it evaporates off, remaining invisible in the atmosphere (15 yrs) M The flame makes the steam come and the water goes (9yrs) U (EA) It soaks into the pan (7 yrs)
4. Relational (R)-integrates the parts with each other so the whole has a coherent structure and meaning 3. Multistructural (M)-picks up more and more relevant or correct features but does not integrate them 2. Unistructural (U)-the learner focuses on the relevant domain and picks up one aspect to work with
Ikonic mode
R The steam causes the water to disappear (7 yrs). This does not happen at our house. There’s still water in the pan because my mum makes the tea with it (8 yrs) M You put the pan on top of the flame and the water goes U The flame does it (5 yrs)
1. Prestructural (P)-the task is engaged, but the learner is distracted or misled by an irrelevant aspect belonging to a previous stage or mode
The sensori-motor (mode) is not included here as it is related to motor-skills and, in this context, not knowledge of them. Source: Adapted from Biggs & Collis, 1991, p. 65 / 66 (Their tables 5.1 and 5.2)
Thefivestepscoveronelearningcyclecentredontheconcretesymbolicmode(the
‘targetmode’)whichisthemodemostrelevanttotheyearsofschooling.Notethat
theUlevelofonemodeistheEAlevelforthemodebelowit.
Themodesofthinkingmostrelevanttoschoolingincludethesensori-motor,
ikonic,concretesymbolicandformalmodes.Aschildrenage,theyareableto
accessmodesofthinkingorrepresentationsthatareprogressivelymorecomplex
andabstract.ThemodesintheSOLOTaxonomydonotprogressivelyreplaceeach
other(asPiagettheorised)butarecumulativeasexplainedbelow.
84
Whenattemptingtolearnanewskillset,suchasTaiChiforexample,analready
accomplishedbasketballplayermustbeginatthesensori-motorlevelbylearning
(imitatingandpracticing)thebasicfootmovesorhandandarmmovesofTaiChi.
Demonstratingeitheroneisaunistructuralresponse,demonstratingboth
separatelyisamultistructuralresponse,andputtingbothfeetandhand
movementstogetherwiththecorrectbreathingforoneTaiChi“move”isa
relationaldemonstration.Whentheaccomplishedbasketball-playingandnowTai
Chistudenttakestheirfirstdrivinglessonsometenormoreyearsafterstarting
school,heorshebeginsagainatthesensori-motormodetolearntheactions
involvedindrivingtothepointoffluentrelationalexecutionneededtocoordinate
themanydifferentcomponentskillsneededtopass,say,thesafeovertakingpart
oftheactualdrivingtest.
Fromaroundage18months,childrenareabletolinkactionswithimagined
representationsthattheyexpressinwordsanadultwouldinterpretas
“stereotypicalcharactersandobviousplots”(Biggs&Collis,1991,p.63).InTai
Chi,whiledemonstratingaseriesofmoves,alateprimary-agestudentmayuse
phraseslike“horse-ridingstance”,“strokethepeacock’stail”,“repulsethe
monkey”,forexample,asawayofrepresentingtheactionstothemselvesand
others(theseareactualexamplesfromaTaiChisupportcardusedwithallages).
Thismode,calledtheikonicmode,
isevidentintheintuitiveknowledgedisplayedin…scientists[forexample].
Kekule’srealizationofthestructureoftheorganicringcompoundwas
precededbyahypnogogicdreamofsixsnakeschasingeachothers'tails,
andonlylaterwashis"truth"establishedtothesatisfactionofthescientific
communitybyevidenceandargument.Theikonicmodeisthusnotmerely
apresymbolicmodeofinformationprocessingrestrictedtoearly
childhood.Itcontinuestogrowinpowerandcomplexitywellbeyond
childhood.(Biggs&Collis,1991,p.63)
Moststudentsbegintheirschoolingwiththis(ikonic)modeoflearningwell
developedatthemultistructuraland/orrelationallevelswithinthemode.Oral
85
expressionisdominant,butikonicdrawingsandphysicalmodelsrepresenting
peopleandthingsfamiliartothestudentmayalsobeproduced.
Fromaroundagesixyears,studentsbegintoshowconcrete-symbolicmode
thinking.Theknowledge,associatedthinkinganditsrepresentationwithinthis
modeisclassifiedasdeclarative,which
involvesasignificantshiftinabstraction,fromdirectsymbolizationofthe
worldthroughorallanguage,towritten,secondorder,symbolsystemsthat
applytotheexperiencedworld.Thereislogicandorderbetweenthe
symbolsthemselves,andbetweenthesymbolsystemandtheworld.The
symbolsystemsofwrittenlanguageandsignsgiveusoneofthemost
powerfultoolsforactingontheenvironment,andtheyincludewriting
itself,mathematicalsystems,maps,musicalnotation,andothersymbolic
devices.Masteryofthesesystems,andtheirapplicationstorealworld
problems,isthemajortaskinprimaryandsecondaryschoolingaccording
toanycurriculumtheory.Learningintheconcrete-symbolicmodeleadsto
declarativeknowledge,demonstratedbysymbolicdescriptionsofthe
experiencedworld.(Biggs&Collis,1991,p.63)
Intheirprogressthroughthismodefromincompetencetoexpertise,
learnersdisplayaconsistentsequence,orlearningcycle,thatis
generalizabletoalargevarietyoftasksandparticularlyschool-basedtasks.
(Biggs&Collis,1991,p.64)
Responsesobservedmayrangefromprestructural(notoperatinginthetarget
mode,whichisconcretesymbolicinthissituation)tounistructural(U)to
multistructural(M)torelational(R)withinthetargetmodeorabovethetarget
mode(formalmode),whereresponsesareclassifiedasextendedabstract(see
column3,Table2.5).BiggsandCollis(1991)summariseobservationsand
explanationsprovidedbystudentsrelatedtotheconceptofevaporationto
exemplifythefivelevelsofthinkingintheSOLOTaxonomy(seecolumn2,Table
2.5).
86
Bythetimestudentsreachage16years(inYears10or11),someareableto
accesstherepresentationaltoolsforformalthinking.Thedifferencebetweena
studentoperatingattheconcretesymbolicmodeandformalmodeasitwas
conceivedthenisillustratedinTable2.5(column2)usingtheexampleof
evaporation.Intheconcretesymbolicmode,explanationsaretiedtoconcrete
situationsandoperationaldefinitions(flamesorsunlightforenergy)foreffectsor
changesobserved.
Studentsoperatingintheformalmodeasitwasconceivedthenareabletomove
awayfromparticularconcretereferents(ice,wateror‘steam’andflames,sunlight,
electricity,coal,gas)todiscussevaporationandboilingintermsofa“moving
particle”modelwhereenergyisaddedtoortakenawayfromasituationcausinga
changeofstate(fromsolidtoliquidtogasandbackagain).“Thinkingintheformal
modethusbothincorporatesandtranscendsparticularcircumstances”(Biggs&
Collis,1991,p.63).
ByYear12anumberofstudentswillbeoperatingattheformalmode.Manymay
notentertheformalmodeofthinkingbythetimetheyleaveschoolat17or18
yearsofage.
2.7.2TheSOLOmodel
TheassessmentframeworkdevelopedfortheEVprograminNSWusedan
enhancedversionofthe1991versionoftheSOLOTaxonomy.CalledtheSOLO
modeltodistinguishitfromtheoriginalSOLOTaxonomy,theSOLOmodelincludes
asecondlearningcyclewithintheconcrete-symbolicandformalmodesof
thinking.LiketheTaxonomybeforeit,ithasitsrootsinempiricalevidencefrom
thousandsofwrittenresponsestotestquestions(Panizzon&Bond,2007).
Figure2.6representsthetwo-cycleconcretesymbolicmodeoftheSOLOmodel.
Theconcrete-symbolicmodeofthinkingisthedominantmodeofthinking
throughouttheyearsofschooling.
87
Figure 2.6. Representation of the “two cycles within a mode” SOLO model. Increasing age along the horizontal axis (L to R). Source: Pegg, J., slide from a presentation at the ACER research conference, August 2010, Melbourne.
Thehorizontalaxisrepresentsageinyears.Moststudentsenterschooloperating
intheikonicmode.Student’scapacitytouseandmasteryofthecognitivetools
associatedwiththeconcretesymbolicmodeofthinkingdevelopsovertheyearsof
schoolingthroughtwolearningcycles(thesecondcycleisatahigherlevelthan
theprecedingcycle).Inthejuniorsecondaryyearsstudentsacquirethelanguage
ofscienceconceptswhichtheyareexpectedtouseinexplanationsand
justificationsfortheconclusionstheycometo.
Atage16somestudentsbegintothinkusingabstractconceptsnotlinkedto
particularsituations(suchaspotentialenergy,propertiesoffields,latentheat,
electro-magneticradiation,mass,inertiaandmomentum).
A two-cycle diagram
88
Theneedtomodifythesinglelearningcycleapproachemergedfromanumberof
researchstudieswhereitwasbecomingincreasinglyobvious
thatasingleunistructural-multistructural-relationalcyclewithinamode
didnotaccommodateadequatelytherangeofresponsesofferedby
students.Inparticular,itwasdifficulttointerpretresponsesfrommany
primarystudents,low-achievingsecondarystudents,oradultsnewtoa
particularareaofstudywithinthesinglecyclemodel.(Pegg,Panizzon,
Arthur,Scott,&Aylmer,2011,p.24)
Itwasfoundintheirresponsesthat
anearliercycleoflevels(i.e.,anewunistructural-multistructural-relational
cycle)wasdiscerned.Interestingly,theresponsescodedattheselevelsstill
sharedcharacteristicsofthesamemode[...and]wereparticularlyrelevant
toprimaryandsecondaryeducationintheconcretesymbolicandformal
modes(p.24)
Thetwo-cyclemodelwassubsequentlyvalidatedbypsychometricmodelling
involvingRaschanalyses,andtheresultsofthreestudiestothatendwere
reportedinapaperbyPanizzonandBond(2007).Thetheoryunderpinningthe
SOLOmodelwasoriginallyshapedbyPiaget’sthinkingaboutdevelopmental
stages.However,PanizzonandBond(2006)refertoVygotsky’s(1978)socio-
cognitivetheories,andtheysuggestthatateachercanworkwithstudentsinways
thatsetupthesocialconditionsthatsupporttheemergenceofanew,highermode
ofthinkinginstudents.
2.7.3TheESSA-VALID(EV)assessmentframework
Whilethetestwasdeliveredasapenandpaperexercise(from2005to2010),the
assessmentframeworkdiscussedinthissubsectionwasbeingdevelopedand
validated.
89
Table2.6showsanextractoftheframework.Itshowshowthesyllabusoutcomes
(writtenandpublishedforthe2003sciencesyllabus)weresubsequentlyrelated
tothesixlevelsoftheconcretesymbolicmodeofthinkingintheSOLOmodel.
TwoexamplesoftasksareprovidedinAppendixD.Thefirstisataskrelatedto
heatingicefromthe2005EVpilottest;thesecondisataskaboutmagnetsfrom
the2008test.ThetasksaremappedtotheshadedoutcomesandrelatedSOLO
levelsasshowninTable2.6.
Table2.6andrelatedexplanatorymaterialdetailingthelinksmadebetween
syllabusandSOLOarereproducedasexamplethreeinAppendixD.
90
Table 2.6 Selected outcomes and related SOLO levels in the 2011 EV assessment framework LEVEL 1 LEVEL 2 LEVEL 3 LEVEL 4 LEVEL 5 LEVEL 6
Out
com
es 4
.1 to
4.5
(2
of 7
row
s)
Identify a scientific discovery
Compare scientific discovery to other types of discovery
Link a scientific discovery to its effect on humans
Describe a development in science that has led to new developments in technology
Compare the methods of the scientist to the design model of the engineer and architect
Explain the role of scientific thinking on society
Identify a possible career path in science
Identify a science context in a career
Link a career in science to knowledge and skills required
Identify science as a human activity
Discuss why society should support scientific research
Out
com
es 4
.6 to
4.9
(3
of 1
6 ro
ws)
Identify materials attracted by a magnet (example two)
Compare the observable effects when magnets are placed end to end
Link the observable effects when two magnets are placed end to end with their position
Describe a magnetic field as producing a force that attracts particular metals
Describe the poles of a magnet as the area/ends where the magnet’s field is most intense
Explain the behaviour of magnetic poles using the term field
Identify that objects / substances take up space and/or have mass/weight
Explain that materials are held together differently in solids, liquids and gases
Explain density in terms of a simple particle model
Identify an observable feature in melting, freezing, condensation, evaporation or boiling (example one)
Describe observable features in melting, freezing, condensation, evaporation and boiling
Explain that, when substances melt, freeze, condense, evaporate and boil, they are still made of the same stuff
Identify that particles are continuously moving and interacting
Compare movement and interaction of particles in different states
Explain change of state in terms of rearrangements of particles
Identify that as particles are heated they gain energy
Identify that as particles are heated they gain energy and move further apart
Relate changes of state to the motion of particles as energy is removed or added
No content for Outcomes 10 - 12 is included
Outcomes 4.13 to 4.15* (1 of 8 rows)
Make a simple observation
Compare observations made by different people
Explain strategies to increase accuracy of observation
Correctly sequence steps in a scientific procedure
Accurately and systematically record observations and data
Discuss the relationship between accuracy and reliability
Outcomes 4.16, 4.17 a-d & 4.18** (1 of 8 rows)
Use a simple key or symbol to represent a concrete object or representation
Distinguish between different symbols
Complete diagrams and symbolic representations
Correctly sequence steps in a process described in a text
Distinguish between two related sets of data / information
Represent relationships using keys, symbols and flow chart
Outcomes 4.17e-g, 4.19-4.21*** (1 of 7 rows)
Identify a common unit of measurement (example one)
Identify the ratio of one unit to another
Complete a correct conversion of one unit to another
Create a simple scale
Compare the scale on two axes
Create an appropriate scale
Source: NSW Department of Education and Training DET, 2011. Shaded rows are referenced in the body text. * Planning and Conducting Investigations area / ** Communication area / and *** Critical thinking area
91
2.7.4TheEVtest:“fitforpurpose”?
Theliteraturereviewedinthischapterdescribesthreebroadpurposesfor
assessment:toimprovelearning(formativeassessment);toassessprogressin
learning(summativeassessment);andtomonitoraspectsof,and/ortheoverall
effectivenessandefficiencyof,theeducationsystem.TheEVprogramprovides
feedbackonallthreepurposes.Feedback(intheformofresultsfromaoneoff
externaltest)isprovidedtostudents;theirparentsandcarers;theirteachers;the
schoolstheyattend;theeducationsystemauthorities;andgovernments.
Fensham(2013)describedtheEVtestdevelopmentprocessesascomparableto
thePISAprocesses,whichhesaidwereexemplary.Theinternationaltests,hesaid,
prioritisedreliability,whichinthiscasewasaboutensuringthatthescores
includedthemeasureofstatisticalcertaintyrelatedtothemeansscores.The
discussioninthelaterpartofthissubsectionwilldescribehowtheEVtest
developmentprocessesstriveforbothvalidityandreliabilityinanefforttobeas
fitforpurposeaspossible.
TheresultsfromtheEVtestareorganisedintoasummativereportofachievement
attheendofYear8.Thereportforstudents,parentsandteachersprovidesthe
resultsforfiveareasorcategoriesofoutcomes.Examplesandrelateddiscussionof
thisaspectoftheEVprogramareprovidedasexamplefourinAppendixD.The
scoresfromitemsintheEVframeworkmappedtotheCriticalThinkingarea(see
Table2.6)aredistributedtotheWorkingScientificallyandCommunicating
Scientificallycategories,dependingonwhethertheitemshadaninvestigatingor
communicatingcontext.Thestudentreportprovidesindividualfeedbackonevery
taskanditeminthetest.
TheformativeintentoftheEVprogramissignalledinthereporttoparentsand
students:
Students,parentsandteacherscanusethe[EV]levelstoplanlearning
programsandactivitiessothatstudentskeepmovingforwardintheir
scienceknowledgeandskills.(NSWDET,2007,p.3)
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ThelevelsreferredtoarethesixlevelslinkedtotheSOLOmodeldiscussedabove.
Progress(“movingforward”intheEVreport)insciencelearningisdefinedbythe
languageusedineachoftheleveldescriptionsforaparticularreportingcategory.
Ofinterestintheearlydaysoftestingwastheoverallconcernexpressedby
teachersthatthetestwastoomuchaboutreading,whichintheirviewwasgetting
inthewayof‘seeingthescience’questions.TheresultsfromthestudentEVsurvey
showedthatstudentsactuallyenjoyedthetestandstimulusmaterialandtheydid
notthinkitdistractedthem(seequestionsinthelastsectionofthesurvey).
Articlesthatteacherssawasbeing‘toodifficult’,moststudentsenjoyeddoing.
Oneoftheintentionsofassessingthiswaywastoputahighvalueongetting
studentstoreadsciencerichtextsandtoidentifythesciencecontent.Students
stronglyagreedthat“literacyisimportantinlearningscience”(thirdquestionin
thesurvey).Detailedfeedbackfromselectedcasestudyschoolsonsomeofthe
surveyitemsisprovidedinChapter6.
AccordingtoMessick(1995),“Constructvalidity[inprincipleandpractice]is
basedonanintegrationofanyevidencethatbearsontheinterpretationor
meaningofthetestscores”(p.742).Theprocessesusedtodevelopitemsandtasks
fortheEVtestprovidearepresentativecoverageofsyllabusintentions(mappedto
theEVassessmentframework),andtheresponsesitemselicitfromstudentsare
evaluatedbyexperiencedteachersforalignmentwithintendedlearningas
describedinthesyllabus.
Currentpsychometricmethodsareusedtomonitortheconsistencywithwhich
markingrubricsareappliedduringtheactualmarkingprocessandinreviewing
theresultsofpilotmarking.Theanalysisofscoringoftheextendedresponseitems
“utilisestheRaschUnidimensionalMeasurementModel(RUMM)…andthe
InteractiveTestAnalysisSystem(QUEST)”(Peggetal.,2011,p.36).Itemsand
tasksthatdonotmeetthecriteriaforinclusioninthetestarediscardedor
modifiedforpilotingthefollowingyear.
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TeacherswhohavehadexperienceteachingYear8students(butarenotcurrently
doingso)wereinvitedeachyeartoexpressaninterestindevelopingitemsand
tasksforthetests.Agroupcomprisingteacherswithpriorexperienceandsome
whoarenewisselected,andafterattendingaone-daytrainingworkshoptheyare
askedtowriteitemsandtasks,forwhichtheyarepaidbytheDepartment.
Theworkshoptakeswritersthroughthecriteriaforselectingappropriatestimulus
materialandwritingrelateditemsrelatedthataddresssyllabusexpectations
(outcomesandrelatedessentialcontent)forStage4students.Writersarealso
takenthroughtheSOLOmodelandshownexamplesofitemsandtasksrelatedto
thetwocycleswithintheconcretesymbolicmodethatareexemplarsofitemsand
tasksusedinprevioustests.
Theitemsandtasksproducedarecollected,assessedandeitherdiscardedor
editedbyofficersintheEVtestdevelopmentunitoftheDepartment.Surviving
stimulusmaterialsandrelatedsetsofitemsareedited,mappedagainsttheEV
assessmentframeworkandcollateduntilmorethanenoughforonetestare
available.Theseitemsarethenreviewedbyanexpertpanelofteachersdrawn
fromarangeofspecialistareaswithintheDepartmentincludingAssessment,
Equity,KeyCompetencies,AboriginalandTorresStraightIslanders,Language
BackgroundsOtherthanEnglish,andLiteracyandNumeracy.Examplesoftest
items,relatedstimulusmaterialsandthestudentsurveyareincludedatexample
fiveinAppendixD.
Severaldifferenttestsusingamixofitemsandtasksarecompiledandsentofffor
piloting.Intheearlystages,pilotingwasdonewithstudentsintheirsecondyearof
secondaryschoolinginthevariousstatesofAustralia.Nowitisdoneearlyinterm
oneofthenewschoolyearwithstudentswhodidthetestinthepreviousyear.
Pilotingensuresthattheitemsandtaskswithpoortestcharacteristics
(discrimination,difficulty,ambiguity,constructvalidity)areidentifiedand
discardedfromfurtherconsideration.Markingrubricsforthethreeextended
responsequestions,developedbyexperiencedscienceteacherswithSOLO
expertise,arerefinedduringthepilotmarkingprocess.
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Experiencedscienceteachersarecontractedtoscoreonlinethethreeextended
responsequestions.Theyareprovidedwithuptofourhoursoftraininginthe
SOLOmodelandtheconsistentapplicationofthemarkingrubricsbeforeactual
markingcommences.Themarkingprocessiscontinuouslymonitoredonlineto
ensureconsistencyofrubricapplication.Everyhour,allmarkersofaparticular
questionarepresentedwiththesamestudentresponseandtheirscoresare
checkedtoensureconsistency.Thecheckmarkingisdoneusingstudentresponses
thathighlightparticularscoringissuesthatemergedduringpilotmarking.
Thetestincludesmultipleitemstargetingthesameconstruct.Thisistoimprove
reliabilityofinferencesaboutthatconstruct.Intheend,theinterpretationofhow
manyitemsareneededtoachieveareliableinferenceisajudgmentcall.In
addition,itemsfrompreviousyearstestsareincludedtoenableequatingoftest
resultsacrosstheyearsoftesting.Theequatingprocessusessamplesofitems
distributedacrossthetesttakenbythewholecohortsothattheriskofaschool
seeingitemsithasusedbeforeinitsowntestingisveryunlikely.
AsPISA,TIMSSandNAP-SLtestsareconsideredhighstakestesting,intheinterest
offairnesstoall,equatingitemsarenotreleased.Testpapersareretainedatthe
endofthetestsessionsandsentbacktothemanagingagencyafterthetestsare
completed.Onlinedeliverymakessecurityarounditemseasiertoensure(asfor
NAP-SLtestingin2015).Examplesoftestitemsnotretainedforequatingpurposes
werepublishedinthereportssomeonetotwoyearsafterthetestingwas
completed.Fensham(2013)hasexpressedaviewthatmoreoftheTIMSSandPISA
itemsshouldbereleasedtoprovidegoodassessmentmodelsforschoolstouse.
ThenextsubsectionexamineshowSOLOhasbeenusedinAustraliaandNew
Zealand.
2.7.5SOLOandassessmentinAustralasia
SOLOtheoryhasbeenusedinthedesignofassessmentframeworksforlargescale
testinginAustralasiasincetheearly2000s.IthasbeenusedinscienceinAustralia
andforreading,writingandmathsinNewZealand.
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The1991versionoftheSOLOTaxonomywasusedbytheACERtodevelopthe
ScientificLiteracyProgressMap(SLPM)(ACER,2004b).TheSLPMwasinitially
developedasatoolforcategorisingassessmentitemswrittenfortheScience
EducationAssessmentResource(SEAR)(ACER,2004a,).Itemsandandtasksfrom
thisprojectareavailableonlinetoscienceteachers(ESA,n.d./Improve).
TheSOLOTaxonomywassubsequentlyusedtodeveloponeofthestrandsinthe
assessmentframeworkforthenationalYear6sciencetest(ACARA,2014a).It
providedthelanguageforthescaleusedtodescribethechangeinqualityof
studentanswersfoundinstudents’answerstotheitemsandtasksintheYear6
test.
TheSOLOTaxonomyisutilisedintheassessmentandreportingframeworkforthe
NewZealand-basede-asTTleprojectthatprovidesassessmentitemsforreading,
writingandmaths.ItemsareclassifiedagainsttheNewZealandnational
curriculumandthefivelevelsintheSOLOTaxonomy(Hattie&Brown,2004).
SOLOwasconsideredforinclusioninthePISA2015assessmentframeworkas
disussedabove.AsfarasIamaware,SOLOtheoryisnotusedanywhereelseinthe
contextoflarge-scaletestingofscienceinCanada,NewZealand,theUKortheUSA.
2.8Themesfromtheliteraturereviewandtheirrelevancetothisthesis
Aneedtoliftandbroadenthelevelofskillsstudentsacquireinthefirstphaseoftheir
education.
Thedemandsoftheknowledgesocietyandtherelatedknowledge-basedeconomy
requireaworkforceabletoadapttochangingopportunities.Todothis,people
needtokeeplearningascircumstanceschangeovertheirlifetime.Thisrealisation
hasledtotheunderstandingthatleavingschoolistheendofthefirstphaseof
preparationforalifethatwillrequirefurtherepisodesofformallearningor
trainingatleasttoensureongoingaccesstoemployment.
Employersaretellinggovernmentsthattheyneedgraduatesfromthisfirstphase
ofschool,traininganduniversitywhohaveabroaderrangeofskills(both
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cognitiveandsocial)andhigherlevelsofskillthanbefore.Expertiseisnotjust
aboutknowing,itisaboutbeingabletousethatknowingintheworkplaceand
beyondtosolveproblemsandexplainthosesolutionstoothers,andtoboth
quantifyandqualifytherisksinvolvedinimplementingdifferentoptions.These
issueshavebeendealtwithinanumberofOECDreportsincluding(OECD,
1997);(CERI,2008).
Educationagencieschargedbygovernmentstoproducethecurriculumforschools
inAustraliahaveretainedacorecurriculumforallstudentsuptotheendofYear
10broadlydefinedineightlearningareas,includingscience.Thescience
curriculumatthetimeofinterestforthisproject(uptotheendof2014)consisted
ofknowledgeandunderstandingsdrawnfromthemodels,theoriesandlaws,
structures,systemsandinteractionsunderpinningtraditionaldisciplinesof
scienceandtheskillsof“workingscientifically”(BOS,2003,p.21)inaboutequal
measure(10ofthe22outcomesareskills).
Inrecognitionoffallingstudentengagementandinterestinsciencestartingat
school,butparticularlysointheearlyyearsofsecondaryschooling,changeswere
madetothecurriculum.The2003curriculuminNSWrequiredscienceteachersto
providecontextsforlearningaboutscienceandinwhichtodoscience.The
prescribedcontextsinNSWweretodowiththehistoryofscience,thenatureand
practiceofscience,theapplicationsofscienceandimplicationsofdoingso
includingcurrentexamplesandworkinvolvingscience.
Teacherswerealsorequiredbythatcurriculumtousescienceresourcesto
providestudentswiththeopportunitytoacquiretheKeyCompetences,develop
skillsintheuseofICT,workaloneandinteamssafelyandinclusively(considering
genderandculturaldifferences),acquiresomeunderstandingandappreciationof
AboriginalandTorresStraitIslanderPeopleworldviews,acquiresome
understandingandappreciationofhowscienceimpactsourciviclifeandthe
environmentandtoimprovetheirgeneralliteracyandnumeracyskills.
Totheextentpossible,giventhebreadthofexpectations,thescopeanddepthof
whatwastobelearnedwasdescribedinbundlesoflearningframedasoutcomes.
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Outcomesweredefinedbyaminimumnumberofactionsandcontextsfortheir
acceptableperformance.Theoutcomesdescribedahierarchyoflearning(inaset
ofstandardsfortwostagesinthejuniorsecondarycurriculum)thatstudentswere
expectedtoengagewithandacquire.Years7and8comprisedonestageandYears
9and10thesecondstage.Twenty-twooutcomesprovidedthescopeanddepthof
expectedlearningsinscienceattheendofYear8andagainattheendofYear10.
Teachersareexpectedtoassessstudentachievementoftheseoutcomesand
reporttoparentsonprogressintheirlearningtwiceayear.
Assessmentasananswertohigherexpectations.
NSWhadtwoexternalpenandpapertestsastheprimarymeansforsatisfying
stakeholdersoftheextenttowhichstudentshadacquiredtheexpectedlearnings,
oneattheendofYear10andtheotherattheendofYear12.Noneoftheother
statesandterritorieshadaYear10sciencetest.WhenNSWintroducedtheYear8
sciencetestfrom2007itwastheonlystatetodoso.Queenslandintroduceda
scienceassessmentprogramin2009forYears4,6and9,butabandoneditatthe
endof2012(QSA,2012).WesternAustralia,introducedasciencetestforits
studentsinYears5,7and9from2010(SCSA,2010)andabandoneditafter2013.
AssessmentinthejunioryearsofsecondaryschoolinNSWwas,andstillremains,
theresponsibilityofscienceteachers.Theyweresupportedinthattaskas
discussedaboveinearliersectionsofthischapter.
Goodrumetal,(2001)reportedintheirreviewthatinsecondaryschoolsacross
Australia
Traditionalassessmentpracticesremainasoneofthemostsignificant
barrierstoeducationalreforminsecondaryschoolswhereteachersare
requiredtocovertoomuchcontenttopreparestudentsfor“thetest”.
Teachersindicatethattestsarethemostcommonformofassessmentand,
onaverage,represent55%oftheweightingofassessment[…]Assessment
is[…]typically,summative,norm-referencedandfocusedoncontent.
Students[report]thatquizzesarefrequentlyusedtoprovidefeedbackto
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[them],howeverone-thirdofstudentsindicatethattheirteachernever
spoketothemabouthowtheyweregoinginscience.(p.155)
ItisfairtosaythatNSWscienceteachershadastrongertraditionofexternal,
summativetestingembeddedintheirculturethanotherstatesandterritoriesasis
elaboratedbelow.
GiventhecontinuationwithexternaltestingforallstudentsinNSWinYears8and
10(upuntiltheendof2011)andcontinuingtothisdayattheendofYear12,itis
likelythatthefindingsin2000mightstillapplyinmanysecondaryschoolsinNSW
today.Astheevidencefromcasestudyschoolsinthisprojectshows,testsarea
dominantformofassessmentinscienceinYears7and8tothisday.However,that
assessmentisnowmuchmorefocusedonthefullrangeofoutcomesandtheshift
towardthethreeboldedindicatorsofbetterassessmentpracticelistedinTable2.1
iswellunderway.
AroleforSOLOtoinformfeedbackaboutprogressinlearning.
AsthediscussionabouttheEVtestindicated,theuseofSOLOtoprovidean
additionalcomponentoffeedbackaboutthelevelofunderstandingdemonstrated
bystudentsintheiranswerswasvindicatedbyPISA2015testingthathaditemsin
itdesignedtoprovidefeedbackonthelevelofscientificliteracydemonstratedby
students.However,workintheUSandelsewhereonhow(toassessthefullrange
ofhigherlevelsofcognitivefunctioningexpectedofstudents)hasyettobe
demonstratedasRuiz-Primorevealsinher2009reporttotheUSNational
ResearchCouncil.
Ruiz-Primo(2009)wasaskedbytheUSNationalResearchCounciltoprovidea
paperthatreconciledtwenty-firstcenturygenericemployment-relatedskills
(NRC,2008)andcompetenciesatthecoreofscienceeducation(Duschl,
Schweingruber,&Shouse,2007).Herfirstcommentwasthatexpertiseislocated
inaknowledgedomain(scienceandtechnologyinthiscase).Shethengoesonto
elaboratethatsuitablesciencecontextsneedtobedescribedtoassesstheextent
towhichstudentshaveacquiredthefollowingtypesofknowledge:
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1. Declarativeknowledge–knowingthat
2. Proceduralknowledge–knowinghow
3. Schematicknowledge–knowingwhy
4. Strategicknowledge–knowingwhen,where,whyandhowtoapply
knowledge
5. Metacognitiveknowledge–knowingaboutone’scognitionandhowto
regulateone’scognition(withmetacognitivestrategies).(pp.24-25)
HavingreviewedtheassessmentframeworksforTIMSS,PISAandtheUS,
CollegiateLearningAssessment(CLA)andNationalAssessmentforEducational
Progress(NAEP)sciencetests,shesaidthatnoneofthecurrenttestsprovide
evidenceforjudgingthedegreeofproficiencywithalltheseformsofknowledge.
However,sheexpressesthebeliefthataccesstoappropriatecomputer-based
technology(simulations)shouldenableteststhataccessallformsinthefuture.In
thebroadschemeofthings,theinclusionofSOLOintheEVtestsforNSWstudents
(andWebb’sDOKlevelsinthePISA2015test)isamodestbeginningtohelping
teacherssupportstudentacquisitionofthehighestlevelsofatleastoneofRuiz-
Primo’s(2009)fivetypesofknowledge,declarativeknowledge.
ThefivetypesofknowledgedescribedbyRuiz-Primo(2009)rangewellbeyond
cognitivefunctioningtoincludepurposefulactivitywithotherpeopleand
applicationofexpertisetodoing.Assessingperformanceinauthenticsettingsis
thepreferredoptionhere(Matters&Curtis,2008).Choosingcorrectoptionsfrom
abatteryofmultiplechoiceitemsisnotgoingtobeseenasanauthentic,validor
reliabledemonstrationofexpertiseneededinthe21stcenturybymembersofthe
ARGorresearcherswhoholdsituativeorsocioculturalperspectiveonlearning
(Billett,1996;Cowie,2013;Gipps,1999;Lemke,2001;Tobin,2012),orbythe
widercommunity(Hattie,2005).Norisitavaliddemonstrationoftheuseof
expressivelanguagetoconstructascientificreport,explanation,orprocedure,or
forthejustificationofacourseofaction.Actualuseofexpressivelanguageto
representknowledgeandunderstandingindifferentlearningdomainshasledtoa
viewofscienceasamulti-literacy(Hackling,Peers,&Prain,2007;Hand,Yore,
Jagger,&Prain,2010;Tytler&Prain,2010;Waldrip,Prain,&Carolan,2010).This
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viewofscienceisdiscussedinthenextchapterandusedtojustifytheuseof
NAPLANresultsasavalidpredictorofscientificliteracyasmeasuredintheEV
test.
Theneedtoteachstudentshowtolearnsotheycanbecomeindependentlearners
Theresearchliteraturediscussedinthischapterhasidentifiedthatwhatteachers
dowithstudentsinthenameofscienceeducationaccountsfor30%ofthe
variabilityinachievement(Hattie,2003b).Whatstudentsbringtotheclassroom
bywayofnaturalability,priorschoolexperiencesandfamilybackgrounds
accountsfor50%ofthevariability.Theremaining20%isattributabletohowwell
theschoolenvironment(leadership)ismanagedtoenhancethepositiveinfluences
andminimisethenegativeinfluencesontheoveralllearningofscienceinthe
schoolsetting.
Itfollowsthatsupportingteacherstodothebestjobtheycanislikelytohavethe
mosteffectonstudentlearningandengagementwithscience.Hattie(2005)has
shownthatteacheruseofformativepracticesisoneofthemosteffectivewaysto
improvestudentachievement(asmeasuredbylarge-scaletestresults).Other
worklookingathowtoteachstudentsto“learnhowtolearn”(LHTL)concludes
that“emphasisshouldbeplacedonpracticesthathavepotentialtopromote
autonomyinlearning”(Blacketal.,2006).Oneapproachtodoingthisistoteach
studentshowtolearnbyprogressivelygivingthemcontrolandownershipofthe
strategiesofformativeassessment.Knowinghowtolearnandbeingmotivatedto
doso(self-regulation)isprobablythemostimportantoutcomeforschooling.
Theassumptionthatthiscapacityforself-regulationwouldshowupinsubsequent
achievementinandengagementwithsciencebeyondYear8underpinnedthethird
subsidiaryresearchquestioninthisresearchproject.Thatquestionwas:Istheuse
offormativepracticesbyteacherslinkedtoimprovementinstudents’EVresults
andlaterachievementinandengagementwithscience?
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Summarycomments
Thisprojectisabouttheassessment-relatedworkofscienceteachersintheearly
yearsofsecondaryeducationinalargegovernmentschoolsysteminoneofthe
mostadvantagedanddevelopedcountriesintheworld(OECD,2018;UNDP,
2018).Itexplorestheimpactoftwoassessmentinitiativesonteachers
assessment-relatedworkalmostadecadeaftertheywereputinplace.The
constructsforfive“dimensionsofformativepractice”arethewindowsthrough
whichthatworkcanbeexamined.
Broadfoot(2009)impliesthatweareatatippingpointinourcollective
understandingandapplicationofassessment:
Thepurposeofassessmentduringthe20thcenturyhasbeen
overwhelminglythegenerationofsummativedata.Thecontentaddressed
hasconcernedprimarilycognitivetasks.Themodehasbeenthelargely
traditionalvehicleofpaper-and-penciltestsandtheirorganisationthrough
largetestingandassessmentproviders…Coulditbe,finally,thatthegrand
narrativesofintelligenceandability,whichwereregardedasthekeytothe
determinationoflifechances,arebeginningtoyieldtoamorepractical
discourseofmultipleexperiences,skills,knowledgeanddispositions?(pp.
x-xi)
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CHAPTERTHREE:RESEARCHDESIGN,METHODOLOGY,METHODS
3.1Introduction
ChapterTwoprovidedanoverviewoftheliteraturerelatingtoassessment
generallyandformativepracticesinparticular,alongwiththeconceptofa
learningprogressionandSOLOtheory.Italsoreviewedworkbeingdonewith
formativepracticesasawayofimprovingstudentcapacityforself-regulated
autonomouslearningtoequipthemforlifelonglearning,thelatterbeingahighly
sought-afteroutcomeforeducationinthe21stcentury.ThedevelopmentofSOLO
theoryfromTaxonomytomodelanditsuseintheEVprograminNSWschoolsand
beyondwasoutlinedaswell.
Thischapterdescribesandexplainstheresearchdesignandthemethodsusedto
collectdataandinformationtoanswerthethreeresearchquestionsposedin
ChapterOne.Thequestionswere:
1. WhatusearescienceteachersmakingoftheEVprogramincludingSOLO
andwhyisitusedornotused?
2. Whatformativepracticesareevidentintheworkofscienceteachersand
whyaretheyusedornotused?
3. Istheuseofformativepracticesbyteacherslinkedtoimprovementin
students’EVresultsandlaterachievementinandengagementwith
science?
Section3.2providesarationaleforemployingamixedmethodsresearchdesign
involvingthreephases.Phasesoneandtwoinvolvedquantitativemethods.The
thirdphaseemployedquantitativeandqualitativemethodsinthecontextofcase
studies.
Section3.3describesthefirstphaseinwhichaquantitativemethodwasusedto
deliverasampleofschoolstoworkwith.Thequantitativemethodwasa
regressionanalysisusingdataprovidedbytheDepartmentfor394government
secondaryschoolsinNSW.Aswillbeexplainedinthissection,theresidualsfrom
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thatregressionanalysiswereusedasameasureofthescientificliteracy
componentofEVtestresultsandasameasureoftheeffectsizeofscienceteaching.
Onthebasisoftheschoolresidual,EVresultsforstudentsataschoolwere
designatedaswellaboveexpectation(WAE),atexpectation(AE)andwellbelow
expectation(WBE).
Section3.4describesthesecondphasethatalsoinvolvedusingaquantitative
methodology.WhilsttheresidualswereindicatorsofEVresultsabove,atorbelow
expectationandoftherelativesuccessofscienceteaching,theresidualssay
nothingabouttheteacherpracticesassociatedwiththoseresults.ANOVAwas
usedtotestforstatisticallysignificantrelationshipsbetweenaspectsofthe
assessment-relatedpracticesusedbyteachersandEVresultscategorizedasWAE,
AEandWBE.
Section3.5explainsthethirdphaseinvolvingcasestudiesofassessment-related
workpracticesinself-nominatedgovernmentschoolsciencedepartmentsandof
teachersworkingthere.Quantitativedataaboutstudentresultsandnumbersof
studentscompletingYear12sciencecourseswereobtainedfromteachersatthe
casestudyschools,thestatecurriculumauthority’swebsite(theBoard)andthe
MySchoolwebsiterespectively.Qualitativedatawerealsocollectedfromteachers
intheformofaudio-recordedinterviewsandartifactsofassessment-related
practice.Narrativesdescribingtheassessment-relatedworkdonebyscience
teachersateachofthecasestudyschoolswereconstructedusinginterpretive
methodology.
ItwasproposedattheendofChapterTwothatdatacollectedtoanswerresearch
questionthreecouldbeusedtotestthepropositionthatstudentsexposedto
formativepracticesmightbebetterself-regulatedlearnersthanthosenotso
exposed.Section3.6discusseshowdatafromtheMySchoolwebsitewasaccessed
andusedtoconstructabasisforcomparingschoolsinordertotestthree
predictionsdesignedtoprovidefindingsrelevanttoansweringthesecondpartof
researchquestionthree.Statisticalcorrelationsweredonetoassessesthestrength
ofassociationbetweenachievementandengagement.
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Section3.7discussesthelimitationsarisingfromtheresearchdesignandmethods
usedinthisproject.
3.2Mixedmethodresearch,casestudiesandresearchdesign
Johnson,Onwuegbuzie,&Turner(2007)definemixedmethodsresearchas:
thetypeofresearchinwhicharesearcherorteamofresearcherscombines
elementsofqualitativeandquantitativeresearchapproaches(e.g.,useof
qualitativeandquantitativeviewpoints,datacollection,analysis,inference
techniques)forthebroadpurposesofbreadthanddepthofunderstanding
andcorroboration.(p.123)
Followingareviewofmanypublishedstudies,CreswellandPlanoClark(2011)
proposedsixmixed-methodsresearchdesigns:
1. convergentparalleldesign
2. explanatorysequentialdesign
3. exploratorysequentialdesign
4. embeddeddesign
5. transformativedesign
6. multiphasedesign.
Creswell(2012)characterisesthefirstfourofthesedesignsas“basic”andthelast
twoas“complexdesignsthatarebecomingincreasinglypopular”(p.540).The
explanatorysequentialdesignmethodcollectsquantitativedatafirstandthen
drawsonqualitativedata“tohelpexplainorelaborateonthequantitativedata”(p.
542).Creswellarguesthatexplanatorysequentialdesign(number2inthelist
above)canbecomeatransformativedesign(number5).Thedesignbecomes
transformativewhentheexplanatorysequentialdesignisembeddedwithinan
overarchingframeworkthat
informstheoverallpurposeofthestudy,theresearchquestions,thedata
collection,andtheoutcomeofthestudy.Theintentoftheframeworkisto
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addressasocialissueforamarginalizedorunderrepresentedpopulation
andengageinresearchthatbringsaboutchange.(p.546).
Thisresearcherintendsattheconclusionofthisstudytoprovidefeedbacktoall
participantschools.Thesocialpurposehereistoassistschools,particularly
regionalschoolswheretestresultsinsciencedonotappeartobeasstrongoverall
astestresultsareinmetropolitanschools.AccordingtoFlyvbjerg(2011),case
studiesprovidethe“concrete,context-dependentknowledge…necessarytoallow
peopletodevelopfromrule-basedbeginnerstovirtuosoexperts”(p.302).Acase
studyconductedonanumberofphysicallyseparatedsiteshasbeenalternatively
definedbyotherresearchersasamultiple(Stake,2005)orcollective(Yin,2003)
casestudy.Giventhatoneofthepurposesfordoingthisstudyistoprovideschools
withfeedbackaboutpractices,casestudiesprovideapotentiallypowerfulvehicle
fordoingso.
ForFlyvbjerg(2011),
(t)hedecisivefactorindefiningastudyasacasestudyisthechoiceofthe
individualunitofstudyandthesettingofitsboundaries…notsomuch
makingamethodologicalchoicebutachoiceofwhatistobestudied.(p.
301)
Theunitofstudyhereisthesetofassessment-relatedpracticesusedbyscience
teacherswiththeirjuniorsecondarysciencestudentsingovernmentschoolsand
evidenceoftheimpactofthesepracticesonscienceachievementandengagement,
bothofwhichwillbedefinedinthenextsection.Theboundariesofthestudywere
delineatedbyfiveconstraints:
1. manageabilityofsamplesizefortheresearcher
2. purposiveselectionrequirements
3. availabilityofvolunteerparticipants
4. availabilityofrelevantcontent
5. manageabilityforschoolparticipants.
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First,theresearchwasconstrainedbythenumberofschoolsabletobeengaged
withbyasoloresearcher.While18schoolswereidentifiedandconsidered
manageable,intheendonly16werevisitedduetotimeandotherconstraints.
Second,theschoolsvisitedwerepurposivelyselectedonthebasisoftheirresidual
ranking.Theaimwastoworkwithschoolsasclosetothetop,middleandbottom
ofthethreeschoolgroupsthatcouldbeattainedgiventhenextconstraint.
Residuals,residualrankingandpurposiveselectionwillbeexplainedinthenext
section(section3.3)
Third,eachparticipatingscienceteacherhadtobeavolunteerandhavethe
supportoftheirdepartmentheadandschoolprincipal.Researchfindings,inthe
eventofpublication,hadthepotentialtobeconfrontingsoconsenttocollect
informationwasaskedforontheconditionofanonymityforschools,teachersand
students.
Fourth,schooldatasets,audio-recordedinterviewsandteacher-provided
assessmentartifactsallhadtoprovidecontentrelevanttoorproducedinthe
periodofinterest(2011-2014)asexplainedinChapterOne.
Fifth,thedata-gatheringexerciseshadtobemanageableforschool-based
participantsandseenasworthwhilefromtheirperspective.Thisentailedthe
researcherbeingflexibleinrelationtohisexpectationsofparticipants.
Tosummarise,thethreephasesoftheresearchdesignandmethodsdelivered:
1. threegroupsofschoolsdifferentiatedfromeachotherbyan
unconventionalmeasureofscientificliteracyattainment(aquantitative
PhaseOne)
2. findingsaboutscienceteacherengagementwiththeEVprogram(including
SOLO)andformativepracticesbasedontheanalysisoftheirresponsestoa
commononlinesurvey,initiallysortedaccordingtothegroupofschoolsthe
responsescamefrom(aquantitativePhaseTwo),
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3. dataandinformationaboutstudentachievementinandengagementwith
scienceuptotheendofYear12plusinformationaboutassessment-related
practicesinthesciencedepartmentsofthe16casestudyschools
purposivelychosenfromeachofthethreegroupsofschools(aquantitative
andqualitativePhaseThree).
3.3PhaseOne:selectingthesampleofschoolstoworkwith
Bryman(2012)identifiesnineapproachestopurposivesampling,oneofwhich,
maximumvariationsampling,hedescribesas“samplingtoensureaswidea
variationaspossibleintermsofthedimensionofinterest”(p.419).Flyvbjerg
(2011)arguesthatbychoosing“maximumvariationcases”(p.306)aresearcher
hasthebestchanceofidentifyingfindingsthatareeitherconsistentorinconsistent
withpredictionortheory.Thedimensionofinterestinthisphaseofthestudyis
thescientificliteracyattainmentofstudentsataschool.Thegoalwastoselecta
sampleofschoolscomprisedofthreegroupswhosestatisticalmeansforthe
measureofscientificliteracyattainmentwereasdifferentaspossible.
Aswillbeexplainedlaterinthissection,astudent’sEVtestresultsareafunction
oftheirgeneralliteracyandnumeracyskillsandtheirdispositiontoapplythemto
learningscience.Whileastudentacquiresscientificliteracyfrommanysources,
theEVtesttargetsthescientificliteracyexpectationsdescribedinthescience
syllabusthatscienceteachersareexpectedtoteachstudents.
Thequantitativemethodusedinthisphaseofthestudyseparatesthecontribution
ofscienceteachingtostudentattainmentofscientificliteracyfromother
contributions.Asacrudegeneralisation:
Scientificliteracy
attainment=
EVtest
results-
generalliteracyand
numeracyskillscontribution
Themethodologyusedtoachievethatseparationandthethinkingbehindit
follows.
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3.3.1Selectingthesampleofschoolstoworkwith
AsexplainedinChapterOne,thisresearcherfirstapproachedtheNSW
DepartmentofEducationin2012todiscusstheirpossibleinterestinaproposalto
researchtheimpactoftheEVprogramonscienceteachinginNSW.The
Departmentagreedtoassist.
ThefirststepinvolvedtheDepartmentpsychometricianscheckingtheintegrityof
datasetsheldforstudentswhohadsatEVtestsinthefouryears2011to2014.
Thischeckestablishedthatatleast465schoolshadYear8studentswhosatEV
testsinthisperiod.Tobeeligibleforthisstudy,aschoolhadtohaveaminimumof
10Year8studentswhohadsattheEVtestin2011.Departmentpsychometricians
alsocheckedwhetherthosesamestudentshadsattheYear7NAPLANtestsin
2010andYear9NAPLANtestsin2012atthatschool.Comparabledatasetsforthe
nextthreeyears(2012,2013and2014)hadthentobeconfirmed.Whenthiswas
done,thenumberofschoolswithsufficientstudentstomeettheeligibility
requirementswas394.
ThenextstepwastouseNAPLANresultstogenerateasciencepredictorthatcould
betestedinaregressionwithactualEVresultsforthesamestudents.Theaimwas
tofindapredictorthatproducedthebest“fit”betweenagraphofthepredictor(as
theindependentvariable)andactualEVresult(dependentvariable)forpairsof
students.Themeasureof“fit”iscalledthe“coefficientofdetermination”(Laerd
Statistics,2013,p.1)andhasthesymbolR2.Thevalueasapercentage(inthis
context)isameasureofhowwellthepredictoraccountsforthevariabilityinthe
EVscore.Thecloserto100%,themorethepredictorissaidtoaccountforthe
scoreintheEVtest.A‘lineofbestfit’goingthroughthegraphofpairedstudent
resultsataschoolcanbedrawn.
PlottedresultsarescatteredaboveandbelowthatlineasshowninFigure3.1.
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Figure 3.1 Regression of 2014 EV results over a NAPLAN-based predictorSource: Department of Education, 2016
Thetwolinesshowninfigure3.1separatethetopandbottomtwentypercentof
pairedresults.Thestatisticaldistancebetweenthelineofbestfitandtheplotted
resultistermedtheresidual.Theresidualsizeincludesbothmeasurementerror
andrealdifferencesbetweenpredictorandactualEVresult.Iftheresidualisabove
thelineofbestfit,thentheEVresultispositiveanddeemedforthepurposesof
thisstudy,“betterthanexpected”;ifbelow,theresultisnegativeanddeemed
“belowexpectation”.
FourpredictorsofEVresultswereagreedtoindiscussionsbetweenresearcher
andtheDepartmentfortesting.Thepredictorswere:Years7and9literacyand
numeracyresults(combinedandaveraged);Years7and9literacyresultsonly
(combinedandaveraged);Year7literacyandnumeracyresults(combinedand
averaged);andYear7literacyresultsonly.TheDepartmentperformedseparate
regressionsofEVresultsoverthefourdifferentpredictorsandsetsofresidualsfor
the394schoolsforeachoftheyearsfrom2011to2014werecalculated.A
representationoftheregressionusing394pairsofschoolresultsforthe2014
schoolyearisprovidedinFigure3.1.ThebluediamondsarethepairedschoolEV
results(verticalaxis)andpredictorvalues(horizontalaxis).
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Theslightcurvatureinthetwolinesdelineatingthe80th(topline)and20th
percentilesasdrawnonthegraph(seeFigure3.1)aretheresultofusingfirstand
thirdorderfactors(derivedfromthepredictor)toprovide‘linesofbestfit’.
Equivalentplotsforyears2011,2012and2013werealsoproduced.
Themodelofbestfitturnedouttobethatthepredictorbasedontheaverageof
Years7and9literacyandnumeracyresultscombined.Thecoefficientof
determination(R2)forthatpredictor,averagedoverthefouryearsofinterest,was
R2=.892.Thefour-yearaveragesforR2fortheotherthreepredictorsintheorder
listedabovewere.889,.887and.870,respectively.ThecombinedYear7andYear
9literacyandnumeracypredictoraccountedfor89%oftheexplainedvariationin
EVresultsacrossthestate.
Residualsfromtheregressionprovidingthelineofbestfitwereusedtogenerate
threelistsofschoolsfromacrossNSWidentifiedashavingscientificliteracy
achievementwellaboveexpectation(WAE),asexpected(AE),andwellbelow
expectation(WBE).Thegroupscorrespondedapproximatelywiththetop20%,the
middle20%(spreadevenlyaboveandbelowthelineofbestfit)andlowest20%of
residualsrespectively.
ScienceteachersfromthethreegroupsofschoolswithresultsidentifiedasWAE,
AEandWBEwereinvitedtocompletethesameonlinesurvey(tobeexplainedin
thenextsection,section3.4).Theinvitationsidentifiedawebsiteforsurvey
returnswhichwasdifferentforeachofthethreeschoolgroups.ChapterFour
includesastatisticaldescriptionofthesampleanditsconstituentgroupsand
analysisofthosereturns.
3.3.2Regressionresidualasbothmeasureofcollectivescientificliteracy
and‘effectsize’ofscienceteaching.
Sixpropositionsprovidethebasisforusingaregressionresidualasbotha
measureofscientificliteracyandeffectsizeofscienceteaching.Thefirst
propositionisthatstudentresponsestoitemsandtasksinwell-constructedpen-
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and-papertests(oronlineequivalents)providevalidevidenceformaking
judgmentsaboutthelevelofachievementofmanyaspectsofscientificliteracy.
ThispropositionattractssupportfromFensham(2013),whocommendstheEV
testasanexampleof“agoodmodel”(p.18)ininternationalcomparisons.Rowe
(2006)inpreliminarycommentaryaboutrelationshipsbetweenPISA2003
reading,numeracyandscientificliteracyresults,says“ReadingLiteracy
competenceconstitutesthefoundationalskillthatunderlieseffectiveengagement
withtheschoolcurriculum.”(p.9,Italicsintheoriginal)
Thesecondpropositionisthatschoolscienceisamultiliteracy.Hackling,Peers,
andPrain(2007)describeitthisway.
Science-specificaswellaseverydayliteraciesarerequiredbystudentsto
effectivelyengagewithscience,constructscienceunderstandingsand
developscienceprocesses,andtorepresentandcommunicateideasand
informationaboutscience.(p.14)
Whilestudentsacquire“science-specific”literacyfromanumberofsources,theEV
testtargetsthe“science-specific”literacydescribedinofficialcurriculum
documents.Scienceteachersareexpectedtoteachthatcontentandrelated
vocabularytostudents.Aswell,itisimportanttorecognisethatscienceteachingis
expectedtodevelopotherscience-relatedcapabilitiesthatarenotdirectly
assessableusingpen-and-papertesting(suchasthoseneededformanaging
practicalinvestigations).
Thethirdpropositionisthataccordingtotheconsensusofresearchreportedby
Hattie(2003b),only30%oftheaccounted-forvariationinachievementmeasured
bytestsisattributabletotheexperiencesstudentshaveintheclassroom;50%is
attributabletostudentfactorssuchasabilityandsocioculturalbackground;and
home,peerandschoolenvironment(physical,socialandcultural)influences
accountfortheremaining20%.
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ThefourthpropositionisthatanempiricallytestedNAPLAN-basedpredictorofan
individual’sEVresultprovidesthebestindependentmeasureofwhatisbeyond
thecapacityofscienceteachersworkingintheirscienceclassroomstoinfluence.
Inotherwords,itisameasureofthefactorsHattie(2003b)referstointhe
previouspropositionasresponsiblefor70%oftheexplainedvariationin
achievement.
Ofthefourpredictorstestedforthisproject,theonebasedonanaggregationof
Years7and9readingandnumeracyscores,equallyweighted,providedfor89%of
theexplainedvariability(R2av=0.892)intheEVresultoverthefouryearsof
interest.Theremaining11%ofexplainedvariabilityismostlikelyattributableto
theimpactofscienceteaching.Thisissmallintheoverallschemeofthings
because,accordingHattie(2003b),theteachers’contributiontoachievement(in
scienceinthiscase)is30%overall.
Thiscontributionofscienceteachingtoscienceachievement(asmeasuredintests
liketheEVtest)issosmallthat“maximumvariationcases”(Flyvbjerg,2011,p.
306)aresoughttoensurethebestchanceoffindingcorroboratingevidencethat
theresidualisameasureoftheeffectofscienceteaching(suchasbetterthan
expectedscientificliteracyachievement).
ThefifthpropositionisthattheresidualfromaregressionofactualstudentEV
resultsovertheirpredictedresultsisavalidmeasureoftheimpactofscience
teachingattheschoollevel.Itisarealeffect(overandabovethemeasurement
errorcomponent)thatcontributesperstudentmarkstobothEVresultsand(toa
lesserextent)toNAPLANresults.Theresidualiswhatyougetwhenalltheother
contributionstoEVresultsapartfromscienceteachingareaccountedfor.This
effectwasdesignatedforthepurposeofthisthesisasthecollectivescientific
literacyscorefortheschool.
Thesixthpropositionisthatwhenstandardisedappropriately,thescientific
literacyscoreisavalidmeasureforcomparingschools.Thestandardisedfour-year
averageresidual(actualmarks)rangedfrom2.68marksperstudentperschool
abovethestateregression“lineofbestfit”and2.50marksperstudentperschool
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belowit.Asageneralisation,aslongasthesameorequivalentsetsoftestresults
areusedtogeneratetheresiduals,standardisedscientificliteracyscores(as
representedbytheresiduals)provideavalidbasisforcomparingtheeffectof
scienceteachingonindividualsinaclass;groupswithinaclass;classesataschool;
andschoolsinadistrict,state,nationorgroupofnations.
Giventheabovereasoningandconditions,NAPLAN-basedpredictorscouldalsobe
usedtoassesstheimpactofteachingonachievementinotherlearningdomains
apartfromscience.
3.4Phasetwo:onlinesurveyforscienceteachers
Themainpurposeoftheonlinesurveywastocollectdatafromscienceteachers
abouttheirassessment-relatedwork.Itsotherpurposesweretocollectdirect
evidenceofteacheruseofEVprogramresourcesandrelatedunderstandingofthe
SOLOmodelembeddedintheEVprogram.BoththeEVprogramandembedded
SOLOarespecificNSWinitiativesdesignedtosupportteacheradoptionof
formativepractices.Findingsfromtheanalysisofsurveyreturndatawerethe
primarysourceofevidenceforansweringresearchquestionsoneandtwo.
3.4.1Surveydesign
Aninitialsetofitemsforthesurveywasconstructedusingideasfromarangeof
inputsthatincludedthepublishedworkofresearcherswithaspecialinterestin
assessment,forexample,Black,Harrison,Lee,Marshall,&Wiliam(2004),Hattie
(2012),andShute(2007).AnothersourceofideasforitemswastheNSWBoardof
Study’ssyllabus(BOS,2003)anditssectionsonassessmentforlearningandthe
useoftermssuchas“practices”and“strategies”(pp.71-75).
Otherinfluencesthatimpactedthecontentofsurveyitemsandtheoveralldesign
ofthesurveywerethisresearcher’spreviousexperiencesinthecontextof‘insider’
workdescribedinChapterOne.Thisworkvariouslyincludedcritiquing,
constructingandimplementingsurveys,collatingandanalysingtheresults,and
providingfeedbackonproposedsurveys.Twosurveysthathadadirectinfluence
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onthecontentandformofthefinalsurveyproducedforthiscurrentresearch
were:
• thetelephonesurveyforsecondaryscienceteachersusedtocollectdatafor
theStatusandQualityofSciencereview(Goodrum,Rennie,&Hackling,
2001)
• anationalsurveyonNAPLANtesting(Dulfer,Polesel,&Rice,2012).
Theformerhelpedwiththescopeofthequestions,thelatterwiththeformatofthe
questionsandthedecisiontoaskforpersonalinformationlastofall.
Toensurefacevalidity,itemsforthesurveywererefinedinaniterativeprocess
involvingseveralmeetingswithdifferentgroupsofscienceteachersandonewith
educationofficersintheDepartmentwhohadexperienceofsurveydesignand
expertiseinassessmentandSOLO.Adraftversionofthefinalsurveywastrialed
onlinebyfivescienceteacherswhovolunteeredtodosoatthelastmeetingwith
scienceteachers.Noneofthetrialingteacherswerefromschoolssubsequently
invitedtoparticipateintheresearch.
Itwasthistrialingthatconfirmedthe25-minutetimeallowancesuggestedfor
completingthesurveyonline.Notwithstanding,theonlineversionallowed
teacherstostop,saveandresumeatwill,andtheywereencouragedtokeepacopy
oftheirresponsestocheckagainstthestateresultstobeforwardedatalaterdate.
Anotherpurposeforanonlinetrialwastoensurethattheonlineplatformholding
thesurveywasworkingasanticipated.Followingthetrial,andafterevaluating
teacherfeedbackfrommeetingsandone-on-oneconversationswithscience
teachers,itwasdecidedthatprovidingfeedbacktoparticipantswasan
appropriateincentive.
ThedecisiontouseUTS’sSurveyManagerastheplatformofchoicefortheonline
surveywasbasedon:
• feedbackfromscienceteachers(convenienceofonlinesurveysand
anonymity,ifwanted)
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• easeofdistributionandmanagementofreturns
• supportfromexperiencedstaffassociatedwiththesurveyplatform
• capacityforanalysisusingdescriptivestatisticsofcollectedresponses
• capacitytodownloadtoExcelandSPSS,ifrequired,formoresophisticated
analysis
• separatereturnofindividualcompletedsurveyswithadateandtimestamp
tochecktherequestforindependentindividualreturnsmadeinthesurvey
itself.
Thesurveyquestionsandrelateditemsareorganisedinfoursectionsasshownin
Table3.1.
Table 3.1 Structure of online survey for science teachers Section ONE: About ESSA/VALID • Q1 a-i & Q2 a-m was about the EV program itself and included statements requiring
yes/no responses about teacher engagement with test feedback data and components of EV program resources
• Q3 asked about their understanding of the purpose of the EV program (write a response)
• Q4 asked how well teachers understood the EV program (five point scale: very poor to very good)
• Q5 asked about intention to take up optional VALID 10 test (Yes / No / Unsure) Section TWO: About SOLO • Q6 a-j items here sought to discover the extent of teacher engagement with
aspects of SOLO through a series of yes/no responses • Q7 rate my understanding of SOLO (five point scale: very poor to very good) • Q8 I learnt most about SOLO… (write a response)
Section THREE: About “Assessment for Learning” • Q9 to Q15 were about formative practices. Questions and related items in this
section were organised using the five dimensions of formative practices* • Teachers were asked to choose between (not known-unsure about / never / seldom
/ sometimes / often) when responding to each of the survey items Section FOUR: About your teaching experience / context • Q16 to Q26 invited respondents to provide information about themselves, their
experience and training and about their current school. The last two questions in the fourth section
• Q27 and Q28 asked teachers to participate in a follow-up case study and to identify themselves, their school and provide contact details to facilitate that if interested.
* Responses to survey items provided the opportunity to create individual teacher profiles in terms of the five dimensions of formative practices differentiated from each other by the relative strength of each dimension.
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ThecompletesetofsurveyquestionsisprovidedasAppendixF.
3.4.2Analysisofsurveyresponses
Cresswell(2012)describesafivestepprocessfortheconductofhypothesis
testinginthefourtheditionofhishandbooktitledPlanning,Conducting,and
EvaluatingQuantitativeandQualitativeResearch.Thestepsare:
1. Identifyyournullandalternativehypothesis
2. Setthelevelofsignificance,oralpha(α)level,forrejectingthenullhypothesis
3. Collectdata
4. Computethesamplestatistic
5. Makeadecisionaboutrejectingorfailingtorejectthenullhypothesis.(pp
188-195,italicsintheoriginal)
Thisprocedurewasgenerallyfollowedintheconductofanalysisofquantitative
datacollectedforthisprojectandreportedintermsconsistentwithcurrent
AmericanPsychologicalAssociation(APA)protocols.
Thedesignintentionherewastocharacterisetheassessmentrelated-workof
scienceteachersintermsrelatedtotheiruseofEVresources,SOLOandthefive
dimensionsofformativepractice.Further,thesamplingmethodologydeliveredthe
responsesinthreesetscorrespondingtothegroupsofschoolswithresults
labelledasWBE,AEandWAE.Thethreegroupswereineffectthreeseparate
populations.Surveyreturnsconstitutethesamplesrepresentativeofthose
populations.Theseparatedsurveyreturnspresentedtheopportunityfortesting
thehypothesisthattherewerenodifferencesinteachers’assessment-related
work(thenullhypothesis)despitethegroupshavingEVresultsclassifiedasWAE,
AEandWBE.
Thetoolsusedtobothmanageandanalysethedatacollectedfromteacher
responsestothesurveywereMicrosoft’sspreadsheetsoftware,ExcelandIBM’s
StatisticalPackagefortheSocialSciences(SPSS)whichwasrenamedIBMSPSS
Statisticsin2014.SPSSsoftwareincludesarangeofstatisticaltoolsthatcanbe
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appliedtoprovidedescriptivestatisticsandarangeofinferentialstatistical
analyses.Inferentialstatisticsprovideamethodfor“generalizingfromasampleto
apopulation.”(Lane,n.d.).
Itwasdecidedtouseone-way,between-subjectsANOVAtotestthenull
hypothesis(thatteacherassessmentrelatedworkwasthesameacrossthe
populationofschoolsineachofthethreegroupsofschools).Iftheanalysis
producedstatisticallysignificantdifferencesinaspectsofteacherpracticebetween
thepopulationsanditwasreasonabletorejectthenullhypothesisandconsideran
alternativehypothesis.Thealternativehypothesiswasthataspectsofassessment-
relatedworkandstudentlevelsofscientificliteracyarepositivelyassociated.
1ThedefaultassumptioninSPSSforANOVAcalculationsisthenullhypothesis.
Twoerrorsarediscussedinthestatisticsliteraturerelatedtorejectingatruenull
hypothesisorfailingtorejectafalsenullhypothesis.Sampletestingmayreturn
meansdifferencesthatatfirstglancesuggestpopulationdifferencesinthevariable
ofinterestwheninrealitythedifferencesdonotexist(afalsepositiveresult).Asa
consequence,rejectingthenullhypothesiswouldbeanerror.Thiserroris
identifiedasa“typeIerror”(Lane,n.d.,p.377).SPSSsoftwareprovidesaprintout
ofthetargetstatisticandthelevelofstatisticalsignificance(designatedbythe
letterp)relatedtothatstatistic.Byconvention.insocialresearch,apvaluebelow
0.05(or.01insomesituations)isconsideredareasonablebasisforrejectingthe
nullhypothesis(Bryman,2012andCresswell,2012).
Intheeventthatthereareactualdifferencesbetweenpopulationmeansbutthe
sampletestingwasnotsensitiveenoughtorevelthedifferences(afalsenegative
result),itispossibletodecidethatthenullhypothesisshouldberetainedrather
thanrejected.Thiserror(failingtorejectthenullhypothesis)iscalleda“typeII
error”(Lane,n.d.,p.378).Theprobabilityofmakingthatmistakecanbereduced
bygoodexperimentaldesignandappropriatechoiceofstatisticaltools.The
conceptofstatisticalpowerisusedinthiscontext;itisameasureof“the
probabilityofrejectingafalsenullhypothesis.”(Lane,n.d.).Thegreaterthepower
thebetter.
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Thelimitationsrelatedtousingandinterpretingtheresultsofinferentialstatistics
inthisprojectwillbeprovidedinsection3.7.2and3.7.3.
3.5Phasethree:casestudiesandsciencedepartmentassessmentrelated
narratives
Bothquantitativeandqualitativedatawerecollectedforcasestudiesofscience
departmentsin16schools.Themethodsusedwereaudio-recordedsemi-
structuredinterviews,teacher-selectedartifactsofassessment-relatedpractices,
andaproformacompletedbyteachersandpopulatedwithofficialschooldata
aboutachievementinandengagementwithscience.
3.5.1Audio-recordedsemi-structuredinterviews:purposeand
development
Thepurposeoftheinterviewswastocollectqualitativedatathatcouldbe
interpretedtoprovidecontextualinformationabouttheschoolanditsscience
department’scultureandpractices,andfromthistoconstructschool-specific
narrativesaboutassessment-relatedworkinthesciencedepartment.Substantive
contentwouldbeusedtoinformanswerstotheresearchquestions.
Theinterviewwassemi-structured(afterBryman,2012)usingasetofkeyand
followupquestions(totestsilencesinrelationtooptionspossiblyforgotten).
Giventhedemandsbeingmadeofcasestudyparticipants,aone-hourinterview
wasconsideredsufficientforthesepurposes,andthisprovedtobethecase.
Becausetheinterviewwasaone-offevent,thequestionssoughtresponsesto
relativelyspecificaspectsofassessmentandrelatedpracticesinthecontextof
scienceteaching,manyofwhichhadbeenfirstraisedinsectionthreeoftheonline
surveythatteachershadcompletedsomemonthsearlier.
Afinalsetofquestionswastrialedataschoolnotinvolvedintheresearch.The
purposesforthetrialweretoassessthebestplaceattheschooltoconductthe
interviewsothatparticipantsfeltatease;totestthelanguagerelatedtothe
conductoftheinterviews;tocheckonthewordingofquestions;andtodetermine
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howbesttodescribetheartifactsofinterestforcollection.Thegoalwastoensure
thattheintervieweesfeltascomfortableaspossibleasquicklyaspossible.Aprecis
ofthequestionsandpurposesforaskingthemfollows.
Questions1-3askedwhatpromptedparticipantstojointhecasestudy.Thiswas
followedbytwoquestionsabouttheiruseoftheEVtestandrelatedresources.The
hoped-forresponseswereinsightsintowhatimpact(ifany)theEVprogramhad
onassessment-relatedworkofteachers(sectiononeoftheteacherquestionnaire).
Questions4-8askedaboutthecollectionanduseofevidenceoflearning,and
morespecificallyaboutpeerandself-assessmentopportunitiesgiventostudents
(again,seekinginsightsastotheextenttowhichthesetwokeyaspectsof
formativepracticewereapriorityinteacherthinkingatthisschool).
Questions9–10askedaboutschoolandsciencedepartmentprioritiesinan
attempttogainsomeinsightintotheiralignment.Basedonthisresearcher’s
experience,therewasalikelihoodofschoolprioritiesbeingformativeassessment
and/orthedevelopmentofstudentliteracyandnumeracyskills,thelatterbeingan
attempttounderstandwhetherthereisanemphasison‘writingtolearn’and,ifso,
towhatextenthasitbeentakeupbyteachersinthesciencedepartment.
Questions11–12wereaboutresourcesusedtoteachscienceandaquestion
abouthowknowingwhetherwhatoneisdoingworks(asatestoftheir
commitmenttoassessment).Thiswasalsorelatedtosurfacingunderstandings
aboutusingthesameresourceforbothteachingandassessment.
Anopportunitywasprovidedinrelationtotheonlinesurveyteachershad
completedsomemonthsearlierforintervieweestoexplainhowtheydecidedwhat
weretheappropriateresponseoptionsfromamongthechoices:not
known/unsureabout;never;seldom;sometimes:andoften.Thepurposehere
beingtocheckthatthebasisforchoosingwassimilarforallrespondents.
Aquestionwasaskedaboutwhatintervieweesunderstoodprogressioninlearning
sciencemeans(giventhatSOLOprovidesoneandthesyllabusoutcomesina
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standardsframeworkanother).Theconceptofaprogressioninlearningisastrong
themeintheresearchonformativeassessment(seeChapterTwo).
Aquestionwasaskedabouttheregularityofsciencedepartmentmeetingswas,as
wasoneaboutthenatureandextentofdiscussionsaboutassessmentatthose
meetings.Itwashopedthatdiscussionheremightprovideinsightsintopractices
aroundthesettingandassessingofstudenttasks;howissuesaboutreliabilityand
validityaredealtwith;andwhetherthemeetingsprovidedopportunitiesfor
teacherstodisplaygoodlearningbehaviourswitheachother.
Anopportunitywasprovidedforintervieweestodiscusswhat,ifanything,had
surprisedthemaboutaspectsoftheirschoolEVresultsorstudentsurvey
feedback,Year10orYear12dataputintotheproforma.Thisquestionwas
exploratory,andhoped-forresponsesincludedreferencestohowthescience
departmentwasrespondingtostudentperceptionsoftheirscienceexperienceor
theextenttowhichthisexerciseinresultanalysiswasmoreorlessthanwhatis
currentlythenorm.
Interpretiveanalysisbytheresearcherofteacherresponsestotheinterview
questionswasaniterativeprocess.Theprocessinvolvedtheproductionof
comprehensive,holistic,qualitativedescriptions(Sandelowski,2000)ofpractice
framedbytheinterviewquestions.Thepurposeoftheanalysiswastogenerate
narrativesincludingexamplesorcontextstosupportandilluminateanswersto
theresearchquestions.
All16recordedinterviewswerelistenedtoatleastthreetimes.Nomorethanfour
interviewswerelistenedtoandanalysedinanyoneday.Theelapsedrecording
timestouniquelydescriptiveinstancesofpracticeinthecontextofthatschoolwas
noted(toenableefficientreturntothenatalatertimeforadditionalreplaying).
Noteswerecreatedduringthefirstreplaytosummariseresponses.Replaywas
stoppedandrewoundoversomesectionstocheckthattherecordwasaclearand
accuratesummaryofwhathadbeensaid.
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Whilethesecondreplaywasinprogress,thefirstsetofnoteswascheckedto
ensurekeyactivities,strategies,examplesorinsightsrelatedtoformativepractices
alreadynotedwereconsistentwithwhatwasbeingsaid.Atthethirdlistening,
priornoteswerecomparedwithwhatwasbeingheardtoensureallkeyinsights
andexampleswereappropriatelyreferenced,andfurtheradditions/corrections
weremadewhenconsideredappropriate.
TheteninterviewswiththecasestudyschoolsreportedoninChapterFivewere
thenlistenedtoagainbeforewritingtheassessmentnarrativesusingthefollowing
scaffold.Thecomponentsofthescaffoldwerederivedfromtheteacherinterview
questions(AandB),theteachersurveyquestionsincludingthefivedimensionsof
formativepractice(CtoG).Thelastcomponent(H)wasanopportunitytoprovide
summativecommentsidentifyinguniquepracticesorcommonalitieswithother
schools.
A.EngagementwithEVfeedback,resourcesandSOLO
AnyreferencestotheEVprogram,howitwasvaluedcomparedtoNAPLAN,issues
withdoingthetests(students,staffsupervisionoraccesstocomputers),feedback
used(orignored),andimpactonscienceassessmentgenerallywerereportedhere.
AnyreferencestoSOLOoritsuseswerealsoreportedhere.
B.Groupingforinstruction
ThesourcesofassessmentdatausedtoestablishYear7classes,whodiditand
howitwasusedtoallocatestudentstogroupsforinstructionarereportedhere.
Classessoformedwerevariouslylabeledasmixedability,graded,streamed,or
parallel.Thetimingandbasisforchangingstudentallocationstoclassesasthey
progressedfromYear7toYear9werealsoreported.
C.Useoflearningintentionsandsuccesscriteria
Inthissection,schoolandsciencedepartmentteachingandlearningprioritiesand
theirsourceswererecorded.Theformofteachingandlearningprogram
componentsthatcommunicatedlearningintentionstoteacherswerenoted.Also
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recordedweredetailsofassessmenttasks,prioritiesasrevealedintherelated
rubrics,andalignmentwithsyllabusintentions.Thelinksbetweensuccesscriteria,
markallocationandsubsequentconversiontogradesforthepurposeofreporting
toparentswasalsoexamined.Theresearcheralsolistenedforevidenceofstudent
involvementindevisingorchoosingeitherlearningintentionsorsuccesscriteria.
D.Classroomdiscourseandevidenceoflearning
Teachingscienceinvolvesengagingstudentsinarangeofactivities,including
usingequipmenttomeasureandrecordobservations;accessingsecond-hand
sourcesofdataandinformation;anddesigningandcarryingoutinvestigationsto
solveproblemsandanswerquestions.Itinvolvesworkingaloneandwithothers
anditmaytakeplaceinaregularclassroom,adedicatedspacewithspecialfittings
(suchasschoollaboratories)andaccesstoarangeofspecialistequipment
(includingICTbasedtools),oritmaytakeplacebeyondtheschoolwalls.Of
interestherewastheextenttowhichteachersmadeuseofthediversityofoptions
inthesesettingstoobserveevidenceoflearningandhowtheymanagedthe
discoursesothatevidenceoflearningwasmadeexplicit.
E.Feedback
Thissectionrecordswhodidwhatwiththeevidenceoflearningproducedfrom
teachingandlearningactivities(suchasthosedescribedintheprevioussection).
Inparticular,itwasusefultorecordwhetherthefeedbackprovidedsoughtto
progresslearningforboththestudent/sandtheirteachers,andwhetheritwas
aboutwhatformthecompletedtaskwouldtake,theskillstobeimproved,
metacognition,orpraiseforthelearner(suchasatickorcomment).Ofinteresttoo
werethereferentsforcriteriausedinfeedback.Referentsofinterestherewere
syllabusintentions(scopeofresponsesand/ordepth),misconceptions,SOLO
levelsofthinking,orsomeotherreferentsuchastheBoard’sCommonGradeScale.
Howaccumulatedmarksareconvertedtogradesforreportingpurposeswasalso
ofinteresthere.
F.Activatingstudentsasinstructionalresourcesforothers
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Heretheemphasiswasonrecordingtheopportunitiesstudentsweregivento
providepeerfeedbackandtheguidancetoensurethatitwasaproductiveprocess
forboththeproviderandrecipient.Examplesmightincludestructuredgroup
workwherestudentsareassignedrolesorgivenopportunitiestodemonstrateto
orinstructothers;teacheruseofstrategiessuchaspredict-observe-explain(POE);
think-pair-share-report;jig-saw;orjointconstructionofstudentresponsesto
phasesinaninvestigation.
G.Activatingstudents(andteachers)aslearners
Inthissectionthefocuswasonreportingexamplesofgoodlearningbehaviours
modeledbyeitherorbothstudentsandteachers.Tobeworthnoting,the
opportunitieshadtobeexplicitlyprovided(suchaskeepingreflectivejournals,
choosingitemsforaportfolio,defendingchoices,ormakinglinkstoprevious
learninginscienceand/orothersubjects).Forteachers,opportunitiesmayinclude
workingcollaborativelywitheachothertomarkassessmenttasks;annotating
worksamplestousewhenconvertingmarkstogrades;identifyingmarkcut-offs
forconvertingtogrades;developingfurtherunderstandingaboutwhata
progressionoflearninginsciencelookslike;developinga“scopeandsequence”
foraunitofwork;ordevelopinganassessmentrubricthatincludescriteriafor
rewardingdifferentlevelsofstudentresponsetoanitemortask.
H.Comparativesummativecomments
Summativestatementsrelatingcomparativeachievementandengagementto
aspectsofformativepracticerevealedininterviewsandartifacts,alongwith
commentaryabouttheextentofconfirmationforthepredictions(orotherwise),
completedthereports.
3.5.2Artifactsofassessmentpractice:purpose
Schoolsidentifiedforparticipationinthecasestudieswereadvisedinanemailto
collectanydocumentation,models(orimagesofsame)usedtoinformorsupport
assessment-relatedworkinscienceatthetimeofhisvisit.Artifactssoughtwere
examplesofthingsteachersconsideredtobe‘bestpractice’.Thepurposewasto
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usetheartifactstoconfirminterviewandsurveyresponsesandtoprovide
examplestoillustrateassessment-relatednarrativesdevelopedforspecificcase
studyschools.Theartifactsaskedforincluded:
• teacher-devisedassessmentpoliciestoguideassessment-relatedworkof
scienceteachers
• formalreportsofachievementorprogressbystudents(theonessent
home)
• examplesofassessmenttasks
• learningprogramswherespecificreferencestoassessmentweremade
• lessonplansorstudent‘worksheets’whereassessment-relatedactivities
werethemainfocus
• annotatedexemplarsofqualityworkatdifferentlevelsproducedby
students
• rubricsusedtoassessactivitiesandtoprovidefeedbacktostudents.
Analysisofthecollectedartifactsofassessmentpracticewasperformedafter
listeningtoandsummarisingtheinterviews.Thefocuswastolookfor
confirmatory/contradictory/additionalinformationtoillustratethenarrativesfor
eachschool.
3.5.3Casestudyschooldata:purpose
Participatingteachersatcasestudyschoolswereaskedinadvanceofaschoolvisit
toprovideschool-leveldataaboutEVachievement,Year10resultsandYear12
sciencecoursecompletiondatarelevanttotheyearsofinterest(2010to2015).
Participantsweresentaproforma(inbothhardcopyandasanexcelspreadsheet)
toassistthemprepareforaplannedvisit.Theschool-specificinformationwas
soughttoprovidedataaboutlaterachievementandengagement(explainedin
subsection3.5.5),bothofwhichwererelevanttoansweringresearchquestion
threeandforassessingpredictionsrelatedtoself-regulatedlearning.The
proformasenttoschoolsisattachedasAppendixE.
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TheEVdatarequestedofcasestudyschoolswasfortheyearsfrom2007-2015.It
transpiredthatinmostcasesrespondentswereonlyabletoaccessdatainSMART
fortheyears2011to2015.SMARTistheacronymforSchoolMeasurement
AssessmentandReportingToolkit.Itissophisticatedsoftwaretoolprovided
onlinetoschoolsbytheDepartmentanditcanbeusedtoperformlimitedformsof
analysisontestresultsfromexternaltesting.
Datafortheyearsbeforethatwereapparentlyunavailabletotherespondents,
exceptforthreeschoolswherethedatahadbeenretainedinsciencedepartment
records.OtherdatarelatingtoYear10resultsandnumbersforYear12
completionsofseniorsecondarysciencecourseswereavailabletoschoolsinthe
Board-providedResultsAnalysisPackage(RAP).Mostschoolsdidnotretainthe
Year10dataaspartoftheirsciencedepartmentrecords.Year12resultswere
generallyretainedatthesciencedepartmentlevelandwasprovidedtothe
researcherinallcases.MostschoolshadtoasktheHeadTeacherEnglishfortheir
numbersinordertocalculatetheproportions(asapercentageoftheEnglish
candidature)ofstudentsdoingthevarioussciencesubjects.
ItisfortheprincipaltodecidewhoataschoolhasaccesstoSMARTandRAP.The
purposeforaskingschoolsabouttheirresultswastocollectinformationduring
interviewsabouthowthatinformationwasusedtoinformassessment-related
workintheschoolandinitssciencedepartment.Onlythreeschoolsbrought
completedproformastointerviews.Theremainderprovidedthemafterthe
interviews.Inafewcasestudyschools,thisinformationwasnotimmediately
accessibletoscienceteachersotherthantheHT.
TheresearcherhadDepartmentalapprovaltoaccessanduseaggregatedschool-
levelresults.However,accesstothepatternofschoolresultswasatthediscretion
ofschoolprincipals.AccesstotheresultswasprovidedbythePrincipalinallbut
twoschoolswhowithheldtheYear10datarequested.
Feedbacktoschools,studentsandparentsfromtheDepartmentaboutEVtest
resultsisprovidedinSMART.Theproformaprovidedtoschoolsincluded
tabulatedspacesforschool-leveldataforfourofthefivereportingcategories
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relatingtoEVtestresults.Studentachievementdatafortheschoolandstateare
bothreportedinSMARTagainstthreeachievementbands.
School-providedandotherdatafromcasestudyschoolswerecollectedfrom
schoolsandrecordedinanExcelspreadsheetwhichwaslatertransferredtoSPSS
inordertoperformstatisticalprocesseswiththedata.Aswillbediscussedinmore
detailinChapterFive,sixitemsofthe21inthesurveywillbereportedoninthis
thesis.Analysisofstudentsurveyresponseswasdesignedtoprovidepatternsof
differenceinstrengthofagreement/disagreementoneachoftheitemswithinand
betweenthepairedschools.Thisanalysiswasstraightforward.Themeanscores
wereprintedoutastablesanddifferentcolouredhi-lighterswereusedtoidentify
eachschool’sdifferencewiththestatepopulationrating(above,below,thesame
eachhaddifferentcolours).
Howlaterachievementandengagementinsciencewereassessedforthepurposes
ofthisresearchisexplainednext.
3.5.4Defininglaterachievementinscience
Themeasureofstudents’laterachievementinsciencewasthepatternofgrades
awardedtostudentsattheendofYear10(twoyearsaftertheEVtest)basedon
schoolprocessesandendorsedbytheBoard.Anoptionwouldhavebeento
includeend-of-Year12resultsinscienceaswell.Thiswasnotdonefortwo
reasons:first,becausethedatacollectedaboutassessmentpracticeswas
specificallyfocusedonthefirstthreeyearsofsecondaryschooling;andsecond,to
reducetheamountoftimerequiredofparticipatingteachers.
Theissueofassessingimprovementinachievementovertheyearswithinaschool
isnotstraightforwardbecausethebasisforbothassessingandreporting
achievementisdifferentateachofthetwochosenpointsofinterest.Thekey
differencesinthereportingofachievementareoutlinednext.
ResultsfortheEVtestareaone-offsummativeassessmentreportedinlevelsfrom
1to6referencedtoascalebasedonSOLOlevelsoflearning.InSMART,asecond
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wayofprovidingfeedbackonresultsistoreportitastheproportionofstudentsin
achievementbands(threebandsareused:band1,band2andband3,thelatter
beingtheproportionofstudentsattheschoolattaininglevels5and6,thehighest
twolevels).
StudentachievementattheendofYear10isreportedasgrades(AtoE,Ais
highest).ThegradesarereferencedtotheBoard’s(BOS,2013).TheScale
describesfivestandardsofachievement.Inallofthe16schoolsinterviewedthe
gradesawardedbyteachersarebasedontheirjudgmentofthestandardimplied
byparticularmarkrangeswithintherangeofaggregatedmarksforalltasks
completedinthatyear.Forexample,marksrangingfrom60to70(outofsay100)
mightbeindicativeofworkconsistentwiththatdescribedforaBgradeonthe
Board’sScale.TheBoard’sCommonGradeScaleisinnotrelatedtoSOLOlevels.
Casestudyschoolsprovidedtheproportionsofstudentsobtainingthetop,middle
andbottomachievementbandsinYear8fortheirschool,andcomparabledatafor
thestateintheyearsofinterest.Schoolsalsoprovidedtheproportionsattaining
gradesAtoEinYear10fortheirstudents.Therelativeproportionsofstudents
obtainingAtoEinscienceinthestateintheyearsofinterestwereobtainedfrom
theNSWcurriculumandassessmentauthority’swebsite(NESA,2017).
Thus,changesinintra-schoolproportionsrelativetothestateatbothYear8and
Year10provideagoodbasisformonitoringlaterachievement(Year10compared
toYear8).
3.5.5Definingengagementwithscience
Inthecontextofthisproject,asimpleoperationalviewofengagementwaschosen
toassesstheextentoflaterengagementwithscience(seeresearchquestion
three).Itwaschosenforpragmaticreasonsrelatingtodataavailabilityandthe
sensewithwhicheducationministerTebbuttuseditwhenannouncingtheEV
programin2005(seesection2.2).Asstudentsarefreetochoosewhetherornot
theytakeupsciencecoursesafterYear10,comparingtheproportionsofstudents
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completingsciencecoursesattheendofYear12waschosenasthemeasureof
laterengagement(seeresearchquestionthree).
Becausescienceisacompulsorycourseforthefirstfouryearsofsecondary
schoolingadifferentwayofassessingengagementwasneeded.Studentresponses
toitemsfromthestudentsurveyaccompanyingtheEVtestprovideanalternate
wayofmeasuringengagementattheendofYear8.ItemsintheEVsurveyasked
studentstorateonafour-pointscaletheiragreement(ordisagreement)witha
seriesofstatementsrelatedtoscienceandtheirschoolscienceexperienceofit.
Selectedsurveyitems(sixof21)werechosenasthebasisformeasuring
engagement.
Theitemschosencoveredinterestinscience,enjoymentofscienceinprimaryand
secondaryschool,perceiveddifficultyofsciencerelativetoothersubjects,
perceivedsuccessinlearningitandwhetheritwasoneoftheirfavouritesubjects.
These(andother)aspectsofaffectappearinresearchpapersattemptingtodefine
engagementwithscience(includingitsretentionwhenfreetodropit).Seefor
exampletheUK’s,NationalFoundationforEducationalResearch(2011)report
titledExploringyoungpeople’sviewsonscienceeducationwheresomeofthese
aspectsarediscussed.Atthistime,theredoesnotappeartobeanevidence-based
consensusabouthowbesttodefineengagement.Studentfeedbackonaspectsof
affectaddressedbytheitemsprovidedataforevaluatingtheirusefulnessas
markersforstudentself-regulationwhichisexploredinChapterFive.
Laterengagement
Thedataprovidedbyschoolswasusedtogenerateanoperationaldefinitionof
laterengagement.Englishisamandatorycourseforallstudentswantingthe
HigherSchoolCertificate(HSC).TheHSCistheschoolexitcredentialprovidedto
studentsfromNSWschoolswhowantitassupportforentrytopostschooloptions
includingworkandhigherorfurthereducation.Scienceteacherswereaskedto
converttheirsciencecoursecompletionnumberstoapercentagerelativeto
Englishnumbersattheschool.
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Englishandseniorsciencecourseseachyearacrossthestateforthepurposesof
theHSCwereobtainedbytheresearcherfromtheNSWEducationandStandards
Authoritywebsite(NESA,2017).StatewideproportionsrelativetoEnglishwere
calculatedforthestate.Thesetwosetsofnumbers,schoolandstateproportions,
provideanobjectivebasisformakinginter-schoolcomparisonsrelatedto
engagementasdefinedabove.Studentsmakeachoicetocontinuewithordrop
scienceafterYear10.Thus,themeasureofengagementbasedonproportions
completingsciencecourses(relativetoEnglish)attheendofYear12would
appearalsotobeastrongmeasureofthecollectivevaluingofsciencebystudents
ataschoolhalf-waythroughYear10whentheymaketheirchoicesforsubjectsto
studyinthesenioryearsofschooling.
ThestudentsurveycomponentoftheYear8EVtestprovidesawayofmeasuring
students’levelofsatisfactionwiththeirexperienceofscienceinthefirsttwoyears
ofsecondaryschool.Whenaggregatedandaveragedovertheyearsofinterestand
comparedtostatewidedata,thesurveyprovidesanobjectivemeasurefor
engagementthatcanbecomparedovertimebothwithintheschoolandbetween
schools(whenreferencedtostateproportions).
ThedatausedtoproduceaYear8measureofengagementwerecollatedfrom
schoolrecordsbyteachersincasestudyschools.Thedataaskedforwasasubset
oftheEVfeedbackprovidedinSMART.Giventhatonethirdoftheteachershad
saidinsurveyresponsesthattheyhadnotlookedatsurveydata(seesection
5.6.2),responsestoonlysixidentifieditems(of22)wereaskedfor.SMART
includesthestateproportionsofstudentsateachachievementbandlevelforeach
item.
Whileitistruetosaythatcross-schoolcomparisonsforbothachievementand
engagementcanbemadeusingobjectivemeasures,thesewouldalmostcertainly
notbevalidunlessotherfactorscontributingtothescoresaremadeexplicit.Those
doingthecomparisonarethenabletomakeaninformedjudgmentabout
differencesafterconsideringthelikelyimpactofthesefactors.Thisissueisdealt
withinthenextsection.
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3.6Comparableschoolsandthreepredictions
Thepointofmakingintra-schoolcomparisonsforachievementinandengagement
withscienceistoassesswhether,overtime,successivecohortsofstudentsare
doingbetteratkeypointsinthejourneythroughsecondaryschooling,suchasat
theendofYears8,10and12.Inotherwords,aretherefinementsbeingmadeat
theschoolleveltoteachingandlearningprogramsinthelightoffeedback
resultinginbetteroverallachievementforsuccessivecohortspassingthrough
thosepoints?Changestoachievementandengagementpatternsthatreveal
growingproportionsofstudentsathigherlevels/grades/numberstakingsenior
sciencecourseswouldnodoubtbewelcomedasevidenceofimprovementandbe
entirelyconsistentwiththeuseofformativepracticesbyscienceteachers.
Inthecontextofthisresearch,inter-schoolcomparisonsprovideameansfor
independentlytestingthevalidityofaclaimmadeinSection3.3.Theclaimthere
wasthatthesizeandsignoftheregressionresidualisadirectmeasureofthe
scientificliteracycomponentofEVresults…themorepositivetheresidual,the
biggerwasthecontributiontotheEVresultoverall(makingitbetterthan
expected).Also,itwasclaimedtherethatthescientificliteracyeffectisdirectly
relatedtotheimpactofscienceteaching.Ifthatisavalidclaim,thenforapairof
comparableschools(oneintheWAEgroupofschoolsandoneintheWBEgroup,
say)theactualEVresultsintheWAEschoolshouldbebetterthantheresultsin
theWBEschool.Themeaningof‘comparable’isexplainedbelow.
Comparableschoolsweredefinedbytheresearcherasschoolshavingthesameor
verysimilarSEAscores.SEAistheacronymfor“socio-educational
advantage”(ACARA,2014b,p.3),whichisameasurepublishedforschoolsonthe
MySchoolwebsite.Itisanindependentmeasureofthecapacityforlearningeach
studentbringstoschool.Thismeasureofstudenteducational
disadvantage/advantageisdeterminedfromparents’levelsofeducation,
occupationandpost-schoolqualifications.Afourthcategoryofcurrent
employmentstatusofparentswasaddedtoSEAdeterminationsfrom2013
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onwards(ACARA,2014b)becauseitwasfoundhelpfulinimprovingthe
correlationbetweentheSEAscore,ICSEAandsubsequentNAPLANresults.
TheSchoolProfilepageforeachschoolontheMySchoolwebsiteprovidestheSEA
dataasaquartileprofileshowingtheproportionsofstudentsatthatschoolinthe
fourquartersfromthemosteducationallydisadvantagedtothemosteducationally
advantaged.Inordertoprotecttheidentityoftheschool,theSEAprofiledatafor
eachschoolwasusedtoproducewhattheresearchercalledtheSEAscore.The
profilequartileswereconvertedtoasinglescoreonascaleof0–10usingasimple
lineartransformation.Thelowerthenumber,thelargertheproportionof
educationallydisadvantagedstudentsattheschool;thehigherthenumber,the
largertheproportionofeducationallyadvantagedstudentsattheschool.TheSEA
scoreforeachschoolisthefour-yearaverageoftheSEAscoresfortheYear7
intakesin2010to2013,inclusive.
ThereasoningbehindthedecisiontousetheSEAasthecontrolfollows.InHattie’s
(2003b)termsACARA’sSEAisequivalenttothestudentfactorsthathesays
provide50%oftheaccounted-forvariabilityintestresults.Themeasureof
regionalremotenessandpercentageofIndigenousstudentenrolment,which
ACARAreferstoasschoolfactors,areequivalenttothefactorsHattie(2003b)says
contributeupto20%oftheaccounted-forvariabilityintestresults.Whatthe
teacherdoesintheclassroomcontributestherest,hesays.
TheANOVAperformedonteacherresponsestothesurveyquestionsabout
formativepracticesprovidedaprofileofscienceassessment-relatedworkforthe
sampleofteachersfromeachoftheschoolgroups.Ifthesamplemeansrelatedto
thedimensionsofformativepracticein,say,theWBEandWAEsamplewere
showntobesignificantlydifferent,thedifferenceinpracticeassociatedwiththat
meanwasthengeneralizedtoapplytoalltheschoolsinthatgroup.Thegroup
profileisdescribedintermsofthefivedimensionsofformativepractice.IftheEV
resultsforcomparable(thatis,havingthesameSEAscores)schoolsare
statisticallysignificantlydifferentinthewaypredictedbytheresidual,thenit
wouldbereasonabletoattributethatdifferencetotheformativepracticeprofileof
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scienceteachersinthatgroupofschools.Thisisbecausetheresidualassigningthe
schooltoaparticulargroupisalsoanimputedmeasureofthe‘effectsize’of
scienceteaching.
Thestrengthoftherelationshipsbetweenschoolgroup,EVresults,andformative
practiceprofilescanbetestedusingcorrelationstatisticswhichSPSShasthe
capacitytoperform.Aswell,accordingtotheresearchevidencediscussedin
ChapterTwo,ifformativepracticesaremorefrequentinWAEschoolsthenwe
couldreasonablyexpectthatstudentsintheWAEschoolare,collectively,more
skilledatlearningandmoremotivatedandengagedthanstudentsintheWBE
school.IfthatisthesituationattheendofYear8,itcouldreasonablybeexpected
thatstudentsintheWAEschoolwouldapplythoseskills,motivationand
engagementgoingforward,withthesamerelativeeffectsonachievementat,say,
theendofYear10.
Withtheaboveinmind,threepredictionsweremade:
1. OverallEVresultsforstudentsincomparableschoolswillbebetterinWAE
schoolsthanAEschools,andAEschoolresultswillbebetterthanWBE
schools.
2. OverallYear10scienceresultpatternsforstudentsincomparableschools
willbebetterinWAEschoolsthanAEschools,andAEschoolresult
patternswillbebetterthanWBEschoolpatterns.
3. Theproportion(relativetoEnglish)ofstudentscompletingYear12science
coursesincomparableschoolswillbehighestinWAEschools,andAE
schoolswillhaveahigherproportionofcompletionsthanWBEschools.
Verificationofthepredictionsandrelateddiscussiondrawingontheassessment-
relatednarrativesparticulartothecasestudyschoolswillbeprovidedinChapter
Five.
Findings(ChapterFour)andassessment-relatednarratives(ChapterFive)
providedthedataandinformationusedtoinformdiscussionreportedinChapter
133
Sixabouttheimpactofformativepracticesonstudentlearningofscienceinthe
earlyyearsofsecondaryeducationinNSWgovernmentschools.
3.7Limitations
Specificfactorsthatimpactthetrustworthinessandthevalidityoffindingsinboth
qualitativeandquantitativeresearchgenerallyandinthisresearchspecifically
follow.
3.7.1Trustworthinessofqualitativeresearch
Toensurethepersuasivenessoftheanswersrelatingtothe“why”,“how”and
“impact”componentsoftheresearchquestions,thisresearchertookstepsto
ensurethattheevidenceusedtoconstructanswerssatisfiesthefourcriteriafora
“trustworthystudy”(Shenton,2004,p.64):credibility,transferability,
dependability,andconfirmability.Potentialconcernsthattheresearcherinthis
projectshouldhavebeenpositionedasaparticipantresearcher/observer
(Denzin&Lincoln,2011andHammersley,2008)areaddressed.
OriginallyproposedbyGuba(1981),Shentonhasusedtheabovefourcriteriain
hisownwork,claimingthatthecriteriahavebeen“acceptedbymany”(Shenton,
2004,p.64).Shenton(2004)arguesthatthesecriteriaareanalogoustofour
criteriausedbypositiviststodefendtheirwork.Credibilityisthequalitative
researchanalogforinternalvalidity;transferabilityistheanalogforexternal
validity/generalisability;dependabilityreplacesreliability,andconfirmability
replacesobjectivity.
Credibility
Credibilityisaboutcongruenceoffindingswithreality(Merriam,1998).
Transferabilityisaboutprovidingenoughcontextualdetailforapersontomakea
judgmentthat“findingscanjustifiablybeappliedto[adifferent]setting”(Shenton,
2004,p.63).Dependabilityisdifficulttoachieveinaqualitativestudy,butagoal
shouldbetohavesufficientdetailtoenable“afutureinvestigatortorepeatthe
study”(Shenton,2004,p.63).Confirmabilityisabout“researchers[takingsteps]
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todemonstratethatfindingsemergefromthedataandnottheirown
predispositions”(Shenton,2004,p.63).
Inrelationtocredibility,Shenton(2004)advocates14“strategies”(p.64)thatmay
beusedtoachievecredibility.Theseincludeusingwell-establishedmethodsin
qualitativeresearch“ingeneralandin[education]inparticular”(p.64).
Interpretiveanalysisofinterviewsandartifactsofpracticewithintheconstraints
ofacasestudyisawell-acceptedmethodologyinqualitativeresearch.Inthis
project,interpretiveanalysisofsemi-structuredinterviewsandartifactsof
assessmentpracticethatwereselectedbyteachersasrepresentativeoftheir‘best
practices’produceddataandfindingsaboutcontextrelevanttounderstanding
resultsobtainedquantitatively.
Anotherstrategyforensuringcredibilityisresearcher“familiaritywiththeculture
ofparticipatingorganisations”(Shenton,2004,p.65).Thisresearcher’sdirectand
continuousinvolvementwithscienceeducationsincethelate1960swasan
importantfactorinhisdecisionsaboutwhattoaskofparticipantsinthecasestudy
componentsand,asmentionedearlierinSection3.4,hischoosinganddevising
itemsfortheonlinesurvey.Otherstrategiesmentionedinrelationtocredibility
includetacticstoensurerespondenthonestyincludingiterativequestioning.These
wereexplicitconsiderationsatvariouspointsintheresearchreportedhere.
Usingmultiplesourcesandmultipledatacollectionstrategiesisanotherwayto
promotecredibilityinresearch.Inthisresearchproject,someoftheinterview
questionssoughttocorroboratetheextentofsharedunderstandingbetween
intervieweeandinterviewer(thisresearcher)whenitcametoitemslistedinthe
onlinesurvey.Examplesfromtheonlinesurveyincludeitem10eabouttheuseof
think-pair-share-reportstrategy;item11cabouttheuseofgradesasaformof
feedback;item15eabouthowstaffdevelopasharedunderstandingofwhat
progressioninlearningsciencelookslike;andadirectquestionaskingteachers
howtheydecidedbetweenoften,sometimesandseldomwhenconsideringhow
frequentlytheyemployedtheactivities/strategiesdescribedintheonlinesurvey
items.
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Transferability
Transferabilityisthesecondcriterionusedtoestablishtrustworthiness.In
relationtoqualitativeresearch,thisiscontentiousbecauseofthelimitations
imposedbytheboundariesofcasestudywork.Shenton(2004)says:
Ultimately,theresultsofaqualitativestudymustbeunderstoodwithinthe
contextoftheparticularcharacteristicsoftheorganisationororganisations
and,perhaps,geographicalareainwhichthefieldworkwascarriedout.(p.
70)
Shenton(2004)cautionsthatwheninconsistenciesarefound,thismaynotreflect
onthetrustworthinessoftheresearchbutmaybeanindicatorofmultiplesocial
realities.Inthisresearch,everyattemptwasmadetoprovidesufficientcontextual
informationforpeopletomakeajudgmentaboutthecontentionthatformative
practiceshaveademonstrableimpactonsciencelearningandrelatedattitudesto
science.
Dependability
Dependabilityisthethirdcriterion.Thedetailprovidedabouttheconductofthe
researchreportedhereshouldenableapersontorepeattheprocessatanother
placeorinafuturetimeperiod.Theirintentionmightbetoconfirmfindings,but
equally,itmightbeaboutwhetheradifferentrealityisabetterfitforthefindings.
Confirmability
Thefourthcriterionoftrustworthiness(confirmability)canbeprovidedby
triangulationtocheckinvestigatorbias(ortoassessparticipantresearcher/
observerbias);makingexplicittheresearcher’sbeliefsandassumptions;drawing
attentiontolimitationsofthemethodsusedandtheirpotentialimpactonfindings;
anddescribingexplicitlyandindetailthemethodsthatenablescrutinyofresults.
Thedetailsprovidedinthisthesisrelatingtothemethodsandsamplesizesshould
enableareadertoverifyforthemselvesthefindings,inferencesandconclusions.
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Inthisproject,interpretiveanalysisofsemi-structuredinterviewsandartifactsof
assessmentpracticethatwereselectedbyteachersasrepresentativeoftheir‘best
practices’produceddataandfindingsaboutcontextrelevanttounderstanding
resultsobtainedquantitatively.
3.7.2Validityandreliabilityofquantitativedata
Quantitativeresearchcriteriarelatingtovalidity,reliabilityandobjectivityhave
longbeentouchstonesforassessingtheworthofresearchfindings(Bryman,
2012).Intheapplicationofstatisticalmethodstoprovideanobjectivebasisfor
reportingfindings,adistinctionismadebetweendescriptivestatisticsand
inferentialstatistics.Descriptivestatisticsincludeconceptssuchassum,average,
mean,measuresoffrequency,measuresofdistribution.Inferentialstatistics
involvetheuseofconceptssuchascorrelation,probability,statisticalsignificance,
powerandconfidencelevelsindiscussingtestresults.
SPSSsoftwareprovidestoolstoanalysequantitativedataandproducearangeof
descriptivestatisticscharacterizingthedata.Featuresofthedatacanthenbe
evaluatedforimpactontheinferentialstatisticofinterest.Datamaybejudgedas
beingeitherparametricornon-parametricandtheappropriatetoolcanbechosen
fortheproposedtest,suchasANOVA.TheaccuracyofthecalculatedANOVA
statisticmaybecompromised(andinextremesituations,invalidated)byusing
datathatdoesnotfullycomplywithallthedataassumptionsforparametric
analysiswhich,accordingtoaLaerdStatistics(2018)tutorialandLane(n.d.),are:
1. Thedependentvariableshouldbemeasuredattheintervalorratiolevel
2. Theindependentvariableshouldconsistoftwoormorecategorical,
independentgroups
3. Independentobservations(norelationshipsbetweenthegroups;nosubject
inmorethanonegroup)
4. Nosignificantoutlierdatavalues
5. Dependentvariabledatashouldbeapproximatelynormallydistributedfor
eachcategoryoftheindependentvariable
6. Datadisplayshomogeneityofvariation
137
7. Samplenumbersinthedifferentgroupsareapproximatelyequal.
AccordingtoLane(n.d)andRennie(1998)thepowerofthestatisticbeing
calculatedusingsamplesisenhanced(reducingthechanceoffailingtorejectthe
nullhypothesis)whenthe:
1. samplesizeislarge
2. standarddeviationissmall
3. differencebetweenthehypothesizedandactualmeansbeingcomparedare
large
4. significancelevelislessstringent
5. atestisonetailed(andthehypothesizeddirectioniscorrectlyspecified).
Intheeventthattheparametricstatisticandrelatedstatisticalsignificancefigure
basedonanassumptionofparametricdataisinconclusive,posthoctestsbasedon
theassumptionthatthedatawere,ineffect,nonparametricmaybemorepowerful
orrobustandprovideareasonablebasisforrejecting(orretaining)thenull
hypothesis.
Teachersurveyresponsesandtheschool-leveldatasetsforEVtestresults,Year10
assessmentsandYear12sciencecoursecompletionnumberswereprocessed
usingbothdescriptiveandinferentialstatistics.Findingsfromtheapplicationsof
statisticalprocesseswillbeprovidedinChaptersFourandFive.
3.7.3Summaryoflimitationsaffectingthisstudy’sfindings
Qualitativedata
Twolimitationsinrelationtotheartifactscollectedforthisprojectareworth
mentioning.Thefirstwasthat,forthemostpart,artifactsreflectedcurrent
practiceandwithfewexceptionshadbeenproducedinthetwoyearspreceding
thisresearchinresponsetotheintroductionofanewsyllabusthatwasbeing
implementedfrom2014.Theyearsofinterestforthisprojectpredated2015.The
secondwastheextenttowhichtheartifactswererepresentativeofthediversityof
teacherpractice.
138
Intheend,thesamplesprovidedwereassessedforalignmentbetweenaspectsof
theprovidedassessmentrubricandsyllabusintentions(asexpressedby
outcomes,accesstorelatedcontentprescribedbythesyllabus,andthecontextin
whichtheactivitywasembedded).Thesyllabusthen,asnow,intendedteachersto
providecontextualisedactivitiestoengagestudentinterest.
Whenconsideringthecharacterisationsofformativepracticesproducedfrom
teachersurveyresponses,itwasimportanttorememberthattheprofilesdrawn
wereonlyinrelationtopracticesinYears7,8and9.Thisisrelevanttoany
discussionabouttheextrapolationoffindingsinrelationtothethreepredictions
describedinSection3.6.
Greatcarewhentryingtointerpretteacherresponsestointerviewquestions
aboutassessment-relatedpracticeshadtobetakenfortworeasons.Thefirstwas
thatthisresearcher(whoconductedtheinterviews)knewonlyoneofthe
participatingcasestudyschoolscienceteachersbeforetheinterviews.Hehad
attendedatwo-dayworkshoppresentedbythisresearchermorethantenyears
earlier.Initialnaturalreservewhenitcametodisclosureofpracticeswasevident
inmostcases.
However,anhourisageneroustimeforaone-on-onediscussionandmost
participantsseemedtoappreciatetheopportunitytodiscusstheirpracticewithan
interviewerwhounderstoodtheirsituationandtowhomtheycouldmakefrank
disclosuresabouttheirwork.Nointerviewwasterminatedbeforetheassigned
time;mostwentlonger.
Thesecondreasonwasthattheinterviewswerebeingconductedin2016about
assessmentpracticesrelatedtoasyllabusthatschoolswerenolongerworking
with(itwasreplacedafter2014).Thenewsyllabuswassenttoschoolsin2012
andscienceteacherswereencouragedthentobeginplanningforits
implementationintoYears7and9from2014andYears8and10from2015.The
newsyllabusbecamethebasisforEVtestinginYears8and10from2015,theyear
aftertheperiodofinterestforthisthesis.
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ThismeantthatHTsincasestudyschoolsweremanagingsyllabusimplementation
processesthathadbeeninprogressforatleasttwoyearsaftertheperiodof
interestrelatingtoachievement.Theseprocessesincludedreviewingand
adjustingthesetofsummativeassessmenttaskstoreflectnewsyllabuslearning
intentions.Inpracticethismeantverylittlechangeinthesubjectmatterandthe
weightingbetweenknowledgeandunderstandingandskillswasthesame(50:50).
Anumberofthecasestudyschoolshadchangedtheassessmentmodesusedto
collectassessmentdata.Somereplacedformalpen-and-papertestswithresearch
projects,practicaltasksandoralpresentations.Theissuewastoworkoutwhether
whatwasbeingprovidedinthediscussionandartifactswererecentinnovations
(i.e.hadbeenintroducedafter2014orwereinplacebeforethat).
Artifactsofassessment-relatedpracticeprovidedbyteachersneededtobe
consideredinthelightofrecencyaswell.Themainissuewastoworkoutwhich
partoftheschoolnarrativesaboutassessmentforlearningappliedbeforeorafter
2014.Questionsfromtheinterviewerwereusedtoassistwiththatwhere
necessary.
Quantitativedata
Thecriterionofdataindependencewasprovidedbyanexperimentaldesignthat
askedforanddeliveredresponsesfromeitherWAEorAEorWBEdesignated
schoolstothreedifferentwebsites.Theinstructionswiththeonlinesurveywere
explicitinaskingforindividualresponses.Acheckonthetimingofsurveyreturns
supportedtheassessmentthatreturnswerefromindividualsevenwhenmultiple
returnsfrom(teacher)identifiedschoolswerereceived.Oneschoolthatidentified
itselfsaidithadprovidedaconsensusreturnfromthefiveteacherscomprisingthe
sciencedepartment.Itwastreatedasanindividualreturnforthepurposesofthis
exercise.
ThedatanormalityrequirementwastestedusingtheShapiro-WilktestinSPSS.
TheSPSStutorialadvicewasthattheShapiro-Wilktestismoreappropriatefor
samplesizeslessthan50(LaerdStatistics,2017).
140
Therequirementforhomogeneityofvariancewastestedusingboththe
parametricLevenetestandWelch(nonparametric)testfor‘robustnessofmeans
equality’andthemostappropriatetestresultwasreported.Bothofthesetestsare
readilyavailableinSPSS.
IftheANOVAstatisticforthebetween-groupmeanswasstatisticallysignificant,
thenonparametricGames-HowellMultipleComparisonsTestwasusedtoidentify
thegroupswithstatisticallysignificantmeans.TheGames-Howelltestis
recommendedwherethegroupsizeswererelativelysmallandunequalinnumber,
and,asinsomecases,datasetswereborderlineintermsofhomogeneityof
varianceandnormaldistribution(LaerdStatistics,2017).TheTukeyHSDtestisa
parametrictestandwasnotanappropriatetestinmostcases.Thesetwotests
(andmore)werereadilyaccessiblewithintheSPSSsoftwareused.
Becausethesurveywasvoluntaryandanonymous,itwasnotpossibleto
predeterminethetotalnumberofresponsesorhowtheindividualresponse
numberswouldbedistributedacrossthethreepopulations.Asaconsequence,the
groupsizeswereunequalandthenumberofsubjectsrelativelysmall.Whilethere
were101respondentsintotal,onlycompleteoralmostcompletedatasetsfor
sectionsbeinganalysedwereused.Thenumberofdatasetsremainingineach
groupwere:nWBE=32,nAE=28,andnWAE=25,meaningthatdatafrom16(15%)
oftherespondentswasnotused.Theimpactofmissingdatawithinthedatasets
usedwasmanagedbytheSPSStoolsusedtoreportthestatisticalsignificanceof
thestatisticproduced.
ThenonparametricKruskal-WallisANOVAwasgenerallyusedwheretestsfor
homogeneityofvarianceandnormalitywerenotcompletelysatisfied.
Year-on-yearvariabilityandschoolmisfortunescanimpactresultsinaone-off
test.Examplesmightbethedeathofateacherorastudent,aswellasindividual
studentcircumstances.Therelativeimpactofindividualorgroupmisfortuneon
aggregatedresultsisinverselyproportionaltotheYear8population.Forexample,
onestudentdroppinganachievementlevelinaschool’sYear8populationof30
producesa3%variationintheproportionofstudentsatthatgradelevel;inaYear
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8with100ormorestudents,theimpactisoftheorderofa1%variationorless.
Averagingresultsoverfouryearsreducestheimpactofyear-on-yearvariations,
particularlyforsmallschools.Thiswasafactortakenintoaccountwhen
determiningthetolerancesfordecidingdifferencesinresultsorengagement
patterns(seeChapterFive).
3.8Researchapprovals
AsaPhDcandidate,thisresearchersoughtandwasgrantedUTSethicsapproval
(UTSHRECREFNO.2015000453)inSeptember2015toundertaketheresearch
describedinthisthesis.
AnapplicationtotheNSWDepartmentofEducationtoaccessitsstate-wideEVand
NAPLANresultsandtoapproachschoolstoparticipateinresearchwasgrantedin
November2015(SERAP2015373).
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CHAPTERFOUR:FINDINGSFROMPHASETWO
Thischapterreportsfindingsfromphasetwooftheresearchdesign,theanalysis
ofsurveyreturnsfromscienceteachers.Thefindingsprovidepartialanswersto
thefirsttworesearchquestions:
1. WhatusearescienceteachersmakingoftheEVprogramincludingSOLO,
andwhyisitusedornotused?
2. Whatformativepracticesareevidentintheworkofscienceteachers,and
whyaretheyusedornotused?
Findingsinrelationtothewhyorwhynotcomponentsofthequestionsare
providedinChapterFive.
Section4.1reportsthesizeofthegroupscomprisingthesampleofschoolsinvited
toparticipateintheresearch(fromphaseoneoftheresearchdesign).Also
discussedhereistheimpactofusingtheregressionresidual(whichisanimputed
measureofthescientificliteracyattainedrelativetoapredictor)torankschools
insteadofEVresults.Itisrelevanttothetransformativeintentofdoingthis
researchaswillbediscussedfurtherinChaptersFiveandSix.
Section4.2providestheresultsandfindingsfromanalysisofthesurveyreturns.
Theyarereportedinfoursetsrelatingtothesectionsinthesurvey.
Section4.3reportssomeadditionalfindingsthatwillbereferredtoinsubsequent
chapters.
Section4.4providesasummaryofkeyfindingsgroupedunderthetworesearch
questionstheyprovideanswersto.
Section4.5providesasummaryoffindingsinrelationtothesecondresearch
question.
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4.1Introduction
Phaseoneintheresearchdesigndeliveredthesampleofschoolstoworkwith.The
regressionanalysisofEVresultsoverthechosenpredictorproducedresidualsfor
394schools.Theschoolswerethenorderedaccordingtotheirresiduals(biggest
positiveresidualatthetop).Thesizeoftheresidualwasdeemedforthepurposes
ofthisthesis(seesubsection3.3.2)tobeameasureofthescientificliteracy
componentofEVtestresultsandameasureofthescienceteachingassociatedwith
it.
AsshowninTable4.1theapproximately20%ofschoolswiththebiggestpositive
residualswerelabelledasschoolshavingEVresultsthatwerewellabove
expectation(WAE);approximately20%ofschoolswiththelargestnegative
residualswerelabelledashavingEVresultswellbelowexpectation(WBE).A
middlegroupofschools(approximately20%)straddlingthelineofbestfitline
(zeroresidual)werelabelledashavingresultsatexpectation(AE).Theremaining
schoolswerelabelledas‘notdefined’.Expectationwasdefinedintermsofthe
differencebetweentheactualEVresultandNAPLAN-basedpredictor.
Table 4.1 Defining populations from which to invite research participants
Standardised residuals
Residual Rank
Quintile group
Group label Number of schools
2.68 to 0.56 1—85 TOP Well above expectation (WAE)
85
0.55 to 0.16 86—166 - Not defined 81 0.15 to -0.20 167—254 MIDDLE As expected (AE) 88 -0.21 to -0.56 255—309 - Not defined 55 -0.57 to -2.50 310—394 BOTTOM Well below
expectation (WBE) 85
Note. A positive residual means that EV results were above expectation. A negative residual means that EV results were below expectation. Expectation is defined as relative to the “line of best fit” for the result pairs used in the regression model.
144
AswillbedemonstratedinChapterFive(seeTable5.1),thethreegroupsof
schoolsareineffectthreeseparatepopulationsdefinedbythesizeoftheirgroup
meanresidualsandthefactthatwhenmeasurementerrorsaretakenintoaccount,
thereisnegligibleoverlapbetweenthedistributionsofresultsassociatedwiththe
WAEandAEandAEandWBEgroups.ThereisnooverlapbetweentheWAEand
WBEdistributions.Thislastdifferenceisimportantbecauseitmeansthat,interms
ofstatisticalconvention,findingsofstatisticalsignificancebetweenthesample
meansineachgroupcanbegeneralisedtothegrouppopulationfromwhichthat
samplewastaken.
Also,thedifferencesbetweenWAEandWBEgroupsmeanresidualsareasfar
apartascouldbemanagedwithintheconstraintsofthemethodologyused.The
intentionwastoachieveFlyvbjerg’s(2011)pre-conditionofmaximumdifference
betweenthegroupmeasureofthekeyvariable(scientificliteracy)weare
interestedin.
IntheNSWgovernmenteducationsystem,schoolsareclassifiedinanumberof
ways,includingbyproximitytomajorpopulationcentres(metropolitan,
provincial,ruralandremote),bygender(coeducational,boysorgirlsschools),and
bystudententrycriteria(comprehensive,partiallyselectiveentryorfullyselective
entry).Whenschoolsarerankedusingconventionalmeasuresofachievement,
suchasEVtestresults,thefullyselectiveentryschoolsoccupythetop19positions
andprovincialschoolsperformpoorlyrelativetometropolitanschools.Only9%of
provincialschoolswereinthetop20%ofschoolsbasedonEVresults.
Theuseoftheresidualtorankschools(Table4.1)producedthefollowingfindings.
Scientificliteracyscores,fortheyearsfrom2011to2014,werebetterthan
expected(aresidualabovezero)in53%ofthe394schoolsmeetingcriteriafor
inclusioninthestudy.Whilstitisarguablethatthedifferenceisnotstatistically
significant,theconsistencyoftheslightpositivebiasoverfouryearsisinteresting,
ifnotreal.Whenthisresultislookedatbygovernmentschoolcategory,67%ofall
provincialschools,68%offullyselectiveentryschools,and23%ofpartially
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selectiveentryschoolsallachievedbetterthanexpectedEVresults(theresidual
wasthefour-yearaverageofschoolresiduals).
AccordingtoThomsonetal.(2017)approximately25%ofschoolsinAustraliaare
classifiedasprovincial(thenextcategoryaftermetropolitan,basedontheirsize
anddistancefrommajorpopulationcentres).Assumingthisfigureisrelevantto
NSW,around115schoolswouldbeinthatcategoryofschool.Whenwecountup
thenumberofprovincialschoolsinthetop20%ofschoolsrankedaccordingto
theirresidual,56%oftheschoolsthereareprovincialschools.Also25%ofthe
schoolsinthebottom20%ofschoolswereprovincialschools.
Thus,onthebasisofresidualrankings,provincialschoolshadmorethandouble
theirexpectedpresenceinthetop20%groupandwererepresentedasexpectedin
thebottom20%group.ItwasarguedinChapterThreethattheresidualisadirect
measureoftheeffectofscienceteaching.ThejustificationforlookingatEVresults
above,atandbelowexpectationandtheirattributiontoschooltypeisprovidedin
thenextparagraph.
InSection3.2referencewasmadetothetransformativeintentofthemixed
methodsdesignemployedinthisresearchproject.Theresearcherwillprovidethe
findingstotheschoolsthatparticipatedandtotheNSWDepartmentofEducation
thatsupportedit.Iftheunconventionalmeasureofteachingsuccess(residual
valueandpolarity)isvalidated,thentheschoolsreallyneedinghelptoimprove
studentachievementinandengagementwithsciencecanbespecificallyidentified
andtargetedforsupport.
Leavingthecategoryofschooloutofconsiderationinthefirstphaseofthe
research,principalsofschoolswithWAE,AEandWBEEVresultswereinvitedto
supporttheirscienceteachers’participationintheresearch.Ofthe394eligible
schools,258principalsreceivedinvitations(66%ofeligibleschoolsand55%ofall
465governmentsecondaryschoolsinNSWwithYear8studentenrolments.
Ofthe101surveysreturnedbyscienceteachers,35werefromWBEschoolsand
therewere33eachfromAEschoolsandWAEschools.Itisnotpossibleto
146
determinetheresponseratebecausethenumberofteacherswhoreceived
notificationaboutthesurveyisunknown.Intheirresponsestotheonlinesurvey,
42respondentsidentifiedthemselvesandthe36schoolsinwhichtheytaught.Not
allthesurveyreturnswerecompleteandthisshowsupinthenumberscounted
forthepurposeofstatisticalanalysis.
ThesurveyquestionsareavailableasAppendixFandaprintoutofdescriptive
statisticsofteacherresponsesisprovidedasAppendixJ.
4.2Findingsfromanalysisofthescienceteachersurveyreturns.
Theresidualusedtocreateschoolgroupsfromwhichtosamplecontainsno
informationaboutthecharacteristicsoftheteachingexperiencedbystudentsin
theschoolsthatprovidedresponses.Phasetwooftheresearchsoughttoestablish
therelationship,ifany,betweenthethreeschoolgroupsandtheextenttowhich
teachersuseEVresources,includingSOLOandformativepracticesintheirwork.
Thesurveyundertakenbyallrespondingteacherswasidentical.However,their
returnswerecollatedaccordingtothegrouptheirschoolhadbeenassignedto.
AseriesofANOVAswereperformedtoestablishthestrength(inthestatistical
sense)ofanyassociationsbetweentheschoolgroupandaspectsofassessment-
relatedworkdonebyteachersinthosegroups.Thesurveyhadfourpartsand
analysisofthesetofresultsfromeachpartisreportedseparatelyinsubsections
4.2.1to4.2.4.
Subsection4.2.1describestheextentofteacherengagementwithanduseofEV
resources,theirunderstandingoftheEVprogram,andtheirinvolvementwithitat
andbeyondschool.
Subsection4.2.2describestheextentofscienceteacherengagementwithand
understandingofSOLO.Thesetwosetsofresultsandrelatedfindingsdetailthe
extentanddepthoftheimpactoftheEVprogram,includingSOLO,onthe
assessment-relatedworkofthesampledjuniorsecondaryscienceteachersfrom
2011to2014.
147
Thefindingsinthesetwosubsectionsarethemaininputsforaddressingresearch
questionone.
Analysisofteacherresponsesanditemsinthethirdsectionofthesurveyprovided
datarelevanttocharacterisingteachers’assessmentrelatedworkintermsofthe
fivedimensionsofformativepractice.Theanalysiswasalsoaimedatestablishing
thegeneralityofthefindingfromthesampletothegrouppopulation.Thefindings
fromthatanalysisarereportedinSubsection4.2.3andwereusedtoinform
answerstothesecondandthirdresearchquestions.
Internationalresearchdiscussedinchaptertwoshowsthatbetterlearning
outcomesarestronglyassociatedwithteacheruseofformativepractices(see,for
example,CERI,2005).AsexplainedinChapterOne,itwasforthisreasonthat
syllabusadvicesupportingtheuseofassessmentforlearning(underpinning
formativepractices)wasincludedinofficialsyllabusdocumentsinNSW.The
findingsreportedinSubsection4.2.3arealsothebasisfordiscussioninChapter
Sixontheextenttowhichthefindingsheremakeacontribution(through
replication)tothegrowingbodyofinternationalresearchonthepowerof
formativepracticesandonlearninghowtolearn.
Thefourthsetoffindings,reportedinSubsection4.2.4,areabouttheparticipating
teachersandtheirschools.Findingsinthissectionprovidebackground
informationusedtoinformassessmentnarrativesandconclusionsreportedin
ChaptersFiveandSixrespectively.
Subsection4.2.5reportsotherfindingsfromthesurveyanalysisusedto
contextualisediscussioninChaptersFiveandSix.
4.2.1Setoneresults:TeacherengagementwithEVresources(survey
questions1to5)
Questionone(Q1)itemsintheteachersurveyaddressedthescopeofrecent(past
12months)teacherengagementwithEVresults.Teachersrespondedyesornoto
atotalofnineitems.Itemsweregroupedintothefollowingcategoriesofactions:
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• accessingresults(items1ato1d)
• discussingresultswithcolleagues(items1e,1g&1h)
• discussingresultswithstudents(items1f&1i).
Questiontwo(Q2)itemssoughttofindouttheextentofteacherengagementwith
anduseofEVrelatedactivitiesandresourcesoverthepasttwoyears.Teachers
respondedyesornotoatotalof13items.Categoriesofactionswere:
• accessingEVresourcesandmaterials(items2a,2b&2d)
• usingEVresourcesintheclassroom(items2c&2g)
• usingEVquestionsandotherresourcesinorasmodelsforschool
assessments(items2e,2f&2h)
• changingfacultyprograms(item2i)
• engagingbeyondschoolinEVrelatedactivities(2jto2m).
AnalysisofdatafromQuestionsoneandtwo
ThehypothesiswasthatteachersinschoolswhereEVresultsweredeemedtobe
WAEwouldmakegreateruseofEVresourcesthantheircolleaguesinschools
whereresultsweredeemedasWBE.ThedecisionwasmadetoincludeAEschools
inthetestingtoassesstheconsistencywithwhichthemeasuresofteacheractivity
associatedwithAEschoolswaslowerthaninWAEschools,buthigherthanin
WBEschools.Onbalance,EVresultsinAEschoolsshouldbebelowWAEschools
andaboveWBEschoolsEVresults.Ifthispatternisfound,itaddsweighttothe
credibilityoftheresidualasameasureofscienceteachingeffectiveness.
ANOVAproceedsontheassumptionofthenullhypothesis(thatthereareno
statisticallysignificantdifferencesinthelevelofEVresourceusebyteachersinthe
threegroups).Subsection3.7.2discussedgeneralconsiderationsrelatingtothe
featuresofdatasetsandtheappropriatechoiceoftoolfromthesuiteoftools
availableinSPSS.Subsection3.7.3particularisedthatdiscussiontothisproject.
Consequently,datasetswereanalysedfornormalityandhomogeneityofvariation
andappropriatestatisticaltoolschosentoperformANOVAandrelatedsignificance
testing.IndicativefindingsfromANOVAwereassessedagainstasignificancelevel
149
(p)of.05.Thedecisiontoacceptorrejectthenullhypothesiswasmadeby
referencetotheconventionalstandard.
ThedescriptivestatisticsforQ1&Q2(combined)arepresentedinTables4.2and
therelatedmeansplotsinFigure4.1.
Table 4.2 Descriptive statistics for Q1 & 2 (n = 85)
Result group x̅ s σx̅ n Q1 & Q2 ( / 22)
WBE 7.63 4.85 .86 32 AE 11.82 3.98 .75 28 WAE 11.48 4.55 .91 25 Total 10.14 4.86 .53 85
Figure 4.1 Means plots for Q1 & Q 2 combined
TheQ1&Q2(combined)datasets(n=85)passedboththenormalityand
homogeneityofvariancetests(p>.05).TheShapiro-Wilkstatistic(W)forthe
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WBEgroupW=.965,p=.38;theAEgroupW=.982,p=.90,andtheWAEgroupW
=.964,p=.49.TheLevenevariancestatisticwasF2,82=.821,p=.44.
TheparametricANOVAstatisticforQ1&Q2combined(F2,82=8.093,p=.001)
supportedtherejectionofthenullhypothesis(p<.05).Thismeansthattherewas
astatisticallysignificantdifferencebetweenoneormoreofthegroupsmeans.
TheGames-Howellmultiplecomparisonsanalysisindicatedthatthex̅WAE-x̅WBE
(difference=3.86,p=.009)andx̅AE–x̅WBE(difference=4.20,p=.001)were
statisticallysignificant,butthatthex̅AE–x̅WAE(difference=.34,p=.994)wasnot.
BasedonthedataanalysisforQ1&Q2combined,itcanbereasonablyconcluded
that,asagroup,teachersatschoolswhereresultsweredeemedtobeWBEmake
lessuseoverallofEVresultsandresourcestosupporttheirassessment-related
workthandotheircolleaguesatschoolswhereresultsaredeemedtobeAEor
WAE.
Asupplementaryanalysiswasthenperformedonthecombineddatabutthistime
disaggregatedagainsttheeightcategoriesidentifiedabovetodifferentiate
particularsimilaritiesanddifferencesbetweengrouppractices.
Alleightcategory-separateddatasetsfailedtheShapiro-Wilktestfornormality(p
<.05)andallbutone(categoryF)failedtheLevenetestaswell.Inthelightofthat
failure,thenonparametricKruskal-WallisANOVAwasapplied.Itdemonstrated
statisticallysignificantdifferencesbetweenfouroftheeightcategorymeans,as
showninTable4.3.
151
Table 4.3 Results of nonparametric ANOVA for eight EV categories
Figure4.2providesavisualrepresentationofthefourcategoriesmeansthatwere
statisticallysignificantlydifferent.ReadverticalbarsLtoR(matchedwithEVAto
EVGdowntheRHSlabels).
152
Figure 4.2 EV category means shown to be statistically significantly different
Takingintoaccountthe95%confidenceintervalsforthemeans,visualinspection
showsthatWBEmeansspreadsforcategoriesEVAandEVD(firstandsecondplots
fromtheleft)appeartobebelowtheWAEmeansspreadsforthesamecategories.
WBEmeansspreadsforcategoriesEVFandEVG(thirdandfourthplots)appearto
belowerthantheAEmeansspreadsforthosecategories.TheAEandWAEmeans
spreadsforallfourcategoriesappeartooverlapeachother.
TheposthocGamesHowellmultiplecomparisonstestsconfirmedthatthe
statisticallysignificantdifferencesinmeans(p<.05)were,asobserved,between
theWBEandWAEmeansforcategoriesEVAandEVD(difference=1.1,p=.024
anddifference=.73,p=.006respectively)andbetweentheWBEandAEmeans
forcategoriesEVFandEVG(difference=.76,p=.039anddifference=.53,p.=000
respectively).TheGames-Howellmeanscomparisonprocessshowedthatforthe
eightdatasets,theAEandWAEmeanswerenotstatisticallysignificantlydifferent.
Basedontheabove,itwouldbereasonabletoconcludethefollowingabout
teachersuseofresourcesinthelightoftheeightcategories.
153
Thesecond(EVB),third(EVC),fifth(EVE)andeighth(EFH)categoryresponses
werenotstatisticallysignificantlydifferentfromeachother.Thusfigures
discussedforthesefourcategoriesofactionsarebasedonthecombinedtotalof
teachersrespondingfromeachofthethreegroups(n=85).
InrelationtoEVBwhichwasaboutdiscussingresultswithcolleagues,66%had
discussedthetestitemandtaskanalysis,49%haddiscussedtheresultsofthe
studentsurvey,and33%haddiscussedthestudentprofileinformation.
EVCwasaboutdiscussionwithstudents.22%haddiscussedtheitemortask
analysiswithstudentsand18%haddiscussedtheresultsofthestudentsurvey.
EVEwasaboutusingEVresourcesintheclassroom.45%hadusedtheteaching
strategiesprovidedintheSMARTpackageand68%haduseditemsandtasksfrom
EVtestsintheirschoolassessments.
EVFwasaboutengagementbeyondschool.TwoteachersfromtheAEgrouphad
writtenitemsfortheEVtest;twoteacherseachfromtheAEandWAEgrouphad
evaluateditemsforthetest;39%hadmarkedextendedresponsetasks;and30%
hadattendedworkshopsabouttheEVprogram(differenttotrainingformarking).
Thefollowingfindingscanreasonablybemadeforthefourcategorieswhere
statisticallysignificantdifferencesbetweenteacheruseofEVresourceswere
demonstrated.
Thefirstcategory(EVA)askedteacherstosaywhethertheyhad,intheprevious
twelvemonths,lookedatEVresultsforthestudentsurvey(fortheirclass),the
analysisofanswerstotheextendedresponsetasks,andindividualstudentprofile
results.TeachersinWBEschoolshadnotaccessed(viewed)thisinformationas
muchastheircolleaguesinWAEschools.
Thefourthcategory(EVD)askedteacherswhethertheyhadintheprevioustwo
yearsaccessedEVrelatedmaterialsinTaLE(theDepartment’sinternalteacher
supportwebsite),SMARTprovidedfeedbackonEVresultsaswellasadviceabout
teachingstrategiestoaddresssciencemisconceptionsandtheseparatelyproduced
154
markingmanualsforextendedresponsetasks.Again,teachersinWBEschoolshad
notaccessedtheseresourcesasmuchastheircolleaguesinWAEschools.
Thesixthcategory(EVF)askedwhetherteachersintheprevioustwoyearshad
usedEVtestitemsandtasksintheirowntestsorasmodelstoworkwith.
TeachersinWBEschoolshaddonesolessthantheircolleaguesinAEschools.
Theseventhcategory(EVG)askedwhetherschoolshadusedEVresultstoinform
changestofaculty(teachingandlearning)programsintheprevioustwoyears,
TeachersinWBEschoolsmadelessuseofEVresultsinthatprocessthanhad
teachersinAEschools.
Surveyquestionthree(Q3orEV3)askedteacherstoself-reporttheirlevelof
understandingoftheEVprogram.
Thedescriptivestatisticsforthecombineddataandrelatedplotsareshownin
Table4.4andFigure4.3
Table 4.4 Descriptive statistics for Q3 (n = 85)
Result group x̅ s σx̅ n Q3 ( / 5)
WBE 2.97 1.15 .20 32 AE 4.04 .79 .15 28 WAE 3.84 .90 .18 25 Total 3.58 1.07 .12 85
155
Figure4.3Teacherself-ratingfortheirunderstandingoftheEVprogram(n=85)
ResponsestoQ3wereanalysedtodiscoverwhetherteacherratedunderstanding
oftheEVprogramwasdifferentbetweenthethreegroupsofschools.
ThethreedatasetsforQ3failedthenormalitytests(p<.05)butdidpassthe
homogeneityofvariancetests(p>.05).
Giventhefailureonthenormalitytest,itwasdecidedtoapplytheWelchrobust
testofequalityofmeans(Welch’sF2,53.19=9.162,p=.000).Asthepvaluewas
<.05,theresultsweretakenasshowingarealdifferencebetweenoneormoreof
thegroupmeans.
TheGames-Howellmultiplecomparisonsanalysisattributedthedifferencesto
x̅WAE-x̅WBE(difference=.871,p=.006)andx̅AE–x̅WBE(difference=1.067,p=.000)
whichwerestatisticallysignificant(p<.05).Thethex̅AE–x̅WAE(difference=.196,p
=.682)wasnotstatisticallysignificantlydifferent.
156
BasedonthedataanalysisforQ3,itcanbereasonablyconcludedthatteachersin
schoolswithresultsdeemedtobeWBEhadalowerself-ratedunderstandingof
SOLOthantheircolleaguesinschoolswhereresultsweredeemedtobeAEand
WAE.
Q4askedteacherstowritewhattheythoughtwasthemostimportantpurposefor
theEVtest.Table4.5showstheircollatedandcategorisedresponses.
Table 4.5 Summary of EV purposes
Response numbers per group Category of response
WBE n = 32
AE n = 38
WAE n = 25
For students Opportunity to demonstrate their learning Provide students with feedback to improve their learning Opportunity to improve test taking skills Provide challenge for higher achievers For teachers Opportunity for professional learning about assessment Provide feedback on student performance / achievement relative to others Provide feedback on student performance / achievement relative to standards Provide feedback on student learning Provide feedback on learning progress Provide feedback on teaching Provide feedback on teaching programs Other responses No idea of EV purpose An unwelcome imposition Jobs for head office workers No response or left blank
3 0 0 0 0 10 1 12 2 3 5 2 1 2 6
0 3 1 0 1 7 1 1 3 7 7 5 0 0 0 3
0 0 2 1 0 6 2 4 1 8 3 0 0 0 4
Note. Some respondents mentioned more than one purpose thus the group sample numbers (n) do not match the comment totals.
Examplesoftypicalresponsesinclude:
Understandhowwellourstudentsperformrelativetotherestofthestate.
(WBEteacher)
Thetrackingofstudentsastheyprogressthroughhighschool.(WBEteacher)
157
Understandyourstudentsandamendteachingandlearningstrategiesfor
students.(WBEteacher)
Providefeedbacktoteachersontheeffectivenessoftheirteachingthestage4
Sciencesyllabus.(AEteacher)
TogetasnapshotofhowStage4studentshaveprogressedspecificallyin
Sciencesinceprimaryschool.Theextendedresponsesareparticularlyuseful
inidentifyingthestudents’abilityorlackofabilityincommunicatingand/or
understandingscientificconceptsindifferentscenarios.Itisalsoveryuseful
toidentifymisconceptions–soinfluencesourteachingapproaches.(AE
teacher)
Providefeedbacktostudentsontheirknowledgeandunderstandingof
scientificconceptsandtheirscientificliteracy.Provideinformationto
teachersonareasthatneedimprovement.(AEteacher)
Recordofstudentgrowth,strengthsandweaknessesofprograms/areasof
teaching.(WAEteacher)
Toassessstudents’scientificliteracycomparativetotheirpeersinthestate.
(WAEteacher)
Identifyareaswhereweneedtoimproveourteachingofparticularconcepts
orskills.(WAEteacher).
Tosummarise,allthreegroupsofteachersmostfrequentlyidentifiedthepurpose
oftheEVprogramasbeingtoprovide:
• feedbacktoteachersaboutstudentlearning/learningprogress
• comparativeinformationaboutachievement/performancerelativetoother
schools
• feedbackaboutteaching
• feedbackonteachingandlearningprograms.
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Surveyquestionfive(Q5)askedteacherswhethertheirschoolwastakingupthe
invitationtoparticipateinVALID10,whichisanacronymforValidationof
AssessmentforLearningandIndividualDevelopment.VALIDhadbeenintroduced
onavoluntarybasisforYear10studentsforthefirsttimein2015.Itisanewtest
designedtoprovidedataaboutachievementinscienceattheendofYear10.Itisa
Year10equivalenttesttotheYear8EVtest.
IntendedparticipationinVALID10in2016waslowerforWBEschools(n=3)
thaneitherAE(n=6)orWAE(n=6)schools.Thenumbersarebasedonacount
fromidentifiedschoolsineachgrouptoavoiddouble-countingthesameschool.
4.2.2Settworesults:SOLOandextentofteacherengagementwithit
(surveyquestions6to8)
SOLOisthetheoreticalmodelthatinformsfeedbacktoschoolsaboutthelevelof
sciencethinkingexhibitedbystudentsasrevealedintheirselectedresponsesto
itemsandwrittenresponsestotheextendedresponsetasks(seeChapterTwofor
afullexplanation).
Surveyquestionssix(Q6a-j)andseven(Q7)wereaboutteacherengagementwith
anduseofSOLOatschoolandtheirunderstandingofSOLOrespectively.Q6a-j
askedteacherstorespondyesornoto10itemsdescribingactionstakenoverthe
previoustwoyears.TheQ6a-jmeansforteachersattheschoolsineachschool
groupatthetimeofinterestareprovidedinTable4.6andFigure4.4.
Table 4.6 Descriptive statistics for Q6 (n = 85)
Result group x̅ s σx̅ n
Q6 (out of 10)
WBE 2.00 1.87 .330 32 AE 2.21 2.41 .455 28 WAE 2.96 3.18 .636 25 Total 2.35 2.49 .270 85
159
Figure 4.4 Means plots for Q6
LookingatQ6a-jmeans(n=85),thefirstobservationisthatallthreegroupmeans
arelow.Thesecondisthatwhenconfidencelevelsaretakenintoaccount,the
visualrepresentationofthemeansalloverlapanddonotappeartobestatistically
significantlydifferenttoeachother.
Toconfirmthatresult,theShapiro-WilkstestandLevenetestsfordataset
normalityandvarianceofhomogeneityrespectivelywerenotsatisfied(p<.05for
bothandthusbelowtheacceptedpvalueof.05)andthusthenonparametric
Kruskal-WallisANOVAwasused.
ThenonparametricANOVA(Table4.7)includesresultsforbothQ6andQ7.Row1
inthattablesupportstheabovefindingthatthemeansdifferencesbetweenthe
threecategoriesarenotstatisticallysignificantlydifferentforQ6.
160
Table 4.7 Nonparametric ANOVA (n = 85) for SOLO questions (Q6 & 7)
Giventhatthemeansdifferencesbetweenthesamplesfromthethreeschool
groupswerenotstatisticallysignificantlydifferent,totalsampleresponsesare
providedforQ6(Table4.8andFigure4.5).Thefrequenciesrecordedareforthe
totalsofYESresponsestotheitemsinQ6.Noteacherscored9or10outof10.
Table 4.8 Q6 SOLO category counts (n =85)
Total Frequency Percent Cumulative Percent
0 31 36.5 36.5 1 7 8.2 44.7 2 13 15.3 60.0 3 10 11.8 71.8 4 8 9.4 81.2 5 5 5.9 87.1 6 3 3.5 90.6 7 2 2.4 92.9 8 6 7.1 100.0
85 100.0
161
Figure 4.5 Frequency V level of engagement (zero to ten)
Inlightoftheaboveanalysis,whenalmostathirdofthesamplesaidnotoallitems
andwithhalfofthesamplerespondingyestofromonetofiveofthetenquestions,
itisreasonabletoconcludethatinallprobability,mostteachersacrossthestate
havenotengagedwithSOLOtoanextentwhereitgreatlyinformstheir
assessment-relatedwork.
Q7askedforaself-ratingbyteachersoftheirunderstandingofSOLO(1=very
poorto5=verygood).ThemeansforallthreegroupsareshowninTable4.9.The
levelofself-reportedunderstandingrangedfromabovepoortobelowacceptable
andthemeansforallthreegroupsrespondingtoQ7arenotstatistically
significantlydifferenttoeachotherasshowninFigure4.6andconfirmedabove
(seerow2,Table4.7).
162
Table 4.9 Descriptive statistics for Q7 (n = 84)
Result group x̅ s σx̅ n
Q7 (out of 5)
WBE 2.47 1.11 .196 32 AE 2.61 1.10 .208 28 WAE 2.58 1.47 .300 24 Total 2.55 1.21 .132 84
Figure 4.6 Means plots for Q7 self-reported understanding of SOLO
AccordingtoFigure4.7,45%oftheteachersrespondingtothesurveyratedtheir
understandingofSOLOaspoororverypoor.
163
Figure 4.7 S7 Frequency (n = 85) verses level of understanding
TheresultsfromtheanalysisofQ6andQ7supportthefollowingfindingsthat
applytoscienceteachersinthethreeschoolgroupssampled(n=85):
• around40%ofrespondentshad“accessedmaterialaboutSOLO”(survey
wording)
• fewerthan30%hadexplainedSOLOtoanyoneorusedSOLOinthe
classroom
• 46%ofteacherssaidtheyhadaverypoororpoorunderstandingofSOLO
• fewerthan10%reportedthattheirschoolhadusedSOLOconceptsorthe
SOLOmodeltoinformfacultyassessmentpoliciesortoprovidefeedbackon
studentachievementtoparents,and;theoveralllevelofself-reported
understandingofSOLOrangedfrompoortoacceptableatbest.
Surveyquestioneight(Q8)askedrespondentswheretheylearntmostaboutSOLO.
Table4.10summarisescollatedresponsesfromthethreesamples(WAE,AEand
WBE).
164
Table 4.10 Q8 summary of sources for learning about SOLO
Category of response
WBE n = 32
AE n = 28
WAE n = 25
No response / left blank 9 11 8 Training for ESSA / VALID marking 2 3 4
Actually marking ESSA / VALID 10 4 7 Applying it to school assessment 2 - 2 ESSA / VALID workshop 2 3 3 Using it in class 2 1 - Researched it - 7 1 Explaining it to others 1 2 - Talking to colleagues - 4 - Nothing helped 2 - - Never heard of SOLO / what is it? 2 - 4
Note. Total responses do not match total sample (n = 85) because some mentioned more than one source. Highlighted responses indicate the sources most commonly identified.
Arangeofresponsesfromthethreegroupsincluded:
MarkingextendedresponsequestionsforVALID10thisyear.(WBEteacher)
WTFisSOLO?I'veneverheardofthis.Idon'tthinkIspendahugeamountof
timeunderarock,withmyfingersinmyears,crouchedinthefoetalposition
whilsthummingnurseryrhymes,butIhavenotheardofthisterm.(WBE
teacher)
IattendedaworkshoprunbytheESSApeople.(WBEteacher)
Ireadaboutitonlinetodeterminewhatitwas.Idon'trememberit
specificallyfromanytraining.(AEteacher)
Explainingittootherstaff.(AEteacher)
165
ParticipatedinamarkingcourseforwhatESSAisandhowSOLOmarking
schemeswork.(AEteacher)
MarkingESSA.(WAEteacher)
IattendedtherecentMeettheMarkersseminaronSOLOandVALID.Our
facultythendecidedtoimplementspecificSOLObasedquestionsandmarking
schemesinourhalfyearlyexaminationforalljunioryears.Thisallgavea
clearperspectiveandgoodpracticeintheuseofSOLO.Theoutcomesand
markingschemesfromtheseexaminationshavenotyetbeencommunicated
tostudentsorparents.(WAEteacher)
AttendedSTANSWMTM(MeettheMarkers)onESSA(someyearsagoand
regularlyeveryfewyearssince)andmorerecentlybyinvestigatingthework
ofPamHookandothers.(WAEteacher)
SixrespondentsreportedthattheyhadneverheardofSOLOortheywantedto
knowwhatSOLOwas.Markingortrainingformarkingandworkshopswerethe
mostfrequentlymentionedsourcesforlearningaboutSOLO.
Bywayofexplanation,trainingfortheYear8testwasprovidedinworkshopsbya
skilledtrainerwithunderstandingofSOLO;trainingformarkingtheYear10tests
attheschoollevelinvolvedaccessingonlinematerialsandmayormaynothave
beendonecollaborativelywithcolleagues.
4.2.3Setthreeresults:Formativepractices(Questions9to15)
Questionsnineto15(Q9toQ15)soughttocapturetheextentofusebyteachersof
assessmentforlearningstrategies/formativepracticesbeyondthoseassociated
withtheEVprogram.TheEVprogramisaboutusingassessmentdatafor
diagnosticpurposesasdiscussedinearlierchapters.Allitemsintheassessment
forlearning(AFL)/formativepracticessectionofthesurveyareavailableinthe
surveyitself,whichisprovidedasAppendixF.
166
Q9toQ15included47separateitems.Eachiteminvitedoneoffiveresponsesfrom
teachers:NotknownorUnsureabout(NKUA)/Never/Seldom/Sometimes/
Often.
TheanalysisfortheNKUAoptionacrossQ9toQ15forthethreegroupsshownis
presentedinTable4.11(descriptivestatistics)andtheirgraphicalrepresentation
inFigure4.8.
Table 4.11 Means for NKUA option (n = 85)
School group n x̅ s σx̅
WBE 32 .94 1.46 .26 AE 28 .79 2.06 .39
WAE 25 .72 1.02 .20 Total 85 .82 1.57 .17
Figure 4.8 NKUA graphical representation of means
Themeansfromeachgroupoverlappedwhentheconfidenceintervalsweretaken
intoaccountandwerethusnotstatisticallysignificantlydifferent.Onthatbasisthe
167
nullhypothesis(comparableunderstandingoftheitemsbyteachersinthethree
groups)wasretained.
ThenextsetofdatarepresentedinTable4.12andFigure4.9summarisesthedata
fromallrespondents(n=84)forallitemsinQ9toQ15.Calculationswerebased
onassigningvaluestoteacherdecisionsonthefollowingbasis.NKUA=1;never=
2;seldom=3;sometimes=4andoften=5.
Table 4.12 Descriptive stats for Q9 -15 (n = 84)
Result group x̅ s σx̅ n
Q9 - 15 (out of 5)
WBE 3.86 .32 .06 32 AE 4.07 .41 .08 28 WAE 4.10 .37 .08 24 Total 4.00 .38 .04 84
Figure 4.9 Means plots for Q9 – Q15
168
Visualinspectiontakingintoaccounttheconfidencelevelspreadforeachgroup
meanstronglysuggeststhattheAEandWAEmeanswerenotstatistically
significantlydifferent.Also,theconfidencelevelspreadfortheWBEgroupmean
overlapssomewhattheAEandWAEmeanspreads.
Totestwhethersomeorallofthemeanswerestatisticallysignificantlydifferent
(ornot),thefollowingtestswereconductedontheallitemsdata(Qs9-15).Tests
fordatanormality(Shapiro-Wilk)andhomogeneityofvariance(Levene)are
providedinTable4.13.
Table 4.13 Tests for normality and homogeneity of variance for all items Qs 9-15 (n = 84)
Shapiro-Wilk test
WBE W32 = .956, p = .217
AE W28 = .978, p = .793
WAE W24 = .943, p = .191
Levene test F 2,81 = .356, p = .702
Theresultssatisfiedthethresholdsfordatanormalityandhomogeneityof
variance(p>.05)inallthreegroups.
Despitetherebeingunequalnumbersinthethreesamples,theparametricANOVA
statistic(F2,81=3.849,p=.025)andnon-parametricKruskal-WallisANOVA
statistic(χ2(2)=6.695,p=.035)bothreturnedasignificancefigure<.05.(forthe
Kruskal-Wallisresult,seerowoneinTable4.17).
TheGames-Howellmultiplecomparisonsanalysisindicatedthatthex̅WAE-x̅WBE
difference(difference=.24,p=.033)wasstatisticallysignificant(p<.05),butthe
x̅AE–x̅WBEdifference(difference=.21,p=.081)andx̅AE–x̅WAEdifference
(difference=-.03,p=.950)werenot(p>.05).
Anon-balancedecisionwasmadetorejectthenullhypothesisbasedontheresults
oftheabovethreetests.
Areasonableconclusionwasthat,inallprobability,teachersinschoolswhere
resultsweredeemedWBEwerelessfrequentusersofformativepracticesthan
169
weretheircolleaguesatschoolswhereresultsweredeemedtobeWAE.
AsexplainedinChapterTwo,formativepracticeswerecategorizedintofive
dimensions.Surveyitemreturnsweresubsequentlygroupedtoprovidedata
relatingtoeachofthefivedimensionsandthendisaggregatedtoidentifywhether
theactivitywasteacherfocusedorstudentfocused.
Figure4.10representsthatorganization.Itprovidesasummarydescriptorfor
eachofthefivedimensionsandauniqueacronyminparenthesisafterit;teacher
focusedandstudentfocuseditemsrelatedtoeachdimensionareidentifiedand
groupedbelowthedescriptor.
1. Clarifying and sharing learning intentions and success criteria (LISC):
Teacher focus: 9a, 9c & 9e Student focus: 9b, 9d & 9f
2. Engineering effective classroom discourse and using learning tasks that elicit evidence of student learning (CDEL):
Teacher focus: 10a, 10b, 10c & 10f, 10g & 10h Student focus: 10d
3. Providing feedback that moves learners forward (FTAL): Teacher focus: 9h, 11a – e, 12a – g, 14b & 14e Student focus: 14a
4. Activating students as instructional resources for one another (and the teacher) including peer assessment (ASIR):
Teacher focus: 15a, 15b & 15c Student focus: 9g, 10e, 13a, 13b & 13c
5. Activating students (and teachers) as the owners of their own learning including self-assessment (ASTL):
Teacher focus: 14c, 14d, 14f, 14g, 14h & 15d, 15e Student focus: 13d, 13e & 13f
Figure 4.10 Survey questions sorted to show teacher or student as the lead actor
170
Examplesfromthesurveytoillustratethedistinctionbetweenteacherandstudent
focusareprovidedinTable4.14.
Notethatstrategiesfurtherdownthelistareabouthelpingstudentstoexercise
greatercontrolovertheirlearning(Mitchelletal.,2009).Thisisrelevanttothe
discussioninChapterFiveaboutthedegreetowhichself-regulationwasevident.
Table 4.14 Sample items from the online survey with a teacher or student focus
Teacher focus
Student focus
Q9c explain to students the indicators or success criteria I will be looking for in their work
Q10h I explain my responses / thinking
Q10f I use test or assignment items and tasks as stimulus for discussion (in class)
Q11e (provide feedback) advice about how to improve
Q12c (feedback) refers to misconceptions
Q14c I evaluate lessons and record ideas for change next time
Q14f, g & h access and use information in class…about assessment for learning
Q15a collaborate with my science teacher colleagues to develop a shared understanding of what progression in science learning looks like
Q9d allow students some input in deciding what success criteria are to be applied
Q9f ask students why they think they are being asked to do the proposed activities
Q9g encourage peer feedback based on success criteria
Q10d ask students to explain their thinking
Q10e use the “think-pair-share-report” strategy
Q13d (students) self-assess by redoing work to a higher standard
Q13e (student self-) selection of items for a portfolio
Q13f self-assess by getting students to keep a journal of their reflections in their own words (on what they have learned in science lessons)
Q14a students give feedback on my teaching
171
Thedescriptivestatisticsfortheseparateteacherfocusedandstudentfocused
subsetsofitemsforQs9-15areprovidedinTable4.15.Thegraphical
representationsoftheteacherfocusedandstudentfocusedmeansareprovidedin
Figure4.11(secondandthirdverticalbarsineachgroup).
Table 4.15 Descriptive statistics TAFL and SFAL (n = 84)
School group n x̅ s σx̅
AFL for teachers
WBE 32 3.84 .35 .06 AE 28 4.04 .33 .06 WAE 24 4.05 .33 .07 Total 84 3.97 .35 .04
AFL for students
WBE 32 3.40 .43 .08 AE 28 3.56 .64 .12 WAE 24 3.59 .54 .11 Total 84 3.51 .54 .06
Figure 4.11 Formative practice means for all items, teacher items and student items (n = 84)
172
Basedontheabovetableandmeansplots,itwouldappearthatthesamplemean
forteacherfocuseditemsinschoolsdesignatedasWBEwaslowerthanthesample
meansfortheircolleaguesinbothAEandWAEschools,butthatthedifferences
areborderlinestatisticallysignificant.Themeansforstudentfocuseditemsdidnot
appeartobestatisticallysignificantlydifferentwhentheconfidencelevelspreads
weretakenintoaccount.
Normalityandhomogeneityofvariancetestswereperformedonthedatasubsets
relatedtoteacherfocusedandstudentfocuseditemswithinQs9-15.Table4.16
presentstheresultsofthatanalysis.
Table 4.16 Tests for normality and homogeneity of variance on assessment for learning (AFL) responses data sets (n = 84)
Shapiro-Wilk tests AFL for teachers WBE W32 = .987, p = .963
AE W28 = .914, p = .025* WAE W24 = .961, p = .453
AFL for students WBE W32 = .917, p = .017* AE W28 = .960, p = .353 WAE W24 = .958, p = .399
Levene test AFL (teachers) F 2,81 = .421, p = .658
AFL (students) F 2,81 = 1.796, p = .173
*sample failed the Shapiro-Wilk normality test (p < .05)
Thetestresults(Table4.16)didnotsupporttheuseofparametrictestsfor
comparingmeans(smallandunequalsamplenumbersinallthreegroupsandin
theteacherfocusedandstudentfocuseddatasets,onedatasetineachfailedthe
testsfornormality).
173
Basedonthatassessment,thenonparametricKruskalWallisANOVAtestwas
appliedtothedatasets.TheresultsareprovidedinTable4.17.
Table 4.17 Nonparametric ANOVA on AFL ALL, AFL teacher and AFL student means (n = 84)
Statisticallysignificantgroupmeansdifferences(p<.05)werefoundfortheall
itemsdata(χ2(2)=6.695,p=.035)andthemeansfortheteacherfocuseditems
(χ2(2)=6.704,p=.035).Therewerenostatisticallysignificantdifferences(p>.05)
betweenthemeansforstudentfocuseditems(χ2(2)=2.529,p=.282).
Welchrobusttestsofmeansequalityproducedstatisticallysignificantresults(p
<.05)fortheallitem(Qs9-15)data(WelchF2,50.737=4.236,p=.020)andthe
teacherfocuseddata(WelchF2,52.620=3.365,p=.042)butnotforthestudent
focusdata(WelchF2,49.209=1.283,p=.286)wherep>.05.
TheGames-Howellmultiplecomparisonsanalysisreturnedastatistically
significantdifferencebetweentheallitems(Q9toQ15)meanfortheWBEgroupof
schools(x̅WBE=3.86)andtheallitemsmeanfortheWAEgroupofschools(x̅WAE=
4.10).Themeansdifferencewas0.24,p=.033whichislessthanthe.05threshold
forstatisticalsignificance.Nostatisticallysignificantdifferenceswereshownfor
theteacherfocuseditemsorstudentfocuseditemmeans.
174
OnthebasisoftheparametricandnonparametricANOVAontheallAFLitemdata
setandsubsequentposthocanalysis(WelchtestandGames-Howellmultiple
comparisonstests),itisreasonablerejectthenullhypothesisandtoconcludethat
teachersinschoolswhereresultsaredeemedWBEmakelessfrequentuseof
teacherfocusedformativepracticesthantheircolleaguesinschoolswhereresults
weredeemedWAEbutthatnodistinctionbetweenthegroupscouldbemadeon
thebasisofdifferencesinstudentfocus.
Giventhattherewasastatisticallysignificantmorefrequentuseofteacherfocused
formativepracticesbyWAEteachersthantheirWBEcolleagues,thenextstepwas
totestforstatisticallysignificantdifferencesbetweenthemeansforitemsrelated
toeachofthefivedimensionsofformativepracticeineachschoolgroup.
Inordertodeterminewhichofthedimensionsmightpresentgroupmeansthat
werestatisticallysignificantlydifferent,Welchtestsformeansequalitywere
performedonthefivesubsetsofsampledataforeachofthedimensions.The
resultsofthosetestsarepresentedinTable4.18.
Table 4.18 Welch statistics for robust equality of means
Dimension WelchFdf1,df2 Statistic Significance
LISCAll F2,51.823 .460 .634
CDELAll F2,52.205 3.684 .032
FTALAll F2,50.494 4.522 .016
ASIRAll F2,51.2.6 1.714 .190
ASTLAll F2,50.650 3.475 .039
Shadingindicatesdimensionswherestatisticallysignificantmeansdifferenceswerefound
Theresultsofthetestsonthefirstandfourthdimensionsofformativepractice
revealednostatisticallysignificantdifferencesbetweenthegroupmeans.
Statisticallysignificantdifferenceswerefoundbetweengroupmeansforthe
second,thirdandfifthdimension.Forthosedimensionsthenullhypothsiswas
rejectedandtheattributionofthosedifferencesisreportedbelow.
175
4.2.3.1LEARNINGINTENTIONSANDSUCCESSCRITERIA(LISC)
Thisdimensionofformativepracticeisaboutlearningintentionsandsuccess
criteriabeingmadeexplicitbyteachersfor(orby)students.Theitemswereabout
whodeterminedwhatwastobetaughtandlearnedandwhyandhowitwouldbe
assessed.MeansdataandplotsareprovidedinTable4.19andFigure4.12
respectively.
Giventhattherewerenostatisticallysignificantdifferencesbetweenthegroup
means,onlythedescriptivestatisticsforthisdimensionwillbeprovidedhere.
Table 4.19 LISC combined means
School group n x̅ s σx̅
Mean for LISC
WBE 32 4.10 .46 .08 AE 28 4.20 .42 .08 WAE 24 4.12 .48 .10 Total 84 4.14 .45 .05
Figure 4.12 LISC means plots
176
Themeansspreadsforthethreegroupsamplesshowthatteacherledactivity
comparedtostudentopportunitiestosetlearningintentionsandchoose(or
formulate)successcriteriadonotoverlapandarethusstatisticallysignificantly
different.
FindingsfromtheLISCsubsection
From the above it is reasonable to conclude that teachers in all three school groups more
often take the lead when it comes to establishing learning intentions and success
criteria. They do this at self-reported frequencies between sometimes and often.
Teachers report that they involve students between seldom and sometimes in
negotiating learning intentions or success criteria.
4.2.3.2CLASSROOMDISCOURSETHATPRODUCESEVIDENCEOFLEARNING(CDEL)
Thisdimensionofformativepracticeisaboutclassroomdiscourseeliciting
evidenceoflearningforboththeteacherandstudents.Theitemsassociatedwith
thisdimensionwereaboutquestioninganddiscussioninclassandtheuseof
assignmentsandassessmentitemsasthestimulusforthatdiscussion.
TheWelchstatisticreportedaboveinTable4.18forthisseconddimensionshows
therewerestatisticallysignificantdifferencesbetweenoneormorepairsof
samplemeans.Themeansandmeanplotsfortheteacherandstudentfocused
combinedandseparateddataforitemsrelatedtoCDELareshowninTable4.20
andFigure4.13respectively.Thisdatawereexaminedtoseewhethertheteacher
focused(TCDEL)orstudentfocused(SCDEL)datameansorbothwerestatistically
significantlydifferent.
AnexaminationofthemeansspreadsinFigure4.13suggeststhatthemeansfor
bothteacherfocusedandstudentfocuseddatarelatingtoCDELinatleasttheWBE
andWAEschoolsmaybestatisticallysignificantlydifferent.Subsequenttestingfor
normalityandhomogeneityofvarianceinthedataisreportedinTable4.21(note
thatthestudentfocuseddataisbasedononlyoneitem,10d.Thatitemwasabout
thefrequencyofopportunitygiventostudentstoexplaintheirthinking.
177
Table 4.20 CDEL combined, TCDEL & SCDEL means
School group n x̅ s σx̅
Mean for CDEL combined
WBE 31 4.00 .41 .07 AE 28 4.16 .32 .06 WAE 24 4.28 .35 .07 Total 83 4.14 .38 .04
Mean for TCDEL
WBE 31 3.91 .40 .07 AE 28 4.09 .31 .06 WAE 24 4.20 .37 .08 Total 83 4.06 .38 .04
Mean for SCDEL
WBE 31 4.52 .68 .12 AE 28 4.57 .63 .12 WAE 24 4.75 .44 .09 Total 83 4.60 .60 .07
Figure 4.13 CDEL combined, TCDEL, SCDEL means
178
Table 4.21 Tests for normality and homogeneity of variance on CDEL data sets (n = 84) Shapiro-Wilk tests CDEL combined WBE W = .928, p = .038*
AE W = .949, p = .185 WAE W = .931, p = .104
CDEL teachers WBE W = .936, p = .062 AE W = .902, p = .013* WAE W = .944, p = .204
CDEL students WBE W = .656, p = .000* AE W = .675, p = .000* WAE W = .542, p = .000*
Levene tests CDEL (ALL) F 2,81 = .011, p = .989 CDEL (teachers) F 2,81 = .123, p = .884 CDEL (students) F 2,81 = .128, p = .053 *sample failed the Shapiro-Wilk normality test (p < .05)
ThenonparametricANOVA(Table4.22)didshowstatisticallysignificant
differencesbetweenatleastonepairofmeans(p<.05)andthatthatdifference
wasrelatedtotheteacherfocuseddata(TCDEL).
Table 4.22 Nonparametric ANOVA: ALLCDEL, CDEL teacher and CDEL student means (n = 84)
179
TheGames-Howellmultiplecomparisonstestresults(Table4.23)follow.
Table 4.23 TCDEL & SCDEL Games-Howell multiple comparisons test
Dependent Variable
(I) School group by ES
(J) School group by ES
Mean Diff (I-J) SE Sig.
95% CI
Lower Bound
Upper Bound
TCDEL
WBE AE -.17769 .09295 .145 -.4015 .0462
WAE -.28741* .10480 .022 -.5403 -.0345
AE WBE .17769 .09295 .145 -.0462 .4015
WAE -.10972 .09553 .490 -.3413 .1218
WAE WBE .28741* .10480 .022 .0345 .5403
AE .10972 .09553 .490 -.1218 .3413
SCDEL
WBE AE -.05530 .17070 .944 -.4661 .3555
WAE -.23387 .15142 .279 -.5993 .1315
AE WBE .05530 .17070 .944 -.3555 .4661
WAE -.17857 .15004 .465 -.5414 .1843
WAE WBE .23387 .15142 .279 -.1315 .5993
AE .17857 .15004 .465 -.1843 .5414
* Grey shading indicates significantly different means
TheGamesHowellanalysisfortheteacherfocused(TCDEL)data,revealedthatthe
thex̅WAE-x̅WBEpairdifference(difference=.29,p=.022)wasstatistically
significantbutthex̅AE–x̅WBEpairdifference(difference=.18,p=.145)andthe
x̅WAE-x̅AEpairdifference(difference=.11,p=.490)werenot.Forthestudent
focused(SCDEL)meansthetestshowednostatisticallysignificantdifference
betweenthegroupmeans.
FindingsfromtheCDELdataanalysis
Fromtheaboveanalysisitwasreasonabletoconcludethatteachersinschools
whereresultsweredeemedtobeWBE,comparedtotheircolleaguesinschools
whereresultsweredeemedtobeWAE,weremorelikelytoaskclosedquestions,
lesslikelytouseopen-endedquestionsorallowwait-timebeforeanswers,oruse
assignmentsandassessmenttasksasstimulusfordiscussion.Teachersinthe
sampleofWBEschoolswerelesslikely(39%)toasktheirstudentstoexplaintheir
thinkingthantheircolleaguesinWAEschools(75%).
180
4.2.3.3FEEDBACKTHATADVANCESLEARNING(FTAL)
Thisdimensionofformativepracticeisaboutfeedbackthattakeslearning
forward.
TheWelchstatisticforrobustequalityofmeansreportedinTable4.18forthis
dimension(F2,50.494 =4.522,p=.016)indicatedthattherearestatistically
significantdifferencesbetweenoneormoreofthegroupmeans.Thefollowing
analysiswillshowwhichofthosemeanspairsarestatisticallysignificantly
different.
ThemeansandmeansplotsareshowninTable4.24andFigure4.14respectively.
ThedataforSFTALisbasedononeitem(14a)whichaskshowoftenstudentsare
giventheopportunitytoprovidefeedbackontheteachingtheyreceive.
Table 4.24 FTAL combined, TFTAL & SFTAL means
School group n x̅ s σx̅ Mean for FTAL combined
WBE 32 3.38 .29 .05 AE 28 3.59 .36 .07 WAE 24 3.60 .35 .07 Total 84 3.51 .34 .04
Mean for TFTAL
WBE 32 3.42 .31 .05 AE 28 3.64 .39 .07 WAE 24 3.66 .36 .07 Total 84 3.56 .37 .04
Mean for SFTAL
WBE 30 3.30 .75 .14 AE 28 3.82 .82 .16 WAE 23 4.00 .85 .18 Total 81 3.68 .85 .09
181
Figure 4.14 FTAL combined, TFTAL, SFTAL means
FromobservationofthemeansandrelatedconfidenceintervalspreadsinFigure
4.14,itwouldappearthatstatisticallysignificantmeansdifferencesmightbefound
inboththeteacherfocusandstudentfocusdata.
TheFTALteacherdatasetsatisfiedthenormalitytests(p>.05)butthethree
studentdatasetsallfailed(p<.05);allthreedatasetspassedtheLevene
homogeneityofvariancetests(seeTable4.25).
Table 4.25 Tests for normality and homogeneity of variance FTAL responses data sets (n = 84)
Shapiro-Wilk tests FTAL for teachers WBE W = .968, p = .439
AE W = .948, p = .174 WAE W = .953, p = .310
FTAL for students WBE W = .830, p = .000* AE W = .848, p = .001*
WAE W = .856, p = .003*
Levene tests FTAL (ALL) F 2,81 = .560, p = .574 FTAL (teachers) F 2,81 = .411, p = .664 FTAL (students) F 2,81 = .004, p = .996
*sample failed the Shapiro-Wilk normality test (p < .05)
182
ThenonparametricANOVA(Table4.26)indicatedthatatleastoneofthepairsof
meansforboththeteacherandstudentdatasetswerestatisticallysignificantly
different(χ2TFTAL(2)=8.713,p=.013and(χ2SFTAL(2)=11.100,p=.004).
Table 4.26 Nonparametric ANOVA on FTAL ALL, FTAL teacher and FTAL student means (n = 84)
TheGames-HowellmultiplecomparisonsresultsareincludedinTable4.27.
Table 4.27 TFTAL & SFTAL Games-Howell multiple comparisons (n = 84)
Dependent Variable
(I) School group by ES
(J) School group by ES
Mean Diff (I-J) SE Sig.
95% CI Lwr
Bound Upr
Bound
TFTAL
WBE AE -.22228* .09138 .048 -.4428 -.0017 WAE -.23736* .09200 .035 -.4604 -.0144 AE WBE .22228* .09138 .048 .0017 .4428 WAE -.01508 .10432 .989 -.2671 .2370 WAE WBE .23736* .09200 .035 .0144 .4604 AE .01508 .10432 .989 -.2370 .2671
SFTAL
WBE AE -.52143* .20661 .038 -1.0192 -.0237 WAE -.70000* .22440 .009 -1.2443 -.1557 AE WBE .52143* .20661 .038 .0237 1.0192 WAE -.17857 .23574 .731 -.7494 .3922 WAE WBE .70000* .22440 .009 .1557 1.2443 AE .17857 .23574 .731 -.3922 .7494
* The grey shading indicates a statistically significant difference
183
FortheTFTALdata,thex̅WAE-x̅WBEpairdifference(difference=.24,p=.035)and
thex̅AE–x̅WBEpairdifference(difference=.22,p=.048)werestatistically
significantbutthex̅WAE-x̅AEpairdifference(difference=.02,p=.989)wasnot.
FortheSFTALdata,thex̅WAE-x̅WBEpairdifference(difference=.70,p=.009)and
thex̅AE–x̅WBEpairdifference(difference=.52,p=.038)werestatistically
significantbutthex̅WAE-x̅AEpairdifference(difference=.18,p=.731)wasnot.
Thus,statisticallysignificantmeansdifferenceswerebothidentifiedand
confirmed.
FindingsfromtheFTALsubsection
FromtheaboveanalysisteachersatschoolswhereEVresultswereWBE
(comparedtotheircolleaguesatWAEandAEschools)weremorelimitedinthe
rangeofoptionsusedtoprovidefeedbacktotheirstudentsanddidsoless
frequently.WBEteacherswerelesslikelytoseekstudentfeedbackontheir
teaching,lessresponsivetostudentfeedbackontheirteaching,andlessinclinedto
changethenextstepinalessoninresponsetofeedbackfromstudents.
ItwasalsoappropriatetoconcludefromthisanalysisthatontheoneSFTALitem
askingabouttheopportunityforstudentstoprovidefeedbackabouttheteaching
theyexperience,teachersinWBEschoolswerelesslikelytoinviteit(closerto
seldomthansometimes)comparedwiththeircolleaguesatWAEschoolswhosaid
theyinviteditsometimes.
Ononeitem(Q9h)whichaskedabouttheuseofdigitaltechnologytoprovide
feedbackduringalesson,teachersinthethreegroupsampleshadasimilarlow
responserate,withmostsaying(53%)theydidn’tknowaboutitorwereunsure
aboutitorneveruseditforfeedback.
4.2.3.4ACTIVATINGSTUDENTSASINSTRUCTIONALRESOURCES(ASIR)
Thisdimensionexplorestheopportunitiesthatmightbeprovidedforstudentsto
workcollaborativelywithpeersasateacherwouldworkwiththeircolleagues.
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TheWelchstatisticforrobustequalityofmeansreportedinTable4.18forthis
dimension(F2,51.2.6=1.714,p=.190)indicatedthattherearenostatistically
significant(p>.05)differencesbetweenoneormoreofthegroupsamplesmeans.
OnlythemeansandmeansplotswillbeprovidedasshowninTable4.28and
Figure4.15respectively.
Table 4.28 ASIR combined, TASIR & SASIR means
School group n x̅ s σx̅
Mean for ASIR combined
WBE 32 3.88 .40 .07 AE 28 4.08 .47 .09 WAE 24 4.02 .45 .09 Total 84 3.99 .44 .05
Mean for TASIR
WBE 31 4.63 .50 .09 AE 28 4.74 .49 .09 WAE 24 4.60 .49 .10 Total 83 4.66 .49 .05
Mean for SASIR
WBE 32 3.43 .52 .09 AE 28 3.68 .69 .13 WAE 24 3.65 .57 .12 Total 84 3.58 .60 .07
Figure 4.15 ASIR combined, TASIR, SASIR means
185
ObservationoftherelativedifferencebetweentheTASIRandSASIRsamplemeans
showsthatthedifferencesineachgrouppairwerestatisticallysignificantly
different.
FindingsfromtheASIRsubsection
Themainfindinghereisthatacrossthethreegroupsofschoolscombined,
teachersineachsamplesaidtheyworkcollaborativelymoreoftenthansometimes
withcolleaguesonassessmentrelatedtasks.However,theyonlyprovidetheir
studentswithopportunitiestoworkcollaborativelyorprovidefeedbacktoeach
otherseldomtosometimesinaboutequalmeasure.
4.2.3.5ACTIVATINGSTUDENTS(ANDTEACHERS)ASOWNERSOFTHEIRLEARNING(ASTL)
Itemsrelatingtothisdimensionofformativepracticescanvassarangeofactivities
forteachersandstudentsdesignedtopromoteself-assessmentleadingto
meaningfullearning(afactorconceptanditsconnection/stootheraspectsofa
particularcontextthatisunderstoodbythelearnerattheveryleast).
Table4.29andFigure4.16providethedescriptivestatisticsandgraphsofthe
meansforthisdimension.
186
Table 4.29 ASTL combined, TASTL & SASTL means
School group n x̅ s σx̅
Mean for ASTL combined
WBE 31 3.49 .47 .08 AE 28 3.74 .62 .12 WAE 24 3.84 .52 .11 Total 83 3.68 .55 .06
Mean for TASTL
WBE 31 3.66 .52 .09 AE 28 4.00 .61 .12 WAE 24 4.07 .60 .12 Total 83 3.89 .60 .07
Mean for SASTL
WBE 31 3.11 .57 .10 AE 28 3.16 .91 .17 WAE 23 3.26 .69 .14 Total 82 3.17 .73 .08
Figure 4.16 ASTL combined, TASTL, SASTL means
187
Acrossthethreegroupscollectively,themeansfortheteacherandstudentdata
arestatisticallysignificantlydifferent.Thatsaid,thedatasetswereanalysedto
locatewhichofthemeanspairswerestatisticallysignificantlydifferent.Alldata
setspassednormalityandhomogeneityofvariancetests(p>.05),asshownin
Table4.30.
Table 4.30 Tests for normality and homogeneity of variance on ASTL data sets (n = 83) Shapiro-Wilk tests ASTL WBE W = .951, p = .169
AE W = .954, p = .252 WAE W = .948, p = .248
ASTL for teachers WBE W = .961, p = .317 AE W = .948, p = .172 WAE W = .929, p = .093
ASTL for students WBE W = .933, p = .055 AE W = .951, p = .211 WAE W = .961, p = .476
Levene tests ASTL (ALL) F 2,80 = 1.451, p = .240 ASTL (teachers) F 2,80 = .372, p = .690 ASTL (students) F 2,79 = 2.984, p = .056
ThenonparametricANOVAindicatesthattherewerestatisticallysignificant
differencesbetweenatleastonepairofthemeansforthecombinedscoresand
thatthatdifferenceislocatedwiththeteachercomponent(TASTL)asshownin
Table4.31.
188
Table 4.31 Nonparametric ANOVA on ASTL ALL, ASTL teacher and ASTL student means (n = 83)
TheGames-Howellmultiplecomparisonsprocess(Table4.32)confirmedthatthe
meandifferencebetweentheWAEandWBEforTASTLwasstatisticallysignificant
(difference=.41,p=.030)becausep<.05.
Table 4.32 TASTL & SASTL Games-Howell multiple comparisons
Dependent Variable
(I) School group by ES
(J) School group by ES
Mean Diff (I-J) SE Sig.
95% CI
Lwr Bound
Upr Bound
TASTL
WBE AE -.34101 .14862 .065 -.6993 .0173
WAE -.40649* .15409 .030 -.7797 -.0333
AE WBE .34101 .14862 .065 -.0173 .6993
WAE -.06548 .16798 .920 -.4715 .3405
WAE WBE .40649* .15409 .030 .0333 .7797
AE .06548 .16798 .920 -.3405 .4715
SASTL
WBE AE -.04724 .19976 .970 -.5316 .4371
WAE -.15334 .17604 .661 -.5811 .2744
AE WBE .04724 .19976 .970 -.4371 .5316
WAE -.10611 .22396 .884 -.6475 .4353
WAE WBE .15334 .17604 .661 -.2744 .5811
AE .10611 .22396 .884 -.4353 .6475
* Means are statistically significantly different (p < .05)
189
FindingsfromtheASTLdimension
TherelevantfindingswerethatteachersinWAEschools,comparedtotheir
colleaguesinWBEschools,morefrequentlyself-monitortheirteaching,usea
greatervarietyofresourcestoinformtheirassessment-relatedworkandengage
moreinprofessionaldiscussionsaboutsyllabusintentionsandwhatismeantby
progressioninsciencelearning.
Allthreegroupsamplesofteachersindicatedtheyseldomprovidestudentswith
opportunitiestoacquirelearninghowtolearnskillssuchasredoingworktoa
higherstandard,self-selectingitemsforaportfolio(orexplainingtheirchoicesfor
inclusion)orkeepingareflectivejournal.
4.2.4Setfourresults:RespondentData
Dataandinformationaboutteachersandtheirschoolsweresoughtinthefinal
sectionoftheonlinesurvey.Table4.33presentstheaggregateddataprovidedby
teachersfromallthreegroupsofschools.
190
Table 4.33 Data about respondents and their schools Question Response/s 16. Gender: nF = 54 (63%)* nM = 24 17. Years teaching: 0-5 yrs:
n = 10
6-10 yrs: n = 12
11-15 yrs: n = 12
15+ yrs:
n = 44 (56%) 18. Science teacher by training /qualifications:
Yes: n = 76 (95%) No:n = 4
Other qualifications: 4 listed, only one not obviously science related 19. Head teacher: Yes: n = 39 (48%) No: n = 42 (52%) 20. Highest science teaching qualification (n = )
BA + Dip Ed 55 (70%) BTeach (4 yrs) 12 MTeach (5 yrs) 7 Doctorate or PhD 4 Other 3
21. Year training completed: earliest: 1973 latest: 2015
22. Where trained (n = ) completely overseas: 8 overseas and in Australia: 5 completely in Australia: 65 (76%)
23. I teach / have taught Y7-9 classes (n = )
this year 69 (87%) last year 2 the year before last 3 more than three years ago 5
Note. Numbers in bold show the mode. Because most respondents did not identify themselves or their school, it is not possible to provide a meaningful summary of the figures for Q 24-27 inclusive. Q 24 asked for the number of Y8 classes at your school; Q 25 asked for the number of full time teachers at your school; Q 26 asked for the number of part-time teachers at your school and Q 27 asked about part-time science teachers; it seems that almost all schools had part-time science teachers (from 1-3) in 2016. * DE employment figures for 2015 show that 61.7% of permanent secondary teachers are male. (nF = number of females; nM = number of males)
Ahigherproportionoffemalescienceteachersrespondedthanmales(twotoone)
eventhoughtheproportionsofscienceteachersinDepartmentschoolsisthree
malestotwofemales.Morethanhalftherespondentswereinthemost
experiencedcategory.Around1in20scienceteachersinthesampleherehave
morethanthebasicqualificationtoteachscience.Allbutonehadaqualification
thatwasmostlysciencebased.Halftherespondentswereheadteachers.
191
4.3Otherfindings
Attentionisdrawnheretofindingsthatwillbereferredtointhediscussionof
answerstotheresearchquestions(ChapterSix).
Thefirstisabreakdownofrespondentstothesurveyintermsofteaching
experienceineachofthethreeschoolgroups(WAE,AEorWBA).
4.3.1Teacherexperienceandstudentachievement
Theproportionofteacherswith15ormoreyearsteachingexperienceineachof
thethreegroupswas:44%(WBE);57%(AE)and56%(WAE).However,an
ANOVAtocomparethebetweengroupmeansforteachingexperience(F2,80=
2.567,p=.083)showedthattherewerenostatisticallysignificantdifferences(p
>.05)whenitcametocomparingrespondentexperience.
4.3.2TeacheruseofEVstudentsurveyfeedback
Thesurveywasdesignedtoprovidefeedbacktoteachersabouttheirstudents’
experiencesofscienceatschool,includingwhatstudentsthoughtofthetestitself,
aboutsciencelessons,aboutscience,intentionstostudysciencelaterinschool,
whichschoolsubjectstheylikedmost(threetochoosefromoffifteenprovided),
andwhichsubjecttheythoughttheylearntmostin(threetochoosefromoffifteen
provided).
Threeitemsintheonlinesurveyaskedteacherswhetherintheprevious12
monthstheyhad:
• lookedattheresultsfromthestudentsurveyinthelastyear(Q1a)
• discussedtheresultswithcolleagues(Q1g)
• discussedthoseresultswithstudents(Q1i).
TherelevantbetweengroupsANOVAstatistic(F2,82=2.563,p=.083)forthe
clusterofthreeitemsrevealedthatthebetweengroupsamplemeanswerenot
192
statisticallysignificantlydifferent(p>.05).Thus,descriptivestatisticsforall
surveyrespondents(n=85)arepresentedbelowinTable4.34andFigure4.17.
Table 4.34
YES counts for student survey items Total Frequency Percent Cumulative percent
0 26 30.5 30.6 1 19 22.4 52.9 2 26 30.6 83.5 3 14 16.5 100.0
Total 85 100.0
Figure 4.17 Frequency verses item sets for student survey (none to three yes responses)
Justover30%ofteachershadnotengagedwiththestudentfeedbackatall.Fewer
thanoneinfive(16%)teachershadlookedatanddiscussedtheresultswith
colleaguesandstudents.
193
4.4Keyfindingsfromthesurveyanalysis
Thissectionsummarisesthesurveyfindingsastheyrelatetothefirsttworesearch
questions.Thesurveydidnotaddresstheissueofwhy(orwhynot)teachersmade
useoftheEVprogramresources.Dataandinformationtoanswerthatpartofthe
twoquestionsisprovidedinChapterFive.
Wherefindingsweredescribedasstatisticallysignificantthesamplefindings
generalisetotherelevantpopulationfromwhichthesamplesweretaken.The
expressionWAEteachersisshorthandforsayingteachersatschoolswhereEV
resultswereWAE(wellaboveexpectation).AEorWBEteachershavecomparable
meaningsexceptthatthereferenceistotherelevantexpectation.
Researchquestionone:WhatusearescienceteachersmakingoftheEV
programincludingSOLOandwhyisitusedornotused?
1. Justover70%ofsurveyrespondentshadlookedatthefeedbackfromthe
studentsurvey.
2. TeachersatschoolswhereresultsweredeemedtobeWBEmakelessuse
overallofEVresultsandresourcestosupporttheirassessment-relatedwork
thandotheircolleaguesatschoolswhereresultsaredeemedtobeAEorWAE.
3. TherewerenostatisticallysignificantdifferencesbetweenAEandWAE
teachers’engagementwiththeEVprogram.
4. InrelationtoEVBwhichwasaboutdiscussingresultswithcolleagues,66%of
thetotalteachersamplehaddiscussedthetestitemandtaskanalysis,49%had
discussedtheresultsofthestudentsurvey,and33%haddiscussedthestudent
profileinformation.
5. EVCwasaboutdiscussionwithstudents.22%ofthetotalsamplehaddiscussed
theitemortaskanalysiswithstudentsand18%haddiscussedtheresultsof
thesurveywithstudents.
6. EVEwasaboutusingEVresourcesintheclassroom.45%ofthetotalsample
hadusedtheteachingstrategiesprovidedintheSMARTpackageand68%had
useditemsandtasksfromEVtestsintheirschoolassessments.
194
7. EVFwasaboutengagementbeyondschool.TwoteachersfromtheAEsample
hadwrittenitemsfortheEVtest;twoteacherseachfromtheAEandWAE
samplehadevaluateditemsforthetest;39%ofthetotalsamplehadmarked
extendedresponsetasks;and30%ofthetotalsamplehadattendedworkshops
abouttheEVprogram(differenttotrainingformarking).
8. Thefirstcategory(EVA)askedteacherstosaywhethertheyhad,inthe
previoustwelvemonths,lookedatEVresultsforthestudentsurvey(fortheir
class),theanalysisofanswerstotheextendedresponsetasks,andindividual
studentprofileresults.TeachersinWBEschoolshadnotaccessed(viewed)this
informationasmuchastheircolleaguesinWAEschools.
9. Thefourthcategory(EVD)askedteacherswhethertheyhadintheprevious
twoyearsaccessedEVrelatedmaterialsinTaLE(theDepartment’sinternal
teachersupportwebsite),SMARTprovidedfeedbackonEVresultsaswellas
adviceaboutteachingstrategiestoaddresssciencemisconceptionsandthe
separatelyproducedmarkingmanualsforextendedresponsetasks.Again,
teachersinWBEschoolshadnotaccessedtheseresourcesasmuchastheir
colleaguesinWAEschools.
10. Thesixthcategory(EVF)askedwhetherteachersintheprevioustwoyearshad
usedEVtestitemsandtasksintheirowntestsorasmodelstoworkwith.
TeachersinWBEschoolshaddonesolessthantheircolleaguesinAEschools.
11. Theseventhcategory(EVG)askedwhetherschoolshadusedEVresultsto
informchangestofaculty(teachingandlearning)programsintheprevioustwo
years,TeachersinWBEschoolsmadelessuseofEVresultsinthatprocessthan
hadteachersinAEschools.
12. AllthreegroupsofteachersratedtheirunderstandingoftheEVprogramas
acceptableorhigher.Teacherself-ratingsofEVprogramunderstandinginthe
AEandWAEgroupswashigherthanintheWBEgroup(goodcomparedto
acceptable).
13. MostteachersinthethreegroupsidentifiedthatthepurposefortheEV
programwastoprovidefeedbacktoteachersaboutteaching,progressin
learningand/ortheirteachingandlearningprograms.
195
14. FewerWBEschools(threeschools)indicatedthattheywouldtakeupthe
VALID10testcomparedtoAEorWAEschools(sixschoolseach).
15. Fewerthan20%ofrespondentshad‘accessed’SOLO;fewerthan10%reported
usingittoinformfacultypolicyorasabasisforreportingtoparents.
16. ThemostcommonlymentionedsourceoflearningaboutSOLOwasreportedby
respondentsaseitherEVmarkingorworkshopattendance,andthesemadeup
aroundonethirdofallresponsestothequestionaboutwheretheyhadlearnt
mostaboutSOLO.
17. SevenpercentofrespondentssaidtheyhadnotheardofSOLO.
18. Theoveralllevelofself-reportedunderstandingofSOLObyrespondents
rangedfrompoortoacceptable.
Researchquestiontwo:Whatformativepracticesareevidentintheworkof
scienceteachersandwhyaretheyusedornotused?
19. Inrelationtotheuseofformativepracticesoverall,therewerestatistically
significantdifferencesbetweenWBEandWAEteachers.TeachersinWBE
schoolsusedformativepracticeslessfrequentlyintheirteachingthandidtheir
colleaguesinWAEschools.Teachersinallthreegroupsmoreoftendecidedthe
formativepracticestobeusedratherthansharedecisionmakingwithstudents
onwhattasksweretobedoneandwhyandhowtasksweretobedoneand
assessed.
20. Overall,AEteachershadmoreincommonwiththeirWAEcolleaguesthanWBE
colleagueswhenitcametofrequencyofuseofformativepractices.
21. Whenitcametolearningintentionsandsuccesscriteria(LISC),whichwasthe
firstdimensionofformativepractice,teachersinallthreesamplesprovided
studentswiththelearningintentionsandsuccesscriteria(betweensometimes
andoften)morethanstudentswereaskedtoidentifyorchoosethem(between
seldomandsometimes).
22. Theseconddimensioninvolvingclassroomdiscourseelicitingevidenceof
learning(CDEL)revealedthatWBEteachersweremorelikelytouseclosed
questions;lesslikelytouseopen-endedquestions;lesslikelytoallowwait-
timebeforeansweringandlesslikelytouseassignmentsandassessmenttasks
196
asstimulifordiscussionthanweretheirWAEcolleagues.TeachersintheWAE
sampleofschoolsweremostlikelytoaskstudentstoexplaintheirthinking
(moreoftenthansometimes)whencomparedtoeithertheircolleaguesinthe
WBEorAEsamples.
23. Inrelationtofeedback(thethirddimensionofformativepractice),WAE
teacherscomparedtoWBEteachersweremorelikelyto:usegradeslinkedto
syllabusexpectations,providefeedbacktostudentsaddressing
misconceptions,refertosuccesscriteriaorsyllabusintentionsandweremore
responsivetostudentfeedbackontheirteaching.WAEteachersweremore
inclinedtochangethenextstepinalessoninresponsetofeedbackfrom
studentsandwerethemostlikelytoaskstudentstoprovidethemwith
feedbackontheirteaching.
24. Themostfrequentresponsefromallthreesamplesofteacherstotheitem
askingabouttheuseofdigitaltechnologytomonitorlearningprogressduring
alessonwasnever.
25. Intermsofworkingcollaborativelywithpeers(dimensionfour)therewereno
statisticallysignificantdifferencesbetweenpracticesacrossthesamplesof
respondents.Teacherscollectivelysaidtheyworkcollaborativelymoreoften
thansometimeswithcolleaguesonassessmentrelatedtasks.However,they
onlyprovidetheirstudentswithopportunitiestoworkcollaborativelyseldom
tosometimesinaboutequalmeasure.
26. Thefifthdimensionofformativepracticeisabouttakingresponsibilityfortheir
ownlearning.WAEteachersmodellearning-how-to-learnstrategieswith
studentsandcolleaguesmorefrequently(sometimes)thantheirWBE
colleagues(seldom-sometimesequally).
27. Overall,teachersinthethreesamplesindicatedtheyseldomprovidestudents
withopportunitiestoacquiretheskillsneededtotakecontroloftheirown
learning.
197
4.5Summaryoffindingsinrelationtoscienceteacheruseofformative
practices
Theanalysisoftheresponsesbyscienceteacherstotheonlinesurvey(phasetwo)
producedstatisticallysignificantfindingsabouttheuseofformativepracticesand
EVresults.InschoolswhereEVresultswerewellaboveexpectation(WAE),
comparedtoschoolswhereEVresultswerewellbelowexpectation(WBE),science
teachersweremorefrequentusersofactivitiesassociatedwiththefollowingthree
(offive)dimensionsofformativepractice:
• discourseelicitingevidenceoflearning(seconddimension)
• theprovisionoffeedbackknowntoprogresslearning(thirddimension)
• theuseofandmodeling(topeersandstudentsalike)ofgoodlearning
behaviours,includingself-assessment(fifthdimension).
Therewerenostatisticallysignificantdifferencesinthefrequencyofteacher
practicesrelatedtothefirstandfourthdimensionofformativepracticesfor
sampledteachersineachofthethreeschoolgroups.Aswell,thefrequencywith
whichteachersengagestudentsincollaborativeworkwitheachotherand
opportunitiesforpeerassessmentiscomparableacrossallthreesamplesandless
frequentthantheydowithcolleagues.
Thenextchapterprovidesadditionalcontextforthesefindinginspecific
assessmentnarrativesgeneratedforcasestudyschools.Italsoexplorestheextent
towhichcasestudyschooldataconfirmorrefutethethreepredictionsmadein
Section3.6.Thepredictionsaredesignedtotesttwoclaimsthatareatthecoreof
thisresearch.Thefirstisthatthedualmeasureofscientificliteracyandeffectsize
ofteachingvestedintheregressionresidualisvalid;andthesecondisthat
formativepracticesareassociatedstronglywithhigherachievementand
engagementwithsciencelaterinsecondaryschoolyears.Theconfirmation(or
otherwise)ofthesecondpredictionisanimportantcontributiontoanswering
researchquestionthree.
198
CHAPTERFIVE:PHASETHREE-COMPARINGCASESTUDYSCHOOLS
Thischapterreportsfindingswithwhichtoanswerresearchquestionthree.This
questionis
Doestheuseof(andifso,howdo)formativepracticesbyteachersimprove
students’EVresultsandlaterachievementinandengagementwithscience?
Achievementdataandevidenceofengagementwithsciencefromfivepairsofcase
studyschoolsprovidedthebasisforfindingsrelatedtoimprovement(or
otherwise)inYear8scienceresultsandagainattheendofYear10(later
achievement).SchoolswerepairedonthebasisofhavingcomparableSEAscores
andstatisticallysignificantlydifferentresiduals.ComparableSEAscoresarescores
thatarenotsignificantlydifferentinthestatisticalsense.
ResidualsareimputedtobeameasureoftheimpactofscienceteachingonEV
results;thebiggerthepositiveresidual,thegreaterthecontributionofscience
teachingtothatEVresultintermsofthemarkgain(themeasureofimprovement)
aboveapredictedmarkbasedonNAPLANresults,asexplainedinChapterThree.
Thebiggertheresidualdifferencethebetterbecauseitimprovesthechanceof
identifyingwhatmightbecausingthedifferencesinthoseresults.These
differences,iftheyexist,arelikelytobefoundinthecasestudyschoolnarratives
ofassessment-relatedworkprovidedinAppendixH.
Evidenceofengagementwasprovidedintheformof:
• measuresofstudentresponsestosixitemsintheEVstudentsurvey
• proportionsofstudentscompletingseniorsciencecourses(relativetothe
state)
• informationincasestudyschoolnarrativesaboutassessment-relatedwork.
Thefindingsrelatedtothreepredictionslinkingresidualdifferencesto
achievementandengagementprovidethebasisforansweringthequestion.The
predictionswere:
199
1. AttheendofYear8comparableschoolswiththebiggestresidualswillhave
betterEVresultsandengagementfiguresthanschoolswithsmalleror
negativeresiduals.
2. AttheendofYear10comparableschoolswiththebiggestresidualsatthe
endofYear8willhavebetterresultsthanschoolswithsmallerornegative
residuals.
3. AttheendofYear12comparableschoolswiththebiggestresidualsatthe
endofYear8willhaveahigherproportionoftheirstudents(relativeto
English)completeseniorsciencecoursesthanschoolswithsmalleror
negativeresiduals.
Findingsrelatedtothefirstpredictiondemonstratetherelationshipbetween
teacheruseofformativepractices(indicatedbythesizeandpolarityofthe
residual)andthesizeofEVresultforaschool.Ahighlypositivecorrelation
betweentheresidualandEVresultforcomparableschoolswouldbeastrong
indicationthattheuseofformativepracticeswassomehowinvolved.
Findingsrelatedtothesecondpredictionmayshowanongoingpositive
correlationbetweenahighpositiveresidualforaschoolattheendofYear8and
continuinghighachievementinsciencetwoyearslater.Thisresearcherwas
speculatingthatlaterhighachievementatthisschoolwouldbeassociatedwith
eithercontinuingusebyteachersofformativepracticesoralastingeffecton
studentsfromthatuse.
Findingsrelatedtothethirdpredictionmayshowthatlaterhighengagement(Y12
sciencecompletions)ispositivelycorrelatedwitheitherhighachievementatthe
endofYear8orhighengagement(asmeasuredbyscoresonthesixitemsfromthe
studentsurveycompletedwiththeEVtest)orboth.Thisresearcherwas
speculatingthathighengagementwouldbeassociatedwithcontinuinguseby
teachersofformativepracticeorbealastingeffectonstudentsfromthatuse.
Thelastingeffectreferredtointhecontextofpredictionstwoandthreeisthe
acquisitionofself-regulationandrelatedlearningskillsbystudentsasaresultof
theirexposuretoformativepractices.Thisresearcher’sassumptioninframingthe
200
predictionswasthatmorestudentsatWAEschoolswouldbecomeself-regulated,
autonomousandskilledlearners(ofscience)asaresultoftheirrelativelyhigh
exposuretothosepracticesthanatAEandWBEschools.
Thecredibilityofthisassumptionissupportedbytheresearchintolearninghow
tolearnreportedinChapterTwo.Purposelyteachingstudentsthefivestrategies
offormativeassessmenthasbeendemonstratedtoproducestudentswhouse
“goodlearningbehaviours”(Boyleetal.,2001,p.200).Evidenceoftheextentto
whichteachershaddirectedtheireffortstohelpingstudentsacquirethesefive
skillsetswasprovidedintheresultsoftheteachersurveyreportedinChapter
Four.
Self-regulatedstudentsarealsomotivatedtokeeplearning.Theextentofstudent
likingfortheirscienceexperienceatschoolisapossibleindicatoroftheextentto
whichstudentshadacquiredthedispositionforcontinuedlearninginscience
impliedbyself-regulation.Ameasureofstudentlikingforsciencewasavailablein
thescoresstudentsreturnedonthesixitemsofthestudentsurveyreportedby
casestudyteachers.Anecdotalevidenceofstudentattitudestosciencewasalso
providedinthecasestudyschoolnarrativesofassessment-relatedworkpractices.
Thejustificationforsomeofthecontentinthischapter,particularlythe
identificationofspecificexamplesofassessment-relatedpracticesassociatedwith
successfulcasestudyschools,arisesfromtheintentiontoreportthefindingsto
participatingteachersandtotheDepartment.Afurtherintentionisthatthe
findingsbeusedtosupportprofessionallearningthatleadstogreateruseof
formativepracticesinscienceclassrooms.Thisisconsistentwiththe
transformativeintentoftheresearchasoutlinedinChapterThree.
Table4.1inChapterFourshowedthe394participatingschoolssortedfrom1to
394onthebasisoftheirresidualrankingandsubsequentdivisionintofivegroups.
Schoolsinthetop,middleandbottomgroupswereinvitedtoparticipateinthe
research.Aswasreportedthere,ofthe101surveyreturnsfromteachers,42
teachersidentifiedthemselvesandthe36schoolstheywereworkingat.
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5.1Thecasestudyschools
Table5.1reportsselectedquantitativedataforall36self-identifiedschools.That
dataweresourcedfromtheDepartmentandtheMySchoolwebsite(theSEAscore).
Schoolidentitieswereprotectedbyreplacingtheschoolnamewithanidentifier
code.The16casestudyschoolsengagedwitharehighlightedinthetable.
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Table 5.1 Schools that identified themselves including case study schools (shaded) SCHOOL CODE n = SEAS PEV RPEV AEV RAEV SR RSR
PCWAE1 24 2.7 85.40 127 89.95 46 2.68 1 MCWAE1 19 2.8 78.89 374 82.14 286 1.85 3 PCWAE2 44 1.8 81.90 306 84.79 165 1.69 5 PCWAE7 30 2.3 83.19 237 85.81 129 1.59 8 MCWAE2 54 6.9 87.96 68 90.65 41 1.57 10 PCWAE3 55 2.0 81.26 325 83.64 221 1.43 12
MCFSWAE1 106 8.6 99.90 11 101.97 3 1.19 23 MCWAE3 150 6.2 87.45 77 89.47 54 1.17 24 PCWAE4 161 5.5 89.09 56 91.05 37 1.12 29 PCWAE5 49 2.3 82.57 273 84.44 175 1.08 36 MCWAE6 136 6.0 89.26 51 90.50 43 0.73 58 PCWAE6 28 0.9 82.31 289 83.34 235 0.60 78
n = 12 MGFSAE1 113 9.1 100.76 7 100.23 7 0.12 174
MGAE1 108 3.0 81.65 316 81.86 298 0.12 176 PCAE1 108 3.7 85.40 129 85.55 136 0.08 186 MCAE8 70 2.6 78.62 377 78.82 373 0.06 192 MCAE2 88 3.9 84.94 147 84.85 161 0.03 201 MCAE3 204 3.8 84.30 179 84.28 185 0.01 207 MCAE4 93 2.2 82.19 292 82.16 285 -0.01 213 MCAE5 146 4.1 85.39 128 85.38 141 -0.02 214
MGFSAE2 141 8.3 101.32 5 101.00 6 -0.09 232 MCAE6 89 1.5 79.19 368 79.01 370 -0.01 235 MCAE7 141 2.4 83.42 227 81.91 284 -0.16 244
n = 11 MBFSWBE2 133 8.2 98.99 14 97.99 17 -0.58 313
MGWBE1 142 7.1 89.60 48 88.34 67 -0.75 330 MCWBE7 153 8.2 91.70 31 90.47 44 -0.76 331 PCWBE2 68 2.1 83.01 248 81.42 316 -0.81 335
MCPSWBE3 123 6.9 92.33 26 90.59 42 -1.03 360 PCWBE6 97 2.9 84.16 184 82.14 287 -1.20 368
MGFSWBE1 135 8.9 101.69 3 99.28 14 -1.42 376 PCWBE1 51 1.7 82.97 253 80.61 340 -1.44 377 MCWBE5 79 2.1 85.09 140 82.54 275 -1.48 378 MCWBE4 47 0.7 76.30 392 73.63 394 -1.58 382 MCWBE3 148 4.0 85.70 118 82.85 256 -1.69 383
MCPSWBE2 144 5.4 90.92 37 87.61 78 -1.91 388 MCPSWBE1 34 6.3 92.93 23 89.63 51 -1.93 389
n = 13 Note. School code: First letter is (P)rovincial or (M)etropolitan (ACARA defined). Second letter is (C)oeducational, (G)irls or (B)oys. FS = fully selective entry / PS = partially selective entry. Residual group WAE – AE – WBE then a final number to differentiate schools. Columns: n = number of students whose results were used to perform the regression / SEAS = socio-educational advantage score / PEV = predicted EV result / RPEV = rank out of 394 based on predicted EV result / AEV = actual EV result / RAEV = actual EV rank out of 394 / SR = standardised residual used to designate schools as WAE – AE – WBE / RSR = school rank order based on residual (N = 394).
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Fromthesecodesonecanidentifythecategoryofschool(describedinChapter
One).Atleastonefullyselectiveentryschool(FS)wasfoundineachgroupof
schools(WAE,AE&WBE).OneoftheFSschoolswascoeducational(C)andthe
othertwoweregirls(G)schools.Provincial(P)schoolswererepresentedinall
threegroupsandtherewerethreeintheWAEgroup.Provincialschoolswereall
coeducational(C)schools.TheWBEgroupincludedtwopartiallyselectiveentry
(PS)coeducational(C)schoolsaswellasonefullyselectivegirls(G)school.There
weremetropolitan(M)schoolsinallthreegroups.
TheschoolsinTable5.1arerankedaccordingtostandardisedresiduals(RSR)
showninthefarright-handcolumn.LinesseparateWAEfromAEandAEfrom
WBEschools.NotethatgenerallyspeakingactualEVresults(AEV)higherthan
predictedEVresults(PEV)areassociatedwithpositiveschoolresiduals(second
columnfromtheleft);AEVresultslowerthanPEVresultsareassociatedwith
negativeresiduals.
TheSchoolProfilepageforeachschoolontheMySchoolwebsiteshowsthe
proportionsofstudentsatthatschoolinfourquartersfromthemosteducationally
disadvantagedtothemosteducationallyadvantaged(LtoR).Schoolprofiledata
forYear7studententryfrom2010to2013wasaveragedoverthefouryears.As
explainedinSection3.6,theprofilequarterswereconvertedtoasingleSEAscore
(SEAS)usingalineartransformationasafurthermeasuretoprotecttheschool’s
identity.TheSEAscoreisanindependentmeasureofthecollectivelearning
potentialofstudentsataschool.ThecolumnheadedSEASshowsthefourquarters
ofthesocioeducationalprofileforstudentsatthatschoolasasinglescore.
Theaimwastohaveamongthecasestudiesthesixhighest-rankedschoolsfrom
theWAEcategory,thesixschoolsclosesttoazeroresidual(AEcategory)andthe
sixlowest-rankedschools(intheWBEcategory).Tothisend,teacher-identified
schoolsineachresidualcategorywereinvitedtoparticipateinorderoftheir
residualsize.
Table5.2providesdescriptivestatisticsforthethreegroupsofschoolschosenon
thebasisoftheirresiduals.
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Table 5.2 Mean standardised residuals and SEA scores
Residual means for the three populations
Residual means for self-identified schools
Mean SEA scores for self-identified schools
Residual means for case study schools
Mean SEA scores for case study schools
WAE μ = 1.02 σ = 0.39 N = 85
x̅ = 1.42 s = 0.55 σx̅ = 0.16 n = 12
x̅ = 3.86 s = 2.24 σx̅ = 0.65
n = 12
x̅ = 1.8 s = 0.45 σx̅ = 0.19
n = 6
x̅ = 3.85 s = 2.4 σx̅ = 0.94 n = 6
AE μ = -0.01 σ = 0.10 N = 88
x̅ = 0.01 s = 0.09 σx̅ = 0.03
n = 11
x̅ = 4.06 s = 2.44 σx̅ = 0.74
n =11
x̅ = -0.02 s = 0.05 σx̅ = 0.03 n = 4
x̅ = 4.4 s = 2.84 σx̅ = 1.42
n = 4
WBE μ = -1.08 σ = 0.44
N = 85
x̅ = -1.28 s = 0.46 σx̅ = 0.13
n = 13
x̅ = 4.96 s = 2.85 σx̅ = 0.79
n = 13
x̅ = -1.67 s = 0.22 σx̅ = 0.09 n = 6
x̅ = 4.6 s = 3.0 σx̅ = 1.21 n = 6
Note. μ = population mean / x̅ = sample mean / σ = standard deviation (population) / s = standard deviation (sample) / σx̅ = standard error (sample) / N = population number / n = sample number
ThesecondcolumninTable5.2(readinglefttoright)showstheresidualmeans
foralltheschoolsineachofthethreegroupsinvitedtoparticipate.Thethird
columnhastheresidualmeansforself-identifiedschoolsincludingthecasestudy
schools.ThefourthcolumnistheSEAscoredatafortheself-identifiedschools.The
fifthcolumnfromtherightshowstheresidualmeansforthecasestudyschools,
andthesixthcolumnshowsthemeanSEAscoresforthecasestudyschools.
Theresidualmeansforthethreeschoolgroups(column1intheTable5.2)are
separatedbyalmostthreestandarddeviations,whicheffectivelyprovidesthree
differentpopulationsfromastatisticalperspective(theoverlapattheextremesof
theresidualdistributionsisapproachingonepercentorless).Thisdistinctionis
important,aswasshowninChapterFourwhenANOVAfindingsbasedonsample
datacouldbeappliedtoalltheschoolsinthatpopulation.
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Figure5.1representsvisuallythemeansandrelatederrorbars(atthe95%
confidenceinterval)forthedataincolumnstwo,four,threeandfive(readingLto
R)inTable5.2.
Figure 5.1 Graphical representation of descriptive statistics for identified (ID) and case study (CS) schools combined and case study (CS) schools separately
Thedatasetsforallidentifiedschools(n=36)fromTable5.1weretestedusing
SPSSfornormality(Shapiro-Wilktest)andhomogeneityofvariance(Levene
tests).Threeoftheninedatasets(AEschoolsSEAscoresandEVresultsandWAE
schoolsEVresults)failedthenormalitytest(p<.05).Allthreedatasetsof
residualsfailedthehomogeneityofvariancetest(p<.05),whichwasnot
unexpectedgiventhenon-randomwaytheschoolsassociatedwitheachgroup
wereselected.Correlationresults(n=36)arereportedintermsofthe
nonparametricSpearmancoefficient(r),degreesoffreedom(df)andatwotailed
significanceofeither.01or.05(asshownwiththereportedcorrelation
coefficient).
206
ThecorrelationbetweentheresidualsandactualEVresults(r=.18,df=34,p
=.283)wasslightlypositivebutnotstatisticallysignificant(p>.05).
ThecorrelationbetweentheSEAscoresandactualEVresults(r=.84,df=34,p
=.000)wasveryhighlypositiveandhighlystatisticallysignificant.TheSEAscore
andresidualcorrelation(r=-.08,df=34,p=.627)wasslightlynegativeandnot
statisticallysignificant.Thesetwofindingswerehopedforgiventhattheresidual
wassupposedtoshowaneffectofteachingoncestudentbackgroundandschool
factorshadbeentakenoutoftheEVresult.
AnANOVAperformedontheSEAscoresandresidualsrelatedtoeachofthethree
schoolgroupsfurthersupportedthecorrelationresults.Welchteststatisticsfor
thethreedatasets(WSEAS(2,12.525)=.281,p=.759)indicatethatthemeanSEA
scoresforeachofthethreegroupswerenotstatisticallysignificantlydifferent.
However,themeansfortheEVresultsforthethreegroups(WEV(2,13.133)=4.98,p
=.025)didshowatleastonestatisticallysignificantdifferencebetweenapairof
thethreegroupmeans.TheTukeymultiplecomparisonstest(EVresultspassed
thehomogeneityofvariancetest)showsstatisticallysignificantmeansdifferences
betweentheEVresultsfortheWAEandWBEschoolgroups(x̅wae-x̅wbe=4.94,p
=.03).ThefindingfromthattestingwasthattheEVresultsofWAEschoolshada
statisticallysignificantlyhighermeanthantheEVresultsofWBEschools.Thiswas
confirmationofastatisticallysignificantassociationbetweenhighEVresultsand
highpositiveresidualsandlowerEVresultsandlownegativeresiduals.
AsexplainedinSection3.2,theintentionwastohavetheresidualmeansforthe
WBEandWAEschoolsaswidelyseparatedaspossible.Thiswastoprovidethe
bestpossiblechanceoffindingdifferencesintheteachingassociatedwiththe
residualsgiventhattheimpactofclassroomteachingonlearningisarelatively
smallcontributiontotheaccountedforvariabilityinachievement(around30%
accordingtoHattie(2003b)).Theextenttowhichtheresidualsrepresent
“maximumvariability”(Flyvbjerg,2011,p.306)canbeseeninthemeansplots
(thefirstandsecondplotsontheleftinFigure5.1)andtheANOVAresults.
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Theteachersurveyanalysis(ChapterFour)attributedtheresidualdifferencesto
thefrequencywithwhichteachersineachofthethreeschoolgroupsused
activitiesassociatedwiththefivedimensionsofformativepractice.EVresultsthat
werewellaboveexpectation(WAE)werestatisticallysignificantlyassociatedwith
morefrequentusebyteachersinWAEschoolsofactivitiesassociatedwiththe
second,thirdandfifthdimensionsofformativepracticeassummarisedinSection
4.5.
5.2Threepredictionsandthecasestudyschools
Thissectionexplainsthedataaboutachievementandengagementrelevanttothe
threepredictions.Researchquestionthreeaskshowformativepracticeshelp
improvestudentsresultsandachievement.Thehypothesiswasthatexposureto
formativepracticesproducesself-regulatedautonomouslearners.Asoutlinedin
theopeningsectionofthischapter,theintentionwastoprovidecredibleevidence
thatself-regulatedautonomouslearnersaretheengineersoftheirimproved
achievementandengagementinscience.
5.2.1Predictionone:Year8achievementandengagement.
Participatingteachersatthecasestudyschoolswereaskedtotranscriberesults
fromtheSchoolsMeasurement,AssessmentandreportingToolkit(SMART)intoa
proformasentwellbeforetheschoolvisit.Teacherswereaskedtobringthe
completedproformatotheinterviewwhenitwouldbediscussed.Theproformais
providedasAppendixE.ResultsarereportedinSMARTagainstsix,SOLO-related,
levels.Schoolswereaskedtoaggregatetheresultsintothreeachievementbands.
Levels5and6werelabelledastopbandresults;levels3and4weremiddle-band
resultsandlevels1and2werebottom-bandresults.
Achievementdataisreportedinthreeachievementbandsforfiveresult
categories:anoverallEVresult;aknowledgeandunderstandingresult;an
extendedresponsetaskresult;aworkingscientificallyresult;anda
communicatingscientificallyresult.Forthepurposeofthisexercise,resultsfrom
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fourofthefiveachievementcategorieswereaskedfor(theknowledgeand
understandingcategorywasnotprovidedforontheproforma).
EngagementdatawerealsoreportedinSMARTtoteachersagainstachievement
levels.Teacherswereaskedtorecordtheengagementscoresagainstthethree
achievementbandsintheproforma.Thesurveyhad21itemsinit.Onlysixwere
chosenforreportingonintheproforma.TheitemswerelabelledAtoFforthe
purposeofthisanalysis.
StudentsrespondedtoItemsAtoDbychoosingfromafour-pointscale:strongly
disagree,disagree,agree,stronglyagree.Individualresponsestothesurveyitems
wereaggregatedbyschool,groupsofschools,andthestateandreportedbackto
schoolsasgraphswherethescalerangedfrom-2to+2.TheresultsforItemsAto
Darereportedonadifferentscaleinthisthesis.Theeffectistoshiftthescaleso
thatthelowestpossiblescoreiszero.Thecloserthescoreistozero,thestronger
thedisagreementwiththeitemstatement.Ascoreclosetofourmeansastrong
collectedstudentagreementattheschoolwiththestatements.Anevenmixof
agreementanddisagreementintheschoolpopulationwouldproduceascoreclose
to2.
ThestatewideresponsesforItemsAtoDfollow.TableK.2inAppendixIhasthe
fulldatasetforthecasestudyschoolsforthesixItems.
InrelationtoItemA,whichsaid:IwanttostudyasciencesubjectinYears11
and12,topbandstudentsagreed(2.78outof4.00),middleandbottomband
studentsdisagreed(1.76and1.37respectively).
ItemBsaid:ScienceisthehardestsubjectIlearn.Topbandstudentsdisagreed
(1.56outof4.00),middlebandstudentsdisagreedalso(1.69)butbottomband
studentsagreed–just–thatitwasthehardest(2.03).Disagreementinresponseto
thisitemwastakenasapositiveresult.
209
ItemCsaid:Inprimaryschool,Ienjoyedlessonsthatwereaboutscience.Top
bandstudentsagreed(2.76outof4.00),middleandlowerbandstudentsalso
agreed(2.35and2.01respectively).
ItemDsaid:Insecondaryschool,Ienjoysciencelessons.Topbandstudents
agreed(2.83outof4.00),middlebandstudentsalsoagreed(2.23)butbottom
bandstudentsdisagreed(1.91).
ItemEaskedstudentstonominatetheirthreefavouritesubjects(15werelisted
includingscience).Ofthetopbandstudents,13.5%nominatedscienceinthat
group,asdid6.65%ofmiddlebandstudentsand4.58%ofbottombandstudents.
ItemFaskedstudentstonominatethethreesubjectstheythoughttheylearned
mostin.Again,15options,includingsciencewereprovided.Ofthetopband
students,25.13%(oneinfour)nominatedscienceinthatgroup,asdid16.5%of
middlebandstudents(justunderoneinseven)and9.71%ofbottomband
students(aboutoneinten).
Thefollowinggeneralisationscanbemadeaboutstudentresponsestotheitems
acrossthestate.Thehigherthestudents’achievementband:
• thegreaterwastheiragreementwiththepropositionsinItemsA,C&D
• thegreaterwastheirdisagreementwiththepropositioninItemBthat
sciencewasthehardestsubjecttheystudied
• thegreaterwastheproportionofstudentsnominatingscienceasoneof
theirthreeoptionsforItemsE&F.
5.2.2Predictiontwo:Year10achievement
The2011Year8cohortofstudentsprovidedthe2013Year10results,the2012
Year8cohortprovidedthe2014Year10results,andthe2013Year8cohortthe
2015Year10results.Schoolstranscribedontotheproformathegradepatterns
endorsedbytheBoardforeachyearfrom2009.DatafromYear10resultswere
usedinconjunctionwithYear8EVresultstoprovidefindingsinrelationto
210
predictiontwo.Datafrom2012to2015wasaggregatedhereforthepurposeof
interschoolcomparison.
Thisresearcher’sassumptionwasthattheimpactofsyllabuschanges(introduced
in2003)andtheintroductionoftheEVtestin2007onformativepracticeswould
havebeeninstitutionalisedintoschoolpracticesby2011andcontinuedupuntil
2014,afterwhichanewsyllabusbecamethebasisforEVtesting.Correlation
statisticsreportedinSection5.4wereappliedonthatassumption.
5.2.3Predictionthree:Year12engagement
Predictionthreeinvolvestheproportionsofstudentsataschoolcompletingthe
Year11and12(senior)sciencecoursesofferedattheschool.Astudentcouldtake
fromonetothreeofthefollowingfourcourses,dependingonthesizeoftheschool
andresourcesavailabletoit:Biology,Chemistry,EarthandEnvironmentalScience,
andPhysics.Manystudentstraditionallytookoneortwoofthesecourses.Itwas
veryrareforaschooltoprovidestudentswiththreesciencecoursesinYear12.A
fifthcourse,SeniorScience,wasanoptionforstudentsnotwantingtoundertake
furtherstudyinscienceafterschool.AllfivecoursesweredevelopedbytheBoard.
Someschoolsofferedinthesenioryearscoursesinsciencetheyhaddeveloped
andhadendorsedbytheBoard,butnoneofthecasestudyschoolsreported
offeringadditionalBoard-endorsedcoursesintheyearsofinterestforthisproject.
Year12completionsfrom2011to2015wereprovidedbyschoolsonthe
proforma.OnlyYear12completionsfor2015weredirectlycomparablewiththe
Year8cohortthatsattheEVtestin2011(Year8resultswereonlyavailablein
SMARTfrom2011to2014).Nevertheless,dataforYear12completionsforthe
years2012to2015,inclusive,areprovidedinthetablesandwereconsideredin
assessingthedegreeofsupportforpredictionthree.Studentschoosetheir
subjectsforstudyinYears11and12half-waythroughYear10.Intheexperience
ofthisresearcher,thegreatmajorityofstudentscompletethesubjectstheychoose
then.Aswell,giventhattheEVtesthadbeeninplacesince2007forallYear8
students,anyimpactoftheEVprogramandteacheruse(ornot)offormative
practicesonlaterengagementwould,arguably,haveoccurredbeforethat.Asfor
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Year10results,Year12completionsfrom2012to2015wereusedinthe
correlationanalysesreportedinSection5.4.
Thissectionidentifiedanddescribedachievementandengagementdataprovided
byteachersincasestudyschools.Thenextsectionwillendeavortoshowthatthe
schoolsinwhichstudentshadthegreatestexposuretoformativepractices(WAE
schools)wereabletosustainbetterthanexpectedachievementandhigherlevels
ofengagementwithsciencebeyondYear8.Thequantitativedataweresupported
whereappropriatewithqualitativeevidencefromtheassessment-relatedwork
narrativestosupportthecredibleattributionofself-regulationandautonomyto
learnersinthoseschools.Thedataprovidedbyschoolsandnarrativeevidencewill
bediscussedinthecontextofpairedschoolcomparisonsreportedinthenext
section,Section5.3.
5.3Comparedcasestudyschools
Pairedschoolswiththesame(orcloselymatched)SEAscoresarearguedtohave
studentswithequivalentcollectivelearningpotentialsbyvirtueofthe
socioculturalcapitaltheybringtoschool.Theresidualistakentobethemeasure
oftheextenttowhichexposuretoformativepracticeshasenhancedstudents’
scientificliteracyandproducedanEVresultthatisabove(orbelow)expectation.
Thesurveyresultsprovideameasureofstudentsatisfactionwiththeirschool
scienceexperience.InSection5.2.1,theconnectionbetweenhigherachievement
andlevelofsatisfactionwiththeirschoolscienceexperiencewasestablishedfor
thecasestudyschools.Thissatisfactionisattributedtointerestinandmotivation
tocontinuewithlearningscienceandisthebenchmarkforengagement(asdefined
forthepurposesofthisthesisinsection3.5.5)attainedattheendofYear8.
Theassumptionofself-regulationandlearningautonomyisbasedondifferential
evidenceoflaterachievementandengagementincomparableschoolsasexplained
earlier.
212
Tableswithdataaboutachievementandengagementforeachoftheschoolsinthe
pairedcomparisonsbelowaresourcedfromdatatablespresentedinAppendixI.
Thenumbersinthosefivetableswereeithertranscribeddirectlyfromteacher-
completedproformasorderivedfromthemasexplainedinthekeysassociated
witheachtableinAppendixI.
5.3.1PairONE:PCWAE1andMCWAE1
PCWAE1isarelativelysmallprovincialschoolinthewestofthestate.Twosmall
Year7parallel,ungradedclassesareformedeachyear(around15studentsineach
class).Studentsremaininthoseclassesforthefirsttwoyearsofsecondaryschool.
Theschoolhadthelargestpositiveresidualofallschoolsinthestate.Three
scienceteachers,includingtherelievingdeputyprincipalandrelievinghead
teacherscience,attendedtheinterview,whichwentforoveranhour.The
completedproformawasbroughttotheinterview.Aselectionofassessment
artifactswasprovidedbothduringandaftertheinterview.Theschoolhad
engagedwithVALID10andplannedtocontinuedoingso.
MCWAE1isametropolitanhighschooltothewestoftheSydneyCBD.ThreeYear
7gradedclassesareformedeachYearusingfeederschooldata.Feederschooldata
ismostlyliteracyandnumeracybased.Studentsremaininthoseclasseswithfew
changesuntiltheendofYear8atleast.Thirtypercentofitsstudentintakeare
fromrefugeefamiliesandsomeofthemhavehadnoformalschooling.Many
studentsattendanIntensiveLanguageCentrebeforeenteringsecondaryschooling
attheschool.Fourteachers,includingtheheadteacher,attendedtheinterview.
TheteachershadaccessedSMARTdatabeforetheinterviewandtheproformawas
completed.Assessmentartifactswereprovidedduringtheinterviewandsome
wereforwardedlateraswell.TheschoolhadengagedwithVALID10andplanned
tocontinuedoingso.
Table5.3containsinformationaboutachievementandengagementatthesetwo
schools.ItwascompiledfromdataprovidedinAppendixI,TablesK.1&K.3.
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Table 5.3 Pair ONE selected statistics School Y8 ACH Y8 ENG Y10 ACH
SCH (%) STA ALL / 12 TOP / 16 SCH (%) STA
PCWAE1 EV = 89.95 ± 0.79 SEAS = 2.7 ± 0.22 RES = 2.68 ± 0.38
T 29 156 10 13
A-B 33 87
B 2 15 D-E 23 88
MCWAE1 EV = 82.14 ± 1.91 SEAS = 2.8 ± 0.46 RES = 1.85 ± 0.48
T 7 38 1 1
A-B 10 27
B 27 20 D-E 69 265
Y8 ACH = the proportion of Year 8 students in the top (T) and bottom (B) achievement bands. SCH (%) = school proportions represented as a percentage. STA = the proportion of students at the school expressed as a ratio (school proportion as a % over the state proportion as a %) relative to the state designated as 100. Y8 ENG = the rank order of schools based on engagement scores. ALL = all three achievement bands / 12 = the rank out of 12 non-selective schools based on the total survey scores for students at a school (the state figure is counted as a school) / TOP = top achievement band students / 16 = school rank for top band students in the 16 case study schools for which data had been provided (the state figure is counted as a school). Y10 ACH = the proportion of Year 10 students attaining grades A and B and D and E. SCH (%) = the proportion of students at a school with grades A&B and D&E represented as a percentage. STA = the proportion of students at the school as a ratio (school proportion as a % over the state proportion as a %) relative to the state designated as 100.
YEAR8ACHIEVEMENTANDENGAGEMENT
FromTable5.3itisclearthatattheendofYear8,comparedtothestate,the
proportionofPCWAE1studentsattainingtopbandEVresultswasverymuch
higher.MCWAE1,ontheotherhand,hadalowerproportionofitsstudentsinthe
topbandcomparedtobothPCWAE1andthestatewhichisconsistentwith
predictiononeintermsofachievement.
Whenwelookatengagement,asmeasuredbyresponsestothesixitemsinthe
studentsurvey(AppendixI,TablesK.5A–K.5C),attheendofYear8,when
214
comparedtoMCWAE1students,PCWAE1studentsinthecontextofthe11non-
selectiveentrycasestudyschools:
• werelessenthusiasticaboutwantingtostudysciencecoursesinthesenior
years(ranked5th;MCWAE1studentsranked1st);
• foundscienceeasier(3rdcomparedto11th);
• enjoyedtheirprimaryschoolscienceless(9thcomparedtohighest);
• enjoyedtheirsecondaryscienceclassesless(9thcomparedtohighest);
• fewerhadnominatedscienceintheirthreefavouritesubjects(10th
comparedtohighest);and,
• fewerhadnominatedscienceasoneofthethreesubjectstheylearntmost
in(9thcomparedtohighest).
PCWAE1’shighestrankingonanyoftheitemswas3rdforwantingtostudyscience
inthesenioryears(ItemA).However,thescoreonwhichthatrankingwasbased,
wasbelowthestatescore,asweretheotherfivescores.Thiswasanunexpected
resultgiventhatapositiveschoolexperienceinscienceuptotheendofYear8was
associatedwithhighachievement(reportedinSection5.2.1).Thisanomalywillbe
discussedinthesummativecommentspartofthissection.
YEAR10ACHIEVEMENT
BytheendofYear10thedistributionofresultsatbothPCWAE1andMCWAE1had
changedwhencomparedtothestate.PCWAE1topbandnumbersdecreasedfrom
threetotwoacrossthestatetonineforeverytenacrossthestate.Intheirhighest
bandresultsMCWAE1wentfromhavingtwostudentscomparedtofiveinthe
statetooneinfour.Thereducedproportionsofstudentsinthetopbandwasfar
greaterforPCWAE1thanMCWAE1.
Inthebottomband,PCWAE1numbers,comparedtothestate,increasedfromone
inseventonineforevery10inthestate.MCWAE1numbersalsoincreasedfrom
oneinfivetomorethanfivetotwocomparedtothestate.Thisresultstillhad
PCWAE1withbetteroverallresultsinsciencethanMCWAE1andconfirmed
predictiontwo.
215
YEAR12ENGAGEMENT
Table5.4showstheproportionsofYear12sciencecoursecompletionsatboth
schools.Ahigherproportion,relativetothestate,ofPCWAE1studentscomplete
sciencecoursesbytheendofYear12thandostudentsatMCWAE1.Thesefigures
confirmpredictionthree.StudentareaskedinthemiddleofYear10tonominate
coursesforthefinaltwoyearsofschooling.GiventhelowratingbyPCWAE1
studentsoftheirschoolscienceexperienceattheendofYear8,theexpectation
wouldbethatveryfewstudentswouldnominatetodosciencecoursesinthelast
twoyearsofschooling.Theapparentcontradictionwillbediscussedinthe
summativecommentspartofthissection.
Table 5.4 Year 12 science course completions (2013-2015 averages)
School PCWAE1 MCWAE1 Subject (state proportion%) School State School State
Biology (28.5) 40 140 32 112 Chemistry (18) 22 122 12 67 Earth and Environmental Science (2.4) N/A N/A N/A N/A
Physics (16) 22 138 14 88 Senior Science (10.4) 50 481 21 202
School = proportion of students relative to English at the school (relative to 100) State = proportions of students at the school (relative to the state set at 100) completing Year 12 courses.
COMPARATIVESUMMATIVECOMMENTSFORPAIRONE(PCWAE1ANDMCWAE1)
Thefollowingdiscussionoffindingsinrelationtothepredictionsfortheschools
comparedhereandtheircontributiontoansweringresearchquestionthreedraws
ontheschooldataprovidedaboveandreferstotheassessment-relatedwork
narrativesfortheschoolsinAppendixH.
TheexpectationfromthefindingsinSection5.2.1wasthatPCWAE1’srelatively
highresultswouldhavebeenaccompaniedbyapositiveviewoftheirschool
216
scienceexperience.Theassessment-relatedworknarratives(seeAppendixH)for
thetwoschoolshavemuchincommon.Bothrevealagroupofteachersthatgivea
highprioritytohelpingstudentsrecognisethescienceintheireverydaylivesand
theteachersgooutoftheirwaytoprovideadiversityofexperiencesfortheir
students,bothatschoolandbeyondtheschoolgates,includingshowingstudents
placeswherescienceisthebasisfortheworkbeingdonethere.Thisdiversityof
experiencesisusedasthebasisforteachingactivitiesthatprovideevidenceof
learning(intheformofwrittenandoralreports)aswellasthetraditionalpen-
and-paperteststhatteachersusetoproduceformalassessmentsforthepurpose
ofreportingtoparents.
Teachersatbothschoolsareveryawareofthelimitedliteracyskillspossessedby
manyoftheirstudentsandtheyactivelypromotetheuseofappropriatescientific
termsinstudenttalk.Wholeclassdiscussionisanimportantstrategyandstudents
areencouragedtolearnandusethevocabularyofsciencerelevanttothetopics
beingstudiedatschool.Learningintentionsandsuccesscriteriaareprominentin
theworktheydowithstudentsandteachersmakeuseofthemtoinformfeedback
tostudents.Groupworkisencouragedandsupported.PCWAE1appearstoprovide
moreopportunitiesforpeerassessment(e.g.feedbacktoeachotheronatoythat
studentsmakeandpresenttotheclass)thanMCWAE1.Bothschoolsmakeuseof
olderstudentstomentoryoungerstudents.Teachersmeetregularlyand
collaborativelyprepareteachingprogramsandassessmentissuesaswellas
sharingmarking.
Giventheabove,andtheabsenceofschoolfactorsnegativelyimpactingon
classroomenvironments(absenteeismislow,studentrelationshipsarereported
asbeinggood),thedifferenceinstudentratingoftheirschoolexperienceseemsto
berelatedtoattitudestosciencethatstudentsbringtoschool.Evidencetosupport
thiswasprovidedbystudentsinanswertoItemC,whichaskedabouttheir
enjoymentofclassesinprimaryschoolwheresciencewasthefocus.PCWAE1
studentsranked9thoutof11here,andMCWAE1studentsranked1st.The
comparablequestion(ItemD)forsecondaryscienceclassesproducedasimilar
result(9thcomparedtofirst).Inresponsetoaquestionaskingwhichthreesubjects
217
studentsthoughttheylearntmostin(of15provided,includingscience),PCWAE1
rankedscience9thandMCWAE1listeditthemost.
Nootherevidenceaboutstudentorcommunityattitudestosciencewas
purposefullycollectedinthisproject.Theanecdotalevidencefromteachersat
PCWAE1wasthatstudentsatthatschoolthoughttheteachersweretoughon
studentsandfolloweduponworkset.Thisresponsewasprovidedwhenteachers
whohadreadthesurveyresultsbeforetheinterviewhadthenaskedstudents
aboutit.
ItappearsthatPCWAE1’srelativelyhighaspirationtodoseniorsciencecourses
expressedattheendofYear8(3rdintheranking,butstillbelowthestate’sscore)
didcomeabout.AhigherproportionofstudentsatPCWAE1completedYear12
sciencecoursesthantheircounterpartsatMCWAE1.Itmaybethatthehigher
take-upofseniorsciencecoursesattheprovincialschoolwasapragmatic
responsetotheperceptionofmorejobopportunitiesrelatedtosciencethanother
subjectchoices.However,teachersatbothschoolshadbeenprovidingthat
informationtostudentsthroughexcursionstoplaceswheresciencewasa
requiredqualificationfortheworkobserved(medicine,agricultureand
universitiesinthecaseofPCWAE1).TeachersatMCWAE1mentionedhigh
parentalexpectationsandsupportforstudentstodowellatschool,including
buyingsciencetextbookstosupportindependentworkbystudentsonscienceat
home.
5.3.2PairTWO:MCAE2andMCWBE3
MCAE2isametropolitanschoolbetweenHornsbyandNewcastlecity.It
establishesthreeorfourmixedabilityclassesforstudentsusingfeederprimary
schoolsschooldata.Oneselectiveentryclassisestablishedforhigh-achieving
studentswithaparticularinterestinSTEM.Togainentrytothatstreamstudents
sitanentrytestsetbytheschooland/orareinvited.Studentsremainintheir
classesuntiltheendofYear8;thespecialclassendsattheendofYear9when
thosestudentshavecompletedStage5.Onlytheheadteacherwasattheinterview.
218
Assessmentartifactsandtheproformawereprovidedlater.Theschoolhad
engagedwithVALID10andplannedtocontinuedoingso.
MCWBE3isametropolitanschooltothesouth-westoftheSydneyCBD.Theschool
providesforsixYear7classesusingfeederschooldata.Atopstreamoftwolarge
gradedclassesisestablishedandasecondstreamoffourungradedclasses.The
classesremainlargelyunchangeduntiltheendofYear8.Onlytheheadteacher
waspresentattheinterviewandassessmentartifactsandresultsweresentlater.
ThestaffwerenotpreparedtoengagewithVALID10atthetimeofinterview.
ThetwoschoolshavecomparableSEAscoresbutstatisticallysignificantly
differentresidualsasshownbythedataprovidedinTable5.5
Table 5.5 Pair TWO selected statistics
School Y8 ACH Y8 ENG Y10 ACH SCH (%) STA ALL / 12 TOP / 16 SCH (%) STA
MCAE2 EV = 85.45 ± 0.48 SEAS = 3.9 ± 0.30 RES = .03 ± 0.42
T 16 86 8 12
A-B 28 74
B 7 52 D-E 25 96
MCWBE3 EV = 82.85 ± 0.29 SEAS = 4.0 ± 0.25 RES = -1.69 ± 0.13
T 12 65 12 14
nil nil
B 12 89 nil nil
Y8 ACH = the proportion of Year 8 students in the top (T) and bottom (B) achievement bands. SCH (%) = school proportions represented as a percentage. STA = the proportion of students at the school expressed as a ratio (school proportion as a % over the state proportion as a %) relative to the state designated as 100. Y8 ENG = the rank order of schools based on engagement scores. ALL = all three achievement bands / 12 = the rank out of 12 non-selective schools based on the total survey scores for students at a school (the state figure is counted as a school) / TOP = top achievement band students / 16 = school rank for top band students in the 16 case study schools for which data had been provided (the state figure is counted as a school). Y10 ACH = the proportion of Year 10 students attaining grades A and B and D and E. SCH (%) = the proportion of students at a school with grades A&B and D&E represented as a percentage. STA = the proportion of students at the school as a ratio (school proportion as a % over the state proportion as a %) relative to the state designated as 100.
219
YEAR8ACHIEVEMENTANDENGAGEMENT
MCAE2resultsarepositivelyskewedwithahigherproportionofstudentsinthe
topbandcomparedtothebottomband;MCWBE3hasahigherproportionofits
students(relativetothestate)inthebottomband.Thecomparisonhereconfirms
predictiononeinrelationtoachievement.
InrelationtoengagementwithscienceattheendofYear8,comparedtoMCWBE3
MCAE2studentswere:
• slightlylessenthusiasticabouttakingscienceinthesenioryears(8th
comparedto7thoutofthe11non-selectiveschools)
• slightlymorelikelytodisagreethatsciencewasthehardestsubjectthey
studied(5thcomparedto6th)
• likedtheirprimaryscienceclassesless(8thcomparedto6th)
• likedtheirsecondaryscienceclassesmore(7thcomparedto10th)
• proportionatelymorelikelytoincludescienceasoneoftheirthree
favouritesubjects(7thcomparedto9th)
• proportionatelymorelikelytoincludescienceinthegroupofthreesubjects
theythoughttheylearntmostin(8thcomparedto11th).
ThesefiguresshowthatMCAE2hadaslightlymorepositiveviewoftheirschool
scienceexperiencethanstudentsatMCWBE3.
YEAR10ACHIEVEMENT
MCWBE3didnotprovideanydataforYear10,sonocomparisoncanbemade
here.Asforthefirstpairofschools,Year10resultsforMCAE2changedfromYear
8toYear10.Theproportion(relativetothestate)oftopbandstudentsatMCAE2
wentfrom17comparedto20inthestatedowntothreecomparedtofourinthe
state.Theproportionofstudentsintheirbottombandwentdownfromonetotwo
inthestatetothestatefigures(almostoneforone).
220
YEAR12ENGAGEMENT
Table5.6showstheproportionsofstudentscompletingYear12seniorscience
coursesatthetwoschools.MCAE2hasproportionatelymoreofitsstudents
completingBiology,ChemistryandPhysicscoursescomparedtoMCWBE3.These
dataconfirmpredictionthree.
Table 5.6 Year 12 science course completions (2013-2015 averages)
School MCAE2 MCWBE3 Subject (state proportion%) School State School State
Biology (28.5) 57 200 21 74 Chemistry (18) 19 106 7 39 Earth and Environmental Science (2.4) N/A N/A N/A N/A
Physics (16) 10 63 9 56 Senior Science (10.4) N/A N/A N/A N/A
School = proportion of students relative to English at the school (relative to 100) State = proportions of students at the school (relative to the state set at 100) completing Year 12 courses.
COMPARATIVESUMMATIVECOMMENTSFORPAIRTWO(MCAE2ANDMCWBE3)
OfinterestherewasthefactthatMCAE2activelypromoteditselfasaSTEMschool
withaparticularinterestintheBiosciences.Thatsaid,itappearstobesucceeding
anditperformedbetterinsciencethanitscomparableschoolpair.However,given
thespecialstatusofscienceattheschool,thedifferentialonengagementwith
sciencebystudentsatthetwoschoolsisnotparticularlymarked.Aswell,students
attheendofYear8atMCAE2wereonlyslightlylessenthusiasticabouttaking
seniorscienceclassesthanwerestudentsatMCWBE3.
5.3.3PairTHREE:PCWAE2andMCWBE5
PCWAE2isarelativelysmallcoeducationalregionalschoolinthecentral-westof
thestate.TheschoolestablishesthreeYear7classeseachyearfromstudentsin
theirfeederprimaryschools.Theclassesareinitiallyungraded,butaftersix
221
monthsstudentsaregradedusingscienceassessmentresults.Classesare
reviewedeverysixmonthsandchangesmadedependingonassessmentresults.
ThiscontinuesuntilhalfwaythroughYear10.Thescienceheadteacherwasthe
maincontributorattheinterviewandhadmovedfromametropolitan
coeducationalschooltotakeupthatpositionbefore2011.Therearefourfull-time
andtwopart-timescienceteachersattheschool.Afull-timelaboratoryassistant
andapart-timeagricultureassistantsupporttheworkofthesciencedepartment.
Oneofthescienceteacherswastrainedasanagricultureteacher.Theheadteacher
saidshehadbeeninvolvedovertheyearsinjuniorandseniorsecondaryscience
syllabusconsultationprocessesaswellasreviewingitemsforinclusioninEVtests.
Anotherscienceteacherwhohadbeenattheschoolforseveralyearsjoinedthe
interviewtowardstheend.ArtifactsofYear7andYear8assessment-relatedwork
wereprovidedandtheproformawascompletedandforwardedafterthe
interview.TheschooldidthefirstoftheVALID10tests,butatthetimeofthe
interviewitwasnotplanningtocontinuewithit.
MCWBE5isamedium-sizedmetropolitancoeducationalhighschool.Overthe
yearsofinterest,itprovidedfromfourtofiveYear7classeseachyeardepending
ontheintakenumbersfromfeederprimaryschools.OneclassisacombinedYear
7-8classthathasagiftedandtalentedstudentintakeofaround15studentseach
year.Studentswantingtoenterthisclasssitsanentrancetestsetbythehigh
school.Asecondclassofhighachievingindependentlearners(identifiedbytheir
feederschools)wasalsoestablishedeachyear.Twoorthreesmallerungraded
classeswerethencreatedfromtheremainderoftheintake.Theseclassesare
retainedmostlyunchangeduntiltheendofYear8.Thescienceheadteacherhad
occupiedthepositionthroughouttheperiodofinterestandwastheonlyscience
staffmembermetwithandinterviewedatthisschool.Hispreviousschoolwasa
provincialhighschoolinthewestofthestate.Thereweresixfull-timeandone
parttimescienceteachersattheschool.ArtifactsofYear7andYear8assessment-
relatedworkwereprovidedandthedataproformawascompletedandforwarded
aftertheinterview.Thesciencedepartmenthadnoplansatthetimeofinterview
totakeupVALID10.Table5.7providesrelevantdataaboutachievementatthetwo
schools.
222
Table 5.7 Pair THREE selected statistics
School Y8 ACH Y8 ENG Y10 ACH SCH (%) STA ALL / 12 TOP / 16 SCH (%) STA
PCWAE2 EV = 84.79 ± 0.31 SEAS = 1.8 ± 0.45 RES = 1.69 ± 0.21
T 12 65 7 11
A-B 17 45
B 12 89 D-E 37 142
MCWBE5 EV = 82.54 ± 0.56 SEAS = 2.1 ± 0.11 RES = -1.48 ± 0.28
T 13 70 3 3
A-B 29 76
B 18 133 D-E 24 92
Y8 ACH = the proportion of Year 8 students in the top (T) and bottom (B) achievement bands. SCH (%) = school proportions represented as a percentage. STA = the proportion of students at the school expressed as a ratio (school proportion as a % over the state proportion as a %) relative to the state designated as 100. Y8 ENG = the rank order of schools based on engagement scores. ALL = all three achievement bands / 12 = the rank out of 12 non-selective schools based on the total survey scores for students at a school (the state figure is counted as a school) / TOP = top achievement band students / 16 = school rank for top band students in the 16 case study schools for which data had been provided (the state figure is counted as a school). Y10 ACH = the proportion of Year 10 students attaining grades A and B and D and E. SCH (%) = the proportion of students at a school with grades A&B and D&E represented as a percentage. STA = the proportion of students at the school as a ratio (school proportion as a % over the state proportion as a %) relative to the state designated as 100.
TheSEAscoresforthetwoschoolswereverylow,indicatingthatthereweremany
moresocio-educationallydisadvantagedstudentsatthetwoschoolsthan
advantagedstudents.TheSEAscoreswerecomparablebuttheirresidualswere
statisticallysignificantlydifferent.
YEAR8ACHIEVEMENTANDENGAGEMENT
AttheendofYear8,itwasclearthatPCWAE2wasoutperformingMCWBE5when
itcametoEVresults(seeTable5.7).WhileMCWBE5hadmorestudentsinthetop
band,ithadamuchgreaterproportionofitsstudentsinthebottombandthandid
PCWAE2.
223
Inrelationtoengagement,ofthe11non-selectivecasestudyschools,attheendof
Year8,comparedtoMCWBE5students,PCWAE2students:
• wereslightlylesswantingtostudyscienceinthesenioryears(ranked3rd
comparedto2nd)
• foundscienceslightlyharder(8thcomparedto7th)
• likedscienceatprimaryschoolless(7thcomparedto2nd)
• likedscienceclasseslessinsecondaryschool(6thcomparedto3rd)
• hadthelowestproportionofstudentsnominatingscienceintheirgroupof
threefavouritesubjects(MCWBE5ranked3rd)
• hadalowerproportionoftheirstudentsnominatingscienceasoneofthe
threesubjectstheythoughttheylearnedmostin(5thcomparedto3rd).
Thesefiguresareinconsistentwithpredictiononeandagainstthepattern
discussedinSection5.2.1(studentsattheWAEschoolshouldbemorepositive
abouttheirschoolscienceexperience).
YEAR10ACHIEVEMENT
InthetwoyearsfromYear8toYear10,comparedtothestate,PCWAE2’s
proportionofstudentsinthetopbandhaddeclinedandincreasedinthebottom
band.MCWBE5’sproportionoftopbandstudentshadincreasedandbottomband
proportionshaddecreased.Theseresultswereinconsistentwithpredictiontwo.
However,thereisaquestionmarkovertheassumptionofcomparabilityofthe
Year10resultsbecauseofthepatternchangeingradesfrom2011(state-wide
examrelated)to2012(whengradeswereschooldetermined).Theproportionof
A+B+CgradesinMCWBE5wentfrom72%(upto2011)to82%(2012to2015).In
thatsametimespan,PCWAE2’sresultswereeffectivelyunchanged(theywent
from62%to63%).
YEAR12ENGAGEMENT
Table5.8showstheproportionsofstudentsatthetwoschoolswhocompleted
sciencecoursesattheendofYear12.
224
TheproportionsofHSCsciencecoursecompletionsoverthethreeyearscompared
tothestatewerethesameinbothschoolsforBiology.PCWAE2hadlessinPhysics
andChemistrythanMCWBE5.PCWAE2hadmoreofitsstudentscompleteSenior
SciencethanMCWBE5.Thefindinginrelationtopredictionthreeforthispairof
schoolswasinconclusive(seethesummativecommentsbelow).However,given
thelowSEAscoresforbothschools,theproportionsofstudentscompletingsenior
sciencecourseswereabovestatefiguresinBiology,wellaboveforSeniorScience,
butclosetostatefiguresinChemistryandPhysics(proportionatelymoreWBE
studentsthanWAEstudentscompletedPhysicsandChemistry).
Table 5.8 Year 12 science course completions (2013-2015 averages)
School PCWAE2 MCWBE5 Subject (state proportion) School State School State
Biology (28.5) 38 133 38 133 Chemistry (18) 16 89 18 100 Earth and Environmental Science (2.4) N/A N/A N/A N/A
Physics (16) 13 81 17 106 Senior Science (10.4) 30 288 20 191
School = proportion of students relative to English at the school (relative to 100) State = proportions of students at the school (relative to the state set at 100) completing Year 12 courses.
COMPARATIVESUMMATIVECOMMENTSFORPAIRTHREE(PCWAE2ANDMCWBE5)
Thediscussionoffindingsforthepairofschoolscomparedhereandtheir
contributiontoansweringresearchquestionthreedrawsontheschooldata
providedaboveandreferstotheassessment-relatedworknarrativesforthe
schoolsinAppendixH.Thenarrativesforthetwoschoolsreflecttheirvery
differentprioritiesforsciencelearning.Thenarrativesforthetwoschoolsprovide
evidenceofschool-factordifferences,particularlyinrelationtosummative
assessment.
IntheWAEschool,thefocuswasonpreparingstudentstoundertakesenior
sciencecourses,andstudentsclassplacementwasreviewedeachsemesterinthe
225
lightofassessmentperformance.Thesciencedepartment’sstaffwereactive
participantsintheschool-wideliteracyprogramandprovidedoneperiodof
sciencepertimetablingcycletoit.Scienceteachersalsoprovidedstudentswith
specificsciencevocabularyhomeworklinkedtothetopicsbeingstudied.Science
teachingwashighlydifferentiatedandsensitivetostudentliteracyneeds.Talk
comesfirst,thenteacherdirectedreading(bystudentstotheclass),followedby
writing.
Considerablelaboratory-basedpracticalworkisalsoundertakenbystudentsin
thenameoflearningtheskillsofworkingscientifically.Whatistalkedaboutand
writtenishighlymanagedbyteachers.Whilstothertaskscontributetooverall
assessmentresults,therearetwoformaltestsperyear.Rubricsforscoring
studentsworkwerepreparedtoreflectlearningintentionsandsuccesscriteria
describedintheBoardsyllabus.Therubricswereprovidedtostudentsbefore,
duringandafterassessmentandfeedbackisprovidedontheextenttowhich
intentionsweremet.Studentsdoamajorresearchprojecteachyearandpractical
tests,evidencefromwhichcontributestostudents’overallassessmentinscience.
Theresearchtaskwastightlyconstrainedbyteachersandadetailedscaffoldfor
thefinalreportwasprovided.
IntheWBEschool,theprioritywasforstudentstoenjoytheirschoolscience
experiences.Thefocusforteacherswasonprovidingadiversityofrichscience
experiences,somearisingspontaneouslyoutofstudentinterest,withinand
beyondtheschoolboundary.Atthetimeofinterestforthisproject,theredidnot
seemtobeastrongemphasisonusingliteracystrategiesinscience.Assessment
waslikelytobenegotiatedwithstudents,peerassessmentwasusedtoprovide
feedbackononeofthetasks(amodel-makingexercise),andtherewasan
opportunityforself-assessmentattheendofeachtopic.Evidenceoflearningwas
collectedfromavarietyoftasksandtherewasagooddealofindividualteacher
judgmentinvolvedwhenitcametopreparingreportsforparents(andstudents).
Summativeassessmentwasalow-keyaffair(deliberately)andstudentswerenot
shiftedaroundonthebasisofresultsuntiltheendofYear8.
226
TheoverallnegativeimpressionrecordedbyPCWAE2studentsisinconsistent
withtheengagementaspectofpredictionone.Thelearningprogramsatboth
schoolsencouragetheuseofcontextstosupportteachingandlearning.At
PCWAE2,mentionwasmadeofagricultureandbiotechnologyascontextsmostly
used.TheWAEschoolhasahigh-stakes,summativeassessmentapproachwhich
hasbeenshownintheresearchliterature(Harlen&Deakin-Crick,2002)toimpact
negativelyonthemotivationtolearnofstudentswithpoorlearninghistories.As
theWAEschoolhereisaprovincialschool,thepossibilityofstudentsocio-cultural
factors(similartothoseoperatinginPCWAE1above)impactingtheengagement
scoresshouldnotbeoverlooked.
ByYear10,theachievementpatternrelativetostatefiguresattheWAEschoolis
belowthatoftheWBEschool,andcompletionsofSeniorSciencecoursestwoyears
afterthatwerenottoodissimilaratthetwoschools.Theachievementfindingsat
theendofYear10areinconsistentwithpredictiontwo(issueswithcomparing
Year10resultsnotwithstanding).However,thefindingsinrelationtoprediction
threeareinconclusive.Overall,ahigherproportionofPCWAE2studentscomplete
sciencecourses,butasmallerproportioncompletethetwomostdemanding
courses,ChemistryandPhysics.
Possibleexplanationsfortheunexpectedfindingsinrelationtothepredictionswill
bediscussedinthesummarysectionofthischapter(Section5.5).
5.3.4PairFOUR:MGFSAE2andMGFSWBE1
Threefullyselectiveschoolswereincludedforcasestudy.TheywereMGFSWAE1,
MGFSAE2andMGFSWBE1.Allthreeweremetropolitan;thefirstwasa
coeducationalschool;thelattertwobeinggirls’schools.Thetwogirls’schools
werethefocusforpairedcomparisoninthissection.Howevercommentaryand
comparisonsweremadeinvolvingallthreeschoolsasconsideredusefulto
understandingsimilaritiesanddifferencesrelevanttothepredictionsbeingtested.
Theheadteachersatthethreeschoolsofinterestinthissectionwereatthose
schoolsatthetimeofinterestforthisproject(2011–2014).Allthreeschoolseach
227
yearestablishedfromfourtofiveYear7classes.Theclasseswereestablished
usingselective-schooltestresultsandfeederschoolinformationaboutthe
students.Fromthepointofviewofscience,theclasseswereeffectivelyungraded.
OnlytheheadteacherfromtheWAEandAEschoolwereinterviewed.Thehead
teacherandsevensciencestaffmemberswereinvolvedintheinterviewatthe
WBEschool.Bothschoolsprovidedarangeofassessment-relatedartifactsfor
Years7to10.TheHTscienceattheWBEschoolbroughtapartiallycompleted
resultsproformatotheinterview.TheHTattheAEschoolhadcompletedthe
proformafortheinterview.TheWBEandAEschoolhavebothengagedwith
VALID10,andtheWAEschoolhadnoplansfordoingsoatthetimeofinterview.
Atleast94%ofstudentsinallthreeschoolswereinthetopachievementbandfor
EVresults.Noneofthethreeschoolshadanystudentsachievinglowerthanthe
middleachievementband.Studentsatfullyselectiveentryschoolsarethere
becauseoftheiroutstandingperformanceonpen-and-papertestsofgeneral
ability,literacy(includingwriting)andnumeracy.TheNAPLANpredictorsfortheir
EVresultsputtheminthereverseordertothatestablishedbytheirresiduals(see
Table5.9).
TheirSEAscores(allotherfactorsbeingequal)forthethreeschoolswerenot
comparable(seeTable5.9)shouldhavedeliveredMGFSWBE1withthebestEV
result;itcame3rd.MCFSWAE1,whichshouldhavebeen2nd,was1st,aheadof
MCFSAE2,whichcame2nd.
TheinternationalTIMSSandPISAtestresultsdonotrevealanygenderbiasin
achievementinthefirstfewyearsofsecondaryschoolinginNSWschools
(Thomson,DeBortlietal.,2017;Thomson,Wernertetal.,2017).However,thereis
internationalresearchevidencethatadolescentgirlsinthemostdeveloped
nationsarelessengagedwithsciencethanadolescentboysare(Bøe,Henriksen,
Lyons,&Schreiner,2013;Sjøberg&Schreiner,2010).Forthisreasonthe
comparisonsmadeherewillfocusonthetwogirlsschools.
228
YEAR8ACHIEVEMENTANDENGAGEMENT
Table5.9providessomedatarelevanttomakingcomparisonsandfindings
relevanttothepredictions.TheEVdataforthethreeschoolswassourcedfrom
TableK.1inAppendixI.
Table 5.9 Pair FOUR selected statistics
School Y8 ACH Y8 ENG Y10 ACH SCH (%) STA TOP / 16 SCH (%) STA
MCFSWAE1 EV = 101.97 ± 0.71 SEAS = 8.6 ± 0.16 RES = 1.19 ± 0.29
TEV 95 TER 85 TWS 80 TCS 89
511 419 412 397
4 A 63 485
MGFSAE2* EV = 101.00 ± 0.65 SEAS = 8.3 ± 0.16 RES = -0.09 ± 0.44
TEV 95 TER 85 TWS 76 TCS 89
511 419 392 397
15 A 83 639
MGFSWBE1* EV = 97.99 ± 0.54 SEAS = 8.9 ± 0.14 RES = -1.42 ± 0.02
TEV 94 TER 70 TWS 78 TCS 93
505 345 402 415
8 A 85 654
Y8 ACH = the proportion of Year 8 students. SCH (%) = school result. TEV = proportion of overall EV result in the top band / TER = proportion of results in the top band extended response tasks. TWS = proportion in the top band for working scientifically. TCS = proportion of results in the top band for communicating scientifically. STA = ratio of top band school achievement relative to the state score at 100 (ratio obtained by dividing school % proportion by state % proportion). Y8 ENG = the rank order of schools based on engagement scores. TOP / 16 = the rank out of 16 (the state figure is counted as a school). Y10 ACH = proportions of A grades at the school and relative to the state. SCH % = the proportion of Year 10 students attaining A grades. STA = the ratio of A grades at the school relative to the state set at 100 (ratio produced by dividing the school % proportion by the state % proportion). * Girls schools.
Inthiscomparison,theAEschoolwiththelowerSEAscore(8.3±0.16)hadthe
betterEVresult(101.00±0.65comparedto97.99±0.54)andahigherresidual
thantheWBEschool(-0.09±0.44comparedto-1.42±0.02).ThelowerSEAscore
fortheAEschoolisstronglysuggestiveofgreatervalueaddingtoitsEVresultthan
229
ifithadacomparableSEAscore.Fromthisperspective,theachievement
componentofpredictiononeissatisfied.
ThegreatestachievementdiscrepancybetweentheAEandWBEschoolisinthe
extendedresponsereportcategory,wheretheproportionofgirlsattheWBE
schoolwas70%comparedto85%attheAEschool.Thiswillbediscussedinthe
summativecommentspartforthissection.
ThesourcesofdataonrelativeengagementwereTablesK.5A,B&CinAppendixI.
Thecomparisonsbelowincludetherelativeorderofschools(inparentheses).The
surveyresultswerethemeasureofstudentengagementforscienceattheendof
Year8.Onlytopbandstudentsineachofthe15casestudyschoolswillbe
comparedhere.AttheendofYear8,girlsatthe:
• WBE(4th)schoolweremorepositiveabouttakingaseniorsciencesubject
(ItemA)thanweretheirAE(9th)counterparts(andbothschoolscores
werebelowthestatefigure)
• AE(13th)andWBE(14th)schoolsthoughtscienceharderthantheir
counterpartsacrossthestate(ItemB)andbothwereabovethestatescores
intheiragreement
• WBE(9th)andAE(14th)schoolsenjoyedtheirprimaryschoolscience
experiencesintheorderlisted;theAEschoolrankingwasbelowthestate
(ItemC)
• WBE(12th)andAE(15th)schoolsenjoyedtheirsecondaryschoolscience
experiencesandproportionsincludingscienceintheirthreefavourite
subjectsaslistedhere;bothschoolscombinedscoreswerebelowthestate
(ItemsDplusEscore)
• WBE(6th)andAE(12th)schoolslistedscienceinthegroupofthreesubjects
thatstudentsthoughttheylearntthemostinintheorderlisted;theAE
school’sscorewasbelowthestate(ItemF).
230
ItisclearthatforMGFSAE2,highachievementinscienceisnotassociatedwith
positiveattitudestowardscience.Possiblereasonsforthiswillbecanvassedinthe
summativecommentspartforthissection.
YEAR10ACHIEVEMENT
Theschooldataprovidedbythetwoschoolsincludedthelevels/gradesawarded
onthebasisofthepatternofresultsfromtheexternalexaminationatYear10.The
lastexamwasin2011.Therewasadiscontinuitybetweentheresultsbeforeand
aftertheYear10examended,thusthisresearcherwasreluctanttodrawany
conclusionsaboutachievementchangesrelativetoYear8andremainedsilent
aboutpredictiontwofortheseschools.
YEAR12ENGAGEMENT
Table5.10showstheproportionsofstudentsatthethreeschoolscompletingYear
12sciencecourses.OveralltheWBEschool’sproportionsofYear12completions
werelargerthantheAEschool’scompletions.Thiswascontrarytoprediction
three.
Table 5.10 Year 12 science course completions (2013-2015 averages)
School MCFSWAE1 MGFSAE2 MGFSWBE1 Subject (state proportion) School State School State School State
Biology (28.5) 34 119 20 70 22 77 Chemistry (18) 70 389 54 300 58 322 Earth and Environ. Sci. (2.4) N/A N/A N/A N/A N/A N/A
Physics (16) 46.4 288 23 144 28 175 Senior Science (10.4) 5.8 87 N/A N/A N/A N/A
School = proportion of students relative to English at the school (relative to 100) State = proportions of students at the school (relative to the state set at 100) completing Year 12 courses.
231
COMPARATIVESUMMATIVECOMMENTSFORPAIRFOUR(MGFSAE2ANDMGFSWBE1)
Thefollowingdiscussionoffindingsinrelationtothepredictionsforthetwogirls
schoolscomparedhereandtheircontributiontoansweringresearchquestion
threedrawsontheschooldataprovidedaboveandtheassessment-relatedwork
narrativesfortheschoolsinAppendixH.
FindingsinrelationtothepredictionsarequalifiedbecausetheSEAscoresarenot
comparable.ThefactthattheAEschoolhasalowerSEAscorethantheWBE
schoolprovidesconfidencethattheresidualdifferencesupportstheconclusion
thattheAEschoolsEVresultswerebetterthanexpectedduetotheirmore
frequentexposuretoformativepractices.Areviewoftheassessment-relatedwork
narrativesforthethreeschoolsandresultsinothercategoriespointstoa
differenceinemphasisonwhatwasvaluedassourcesofevidenceoflearningas
explainedinthenextparagraph.
IntheWBEschool,studentsworkedoncross-facultyprojectsandbeyondthe
schoolgates.Evidenceoflearningwasobtainedfromstudent-createdmodels,
writtenreports(usingtightlyconstrainedscaffolds)andgrouppresentations
supportedbytechnologyaswellastraditionalpen-and-papertests.Bycontrast,
theAEschoolhadastrongemphasisonwrittenevidenceoflearningdrawnfrom
traditionallaboratoryandtext-basedexperiencesmostlyprovidedwithinthe
schoolboundaries.‘Writingtolearn’wasahigherpriorityfortheAEschool.
Simplyput,studentsattheWBEschooldidnothavethesameopportunitiesto
writeanswerstoopen-endedextendedresponsetasksasstudentsintheAE
school.Thisresearchersuggeststhatdifferentialopportunityisthemain
contributortothebetterEVresultsattheAEschool.Fulleraccountsofthe
narrativesforthetwoschoolsareprovidedinAppendixH.
Predictionthreeisabouttheproportionsofstudents(relativetothestate)
completingseniorsciencecourses.Theexpectationfrompredictionthreewasthat
theAEschoolwouldhaveahigherproportionofitsstudentscompletingYear12
sciencecoursesthantheWBEschool,whichwasclearlynotthesituationhere.It
wouldappearthattheAEgirls’strongdislikeforscienceattheendofYear8
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continuedandwasafactorintheirloweruptakeofsciencecoursesinthesenior
years.
Ifweextrapolatestudents’ratingsoftheirschoolscienceexperienceattheAEand
WBEschoolsfromYears8to10,whenstudentsmakechoicesaboutwhetherand
whatsciencetodointhesenioryears,itappearsherethatYear8engagementand
Year12engagement(seniorcoursecompletions)correlatebetterthanYear8
achievementandlaterengagement.Predictionthreeincludestheunderstanding
thatself-regulationprioritiseslearningoverenjoyment.ThelinksbetweenYear8
achievementandlaterengagementwillbeexploredinthenextsection(Section
5.4),wherethefindingsfromstatisticalcorrelationswillbereported.
Thatsaid,thenarrativesforthetwoschoolssuggestthatthemorepositiveattitude
toscienceattheWBEschoolisrelatedtoqualitativelydifferentlearningprograms.
AttheendofYear8,thegirlsattheAEschoolhaddemonstrablybetterwriting
skills,butthegirlswereclearlynotenjoyingthesciencetheywroteabout.
5.3.5PairFIVE:PCWAE2andPCWAE3
Therankorderingofschoolsinthestatethatisbasedontherelativesizeand
polarityoftheresidualfromaregressionofEVresultsoveraNAPLAN-based
predictorproducedanunexpectedfinding,whichwasthattheproportionof
provincialschoolsrankedinthetop20%ofthestatewentfrom9%to56%(see
Section4.1).Sevenofthe12WAEschoolsthatidentifiedthemselveswere
provincialschools(seeTable5.1),whichwasacoincidencebutreflectedthatstate-
widefinding.
Inprinciple,comparingaprovincialandametropolitanschool,orevenafull
selectiveschool,shouldnotmatteraslongastheSEAscoresareidenticaland
schoolfactors(suchasattendancerates)aretakenintoaccount.Thiswasdonein
theearlieranalysestocomparePCWAE1andMCWAE1,andPCWAE2and
MCWBE5.ThepremiseisthattheSEAscorecapturesallthatmatterswhenit
comestostudents’sciencelearningpotential.
233
ThissectioncomparesthreeWAEprovincialschools,twoofwhich(PCWAE1and
PCWAE2)werelookedatearlierinthischapter,butinthecontextofcomparisons
withotherschoolshavingthesameSEAscoresastheprovincialschools.Thethird
provincialschool(PCWAE3)wasselectedforpairingwithPCWAE2becauseithad
comparableSEAscoresandcomparableresiduals(‘comparable’meaningnot
significantlydifferentinthestatisticalsense).ThethumbnailsketchesofPCWAE1
andPCWAE2wereprovidedaboveinthecontextofPairsONEandTHREE
respectively;thethumbnailsketchforPCWAE3follows.
PCWAE3isthelargestofthethreeprovincialschools.Eachyear,theschool
establishesfourtofiveYear7classesusingdatafromfeederschools.Asingletop
streamclassisestablishedfromthehighestachieversandabottomstreamsmall
classconsistsofstudentswiththeweakestliteracylevels.Thetwoorthreeclasses
inthemiddlehavetheremainderofthestudentsallocatedinnoparticularorder.
Allclassesaremixedabilityfromascienceperspective.Thescienceheadteacher
wastheonlyteacherinvolvedintheinterviewandhadbeenattheschoolfrom
beforetheperiodofinterest.ArtifactsofYear7andYear8assessmentwere
providedattheinterviewandtheproformahadbeencompleted.Theschoolhad
noplanstotakeupVALID10atthetimeofinterview.
Table5.11providesselecteddatasourcedfromdatatablesinAppendixItomake
comparisonsrelevanttoaddressingthethreepredictions.
234
Table 5.11 Pair FIVE selected statistics
School Y8 ACH Y8 ENG Y10 ACH SCH (%) STA ALL / 12 TOP / 16 SCH (%) STA
PCWAE2* EV = 84.79 ± 0.31 SEAS = 1.8 ± 0.45 RES = 1.69 ± 0.21
T 12 65
7 11
A-B 17 45
B 12 89 D-E 37 142
PCWAE3* EV = 83.64 ± 0.79 SEAS = 2.0 ± 0.27 RES = 1.43 ± 0.25
T 12 65 11 16
A-B 24 71
B 13 96 D-E 7 127
Y8 ACH = the proportion of Year 8 students in the top (T) and bottom (B) achievement bands. SCH (%) = school proportions represented as a percentage. STA = the proportion of students at the school expressed as a ratio (school proportion as a % over the state proportion as a %) relative to the state designated as 100. Y8 ENG = the rank order of schools based on engagement scores. ALL = all three achievement bands / 12 = the rank out of 12 non-selective schools based on the total survey scores for students at a school (the state figure is counted as a school) / TOP = top achievement band students / 16 = school rank for top band students in the 16 case study schools for which data had been provided (the state figure is counted as a school). Y10 ACH = the proportion of Year 10 students attaining grades A and B and D and E. SCH (%) = the proportion of students at a school with grades A&B and D&E represented as a percentage. STA = the proportion of students at the school as a ratio (school proportion as a % over the state proportion as a %) relative to the state designated as 100.
YEAR8ACHIEVEMENTANDENGAGEMENT
Thedatarelevanttoconfirmingtheachievementcomponentofpredictionone
(Table5.11),hasPCWAE2withastatisticallysignificantlyhigherEVresultthan
PCWAE3,thoughonlyjust.Onthebalanceofprobabilities(anotionallylowerSEA
scoreandhigherEVresult),thissupportspredictionone.NotethatPCWAE1’s
resultsarestatisticallysignificantlybetterthaneitherofPairFIVE’sresults,butit
hasastatisticallysignificantlyhigherSEAscorethaneitherofthetwoschools
comparedhere.
Table5.12recordstheproportionsofstudentsateachofthethreeachievement
levelsinthreeEVresultreportingcategories(ER,WSandCSareallidentifiedin
235
thelegend).ThislevelofcomparisoniswarrantedbecausetheEVresultsfromthe
twoschoolsareveryclose(justastheywereforMCFSAE2andMCFSWBE1).
Table 5.12 PCWAE2 and PCWAE3 Year 8 EV results
EV % ER % WS % CS % School SEAS SRES AB sch sta sch sta sch sta sch sta
5-6 12 18.6 18 20.3 16 19.4 14 22.4
PCWAE2 1.8 1.69 3-4 76 67.9 66 63.4 69 63.3 71 60.3
1-2 12 13.5 16 16.3 15 17.3 15 17.3
5-6 12 18.6 15 20.3 15 19.4 14 22.4
PCWAE3 2.0 1.43 3-4 75 67.9 66 63.4 68 63.3 66 60.3
1-2 13 13.5 19 16.3 17 17.3 20 17.3
Note. SEAS = socio-educational advantage score / SRES = school residual / AB = achievement band / EV % = proportions of students within each achievement band based on their total EV result (sch = school & sta = state) / ER % = proportions for extended response tasks / WS% = proportions for working scientifically / CS% = proportions for communicating scientifically
Inthreeofthefourreportingcategories,thereisasmallbutconsistentpositive
skewinPCWAE2’sresults.Thisobservationwasmostpronouncedforthe
extendedresponsetaskcategory.Therelativelylowtopbandproportionsof
studentsatbothschoolsisconsistentwiththeirrelativelylowSEAscores.
However,thelargeproportionsofstudentsinthemiddlebandandsmall
proportionsinthebottombandistestimonytoeffectiveteachinginthetwo
schools.Possiblereasonsforthisresultwillbeexploredinthediscussionpartof
thissection.
Table5.13enablescomparisonsofengagementforthethreeprovincialschools.
Thesethreeareincludedherebecausetheachievement–engagementpattern
describedinSection5.2.1wasageneraloneandnotlinkedtopairsofschoolswith
commonSEAscores.ThefindingsinthatsectionshowedthathigherEVresults
andpositiveattitudestowardschoolscienceexperiencewereassociated.
EngagementfindingsforPCWAE1andPCWAE2(reportedonincomparisons
236
above)wereinconsistentwiththatgeneralfinding.Inboth,engagementmeasures
werewellbelowthetwometropolitanschoolseachwasbeingcomparedwith,
despitebothprovincialschoolshavingbetterEVresultsthanthemetropolitan
schooleachwascomparedwith.
Table 5.13 Case study school ranks based on student scores for the six items from the student survey
School PCWAE1 PCWAE2 PCWAE3 Item ALL / 11 TOP / 15 ALL / 11 TOP / 15 ALL / 11 TOP / 15
A 5 11 3 8 6 10
B 3 9 8 8 4 4
C 9 11 7 7 11 15 D 9 13 6 10 8 15 E 10 8 11 13 8 14 F 9 14 5 8 10 13
AVERAGE RANK 7.5 11 6.7 9 7.8 11.8
ALL / 11 = all students at the 11 non-selective entry schools. TOP / 15 = top band achievers at the 15 case study schools. 3 & 4 are both better than the state figures
Whenconsideringstudentrankingsonengagementforthenon-selectiveschools,
thethreeprovincialschoolswereclearlyinthelowesthalfofthestateforallbut
thefirsttwoitemsrelatedtoengagement.Overall,PCWAE2wasmorepositive
thaneitherPCWAE1orPCWAE3.Thiswasalsotrueforthetopbandachieversin
allthreeschools.
WhencomparingonlyPCWAE2andPCWAE3,itwasfoundthat,overall,of
PCWAE2studentsattheendofYear8:
• morewantedtodoaseniorsciencecourse;
• fewerthoughtsciencetheirhardestsubject;
• moreenjoyedtheirprimaryscienceclasses;
• moreenjoyedtheirsecondaryscienceclasses;
• asmallerproportionlistedscienceintheirlistofthreefavouritesubjects;
237
• alargerproportionlistedscienceinthegroupofthreesubjectsthestudents
thoughttheylearntmostin.
YEAR10ACHIEVEMENT
Turningnowtolaterachievement,PCWAE3didnotprovideYear10achievement
datafrom2012to2014butdidprovideresultsforthethreeyearsuptoand
including2011,theyearofthelastexternalsciencetest.Itisobviousthatadirect
comparisonbetweenPCWAE2’sandPCWAE3’sYear10resultswouldnotbea
validexercise.However,itispossibletocomparethegrade/leveldistributions
comparedtostatefiguresfortheappropriateyearsandthentoinfer,with
appropriatecaution,theextrapolationofthatpatterntotheyearsofinterest
(2011–2014).
Table5.11providesthedatashowingchangesinthepatternofresultsfromYear8
toYear10relativetothestate.Distributionsofschoolresultsrelativetothestate,
andthechangedproportions,showthatPCWAE2studentshavenotretainedtheir
achievementedgeoverPCWAE3.Thesedatadonotconfirmpredictiontwo.
Reasonsforthechangeinresultspatternsarediscussedinthesummative
commentspartofthissubsection.
YEAR12ENGAGEMENT
LookingnextatYear12completionsforthetwoprovincialschools(Table5.14),
thestudentproportionscompletingsciencecoursesattheendofYear12at
PCWAE2relativetothestateandcomparedtoPCWAE3were:moreinBiology,
comparableinChemistry,moreinPhysics,andmoreinSeniorScience.PCWAE3
alsoofferedEarthandEnvironmentalScience,whichPCWAE2didnot(10%of
PCWAE3studentscompletedthiscourseattheendofYear12).Withoutknowing
moredetails(suchaswhetherBiologyandEarthandEnvironmentalSciencewere
offeredasaneither/oroptionorbothcouldbetaken),itwouldappearthat
PCWAE2hadmoreofitsstudentscompletingYear12coursesthanhadPCWAE3,
whichwasconsistentwithpredictionthree.
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Table 5.14 Year 12 science course completions (2013-2015 averages)
School PCWAE2 PCWAE3 Subject (state proportion) School State
(100) School State (100)
Biology (28.5) 38 133 19 67 Chemistry (18) 16 89 17 94 Earth and Environmental Science (2.4) N/A N/A 10 417
Physics (16) 13 81 11 69 Senior Science (10.4) 30 288 22 212
School = proportion of students relative to English at the school (relative to 100) State = proportions of students at the school (relative to the state set at 100) completing Year 12 courses.
COMPARATIVESUMMATIVECOMMENTSFORPAIRFIVE(PCWAE2ANDPCWAE3)
Thefollowingdiscussionoffindingsinrelationtothepredictionsfortheschools
comparedhereandtheircontributiontoansweringresearchquestionthreedraws
ontheschooldatamentionedaboveandtheassessment-relatedworknarratives
fortheschoolsinAppendixH.
Forpredictionone,PCWAE2hadthebetterachievementandengagementoverall.
Forthetwoschoolstheassessmentnarrativesdiscussedtheprioritygiveninboth
schoolstoworkingonimprovingstudents’literacyskills.Theassessment
narrativesforbothschoolsprovidedconvincingevidenceofdifferentialteaching
thataimedtoaddressthefullrangeofliteracydeficitsthatstudentsbringto
scienceclasses.
BothschoolsareintheWAEgroupofschools.WAEschoolsweremorefrequent
usersofthreedimensionsofformativepracticethanWBEschools.Itisreasonable
tosuggestthatattheendofYear8,PCWAE2wasmoresuccessfulatlifting
studentsresultsthanPCWAE3becausePCWAE2teachersweremoreeffectiveat
promotingdiscoursethatelicitsevidenceoflearning,providingfeedbackthat
advanceslearning,andmodelinggoodlearningbehaviourstopeersandstudents.
239
TheevidenceforthisconclusionisthepositivebiasintheresultsforPCWAE2
studentsintheextendedresponsecomponentoftheEVresults;inthedetailofthe
assessmentnarrativeforPCWAE2comparedtoPCWAE3,and;morestudentsat
PCWAE2hadputscienceinthelistofthreesubjectstheythoughttheyhadlearned
mostin.
Thisbeingthecase,howisitthatbytheendofYear10,theoverallresultsat
PCWAE3arebetter?Theanomalytobeexplainedisthepatternofbetterresultsby
PCWAE3attheendofYear10comparedtoPCWAE2(relativetothestate),which
iscontrarytopredictiontwo.OnepossibilityisthatPCWAE3’sSEAscore
advantage(2.0comparedto1.8)isreal.Asecondpossibilityisthatstudent
absenteeismwashigheratPCWAE2overthefouryears.Athirdpossibilityisthe
impactofahigh-stakessummativeassessmentregimesuchaswasrevealedinthe
narrativeforPCWAE2comparedtothelow-keyapproachbyPCWAE3to
summativeassessment.
IfstudentabsenteeismishigheratPCWAE2,thismightbeadecisivefactorin
reducingtheirYear10results.Disruptiontoindividuallearningprogressdueto
absenceanddisruptiontogrouplearningasaresultofabsenteeismwasidentified
bytheheadteacherintheinterviewatPCWAE2.FromtheMySchoolwebsite,the
proportionofindigenousstudentscomparedtonon-indigenousstudentsat
PCWAE3ishigherthanatPCWAE2(1in4comparedto1in5).Thisbecomes
relevantbecausedatafromtheMySchoolwebsiteforthetwoschoolsshowsthat
theattendanceratesforPCWAE3studentsare15%lowerforindigenousand5%
lowerfornon-indigenousstudentsthanatPCWAE2.Thus,onanyonedaythe
proportionofallstudentsawayatthetwoschoolsislikelytobegreaterat
PCWAE3thanatPCWAE2.So,despitelowerdailyattendanceratesatPCWAE3,its
Year10resultsarebetterthanPCWAE2’sresults.
Giventhatabsenteeismismorelikelytohaveagreaternegativeeffecton
achievementatPCWAE3thanatPCWAE2,itispossiblethatthereisanothermore
potentfactoratworkhererelatedtodifferentapproachestosummative
assessment.ResearchdiscussedinChapterTwoidentifiedthenegativeeffectof
240
high-stakessummativeassessmentonthemotivationtolearnofstudentswith
poorlearninghistories.Bothschoolshaverelativelyhighproportionsofstudents
withpoorlearninghistories(reinforcedbypublicityaroundNAPLANresults,
whicharegenerallypooratboththeseschools).
PCWAE2havestrictlygradedclassesinscience,thecompositionofwhichis
changedaftersummativeassessmenteverysixmonthsfromhalf-waythrough
Year7tohalf-waythroughYear9.PCWAE3takesalow-keyapproachto
summativeassessmentandkeepsthenumberofformalassessmenttaskstoa
minimum.Onceestablished,classesatPCWAE3areretainedrelativelyunchanged
untiltheendofYear8.Itmaybethatoverthefouryears(fromYear7to10)that
thenegativeimpactonmotivationtolearnisgreateratPCWAE2thanPCWAE3.
TheapproachtoassessmentatPCWAE3isverysimilartothatatMCWBE5.
(MCWBE5wascomparedtoPCWAE2aspairTHREEabove).Absenteeismat
MCWBE5wasthelowestofthethreeschools.LikePCWAE3,MCWBE5established
streamedclassesatthebeginningofYear7whichtheyretaineduntiltheendof
Year8.Summativeassessmentwasalow-keyaffair.Allthreeschoolshad
comparableSEAscores,thusmakingcomparisonfair,basedontheirSEAscores.
MCWBE5’sresidualiswellbelowboththeprovincialWAEschoolsandEVtest
resultwaslowerthaneitherofthetwoprovincialschools.LikePCWAE3,MCWBE5
performedbetterthanPCWAE2bytheendofYear10.Thisoutcomeisatleast
suggestivethatsummativeassessmentpracticesatPCWAE2mayhavebeena
contributortoitslowerachievementbytheendofYear10thaneitherPCWAE3or
MCWBE5.
Astoattributionofsummativeassessmentimpactondifferencesinengagementat
theendofYear8andYear12forthethreeschools,theevidenceislessclear.
AttheendofYear8PCWAE2studentswereenjoyingtheirsecondaryscience
classesmorethanPCWAE3students,topstudentsatbothschoolslesssothan
theiroverallresultindicatestheyshould(seesection5.2.1).MCWBE5students
241
weremorepositive(3rdonItemD)thanboththeprovincialschoolsandthiswas
sharedbytheirtopstudentsaswell(3rdonItemD).
AsmallerproportionofstudentsatPCWAE2includedscienceintheirlistofthree
favouritesubjects(ItemE)thanatPCWAE3.Topbandstudentsatbothschools
hadevensmallerproportions(outof15schools,PCWAE2was13thandPCWAE3
was14th).MCWBE5ranked3rdinthestateoverallanditstopbandstudentswere
also3rd.
Whenitcametotheproportionsidentifyingscienceinthegroupofsubjectsthey
thoughttheylearntmostin,morePCWAE2studentsthanPCWAE3studentsdidso
(5thoveralland10th,respectively).Topbandstudentsrepeatedthatpattern,but
wereasmallerproportionagain(8thcomparedto13thoutof15schools).MCWBE5
studentshadthe3rdlargestproportioninthestateandtheirtopbandwasthe7th
largest.Basedontheabove,itwouldbedifficulttomakeadefinitiveclaimabout
thenegativeimpactoftheassessmentregimeatPCWAE2oneitherenjoyment
(ItemsD&E)orsenseofachievement(ItemF).
AnexplanationforMCWBE5students’muchhighersatisfactionwiththeirschool
scienceexperiencecomparedtoeitherPCWAE2orPCWAE3wouldappeartobe
lessrelatedtosummativeassessmentthanteacheruseofformativepractice.The
assessment-relatednarrativeforMCWBE5pointstoteachersatthatschoolgiving
studentsagreatersayinwhattodointhenameofscienceeducation,aswellas
moreopportunitiesforpeerandself-assessmentwhichseemtocometoincrease
withthenumberofyearsspentatsecondary.MCWBE5hadthehighest
proportionsofstudentscompletingseniorsciencecoursesofthethreeschools.
5.4Correlationandstrengthofassociationsbetweenschoolvariables
Correlationprovidesawayofconfirming(ordisconfirming)therelativestrengths
ofassociationsbetweenvariables.Thestrengthofacorrelationcanprovidemore
supportforoneorotherinferencewhenconsideringthequalitativeevidencein
theassessmentnarratives.Inthesituationsbeingcomparedherewearelookingat
scoresthataretwo(Year8toYear10)andfouryearsapart(Year8toYear12).As
242
mentionedearlier,studentsmaketheirchoicesforsciencecoursestheywishto
studyinYears11and12(thelasttwoyearsofsecondaryeducation)inthemiddle
ofYear10.
Thisresearcher’sexperiencesuggeststhatoncemade,studentstendtofollow
throughwiththosechoices.Thus,thedecisiontouseYear12dataforcompletions
needstorecognisethatthefiguresreflectdecisionsmademorethantwoyears
earlier,lessthantwoyearsaftertheEVtest,andbeforeYear10resultswere
finalised.TheEVtesthasbeeninplacesince2007;theresultsbeinglookedathere
areforthefourYear8cohortsfrom2011to2014.Theirscoresarecorrelatedwith
Year10studentswhodidtheEVtestfrom2009to2012andYear12studentswho
didtheEVtestfrom2007to2010.ThefirstEVtestforstudentsacrossthestatein
NSWwasin2007.Theadviceaboutassessmentforlearningwaspromulgatedwith
the2003syllabus.Thepointbeingmadehereisthatchangesinresponsetoboth
initiativeswereasstronglyembeddedinpracticeastheywereevergoingtobeby
theendof2014,whenthenewsyllabusbecamethebasisforongoingEVtesting.
Fromthisperspectivethecorrelationbetweensetsofresultsthatare
asynchronouswasnotconsideredamajorissuewhenitcametoassessingthe
limitationsofcorrelationstatisticsasappliedhere.
Anotherassumptionhereisthatscienceresultsareafunctionofallthescience
teachers’effortsataschoolandthatstaffchangesortraumaticeventsatanyone
schoolduringthattimewererelativelyminor.Nevertheless,anystatistically
significantcorrelationsneedtoconsiderspecificschoolcircumstances.School
circumstancesthatwerelikelytoimpactresultsandengagementweredisclosedto
theresearcherandwereincludedintheassessment-relatedworknarrativesfor
thecasestudyschoolsasappropriate.
Asexplainedearlier,SPSSsoftwarewasusedbytheresearcherinthisprojectto
performbivariatecorrelationsusingeitherparametricornonparametricmodels
asappropriate.
243
5.4.1Correlations:fullyselectiveentrycasestudyschools(n=3)
Atwo-tailedcorrelationanalysisusingSPSSwascarriedouttotesttheobservation
thatengagementattheendofYear8isthebetterpredictoroflaterengagement.
Measuresofthefollowingvariablesforthethreeschoolswereused.
1. Year8results(Year8achievement)
2. Year8scoresforItemAofthestudentsurvey(aspiringtodoseniorscience
courses)
3. Year8scoresforItemsDandEfromthestudentsurvey(Year8
engagement)
4. Year10proportionsofAgrades(laterachievement)
Year12meanseniorcoursecompletionsinBiology,ChemistryandPhysicsonly
(laterengagement).
ThedatasetssatisfiedtheShapiro-Wilktestfornormality(p>.05).Resultsare
reportedintermsofthePearson’scorrelationcoefficientr,degreesoffreedom(1),
andatwo-tailedsignificance(p)valueateitherthep=.01orp=.05level(as
shownbythevaluequotedwiththereportedcorrelationcoefficient).
ForengagementatYear8(twoitemsfromthestudentsurvey)andachievementat
Year8,thecorrelationsforthetopbandstudents(atleast94%ofallstudentsat
theschools)onItemD(rD(1)=-.14,p>.05)andforItemE(rE(1)=.41,p>.05)
wereslightlynegativeandmoderatelypositive,respectively,butneitherwas
statisticallysignificant.Thus,itwouldbedifficulttodefendanyconclusionthat
likingscienceclassesanddoingwellintheEVtestwererelatedatthesethree
schools.
ThecorrelationsbetweenYear8engagement(thesametwoitemsasbefore)and
Year10achievementwererD(1)=-.88,p>.05andrE(1)=-1.0,p<.05.The
formerwashighlynegativeandnotstatisticallysignificant,thelatterwasvery
highlynegativeandstatisticallysignificant.Studentswhoputsubjectsotherthan
scienceintheirlistofthreefavouritesubjectsattheendofYear8achievedvery
244
goodresultsinscienceattheendofYear10.Inthesethreeschoolsitseemsthat
notlikingsciencewasnoimpedimenttoachievingwellinitattheendofYear10.
InrelationtoYear8engagement(twoitemsasbefore)andYear12engagement
(Biology,ChemistryandPhysicscompletions),thecorrelationswerehighly
positivebutnotstatisticallysignificant(rD(1)=.68,p>.05)andforrE(1)=.96,p
>.05).AttheendofYear8,aspiringtodoscienceinthesenioryears(ItemAinthe
survey)andactualengagementfiguresforthosestudentswhohadchosenscience
attheendofYear10(twoyearsaftertheirEVtest)andfinisheditattheendof
Year12(fouryearsafterthatEVtest)werehighlypositivelycorrelatedbutnot
statisticallysignificant(rA=.92,p>.05).ThecorrelationbetweenYear8
achievementandYear12completions(r=.63,p>.05)wasalsohighlypositivebut
notstatisticallysignificant.
Thus,itseemsthatforthethreemetropolitanfullyselectiveschools,the
combinationofwantingtodoseniorsciencecourses(ItemAinthestudentsurvey)
andlikingscienceattheendofYear8(ItemsDandE)waslikelytobeabetter
predictorofYear12sciencecoursecompletionsthanYear8achievement.
5.5.2Correlations:non-selectiveentrycasestudyschools(n=11)
Thetestingofcorrelationsbetweenvariableswasrepeatedforthenon-selective
entrycasestudyschools(n=11).Twomorevariableswereaddedtothelistfor
thepurposeofthisanalysis.Thevariablestestedwere:
1. Year8results(anachievementmeasure)
2. Year8aspiringtodoseniorsciencecourses(ItemAonthestudentsurvey)
3. Year8studentsurveyitemsDplusE(acollectivemeasureofYear8
engagement)
4. Year10achievement(thecumulativeproportionofAs,BsandCsawarded
tothecohort)
5. Year12engagement(theaverageofschoolproportionscompletingBiology,
ChemistryandPhysicscoursesattheendofYear12)
6. Residuals(ameasureofteachingeffect/scientificliteracyscores)
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7. SEAscores(themeasureofsocio-educationaladvantage).
AllsevendatasetstobecomparedpassedtheShapiro-Wilktestfornormality(p
>.05).OnthatbasisitwasdecidedtousethePearsonparametriccorrelation(r)
two-tailedtestintheSPSSsoftware.Themodelprovidesforninedegreesof
freedom(basedonn=11)andasignificance(p)valueateitherthe.01or.05level
(asreportedwiththecorrelationcoefficientproducedbytheSPSSmodel).
ThefirsttestsweretoassesswhetherYear8engagementorYear8achievement
wasthebetterpredictoroflaterachievement(Year10results)andengagement
(Year12seniorsciencecoursecompletions).
ThecorrelationbetweenYear8engagementandYear10resultswasstrongly
negativeandstatisticallysignificant(r(9)=-.69,p>.05).Thisfiguresuggeststhat
notlikingscienceattheendofYear8anddoingwellinitlateron(attheendof
Year10)wasthenormfortheprovincialandnon-selectiveentrymetropolitan
casestudyschools.
BetweenYear8engagementandYear12engagement,thecorrelationwas
moderatelypositivebutnotstatisticallysignificant(r(9)=.384,p>.05).Thisisan
expectedresultbutinnowaypredictiveinthiscontext.Ontheotherhand,the
correlationbetweenYear8achievementandYear10achievement(r(9)=.70,p
<.05)washighlypositiveandstatisticallysignificant.ThecorrelationbetweenYear
8achievementandYear12engagement(r(9)=.65,p<.05)wasalsohighly
positiveandstatisticallysignificant.
Forthenon-selectivecasestudyschoolscomparedforthisexercise,Year8
achievementisamuchbetterpredictoroflaterachievement(asmeasuredbyYear
10results)andengagement(Year12seniorsciencecoursecompletions)thanYear
8engagement.
InthecomparisonslookingatmeasuresofYear8engagementinprovincial
schoolsandmetropolitancasestudyschoolsrelativetothestate,itappearedthat
246
provincialschoolshadalowerlevelofengagementwithsciencerelativetothe
stateandrelativetothemetropolitanschoolstheywerebeingcomparedwith.
ThethreeprovincialschoolsallhadlowSEAscores.Thenon-selective
metropolitanschoolshadslightlyhigherSEAscoresoverall.Onepossibilityisthat
alowSEAscoremightbeanindicatoroflowinterestinscience.Thecorrelation
betweenSEAscoresandYear8engagementforthenon-selectivecasestudy
schoolswasshowntobemoderatelynegativebutnotstatisticallysignificantlyso
(r(9)=-.42,p>.05).Thus,anysuggestionthatalowSEAscoreandlow
engagementwithscienceatYear8arenecessarilyrelatedwouldnotbesupported
bythisfinding.
Thecorrelationbetweentheresiduals(ameasureofscientificliteracy
achievement)forthe11non-selectiveentryschoolsandengagement(likingtheir
schoolscienceexperience)wasmoderatelynegativebutnotstatistically
significantlyso(r(9)=-.30,p>.05).Theconclusionfromthisresultisthatforthe
casestudyschools,goodEVresultsandstudentsnotlikingtheirscience
experienceisthemorelikelycombination.
5.5.3Correlations:provincialcasestudyschools(n=3)
Toassessthestrengthoftheassociationsbetweenvariables,thefollowing
variablesinvolvedinthecomparisonsbetweenthethreeprovincialschoolswere
testedforstatisticallysignificantcorrelationsusingSPSS:
1. EVresults(Year8benchmarkmeasureofachievement)
2. StudentsurveyItemsD+Ecombinedlevelsscore(Year8benchmark
measureofengagementwithscience)
3. Year10sumofgradesA+B+C(laterachievement)
4. Year12completionsofBiology,ChemistryandPhysics(averagemean
proportionscomparedtoEnglishatthatschool)
5. Residual
6. SEAscore.
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MostofthevariabledatasetspassedtheShapiro-Wilktestfornormality(p>.05).
Asaresult,theSPSSprocedureforatwotailed,bivariate,parametriccorrelationof
thevariableswasused.ResultsarereportedintermsofPearson’sCorrelation
Coefficient(r),degreesoffreedom(1)andwhetherthecorrelationwas
statisticallysignificantrelativetothemodelreportedvalueateitherthep<.01or
p<.05levelofsignificance.
TheSEAscorewasincludedtotestthepossibilitythatengagementmaybe
positivelycorrelatedwithit.Thecorrelationforthethreeprovincialschoolsonthe
Year8engagementvariable(ItemsD+E)andSEAscoreproducedamoderately
negativebutnotstatisticallysignificantcorrelation(r(1)=-.43,p>.05).Thiswas
consistentwiththecorrelationforall11nonselectiveschools(r(9)=-.42,p>.05)
andforthefullcomplementofcasestudyschools(r(13)=-.38,p>.05).The
evidencehereisthatSEAscoreandengagementare,ifanything,negatively
correlated.Thehigherthestudents’learningpotential,thelesstheylikedtheir
schoolscienceexperience.
Anothercheckistoseeiftheresidualandengagement(ItemsD+E)arepositively
correlated.Theresidualisameasureoftheimpactofscienceteachingon
achievement,butitmight,arguably,beanindicatorofstudentattitudinal
responsestothatteaching.Forthethreeprovincialschools,thecorrelationwas
highlynegativebutnotstatisticallysignificant(r(1)=-.76,p>.05).Forthe11non-
selectiveentryschoolsthefigurewasmoderatelynegativeandalsonot
statisticallysignificant(r(9)=-.30,p>.05).Forallcasestudyschoolsr(13)=-.27,
p>.05.Again,theanalysisdoesnotsupportanydefinitiveconclusionbutis
suggestivethatthemorecapablestudentsacrossthestatearenotenjoyingtheir
sciencelessons.
WhenthecorrelationbetweenstudentsatisfactionwiththeirYear8schoolscience
experienceandbeingineitheraprovincial(1)ormetropolitanschool(2)was
testedforthe11non-selectiveentryschools,theresultwasmoderatelynegative
(r(9)=-.46,p>.05)butnotstatisticallysignificant.Aswell,comparingtheaverage
levelsofsatisfaction(descriptivestatistic)recordedforItemsDandEforallthe
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casestudyschools(n=15)showsthatx̅metro=34.3versusx̅prov=22.1.Thus,itis
notunreasonabletoconcludefromtheaboveanalysesthatprovincialstudentsin
thissamplewerelesspositiveabouttheirexperienceofschoolsciencethantheir
metropolitancounterparts.
5.5Summary
ThecomparedpairsofschoolswerePCWAE1andMCWAE1,MCAE2andMCWBE3,
PCWAE2andMCWBE5,MGFSAE2andMGFSWBE1,andPCWAE2andPCWAE3.
ThefirstthreepairsofschoolshadcomparableSEAscoresbutstatistically
significantlydifferentresiduals.Thefourthpairwerefullyselectiveentrygirls’
schools.Thegirls’schoolswerepairedonthebasisofbeingselectiveentrygirls’
schools(buttheydidhavestatisticallysignificantlydifferentSEAscoresand
residuals).Thefifthpairwerecoeducationalprovincialschoolswithcomparable
SEAscoresandresiduals.‘Comparable’meansthescoreswerenotstatistically
significantlydifferent.
ThefirstandfifthpairofschoolswereWAEschoolsbecausetheyhadhighly
positiveresiduals,whichmeantthattheirEVresultswerewellaboveexpected.
Theresidualsfortheotherthreepairsweredifferentenoughtoassigneachschool
inthepairtoadifferentschoolgroupbasedontheirEVresultsbeingasexpected
(AE)orwellbelowexpectation(WBE).ExpectationwasrelativetoaNAPLAN-
basedpredictedsciencescore,asexplainedinSection3.3.
ThefindingsreportedinSection4.5werethatteachersinWAEschoolsweremore
frequentusersofthreeoffivedimensionsofformativepracticethanweretheir
colleaguesinWBEschools.Aswell,overall,teachersinAEschoolsweremorelike
theirWAEcounterpartsinthefrequencyoftheiruseofformativepractices.
Theresearchquestiontobeansweredinthischapterwas:
Doestheuseof(andifso,howdo)formativepracticesbyteachersimprove
students’EVresultsandlaterachievementinandengagementwith
science?
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Section3.6explainedthatbyidentifyingschoolswithmatchingSEAscoresinalist
ofschoolssortedfromtoptobottomaccordingtothesizeoftheirresidualsthe
possibilityarisesofshowingthatbetterthanexpectedEVresults(intermsofa
predictor)arehigheractualEVresults(inabsoluteterms).Thatsaid,itcanbeseen
fromthetablesinSection5.3thatintermsofEVresults,PCWAE1’sEVresultis
higherthanMCWAE1’s,MCAE2’sishigherthanMCWBE3’s,PCWAE2’sishigher
thanMCWBE5’s,andPCWAE2’sishigherthanPCWAE3’s.Thus,itispossibleto
showthatforfourpairsofthecasestudyschoolswhereSEAscorescouldbe
matched,theschoolswiththebiggestresidualshadthebetterEVresults.Thiswas
theclaimmadeinpredictionone.Thehighresidualsareassociatedwithmore
frequentusebyteachersofthreedimensionsofformativepractice,theuseof
whichislinkedtohigherthanexpectedscientificliteracycontent,thusboostingEV
results.
Thesecondpartofpredictiononelinksresidualsizetoengagement,asmeasured
bystudentscoresonthesixitemschosenforconsiderationhere.Thepresumption
inmakingthelinkbetweenachievementandengagementisthatstudentexposure
toformativepracticeshasproducedstudentswhoarenotonlygoodatsciencebut
enjoylearningit.Thispresumptionwassupportedbyresearchfindingsdiscussed
inChapterTwothathadlinkedexposuretoformativepracticeswiththe
acquisitionofgoodlearningbehavioursandpositivedispositionstowardlearning.
Thisresearcherchosetousestudentenjoymentoftheirschoolscienceexperience
asameasureofpositivecommitmenttolearningscience.Additionalsupportfor
thelinkingofachievementandenjoymentwasprovidedbythefindingreportedin
Section5.2.1thatattheendofYear8,acrossthestate,higherachievementand
enjoymentoftheirschoolscienceexperiencewerepositivelyassociated.
AttheendofYear8,studentsinthehigher-achievingschoolinfourofthefive
pairsofcasestudyschoolsscoredacombinedItemD+Ebelowthescoreof
studentsintheschoolitwaspairedwith(seeTableK.5AinAppendixI).ItemD
wasaratingofenjoymentoftheirsecondaryscienceclassesandItemEwasthe
proportionofstudentswhohadincludedscienceinthegroupoftheirthree
favouritesubjects.Theexceptionwasthesecondpair,MCAE2andMCWBE3,
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wherethehigherachievingschool,MCAE2,wasslightlyaboveMCWBE3inboth
theoverallandtopbandcomparisons.Theclosenessofthepairedresultsherewas
somewhatsurprising,giventhatMCAE2promoteditselfasaSTEMschooland
establishedeachyearaclassofstudentswhohadsataselectiveentrytestforthat
classonthebasisoftheirinterestindoingSTEM.
TheseresultsappeartocontradictthegeneralfindinginSection5.2.1thatacross
thestate,higherachievementandenjoymentofschoolsciencewerepositively
associated.ItseemsthatattheendofYear8,highachievementhadbeen
accomplishedattheexpenseofstudentenjoymentoftheirschoolscience
experience.ThisfindingisalsosupportedbythecorrelationsreportedinSection
5.4.
Ofinterestalsowastheobservation(for10ofthecasestudyschools)that
provincialstudentsweremorenegativeabouttheirschoolscienceexperiencethan
metropolitanstudents.Italsoseemsthatthehighestachievingstudentsinthe10
schoolsweretheonesmostnegativeaboutthisexperience.Totheextentthat
enjoymentofsciencewasanindicatorofself-regulationattheendofYear8,these
findingsarenotsupportiveofthatconclusion,norarethefindingspromisingas
predictorsoflaterengagementwithscience(Year12sciencecoursecompletions).
Predictiontwowasthattheschool(inthepairsofschools)withthebiggerresidual
attheendofYear8wouldgoontohavethebetterresultsattheendofYear10.
Thepredictionwasconfirmedforthefirstpairofschools(PCWAE1andMCWAE1).
Itwasnotpossibletomakethecomparisonforthesecondpair(MCAE2and
MCWBE3)becauseMCWBE3didnotprovideYear10results.Itwasnotconfirmed
forthethird(PCWAE2andMCWBE5),fourth(MGFSAE2andMGFSWBE1)andfifth
(PCWAE2andPCWAE3)pairsbecauseofuncertaintyaboutthecomparabilityof
theYear10results.
Inanidealworld,resultsfromaYear10EVtestandrelatedstudentsurveywould
havebeenthebestoptionfordoingthiscomparison.Unfortunately,suchatestand
relatedsurveydidnotbecomeavailableuntilafter2014.Itwouldthereforebe
251
unsafetosaythatthereweremoreself-regulatedlearnersinWAEschoolsonthe
evidencefromonepairofschools.
Findingsrelatedtopredictionthreeweremeanttodemonstratethepersistenceof
positiveattitudestoscienceprovidedbythepresenceofself-regulatedlearnersin
postYear8yearsofWAEschools.Theindependentevidenceofthepresenceof
self-regulatedlearnersingreaternumbersinWAEschoolswassupposedtobe
confirmedbyhigherproportionsofstudentscompletingsciencecoursesattheend
ofYear12.Thesewerecoursesthatstudentshadinitiallychosenhalf-waythrough
Year10.Havingquestionedthevalidityandreliabilityofthedatausedtoverify
predictiontwo,weareleftwithdataaboutYear8achievement,Year8engagement
andYear12engagement.
Twowaysofmakingthatinterschoolcomparisonareprovided.Thefirstisthe
proportionofstudentsateachschool(relativetoEnglishwhichisacompulsory
courseforstudentswantingtoreceivetheschoolexitcredentialattheendofYear
12)completingoneormoreofthefiveseniorsciencecoursesthatwereavailable
tostudents.AlltheschoolsresearchedhereofferedBiology,ChemistryandPhysics
intwoormoreofthethreeyearsofinterest.MostalsoofferedSeniorScienceand
oneofferedEarthandEnvironmentalScience(PCWAE3in2014)inthethreeyears
ofinterest(2013to2015).
Thesecondistocomparethisschoolproportiontothestatewideproportions.The
assumptionbehindbothmethodsisthatschoolstrytoaccommodatestudents’
preferencestothebestoftheirability,giventheresourcesschoolsareableto
allocate.Asastartingassumption,itwasacceptedthattheschoolproportions
shownhereaccuratelyreflectstudentdemandforsciencecoursesmorethanthe
constraintsofavailableresources;thiswillbelesstruethesmallertheschoolis.
ForthepairsofcasestudyschoolsmatchedbySEAscoresanddifferentresiduals
indicatingtheirdegreeofexposuretoformativepractices,thefindingisthatthe
betterEVresultswere,thehighertheproportionofstudentstakingupand
subsequentlycompletingsciencecourses.Itwasobservedthatachievementatthe
endofYear8wasastrongercorrelatewithcompletionthanlikingthesubjectat
252
thattime.Onbalance,thecombinationofhighachievementinscienceandnot
likingtheexperiencewasthenormforthecasestudyschools,whichwas
contradictedbythefindingreportedinSection5.2.1fromthelargersampleof
schoolsthatidentifiedthemselves.
Inconclusion,theevidencediscussedhereconfirmsthepositiveassociation
betweenbetterEVresultsandthefrequencyofexposureto:
• discoursethatelicitsevidenceoflearning
• theprovisionoffeedbackknowntoprogresslearning
• theuseandmodeling(topeersandstudentsalike)ofgoodlearning
behaviours.
Theattempttodemonstratethatmorefrequentexposuretothesethree
dimensionsofformativepracticehadproducedmoreself-regulatedstudentsin
WAEschoolsthanAEorWBEschoolshasnotbeendemonstratedconvincingly.
Theassessment-relatedworknarrativesfortheschoolswithbetterthanexpected
EVresultsallhadstrongprogramsaimedatbuildingstudentcapacitytousethe
languageofsciencetoexplainphenomenainthenaturalandmadeworldsthey
inhabit.Itappearstothisresearcherthattheliteracyfocuswasinresponsetoa
widerschoolpriorityand/orinresponsetoscienceteachers’awarenessofthe
importanceofscientificliteracyforsuccessinschoolscienceandaspreparation
forlifeandworkafterschool.Inschoolswhereresultswerewellbelow
expectation,theassessmentnarrativeshadlittleexplicitevidenceofapriorityfor
buildingstudentcapacitytousethelanguageofscienceasatoolformanaging
theirlearningofscience.
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CHAPTER6:DISCUSSIONANDFUTUREDIRECTIONS
6.1Introduction
InChapterOneitwassaidthattheobjectiveofthisthesisistoanswerthebroad
question:Towhatextentistheassessment-relatedworkofscienceteachersin
NSWgovernmentschoolsformativeandwhyitmatters?ChapterTwogavetwo
reasonsforwhythisstudymatters.Thefirstisthatteacheruseofformative
practices(Black&Wiliam,2009)islinkedtohighachievement(Hattie,2012)as
measuredbytraditionalpenandpapersummativetests.Thesecondreasonisthat
teachingstudentstousethestrategiesofformativeassessmentthatunderpin
formativepracticeshasshownconsiderablepromiseasawayofhelpingstudents
tolearnhowtolearn.AccordingtotheOECD,“layingthefoundationsforlifelong
learning”(CERI,2008)p.1)shouldbeapriorityfortheinitialphaseofschooling;
knowinghowtolearnwouldbeimportantpreparationforthat.
A2018updatedlistofeffectsizesofparticularteachingstrategiesontestresults
showformativepracticestobeamongstthemosteffective(Hattie,2018).
Strategiessuchasclassroomdiscussion(0.82),providingfeedback(0.70),
responsetointervention(1.29),jigsawmethod(1.20)andscaffolding(0.82)are
amongstthemostpowerfulwaysforteacherstooperateintheclassroom.Two
curriculumstrategiesknowntohaveaboveaverageeffectsizesincluderepeated
readingprograms(0.75)andcoreandspecificvocabularyprograms(0.62).Bothof
thesewereinevidenceinWAEcasestudyschools.Theeffect-sizeofeachstrategy
isprovidedinparenthesis;higherthan0.42isanaboveaverageeffect.
Researchshowsthatteachingstudentsthestrategiesofformativeassessmentis
associatedwiththemacquiringtheskillsoflearninghowtolearn(LHTL)and
becomingautonomouslearners(Blacketal.,2006;James,2006).Learning
autonomyishighlyvaluedinthecontextofpreparingpeopleforlifeinthe
knowledgesocietyandrelatedglobaleconomyasdiscussedinChapterTwo.Again,
accordingtoHattie(2018),theeffectsizeonachievementofstudents’acquiring
andusingthesestrategiesisveryhigh.Examplesinclude:transferstrategies
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(0.86),deliberativepractice(0.79),strategiestointegratewithpriorknowledge
(0.93)andsummarization(0.79).Boyleetal.(2001)wouldrefertothese
strategiesbeingusedbystudentsas“goodlearningbehaviours”(p.200).
AsoutlinedinChapterOne,twoinitiativesintroducedintoNSWschoolsin2003
and2007respectively,weredesignedtoshiftteachers’assessmentfocusfrom
summativetoformative.Theneedforthatshifthadbeenelaboratedinthereview
ofthestatusandqualityofscienceeducationinAustraliapublishedearlier
(Goodrumetal.,2001).
Theinitiativestooktheformofstrongadvicetoteachersintheofficialcurriculum
aboutbringingteachingandassessmenttogether(assessmentforlearningasit
wascalledthere)andacompulsorysummativetestforallYear8students.Thetest
alsohadadiagnosticpurposewhichwastoprovideaprogressreportonscience
achievementhalf-waythroughthefour-yearsciencecourse.Thediagnostic
purposeoftheEVprogramwasenhancedbyusingtheSOLOmodelinthedesignof
theassessmentframeworkfortheEVprogram.Testitemsandtaskswere
designedtochallengestudentsacrosssixlevelsofthinkingdescribedbythemodel.
Atthetime,boththeNSWDepartmentofEducation(theDepartment),whichwas
responsibleforthetest,andthecurriculumauthoritythathadproducedthe
curriculum,providedadditionalsupporttoteacherstoassistthemachievethe
shiftinemphasis.Examplesofthatsupportareoutlinedbelowandweredescribed
inearlierchapters.
Theimpactontheassessment-relatedworkofscienceteacherswasofboth
personalandprofessionalinteresttothisresearcherforreasonsexplainedin
ChapterOne.Toassesstheimpactofthetwoinitiativesonassessment-related
workasdescribedinearlierchapters,threeresearchquestionswereposed,a
researchdesignwasdevelopedanddatagathered.
Thefirstresearchquestionaskedaboutteacheruseoftheresourcesrelatedtothe
EVprogram.Theprogramcomponentsincludedatest,arelatedstudentsurvey,
provisionofareporttoparentsandcomprehensiveresults(totheirteachers,
schoolandschoolsystem),teachersupportintheformofmarkertrainingand
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onlineprofessionallearningmodules.Discussionrelatedtoreasonsfortheiruse
(ornot)arereportedinSection6.2.
Thesecondresearchquestionsoughttofindouttheextenttowhichscience
teachersareusingformativepractices.Factorssupportingorimpedingtheuseof
formativepracticeswillbediscussedinSection6.3.
Thethirdresearchquestionaskedwhetherteacheruseofformativepractices
improvedstudentEVresultsandwhetherthatusewaslinkedtolaterachievement
inandengagementwithscience.TheanswerstothatquestioninvolvingYear8
studentsataschool,theirlaterachievement(Year10)andlaterengagement(Year
12)inscienceatschoolarediscussedinSection6.4.
Theresearchmethodologyusedtoprovidethefindingsinformingtheanswersto
researchquestionthreeisthebasisforclaimsbythisresearcheroforiginalityand
contributiontotheinternationalbodyofworkonformativeassessment.
Section6.5providessuggestionsforfurtherworktoconfirmfindings.
Thefinalsection(Section6.6)ofthischapterprovidesrecommendationsto
relevantauthoritiesarisingfromthefindingsreportedinthisthesis.
6.2Discussionoffindingsaddressingresearchquestionone.
Thequestionwas:WhatusearescienceteachersmakingoftheEVprogramand
whyisitusedornotused?
TheassessmentframeworkfortheEVtestdiscussedinChapterTwoprovidesa
mapoflearningalongtwoaxes,oneaxisbeingwhatshouldbelearnedinthename
ofscienceinYears7and8inNSWschools.Theotheraxisdescribessixlevelsof
thinkingaboutsciencethatastudentcandemonstrateintheirresponsestotest
itemsandtasks.TheSOLOmodelprovidesdescriptionsforthesixlevelsagainst
whichresponsesaretobejudged.Thebroadercontextincludesthetoolsfor
collectingevidenceoflearning(itemsandtasksinthetest),assigningvaluetothat
evidence(marking),reportingresultsandmakinguseofresultstoimprove
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learningwillbereportedonhereaswell.Subsection6.2.1willfocusonteacheruse
oftheEVprogramresourcesmorebroadly;subsection6.2.2willexploretheextent
ofteacherengagementwithSOLO.
6.2.1TeachersandtheEVprogram
ThefollowingdiscussionrelatestothecollectedresponsesfromWAE,AEandWBE
teachers(n=85)totheonlineteachersurveyandtoevidencefromtheassessment
narratives(AppendixH)asappropriate.Thefirstfivequestions(Q1-Q5)inthe
teachersurveycollecteddataabouteightcategoriesofactionsdescribingthe
scopeofteacherengagementwithEVresources(Q1andQ2),theirlevelof
understandingoftheEVprogram(Q3),whatthemainpurposeoftheprogramwas
(Q4)andQ5askedwhethertheywouldparticipateintheextensionoftheprogram
toYear10.
ChapterFourprovidedthedetailedanalysesoftheirresponses.Inbrief,the
findingswere:
• theoveralllevelofWBEteacherengagementwithEVresourceswaslower
thanthatforAEandWAEteachers(seeFigure4.1);
• thatteacherunderstandingoftheEVprogram,onafive-pointscaleranging
fromverypoortopoor,acceptableandthengoodtoverygood,located
WBEteachersatacceptableandAEandWAEteachersatgood(seeFigure
4.1B);
• mostrespondentswrotethatthepurposeoftheEVprogramwastoprovide
teacherswithfeedbackonstudentlearning(seeTable4.5);and
• thatfewerWBEschoolsthanAEorWAEschoolswouldbetakingupthe
VALID10testopportunity.
Teachersfromallthreegroupshaddiscussedresultswitheachother(66%)but
lesssowithstudents(22%).Apossiblereasonfornotdiscussingresultswith
studentswasprovidedincasestudyschoolnarrativeswhereseveralteachershad
mentionedthelargetimegapbetweendoingthetest(November)andwhenthe
resultswerereturned(March-Aprilthefollowingyear).
257
Noneoftheschoolsmentionedusingitemsortasksthatstudentshaddonepoorly
inasthebasisforreteaching.Poorperformanceinworkingscientificallyor
communicatingscientificallyareprocessesthatcouldberetaughtinthecontextof
anytopics,includingthosebeingdoneinYear9.Reteachinginresponseto
feedbackisacharacteristicofformativepractice.Morebroadly,theliteratureon
feedbackisconsistentlyoftheviewthattheshorterthetimedifferencebetween
actionandfeedback,themorelikelyitistobeacteduponbythelearner(Black
(2007),Hattie&Timperley(2007),Masters(2013),Ruiz-Primo&Li(2012)and
Shute(2007)).
Almost40%ofrespondentshadmarkedextendedresponsetasksandalmost30%
saidtheyhadattendedworkshopsabouttheEVprogram(separatefromtraining
formarkingextendedresponsequestions).Respondingtotheteachersurveywas
voluntaryandanonymous.TeachersexposedtothosetwocomponentsoftheEV
programwerepossiblymoreinclinedtorespondtothesurveythanthosenotso
aware.Itmayalsobeafactorinthehighproportionofthesamerespondentswho
ratedtheirunderstandingoftheEVprogram(seeQ3referenceabove)as
acceptableandhigher(87%).Thatsaid,theEVprogramappearstobewell
understoodbymostoftherespondents,includingthoseinregionalareas,afinding
supportedbyanswerstothenextquestioninthesurvey,Q4.
Thecollationofteacherresponsestothefreeresponsequestion(Q4)aboutthe
mostimportantpurposefortheEVprogramrevealedmultiplepurposesfrom
somerespondents.Overall,themajority(70%)sawthepurposeasbeingabout
providingfeedbacktoteachersonlearningand/orteaching,whichwasconsistent
withtheDepartment’srhetoricaboutitspurpose(seeChapterOne).Aminority
(21%)sawitspurposeasprovidingfeedbackoncomparativeperformancewith
otherschoolsandthestate.Asmallproportion(9%)wroteaboutitspurposein
termsofdirectstudentbenefit,whichsuggestedtheysawitspotentialforstudent
self-evaluationwhichisacharacteristicofformativethinking(BlackandWiliam,
2009).
258
InrelationtotheEVprogramoverall,fiveresponsesprovideaninsightintoissues
someteachershavewiththeprogram.TheheadteachersatMCWBE5and
MCFSWBE1wereasnothappythatsciencehadbeensingledoutforspecial
treatment(intheformofanexternaltest).Threeotheranonymouscomments
fromrespondentstotheteachersurveyincluded:
Noidea.It'sanimpositionintoanalreadycrowdedcurriculumthatrequires
aninordinateamountoftimeandresourcesforsomethingthatonlyappears
tobetheretojustifyawell-paidjobortwoelsewhere.(WBEteacher)
[TheBoard]tickstheboxformoretestsforschool.Justifiesfundingbasedona
testthatdoesn'tnecessarilymatchtothecurriculumthatthestudentsare
doingatthetime.(WAEteacher)
TokeeppeopleinHeadOfficeinajob.(WBEteacher)
Theseweretheonlynegativecommentsinatotalofninety-fivedifferent
responsestothequestionaboutthemainpurposeoftheEVprogram.
Q5fromthesurveyaskedaboutintentionstotake-uptheVALID10test
(introducedin2015onavoluntarybasis;datacollectionforthisprojectwasin
2016).VALID10istheY10equivalentoftheY8test(asexplainedinChapterOne).
Itwasimpossibletobedefinitiveabouttheintendedtake-upbecausethiswasan
anonymousteacherresponsesurveyandtherewasnowayofknowingwhich
teacherswereatwhatschoolsandwhethertherewasmorethanoneteacherfrom
aschoolresponding.Basedontherawdata,72%ofteachersinWAEschoolssaid
theywouldbetakingupthetestthatyear,52%ofAEteachersand47%ofWBE
teachers.Theoverallresultforthesample(n=84)was56%whichsuggeststhat
aroundhalfthestate’sYear10classeswerepreparingtotakeupthetestona
voluntarybasisin2016.
FourschoolsreportedwantingtoseeevidenceofchangefromYear8toYear10
(MGFSAE2,MCWBE4,MCWAE2andPCWAE1)asthereasontheytookuptheoffer
ofparticipatinginVALID10.Reasonsgivenfornottakingitonincludedtoreduce
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assessmentpressureonstudents(PCWAE3andMCWBE5);issuestodowith
computeraccess(PCWAE2andMCWBE5);teachersweretoobusyatthattimeof
theyear(MCFSWAE1);notmuchpointgiventhatstudentsallwentontoYear11
anyway(MCWBE5andMCFSWAE1).Anaside:inseparateconversationswith
scienceteachersoutsidethecontextofinterviewsincasestudyschools,somehad
reportedtheydidnotwanttoengagewithVALID10because,unliketheYear8test,
trainingandmarkingwasonsite(atschool)andunpaid.
Askingcasestudyteacherstocompleteaproformawithasampleofdatafor
studentsattheirschoolwasmeanttoprovidethisresearcherwithanopportunity
tofindoutthebreadthanddepthofanalysisteachersdowithbothEVtestand
studentsurveyresultsaswellastheirownteacherdevisedassessments.Onlyfour
ofthecasestudyschoolshadengagedwiththeproformabeforetheinterview.
Thusdiscussionattheinterviewoftheirpracticesinrelationtodataanalysiswas
limitedbythelowoverallresponseatthattime.Thelowresponsewastakenasan
indicatorthatusingdataforformativepurposeswasnothighonteachers’
assessmentagenda.Thisimpressionwasconfirmedandrecordedinassessment
narrativeswherelearningintentionsandsuccesscriteriawereprimarilyusedby
teachersasthebasisforfeedbackonstrengthsandweaknessesinanswersto
summativeassessmenttasks.Therewaslittleevidenceofstudentsbeinggiventhe
opportunitytouselearningintentionsandsuccesscriteriatoprovidefeedbackto
peersorinself-assessmentactivities.(overall,only16%ofteacherssaidtheyoften
askedstudentstoredoworktoahigherstandard).BothHattie(2012)andMitchell
etal.(2009)describeresearchsupportingtheeffectivenessofreflectionasanaid
toimprovinglearning.
Mostoftheheadteachersinterviewedsaidthatthelevelofresultsanalysisasked
forintheproformawassomethingtheyhadnotconsidereddoingbefore.
However,thethreewhodidcometotheinterviewwithcompletedproformassaid
itwasbeneficialtolookatthedataovertimeandtoidentifytrends.Thehead
teacheratMCWAE2suggestedthatprovidingadatadownloadingcapabilityfrom
SMARTwouldencouragegreateraccessandusebyscienceteachersofthedata,
particularlythestudentsurveydata.She,alongwiththeheadteachersatMCWBE3
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andMCPSWBE2,saidtheysawvalueinkeepingarecordovertimeofresultsfrom
Year8toYear10science.
AllheadteachersinterviewedsaidtheykeptfacultyrecordsofHSCresultsover
time.Noanalysiswasdonebyheadteacherstofindtheproportionsofstudents
doingseniorsciencecourseseachyearincasestudyschoolsbeforetheir
participationinthisproject.MostdidnothavefacultyrecordsovertimeofY10
gradesafterexternaltestingstopped.Thiswasnotaprioritybecausealmostall
studentswentontoYear11andmanytookupseniorsciencecourses.There
seemedtobelittleawarenessbyheadteachersthattheserecordsprovideabasis
formonitoringengagementinscience(Year12proportionsrelativetoEnglish)or
ofprogressinlearning(fromYear8toYear10).
InrelationtomonitoringprogressinlearningfromYear8toYear12,doingthis
wasnothelpedbythefactthatYear8resultsarereportedagainstsixlevels,Year
10resultsarereportedagainstfivegradesandYear12resultsarereported
againstsixlevels(notcommensuratewiththeYear8levels).Thepossibilityfor
monitoringstudentachievementandengagementfromYear8toYear10using
VALID10resultsisnowavailabletothoseschoolstakinguptheVALID10test.K-6
schoolstakinguptheVALID6optioncanreporttheirresultstothesecondary
schoolsreceivingtheirstudents.
Itisalsopossiblethatsomescienceheadteachersandclassroomteachersdonot
havethestatisticalskillsand/orspreadsheetfluencyandexpertisetoconfidently
managethetransferandtransformationoftheEVdata.Thiswasfoundtobea
barriertomeaningfulengagementwithNAPLANresultsforsomesecondary
teachersofEnglishandMathematics(Pierce&Chick,2011).
StudentEVresultsaredistributedtoparentsafterprintingoutbytheschool.
Typically,resultsaresenthomeinthesamewaythebi-annualschoolreportson
allcoursesaredistributed.Whenaskedwhatfeedback,ifany,wasprovidedby
parentstoscienceteachersabouttheEVreports,noneofthoseinterviewedcould
recallanyparentcommentingonoraskingformoreinformation.Thiswasalso
trueforthetwoschoolsthatsaidtheyhandedthereportstoparentsattheir
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regularparent–teachernightheldearlyinYear8.Whenaskedwhytherewasno
apparentinterestfromparentsintheresults,severalcommentedthatthetime
intervalbetweendoingthetest(Novemberthepreviousyear)andreceiptofthe
report(March-Aprilthenextyear)mayhavebeenafactor,thoughnonesuggested
howthatmighthaveinfluencedtheapparentlackofparentinterest.Theresearch
literatureonthereducedeffectoffeedbackprovidedwellaftertheassessmentwas
mentionedearlierinthissection.
TheinclusionofastudentsurveywiththeEVtestwasauniqueadditiontolarge
scalewholeofcohorttestinginNSWschools.Onlystudentsatschoolschosenin
nationalsamplestoparticipateinTIMSStesting(inYear4and/orYear8)had
completedsurveysandtestsbeforeEVtestingbegan.Teachersfromallthree
schoolgroupsrespondingtothesurveyhadindividuallylookedatthestudent
surveyresults(67%.Yetonly20%haddiscussedtheresultswithcolleaguesor
students.Casestudyschoolssaidintheinterviewsthatthemainreasonfornot
havingthosediscussionswasbecauseteachershadnotbeengivensupportor
encouragementtodoso.Ontheotherhand,almostallthecasestudyschoolssaid
theymetregularlyasastaffandthatassessmentwasafrequentitemonthe
agendaforthosemeetings.Hadthestudentsurveybeenofinterestorseenas
relevant,giventheregularmeetings,itcouldhavebeenontheagenda.Itwould
appearthatscienceachievementwasofmoreinterestthanstudentengagement
withscience.
Thepersonalandprofessionaldiscomfortofteacherstostudentdissatisfactionis
understandable.Inrecognitionofthat,EVresultsaredeliberatelynotpublicizedin
thesamewayNAPLANresultsare.Allinterviewedsaidtherewasnopressure
fromtheschoolexecutiveoverEVresults,onewayortheother.Whilstthisisin
keepingwiththelow-stakesintentionsofdiagnosticassessment,themainreason
thefeedbackisprovidedistopromotechangeleadingtobetteroveralllevelsof
studentachievementandengagement.Thereisastrongelementoftrustbeing
placedintheprofessionalismofteacherstorespondtothefeedback.Basedonthe
highlevelofintention(morethan50%sayingtheywouldtakeupthevoluntary
Year10test),therelativeabsenceofnegativefeedbackabouttheprogram(see
262
individualteachercommentsabove)andthefactthat48%ofteachershadused
theresultstoinformchangestoteachingandlearningprograms,thatapproachby
theeducationsystemandschoolmanagersseemstobesound.
PCWAE1teacherswereawarestudentsattheirschooldidnotlikescienceortheir
experienceofitbutcouldnotofferanyreasonapartfromreportingacomment
fromstudentsthatteachersattheirschoolwerestrictaboutstudentscompleting
theirwork.AsreportedinChapterFive,studentsatbothPCWAE2andPCWAE3
hadlowrankingsoftheirschoolscienceexperiencesaswell(seeTableK.5A,Band
CinAppendixI).Thatnegativitywasalsoreportedfortheirprimaryschoolscience
experienceandallthreewerebelowthestatefiguresfortheproportionsincluding
scienceintheirlistofthreefavouritesubjects(PCWAE2wasthebestofthethree
there).Theapparentparadoxofbetterthanexpectedachievementanddislikefor
theirschoolscienceexperiencewillbediscussedfurtherinsection6.6.
Ofthethreefullyselectiveschools,studentsfromMGFSAE2recordedtheleast
positiveviewsoftheirschoolscienceexperience.MGFSAE2’srankingonItemsD
andEcombinedwas16th(outof16).Thethreeselectiveentryschools’top
achievementbandstudentsrecordedthethreehighestlevelsofagreementwith
ItemBwhichsaidthatsciencewasthehardestsubjectIlearn(1st,3rdand2nd
respectivelyfortheWAE,AEandWBEschoolsinthatorder).Areviewofthe
assessmentrelatedartifactsprovidedforthethreeschoolsshowedthatthe
expectationsforknowledgeandunderstandingwerewellabovesyllabus
expectationswhichmaybeafactorcontributingtothemnotenjoyingtheirschool
scienceexperiences.
Incontrasttotheabove,asshowninTablesK.5DandK.5CinAppendixI,
MCWBE5,MCWAE1andMCWBE4wereatthetopofcasestudyschoolrankings
(andabovethestate)forstudentenjoymentoftheirsecondaryschoolscience
experience(studentsurveyItemsDandE).Thethreeschoolsalsohadthelargest
proportionsofstudentsnominatingscienceasthesubjecttheylearntmostin
(ItemF).EVresultsforallthreeoftheschoolswererelativelylow(82.54,82.14
and73.63respectively).However,studentsatMCWBE5thoughtsciencewasnotas
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difficult(5thoutof11non-selectiveschoolsandcountingthestateasoneschool)
asstudentsatMCWAE1(1st)orMCWBE4(2nd)did.Forstudentsatthesetwo
schools,perceiveddifficultydidnotseemtoimpactenjoymentoftheirschool
scienceexperience.Enjoymentofscienceand/orengagement,aswaspointedout
inSection5.4forallstudents(threelevelsofachievementtogether)atthe
differentschools,wasnotobviouslyrelatedtoeitherSEAscoresorresidual
rankings.
AnalysisoftheassessmentnarrativesforMCWBE5andMCWAE1,andtheschools
theywerecomparedwith(PCWAE2,PCWAE1respectively),didnotprovide
consistent,substantiveevidencethatstudentsatanyofthefourschoolsattheend
ofYear8hadacquiredskillsassociatedwithself-regulation.MCWBE4wasnot
comparedtoanyschoolandithadaSEAscoreof0.7andaresidualof-1.58.Their
assessmentnarrativewasmorefocusedonhowsciencecontextswerebeingused
toimprovestudent’sliteracyandnumeracyskillsandidentifyformation.A
hypothesizedlinkbetweenhighachievementandengagementattheendofYear8
andself-regulationcouldnotbesupported.Inessence,whilstself-regulation
(Boekaerts&Corno,2005)andlearninghowtolearn(James,2006),areseenas
important,themethodsusedinthisprojectandrelatedfindingsdidnotshowa
hopedforconsistent,patternthatcouldreasonablybeattributedtostudentself-
regulation.
Overall,basedonteachercommentsintheinterviews,studentslikedoingthe
onlineEVtestwhichteacherssaidstudentsfindinherentlyinteresting.Inonlytwo
schoolswasitsuggestedthat(some)studentsdidnottakethetestseriously
(MGFSWBE1andMCWBE4).Noneoftheschoolsreportedspendingtime
preparingstudentsforthetestapartfromthebasicrequirementstoensurelogin
successandforstudentstofamiliarizethemselveswithhowtorespondtothe
itemsandtasks.ThecommonmessagegiventostudentswasthattheYear8EV
resultswouldnotbeusedinschoolassessments,butthatstudentsshoulddotheir
bestbecausethetestresultswouldhelpteacherstoimprovetheirteaching.
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Noneofthecasestudyteachersinterviewedmentionedtheyhadusedtheteaching
strategiesadviceprovidedinSMARTtoaddressmisconceptionsidentifiedin
feedbacktotheschool.Theoverallsurveyresponsetothatquestionwasfewer
thanhalfsaying‘yes’(oneinthreeWBEandWAEteacherssaid‘yes’;AEteacher
responsewastwointhreesaying‘yes’).Theprovisionofthisresourceinthe
feedbackpackagewasoverlookedbymostteachersitseems.Thisresearcher’s
explanationforthatistheoveralllackofincentiveforteacherstoengagewiththe
massofdataavailableintheSMARTpackage.ThatappearstobethecaseforWAE
schools’lowresponsecomparedtoAEschoolswhereresultswereperhapsnotas
goodorteachersinthoseschoolswerekeentodobetterfortheirstudents.WBE
schoolshadalowerlevelofengagementforallaspectsoftheprogram.
ThenationaltestsinAustraliaforliteracyandnumeracy(NAPLANtests)were
usedinthisprojecttodeveloppredictorsofEVsuccess.Thesetestsareexamples
ofsummativetestsalsobeingusedfordiagnosticpurposes(aswellasother
purposesdiscussedinChapterTwo).Theanecdotalfeedbackfromthescience
headteachersincasestudyschoolswasthatNAPLANfeedbackattractsmore
interest,attentionandtimefromparents,studentsandtheirschools’senior
executivesthandoesthefeedbackonEVresults.Thereasonsmostgaveforthe
attentiontoNAPLANwasthepublicationoftheschool’sresultsonawell-
publicizedwebsiteforalltheworldtosee(theMySchoolwebsite),mediainterest
incomparingschoolsandtherequirementtoreportNAPLANresultsinannual
schoolreports.
Insummary,teachersareusingoradaptingEVtestitemsandtasksfrompasttests
toenhancetheirsciencedepartmentformalassessmentprograms(69%).
Teachersinschoolswhereresultsarewellabove(WAE)oratexpectation(AE)are
usingtheresourcesmoreandinawidervarietyofwaysthantheircolleaguesin
schoolswhereresultsarewellbelowexpectation(WBE).However,overall,fewer
thanhalf(48%)oftheteachersthatrespondedtothesurveysaidtheywereusing
thefeedbackfromEVresultstoamendtheirteachingandlearningprograms.
Teachersinschoolswhereresultswereasexpected(AE)reportedthehighest‘yes’
265
responserate(75%)totheitemaboutusingthefeedbackfromEVresultsto
amendtheirprograms.
6.2.2TeachersandSOLO
EngagementwiththeSOLOmodelwasaddressedintheonlinesurveyinthree
questions,questionssixtoeight.SOLOwasakeyelementintheassessment
frameworkfortheEVprogrambecauseitprovidedthebasisforfeedbackabout
thelevelofthinkingevidentinstudentresponsestoitemsandtasksinthetest.
AsreportedinChapterFour,theoverallfindingwasthatdifferencesbetweenthe
responsesofWAE,AEandWBEteachersonanyoftheaspectsofSOLO
engagementinvestigatedherewerenotstatisticallysignificant.Alsotheoverallyes
responsestoitemsbeganat54%anddeclinedfromtheretoalowof5%onthe
secondlastiteminQ6whichwasaboutreportingtohomeusingSOLO.
OnQ7,whichaskedteacherstoratetheirunderstandingofSOLO,onaratingscale
goingfromverypoortopoor,thenacceptableandgoodtoverygood,themodal
responsewas“acceptable”(29%chosethatoption).
Whenteacherswereaskedinquestioneight(Q8)wheretheylearntmostabout
SOLO,themostcommonlymentionedsituationwastrainingformarkingtheEV
testormarkingEVtests(35%).ThenextwasinEVworkshops(9%)followedby
neverheardofSOLO(7%).Itwasnotpossibletodistinguishwhetherthe
responseswereabouttheYear8markingforextendedresponsetaskswhichis
doneexternallytotheschoolbyexperienced,trained,scienceteachersorYear10
marking.Trainingforthelatterisdoneatschoolorhomebyworkingthrough
onlinemodules.
Ofthesixteenschoolsvisited,onlytwowereactivelyusingSOLOtoinformtheir
assessmentfeedbacktostudents(MGFSAE2andMCWAE2)atschool.MCWBE4
indicatedthattheschoolwasconsideringusingSOLOasanenhancementtoits
assessmentpoliciesandpractices.Neitherschoolusedittoreporttoparentsor
carers.MCWAE2recogniseditspotentialtoprovidefeedbacktohelpstudentswith
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theirexpressivelanguageskillsinscienceandwereusingittomarkextended
responsequestionsteachersattheschoolhadconstructedorappropriatedfrom
othersources.TheHTatMCWBE3wasactivelyworkingonbuildingstaff
understandingaboutSOLOinordertouseitasthebasisforfeedbacktostudents
inscience.
AcogentreasonfornotusingSOLOwasgivenbythetwoteachersinvolvedinthe
interviewatPCWAE2.TheysaidthatstudentsfounditconfusingtoreconcileSOLO
andNSWBoardofStudies(theBoard)providedfeedback(reportedinlevelsand
gradesrespectivelyandbasedondifferentcriteriaasexplainedinChapterTwo).
Giventhattheschool’spriority(seetheirschoolnarrativeinAppendixH)tohave
studentsdoseniorsecondarysciencecourses,theteachersfelttheireffortswould
bebetterspenthavingstudentsunderstandtheBoard’sCommonGradeScale
approachtoassessment.HeadteachersatMCWAE2andMGFSAE2whowere
activelyusingSOLOtoimprovestudentlearninginscienceappearedtohavea
reasonableunderstandingofSOLOlevels.TheheadteacheratMCWAE2was
workingwiththeoriginalSOLOtaxonomyratherthantheversionbeingusedin
theEVprogram.
Fromtheabove,theSOLOcomponentoftheEVprogramwasnotverywell
understoodbyscienceteachersrespondingtothesurveyandwaslargelyignored
asabasisforprovidingfeedbacktostudentsabouttheirlevelofthinkingin
science.
TheEVprogramandtheSOLOmodelareexclusivelyDepartmentinitiativesand
theabovefeedbackwillbeofinteresttotheDepartment.However,theuseofa
formal,externally(totheschool)developedandimposedsummativetestto
providefeedbacktoteachersonprogressinlearningisofgeneralinteresttoall
systemswheresuchtestingisdonewithdiagnosticintent.Aswasdiscussedin
ChapterTwo,thelastroundofPISAtesting(2015)inscienceincludedacognitive
demanddimensioninitsassessmentframework.SOLOwasconsideredforthat
rolebutthetestdeveloperschoseanalternative,simplermodelthatrecognised
threelevelsofcognitivedemand(OECD,2017).Recognisingcognitivedemandin
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theassessmentframeworkofaninternationaltest,suchasPISA,representsa
qualitativeimprovementinthesophisticationofmeasurement-based,assessment
modelsofwhichtheEVandPISAtestshavebeendescribedasexemplary
(Fensham,2013).
6.3Discussionoffindingsaddressingresearchquestiontwo
Thequestionasks:whatformativepracticesareevidentintheassessment-related
workofscienceteachersandwhyaretheyusedornotused?
Thefocusherewillbetolookfirstatcasestudyschools’assessmentrelated-work
narratives(providedatAppendixH)forexamplesofsciencedepartmentpractice
thatreflectformativeintentions(6.3.1)beforelookingatevidenceofformative
practiceintheclassroom(6.3.2).Inthesectiononclassroompractices,discussion
willbelinkedtothefivedimensionsofformativepracticewhichcomprisedthe
theoreticalframeworkforassessingtheextenttowhichpracticeswereformative.
6.3.1Sciencedepartmentassessmentpractices
AswasdescribedinChapterFive,studentallocationtoclassesinthejunior
secondaryyearsofhighschoolforthepurposesofinstructionwasdoneincase
studyschoolsalmostalwaysonthebasisofachievementinliteracyandnumeracy
asassessedbyteachersattheendofYear6.TheDepartment’sstaffingformula
providesteachersonthebasisthatnojuniorsecondaryclassinthecoresubjects
(whichincludesscience)“needexceed30students”(NSWDofE,2017).Inpractice
however,someclassesinagivenYearwereallocated(withstaffagreement)more
than30studentsinordertocreatesmallerclassesfor‘lowerability’students
(generallymeaningstudentswithpoorlearninghistories).Socalled‘bottom’
classesweregenerallyassignedcloseto20studentsorfewerifpossible.Fromthe
perspectiveofscienceteachers,theclassesassignedtothemwere“ungraded”in
termsofpriorsciencelearning.Thescienceheadteachersinvolvedininterviews
saidtheirexpectationwasthatteacherswouldworkfromthatassumption.The
rangeofresponsesbyteacherstothediversityofstudentsintheirclassesis
discussedinSection6.3.2.
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ItisimportanttounderstandthatteachersinNSWgovernmentschoolswere
requiredbytheiremployer(theDepartment)tomakeuseofaspecified
curriculumandemployer-providedpolicydocuments(NSWDofE,2013)toguide
preparationoftheirteachingandrelatedassessmentwork.Thisrequirement
appliedwellbeforetheperiodofinterestforthisprojectandcontinuestoday.The
responsebyscienceteachersincasestudyschoolstotheabovewastousethe
syllabusandrelatedimplementationsupportandpolicyadvicetoguidetheir
constructionofaplannedprogramofworkfortheirstudentsmappedtotheforty
weeksoftheschoolyear.Importantstructuralfeaturesoftheprogramofwork
werethecurriculumstandardsdescribedintermsofoutcomesandrelatedcontent
todefinethescopeandlevelofexpectedlearningrelatedtoeachoutcome.The
curriculumexpectationwasthatthelearningwouldbespreadequallybetween
knowledgeandunderstandingofscienceandrelatedcontextsandtheacquisition
ofskillsrelatedtoworkingandcommunicatingscientifically(BOS,2003).
Incasestudyschools,thesciencedepartment’sprogramdescribedforteachersthe
scienceknowledgeandunderstandings,skillsandattitudestheywereexpectedto
“teach”tostudentsintheirclassesinthefouryearsfromYear7uptotheendof
Year10andhowitwouldbeassessedalongthewayforthepurposesofcollecting
evidenceoflearningtobeusedinpreparingprogressreportsaboutstudent
learningforparents.Thereisarequirementtoreporttoparentsatleasttwicea
year.Thecurriculum(calledasyllabusinNSWbecauseofitsspecificityabout
whatwasexpectedtobetaught)inplaceatthetimeofinterestforthisproject
includedadvicethatteachingandlearningneedtobecloselylinked,anintention
capturedinthephrase“assessmentforlearning”(BOS,2003,p.70).Tohelp
teachersdothat,theDepartmentandBoardprovidearangeofsupportmaterials
andprofessionallearningactivitiesthatteacherscanaccessandworkthroughto
deviselearningandassessmenttasksthatbetterreflectthefullrangeof
curriculumintentionsandthatarefair,validandreliablereflectionsofthose
intentions.
Inresponsetothatsupport,therangeoftasksandactivitiesdescribedinthe
narrativesasbeingusedbyteacherstocollectevidenceoflearning,apartfrompen
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andpapertests,includedstudentresearchprojects(amandatedactivityinthe
curriculum),fieldworkreports,excursionreports,writtenresponsestolaboratory
tasks,internetandothertext-basedresearchtasks,oralpresentationsandcreative
activitiessuchasmodelmakinganddiarywriting,tonamesome.Theseactivities
wereeitherdoneentirelyinclasstimeorinbothclassandhometime.Student
responsestotheactivitiesprovidedevidenceoflearningthatwasusedbyteachers
forbothformativeandsummativeassessmentpurposes.Whilstawiderangeof
taskswasbeingused,whatstudentsknowandunderstandasreportedtoparents
(typicallyexpressedasamarkorgrade)wasdominatedbytheweightofevidence
fromtasksreturningmarksbasedonteachers’judgmentsofthequalityof
expressivelanguageusedbystudentsintheconstructionofresponsestothe
requirementsofthosetasks.
Accompanyingmanyactivitieswererubricssettingoutthelearningexpectations
andsuccesscriteriathatwouldbelookedforinassessingtheworthofthe
evidenceoflearningdemonstratedinstudentresponses.Thelearningintentions,
aswrittendown,weretypicallyderivedfromcurriculumoutcomesandrelated
contentthatdescribedthescopeandformofexpectedresponses(descriptions
includingcomparisonandcontrasts,graphicrepresentationswithappropriate
labels,explanations,justificationsandaspectsofperformancestonamesome).The
judgmenttobemadeofthequalityoftheresponsewasalmostalwaysreferenced
tothefivegradesintheBoard’sCommonGradeScaleadvice(BOS,2013).SOLO
levelsandrelatedlanguageonlyappearedinartifactsprovidedbytwocasestudy
schools(MGFSAE2andMCWAE2).
OfinterestwastheplaceAEteachersoccupiedintheanalysisoftheresponses
againstthefivedimensionsofformativepractice.TheAEteachersarethegroupof
teacherswhosestudents’EVresultswereasexpectedbasedonthepredictor.AE
teacherresponsesprovidedreferencelevelsforthisexercise.Fromtheanalysis
reportedinchapterfivethefrequencymeansfortheAEgroupofteacherswere
alwaysbetweentheWAEandWBEteachers.However,forthethirddimension
(feedbackthatadvanceslearning)boththeWAEandAEmeanswerestatistically
significantlydifferentto(above)theWBEmeanwhichmeantthatthesetwo
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groupsofteachersweremorefrequentusersofavarietyoffeedbacksourcesthan
weretheirWBEcolleagues.
Howteachersengagestudentswithcurriculumcontentandconductassessments
oftheextentoflearningisadecisionforclassroomteachers(BOS,2003).The
extenttowhichtheformsofevidencefromthesurveysandassessmentnarratives
canbesaidtobeformativeisdiscussedbelowinSection6.3.2.
6.3.2Formativeclassroompractices
Together,thequestionsandrelatedactivitiesdescribedintheitemsfromthe
scienceteachersurveyinQuestions9to15addresswhatwerecalledinearlier
chaptersfivedimensionsofformativepractice.Thedimensions,bringingtogether
scienceinstructionandassessmentstrategies,are:
1. Clarifyingandsharinglearningintentionsandsuccesscriteria(LISC);
2. Engineeringeffectiveclassroomdiscourseandusinglearningtasksthat
elicitevidenceoflearning(CDEL);
3. Providingfeedbackthatmoveslearnersforward(FTAL);
4. Activatingstudentsasinstructionalresourcesforoneanother(including
peerassessment)andtheirteachers(ASIR);
5. Activatingstudents(andteachers)asownersoftheirownlearning
(includingself-assessment)(ASTL).
Thesefivedimensionsprovidetheframeworkforassessingtheextenttowhich
practicesdiscussedherecanbedescribedasformative.AsdiscussedinChapter
Four,theintentionwastofindouttheextenttowhichteacherswerethemselves
activelyusing,aswellaspromotingstudentagencywith,formativepractice
dimensions.TheexamplesandcontextsdiscussedhererelatetoYears7and8.
Teacheruseoflearningintentionsandsuccesscriteria(LISC)
Asmentionedinthefindingsfromtheteachersurvey(Section4.2.3.1),students
hadverylittleinputintothechoiceoftask,learningintentionsorsuccesscriteria
whichforthemostpartappearedtobegivendeterminedbytheteacher.There
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werenostatisticallysignificantdifferencesbetweenthethreeschoolgroupswhen
itcametothefrequencieswithwhichlearningintentionsandsuccesscriteriawere
used.Also,therelativefrequenciesofopportunitiesforstudentstotakeownership
werefewerthanteacherledsituations.
Inthecontextofteachingandlearningtasks,thepurposeoftaskswastypically
explainedtostudentsintermsofcurriculumintentions.Whenhelpingstudents
prepareforassessment,teachersusedrubricstodescribefeaturesofanswersthat
wouldattract‘fullmarks’.Almostallschoolsprovidedwrittenrubricstostudents
tohelpthemunderstandthecriteriathatwouldbeusedtoassignscores.Students
typicallyattemptedformalassessmenttasksindividuallyandwithoutassistance
fromothers.Theirresponsesweretypicallyscoredbyteacherseitherworking
alone(mostoften)orsharedwithotherteachers.Aswillbeclearfromthe
discussionfollowingrelatingtothenexttwodimensions,theuseofLISCtofocus
discourseandfeedbackwasmorefrequentinthesampleofteachersinWAEand
AEschoolswhencomparedtothesampleofteachersintheWBEschools.
Classroomdiscourseelicitingevidenceoflearning(CDEL)
Inthisdimensionofformativepractice,statisticallysignificantdifferenceswere
foundbetweenthethreeschoolgroupsrelatingtoteacher-directedclassroom
discussion.WAEteachersweremorefrequentusersthanWBEteachersofwait-
timebeforeresponding,ofdiscussionaboutitemsfromtestsandassignmentsand
studentresponsestothoseitems.WAEteachersmorefrequentlyaskedstudentsto
explaintheirthinkingaswellasexplainingtheir(teacher)thinkingtostudents.
TeachersinWAEschools,inparticular,hadastrongcommitmenttodeveloping
students’literacyskillsandhelpingstudentstoacquirethescientificvocabulary
neededtodescribeandexplainthescienceintheworldaroundthem.
MCFSWAE1providedamostlyschool-basedrangeofscienceactivitiesfocusedon
laboratoryworklinkedtotext-bookpracticalactivitiesandrelatedskills
development.Theheadteacherreportedanemphasisonwritingexplanationsasa
focusforYear7and8science.MGFSWBE1ontheotherhand,hadanemphasison
scienceprocessskillsbutstudentsalsoworkedonprojects(involvingVisualArts
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andPersonalDevelopment,HealthandPhysicalEducation)aswell.Studentswere
alsoprovidedwithexperiencesbeyondtheschoolgate(anexcursiontotheZoo).
Thegirlsweregivenopportunitiestodiscussscienceingroupsandinwholeclass
discussionandtomakemodelsanddeliverpresentationsaboutwhattheyhad
learned.ThegirlsatMGFSWBE1wereprovidedwithamorediversifiedsetof
science-richcontextsthancoedstudentsatMCFSWAE1andawiderrangeof
experiencesinwhichtoexplorethemeaningsofscience.
BothPCWAE1anditspairedschool,MCWAE1(pairone)providedstudentswitha
rangeofsciencerichcontextsbothintheschoolsciencelaboratoryandbeyondthe
schoolgate.Theteachersworkedhardatbothschoolstofitsyllabusintended
sciencelearningwithcontextsrelevanttotheexperienceofstudents.Bothschools
hadthesmallestYear7and8classesofallthecasestudyschools.Theexperiences
providedwerewellusedbyteacherstodevelopstudents’oralandwritingskillsas
wellashelpingthemtoacquirethevocabularyneededtodescribeandexplainthe
scienceintheexperiencesprovided.
MCAE2anditspairedschoolMCWBE3(pairtwo)providedarangeofschool-based
sciencelaboratoryandtext-basedactivitiesfortheirstudents.Thefocusatbothwas
ondevelopingskillsrelatedtoscientificinvestigationsinthosecontexts.MCAE2
engageditsstudentsinawiderangeofscienceprojectsanditsendsthebest
projectstotheNSWScienceTeachersAssociationYoungScientistAwards.Eachyear
itestablishesaclassofYear7studentswithaninterestinscienceandwhohave
donewellinascience-basedtestsetbytheschoolandcompletedinYear6.
PCWAE2andMCWBE5(pairthree)bothprovidearangeofschool-basedscience
laboratoryandtext-basedactivitiesfortheirstudents.PCWAE2makesuseofa
rangeofagriculturalcontextsoutsidetheclassroomandbeyondtheschoolgateto
widentheopportunitiesforitsstudentstoengagewithscience.MCWAE2provides
arangeofsciencerichactivitiesoutsidetheclassroomandbeyondtheschoolgates
toitsstudentsaswell.PCWAE2hasparticularemphasisondevelopingtheliteracy
skillsofitsstudentwithaparticularemphasisonwholeclassdiscussionand
readingaloud.
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Providingfeedbackthatadvanceslearning(FTAL)
Thiswasanotherdimensionwheretherewerestatisticallysignificantdifferences
betweenthethreegroupsofteachers.InthisdimensionbothWAEandAEteachers
weremorefrequentusersthantheirWBEcolleaguesofawiderangeof
opportunitiesforandsourcesoffeedbackrangingfromdigitalpolling,toticks,
marks,gradesandcomments,bothencouraginganddiagnostic(includingthe
provisionofmodelanswers,intermsofsuccesscriteria,misconceptions,SOLO
levels,elementsoftheQualityTeachingmodel,syllabusexpectationsandBloom
categories);WAEandAEteacherswerealsomorelikelytoasktheirstudentsfor
feedbackontheirteachingandtochangedirectioninlessonsinresponseto
studentfeedback.
ItwasestablishedinChapterFourthatEVresultsforstudentsinWAEschools
werebetterthancomparableAEorWBEschoolresults.Thebetterresults
indicatedthatWAEstudentsweremorescientificallyliteratethanstudentsin
comparableAEorWBEschools.Thusitwasnosurprisethatthedominanttheme
toemergefromtheWAEcasestudyschoolnarrativeswasthefocusWAEteachers
hadonprovidingfeedbackwiththeexplicitpurposeofdevelopingexpressive
literacyskillsandstudentacquisitionofsciencevocabularyrelatedtothescience
topicsbeingstudiedatthattime.
Activitiesincludedrequiringstudentstolearnthevocabularyrelatedtothe
conceptsbeingtaughtinthecurrenttopic(allsixWAEschools),bygettingthemto
writeextendedanswersonworksheetswithscaffoldsandspacetowrite
descriptions,comparisons,explanationsandjustifications(MCFSWAE1and
MGFSAE2).AttheendofYear8,MCFSWAE1andMGFSAE2hadalmostidentical
resultprofilesinthefourresultcategoriesmonitoredforthisproject.MGFSWBE1
hadamuch-reducedtopbandperformanceintheextendedresponsecategoryof
resultsthantheothertwoschools(seeTable5.10).Thedifferencetherewas
attributedbythisresearchertofeweropportunitiesbeingprovidedtothegirlsat
theWBEschooltoperforminthiswayandconsequentlessfeedbacktosupport
thatwayofrepresentingwhattheyknew.Theirpotentialforperformingstrongly
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inthiswaywassuggestedbythefactthattheirperformanceinthecommunicating
scientificallyreportcategorywasstrongerthantheothertwoschools(seeTable
5.10).
PCWAE1students,comparedtoMCWAE1studentshadthebetterEVresultoverall
andresultprofileaswell,butthenalmostalltheirstudentswerefromEnglishasa
firstlanguagebackground.ThatwasnotthecaseforMCWAE1students(85%of
theirstudentscamefromlanguageotherthanEnglishbackgroundsandarounda
thirdofthemwererecentrefugeeswithlittleornoprimaryschooleducation).
Thatsaid,theuseoffeedbacktoimprovelearningoutcomesatPCWAE1was
outstandinginthatitproducedaresultprofileforitsstudentsattheendofYear8
thatwasbetterthanmanyschoolswithhigherSEAscoressuchasMCWAE2,
MCWBE3andMCWBE5(seeTable5.1andTableK.1inAppendixI).
Wholeclassoraldiscussionofsciencecontextsandrelatedconceptswere
explicitlymentionedbyallsixWAEschoolsaswell.PCWAE1explicitlyreferredto
pretestingwhenstartingnewtopics.PCWAE2providedthemostevidenceofa
differentiatedapproachtodealingwiththediversityofstudents’literacyand
numeracylevelsatthetimeofinterestforthisproject.Thefeedbackprovidedby
PCWAE2teachersinthecontextofclassroomworkwasveryeffectivein
supportingsciencelearning(asdemonstratedclearlyinthebetterresultprofilefor
theextendedresponsereportcategorywhencomparedtoMCWBE5whichwasits
pairedschool(seeTableK.1inAppendixI).Bycomparisonthenarrativefor
MCWBE5showedanemphasisonprocessovertheacquisitionofconceptual
knowledge(andrelatedvocabulary).Theprofilesforworkingscientificallywere
verysimilar.Overall,PCWAE2hadapositiveskewintheirresultpattern;
MCWBE5hadanegativeskew).
Ofinterest,asdiscussedinChapterFiveweretheverydifferentlevelsofstudent
satisfactionwiththeirschoolscienceexperience.Thatwasrecordedbythesetwo
schoolsintheirresponsestothesixitemsfromthestudentsurvey.Onthe
combinedscoresforitemsDandE(enjoymentofsciencelessonsandscienceas
oneoftheirthreefavouritesubjects,PCWAE2ranked14th(outof16schools);
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MCWBE5ranked4th.SeeTablesK.5A-DinAppendixIfortheircomparativescores
onallsixitems.NotenjoyingsciencedidnotdeterstudentsatPCWAE2from
achievinghighlyandnordiditappeartodetertheirtakeupofseniorscience
courses,relativetoEnglishattheirschool,thestateandMCWBE5(seeTable5.9).
Thisapparentparadoxwillbefurtherdiscussedinthenextsection,Section6.4.
Asimilaroutcomeforthetwofullyselectivegirlsschoolswasinevidenceaswell.
MGFSAE2outperformedMGFSWBE1despitethelatterhavingahigherSEAscore.
OntheircombinedscoresforItemDandE,MGFSWBE1rankedaheadofMGFSAE2
(13thcomparedto16thoutof16).MGFSAE2’sprogramwasstronglytext-based
andlinkedtoconventionalsciencelaboratory-basedskills.Thegirlsatboth
schoolshadthe3rdand2ndhighestlevelsofagreementwiththestatementthat
sciencewasthemostdifficultsubjecttheylearnt(MCFSWAE1was1st).Their
artifacts,whencomparedtothoseoftheothercasestudyschools,showed
knowledgeandunderstandingdemandswayabovetheotherschools(andforthat
mattersyllabusexpectationsaswell).Intheendthetake-upofsciencesubjects
overallbytheWBEschoolwasgreaterthanintheAEschool(relativetothestate)
byawidemargin(seeTable5.11).
SummativeassessmentatPCWAE2wasmuchmoreconsequentialforstudents
thaninothercasestudyschools.Studentsweremovedtoadifferentclassatsix
monthlyintervalsifperformanceandachievementwaseitherverygoodorpoor.
Thereasongivenforthatwastobetterpreparestudentsforsuccessinsenior
sciencecoursesasameanstotheendofobtaininggoodscience-relatedjobsafter
school.
Activatingstudentsasinstructionalresourcesforoneanother(includingpeer
assessment)andtheirteachers(ASIR)
Therewerenostatisticallysignificantdifferencesbetweenteachersinthethree
schoolgroupswhenitcametoactivitieslinkedtothisdimensionofformative
practice(seeTable4.15).Teachersinthethreeschoolgroupshadcomparable
usagefrequenciesforactivitiessuchascollaborativelypreparingassessmenttasks,
markingcriteriaorrubricsandsharedmarking(approximately95%said
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sometimesoroften).WhenitcametoprovidingstudentsinYears7and8with
opportunitiesforpeerassessment,theywerelimitedandsubjective(notwell
groundedinthelanguageoflearningintentionsandsuccesscriteria).Examples
mentionedintheartifactswerenotlimitedtoWAEschools(PCWAE1and
MCWBE5includedexamples).Intermsoffrequencies(combiningsometimesand
oftenresponsestoitems)fortheprovisionoffeedbacktopeersusingsuccess
criteria,workingingroupsonthink-pair-share-reportactivities,writinglearning
intentionsandsuccesscriteria,constructingassessmentitemsandtasks,the
proportionsrangedfrom86%beingprovidedwithopportunitiestousesuccess
criteriaorassessmentrubricsandguidelinesto24%beinggiventhechanceto
constructassessmentitemsandtasks.Anumberofschoolsmentionedthatthey
gavemoreopportunitiesforstudentstoprovidefeedbacktoeachotherinYears9
and10(MGFSAE2,MGFSWBE1,MCWBE5andPCWAE2).
Activatingstudents(andteachers)asownersoftheirownlearning(includingself-
assessment)(ASTL)
Analysisofteachersurveyresultsforthisdimensionrevealedstatistically
significantdifferencesintheteacher-initiatedaspectsofthisdimensionof
formativepractice(seeTable4.35).WAEteachers,comparedtotheirWBE
colleaguesweremorefrequentevaluatorsoflessons,keepersofnotesonlearning
issuesindividualstudentshave,accessorsofinformationaboutassessment,more
frequentlyengagedwithcolleaguesinactivitiesrelatedtoimprovingpersonaland
sharedknowledgeaboutsyllabuslearningintentionsandwhatprogressionin
sciencelearning‘lookslike’.Themeansbetweenthethreegroupswerenot
statisticallysignificantlydifferentintermsoftheopportunitiesprovidedto
studentstoredoworktoahigherstandard(71%ofteacherssaidtheydidthis
sometimesoroften),gettingstudentstoself-selectitemsforportfolios(30%said
sometimesoroften)andkeepingajournalofreflectivewritingonscience(23%
saidsometimesoroften).
Astheaboveshows,opportunitiesforstudentstoself-assesswerenotlimitedto
WAEschoolsandthoseopportunitieswereinfrequent.Twoexampleswere
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recordedinthenarrativesforcasestudyschools.PCWAE1providedan
opportunityinthecontextofatoyprojectandMCWBE5gavestudentsthe
opportunitytoself-assessagainstfivecriteriaonanumberoftasks.
Theanecdotalevidencefrominterviewandartifactswasthatwherepeerandself-
assessmentwerediscussedduringtheinterviews,theywereopportunitiesgiven
moretostudentsinYears9and10thanYears7and8atthetimeofinterestfor
thisproject.Thesamewastrueforextendedgroupworkanduseofstrategiessuch
asthink-pair-share-reportorjigsawmethods.
ThefindingthatWAEteachers,comparedtotheirWBEcolleagues,weremore
frequentusersofawide-rangeofactivitiesinvolvingtheuseandmodeling(to
peersandstudentsalike)ofgoodlearningbehaviourswasindicativeofthem
‘practicingwhattheywereteaching’.Thiswasmostmentionedwhenitcameto
staffmeetingswhereassessment-relatedworkwasbeingdiscussed,when
assessmentitemsandtaskswerebeingcollaborativelydevelopedorselected,
whenmarkingrubricswerebeingdevelopedandcollectivelyusedwitheachother
andstudentstoassessstudentresponsestotasks(seesection4.3.2.5).
Overviewofandreasonsforusingornotusingformativeassessment
ScienceteachersinNSWgovernmentschools,afteradecadeofexternallyprovided
Year8sciencetestingandrelatedfeedbackonachievementinformedbytheSOLO
model,havenottakenupSOLOinasubstantialway.Themostprobablereasonfor
itnotbeingmorewidelyadoptedbeingtherequirementtoreportachievementin
termsofgradeslinkedtosyllabusstandardsnot,themselves,definedwithany
referencetotheSOLOmodel.ThiswasexplicitlymentionedbyPCWAE2asone
reasonfornotcontinuingwiththeVALID10testaftertheyearofitsintroduction
in2015.
EVsciencetestresultswerebestinschoolswherescienceteachersweremore
frequentusersthantheircolleaguesinotherschoolsofactivitiesrelatedtothree
dimensionsofformativepractice.Thedimensionswere:
278
• discourseelicitingevidenceoflearning(seconddimension);
• theprovisionoffeedbackknowntoprogresslearning(thirddimension);
and
• theuseandmodeling(topeersandstudentsalike)ofgoodlearning
behaviours(fifthdimension).
Thefirstdimensionaboutlearningintentionsandsuccesscriteriawasbeingwell
usedbyteachersinallschoolstoguidebothinstructionandassessment.The
languageofintentionsandcriteriawerealmostinvariablyderivedfromthe
languageofoutcomesandrelatedcontentthatdefinedcurriculumstandardsinthe
officialcurriculumforNSWschools.Teacherusedominatedthisdimension.The
overallresult,relativetothefourpointscaleofnever,seldom,sometimesand
often,wasbetweensometimesandoftenasshowninFigure4.12.Opportunities
forstudentstodevelopskillsintheirusewasratedbetweenseldomand
sometimes,butclosertosometimes.
Thefourthdimensionofformativepracticerelatestoactivatingstudentsas
instructionalresourcesforeachotherandtheirteachers.Studentperformances
provideteacherswithfeedbacktheycanusetoadjustandimproveinstruction.
Providingopportunitiesforpeerassessmentisanotherwayofdoingthat.
Teachersoverallwereevenlydistributedintheirresponsestoitemsrelatedtothis
dimensionbyansweringfromseldomtosometimes(Figure4.15).Therewas
anecdotalevidenceofmorefrequentopportunitiesforstudentstoengageinboth
formalandinformal(structuredgroupwork)peerassessmentinYears9and10.
Howeverteacher’sworkingtogethertodevelopassessmentprograms,itemsand
sharedmarkingwasratedbetweensometimesandoften,butclosertooften).
Noexplicitreasonsemergedfromtheinterviewsastowhystudentsweren’tbeing
givenmoreopportunitiestodeveloptheskillsofformativeassessmentinscience
forthemselves.However,apossibleexplanationmaybefoundintheofficial
sciencecurriculumwherethelanguageusedtodescribeskilloutcomesforthefirst
twoyearsofsecondaryscience(outcomes13to22of22outcomes)isexplicit
abouttheneedforteacherguidance.The‘guidance’providedbyteachersof
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studentsinthoseyearstooktheformofworksheetsthateffectivelyledstudents
frombeginningtoendofatask(asevidencedintheartifactssupplied).The
studentresearchtaskwasinalmostallcasestudyschoolsaheavilyscaffolded
projecttellingstudentswhattheycouldandcouldnotresearch,howtodoitand
whatneededtobeincludedinawrittenreportattheend.
6.4Discussionoffindingsaddressingresearchquestionthree
Researchquestionthreeasks:Doestheuseof(andifso,howdo)formative
practicesimprovestudents’EVresultsandlaterachievementinandengagement
withscience?
Theshortanswerforschoolsthatself-identifiedis‘yes’whenitcomestotheuseof
EVresults.Table5.1listsalltheschoolsthatidentifiedthemselves.Schoolsare
listedinorderofthesizeandpolarityoftheresidual(secondlastcolumnfromthe
right)fromregressingtheirEVresultsoveranEVresultpredictorderivedfrom
NAPLANscoresasexplainedinChapterThree.
TheresidualisthemeasureofaneffectsizeofteachingontheEVresultaswas
alsoexplainedinChapterThree.Theschoolsweregroupedaccordingtothesize
andpolarityoftheresidual.WAEschoolshadresidualsthatplacedtheminthetop
20%ofschoolsandWBEschoolshadresidualsthatplacedtheminthebottom
20%ofschools.InChapterFourthefindingsfromasurveyofteacherassessment
relatedpracticeswerethatteachersatWAEschoolscomparedtoWBEschools
weremorefrequentusersofactivitiesassociatedwiththreeofthefivedimensions
offormativepractice.TheEVresultsofschoolsassociatedwithlargepositive
residualswerealsoschoolswherescienceteachersweremorefrequentusersof
activitiesassociatedwiththreeofthefivedimensionsofformativepracticethan
theircolleaguesatotherschoolswithsmallerresiduals.
OtherresearchdiscussedinChapterThreeexplainedthatthreemajorfactors
contributetotheaccountedforvariabilityoftestresults,namely,studentsocio-
culturalbackgroundandpreviouslearninghistory(50%),theactionsoftheir
teachers(30%)andschoolenvironmentfactors(20%).AsdiscussedinChapter
280
Three,theSEAscoreforaschoolisanindependentmeasureofthelearning
potentialstudentsbringtoschoolandthiswasthebasisforcreating“comparable
pairs”ofschools.Becauseitwasimpossibletoaccountobjectivelyforthe20%of
schoolenvironmentfactorsintwodifferentschools,comparingdifferentschools
withthesameSEAscorebutwidelydifferentresidualsprovidedthebest
opportunityforconfirmingthatdifferencesintheuseofformativepractices
providethemostlikelyreasonforEVresultdifferences.
Onthatbasis,itwasestablishedinChapterFourthatforcomparableschoolpairs,
theschoolwithbetterEVresultswasassociatedwithmorefrequentuseby
teachersofactivitiesassociatedwiththreeofthefivedimensionsofformative
practice.Thoseactivitieswere:
• promotingclassroomdiscoursethatelicitsevidenceoflearning;
• providingfeedbackknowntoprogresslearning;and
• theuseandmodeling(topeersandstudentsalike)ofgoodlearning
behaviours.
Theassessment-relatedworknarrativesforWAEschoolsallincludedstrong
referencestousingsciencecontextsforthespecificpurposeofhelpingstudentsto
acquirescientificvocabularyandtheskilltouseitappropriatelyandfluently
(orallyandinwriting).MGFSAE2alsohadahighpriorityfor‘writing’science.The
assessmentnarrativesoftheothercasestudyschoolsgavemoreprominenceto
otherpriorities,suchasinvestigationskills(MGFSWBE1,MCAE2,MCWBE3,
MCWBE5)oridentitybuilding(MCWBE4).Byputtingtogethertheanalysisofthe
surveysandapriorityforusingthelanguageofscience,thefollowingpictureof
formativepracticeinWAEschoolsemerged.
TeachersinWAEschoolsmanagedclassroomdiscoursethatproducedevidenceof
learning(theseconddimensionofformativepractice)thatinformedteacher
feedback(thethirddimension)onhowwellstudentsweredoinginusingscientific
language.Teachersspentalotoftheirclass-timemodellingtostudentsgood
learningbehaviours(thefifthdimension)foracquiringtheskillsandtexttypes
relatedtoscientificliteracy,includingusingprescribedlearningintentionsand
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successcriteriarelatedtoscientificliteracy,toself-evaluate.Theanswertohow
formativepracticesimproveEVresultsrestsonthecredibilityoftheclaimthatthe
formativeuseofliteracystrategiesinsciencecontextsisthemostpowerful
influenceonsciencelearningoperatinginthecasestudyschools.Referencesmade
toHattie’s(2018)workoneffectsizesofdifferentinterventionsonlearninginthe
openingsectionofthischapterprovidesindependentconfirmationofthepowerof
suchapproaches.
Ahoped-forlastingeffectofstudentexposuretoformativepracticewastheir
acquisitionoftheskillsandattributesofself-regulated,autonomouslearners.This
wasanexpectationbasedonworkreportedintheliteraturereview(ChapterTwo)
linkingexplicitteachingoftheskillsofformativeassessmenttostudentself-
regulation(Blacketal.,2006andJamesetal.,2007).OngoingexposureafterYear
8tohigherfrequencyteacheruseofformativepracticeand,perhaps,acquisitionof
studentself-regulation,inthatlight,shouldcontinuetoproducebetterresultsfor
thosestudentsattheWAEschool(atbothYear10andinseniorsciencecourses).
Also,theexpectationwasthathigherproportionsofstudentswouldbecompleting
seniorsciencecoursesthanintheirpairedschool.Thatlegacymaybethe
explanationforbetterlaterachievementandhigherengagement.
However,inrelationtothelaterachievementandengagementpartofresearch
questionthree,analysisreportedinChapterFiveofdatafromassessment-related
worknarrativesassociatedwiththecasestudyschoolswasnotasoundbasisfor
makinganyclaimsaboutanongoingeffect.Thecorrelationbetweenthemeasure
ofYear8engagementandYear12sciencecoursecompletionsinconclusive.
However,thecorrelationsbetweenYear8achievementandYear12sciencecourse
completionsataschoolwaspersuasiveforthecasestudyschools.Giventhe
unreliabilityofcomparingYear8andYear10resultsandabsenceofapersuasive
supportingcorrelationsbetweenYear8engagementandYear12engagement,the
acquisitionofself-regulationbymorestudentsinhighresidualschoolscompared
toother,lowerresidualschoolsasproposedherecouldnotbejustified.
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Fromtheabovediscussionofevidence,itisreasonabletoclaimthatteacheruseof
formativepracticeshelpedstudentstoachievebetterresultsinscienceattheend
ofYear8.Anadditionalconclusionthatstudentsexposedtothosepracticeshad
acquiredtheskillsofself-regulationasaconsequenceofexposuretothose
practicescouldnotbesupportedbytheavailableevidence.
6.5Suggestionsforfurtherresearch
Giventheimportanceofproducingstudentswhoareself-regulated,autonomous
learnersbythetimetheyleaveschool,furtherstudiesusingtheresearchdesignat
thecoreofthisprojectiswarrantedbythefindingsreportedinthisthesis.Theuse
ofreliable,comparabledataonachievementandengagementafterYear8to
investigatetheworthofteachingformativeassessmentstrategiestostudentsmay
beworthwhile.Additionalresearchtothatendisdiscussedbelow.
Provincialstudentsapparentlowregardforscience
ThefindingsreportedinChapterFiveaddweighttoconcernsalreadyexpressedby
otherresearcherswhohavereportedsimilarfindingsfromtheirresearchfor
provincialstudentsintheearlyyearsofsecondaryschooling.LyonsandQuinn
(2010,2012,2014)confirmthatAustralianprovincialschoolstudents’negative
attitudestosciencerelativetotheirmetropolitancounterpartspersistuptoYear
10.Theresearcherscouldonlyspeculateastothereasonsforthatnegativitybut
didseeitasabarriertobeovercome(curriculummismatchwithstudent
experience,ashortageofspecialistteachersandlackofperceivedrelevancewere
someofthepossibilitiestheylisted).TytlerandSymington(2015)writingin
TeachingSciencelistotherresearcherswhoreportedsimilarfindings.
Asmentionedintheopeningparagraphofthischaptergraduatingstudentswho
knowhowtolearnisimportant.Thatbeingso,thenitisimportanttofindoutwhy
provincialstudentsdon’tenjoyanexperiencethatmanyareclearlydoingwellat
(aftertakingintoaccounttheirlowerliteracyandnumeracylevelscomparedto
theirmetropolitancounterparts)isalsoimportant.Ifprovincialstudentsboth
understandwhytheyaredoingbetterthanexpected(byacquiringthefluencywith
283
andcontroloverthelanguageofscienceattheveryleast)andfeeltheyaredoing
betterthanexpectedthatmightprovidethemotivationforevenmorestudentsto
takeupscienceinthesenioryears.Palmer(2015)identifiedstudentenjoymentof
scienceasareasonfortakingitupinthesenioryearsofschoolingandhopefully
beyondintopreparationforaSTEMcareer.
Afirstsuggestionforfutureresearchinthisareamaybetotryandunderstand
whyprovincialstudentshavealesspositiveviewoftheirschoolscience
experiencethantheirmetropolitancounterparts.Aninitialprojectmight
undertakeafullanalysisofthestudentsurveysforthecasestudyschoolsinthis
project.TheDepartmenthasthatdatafrom2005uptothepresenttime.Atthe
veryleast,itmayprovideamorenuancedunderstandingofstudents’viewsabout
theirexperienceofscienceatschoolandadditionalcluesastowhytheydon’tlike
science.Schoolfactorsexternaltothescienceclassroommaybeacontributor,but
theconsistencyofthelowregardbystudentsinprovincialsettings(allthreeofthe
provincialWAEschoolsinthisproject)maywellhavemoretodowithparent
socio-culturaldispositionsthataccordalowervaluetoscienceinthose
communitiesthanelsewhere.Arelatedquestiontoexplorewouldbewhy
provincialstudentstakeupseniorsciencecourseswhentheyclearlydonotlike
thesubject.
Studentbackgrounds,accordingtoHattie(2003b),areresponsibleforuptohalf
theaccountedforvariationintestresults.Thesuggestionthatthesevaluesmaybe
implicatedcomesfromthefindingthatstudentsatthethreeschoolsalsorecorded
lowenjoymentoftheirprimaryscienceclassexperiences(ItemCinthestudent
survey).Topbandachieversatthethreeprovincialschoolsrankedtheir
experienceatprimaryschoolyearsscienceexperiencesat12th(PCWAE1),7th
(PCWAE2)and16th(PCWAE3)outofthe16schoolscomparedhere(thestate
resultwascountedasaschoolinTableK.5BinAppendixI).
Theimportanceofself-regulation
Giventhegrowingimportanceofproducingself-regulated,autonomouslearnersas
avaluedoutcomeofschoolingitmaybeusefultoconfirmwhetherputtingmore
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effortintoexplicitlyteachingstudentsthestrategiesofformativeassessmentisthe
mosteffectivewayofdoingthat.Itmaybethatotherteachingapproachescando
thejobmoreeffectively.Twoapproacheshavealreadyshownpromiseinthat
regard.Thefirstisinquiry,thesecondisproblemsolving.Theirimportanceas
aspectsofscienceeducationisreflectedintheworkingscientificallyand
communicatingscientificallyEVreportingcategoriesrespectively.
Theassumptionisthatpenandpapertestsareabletoprovidesufficientvalid,
reliableandauthenticevidenceoftheattributesofself-regulationandlearning
autonomy.ThemethodologydescribedinChapterThreecouldjustaseasilybe
appliedtoexploringwhether,forexample,inquiryorproblem-solvingapproaches
wouldbeamoreeffectivemeanstothatend.Teachersurveysdesignedto
characteriseteachingthatreflectsbestpracticeinteachinginquiryandproblem
solvingmaybesubstitutedfortheformativepracticessurveyusedinthisproject.
Anappropriatesetofinterviewquestionscouldbedeveloped,artifactscollected
andrelatednarrativesgeneratedtoexamineforcorroborationoffindings.
Anotherapproachtoinvestigateisthatofrepresentationalpedagogieswhichwere
speculativelypositedasa“signaturepedagogy”forsciencebyTytler,Prain,Huber
&Waldrip(2013).Researchpapersalreadypublishedcouldprovidetheactivity
descriptors(suchastheoneonforcesespousedbyHuber,TytlerandHaslam
(2010))withwhichtogeneratesurveyitemsthatcouldbepilotedwithschools
knowntobeearlyadoptersofthesepedagogies.
Representationalpedagogiesareessentiallyformativebecausetheyshiftthe
emphasisfromwhattheteacherisdoingtowhatthestudentisdoing.That
approachtoteachingengagesstudentsincreatingrepresentationsofwhatthey
arelearningandchallengesstudentstotestthelimitsoftheirexplanatorypower.
Therepresentationsproducedmaybeinavarietyofformssuchasdiagramsand
3-Dmodels,writtentexts,presentationsusingICTandincludingaudioandvideo
contentoranycombinationthatisdeemedappropriateforpurposeandaudience.
Curriculumintent,pedagogyandassessmentareevaluatedforalignmentbyall
participantsinthebackandforwardnegotiationofmeaning.Representational
285
pedagogiesmaywellbeamoreeffectivewaytoproducestudentswhoareself-
regulatedandautonomouslearnersthanthecurrentapproachintheUKto
explicitlyteachstudentsthestrategiesofformativeassessment(James,2006).
Confirmationoffindingsfromtheinitialresearchproject
Asmentionedabove,theintroductionoftheVALID10testprovidesstandardised
achievementresultsforstudentsinallparticipatingschoolsattheendofYear10.
Theschoolsetsofscienceresultscanbeusedtoevaluatethepredictionthatin
pairsofcomparableschools,theschoolwiththehigherresidualwillcontinueto
producebetterresultsattheendofYear10andagaininsciencesubjectsatthe
endofYear12.DatasetsforthisprojectshouldbeavailablefromtheDepartment
forcohortsofstudentsdoingVALID8(beginning)in2015(basedonthenew
nationalcurriculum),VALID10in2017andY12resultsfrom2019.
Smallerstudiesmaychoosetotestthevalidityandreliabilityofaspectsofthe
methodologyusedinthisproject.Giventheclosenessofthecoefficientsof
determinationforthefourpredictorsused,itmightbesimplertousetheYear7
NAPLANreadingresultsontheirownasthebasisforthepredicatorusedinthe
regressionanalysiswithoutseriouslossintheintegrityofthefindings.
Theteachersurveyinstrumentwouldbenefitfromincludingawiderarrayof
strategiesthatmaybebeingusedbyteacherstoenhancestudentagencyas
autonomouslearners.Hattie(2018)hasalistof33strategiesundertheheadingof
Strategiesemphasizingstudentmeta-cognitive/self-regulatedlearning.Also,
existingPEELresources(Mitchelletal.,2009)couldbeaccessedforappropriate
“goodlearningbehaviours”(p.172).Procedurescouldbetestedforrecognitionby
teachersandselectedforinclusion.AstrategynotonHattie’slististhePredict-
Observe-Explainsequence(White&Gunstone,1992).Theexpandeditemsetso
producedcouldbeaddedtotheteachersurveyforarepeatoftheoriginalstudy
alongwiththeenhancementsmentionedabove.
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Anadditionalenhancementwouldbetoincludeinterviewswithandartifact
collectionfromYear10teachersrespondingtoascienceteachersurvey.The
surveyshouldbethesameforbothYear8andYear10teachers.
Thisprojectusedtheaverageoffourconsecutiveyearsofstandardizedresiduals
asthebasisforchoosingmaximumvariationcases(Flyvbjerg,2011).Inafuture
study,researcherscouldlookforschoolswheretheresidualswereincreasingover
theyears;weredecliningovertheyearsandlookforchangesintheassessment-
relatedworknarrativesforthoseschoolsinabeforeandafterstudy.
Evidencegathering,apartfromthemethodsdescribedabove,couldbeexpanded
toincludeclassroomobservations(recordedbypeople,audioandorvideo
technology)ofteacherenactmentsoftargetstrategiesandstudentresponsesto
them.Theseobservationscouldbeusedtocorroborateteacherresponsesto
surveysandusedtoconfirmthefidelityofstrategyinterpretation.
Giventheabovesuggestionthatcommunityvaluingofsciencemaybeafactor
inhibitingstudentengagementwithscience,itmaybeusefultohavesamplesof
parentsrespondtoappropriateitemsfromthecurrentstudentsurveyinthefirst
instance.Theirresponsestothesame(ortestedequivalentitems)mayprovide
insightsintothesourceofstudentattitudes,particularlyifstudentsandtheir
parentsindependentlycompletethesurveyandtheirresponsesmatchedand
comparedwiththeirchild’sresponses.Intheeventthatthisdoesnotprovidethe
neededinsight,awiderrangeofquestionsaboutsciencemaybehelpful.Tothat
end,BarryFraser’s(Fraser,1978)TestofScienceRelatedAttitudes(TOSRA)survey
mightbeagoodstartingpoint.
6.6Recommendations
ThissectionprovidesrecommendationstotheDepartment,theNSWEducational
StandardsAuthority,theAustralianCurriculumAssessmentandReporting
Authorityandawideraudienceofeducationalresearcherswithaninterestinthe
theoryofformativeassessment,itsintegrationwithinstruction(formative
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practices)anditspotentialforguidingstudentstolearnhowtolearn.The
recommendationsaresupportedbythefindingsreportedinthisthesis.
Theinterestofawideraudienceofeducationalresearchersispredicatedontheir
priorinterestintestingthepowerofformativeassessmenttoimprovestudent
achievementinandengagement(especiallybeyondschool)withscience.Inthat
light,itishopedthatsomeresearchersmightbepreparedtoundertakefurther
workalongthelinessuggestedintheprevioussectiontoaddmoreweighttothe
bodyofresearchsupportingthepowerofformativepracticetoimprove
achievementinandengagementwithscience.
Oneoftheclaimsforimportanceofthisresearchisthemethodologydevelopedby
thisresearchertoisolatethecontributionofteachingfromothercontributionstoa
testresult.Hereitwasusedtoseparatethecontributionofgeneralliteracyand
numeracyskillsfromthescientificliteracycomponentinasciencetestresult.The
scientificliteracycomponentiswhatstudentshavelearnedinthecontextoftheir
sciencelessons.Otherresearchersmightbeinterestedtouseitandconfirmits
utilityinotherlearningareasapartfromscience,suchasgeographyorhistory.
ThelatestroundofPISAtestingcompletedin2015(seeChapterTwo)emphasized
thatprovidingfeedbackonthelevelofthinkingdemonstratedinstudent
responsesisusefulbecauseitdifferentiatesbetweenrecallofanattributeofone
scienceconceptandbeingableto“relateandevaluatemanyitemsofknowledge”
(OECD,2017),p.40).Demonstratingthelatterinasciencecontextisarguablya
highervalueresponseinthecontextofassessingcompetenceinscientificliteracy.
Todosorequiresastudenttousemorecognitiveresourcesthantherecallofa
singleattribute.Tobescientificallyliterate,asthePISAframeworkspecifies,
requiresstudentstooperateatalevelwheretheycanrelateandevaluatemore
thanoneitemofknowledge.Includingcognitivedemandasadimensioninthe
assessmentframeworkenhancesthevalidityofthetestconstructandresultsfrom
it(Messick,1995;Mislevy,2008).
Afterconsideringanumberofschema’tooperationalizetheconstructofcognitive
demand,includingtheBiggsandCollis(1982)SOLOtaxonomy,thedevelopersof
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thePISAtestadaptedWebb’sfourlevelDepthofKnowledgemodel(Webb,1997)
tothatend.
TheOECD-PISAdecisiontoincludecognitivedemandasanaspectofcompetency
inscientificliteracyvindicatedthedecisionbytheDepartmenttoincludea
cognitivedemanddimensionfromtheoutset(2005)initsassessmentframework
fortheEVprogram.TheDepartmentusedtheSOLOmodeldevelopedbyPegg,
PanizzonandothersattheUniversityofNewEngland(Panizzon,2003).TheSOLO
modelwasanevolutionoftheSOLOTaxonomyfirstpublishedbyBiggsandCollis
(1982;1991)andwasdescribedinChapterTwo.Giveninternationalsupportfor
andacceptanceofcognitivedemandasanexplicitenhancementtothePISA
assessmentframeworks,itwouldbeapitytodiscontinuetheonelargescale
assessmentprojectinAustraliawhereitisafeature.
AtthistimeneithertheNSWcurriculumauthority(NESA,2017)northeACARA
publishedachievementstandardsforthecurrentnationalAustralianCurriculum:
Science(ACARA,2018)includeeitherexplicitorimplicitrecognitionofcognitive
demandasadimensionintheirdefinitionsofcompetencyandrelatedassessment
supportmaterialsoradvice.Intheinterestsofimprovingthevalidityof
assessmentandensuringongoingalignmentbetweencurriculumintent,related
instructionandassessmentvalidityasdiscussedintheNRC(2001)report,ACARA
mightwanttoconsiderhowfutureiterationsofthesciencecurriculum(atthevery
least)respondtoPISAleadershipandincludereferencestodifferentlevelsof
complexityinthinkinginitsScienceSequenceofAchievementdescriptions(ACARA,
2018).RatherthandropSOLOforWebb’smodelasusedbyPISA,externally
designed,large-scaletestscouldlookatusingSOLOastheirmodelbecauseofits
historicalprioruseinscienceeducationandelsewhereinAustralasia.
ThetworeportsfromthelastroundofYear6NAPtestinginScienceLiteracyhave
droppedtheAppendicescarriedbysuccessivereportsuptoandincluding2012
wheretheconnectionbetweenSOLOandthattestwasexplained(ACARA,2017).
SOLOwasusedasaclassifierforitemsproducedbyACERtopopulatethedata
baseofscienceassessmentitemsinthecontextofthenationalScienceEducation
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AssessmentResourceproject(ACER,2004a).Thecurrentversionofthatresourceis
beingmanagednowbyEducationServicesAustralia(ESA,n.d.).SOLOisalsoused
toinformfeedbacktoprimaryteachersinNewZealandwhohaveuseditemsfrom
the,sotitled,e-asTTledatabaseofitemstoassessstudentachievementand
progressinreading,mathematicsandwriting(Hattie&Brown,2004).
ThepresumptionoftheDepartment’sinterestisbasedonthefactoftheirtangible
supportforthisprojectbyprovidingthisresearcherwithaccesstoEVtestdata
andrelatedstatisticalanalysis.Therecommendations(below)forchangein
practiceareanexpectedoutcomefromusingatransformativemixedmethods
researchdesigninthisproject(Creswell&PlanoClark,2011).
OnepartoftherationalefortheDepartmentcontinuingwiththeVALIDprogramis
thatitincludesthedimensionofcognitivedemandinitsassessmentframework
andhasdonesofromitsinceptionin2005.Includingcognitivedemandinthe
assessmentframeworkoftestsimprovesthevalidityofthetestasdiscussed
earlier.TheinclusionofcognitivedemandintheOECD-PISAtestassessment
frameworkisvindicationoftheDepartment’searlierdecisiontouseSOLOasthe
basisformeasuringcognitivedemandinitsEVtest.Asecondistheendorsement
oftheEVtestprovidedbyFensham(2013)whosaysthatthe[EV]test
developmentprocessiscomparabletothePISAandTIMSSdevelopment
processes.Inthesamebook,achapterbyMiller(2013)arguesthatassessment
modelsareanimportantcomplementtocurriculumdocumentsbecausetheyhelp
teacherstooperationalizecurriculumstandardsandshowhowbesttoassess
curriculumintentions.
TwocomponentsofthecurrentEVtestdesignaresingledoutforfurther
comment.Thefirstarethethreeextendedresponseitemsincludedineachtest.
Theextendedresponsetasksmodelopen-endedquestionsthatenablestudentsto
respond,usingwrittentext,atthehighestlevelsofthinkingtheyarecapableof.
Thecapacitytowritescientificexplanationsisahighlyvaluedoutcomeofscience
educationwhichsome,atleast,ofthecasestudyschoolparticipantsexplicitly
acknowledged.Inclusionoftheextendedresponseitemsinthetestsignalsto
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scienceteachersandstudentstheimportanceofthisskill.Theevidencereported
inthisthesisshowedthattheresultsofstudentsexposedtoexplicitteachingof
literacystrategiesinformativewaysleadstobetterthanexpectedresults.
Thesecondistheuseofsciencerichstimulusmaterialdrawnfromthewider
readingandInternetexperienceofstudentsascontextsforsciencequestionsisan
importantsignaltostudentsandteachersoftherelevanceofsciencefordealing
rationallywiththeworld.Italsoprovidesopportunitiesforitemconstructionthat
provideshigherlevelsofcognitivechallengetostudentsinaformthatisan
authentictestofaspectsofscientificliteracy(seeaboveinthediscussionofthe
PISArationaleforincludingcognitivedemandinitsassessmentframework).With
somemodification,itemsandtaskscouldeasilybeamendedtoprovideforawider
rangeofresponsesthanwrittentextsalone.Thiswillbeimportantonce
representationalpedagogiesandothermoreprogressiveapproachesbecome
morewidelyused.Thecapacitytouploadvideoandsoundaswellasphotosand
diagramsshouldbeconsideredinadditiontotheconstructionofwrittentextsnow
thatthetestisdeliveredonline.Inthecontextofatest,thesetofitemsatesteeis
providedwithcanbechangedtobettermeettheirdemonstratedability(as
assessedbythesoftwaremanagingtheitemsetbeingdeliveredtothetesteeas
theydothetest).
Thecapacitytouploadawiderrangeofresponsestoitemsandtaskswouldbe
madeeasierbytransformingtheonce-a-yeartesttoanonlinerepositoryofitems,
relatedstimulusmaterialsandextendedresponsetasksfromwhichteacherscould
choose.Theycouldretainandstoreitemsonlineuntiltheyenabledaccessfortheir
studentsastheyworkthroughthetopicorattheendorboth.Thecapacityfor
immediatefeedbackontheirlearning,thisbeingoneofthemostpowerfulmeans
forsupportinglearning,wouldthenbeprovided.Therearealreadyanumberof
items(andrelatedstimulusmaterial)andextended(open-ended)responsetasks
goingbackto2005heldbyESA(SEAR,2004)thatcouldbeusedtopopulatesucha
repository.
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Onlineavailabilityofassessmentitemsandtaskshasanumberofpotential
advantageswhichincludethecapacityto:
• provideimmediatefeedbacktoteachersaboutstudentexperienceof
science(usingitemsfromthecurrentstudentsurvey);
• provideabriefdescriptionofitemandtasklinkstocurriculumintentions;
• informationaboutthelevelofcognitivedemandoftheitemortaskand
possiblereal-worldsituationswhereengagingwiththeparticularitemand
itsstimulusmaterialortaskhasbenefitsfortheindividual,societyorthe
environment;
• provideexplanationsofalternativeconceptionsindicatedbystudent
selectionofparticulardistractors(inmultiplechoiceitems)infeedbackto
students(andteachers);
• suggestionsforactivitiestocorrectmisconceptions(alreadyprovidedin
SMARTforthecurrentversionoftheEVtests);
• providearangeofanswersthatwouldbescoredatdifferentlevels
accordingtotheSOLOmodel(forextendedtasksonly);and
• thehistoryofitemandtaskuseandstudentanswerscouldberetained
onlineandmadeaccessibletobothteachersandtheeducationsystemfor
monitoringpurposes.
Thelastpointwouldenablestrongermeasuresofitemreliabilityanddifficulty
(psychometricdata)tobeconfirmedovertimeaswellasenablingmonitoringof
changeinthequalityoflearningovertimebybothteachersandthesystem.Also,
transparencyabouttheusesofthatdatawouldneedtoclearlyprovidedand
agreedtobyallparticipants.
Studentself-assessmentisseenasanimportantskillforstudentstoacquireinthe
contextofbecomingautonomouslearners(Blacketal.,2006).Withthatinmind,
waysfordirectaccessbystudentstoafuturerepositoryofassessmentitemsand
tasksshouldbedevelopedandtrialed.Inthisscenario,studentswouldbeableto
selectandcompleteitemsandobtainimmediatefeedbackontheirresponses.
Studentaccesscouldbemanagedinawaythatprotectstheintegrityoftheitems,
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relatedstimulusmaterialandextendedresponsetasksbutenablesthedataon
responsestobegeneratedandretained.Studentresponsesshouldalsoberetained
forteacheraccessaswelltoenablethemtoevaluatehowlearningisprogressing
asithappens.Thiswouldprovidetheopportunityforteacherinterventionsbased
onwhattheyseehappeningonlineasstudentsengagewiththematerialthere.
Atthepresenttime,EVdataisprovidedtoNSWschoolsandnotpublishedinthe
samewayasNAPLANdata(onaschool-specificwebsiteforalltheworldto
access).ThefindingsreportedinChapterFivewerethatscienceteachers
understoodthepurposeoftheEVtest,werewillingtoengagewithitandfeedback
fromitandappreciatedtheabsenceofpressuresexperiencedbytheircolleagues
moredirectlyassociatedwiththepublicationofNAPLANresults.Itisstrongly
believedbythisresearcherthatshiftingtheitemsandtasksintoanonline
repositoryaccessibleasdiscussedabovewouldincreaseusagebecausethe
feedbackwouldbeimmediateandthusmostusefultoteachersandstudents
(Black,2007;Hattie&Timperley,2007;Shute,2007).Delayinreceivingfeedback
wasidentifiedbyteachersinvolvedinthisprojectasadisincentivetogreater
engagementwiththeEVprogram.
Intheeventthatpublicaccountabilityisseenasimportant,considerationcouldbe
giventosampletestingalongthelinesofthecurrentNAPprogramforYear6
scienceorsimplycontinueusingthecurrentprogramofTIMSSandPISAtesting
whichAustralianstudentshavebeendoingforthepasttwodecadesalready.Using
onlytheinternationaltestswouldavoidduplicationandfreeupresourcesfor
otherpurposes.
6.7Conclusion
Section2.2ofthisthesisoutlinedthegapbetweenidealandactualpracticefound
byGoodrumetal.(2001)intheirreviewofscienceteachingandlearningin
Australiaattheendofthe20thcentury.Thethreeresearchersintheirreportdrew
attentionthentothestrongemphasis,particularlyinsecondaryschools,on
summativeassessmentandthenegativeimpacts(notjustinAustralia),itwas
havingonscienceteaching,onachievementandonengagementwithschool
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science(seeTable2.1).Thewritersrecommendedgreateralignmentbetween
syllabusintentions(outcomesthatfocusonscientificliteracy),instructionand
assessment.Assessment,theysaid,shouldbeusedmoretosupportinstructionas
itwashappening(formativeassessment).
Thisthesisreportsontheimpactoftwoinitiativesdesignedtohelpteachersshift
theirassessmentfocusfromsummativetoformative.Theinitiativeswerein
responsetothe2001reportbyGoodrumetal.Dataforthethesiswascollectedin
2016andcoveredschoolyears2010to2015.Thefirstinitiativewasintheformof
curriculumadviceforteachersaboutassessmentforlearning(analternativename
forformativeassessment).Itwaspromulgatedinthenewsciencesyllabuswhich
wasintroducedfrom2003(BOS,2003).Thesecondinitiativewasalargescale,
diagnosticsciencetestandstudentsurveyatthemidpointofamandatory,four-
yearsecondarysciencecourse.Thetestwaspilotedin2005,trialedin2006and
implementedacrossthestateofNSWforallYear8studentsfrom2007.Thetest
gatheredevidenceofstudentlearningrelativetosyllabusstandards(describedas
outcomes).Thesurveygatheredevidenceofstudentunderstandingaboutscience
intheworldandabouttheirexperienceofscienceintheschoolsetting.
Parents(andtheirstudents)receivedaprogressreportabouttheirlearningin
termsofbothsyllabusexpectationsandlevelofunderstandingdemonstratedin
relationtothoseexpectations.Thelevelswerereferencedtothesixlevelsof
understandingdescribedintheSOLOmodel.Teachersreceivedacomprehensive
analysisofindividualperformanceoneverytaskanditeminthetestaswellas
students’collectiveviewsaboutscienceandtheirexperienceofitatschool.
Teacherswereexpectedtousetheresultsofthetestandthesurveytodiagnose
strengths,weaknessandgapsinstudentlearning(andlevelofengagementwith
learningscience)andtorespondaccordingly.
ImpactofboththecurriculumadviceonassessmentforlearningandtheEV
programonteachers’assessment-relatedworkwasexploredagainstthefive
dimensionsofformativepracticedescribedinChapterTwo.Theevidencefrom
analysisoftheteachersurveyresponsesrevealedthatfifteenyearsafterthe
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Goodrumetal.(2001)report,instructionandassessmentweremorealignedto
curriculumexpectations(describedintermsofoutcomes)thanwasthesituation
in2000(firstdimensionofformativepractice).Thiswasaconsistentfeatureof
teachingacrossallthreegroupsofschools,regardlessofwhetherEVresultswere
wellabove(WAE),at(AE)orwellbelowexpectation(WBE).
However,inschoolswhereresultswereWAEandAE,theteacherstherewere
morefrequentusersofdiscourseelicitingevidenceoflearning(seconddimension
offormativepractice)andprovidersoffeedbackthatadvancedlearning(third
dimensionofformativepractice)thanweretheircolleaguesinschoolswhereEV
resultswereWBE.
Whenitcametoprovidingstudentsinthefirsttwoyearsofsecondaryschoolwith
opportunitiestotaketheleadasinstructorsforeachother,noneofthethree
schoolgroupsstoodoutfordoingso(fourthdimensionofformativepractice).
InschoolswhereresultswereWAE,teachersthereweremorefrequent
demonstratorsofgoodlearningbehavioursbothwithstudents(andwitheach
other)thanweretheircolleaguesineitherAEorWBEschools(fifthdimensionof
formativepractice).
InWAEschoolsteachersalsofocusedondevelopingstudents’capacitytousethe
languageofscientificliteracyappropriately.ThiswasmostevidentintheWAE/
AE–WBEcomparisonsofschoolswithcomparablesocio-educationaladvantage
(SEA)scores.Inthosecomparisons,WAE/AEschoolshadlargerproportionsof
theirstudentsinthetopbandfortheextendedresponsecategoryofresults
(PCWAE2andMCWBE5,MCAE2andMCWBE3andMGFSAE2andMGFSWBE1).
BecauseitwasnotpossibletoensurethecomparabilityofYear10resultsacross
schoolsnortobesurethattheproportionsofstudentsdoingseniorscience
courseswasadirectreflectionofstudentdemand(ratherthanschoolresource
limitations),threepredictionsdevelopedasindicatorsofstudentself-regulation
couldnotbereliablyverified.Theonlyotherindependentmeasureofself-
regulationavailabletothisproject(studentsreportinginthesurveyapositive
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schoolscienceexperienceattheendofYear8)wasnotconsistentlyfoundinhigh
achievingcasestudyschools.Infact,highachievementwasconsistentlylinkedto
lowratingsbystudentsoftheirschoolscienceexperience.Thiswasveryevidentin
thethreeprovincialcasestudyschools.
Thecombinationofteachersurveyresultsandassessmentnarrativessupportsthe
conclusionthatincasestudyschoolsatleast,teachersretainstrongcontrolover
theactivitiesassociatedwithformativepractices,atleastuptotheendofYear8.
Whilstthisisassociatedwithbetterthanexpectedscientificliteracyoutcomes,
studentsinprovincialschoolsinparticulardonotappeartobeenjoyingthe
experience.Thiswasincontrasttotwocoeducationalmetropolitancasestudy
schools,alsowithrelativelylowSEAscores(MCWAE1andMCWBE4)butwith
highratingsoftheirschoolscienceexperiences.
AttheendofYear10bothMCWBE5andPCWAE3havebetterresultprofilesthan
PCWAE2.AllthreeschoolshavecomparableSEAscores.Thisisareversalofthe
Year8position.Despitetheuncertaintyaroundthecomparabilityoftheactual
results,thedistributionoftheresultsacrossthegradesistelling.Itseemsthatthe
rigorousapplicationofasummativeassessmentpolicyatPCWAE2maybea
contributortothedeclineinachievementfromYear8toYear10.
Takingalltheaboveintoaccountitistheviewofthisresearcherthatprogressis
beingmadetowardhelpingstudentsacquirethetoolsneededtomanagetheirown
learning,asthefocusonmasteringthelanguageofsciencehasshown.However,
thebroadeningofthattoencompassthefullmeaningofbeingscientificallyliterate
(OECD,2017)willrequirethatstudentsareexplicitlytaughttheskillsofformative
assessmentandgivenopportunitiestousethematschool.Thiswillonlyhappen
whenthecommunityacceptsthevalidityandreliabilityofevidenceoflearning
obtainedbymeansotherthanpenandpapertests(ortheiron-lineequivalents).
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APPENDICES
AppendixA:Competencies,BasicSkills,GenericSkillsandKey
Competencies
Table 2.1 Competences, basic skills, generic skills and key competencies
SECTION ONE: Quality Education Review Committee (QERC,1985) general competences and basic skills
1. Acquiring information; 2. Conveying information; 3. Applying logical processes; 4. Performing practical tasks as individuals; 5. Performing practical tasks as members of a group (Recommendation1, p.201).
Basic skills in (the curriculum) including: • communication skills; • Mathematics; • Science; • Technology; • the world of work; and • Australian studies (Recommendation 10, p. 203)
SECTION TWO: Australian Education Council Review Committee (AECRC, 1992) Finn review generic skills
1. Language and communication; 2. Mathematics; 3. Scientific and technological understanding; 4. Cultural understanding; 5. Problem solving; and 6. Personal and interpersonal understanding.
SECTION THREE: Australian Education Council Review Committee (AECRC, 1992) Mayer key competencies (NSW version)
1. Collecting, analysing and organising information; 2. Communicating ideas and information; 3. Planning and organising activities; 4. Working with others and in teams; 5. Using mathematical ideas and techniques; 6. Solving problems; 7. Using technology; and 8. Cultural understanding*
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SECTION FOUR: Science 7-10 syllabus (BOS, 2003) Key Competencies are embedded within the objectives and content of the Skills. The content develops students’ ability to:
1. plan, organise and perform first-hand investigations to test a hypothesis or question that can be researched;
2. collect, analyse and organise information from first-hand investigations and secondary sources, organising data using a variety of methods including diagrams, tables and spreadsheets, and checking reliability of gathered data and information by making comparisons with observations or information from other sources;
3. communicate ideas and information using a range of text types including explanation, procedure and report formats to present data and information from first-hand investigations;
4. identify the nature of issues and problems, framing possible problem-solving strategies and developing creative solutions in a logical, coherent way;
5. use technology including CD-ROMs and the internet to access information 6. work individually and in teams where appropriate, safely, responsibly and effectively
with realistic timelines and goals; and 7. use appropriate mathematical processes including appropriate units, graphs,
spreadsheets and mathematical procedures and relationships. *This was a NSW addition to the list Source: report documents as listed in the Table (see reference list).
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AppendixB:GoalsforSchooling(1989–2008)
Evolution of Australia’s Common and Agreed National Goals for Schooling in the Twenty First Century.
Hobart Declaration on Schooling (1989). The ten goals… 1. To provide an excellent education for all young people, being one which develops their
talents and capacities to full potential, and is relevant to the social, cultural and economic needs of the nation.
2. To enable all students to achieve high standards of learning and to develop self-confidence, optimism, high self-esteem, respect for others and achievement of personal excellence.
3. To promote equality of education opportunities, and to provide for groups with special learning requirements.
4. To respond to the current and emerging economic and social needs of the nation, and to provide those skills which will allow students maximum flexibility and adaptability in their future employment and other aspects of life.
5. To provide a foundation for further education and training, in terms of knowledge and skills, respect for learning and positive attitudes for life-long education.
6. To develop in students: a) the skills of English literacy, including skills in listening, speaking, reading and writing; b) skills of numeracy, and other mathematical skills; c) skills of analysis and problem solving; d) skills of information processing and computing; e) an understanding of the role of science and technology in society, together with scientific and technological skills; f) a knowledge and appreciation of Australia’s historical and geographic context; g) a knowledge of languages other than English; h) an appreciation and understanding of, and confidence to participate in, the creative arts; i) an understanding of, and concern for, balanced development and the global environment; and j) a capacity to exercise judgement in matters of morality, ethics and social justice.
7. To develop knowledge, skills, attitudes and values which will enable students to participate as active and informed citizens in our democratic Australian society within an international context.
8. To provide students with an understanding and respect for our cultural heritage including the particular cultural background of Aboriginal and ethnic groups.
9. To provide for the physical development and personal health and fitness of students, and for the creative use of leisure time.
10. To provide appropriate career education and knowledge of the world of work, including an understanding of the nature and place of work in our society.
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Adelaide Declaration (released in 1998) The achievement of Australia’s common and agreed national goals for schooling establishes the pathway for lifelong learning, from the foundations established in the early years through to senior secondary education including vocational education and linking to employment and continuing education and training. Schooling should develop fully the talents and capacities of every student. In particular, when students leave school they should:
• have skills in analysis and problem solving and the ability to become confident and technologically competent members of 21st century society.
• have qualities of self-confidence, optimism, high self-esteem, and a commitment to personal excellence as a basis for their potential life roles as family, community and workforce members.
• be active and informed citizens with the ability to exercise judgement and responsibility in matters of morality, ethics and social justice; and the capacity to make sense of their world, to think about how things got to be the way they are, to make rational and informed decisions about their own lives and to collaborate with others.
• have a foundation for, and positive attitudes towards, vocational education and training, further education, employment and life-long learning.
In terms of curriculum, students should have: • attained high standards of knowledge, skills and understanding through a
comprehensive and balanced curriculum encompassing the agreed eight key learning areas: the arts; English; health and physical education; languages other than English; mathematics; science; studies of society and environment; technology and the interrelationships between them.
• attained the skills of numeracy and English literacy; in particular, every child leaving primary school should be numerate, able to read, write, spell and communicate at an appropriate level.
• been encouraged to be enterprising and to acquire those skills which will allow them maximum flexibility and adaptability in the future.
In addition, schooling should be socially just, and should ensure that: • outcomes for educationally disadvantaged students improve and match more closely
those of other students. • Aboriginal and Torres Strait Islander students have equitable access, participation and
outcomes. • all students have understanding of and respect for Aboriginal cultures and Torres Strait
Islander cultures to achieve reconciliation between indigenous and non-indigenous Australians.
• all students have the knowledge, cultural understandings and skills which respect individuals’ freedom to celebrate languages and cultures within a socially cohesive framework of shared values.
MCEETYA (2008) Melbourne Declaration (December 2008)
The Educational Goals for Young Australians Goal 1: Australian schooling promotes equity and excellence Goal 2: All young Australians become: – Successful learners – Confident and creative individuals – Active and informed citizens
Source: Hobart and Adelaide Declarations – MCEETYA, 1998 / Melbourne Declaration – MCEETYA, 2008. See reference list for full citations.
300
AppendixC:Ateachingsequenceexemplifyingdifferentviewsoflearning
Aviewoflearningthatclarifiescurriculumintention,guidesinstructionand
shapesassessment.
Thefollowingillustrateshowaviewoflearningandcognitioncanclarify
curriculumintention,guideinstructionandshapeassessment.The2003NSW
ScienceYears7-10syllabus(BOS,2003)requiresstudentstouseaparticlemodel
toexplainchangeofstate(outcome4.7.1,2&3:particlemodel,changeofstateon
p.32).Ateacherwhoisfamiliarandcomfortablewithacognitive,constructivist
viewofcognitionandlearningmighttakestudentsthroughateachingsequence
thatendswithanassessmenttask.
Thissequencemightinvolvestudentssettingupsituationsinvolvingwaterwhere
theycanobserveevaporation,boiling,meltingandfreezing.Inthatscenario,the
teachermovesaroundtheroomprovidingadviceandsupportasstudentswork
throughtheactivities.Thisisfollowedbyateacher-ledexplanationoftheparticle
modelandadiscussionofhowitcanbeusedtoexplaineachoftheexamplesthe
studentshadworkedwith.Studentsarethengivenapen-and-papertaskthathas
shortresponseitems,anextendedtaskofasimulatedexperimentinvolvingice
melting,andasetofquestionsaskingstudentstocreatelabelleddiagramsusing
particlestorepresentthechangefromicetowatertosteam.Whenmarked,the
teacherwouldleadadiscussionoftheresultswiththeclass.Thisdescriptionisa
truncatedversionofthe5Esapproach(AAS,2017),althoughtheoutlinegivenhere
isnotfromthe5Esmaterials.
A teacher who is familiar and comfortable with a situative view of learning might see an
opportunity to address two other syllabus (BOS, 2003) requirements at the same time as
teaching the particle model. Syllabus outcomes related to the nature and practice of
science (outcome 4/5.2a to evaluate the role of creativity … in describing phenomena
on p. 28) and working in teams (outcome 4/5.22.2 to practice aspects of team work
described in content items a to h on p. 44) are outcomes that lend themselves to
groupwork. The teaching sequence might involve a cooperative learning strategy, such
as the jigsaw technique (Mitchell et al., 2009, pp 75-76) to engage with all three
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outcomes. The assessment might involve a presentation by each member of the group
(individual or group role-playing water particles and moving in ways that simulate
evaporation, melting, boiling and freezing followed by a class Q & A led by
performers).
Team members could also be asked to complete a checklist identifying aspects of
teamwork for themselves (self-assessment) and other members of the team (peer-
assessment) in terms of their own contribution to the preparation and delivery of the
content in the presentation. The test could also be done by individuals. When
completed, the teacher would provide feedback to the group drawing on the evidence of
learning from her/his observations, a reading of the checklists, and the test results.
Assessment involves both pen-and-paper responses and observations of performance as
evidence of learning. Feedback can be given in terms of both the particle model of
matter and the processes involved in preparing and delivering the performance.
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AppendixD:FiveexamplesinvolvingaspectsoftheSOLOmodel
Exampleone-heatingice
Anexamplefromthe2005EVpilottestshowshowthetwo-learningcycleSOLO
modelwasappliedtocodeanextendedresponsetask.Thestudentswere
presentedwithadiagramofabeakercontainingice,athermometerandastirrer.
Thebeakerandcontentsweresittingonagauzematandretortstandwitha
Bunsenburnerunderitrunningalow,two-zoneflame(thisequipmentis
ubiquitousstillinNSWgovernmentschoolsciencelabs).Studentswerepresented
withatableofresults(Table2.6)showingtemperaturechangeovertime(from0
to9minutes)
Table 2.6 Table of results from heating ice
Time (in minutes) 0 1 2 3 4 5 6 7 8 9
Temperature (in ℃) 1 1 1 4 15 29 45 61 75 89
Source: ESSA 2005 test booklet, NSW Department of Education and Training
Studentswereasked:
(a) Usingtheinformationfromtheresulttable(Table2.6),describewhatwas
happeninginthefirstnineminutesoftheexperiment.
(b) Usingyourknowledgeoftheparticletheory,explainwhythishappens.
ForthefirstcycleanyONEofthefollowingwereacceptedasaU1response:change
ofstate/theicemelts/describesapartorallofthetrendchangesintemperature
overtimewithorwithoutspecificreferencetotimeintervals.AnM1response
involvedTWOormoreU1responsesbeingprovided.R1responseslinkedthetrend
changeintemperaturetoaninferredmeltingofalltheice.Notethatincycleone,
theresponsesmadenoreferencetoscienceconcepts.Responseswereintermsof
everydaylanguagerelatedtotherelevantobservations.
InthesecondcycleanyONEofthefollowingwereacceptedasU2responses:heat
increasesthemovementorvibrationofparticles/heatisabsorbedbyiceparticles
astheicemelts/heatenergybreaksdownforcesofattractionbetweenparticles
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Produced by the New South Wales Department of Education and Training • Copyright © 2008 New South Wales Department of Education and Training4
Jack and Rana were investigating the behaviour of magnets.They stood two test tubes in a test tube rack. Then they puttwo bar magnets inside each test tube. The results are shownin the photograph.
Describe what A and B show.
Use your knowledge of forces to explain the behaviour of the magnets in test tube B.
A B
Task 2 – Behaviour of magnets
304
SOLO Cycle 2 describes the interaction of magnetic poles and explains the interaction of magnetic and gravitational forces that produces the phenomenon in test tube B in the stimulus photograph
Code Description 8 non-attempt; the page for responding to the task is left blank 0 a response was made but it does not meet any of the marking criteria 1 the response contains a single piece of commonsense information relevant to the major
concept 2 the response contains two or more pieces of commonsense information relevant to the
major concept 3 the response contains a commonsense explanation about the major concept that relates two or more pieces of commonsense information 4 the response contains a single piece of ‘scientific’ information relevant to the major
concept that clearly reflects syllabus expectations or accepted science 5 the response contains two or more pieces of ‘scientific’ information relevant to the major
concept that clearly reflect syllabus expectations or accepted science 6 the response contains a clearly stated ‘scientific’ explanation about the major concept
that relates two or more pieces of information, which clearly reflect syllabus expectations or accepted science
Figure 2.9 Actual EV extended response task. Source: 2008 EV test Note: codes 1 to 6 correspond to U1-M1-R1 & U2-M2-R2 in Figure 2.6
TeacherswhoengagedwithtrainingformarkingtheEVextendedresponsetasks
andsubsequentmarkingreportedthatthetrainingandsubsequentmarkingwas
themostimportantsourceoftheirlearningabouttheSOLOmodel(seeChapter4).
ThetextundertheheadingsCodeandDescriptionprovidethecode(anumber)
andthegeneralcriteriaforassigningtherelatedcodeconsistentwiththe
qualitativedifferencesexpectedforcycle1andcycle2responses.
Theexpectationisthatstudentswillbecomescientificallyliterateasdescribedin
theofficialsciencecurriculum(syllabusinNSW).Partofthisincludesbeingableto
providescientificexplanationsforarangeofphenomenatheyobserveand
experienceinthenaturalandmadeworldsbytheendofYear10.Thisexpectation
includesbeingabletoidentifyandnametheconceptsthatlinksetsofseemingly
disparatearraysofphenomenaandusethoseconceptstoexplainobservations
relatedtothephenomena.
HerethequalityofthinkingiscapturedbylookingatSOLOlevelswithin
modes,belowthemodethatsciencedemandsasthatwhichprovidesa
satisfactoryexplanation.(Biggs&Collis,1991,pp.73-74)
305
Onceassessed,suitableremedialactioncanbetakentohelpthestudentshifttheir
levelofunderstandingtooneclosertothesyllabusversionofascientific
explanation.Theevaluativepurposesofthetest,thatis,providingfeedbacktothe
Department,areexplainednext.
Manystudentsaregoodtalkersabouttheworldtheyinhabitwhentheystart
schoolatage5andthelevelofthat‘talk’forsomewouldbeattheIkonic,R2level
orlower(seeFigure2.6).BytheendofYear8(age13-14yrs),thegraphsforthe
periodofinterest(Figure2.10)showthataround35%ofthestudentsare
operatingatthesecondcycle,unistructurallevel(U2)inscience.Thesecondcycle
iswherewewouldexpectYears7and8secondarystudentstobeworking;overall,
approximately60%are.Lessthan5%ofstudentsareoperatingatthetopendof
thesecondcycle(relationallevelR2).Thisisthelevelwewouldhopemany,ifnot
most,Year12(16-17years)wouldbeoperating.ThislowR2resultisinlinewith
expectationsgiventheageofYear8students.Nevertheless,itshouldbeagoalfor
teacherstoaimatassuggestedinthecommentaryunderthegraphsinFigure2.10.
The2011to2014resultsrepresentedinthefourcolouredgraphsinFigure2.10
arestandardsreferencedtoanassessmentframeworkputinplacein2011.Given
this,itwouldhavebeenunsurprisingtoseethegraphsshowingaprogressive
skewtotherightwitheachsuccessiveyear.Theskewwouldshowthatteachers
wereworkingsuccessfullytoimprovestudentlevelsofthinking,asevidencedby
successivelymoreofthemappearingatthemultistructural(M2)levelatthevery
least.Thereissomevisualevidenceofashifttotherightfrom2011to2013,butit
isnotevidentfromthe2014data.WithoutknowingtheSEforthedatapoints,itis
impossibletocommentonwhetherthatisarealeffectornot.Myresearchfindings
(reportedinChapter5)providesupportfortheviewthattheshiftisnot‘real’.
TheuseofSOLOlevelstoinformthereportingofachievementattheendofYear8
istheenhancementtoEVfeedbackreferredtoinChapter1.Parentsareprovided
withrepresentationsofthinking(criterionreferencedassessment)relatedtoeach
ofthesixlevelsintheSOLOmodel(seeFigure2.6).
306
Figure2.10showstheproportionofYear8studentsateachSOLOlevelforthefour
yearsofinterestinthisproject.ThelastyearfortheESSAtestwas2014.Itbecame
theVALIDtestfrom2015.
Comparison graphs The following graphs compare the performance of students in ESSAonline from 2011 to 2014 tests for Science (overall for the test). Comparison of percentage achievement in levels for Science (overall for the test)
Whilst the pattern in the trend lines is similar across the four years, the positive aspects of the data are that the majority of students are achieving levels 4 to 6 and the very low percentage of students achieving levels 1 and 2. Achievement in Level 4 indicates use of syllabus knowledge, understanding and skills in familiar and unfamiliar situations. These students should be encouraged to deepen and interrelate their learning, as Level 5 describes deep knowledge of concepts in Stage 4 whereas Level 6 describes students with a breadth and depth of integrated knowledge, understanding and skills that can be applied meaningfully to a wide variety of real-world problems. Achievement in Levels 1 to 3 suggests that many students are often not thinking beyond the commonsense or are not confident in applying scientific knowledge, understanding and skills in everyday and/or unfamiliar contexts. Students achieving in Level 3, who are able to logically explain ideas, need particular encouragement to apply science, rather than commonsense knowledge, understandings and skills, to describe and explain the world around them.
Figure 2.10 Statewide performance data and related commentary for the ESSA test 2011-2014 (Source: DEC, Essential Secondary Science Assessment 2014 state report.)
Examplethree-mappingsyllabusoutcomestotheSOLOmodel
307
Table 2.7 Selected outcomes and related SOLO levels in the 2011 EV assessment framework LEVEL 1 LEVEL 2 LEVEL 3 LEVEL 4 LEVEL 5 LEVEL 6
Out
com
es 4
.1 to
4.5
(2 o
f 7 ro
ws)
Identify a scientific discovery
Compare scientific discovery to other types of discovery
Link a scientific discovery to its effect on humans
Describe a development in science that has led to new developments in technology
Compare the methods of the scientist to the design model of the engineer and architect
Explain the role of scientific thinking on society
Identify a possible career path in science
Identify a science context in a career
Link a career in science to knowledge and skills required
Identify science as a human activity
Discuss why society should support scientific research
Out
com
es 4
.6 to
4.9
(3 o
f 16
row
s)
Identify materials attracted by a magnet
Compare the observable effects when magnets are placed end to end
Link the observable effects when two magnets are placed end to end with their position
Describe a magnetic field as producing a force that attracts particular metals
Describe the poles of a magnet as the area/ends where the magnet’s field is most intense
Explain the behaviour of magnetic poles using the term field
Identify that objects / substances take up space and/or have mass/weight
Explain that materials are held together differently in solids, liquids and gases
Explain density in terms of a simple particle model
Identify an observable feature in melting, freezing, condensation, evaporation or boiling
Describe observable features in melting, freezing, condensation, evaporation and boiling
Explain that, when substances melt, freeze, condense, evaporate and boil, they are still made of the same stuff
Identify that particles are continuously moving and interacting
Compare movement and interaction of particles in different states
Explain change of state in terms of rearrangements of particles
Identify that as particles are heated they gain energy
Identify that as particles are heated they gain energy and move
Relate changes of state to the motion of particles as energy is removed or added
308
further apart
No content for Outcomes 10 - 12 is included Outcomes 4.13 to 4.15* (1 of 8 rows)
Make a simple observation
Compare observations made by different people
Explain strategies to increase accuracy of observation
Correctly sequence steps in a scientific procedure
Accurately and systematically record observations and data
Discuss the relationship between accuracy and reliability
Outcomes 4.16, 4.17 a-d & 4.18** (1 of 8 rows)
Use a simple key or symbol to represent a concrete object or representation
Distinguish between different symbols
Complete diagrams and symbolic representations
Correctly sequence steps in a process described in a text
Distinguish between two related sets of data / information
Represent relationships using keys, symbols and flow chart
Outcomes 4.17e-g, 4.19-4.21*** (1 of 7 rows)
Identify a common unit of measurement
Identify the ratio of one unit to another
Complete a correct conversion of one unit to another
Create a simple scale
Compare the scale on two axes
Create an appropriate scale
Source: NSW Department of Education and Training DET, 2011. Shaded rows are referenced in the body text. * Planning and Conducting Investigations area / ** Communication area / and *** Critical thinking area
Table2.7andfollowingtextexplainsthemapofsyllabusoutcomesandSOLO
modellevels1to6.
Whilethetestwasdeliveredasapenandpaperexercise(from2005to2010),the
assessmentframeworkdiscussedinthissubsectionwasbeingdevelopedand
validated.
Table2.7showsanextractoftheframework.Itshowshowthesyllabusoutcomes
(writtenandpublishedforthe2003sciencesyllabus)weresubsequentlyrelated
tothesixlevelsoftheconcretesymbolicmodeofthinkingintheSOLOmodel.
Themeltingicetaskaboveandasecondtaskinvolvingmagnetsdescribedin
subsection2.6.4werepartsoftestsdonebefore2010.Boththesetasks
subsequentlymappedtotheEVframeworkproducedforthe2011–2014tests(see
theshadedsectionsacrosstheextractfromtheEVframeworkinTable2.7).Anew
frameworkwasusedtoinformtestdevelopmentfortheVALIDteststhatbegan
309
from2015.ThiswasbasedonthenewAustralianCurriculumScience(NSW
version).ThequalitycontrolprocessesusedtodevelopitemsandtasksforEV
testsarediscussedinsubsection2.6.4.
Since2011,theEVtestshavebeendeliveredonlinetoschoolcomputerslinkedto
schoolnetworksandtheinternet.Theaffordancesprovidedbyonlinedeliverywill
notbeaddressedinthisthesis.
TheEVframeworkforthe2011to2014EVtestwasorganisedasagrid(Table
2.7).Thecolumnsidentifythethesixperformancelevels(LEVELS1to6)related
tothe“twolearningcycleswithinamode”SOLOmodel.Thefiverows
accommodate21ofthe22syllabusoutcomesdefiningStage4(Years7&8)(DET,
2011).
Theperformancelevels(Table2.7)correspondtothethreelevelsofthinkingin
eachofthetwolearningcyclesintheconcretesymbolicmodeofthinking(see
Figure2.6).LEVEL1=firstcycleU1,LEVEL2=firstcycleM1,LEVEL3=firstcycle
R1,LEVEL4=secondcycleU2,LEVEL5=secondcycleM2,andLEVEL6=second
cycleR2.
ThedescriptorsineachofthegridcellswereidentifiedasappropriateforStage4
learnersbyexperiencedscienceteachersandSOLOexperts(asexplainedinthe
subsection2.6.4).Thewordingusedwasbasedonacombinationoftheir
professionaljudgmentandtheoutputsfromsophisticatedpsychometricanalysis
usingresultsfromtriallingandpilotingandthefirstfewyearsoffullcohort
testing.
Theoutcomesarenumberedintheleft-handcolumn.Thefirstdigitreferstothe
ScienceSyllabusStage,whichinthiscaseisStage4(forstudentstoachievebythe
endofYear8).Thesecondnumberidentifiestheoutcome(from1to21)The
letterscorrespondtocontentrelatedactions(indicatorsofoutcomeattainment)
linkedtoessentialsyllabuscontent(thatstudentswilllearnabout)thatdefinesthe
scopeoftheoutcome.
The21outcomesabletobeassessedbythismodeoftesting(penandpaper)are
groupedonthefullEVassessmentframeworktoreflectgroupsofoutcomes
definedhereassyllabusareas:
310
• Prescribedfocusarea(Outcomes4.1-4.5)
• Knowledgeandunderstandingarea(Outcomes4.6-4.12)
• Planningandconductinginvestigationsarea(Outcomes4.13,4.14&4.15)
• Communicationarea(Outcomes4.16,4.17a-dand4.18)
• Criticalthinkingarea(Outcomes4.17e-g,4.19,4.20&4.21)(DEC,2015,p.18).
Thefirsttwobullet-pointareasarebothknowledgeandunderstandingoutcomes;
theremainingthreearerelatedtoscienceskillsandprocesses.Noteverycellof
everyrowhasacontentdescriptionbecausethesyllabusissilentaboutrelevant
contentatthatSOLOlevel.Thisistobeexpectedbecausethesyllabuswas
publishedin2003;thesixlevelswereidentifiedwithintheexistingsyllabus
contentand‘levelled’usingSOLOexpectationsin2010.
Abouthalfoftheoutcomesareaboutknowledgeandunderstanding(1to12);the
otherhalfarescienceprocess/skilloutcomes(13to22).Theintendedmessageis
thatjuniorsecondaryscienceisasmuchaboutscienceknowledgeand
understandingasitisabout‘doingscience’.Thus,thefullgridprovidesaneasy
waytomaptheitemsforaparticulartestagainstsyllabusexpectationsandall
SOLOlevelsofthinking.
TheCriticalThinkinggroupingofoutcomesintheEVframework(seethebottom
rowofTable2.7)isanattemptbythetestdeveloperstosignaltoteachersthat
havingstudentsengagecriticallywithscienceandscience-relatedissuesisan
importantexpectation.InthefullversionoftheEVframework,thereareseven
rowsofcontentdescriptorsforthisarea.Theonechosenhereisabout
measurement;othersrelatetoaprogressioninthinkingtodowithmathematical
relationshipsbetweenvariables,dataanalysis,evidence-basedconclusions,critical
analysisofscientificexplanations,predictionsandinferences(basedonscientific
evidence),andrecognisingaspectsofaproblemthatmayberesolvedusing
science.
Measurementisanimportantcomponentofthe‘epistemic’basisofscience.The
meaningof‘epistemic’andexamplesofitemsandtasksrelatedtoitareexplained
inthePISA2015frameworksdocument(OECD,2017,pp.29-38).ThesixSOLO
levelsrelatedtomeasurementintheCriticalThinkinginTable2.7beginwith
311
specificcontextsformeasurementsandthemmovetorelationshipsbetween
aspectsofthesameanddifferentmeasurements(SOLOcycleone).FromLEVEL4
theexpectationprogressestodevelopingamoregeneralisedunderstandingof
measurementscales(SOLOcycletwo).Theprogressionhasthepowertoguide
teachingandassessmentalignedtosyllabusintentions.
Thecelldescriptorsalongeachrowprovideguidancetoateacheraboutwhat
contentistobelearnedandthecomplexityofthinkingstudentsareexpectedto
manageastheyworkthroughthetwoyearsofStage4inscience.Anexample
describingapossibleprogressioninlearningaboutunitsofmeasurement(ina
particularcontext)anditsextensiontomeasurementscalesgenerallywillnowbe
described.
Outcome4.7abouttheparticlemodelofmatter(4.7.1)andmeltingiceasa
particularexampleofchangeofstate(4.7.3)arethecontextsforthislearning
sequence.Theendresultofusingdifferentthermometers(glass-alcoholand
digital)withdifferentscales(Kelvin,CelsiusandFahrenheit)istovalidatean
operationaldefinitionforlatentheatofmeltingforonesubstance,water.The
observationthatthetemperatureofanice-watermixturestaysthesameuntilall
theicemeltsisexplainedbytheideathataddedheatisbeingusedto‘overcome’
whateveritisholdingthewaterparticlestogethertomakeiceratherthan
increasingthetemperatureoftheice-watermixture).
Theinitialemphasishereistoensureaccurateandreliablemeasuringofthe
temperatureasicemelts.Theclassdiscussionbeforeworkingingroups(each
usingadifferentthermometerwithadifferentscale)wouldbetodiscussthethree
temperaturescales(Kelvin,CelsiusandFahrenheit).Whythethreescales?Which
onetouse/orallofthem?Why?Whatistheratioofonescaledivisionrelativeto
theotheracrossthethreescales?Howdoweconvertfromonetotheother?Why
mightthisbeausefulconversiontobeabletodo?Aworksheetcouldbedeveloped
forusebymembersofthegroupworkingtogethertodiscussandanswerthe
questionsposedthere.
Oncethetaskiscompleted,eachgroupmembertakestheresultsand
independentlyanswersanothersetofquestions(suchastheonesinthe2005test
312
andothersrelatingtoscaleconversionsanddrawingagraphofonescaleverses
anothertointerpolatewithinandextrapolatebeyond)providedonanothersheet.
Afinalquestiontoanswermightbe:Howwouldyourecalibrateathermometer
wherethescalehadbeenrubbedout?
Thechallengeto‘calibrateathermometerwithnoscale’addressestheBOS
CommonGradeDescriptorcriteriaforanA:“Canapplytheseskillstonew
situations”(BOS,2013).ThetasksabovealsoaddressthreeMayerKey
Competenciesrelatingtosolvingaproblem,usingmathematicalideasand
techniquesaswellasusingtechnology(inthissituation,analoguethermometers
withthreedifferentscalesanddigitaltechnologyintheformofdigitaltemperature
probeslinkedtodataloggersorcomputers).TheMayerKeyCompetencieswere
integratedintothesyllabusatthetimeitwaswritten(AECRC,1992).
Examplefour-reportingachievementattheendofYear8
TheresultsfromtheEVtestareorganisedintoasummativereportofachievement
attheendofYear8.Thereportforstudents,parentsandteachersprovidesthe
resultsforfiveareasorcategoriesofoutcomes.ThescoresfromitemsintheEV
frameworkmappedtotheCriticalThinkingareaaredistributedtotheworking
scientificallyandcommunicatingscientificallycategories,dependingonwhether
theitemshadaninvestigatingorcommunicatingcontext.Thestudentreport
providesindividualfeedbackoneverytaskanditeminthetest.
Individualresponsesarealsoaggregatedtoprovideascoreandpositiononascale
from1to6relatedtothesixSOLOlevelsasshowninFigure2.7.Fivescalesare
providedshowinganoverallscoreforscience,ascoreforthethreeextended
responsetasksandthreeseparatescalesforknowledgeandunderstanding,
communicatingscientificallyandworkingscientifically.Providingfeedbackonfive
categoriesofscienceachievementismoreusefulandrespectfulofachievementby
anindividualthanasingleindicatorofoverallachievement,suchasagradeor
mark.Itisalsodiagnosticinthesensethatanassessmentofstrengthsand
weaknessesinparticularareasofsciencecanbeeasilyseen.
313
Figure 2.7 A sample reporting scale (Source: DET, 2007)
Thestudent’sscore(representedasathicklineonthescale)anditsplacementon
thescaleisdeterminedbyacombinationoffactorsgoingbacktothedevelopment
ofitemsandtasksforinclusioninthetestandthedependability(Harlen,2004)of
theprocessesusedthenandsubsequentlytoproducethescoresandprintits
representationontheproficiencyscale.Thequalitycontrolprocessestodothat
willbediscussedbelow.
Table2.8providesanextractfromtheEVstudentreportforreference.TIMSS,
PISAandNAP-SLalsohavecomparablesetsofdescriptorsforeachofthe
proficiencylevelsrelatedtotheirassessmentframeworks.
Essential Secondary Science AssessmentStudent report for parents 2006 Year 8This report shows the results for: Natalia Allenby
Local High School
What is ESSA?Essential Secondary Science Assessment (ESSA) is a statewide program that complements the school-basedassessment and reporting programs of NSW schools.The ESSA test assesses what Year 8 students know and can doin science; then students, parents and teachers can use the ESSA levels (see the table inside this report) toplan learning programs and activities so that students keep moving forward in their science knowledge andskills.This report provides results from the pilot test that was held on Tuesday 28 November 2006 for approximately58 000 students.
What was tested?The test assessed a variety of Stage 4 outcomes from the Science Years 7-10 Syllabus.
Science:Overall, a broad range of knowledge and skills in science were assessed using three extended response tasks and 75short response and multiple choice tasks.Extended response tasks are writing tasks that provided opportunities for students to demonstrate their integratedunderstandings and skills from various areas of the syllabus.Short response and multiple choice tasks assessed syllabus outcomes that were organised into three interrelatedstrands:
Knowing and understanding:Students responded to items thatspecifically assessed their knowledge andunderstanding of scientific concepts. Someitems tested Prescribed Focus Areas, such asthe nature and practice of science and theimpact of science on society, technology andthe environment.
Communicating scientifically:Students analysed and responded to avariety of texts that are typical ofthose used in Year 7 and Year 8science. Some items required criticalthinking.
Working scientifically:Students had opportunities todemonstrate skills incritical thinking, makingevidence-based conclusionsand in planning, conductingand analysing investigations.
How to read this reportResults are shown on five reporting scales. Each reporting scale has six achievement levels, from Level 1 toLevel 6. These levels are based on the requirements of the NSW Science Years 7-10 Syllabus. They represent astandard of what students know and can do in science. The levels in each strand are described in the tableinside this report.
Each level represents a standardof achievement in science.
An individual's resultis shown by
LEVEL 1 LEVEL 2 LEVEL 3 LEVEL 4 LEVEL 5 LEVEL 6
S A M P L Elower scores higher scores
314
Table 2.8 Extract from student report showing selected levels for three reporting categories
Ý Knowledge & understanding
Communicating scientifically
Working scientifically
Leve
l 6
• Explains physical phenomena using a model, theory or law
• Explains the interaction of complex systems (for example, relates the role of the circulatory system to the needs of cells)
• Explains the theme and function of a complex text
• Critically analyses the credibility of scientific information
• Relates the dependent and independent variables for a given problem
• Describes the wider significance of conclusions (for example, accounts for the differing amounts of water loss by plant cuttings by identifying plant processes)
Le
vel 5
• Describes examples where scientific understanding has changed
• Describes interactions of systems or within systems
• Extracts related information from diagrams, tables, graphs or other texts
• Compares two sets of information (for example, compares a table and graph and inserts information into the graph)
• Identifies ways to improve the reliability and accuracy of controlled investigations
• Applies mathematical models to data (for example, interpolates information from a line graph)
Le
vel 4
• Identifies scientific evidence (for example, identifies evidence that leads to change in a scientific theory)
• Describes a complex process of our world or space (for example, identifies requirements for photosynthesis)
• Identifies an interaction of systems or withina system (for example, identifies evidence that indicates that a chemical reaction has occurred)
• Identifies one piece of relevant scientific information
• Describes an effective solution to a problem with a science context
• Identifies a prediction, inference, conclusion, aim and hypothesis
• Selects one piece of appropriate scientific equipment for a task (for example, identifies a benefit of using a data logger to collect information in an investigation)
• Draws a conclusion based on scientific evidence
Le
vel 3
• Explains a link between technology and science
• Relates simple processes of our world or space (for example, identifies insects as consumers)
• Relates a model to an aspect of our world or space (for example, identifies kinetic energy acting in an activity)
• References information within a diagram, table, graph or other text (for example, summarises ideas across a text)
• Uses cause and effect to explain an observation (for example, identifies the effect of a change during a process)
• Relates equipment and appropriate use for a simple task (for example, identifies the correct use of a thermometer)
• Draws a simple conclusion
Ý Source: DET, 2007, p. 3. The lower arrow represents the transition from the R1 level of the first cycle in the concrete symbolic mode of thinking; the higher arrow represents the transition to the U1 level of the next (formal) mode of thinking.
TheformativeintentoftheEVprogramissignalledinthereporttoparentsand
students:
Students,parentsandteacherscanusethe[EV]levels[Table2.8]to plan
learningprogramsandactivitiessothatstudentskeepmovingforwardin
theirscienceknowledgeand skills.(DET,2007,p.3)
315
ThelevelsreferredtoarethesixlevelslinkedtotheSOLOmodeldiscussedabove.
Progress(“movingforward”intheEVreport)insciencelearningisdefinedbythe
languageusedineachoftheleveldescriptionsforaparticularreportingcategory.
Thefeedbackfromthetestandstudentsurveyisprovidedtoschoolsandschool
systemsparticipatinginthetestsomesixmonthsafterthetestsaredone,andwell
intoanewschoolyearwhenstudentshavecommencedthenextstageoflearning
(syllabusstage5earlyinYear9).Becausethefeedbackisnotimmediate,the
resultsarehelpfultoteacherswhenevaluatingtheirprogramsandmaking
changesforthenextcohortofstudentsasdiscussedinChapter5.
BecausetheprimarypurposeoftheEVtestistoprovidefeedbacktostudents,
parents,teachers,schoolsandschoolsystemsaboutprogressinstudentlearning,
theaimistohaveasmanystudentsfinishthetestaspossible.Thetest
administrationprocessismanagedattheschoollevelbyteachers,andschools
haveoneweekinwhichtocompletetheexercise.Toensurethatstudentsareable
tocompletethetest,timeallocationsforthesectionsofthetestarelistedas
approximateonly.Eightminutesisadvisedforthepreliminary,practiceitems;20
minutesforthethreeextendedresponseitems;anhourfortheshortresponse
itemsets;and,aboutfiveminutesforthestudentsurvey.
Inkeepingwiththepurposeofprovidingfeedbacktoindividuals,studentsdothe
testindividuallyastheywouldanyothertest.Thereisnocompetitiveadvantageto
behadby‘cheating’becausetheresultsprovideindividualfeedbackabouttheir
learningrelativetothesyllabusandSOLOlevels,nothowwelltheyaredoing
relativetootherstudents.
Examplefive-EVtestitems,stimulusmaterialandstudentsurvey
Schoolsareencouragedtokeepandreusethetestitemsandtasksintheirown
school-basedassessmentsbecausetheyareexemplaryassessmentitems.Teachers
haveaccesstoallthetestsfrompreviousyearsandrelatedstimulusmaterialas
wellastheassessmentrubricsusedtomarkthethreeextendedresponseitemsin
thoseyears.
316
ThethreeextendedresponseitemsintheEVtestwereplacedimmediatelyafter
thepreliminarypracticeitemswhenthetestwasinprintform.Experiencewith
externaltestsatthattime,whereextendedresponsequestionswereattheendof
thetest,showedthatmanystudentssimplyignoredthosequestions.Placementat
thebeginningofthetestobtainedanalmost100%response.Ofthethreeextended
responsetasks,oneinvolvedaninvestigationscenario;theothertwoprimarily
addressedsyllabusknowledgeandunderstandingexpectations.
Extendedresponsetasksareopenendedsothatstudentscanrespondatthe
highestlevelofunderstandingtheyarecapableofdemonstrating.(seeexamples
oneandtwoabove).Therelevantsyllabusreferencesrelatedtothesetwotasks
arehighlightedinthesectionoftheEVframeworkprovidedasTable2.7
Shortresponseitemsarewrittentoidentifynotonlyastudent’sknowledgeand
understandingbutalsotheirabilitytocomprehendatorabovethelowesttargeted
SOLOlevelofthinking(asreflectedinthewordingoftheitem).Itemsarelinkedto
apieceofstimulusmaterialrichinsciencecontentfromthesyllabusforthatstage
oflearning.Thetextprovidedischosenfromtherangeofexperiencesan
adolescentlearnerislikelytohavehadortoknowabout.Itmightbeanextract
fromanewspaperormagazineoranadvertisementorarecountofaTVnews
item,forexample.FromthreetoeightitemstargetingarangeofSOLOlevelsmight
berelatedtoanyonepieceofstimulusmaterial.
Itemsandtasks‘lookandfeel’tostudentslikeitemsandtasksinotherexternal
teststheydoeachyearforNAPLAN.Atestwouldhavearound75to85short
responseitems.Notalltheknowledgeandunderstandingsneededtosatisfyitem
demandsareprovidedinthestimulusmaterial.Studentsareexpectedtouse
knowledgeandunderstandingfromthesyllabustorespondappropriately.
Studentsareexpectedtorespondbychoosingonefromthreetofivealternatives
(toidentifythebestanswer)ortowriteafewwordsortheresultofacalculation
ontheanswersheetprovided.Distractorsarechosen,wherepossible,toidentify
misconceptionsstudentsmayhave(seeFigure2.8,Item14).
317
ESSA 2014 TEST Stimulus material and related items 9 to 16
Figure 2.8 One of the stimulus-item sets from the 2014 EV test. Source: NSW Department of Education, ESSA 2014 Test item.
Read the following article then complete items 9 to 16.
Why use a pool cover?
A pool cover is a great investment. Over a whole year, a pool can lose up to 5 mm of water each day. By using a pool cover, the water loss is reduced by about 95%.
Pool covers also extend the swimming season by increasing the pool’s water temperature by up to 8ºC.
A well-fitted pool cover keeps dirt, leaves and insects out of the pool. This also helps the cleaning equipment to keep the water suitable for swimming.
ESSA 2014 © 2014 NSW Department of Education and Communities page 6
9 Choose yes or no for each reason to answer the following question:
According to the article, what are the reasons that a pool cover is a great investment?
Yes No
prevents water loss
saves energy
keeps the pool cleaner
extends use of the pool
10 Using a net to remove leaves and insects from a pool is an example of
chromatography
filtration
sedimentation
11 Swimming pools would lose most water during
cool and cloudy days
cool and windy days
warm and cloudy nights
warm and windy days
12 On a hot day, the water on the surface of a pool would most likely undergo
a physical change
a chemical change
no change
13 Gaseous water is less dense than liquid water because particles in gaseous water are
closer together
further apart
smaller in size
larger in size
14 On hot days, water particles in the pool collide into each other more often because the water particles
have more energy
have less energy
get larger as the pool warms up
are made as the pool warms up
15 What is one environmental impact of covering a pool?
Australia would have fewer droughts.
There would be more water in dams.
People could swim for more months in the year. Swimming pools would stay clean and leaf-free.
16 Pure water has the chemical formula H2O.
What type of chemical substance is pure water?
compound
element
mixture
ESSA 2014 © 2014 NSW Department of Education and Communities page 7
9 Choose yes or no for each reason to answer the following question:
According to the article, what are the reasons that a pool cover is a great investment?
Yes No
prevents water loss
saves energy
keeps the pool cleaner
extends use of the pool
10 Using a net to remove leaves and insects from a pool is an example of
chromatography
filtration
sedimentation
11 Swimming pools would lose most water during
cool and cloudy days
cool and windy days
warm and cloudy nights
warm and windy days
12 On a hot day, the water on the surface of a pool would most likely undergo
a physical change
a chemical change
no change
13 Gaseous water is less dense than liquid water because particles in gaseous water are
closer together
further apart
smaller in size
larger in size
14 On hot days, water particles in the pool collide into each other more often because the water particles
have more energy
have less energy
get larger as the pool warms up
are made as the pool warms up
15 What is one environmental impact of covering a pool?
Australia would have fewer droughts.
There would be more water in dams.
People could swim for more months in the year. Swimming pools would stay clean and leaf-free.
16 Pure water has the chemical formula H2O.
What type of chemical substance is pure water?
compound
element
mixture
ESSA 2014 © 2014 NSW Department of Education and Communities page 7
318
Figure2.9(inexample2above)providesataskfromthe2008EVtestandthe
descriptorsforapplyingacodetostudentresponsesintheonlinemarkingprocess.
Afeatureofthecodingprocessisthatmarkersareaskedtocodeforthehighest
levelofresponseevidencedinananswer.Thetextinthesectionunderthetaskin
Figure2.9outlinesexpectationsforresponses.Forcycle1thelanguageusedis
sourcedfromtheexpectedlearningrelatedtomagnetsandforcesintheK-6
ScienceandTechnologysyllabus.Cycle2responselanguageissourcedfromthe
Science7-10syllabusinusebyschoolsatthetime(BOS,2003).
Someofthestudentsurveyquestionsspecificallyaddressissuestodowiththe
test,asexemplifiedbytheextractfromthestudentsurvey(seeFigure2.11).
ESSA 2014 student survey We would like to know what you think about this science test and about science. This survey is not a test and there are no right or wrong answers. Your responses will be kept confidential so please answer as honestly as you can.
Complete this survey about science I am interested in science.
I know about many careers that are based on science.
I want to study a science subject in Years 11 and 12.
Our knowledge about science is constantly changing.
Science helps me to make decisions about things in my life.
Science impacts on many aspects of my everyday life.
Protecting the environment for the future is my responsibility.
Science provides information about today’s important issues.
Science helps me to understand the world around me.
Complete this survey about the test and science lessons The test was about what I learn in science class.
The test was easier than I expected.
I enjoyed doing the test.
Literacy is important in learning science.
It is important that all students learn science in Years 7 to 10.
Science is the hardest subject that I learn.
In primary school, I enjoyed lessons that were about science.
In secondary school, I enjoy science lessons.
ESSA 2014 © 2014 NSW Department of Education and Communities page 30
319
Figure 2.11 Questions about the EV test. Source: NSW Department of Education and Communities, ESSA Test, 2014.
Studentresponsesareusedasfeedbacktorefineandimprovethetestandthetest
experienceforstudentsgoingforward.Schoolsalsoreceivethefeedbackfrom
studentsattheirschoolandtheirresponsescanbecomparedtotherestofthe
state.
Which part of the test did you like best? Choose one.
Dissolving tablets Expanding joints I think I can! What does your heart do? Nicolaus Copernicus Have you had your milk today? Burn for you Kata Tjuta Why use a pool cover? Wind turbines produce water Spray-on skin cells Earth’s cosy blanket Popcorn bounce! Coal
Bungeeeeeeeee!
Why did you like this part? Choose one reason.
It was interesting.
It was easy to understand.
It was about a familiar topic.
The test items were easy.
I liked the pictures in this part.
I learnt something new.
Complete this survey about your school subjects
My three favourite school subjects are
Aboriginal Education History
Agriculture Language studies
Dance Mathematics
Design and technology subjects Music
Drama PDHPE
English Science
Geography Visual arts subjects
Any other subjects
The three school subjects I think I learn most in are
Aboriginal Education History
Agriculture Language studies
Dance Mathematics
Design and technology subjects Music
Drama PDHPE
English Science
Geography Visual arts subjects
Any other subjects
ESSA 2014 © 2014 NSW Department of Education and Communities page 31
Which part of the test did you like best? Choose one.
Dissolving tablets Expanding joints I think I can! What does your heart do? Nicolaus Copernicus Have you had your milk today? Burn for you Kata Tjuta Why use a pool cover? Wind turbines produce water Spray-on skin cells Earth’s cosy blanket Popcorn bounce! Coal
Bungeeeeeeeee!
Why did you like this part? Choose one reason.
It was interesting.
It was easy to understand.
It was about a familiar topic.
The test items were easy.
I liked the pictures in this part.
I learnt something new.
Complete this survey about your school subjects
My three favourite school subjects are
Aboriginal Education History
Agriculture Language studies
Dance Mathematics
Design and technology subjects Music
Drama PDHPE
English Science
Geography Visual arts subjects
Any other subjects
The three school subjects I think I learn most in are
Aboriginal Education History
Agriculture Language studies
Dance Mathematics
Design and technology subjects Music
Drama PDHPE
English Science
Geography Visual arts subjects
Any other subjects
ESSA 2014 © 2014 NSW Department of Education and Communities page 31
320
AppendixE:Proformaforcasestudyschoolstocomplete
SCHOOL:DATE:
YEAR 8 ESSA-VALID STUDENT SURVEY DATA…Please obtain this from SMART
2011 2011 2012 2012 2013 2013 2014 2014 2015 2015LEVEL School State School State School State School State School State
5-6
A. I want to study a science subject in Years 11 &12
3-4
1-2
2011 2011 2012 2012 2013 2013 2014 2014 2015 2015LEVEL School State School State School State School State School State
5-6
B. Science is the hardest subject that I learn 3-4
1-2
2011 2011 2012 2012 2013 2013 2014 2014 2015 2015LEVEL School State School State School State School State School State
5-6
C. In primary school, I enjoyed lessons that were about science 3-4
1-2
2011 2011 2012 2012 2013 2013 2014 2014 2015 2015LEVEL School State School State School State School State School State
5-6
D. In secondary school, I enjoy science lessons 3-4
1-2
2011 2011 2012 2012 2013 2013 2014 2014 2015 2015LEVEL School State School State School State School State School State
5-6
E. My three favourite school subjects are (record the % for science) 3-4
1-2
2011 2011 2012 2012 2013 2013 2014 2014 2015 2015LEVEL School State School State School State School State School State
5-6
F. The three subjecs I think I learn most in (record the % for science)
3-4
1-2
Forthispage,fillintheboxesbyestimatingthescalereadinginSMARTforeachofthesixcomponents.Ifpressedfortimeonlydotheoddyearscomingbackfrom2015…5/6,3/4&1/2refertostudentachievementlevelsasrepresentedinSMARTforthesurvey.
In terms of your priorites for science in Years 7-9, write the letter representing the six statements (A to E) in order of importance (most important first):
321
6 ** 6 ** 6 ** 6 ** A ** A ** A **5 ** 5 ** 5 ** 5 ** B ** B ** B **4 ** 4 ** 4 ** 4 ** C ** C ** C **3 ** 3 ** 3 ** 3 ** D ** D ** D **2 ** 2 ** 2 ** 2 ** E ** E ** E **1 ** 1 ** 1 ** 1 ** ** ** **
5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 **3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 **1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 **
5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 **3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 **1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 **
5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 **3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 **1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 **
5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 ** 5-6 **3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 ** 3-4 **1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 ** 1-2 **
2015
N = number in the year
2010 2011 2012 2013 2014
2013 2014 2015
N = the number of students who sat the test that year**Copy SMART percentages into the relevant cell. The data is available from the annual school reports in SMART headed Percentages in achievement level .
N = N =
2007 2008 2009 2010 2011 2012
2008
Y8 ESSA-VALID EXTENDED RESPONSE
Y8 ESSA-VALID OVERALL RESULTS
Y8 ESSA-VALID Plan & conduct investigations / Working scientifically
SCHOOL:
DATE:
For this page, If pressed for time, only complete the data for odd years beginning with 2015 and working back.
N = N =
N = N = N =
YEAR 10 SCIENCE (SCHOOL CERTIFICATE, NOT VALID)
N = N = 2009
Y8 ESSA-VALID Problem solving and communication / Communicating scientifically
N =
2009 2010 2011 2012 2013 2014 2015
N = N = N = N = N = N =
2007
* * * * * *
* * * * * *
* * * * * *
* * * * * *
* * * * * *
2014 20152011 2012 2013
HSC Physics Total no in school course --->
COURSE YEAR 2010
HSC Senior Science
HSC Biology
HSC Chemistry
Total number of HSC English students for your school --->
Total no in school course --->
Total no in school course --->
Total no in school course --->
Total no in school course --->
HSC Earth & Environmental Science
SCHOOL:DATE:
For this page, if pressed for time, complete only the odd years working back from 2015. I realize that not all schools offer all HSC courses.
* Divide science HSC course numbers by total ENGLISH numbers for that year and convert to a %
322
AppendixF:Scienceteachersurveyquestions
INSTRUCTIONSANDCONSENT
ThepurposeofthissurveyistofindoutaboutyouruseoftheESSA/VALIDprograminthecontextofallyourassessment-relatedworkinscience.
Thereare26questionsandthewholesurveyshouldtakeyouabout25minutestocomplete.Youcanchangeyourmindatanytimeandstopcompletingthesurveywithoutconsequences.Ifyouchoosetoidentifyyourself,Iwillkeepanydatayouprovideconfidential.
##############################################################
IhavereadandunderstandthematerialabouttheresearchprovidedinATTACHMENTSONEANDTWOforwardedtomebymyprincipal.
Iwishtoproceedwithansweringthequestions
SECTIONONE:ABOUTESSA/VALID
TheESSA/VALIDtesthasbeenapartoftheYear8scienceexperiencesince2007.FeedbackfromtheESSA/VALIDtestandtherelatedstudentsurveyaccompanyingitisprovidedtoschoolsinTerm1oftheyearfollowingthetest.ThefollowingitemsaskaboutyouruseoftheESSA/VALIDtestandrelatedfeedback.[RadiobuttonsforYES/NO]
1.InrelationtoESSA/VALIDresultsformyschool,Ihaveintheprevioustwelvemonths:
1a.lookedattheresultsofthestudentsurvey
b.lookedattheitemanalysisformyclass/school
c.lookedattheanalysisofanswerstothethreeextendedresponsetasks
d.lookedatthestudentprofileinformation
e.discussedtheitemortaskanalysiswithcolleagues
f.discussedtheitemortaskanalysiswithstudents
g.discussedtheresultsofthestudentsurveywithcolleagues
h.discussedthestudentprofileinformationwithcolleagues
i.discussedtheresultsofthestudentsurveywithstudents
2.Ihaveintheprevioustwoyears:
2a.accessedESSA/VALID-relatedmaterialsinTaLE
b.accessedESSA/VALID-relatedmaterialsinSMART
c.usedinmyclassesteachingstrategiesthatIfoundintheESSA/VALID-relatedCurriculumLinksmaterials
323
d.accessedtheESSA/VALIDMarkingManual/sfortheextended-responsetasks
e.usedESSA/VALIDshortresponseitemsintopictests
f.usedESSA/VALIDextended-responsetasksintopictests
g.usedESSA/VALIDitems&/orextended-responsetasksinmyteaching
h.usedESSA/VALIDitems&/orextendedresponseitemsasmodelsforwritingnewitemsandtasksintopictests
i.contributedamendmentstofacultyprogramsasadirectresponsetoESSA/VALIDresults
j.writtenitemsfortheESSA/VALIDtest
k.beenonapaneltoevaluateESSA/VALIDitems
l.beenamarkerfortheESSA/VALIDextendedresponsetasks
m.haveattendedworkshopsaboutESSA/VALID(NOTincludingtrainingforESSA/VALIDmarking)
3.Overall,IwouldratemyunderstandingoftheESSA/VALIDprogramas
verypoor/poor/acceptable/good/verygood
4.IthinkthemostimportantpurposefortheESSA/VALIDtestis…
[aboxwith100wordslimit]
5.MyschoolwillthisyearparticipateintheVALIDsciencetestforYear10students
Yes/No/Unsure
SECTIONTWO:ABOUTSOLO
ThisnextsetofitemsisabouttheStructureoftheObservedLearningOutcome(SOLO)model.[RadiobuttonsforYES/NO]
6.InrelationtoSOLO,Ihaveintheprevioustwoyears:
6a.accessedmaterialaboutSOLOintheMarkingManualfortheextended-responsetasksintheESSA/VALIDtest
b.accessedmaterialaboutSOLOinplacesotherthantheMarkingManualfortheextended-responsetasksintheESSA/VALIDtest
c.explainedtheSOLOmodeltoanotherteacher
d.usedtheSOLOmodeltoexplaintheESSA/VALIDstudentprofiletoastudent
e.usedSOLOtodevelopassessmentcriteriaformyassignments/tests/tasks
f.usedSOLOtoprovidefeedbacktostudentsabouttheirlearning
g.LedadiscussionwithsciencestaffaboutESSA/VALIDresultsandwhattheymeanintermsoftheSOLOmodel
324
h.workedinasciencefacultywhereusingSOLOisanexplicitpartofsciencefacultypolicy&/orpractice
i.usedSOLOconcepts&/ormodelinregularstudentreportsofscienceachievementsenthometoparents/careres
j.usedtheSOLOmodeltoexplaintheESSAstudentprofiletoaparentorcarer
7.Overall,IwouldratemyunderstandingofSOLOas
verypoor/poor/acceptable/good/verygood
8.IconsiderthatIlearntmostaboutSOLOwhen…
[aboxwith100wordslimit]
SECTIONTHREE:ABOUT"ASSESSMENTFORLEARNING"
Thefollowingquestionsareabout"assessmentforlearning"andrelatedpractices.
I'mwantingtofindoutHOWOFTEN(inarelativesense)youdothethingsdescribedbelowinyourdaytodayteachingandrelatedworkinyourYears7,8and9classes.
YoumaynotknowaboutorbeunsureaboutsomethingslistedhereinwhichcasechoosetheNotknown/Unsureaboutbutton.[Respondentshadtheoptionsofmarking:
Notknown/unsureaboutNeverSeldomSometimesOften
9.Whenworkingintheclassroomwithstudents,I
9a.tellthemwhattheyshouldknow,understand,beabletodobytheendofthelesson
b.givestudentstheopportunitytosettheirownlearningintentionsforanactivityorseriesofactivities
c.explaintostudentstheindicatorsorsuccesscriteriaIwillbelookingforintheirwork
d.allowstudentssomeinputindecidingwhatsuccesscriteriaaretobeapplied
e.makethesignificanceofwhattheyaretodoexplicittostudents
f.askstudentswhytheythinktheyarebeingaskedtodotheproposedactivities
g.encouragepeerfeedbackbasedonsuccesscriteria
h.useresultsfrominstantdigitalpollingtechnologytoinformnextstepsinteachingthatlesson
10.Whenmanagingclassroomdiscussions,I
10a.askclosedquestions
b.askopenquestions
c.usewait-timebeforeresponding
d.askstudentstoexplaintheirthinking
325
e.usethe“think-pair-share-report”strategy
f.usetestorassignmentitemsandtasksasstimulusfordiscussion
g.usesamplesofstudentworkorresponsestoassessmentitemsasstimulusmaterialfordiscussion
h.explainmyresponses/thinking
11.Iprovidefeedbackonstudent'swrittenworkintheformof
11a.ticks
b.marks
c.grades(suchasAtoE)
d.commentsaboutwhattheyhavedonewell(eggoodwork,excellent,welldone...)
e.adviceabouthowtoimprove
IFFOR11eYOUCHOSENOTKNOWN/UNSUREABOUTORNEVER,SKIPTHENEXTQUESTION(Q.12)ANDGOTOQ.13
12.AstheBASISformyadviceabouthowtoimprove,Ireferto
12a.exemplaryormodelanswers
b.successcriteria
c.misconceptionsevidentinanswers
d.SOLOlevelsofthinking
e.QualityTeachingdimensionsandrelatedelements
f.Bloom’staxonomy/hierarchyofthinkingskills
g.syllabusstandards(syllabusoutcomes&relatedcontent)
13.Iprovideopportunitiesforstudentstoself-assess
13a.bygettingthemtowritesuccesscriteriaforactivities&investigations
b.bygettingthemtoconstructassessmentitemsandtasks
c.usingsuccesscriteria/assessmentrubricsorguidelines
d.byredoingworktoahigherstandard
e.byselectingitemsforaportfolioofworktheyjudgeasbeingconsistentwithnominatedsuccesscriteria
f.bygettingthemtokeepajournaloftheirreflectionsintheirownwordsonwhattheyhavelearnedinsciencelessons
14.Inmyday-to-daypreparationforandworkinclass,I
14a.askstudentstogivemefeedbackonmyteaching
b.respondtostudents’feedbackonmyteaching(thismaynotalwaysbeanimmediateresponse)
326
c.evaluatelessonsandrecordideasforchangenexttime
d.keepnotesonlearningissuesnoticedforindividualstudents
e.changetheplanned‘nextstep’inalessoninresponsetostudentfeedbackatthetime
f.accessanduseinformationabout“assessmentforlearning”inTaLE
g.accessanduseinformationabout“assessmentforlearning”intheBOSTESwebsite
h.accessanduseinformationabout“assessmentforlearning”fromotherplaces/sources(apartfromTaLE&BOSTES)
15.Icollaboratewithmyscienceteachercolleaguesto
15a.writeitemsandtasksfortests&/orassignments
b.producemarkingcriteria/assessmentrubrics
c.assessassignments/tasks/testsfromeachothersclasses
d.todevelopasharedunderstandingoflearningintentionsandsuccesscriteriaimplicitinsyllabusoutcomesforjuniorsecondaryscience
e.developasharedunderstandingofwhatprogressioninsciencelearninglookslike
SECTIONFOUR:ABOUTYOUANDYOURTEACHINGEXPERIENCE/CONTEXT
16.Iama femalemaleother17.Ihavebeenteaching 0-5yrs6-10yrs11-15yrs15+yrs18.Iamascienceteacherbytraining/qualification YesNoIfNOtoQ.18myqualificationsare…______________________________________________19.Iamaheadteacher,science YesNo20.MyHIGHESTscienceteachingqualificationis Bachelordegree+Diped(orequivalentPostgraduatequalification) BTeach(4yrdegree) MTeach(5yrdegree) DoctorateorPhDOtherscienceteachingqualification______________________________________________21.Icompletedmyhighestqualificationin(whatyear)__________22.Mytraining/qualificationstoteachsciencewereuntertaken completelyoverseas/partlyinAustraliaandpartlyoverseas/completelyinAustralia23.Iteach/havetaughtYears7-9classes thisyear/lastyear/theyearbeforelast/morethanthreeyearsago24.AtmycurrentschooltherearethismanyYear8scienceclasses
327
one/two/three/four/five/six/seven/eight/eight+25.Atmycurrentschooltherearethismanyfull-timescienceteachers one/two/three/four/five/six/seven/eight/eight+26.Atmycurrentschooltherearethismanypart-timescienceteachers one/two/three/four/five/six/seven/eight/eight+Ifyouarehappytobecontactedaboutthissurvey&/ORareinterestedincontributingtoacase-studyaboutESSA/VALIDandassessmentpractices,pleaseprovidethefollowinginformationandidentifyyourselfasrequestedbelow.27.Iaminterestedinfindingoutmoreaboutthissurvey(noteyouwillneedtoprovideyournameandpreferredcontactdetailsbelow) Yes/No28.Iaminterstedinfindingoutmoreaboutthecasestudyandwhatitwouldinvolve(noteyouwillneedtoprovideyournameandpreferredcontactdetailsbelow) Yes/NoMygivennameis:Mysurname/familynameis:Mypreferredcontactmodeis(pleaseprovidedetails):Mycurrentschoolis:Iwasappointedtomycurrentschoolin(year):Mypreviousschoolwas: Thankyouforgivingyourtimetocompletethissurvey.Yourinputwillhelpmetobetterunderstand‘assessmentforlearning’practicesusedbyscienceteachersinNSWYoumightwanttokeepacopyofyourresponsessothatyoucancomparethemwiththecollatedresponsesfromallteacherswhoparticipatedinthesurveywhichwillbeprovidedtoyouinduecourse.JimScottApril2016***PLEASETAKEAMOMENTTOGOBACKOVERTHESURVEYANDCHECKTHATYOUHAVECOMPLETEDALLQUESTIONSBEFOREFINISHING***SaveandcontinuelaterORFinish>
328
AppendixG:Interviewquestionsforcasestudyschoolparticipants(final)
1. Whatpromptedyoutojointhecasestudy?
2. WhatcontributiondoestheEVprogrammaketotheassessment-related
workdonebyyouoryourscienceteachers?
3. HowdoyouprepareyourstudentsfortheEVtest?
4. Consideratopicyouhavejustfinishedteachingorarenowwellinto
teaching.Bywhatmeansdoyoucollectevidenceofstudentlearningasyou
workthroughthetopic?
5. Towhatusesdoyouputevidenceofstudentlearning?
6. Whatsortsofthingsdoyoudointhenameofstudenttostudent(peer)
assessment?
7. Whataboutstudentself-assessment?
8. Whatarethemainsourcesofinformationyouaccesstoinformyour
assessment-relatedwork?
9. Whataretheschool/principalprioritiesandhowdotheyimpactyour
workasascienceteacherinYears7-9?
10. Whatareyour/sciencefacultyprioritiesforscienceteachinginYears7-9?
11. Thinkingbackoverthepastfiveyears,whatarethemainresourcesused
regularlybyyouandyourteacherstosupportscienceteachingandlearning
inYears7-9?
12. Ofallthethingsyouaredoinginthenameofscienceteaching,whichis
havingthemostimpactonstudentlearninginscience?/Howdoyou
know?
13. Thinkingaboutthesurveyyoucompleted(participantswerehandedapage
offiveselectedquestionsfromthesurveytoreview),howdidyoudecide
whatseldom,sometimesandoftenmeant?
14. Ifaskedbyaparentornewscienceteacherwhat“progressioninlearning
science”means,howwouldyouanswer?
15. Whatisthenatureandextentofdiscussionaboutassessmentatscience
facultymeetings?
329
IftheHThadbroughtthecompletedschooldataproformatothemeeting,the
followingquestionwasasked:
16. Whenfillingouttheform,whatresponse/sfromstudentssurprisedyouthe
most?Whydidit/theysurpriseyou?
Onceresponsesconcluded,Iindicatedthattheinterviewwascomingtoanendand
asked:
17. Wasthereanythingyouwanttorevisitoraddbeforetherecorderisturned
off?
Theinterviewwasconcludedbymesaying;“Thankyouforyourtimeand
patience…Ihopeyoufoundtheexperiencefriendlyanduseful…thisconcludesthe
interviewandI’mturningofftherecordersnow”.Oncetherecorderswereoff,I
explainedthatwhenthestudywascompletedIwouldbeprovidingfeedbackon
thesurveyresults(toallsecondaryschoolsinvitedtoparticipate)andcasestudy
summariestoparticipants.
330
AppendixH.Assessmentrelatednarrativesforcasestudyschoolsusedto
makepairwisecomparisons.
ThecriteriaforcomparisonaresharingthesameSEAscoreandhavingdifferent
residuals;themorewidelydifferenttheresidualsare,theeasiertoseedifferences
inassessment-relatedworknarratives.
PairONE:AssessmentnarrativescomparedforPCWAE1andMCWAE1
A.EngagementwithEVfeedback,resourcesandSOLO
PCWAE1
TheprovincialteachersparticipatedinthecasestudytofindoutwhytheirEV
resultswerebetterthantheirNAPLANresults(astheyhadseenbycomparingthe
proportionsofstudentsineachoftheEVandNAPLANbandstostateproportions).
TheywereearlyadoptersoftheEVprogramhavingpiloteditin2005andtrialedit
in2006beforeitbecamemandatoryacrossthestatefrom2007.Theyalsoengaged
withVALID10whenitwasfirstofferedin2015andindicatedtheywouldcontinue
withitintothefuture.TherewasevidencethattheyuseditemsfromtheEVtests
intheirownassessmenttasks,butsyllabuscriteriaratherthanSOLOwasthebasis
formarkingstudentresponsesintheassessmentrelatedartifactstheyprovided.
TheyadmittedthattheirknowledgeandunderstandingofSOLOwas“verylow”
buttheysaidtheylookedattheirEVresultseachyear.Thestudentsurveyresults
werenotusuallylookedatandnoevidencewasprovidedthattheYear8EV
feedbackwasuseddiagnosticallyduringtheyearstheywerereviewingtheir
schoolprograminpreparationforthenewsyllabusbeingimplementedfrom2014
(inY7&Y9).NocommentsweremadeabouttheirexperiencewithSOLOwhen
markingtheVALID10tests.
Whilsttherewasalongstandingandstrongfocusonscientificliteracyandgetting
studentstomakeappropriateuseofscientifictermsinreportsandexplanations,it
wasnotapparentlyconnectedbythemtothesecondcycleSOLOlevels.Twoofthe
threeteachersidentifiedthediagnosticpurposeoftheEVtestintheirresponsesto
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theteachersurveyquestionaskingaboutthemostimportantpurposeoftheEV
program.
MCWAE1
Theschoolhasaconsiderablerefugeeintakeeachyear(around30%).Many
studentshavelittle,ifany,formaleducationorEnglishlanguageskillsbefore
arrivinginAustralia.TheirfirstexperienceforthesestudentsisinanIntensive
LanguageCentrebeforetransitioningtosecondaryeducationwhentheyreachan
appropriateleveloflanguageproficiency.TheHTandthreeofherstaffattended
theinterviewwhichwentoverthehour.TheschoolhasembracedtheEVprogram,
includingVALID10fromitsinceptionandseeitasausefulresourceamongmany
forhelpingtheirstudentstolearnscience.Theteacherslookattheresultswhen
theycomeoutandreportthehaveusedachievementfeedbacktomakechangesto
theirprograms.Teachersdonothaveaccesstothestudentsurveyfeedback.In
relationtotheEVtest,theydospendsometimehelpingstudentstoprepareby
givingthemaccesstosamplequestionsfrompastpapers.Teachersreportthat
studentsenjoydoingthetest.Theywantedtojointhecasestudyinorderto
receivefeedbackontheirassessmentpractices.
B.Groupingforinstruction
PCWAE1
Eachyeartheprovincialschoolestablishedtworelativelysmall(fewerthan
twentystudentsisnotunusual)Y7mixedabilityclassesbasedonstudentdata
providedbythefeederK-6schools.ThetwoclassesgoontoY8largelyunchanged.
TheschoolchoosestoestablishtwosmallclassesineachofYears7&8,butthen
formtwocombinedY9–10classeswhichareverylarge(inexcessofthirty
studentsineach).
MCWAE1
EachyearthreeYear7classes(withfewerthan20students)areestablishedbased
onthelevelofliteracyskills.Classesareungradedfromtheperspectiveofprior
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scienceexperienceorlearning.Assistanceisprovidedtoclassesbylearning
supportteacherstohelpthehighproportionofstudentswithlittleformal
educationandverylimitedEnglishlanguageproficiency.Classesareretained
relativelyunchangeduntiltheendofYear10.
C.Useoflearningintentionsandsuccesscriteria
PCWAE1
Analysisofinterviewresponsesandartifactsprovidedbytheprovincialschool
establishedthattheteachingprogramwasexplicitlybasedonsyllabusintentions
asexpressedthroughoutcomesandrelatedcontent.
Inprogramoutlines,undertheheadingIndicatorsofstudentachievement,alistof
sciencevocabularystudentswereexpectedtoacquirewasprovidedaswasalistof
whatstudentswereexpectedtoknowandunderstand,andaseparatelistofwhat
studentsneededtobeabletodo(skills)bytheendofthetopic.Learningthe
spellingandmeaningsofwordsinthevocabularylistforeachtopicwasthemain
sourceofformalhomework.Indicatorsbasedonthecontentsoftheselistswere
evidentinthecriteriaincludedinrubrics/scaffoldsfortasksrelatedtothetopics
beingtaught.
Teachingactivitiesandrelatedassessmenttasksdescribedintheprogramswere
alignedtosyllabusintentions.Inrelationtothelivedexperiencesofstudents,the
teacherscommentedthataboutonethirdofstudentslivedonruralproperties,did
notrecognisethescienceinthedaytodayplantandanimalhusbandryworkand
theequipmentusedtodothatwork.Addressingthisdisconnectionbetween
scienceandthestudents’lifeexperiencewasapriorityfortheteachers.
Assessmenttaskswereassignedwithrubricsthatclearlydescribedexpectations
basedonsyllabusoutcomes.Teacherssaidtheyusedtherubricstobothintroduce
tasksandtoprovidefeedbacktostudentsoncetaskswereassessed.
TwoformalpenandpapertestsforeachofY7andY8,basedonsyllabusworking
scientificallycontent.Thetestsincludedfreeresponseextensionquestionsthat
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askedstudentstoexplainusingscientificmodels(particlemodel)andtoidentify
andcorrectmisconceptionsinexamplesthatweregiven.
Theteacherssaidtheyprioritizedpracticalactivitiesandreportwriting.Students
didthreeresearchprojectsacrossthefouryearsseventoten(thesyllabus
specifiesaminimumoftwo).Examplesofbothlaboratoryandfieldworkwere
providedintheartifacts.Expectedlearningfromthoseexperienceswastypically
scaffoldedinaworksheetormodeledusingatextbookexample.Open-ended
questionswereevidentinthoseworksheets.Thescaffoldswereinformedby
expectationsdescribedintheskillssectionofthesyllabus.
Reportingtoparentsisingradesalignedtocurriculumstandards(AtoE),whichis
nationalpolicy(thesameappliestoMCWAE1).
TeachersreportedthattheydidnotoftenuseICTinY7/8scienceclasses.
MCWAE1
Thesciencedepartmentprogramhasfourten-weektopicsmappedtosyllabus
outcomesforthefourcontentareas(InYear7thetopicsareForces,Chemical
World,EarthandSpaceandLivingWorld).Syllabusexpectationsarealsomapped
totheeighteenelementsoftheQualityTeachingFrameworkandreferencestothe
crosscurriculumaspectsoflearningareexplicitlyidentifiedaswell.Syllabus
outcomestargetedincludeValuesandAttitudes,WorkingScientificallyand
KnowledgeandUnderstanding.Learningactivitiesaredescribedintermsoflesson
outcomesthatappeartorequirefromonetoanumberoflessonstoachieve.A
diversityofresourcesareidentifiedtoworkwithincludingconventionaltext
books(e.g.CoreScience,ScienceStage4)andworksheetsdescribingactivitiesto
beperformedandwritingtobedone.
Assessmentisbyconventionaltopictestsandendofsemestertests.Studentsare
providedwitharangeofoptionsforrespondingincludingmultiplechoice,short
andlongerresponseitemsinvolvingstudentswritingdescriptionsandor
explanations.Someitemshaveinterestingstimulusmaterialassociatedwiththe
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item.Thereisawordpuzzleattheendofeachtestforstudentstoengagewithif
theyfinishearly.Anexampleofapracticaltestandaresearchprojectscaffoldwas
providedforYears7and8.Norubricslinkedtosyllabusoutcomesordifferent
levelsofanswerswasprovidedasmodelsforstudentstoworkwith.Studentsdid
notappeartohavemuch,ifanysayinchoosingordevisinglearningintentionsor
successcriteria.
D.Classroomdiscourseandevidenceoflearning
PCWAE1
Teachersreportedthatgroupworkiscommonandinstructionisprovidedto
studentsabouthowtoworkcooperativelyintheclassroom,laboratoryandduring
fieldwork(usingthelocalriveranda‘wetlands’area).
Teachersreportedthattheyusedapredict-observe-explainstrategytofocus
discussionofpracticalworkandasapreliminarysteptowritingupapractical
report.Theteachersreportedthatschool-basedlearningsupportstaffwere
regularlyinvitedvisitorstotheirscienceclassestohelpstudentsstrugglingwith
literacyskills.
Teachersdescribedsomeoftheearlyworkdoneintopicsasopportunitiesfor
verbalpre-testingandstudentswerehelpedtoconstructmindmapsasawayof
summarizingtheirlearning.
Schoolpolicyplacedgreatemphasisonliteracylearningasakeytohelpingall
studentssucceed.Thesciencefacultysupportedthisemphasisinitshomework
policy(acquisitionofscientificvocabulary)andinclassroomworkwherestudents
weresupportedandencouragedtoverbalisetheirexperiencesusingthe
appropriatevocabularyearlyandoften.
TheteachingprogramsforYears7and8wereorganizedintotenweektopics(one
perschoolterm).Theprogramsalsolistedresourcessuchasrelevantvideos,text
booksectionsandexcursionswhichwereanannualeventforstudentsinYears7-
10.OneexcursionforY8studentsinvolvedavisittoLaTrobeuniversitytoraise
335
studentawarenessofpostschooloptionsandanotherwhichwasanextendedfive
daytriptotheNSWsouthcoast.Studentswererequiredtowritereportsofthese
activities.
MCWAE1
Sciencelearningactivitiesprovidedtostudentsatthisschoolwerediverseand
includedconventionalclassroombasedactivitiesusingtextbooksandworksheets,
laboratoryactivitiesinvolvingequipmentandreportwriting,excursionsbeyond
theschoolgatesandvisitstotheschoolbypeoplethatworkinSTEMcareers(such
asCSIROandQuestacon.SomeaccesstoICTisprovidedinthelibraryforresearch
purposes.StudentsdoICAStestsandparticipateintheBigSciencecompetition.
Manyattendtheafter-schoolhomeworkcentreanddosciencehomeworkthere,
includingsciencevocabularyandspellingrelatedwork.Thereisaheavyemphasis
inlessonsontalkusingscientificvocabulary(wholeclassdiscussioniscommon).
Thereisexplicitinstructionrelatingtogroupworkandrolestobeperformed.
Studentsarenotconfidenttalkers,especiallyinYears7and8.Studentshavea
strongpreferenceforrotelearning(thatseemedtoteacherstoberelatedto
expectationsbasedonexperiencebroughtfromothercultures).
E.Feedback
PCWAE1
Feedbackonassessmentandothertasksoftentooktheformofdiscussionwith
studentsabouttherubriccriteriaandhowtheywereusedtoallocatemarksthat
mappedontoafive-pointscalerangingfromunsatisfactorytooutstanding.
Whenaskedaboutprogressionoflearning(oneofthequestionsinthesurvey)
theydidnotreadilyrelatesyllabusoutcomesandcontentwiththeideaoflearning
progression.
TheschoolwasmakinglessusenowoftheEducationalAssessmentAustralia
(EAA),InternationalandCompetitionAssessment(ICAS)sciencetests(20
studentssatthemin1999;lastyearonlytwodidso).Scienceteachersdidnotuse
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theresultsfordiagnosticpurposes.Theydiduseitemsfromthemintheirclassand
assessmenttasks.Certificatesaboutparticipationandachievementwerehanded
outataregularschoolassembly.
Intheinterview,therelievingDPdrewattentiontothegoodresultsinYear10(see
theproportionofAsfortheschoolrelativetothestateinTableK.3inAppendixJ)
andcommentedthatresultstheredidnottranslateallthatwelltotheHSC,which
hefoundpuzzlingandforwhichhecouldfindnoexplanation.
Healsocommentedonthestudent’sapparentlowenjoymentofsciencelessons
comparedtothestateassomethinghecouldnotexplain(seeTableK.2data).The
othertwoteacherssaidtheyhadaskedstudentswhytheydidn’tlikescienceand
weretoldthatitwasbecause“you”(scienceteachers)followeduptoensurework
wascompleted.Thisexplicitinterestinaskingstudentswhytheydidnotlike
sciencewasaresponsetoreadingthesurveyfeedbackinpreparationforthe
interview.
MCWAE1
Talkintheinterviewindicatedastrongemphasisonoralfeedbackduringlessons
largelyrelatedtobuildinglanguageskillsintheappropriateuseofvocabulary
relatedtotheconceptsandskillsandprocessesofsciencebeingtaughtatthetime.
Pre-testingwasnotmentioned.Feedbackontestsandworkwasprovidedby
teachersintermsofmarksanddiscussionofanswers.SOLOwasnotmentioned
norweresyllabusoutcomesorexpectations.Researchprojectreportswere
heavilyscaffoldedandteachersreportedtotheresearcherthattimewasgivento
explainingwhatthedifferentcomponentsare.Classandhometimewasgivento
theprojects.
F.Activatingstudentsasinstructionalresourcesforothers
PCWAE1
Peerfeedbackwassoughtwhenoralpresentationsormodelswereproduced.No
otherdetailsaboutthatfeedbackwereprovided.
337
MCWAE1
Theonlyformalopportunityforthatappearedtobeduringgroupworkinthe
contextofpracticalworkinthelaboratory.Teacherscommentedthatthe
classroomsetupdidnotsupportusingthink-pair-sharestrategy.
G.Activatingstudents(andteachers)aslearners
PCWAE1
Thismostlytooktheformofteacher-leddiscussionaboutstudentworkinthelight
ofteacherprovidedrubrics.Therubricsdescribedarangeofresponsesshowing
thefeaturesofresponsesthatachievedhighmarks.Therubricswereinevitably
relatedtosyllabusexpectations.IntensiveliteracyworkwithstudentsinY7&Y8
wasfollowedupinYears9&10withexpectationsthatstudentswouldusethose
skillstoworkindependentlywhilsttheirteacherswereprovidingtimetovarious
groupsintheclass,giventhatstudentswerenotonlymixedabilitybutacrosstwo
grades.Self-assessmentopportunitieswereprovidedasearlyasinY7andteachers
providedfeedbackonit(seeFigure6.1).
Example1:PCWAE1
Name:________________________________________Project:________________________________________________________________________________
Purposeoftoy:_________________________________________________________________________
Areyouhappywithyourfinalproject?Why/Whynot?_____________________________Whataresomethingsyoudidreallywell?___________________________________________
Whataresomethingsyoucouldhavedonebetter?_________________________________
Thanks,Goodjob
Example2PCWAE1
MarksOutstanding--6//High--4-5//Sound--2-3//Basic/limited--1
Justification(opinion+reasons) Clearrecordofchangesmadetotoyandareasonforeachchange.Overalljustificationoffinaldesignandproduct(toy)Somerecordofchangesmadeandreasonsforthesegiven.Briefjustificationoffinaldesignandproduct(toy) Minimalrecordofchangesmadewithlittleorno
338
reasonsgiven.Anattemptmadetojustifyfinaldesignand/orproduct(toy) Anattemptmadetojustifyeithertheirdesignorfinalproductoranychangesmade
Figure 6.1 Opportunities for self-assessment in Year 7 Making a Toy task
Theteacherssaidtheymetregularlybothinformallyandformallytoworkon
aspectsofscienceteachingandrelatedassessmenttasks,whichwereoften
collectivelymarked.Theywereclearlyenthusiasticabouttheirwork.Faculty
programsprovidedwerecomprehensiveandwhilsttheydidnothavespacefor
writtenevaluation,itwasclearfromthediscussionthatthenewprogramsatthe
schoolforthenewsyllabushadbeencollaborativelydeveloped.
MCWAE1
Theteachersmetweeklyassessmentwasoftendiscussedtheysaid.The
developmentoftheteachingprogramswasasharedactivity.Teachers
participatedintheinterviewandweresupportiveandrespectfulofeachotherin
thatdiscussion.
H.Comparativesummativecomments
WhenresultswerecomparedattheendofYears8and10theprovincialschool
hadthebestresults.Alsotheyhadahigherproportionofseniorsciencecourse
completions(asaproportionofthestudentsattheirschool).Thecomparisons
madeheresupportedthethreepredictions,eventhoughtheschoolswereboth
WAEschools..
Theassessmentnarrativesfrombothschools,whencompared,revealedthatinthe
earlyyearsofsecondaryscienceteachingbothschoolsmadeuseofavarietyof
contextsforteachingsciencewhichinturnmeantthatstudentshadopportunities
toprovideevidenceoflearning.Teachersattheprovincialschoolmadegreateruse
ofrubricsrelatedtoscaffoldedtasksandtheyprovidedfeedbackduringandafter
completion.Thefeedbackwasintermsofsyllabusexpectationsandmarks
awardedasrecommendedintheBoard’sCommonGradeDescriptoroutline.There
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weremoreopportunitiesattheprovincialschoolforpeer-andself-assessment.
Summativeassessmentatthemetropolitanschoolwasmorestronglylinkedto
traditionaltestingthanattheprovincialschool.
Whilstthethreepredictionslendweighttotheconclusionthatteachingatthe
provincialschoolwasmorecloselyalignedtotheformativepracticesprofileof
WAEschoolsasidentifiedinchapterfive,thelevelofengagementwithscience
whencomparedtoboththemetropolitanschoolandthestatewasnotinlinewith
expectationsforself-regulatedlearners(theexpectedoutcomefromteaching
characterizedasformativeasdiscussedinchaptertwo).Overall,studentsatthe
provincialschoolwerelesspositiveabouttheirschoolscienceexperiencethan
theirmetropolitancounterparts.
Itwasimpossibletoidentifyfromtheassessmentnarrativeswhystudentsatthe
provincialschoolhadsuchpoorperceptionsoftheirschoolexperienceofscience
attheendofY8.Theteachingprogramatthemetropolitanschool,comparedtothe
provincialschool,wasmorelikethatdescribedinthelefthandcolumnofTable
2.1,yetstudentsatMCWAE1werethemostpositiveabouttheirschoolscience
experienceofallthecasestudyschools(seeTableK.5inAppendixJ).Teachersat
themetropolitanschoolsaidthateventhoughparentsdidnotcometotheschool
often,theywereawareofstrongsupportforteachersandlearningbyparentswho
oftenboughttextbooksforstudentstokeepanduseathome.
PairTWO:AssessmentnarrativescomparedforMCAE2andMCWBE3
A.EngagementwithEVfeedback,resourcesandSOLO
MCAE2
Theprincipalwaskeenfortheschooltobeinvolvedinthecasestudyand
expressedinterestinanyfeedbacktocomeoutoftheprocess.Theheadteacher
sciencewasalsotherelievingdeputyprincipal(R/DP)atthetimeoftheinterview
andtheonlypersonattheinterview.Hehadbeenattheschoolintheheadteacher
positionintheperiodofinterestfortheproject.Thesciencedepartmenthadnot
340
engagedwithSOLObutwerefocusedonsyllabusoutcomesandtheBoard’s
approachtograding.TheR/DPreportedthatstudentstooktheEVtestseriously
andappearedtoenjoytheexperience.Theschoolprovidednospecialpreparation
forit.TheschoolhadengagedwithVALID10andwereplanningtocontinuewithit.
Theschoolhadnotdonetheproformaorcollectedartifactspriortothemeeting.
MCWBE3
ThemetropolitanschooldidnottakeupVALID10in2015andithadnoplanstodo
soin2016.TheHTreportedthatwhenshehadarrivedattheschool,thescience
staffhadverylimitedunderstandingofassessmentforlearningandhadnotmade
useofEVfeedbackatall.TheHTsaidthatsheandanothernewstaffmemberwho
hadarrivedattheschoolinthesameyearweretheonlyoneswhoknewanything
aboutSOLOwhichshecharacterizedas“allabout”recognizing“connections.”
Thefocusfornow,shesaid,wasonimprovingteachingandlearningpracticesin
juniorsecondaryscienceandmakinguseofdata(fromassessmentgenerallyand
SOLOinparticular)totargetresourcestothatend.
Therewasstrongevidenceintheartifactsofafocusonscientificliteracyand
appropriateuseofscientificterminologyinreports.Howevernothingwassaidby
hertolinkthistosecondcycleSOLOresponses.Thisemphasisappearedonlytobe
recent(i.e.,aftertheHT’sarrivalattheschoolandaftertheperiodofinterest).
B.Groupingforinstruction
MCAE2
TheschoolwaspromotingitselfasaschoolwithaspecialinterestinSTEMbroadly
andbiosciencesinparticular.EachYeartheschoolprovidesa‘selectiveentry’test
forlocalY6studentsthatincludessciencequestionsaswellasgeneralabilityand
literacyandnumeracyskills.Thatclassisprovidedwithanacceleratedprogram
andcompletethefouryearsciencecoursebytheendofYear9.Theotherfour
classesareunstreamedandstudentsremainintheirclassuntiltheendofYear8.
TheR/DPindicatedthatthiswasconsistentwithadeliberate‘middleschool’
341
approachtothefirstfewyearsofhighschoolaimedatprovidingsupportand
stabilityforstudentstoassistthemwithtransferfromprimarytosecondary
education.Sometwentystudentseachyearareprovidedwithadditionallearning
supportassistance.
MCWBE3
Themetropolitanschoolestablishedsixorsevenclasses(dependingonnumbers
tobeenrolled)inY7eachyear.Theestablishedclassesarethesameforthefour
coresubjectsandremainrelativelyunchangeduntiltheendofY8.Studentsare
allocatedtoclassesbasedonstudentdatafromthefeederprimaryschools.Two
parallelhighachieverclassesandfourorfivemixedabilityclassesarecreatedby
theY7adviserandotherstaff(notscience)attheschool.Changeswhentheyare
madearenegotiatedacrossthefacultiesusingadiversityofcriteriabuttypically
theyareunrelatedtoscienceassessmentresults.
C.Useoflearningintentionsandsuccesscriteria
MCAE2
TheR/DPdidshowmesometasksstudentsinYears7and8weregiven.Learning
intentionsandsuccesscriteriabasedonthesyllabuswereamajorfocusinthe
researchandothertasksstudentsengagedwithandtheyinformedtheassessment
rubricsusedbyteacherstomarkthem.Evidenceoflearningwasprimarily
gatheredfromthesetasksandusedasthebasisforreportingtoparentstwice
yearly.Thescienceteachersprovidea300wordreportonscienceachievement
twiceayeartoparents.Thereportsincludespecificreferencestoteacher
observationsofstudentsworktoillustrateaspectsofachievementrelevanttothe
reportingcategoriesaddressedintherubrics.
TheschoolretainedaYear7annualtest,butmostoftheevidenceoflearning
comesfrom4-5tasksstudentsdoeachyear,oneofwhichisapracticaltask.The
tasksputastrongfocusonscienceprocessesandtrytoengagethestudentsby
makingthemrelevanttostudentinterests,includingmakingmodels(egparachute
342
andeggdropactivity)andexplainingthemtoothermembersoftheclass.Teachers
provideassessmentfeedback.Teacherjudgmentoflearningisconveyedinmarks
whicharethentranslatedintogradesforthepurposeofreportingtoparents.
Nosampleprogramswereprovided,butthedescriptionprovidedwasoffourto
fiveSTEM/BiosciencetopicsineachofYears7and8“areidentifiersofthe
school.”ThesearecrosscurriculumcoursesincludingPDHPE,HSIEandR/DP
wrotetheseprograms.Eachdepartmentprovidestwohoursinafortnightlycycle
forthisprogram.Recognisedaneedtostrengthenunderstandingandawareness
ofthescientificmethodandabilitytoinvestigatescientificallyandthishasledto
theshifttoinquiry/projectbasedlearningemphasis.Successseenintermsof
growingnumberofstudentstakingupseniorsciencecourses.Studentsaretaking
upschoolcoursesinYear9&10(coursesinforensicsandzoology)ingood
numbers.
MCWBE3
TheHTdescribedthefacultycultureshehadinheritedas“traditionalandresistant
tochange”.Whenshearrivedattheschoolsheobserveda“widespectrumof
learners”attheschoolbutfewdifferentiationstrategiesinscienceprogramsfor
meetingthoseneeds.Astheinterviewprogressed,hergraspofwhatthose
strategiescouldbewaselaboratedbyreferencetoresourcesshehaddeveloped
withstaffattheschool.Artifactsofthisnewworkwereclearlyalignedwith
syllabus.
Atthetimeofherarrivalstaffwerenotkeento“domorethanrequired”andnone
ofthemhadmarkedeitherHSCorEVextendedresponsetasks.Sheobservedthat
whenshefirstarrivedstaffworkedindividuallytoproduceassessmenttasks
whichwerethenindividuallymarked.Shealsosaidthatatthetimeofherarrival
staffhadapoorunderstandingoftheBOSCommonGradingScaleandtheir
processesfortranslatingmarksintogradeswereunrelatedtosyllabusstandards
andthusinconsistentlyarrivedatacrosstheclasses.
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ShesaidthatitwasherobservationthatstudentsstartedscienceinY7looking
forwardtoandlikingsciencebutwere“disengaged”bytheendofY8.
Teachingprogramsintheperiodofinterestwerefortopicslastingfiveweeks
(nowtheyaretenweeks).TheHTwasnothappywiththeschoolscienceprograms
shehadinherited,whichinherviewwere“allovertheshop”andhadbeen
developedasajointprojectwithseveralotherschools.Staffdidnothaveenough
understandingorwillingnesstodoascopeandsequencefornewsyllabustopics.
Oneofherfirstactionswastopersuadestafftoworkoncreating/collecting
resourcesfornew“scopeandsequences”(teachingprogramoutlinesmappedto
syllabusintentions)whichsheandtheothernewteacherhaddevelopedforyears
7and9soonaftertheirarrivalattheschool.
TherewasverylittleuseofICTinYears7and8scienceclasses.Priorto2015,
worksheetsprovidedbyteachersandtextbookswerethemainresourcesusedto
supportteachingandlearningshesaid.Verylittleworkwasdoneoutsidethe
classroomthenandtherewerenosciencespecificexcursionsbeforeshearrived.
TheHThasprioritizedgettingmorestudentstothink(inscienceclasses)andto
takeseniorsciencecoursesandsheisdoingthatbybuildingtheteachingand
assessmentskillsofherstaff.TherewasnomentionoflinkingofSOLOlevelstothe
discussionaboutwhattheteachingofthinkingmightinvolve.
LiteracyandwritinginparticularareschoolprioritieswhichtheHTsaystheyare
embracingnowinscienceandmakinggooduseofEVextendedresponsetasksto
thatend.
D.Classroomdiscourseandevidenceoflearning
MCAE2
Reportedly,learningtasksareassignedinclassandworkedoninstudentsown
timeaswell.Groupworkisencouragedandsupported.Teacherobservationof
studentteamworkskillsaswellastheirindividuallywrittenreportsprovide
evidenceoflearning.Wholeclassdiscussionisstronglyencouraged;theuseof
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think-pair-share-reportlikestrategiesappeartobeusedinsomeclassesandsome
reflectivewritingbystudentsisencouraged.Studentswereprovidedwitha
diversityoftasks,mostdrawfromawiderangeofcontextsandotherlearning
areas(seeabove).TheschoolengageswiththeYoungScientistcompetitionand
providessomestudentswiththeICASsciencetestsaswell,butlittlewasdonewith
thefeedbackapartfromprovidingthecertificatestostudentswhentheywere
returnedtotheschool.TheschoolengageswithNationalScienceWeekandputs
onactivitiesforfeederprimaryschools.
MCWBE3
Informationaboutclassroompracticebefore2014wasanecdotalbuttheHT
referredtoheavyuseoftextbooks,worksheetswithlimitedopportunitiesfor
extendedwrittenresponsesandconventionallaboratorypracticalworkdesigned
toconfirmsyllabusprioritizedtheories.Practicalworkwasconductedingroups,
buttheHTreportedthatshehadlittleevidenceofpurposefuluseofgroupwork
forpeersupportedlearning.
Theschoolhasalearningsupportunitandanumberofstudentsarereceiving
supportfromitsteachers.
ThetimetablingsoftwareuseddeliversanumberofsplitclassesinYears7and8
(typicallyoneclasssharedbetweentwoteachers)andanumberofclasseswere
andstillaretaughtinthejuniorsecondaryyearsbyPDHPEteachers.
E.Feedback
MCAE2
TheR/DPreportedrecentengagementwithHattie’sVisibleLearning(2009).Itwas
notclearhowfarbackintotheperiodofinterestwasinfluencedbythis.Marks
weregivenrelatedtorubricsbasedonsyllabusoutcomes,butteachersalsogave
writtenfeedbackexplainingwhythemarkwasgivenandsuggestionsforbetter
answerswerealsoprovided.Feedbackwasprovidedagainstrubriccriteriainthe
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contextofclassroomworkeitherone-to-onewiththeteacherorwholeclass
managedbytheteacher.
MCWBE3
TheHTreportedthatwhenshehadarrivedtwoyearsago,feedbacktostudents
fromassessmentandothertaskswasbasicandinvolvedreportingbackofmarks
with,asfarasshecouldascertain,littlediscussionordiagnosis.Assessmentthen
wasdominatedbyendoftopictestsandmarkswererecordedandusedfor
reportingsummatively.Taskscompletedinclassweresimplymarkedandhanded
backwithrudimentarydiscussion(ifatall).
EAA/ICAStestswereandstillareofferedtothetoptwoclassesbutresultsarenot
usedfordiagnosticpurposes.
F.Activatingstudentsasinstructionalresourcesforothers
MCAE2
Opportunitiestoprovidefeedbacktopeersappearedtobelimitedtogroupwork
duringclasswork.SomestudentswerealsoinvolvedindemonstratingtoYear6
studentsduringScienceWeekactivities.
MCWBE3
TheHTwasnotawareofanypeerassessmentopportunitiesbeingprovidedin
scienceclassespriortohertimeattheschool.
G.Activatingstudents(andteachers)aslearners
MCAE2
Someopportunitieswereprovidedinsomeclassesforself-reflectivewriting,but
noinformationaboutfollow-upwasprovided.TheR/DPindicatedthattherewere
regularsciencedepartmentmeetings(onceafortnight)andthatassessmentand
programingwerediscussed.ThesciencedepartmenthadaSTANSWmembership
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andstaffparticipatedinmarkingofexternalexams(HSC)andparticipatedinother
professionallearningactivitiesrelated(mostrecently)toHattie’sVisibleLearning
program.Fromthatitcouldbeinferredthatstaffmodelledgoodlearning
behaviourswitheachother,buttheextentofthatmodellingforstudentswas
unclearfromtheinformationprovidedintheinterview.Also,therewasawareness
oftheneedfordifferentiatedcurriculumtomeetthediverseneedsoftalented
studentsanddifferentapproachesforthetwenty(estimated)studentsinthe
juniorsecondaryyearswhowereonamodifiedprogram(whichwerenot
individuallife-skillsprograms).Characteristicsofthatdifferentiationwerenot
provided.
MCWBE3
Again,atthetimeofherarrival,theHTreportedthattherewaslittleevidenceof
anyself-assessmentactivitiesorstrategiesinuse.Stafftendedtowork
independentlyandithasbeenaslowprocessupskillingtheminassessment
literacysincethen.Teamshavebeenestablishedwithinthesciencefacultyto
facilitatecooperativedevelopmentofprogramsandrelatedresources.This
collaboration,shereported,hadbeeneffectiveinraisingstaffawarenessand
understandingofassessmentissues.
H.Comparativesummativecomments
MCAE2wasanewschoolthathadatthetimeoftheinterviewonlyhaditsfull
complementofstudentsfromYear7to12forafewyears.Inthattime,ithad
deliberatelysoughttoestablishaSTEM/bioscienceidentityforitselfandprovided
studentswithalearningprogramthatreflectedthatemphasis.MCWBE3,onthe
otherhandwasawell-establishedschoolthatprovideditsstudentswithwhatwas
reportedbythenewheadteacherasa“traditional”program.
Forpredictionone,whenachievementattheendofYears8wascompared,
MCAE2’sresultsacrossallfourresultcategorieswerepositivelybiasedtowardthe
topbandofachievementmoresothatthoseatMCWBE3.Bothschoolshadatop
streamofstudents,whichmayaccountforthepositiveskewinbothsetsofresults
347
comparedtothestate.However,MCAE2resultsattheendofYear10wereslightly
positivelybiased,butcouldnotbecomparedwithMCWBE3becausethatschool
didnotprovideanyYear10resultstobecompared.
InrelationtoengagementattheendofYear8,giventheprioritygiventoSTEMat
MCAE2,thelevelofstudentengagement(asmeasuredbythecombinedscoresfor
ItemsDandE),comparedtoMCWBE3werenotthatdifferent.Topbandstudents
attheAEschoolwereonlytwoplaceshigherthantheWBEschool(9thand11th
respectivelyoutofsixteenschools.Thestatescorewascountedasaschool;both
rankedbelowthestatescore(2ndoutof16).Therankings(outof12)forthetotal
schoolresultswerethesame(9thand11threspectivelyandcomparedtothestate
whichranked5th).Basedontheassessmentnarrativesderivedfromthe
interviewsatbothschools,thiswasanunexpectedlycloseresult,particularlyfor
theAE2school,whichshouldhavereturnedamorepositiveresult.
EngagementwasassessedbylookingatYear12completionsrelativetothestate.
Inthiscomparison(seeTableK.4inAppendixJ),attheAEschool,Biology
completionswere200%,Chemistryjustover100%andPhysicswas63%(neither
schoolofferedSeniorScience).Bycomparisonwiththestate,theWBEschool
Biologyproportionwas74%,Chemistrywas39%andPhysicswas56%.
Thefiguresabovesupportthefirstprediction;noconclusioncouldbedrawnin
relationtopredictiontwoandpredictionthreewassupported.
Itwasimpossibletoidentifyfromtheassessmentnarrativeswhystudentsatboth
schoolshadsuchpoorperceptionsoftheirschoolexperienceofscienceattheend
ofY8.
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PairTHREE:AssessmentnarrativescomparedforPCWAE2andMCWBE5
A.EngagementwithEVfeedback,resourcesandSOLO
PCWAE2
TheprovincialschoolwasambivalentabouttheEVprogram.Ontheonehandthe
HTsaiditwasusefulforbothdiagnosticpurposesandcomparativepurposesbut
didnotelaborateonhow.Ontheotherittranspiredintheinterviewthatthe
sciencestaffhadanegativeviewofitscontributiontotheassessmentpracticesat
theschool(apartfromitsvalueinshowingthecomparativestrengthoftheirEV
resultscomparedtoNAPLAN).
TheHTwasconcernedaboutthevalidityofVALID10becausetheyhadrecognised
“rehashed”Y8ESSAquestionsit.Theythoughtthatschoolmarkingreducedits
valueforcomparativepurposes.TheywouldnotbedoingVALID10thisyear
(2016)sayingthattheschoolhadcomputeraccessissues,thatshewouldnotbeat
theschoolinTerm4andthescienceteachersdidnotseethevalueinit.
TheteacherwhowastoberelievingHT(forthenexttwelvemonths)hadjoined
theinterviewtowardtheend.Shereportedthatneithershenortheotherstaff
couldseethebenefitsofusingSOLOasabasisforassessmentbecauseitconflicted
withtheBoard’sgradingsystemandstudentshadfounditconfusingtodealwith
bothsystems.
EVresultsarehandedtoparentsatthefirstparent-teachernightoftheyear.The
HTreportedthat:
• parentsdon’taskquestionsabouttheEVtest;
• thereisnospecialpreparationforthetest;
• studentsliketheonlinesciencetestandtakeitseriously,astheydo
NAPLAN;
• theschoolisfocusedonresultsandtheprincipalis“happy”withscience
resultsgenerallyandtheirEVresultsinparticular.
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TheHTwasawarefromherownanalysisthattheschool’sEVresultswerebetter
thantheschoolsNAPLANresultsbutdidnotelaboratehowshehadarrivedatthat
conclusion.
MCWBE5
TheHTsaidheagreedtoparticipateinthecasestudytohaveasayabouttheEV
programwhichhesawasproblematic.Reasonsgivenincludedgivingsciencea
specialstatuswhichhewaspersonallyuncomfortablewith,issueswithaccessto
computers(sinceitwentonline),sciencestaffnotkeentosuperviseitandaschool
executivewhichhesaidwasnotinterestedintheresults.
Heacknowledgedthatthetestprovidedgoodquestionswhichhesaidwereused
intheirownschooltests.Hesaidthatthefacultywasnotgivenanytimebythe
schooltodigestEVfeedback(comparedtoNAPLANresults).
HeexpressedregretatthelossoftheY10statewidesciencetest(stoppedafter
2011)becauseitprovidedatarget(gradepattern)toaimforattheendofYear10
butalsosaidthattheywouldnotbetakingupVALID10.
B.Groupingforinstruction
PCWAE2
TheHTscienceattheprovincialschoolisresponsibleformanagingthe
compositionofclassesforScience,PDHPEandSocialSciences.Studentsare
initiallyplacedinthreemixedabilityclassesusingprimaryschoolliteracyand
numeracydata.Aftersixmonths,studentsarereorganizedintoseparatelygraded
classesforEnglish,MathematicsandSciencebasedonsummativeassessment
resultsineachofthesubjectsforsemesterone.
ThetopclassinSciencehasclosetothirtystudentsinit;thebottomclasshas
aroundtwentystudentsinitandisprovidedwithlearningsupport.Thereisasix
monthlyreviewofclassplacementsinScienceandstudentsaremovediftheir
performancechangeswarrantedit(eitherupordown).Thispotentialforchanging
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classescontinuesuptoandincludingY10.TheprocessissupportedbytheHT
Sciencewhodescribesherselfasatraditionalscienceteacher.
MCWBE5
FromdayoneinY7themetropolitanschoolplacesitsnewstudentsinclasses
accordingtofourdifferentsetsofcriteria.Atopclassof“giftedandtalented”
students,asecondclassof“independentlearners”,twoorthreeclasses(depending
onnumbers)ofmixedabilitystudentsandabottomclassofstudentswithlearning
disabilitiesandotherwisepoorlearninghistories.Theseclassesarethesamefor
English,Mathematics,ScienceandSocialSciencesandtheyremaininthoseclasses
upuntiltheendofY8.AttheendofY8allstudentsaregradedonthebasisoftheir
resultsfromacommonassessmenttask(typicallyatest)andputintoaclassbased
ontheirrankintheyear.TheytypicallystayinthatclassforYears9&10.
Studentsareinvitedtojointhe“giftedandtalented”classonthebasisoftheir
resultsinatesttheyappliedtositforinY6.Thetestwassetbythesecondary
schoolanddidnotincludeanyitemsrelatedtoscientificliteracy.Studentsare
allocatedtothe“independentlearners”classonthebasisofadvicefromtheirY6
teachers.Aninterestingfeatureofthisschoolisthatitonlyadmits12-15students
tothetopandbottomclasseseachyear.Theystayintheclassfortwoyearsand
theyhavethesameScienceteacherforthetwoyears.
Noexplanationorcommentaryaboutthemeritsorotherwiseofsettingupclasses
inthiswaywasofferedbytheHTscience.Hedidsaythatthebottomclasswas
providedwithadditionalsupportfromtimetotimebylearningsupportteachers
toimproveliteracyandnumeracylevels.
C.Useoflearningintentionsandsuccesscriteria
Thesciencefacultiesfrombothschoolshavehighprofilesintheirlocal
communitiesandhowthisisachievedbyeachofthemwillbedescribedbelow.
PCWAE2
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TheHTexplainedthatfromY7thepolicyistoexposestudentstohigh
expectationsinrelationtousingthelanguageofscienceandthereisclose
alignmentbetweensyllabusintentions,teachingandassessmentintheworkofthe
faculty.Thereareconsequencesforstudentswhoperformverywellornotsowell.
Theymaybepromotedordemotedaclassatthemiddleorendoftheyear(forthe
newschoolyear).
Theprovincialstudentsperformconsistentlywellinlocal,highprofilecommunity
agriculturaleventssuchasregion-based“HoofandHook”competitionswhichare
wellpublicizedinthelocalpress.Inanygivenyear,teachersofAgricultureare
verybusywithactivitiessuchastheabovethattakethemoutsidetheschool
duringtheschoolday,afterschoolandonweekends.TheHTreportedthatthe
Science,AgricultureandPDHPEfacultywasthe“strongest”performingfaculty
groupintheschool.Thereisastrongemphasisinthefacultyoncompetitionasthe
waytogetthebestoutofthestudents.
Inrecenttimes,withtheexceptionoflocalagriculturalevents,theschoolhasbeen
withdrawingfromgeneralscienceandtechnologybasedexcursionsandactivities
beyondtheschoolduetothecosts(oneexamplementionedwasthewithdrawal
fromtheUniversityofNewcastle’sEngineeringChallenge).Instead,localresources
areincreasinglybeingreliedupon(suchashavingalocalAboriginalelderintotalk
tostudents).AccordingtotheHTtheschoolwasnotovertlyrespondingtothe
recentSTEMinitiativebytheDepartmentasstaffattheschoolhaveforsometime
beenusingagriculturalcontextstocreateinterestinsciencebasedcareers
(ArtificialInseminationforcattleandGeneticModificationforCanolaseedwere
givenasexamples).
Thesciencefacultyisheavilyinvestedintheschoolsliteracyprogramand
contributesaperiodaweek(asdotheotherthreecorelearningareas)togeneric
literacyactivitiesprovidedbystafffromallfacultiesintheschool.TheHTscience
saidsheislobbyingformorereportwritingtobeincludedintheprogram.
TheHTsaidherprioritywastomaximizeparticipationinscienceinthesenior
school.Tothatendprogramminghadbeenpareddowntofourtopicsayearwith
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titlessuchasBiology7,Chemistry8andPhysics9sothatstudentsknowwhatthe
contentoftheseniorsubjectsiswhentheychoosetheminthesecondhalfofY10.
Thefacultyhasfourassessmenttaskspersemester,twoofwhichareformaltests
(downfrommorethanadozenovertheyearwhenshehadfirstarrived).The
intentionbehindthereductioninassessmenttaskswastoprovidemoretimefor
teachingandshereportedthatsincedoingthat,resultshaveimproved.
Studentsdoaresearchprojecteachyearwhichisallocatedbothschoolandhome
timetobeworkedon.Thisismorethanthesyllabusrequires(itsuggestsatleast
twobedoneinthefour-yearprogram).Noneoftheothercasestudyschoolsrana
majorresearchprojecteachyear.Thestudentresearchprojectsareheavily
scaffoldedtoensurethatatraditionalreportinvolvinganaim,problem,variables,
method,resultsofobservations(tablesandgraphs),conclusion,discussionand
bibliographyisproducedastheexpectedproduct.
Teachingprogramsareorganizedaroundsyllabusknowledgeandunderstanding
outcomesandrelatedcontent.Investigatingandcommunicationskillsare
addressedintherubricsforthevarioustasksembeddedintheprogram.Those
tasksarebothteachingandlearningactivitiesaswellasassessmenttasks.Among
theartifactsprovidedwasaY7taskrequiringstudentstoproduceaposter
showinghowtoseparateamixture(onechosenfromanumberofactualexamples
withintheexperiencesofstudents)andanothertaskrequiringstudentsto
produceawrittenreportonatopic(eghearttransplants)relevanttotheY8
BiologyandSocietytopic.
Teachingandlearningprogramsalsolisttheresourcesavailabletodothetask
whichincludestraditionaltextbooksandworksheets.Acolumnisprovidedfor
teacherstoaddanyadjustmentstheyhavemadetothelistedprogram.Toassist
withthistask,teachersareprovidedwithaonepagesummaryofsuggestionsfor
adjustingteachingtoensurethatstudentshaveaccesstosyllabusoutcomes(see
Figure5.2).
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Assessmenttasksaresupportedbyrubricsthatspelloutexpectedlearningand
howresponseswillbemarked.TheyarebasedontheBoard’sCommonGradeScale
andmarksareawardedinlinewithrubriccriteriaanddiscussedwithstudents.
Collatedmarksareaggregatedandrecordedandteacherjudgmentisusedto
convertmarkstogradesforthepurposesofreportingtoparents.Staffaregiven
timetoworkthroughthecriteriatoensuresomeconsistencyofjudgmentand
subsequentmarkingissharedtofurthersupportthat.
Studentsusenotebookstokeeparecordoftheirlearningactivities.Worksheets
areexpectedtobestuckintotheirnotebookswhichareexpectedtobebroughtto
everylesson.Monitoringofbookworkbyteachersisnotahighprioritybuttheydo
encourageassiststudentstopeerassesseachothersbookwork(seebelow).
Figure5.2Adviceonadjustmentstoteachingtoaccommodatestudentdifferences
EXAMPLES OF ADJUSTMENTS TO TEACHING AND LEARNING PROCESS IN SCIENCE: AMOUNT TO BE COMPLETED:
1. Reduce no of questions / amount to learn. 2. Reduce length of oral presentation. 3. Reduce length of written response / reading. 4. Reduce homework.
TIME 20. Individualise timeline to complete task. 21. Allow extra time to complete task / respond. 22. Allow extra time to use specific equipment.
LEVEL OF SUPPORT 40. Change the amount of personal assistance. 41. Assign peer buddies/tutors. Select role models. 42. Change groupings in class e.g. small / larger
group activities, paired activities. TEACHER INPUT
5. Use visual aids / pictorial directions. 6. Provide concrete examples / hands-on activities. 7. Plan for generalisations/ links to real life learning. 8. Repeat / model / highlight language and important
points. 9. Provide cues & prompts. 10. Simplify language. 11. Pre-teach vocabulary. 12. Specialist teacher input. 13. Provide training & assistance to help student use
specialised equipment. 14. Explicit teaching of skills eg problem solving/social
STUDENT OUTPUT 23. Adapt how learner responds to instruction. 24. Instead of written response – allow verbal. 25. Use of communication device. 26. Focus on hands-on learning. 27. Note-taker / Scribe 28. Use of cloze, matching activities, short answer,
multiple choice, portfolio, technology / computer supported response.
29. Student focuses on own goal within class activity e.g. communication, self-care, health issues, use of Braille.
SKILL LEVEL 43. Allow use of calculator, number line etc. 44. Student responds using assistive technology /
computer software. 45. Simplify task directions –use step by step guide. 46. Break down skill / task. 47. Use of visual glossaries. 48. Provide support staff / peer to help student cope
with each step of skill. 49. Modify or individualise task to match skill level. 50. Assess different skill e.g. ignore spelling and
focus on communication of ideas.
LEARNING ENVIRONMENT 15. Sit student at front of class. 16. Provide separate space in classroom for individual
tutorials. 17. Evaluate & plan for new environments e.g. camp. 18. Support understanding of appropriate when in non-
class environments e.g. social stories 19. Adjust environment to support needs arising from
disability e.g. access for wheelchair.
MATERIALS / RESOURCES 30. Notes provided for student. 31. Use of computer, iPad, etc. 32. Use of disability-specific materials e.g. audio format,
braille, larger font, coloured papers. 33. Talk to text, speech recognition software. 34. Hands-on materials, simplified timetables etc. 35. Vary arrangement on page, size of writing, visuals,
and point form. 36. Captions/subtitles for visual sources.
HEALTH / SAFETY/ SELF-CARE. 51. Monitor / assist with use of communication device,
personal amplification device, specialised equipment, medication, menstruation etc.
52. Liaise with team stakeholders on regular basis to increase participation, check on health/safety.
53. Monitor lunch time activities to support interaction, safety and direct teaching of skills.
54. Programme specific instruction on anger /depression management. Seek counsellor referral
§ CURRICULUM 55. Students work on similar outcomes but simpler concepts. 56. Students work on individualised outcomes while in class e.g student focuses on
listening, social skills, literacy. 57. Teach individualised skills in unit of work e.g. social skills, symbol reading. 58. Plan activities to target student need e.g. group work for communication.
59. Relate outcomes to functional skills. 60. Adjust curriculum to cater for programming required outside of classroom
e.g. community access, supported work experience. 61. Consistently monitor data to support programming feedback. 62. Implement additional support plan such Behaviour Analysis, Sensory
Integration Plan to compliment programming and IEP.
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MCWBE5
Scienceteachersatthemetropolitanschoolpromotedscienceattheschoolby
runningsomeoftheirassessmenttasksas“shows”intheplaygroundatlunchtime
andintheleaduptoNationalScienceWeek.TheScienceFacultyalsoputon
displaysusingstudentsasdemonstratorsattheschool’sannualopennightfor
parentsofprospectivestudents.Highperformingstudentsarealsoinvolvedin
puttingonscienceshowsforstudentsinthelocalfeederprimaryschoolsaswell.
Theschoolhasastrongreputationinthecommunityforscienceaccordingtothe
HTsciencewhichhesupportedbyreferencetoEVstudentsurveyfeedback(see
Table5.11andrelatedanalysis)andresultsfromaY11studentsurveyconducted
bytheprincipal.
TheHT’spriorityforscienceisthatstudentsenjoythesubject.Thewayhesays
thisisachievedisbygivingaprioritytopracticalactivitiesbothinsideandoutside
theclassroomandreducingassessmentpressure.Thescienceprogramtakes
studentsintotheplaygroundandlocalbushfromY7toY10.Activitiesinclude
observationsusingdataloggersandsamplecollectionforfurtherexaminationand
analysisbackinthelab.Also,sciencetakesstudentsawayforday-longexcursions
attheendoftheyeartoTarongaZoo(Y7),PhysicsisFunatLunaPark(Y8)andthe
AquariumatDarlingHarbour(Y9).Learning/assessmenttasksincludemodel
makingandinvestigationsaswellastraditionalpracticaltests,researchtasks,
problemsolvingandcommunicationtasks.
ThesampleprogramsprovidedtomewerewrittenintotheBoard’sprogramming
templateandincludedscienceknowledgeandunderstandingoutcomesand
relatedcontentbutnoneofthesyllabusskilloutcomeswereexplicitlyreferenced
intheprograms.Assessmenttaskswereidentifiedbyatitleandsomeadditional
informationaboutcontentandskillexpectationswasprovidedinthesecond
columnundertheheadingTeaching,LearningandAssessmenttoassistwith
developingcriteriaforassessment.
Thefacultyprogramswereusedbyteacherstoplanteachingprogramsfortheir
classes.Thesampleprogramsprovidedwerebothforfiveweektopics,suggesting
355
thattherewereeighttopicsfortheyear.Progressisreportedseparatelyforthe
topandbottomclasses.Theindependentlearnersandotherclassesareseparately
assessed.Progressforallgroupsisreportedintermsofgrades.Howeverthegrade
referencingisnotdoneusingCoursePerformanceDescriptors.Insteadtheyare
referencedtodifferentcriteriaforthetopclass,theindependentlearnersand
mixedabilitygroupsandthebottomclass.
ThiswasthecaseuptotheendofY8afterwhichclassesarecreatedbasedon
achievementassessedbyacommontestandtaskattheendofY8andprogress
thereafterisreportedintermsofagradeandplaceintheyear.
Artifactsprovidedincludedrubricswithcriteriaforawardingmarks.Thecriteria
includedreferencestosciencesyllabusknowledge,understanding,skillsand
scientificliteracyexpectations.TherewasnoevidencethattheBoard’sCourse
PerformanceDescriptorsorCommonGradeScalewereusedtoassigngradesand
therewasnomentionaboutprocessesusedtoensureconsistencyofteacher
judgmentintheawardingofgrades(forthethreeorfourclasseswherethiswas
relevant).
TherewasnomentionintheinterviewofSOLObeingusedforassessment
purposesanditwasnotevidentinanyoftheartifactsprovided.SOLOwasnot
mentionedinthecontextoftheongoingfacultyprogramreviewthatbeganseveral
yearsagowiththeintroductionofthenewsyllabus.
Inrelationtoclasstasksandtheresearchproject,therewasnoscopeforstudent
choiceinwhattheywoulddoorhowitwouldbepresented.Itwasnotcleartome
whetherthesetaskswereusedbyallclassesoronlythemiddlegroup(excluding
thetopandbottomclasses).
D.Classroomdiscourseandevidenceoflearning
PCWAE2
356
Underpinningtheteachingattheprovincialschoolisacoherentapproachto
improvinggeneralliteracy(astrongschoolpriority)andthescientificliteracy
skillsofstudents.
ThebottomYear7classreceivesextraattentionfromlearningsupportteachers.
Oraldiscussionisacoreactivityandlearningactivitiesarestructuredtoallow
studentstorespondindifferentwaysaccordingtotheirlevelofskill.Marking
rubricsarerelatedtosyllabusoutcomesandrelatedcontentindicatorswhichare
sharedwithstudentsandusedtoinformoralandwrittenfeedback.Inthisschool,
streamedclassesareusedtodifferentiateteachingandtochallengestudentsatall
stagestodobetter.
AccordingtotheHT,thereisastrongemphasisongroupworkandstudentsare
supportedtodothisinproductivewaysthroughroledifferentiationandrotation
ofrolesinpracticalwork.TheHTgaveextendedexamplesofwhatthat
differentiationlookedlikeacrossclasses.Classroomactivitiesaredifferentiatedto
providestudentsofallskillsandcapabilitieswithachancetosucceed.Worksheets
providescaffoldingthatrangesfromclozepassagestoopenendedtaskswhere
explanationsareexpected.Studentsrespondastheycanandareassessedbytheir
teachersaccordingly.
Oraldiscussionistheinitialgotoactivity,butitcanbeusedforpre-testingandto
engagestudentswhohavedifficultyaccessingandconstructingwrittentexts.The
HTusesoralreadingasastrategytogetstudentstoengagewithwrittentext.She
encouragesstudentstostopandaskwhentheydon’tunderstandwhattheyare
readingandsheconstantlyprobestoensureunderstanding.Pausesare
opportunitiesfordiscussionandsharing,buttherearestrictprotocolsobservedin
theprocesstoensurenooneishumiliated.Shearguesthathavinggradedclasses
helpsinthisbecausestudentsintheclasshavesimilarissuesanditiseasierto
managewhenthedifferencesinabilityarenotsomarked.
MCWBE5
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TheHThereisnotsohandsonwithjuniorclassesandspendsmostofhisteaching
timeinseniorphysicsclasses.Hestronglyencouragespracticalactivityinjunior
classesandcommentedthattworecentstaffchangeshavebeenhelpfulinhaving
thatfurtherimplemented.Staffaregivenfreedomtoteachtheirclassesastheysee
fit.
Heexplainedthatassessmentevidencewasbeingtakenfromagreaterdiversityof
tasksnowthaninthepastincludingpracticalexams(stationssetupandstudents
movefromonetotheotherandrecordinaworksheetwhattheyobserveand
find),communicationandproblemsolvingtasks.Communicationtasksinvolve
engagingstudentswithvideosontheschoolIntranetandgettingthemtoprovide
bothoralandwrittenreports.Hewasparticularlyproudofmodelmakingtasks(a
plantcellforY7andatoycarforY8thatgoesfastestorfarthestandplansfora
bungy-jumping“barbiedoll”forY9)becauseoftheopportunitiesitprovidesfor
studentengagementintheassessmentprocess(seelatersection).Modelmaking
andrelatedactivitieshavebeenafeatureformanyyearsinthesciencefaculty.
Thestudentresearchprojects(oneinY8andtheotherinY10)aremostlydone
individuallyandathomeandtheyarehighlyscaffoldedwitharubricprovidedby
teachersthatemphasizesaspectsofscientificreportsandmethod.Little
informationwasprovidedintheinterviewaboutthefollow-uporsupport
providedtostudentswhilsttheywereexpectedtobeworkingonthesetasks.
Theextenttowhichsupportteacherswereusedtoassistlearninginthelowest
classwasnotexplainedininterview.Descriptionsofactivitiesusedbothinandout
oftheclassroomwerereportedandevidencedintheartifactsprovided.
E.Feedback
PCWAE2
Inadditiontotheextensiveuseoforalfeedbackduringclasswork,feedbackon
writtenworkisprovidedtostudentsintheformofticksandcrossestoindicate
aspectsoftasksaddressedwellorinadequately(orincorrectly).Otherfeedbackis
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intermsoftheBoard’sCommonGradeScalethelanguageofwhichstudentsare
introducedtoinclasstaskandassessmentrubrics.Itisusedtoprovidefeedback
tostudentsforbothteachingandassessmentpurposes.Theintentionisthat
studentsareveryfamiliarwithitandcanuseittoself-assessbythetimetheyget
tothesenioryears.
MCWBE5
Teachersareencouragedtoprovidestudentwithadiversityofactivitiesto
supportenjoymentandspontaneityinscience.Agreatdealofprofessional
judgementisexercisedinassigninggradesforreportinginthefirstfewyearsof
scienceattheschool.Thereareeffectivelythreeseparatereportingstreamsbased
onclassplacementsfromprimaryschoolassessmentofstudentability(see
above).Contentcoverageandmisconceptionsencounteredseemtobethebasis
forfeedbacktostudentsratherthanstrictadherencetosyllabusoutcomes.A
creativity/originalitymarkisalsoavailableformodelsthataremadeinclass.
Studentresearchtasksareforthemostpartundertakenindependentlyby
studentsworkingathome.Scaffoldssetoutexpectationsinrelationtodoingthe
activitiesinthetaskswhicharestronglyalignedtothesyllabusworking/
communicatingscientificallyoutcomes.Howteacherssupportstudentsasthey
workonthesetaskswasnotexplained.
TheHTexpressedaconcernthatseniorstudentsdidnotdoverywellintheHSC
extendedresponsequestionsbecausetheycouldnot“writeaparagraph”.Heused
theterm“backwardsmapping”toexplainthatstudentsneededtobetaughtto
writeearlyoninscience.Hewentontoexplainhowhewasactivelyworkingnow
withhisteacherstodomoreaboutthisinY7science.Hereferredtotwoliteracy
programs(TEEECandtheSuperSix)thatinformedthesciencefacultyworkinthis
area.Thisfocusonassessmentforlearningandliteracyappearedtoberecentand
asaresponsetonewschoolpriorities.
HeandhisstaffasfarasIcouldascertainhadnotengagedwiththeextended
responsetasksintheEVprogram,butdidfreelyusetheshortresponseitems.
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F.Activatingstudentsasinstructionalresourcesforothers
PCWAE2
Theresearcherapproachedthisbyaskingadirectquestionaboutopportunities
beingprovidedforpeerassessment.TheHTsaidthatitwasnotaformalpractice
intheearlyyearsofsecondaryschoolsduetostudent’snaturalreticenceandlack
ofconfidencerelatedtolowliteracyabilities.OneactivitythatwasusedbytheHT
wastoengagestudentsinjointconstructiononthewhiteboardofnotes
summarisingsciencework.Year7and8studentsareinvitedtowrite,say,their
conclusiononthewhiteboardandtheclassengagesinteachermanaged
discussiontoreachaconsensusviewonwhatshouldberecorded.
Studentswereencouragedtoworkingroupsonpracticaltasksandsupportwas
providedtoassistinthisprocess.Therewassomepeerfeedbackencouragedon
studentrecordkeepingintheirnotebookstoo.Studentsprovidedeachotherwith
atickedchecklistbasedontheirassessmentofeachother’snotebooks(criteria
werecategorizedaspositivesuchasneatnessandcompletenessandnegative
includinggraffiti,tornpagesanduncorrectedspellingerrors.AtthispointtheHT
spokeaboutthehighabsenteeratesofstudentsandthefactthatsomeofthatwas
duetosuspensionfromschoolforinappropriatebehaviour.Forsomestudents
continuityintheirschoolrecordwasanissuethatshesaidimpactedovertimeon
achievement.Studentinvolvementinassessingbookworkforeachotherwasan
attempttounderscoretheimportanceofhavingacontinuousrecordofworkto
studyfrom.
MCWBE5
TheHTexplainedthatpeerfeedbackonoralpresentationsrelatedto3Dmodels
producedbystudentswasencouragedandsupported.
Someguidancewasgiveninrelationtocriteriathatshouldbeused(evidenceof
sameinartifactsprovided).Theteacherretainedcontroloverthemarkawarded,
buttherewassomediscussionwithpeersaboutwhatthatshouldbe.Hiscomment
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wasthatkidswere,onthewhole,prettygoodatitoncetheyhadthecriteria
providedandtheywereconsistentaswellasfairwitheachother.
G.Activatingstudents(andteachers)aslearners
PCWAE2
Thescienceprogramsintheearlyyearsherewereveryteacherdriven.Students
weregivenfewopportunitiestochoosewhattheystudied.Theycouldchoosefrom
arangeofindustrialprocesseswhenitcametoresearchingseparatingmixtures(a
Y7task)buttheyhadtoproduceaposter.Abiologytopictaskprovidedalistof
threeproceduresthatcouldberesearched,butithadtobepresentedintheform
ofawrittenreport(Y8).Studentresearchprojectsweretightlyconstrainedbothin
topic(seedgerminationforY7)andexpectationsforpresentation(scaffoldforthe
writtenreport).
Intermsofteachersbeingactivatedaslearners,theHTwasfullofpraiseforher
staff(fourfulltimeteachersandonecasualwhowasnotsciencetrained).Shesaid
ofthemthattheywerethe“mostcohesivecollaborativestaff[shehad]ever
workedwith.”Theyhadengagedwillinglywiththetasksinvolvedinredoing
programsforthenewsyllabus,tookonVALID10butfounditwanting,werefully
committedtogettingthebestfromtheirstudentsandengagedfrequentlyin
professionaldialogueonteaching,studentandassessmentissues.Whenasked
aboutwhattheythought“progressioninlearningscience”meant,boththeHTand
soontoberelievingHTwereabletogiveagoodaccounteachusingadifferent
example.TheHTelaboratedusinginvestigationskillsanddescribedhowthat
mightlookfordifferent“ability”students.Bothdemonstratedagood
understandingofdifferentiationinrelationtosyllabusoutcomes.
MCWBE5
TheHTreportedthatinrecentyearstherehasbeenmorewillingnessbystaffto
meettodiscussprofessionalissuessuchasassessment.Therehadbeentimespent
collaboratingonthedevelopmentofnewprogramsaswell.Sampleprogramsfrom
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2013and2016wereprovidedshowingchangesbutitwasnotcleartomewhether
thesewerewrittenbystaffotherthantheHT.Iwasnotprovidedwithspecific
outcomesfromanyofthesereportedrecentmeetings.Artifactsprovidedincluded
thefollowingscaffoldforY7studentstoself-assess(Figure5.3).Thistooappeared
tobearecentinitiative(post2014).
Student Self Evaluation Rate each statement out of 10 This is my best work 10 9 8 7 6 5 4 3 2 1 0 I understood this task 10 9 8 7 6 5 4 3 2 1 0 All criteria have been met 10 9 8 7 6 5 4 3 2 1 0 I am proud of my work 10 9 8 7 6 5 4 3 2 1 0
Figure 5.3 Self-assessment rating scale
H.Comparativesummativecomments
Twothingsstoodoutinthiscomparison.Thefirstwasthestrongfocuson
instructionaimedatimprovingtheliteracyskillsofthestudentsattheprovincial
schoolwhichthesciencedepartmentstronglysupportedintheirscience
programmingandlessondelivery.Therewasapparentlynosuchemphasisatthe
metropolitanschool.Thefocustherewasonengagingstudentswithadiversityof
scienceactivitiesdesignedtoengageandintereststudents.Thegoalatthe
provincialschoolwastopreparestudentsforseniorscienceoptions.
Thesecondwasthehighstakesassessmentpolicythatgradedprovincialstudents
insciencefromtheendofsemesteroneinYear7andmovedstudentsattheendof
everysemesterthereaftereitherupordownaclassifperformancewarrantedit.
Semestertestsforallclassesplayedaroleinthat.However,theattentionto
differentiatedcurriculumdeliverywasmostthoroughlydemonstratedbythe
provincialschoolherecomparedtoalltheothercasestudyschools.The
metropolitanschoolalsoestablishedtwohighachievingclassesonthebasisof
Year6informationaboutachievement(oneclass)anddemonstratedcapacityfor
independentlearning(asecondclass).Bothclassesonceestablishedremained
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largelyunchangeduntiltheendofYear8.Summativeassessmentwaslowkeyand
evidenceoflearningwascollectedfromawiderrangeofactivities.
Inrelationtopredictionone,PCWAE2’sachievementprofilewasmorepositively
skewedtothetopbandachieversthanMCWBE5’s(TableK.1inAppendixJ).The
biaswasmostobviousfortheextendedresponsecomponentoftheEVresults.
Thiswasevidenceoftheeffectivenessofthestrongfocusonimprovingstudents
literacyskillsinthoseearlyyearsofsecondaryschooling.Therewasnoinsight
providedduringtheinterviewabouthowscienceteachersrespondedtotheclass
ofindependentlearnersatthemetropolitanschool.
However,whenlookingatengagement(TableK.5DinAppendixJ),students
reportedverydifferentlevelsofsupportfortheirexperienceofscienceatthe
school.Thelowerachieving(overall)metropolitanschool’stopbandstudents
ratedtheirexperience(ItemsDandEonthestudentsurvey)4thoutof16(the
numberofcasestudyschoolsplusthestatefigurecountedasoneschool)and
abovethestatefigurecomparedtotheprovincialschool’s14thwhichwasbelow
thestatefigure.Takingallthreeachievementbandsintoaccount,attheendof
Year8,MCWBE5studentsranked3rdandPCWAE2studentsranked12thwhich
wasthelowestofallthecasestudyschools.
Engagementwithscienceasmeasuredbytheproportionsofstudentscompleting
Year12sciencecourseswasstrongeratthemetropolitanschoolforthemore
demandingChemistryandPhysicscourses(seeTableK.4inAppendixJ).Both
PCWAE2andMCWBE5(comparedtothestate)hadmorestudentscompleting
Biology(bothhad133%);inChemistry,bothschoolshadaboutthesame
proportionscompletingasinthestate,butMCWBE5hadslightlymorethan
PCWAE2(100%versus89%);inPhysicstheproportionsrelativetothestatewere
slightlybetterforMCWBE5(106%versus81%).IntheSeniorSciencecourse,
morestudentsatPCWAE2completedthecoursethanatMCWBE5(288%versus
192%).However,whenonelooksatthelargenumberofSeniorSciencecourse
completionsattheprovincialschoolcomparedtothemetropolitanschool,either
studentsattheprovincialschoolhadbecomemorepositiveaboutscienceinthe
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twoyearsafterYear8ortheyhadno(orlessattractive)optionstochoosefromin
Years11and12.ScienceisoptionalafterYear10.
PairFOUR:AssessmentnarrativescomparedforMGFSAE2andMGFSWBE1
A.EngagementwithEVfeedback,resourcesandSOLO
MCFSWAE1
TheHTfromthecoeducationalWAEselectiveschool(MCFSWAE1)participatedin
ordertosupportresearchsuchaswasrepresentedbythisprojectandtoprovide
feedbackabouttheEVprogramwhichwassaidtobea“highquality”program
becauseitstasksanditems“sethighexpectations”and“provideabasisfor
discriminatingbetweenresponsesfromhighabilitystudents”.Scienceteachersat
thisschooluseitemsandtasksfromtheEVtestsintheirownassessment
programsbutdonotuseSOLO-basedrubricstoassessresponses.Theschoolisnot
planningtotakeupVALID10.Studentsurveyresultsarenotlookedatnor
discussedwithstafforstudents.TheHTthoughtthatthetestprovidedquality
feedbacktoteachersand“liked”thatitwasmandatory.
TheHTsaidthatstudentsenjoyeddoingthetestonlineandtookitasseriouslyas
theydidNAPLAN.Someevenusedtheirowndevicestodothetest.Nospecial
preparationforthetestisundertakenapartfromregistrationandworking
throughthesampleitems.Therehasbeennofeedbackfromparentsaboutthetest
orresults(whengiventoparents)anditreceivesnoattentioninannualschool
reports.Theprincipaltakesaninterestintheresults.
MGFSAE2
TheHTatthegirlsAEselectiveschool(MGFSAE2)participatedtofindoutmore
aboutSOLO.TheHTreportedthattheschool’sscienceassessmentprogram
involveda“SOLObasedapproachtoassessment”byprovidingstimulusmaterial
withtestitems.SOLO-basedrubricsareincreasinglybeingusedtomarkresponses
totasksandtoinformfeedbacktostudents.Itwasreportedthatmostofthestaff
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attheschoolsupportSOLOasabasisfortheirownprofessionallearningandfor
itsusefulnessinassessingstudent’swork.
EVfeedbackisdiscussedatthetimeitisprovidedtotheschool.TheHTdoesan
analysisofachievementtoidentifystrengthsandweaknessesoverallandbetween
classesandthisanalysisisdiscussedwithstaff.TheHTreportedthatEVresults
informteachers’ongoingdevelopmentofteachingprogramsandteacher
assessmentofstudentwork.
Thegirlsenjoydoingthetestonlineandtakeitseriously.Someusetheirown
devicestodothetest.StaffwillcontinuewithVALID10andareinterestedinthe
feedbackonstudentgrowthfromY8toY10,particularlyinrelationtomiddleband
students(onlyoneortwostudentswereassessedaslowband).
TheHTdescribestheSOLOrubricasaboutrewardingstudentresponsesthat
showappropriate“connections”betweenscienceconcepts.Differencesbetween
SOLOmarkingandBoardmarkingweredescribedtomebutwerenotseenas
problematic.TheHThadcompletedtheproformaandacknowledgedthatshe
foundtheresponsestothestudentsurveyconfrontingbutuseful.Theconcernwas
thatstudentattituderesponseswerebelowstatefiguresbutnoimmediate
thoughtsabouthowtoimproveattitudeswereoffered.TheHTnominateditemsF
&E(fromthestudentsurvey)asthemostusefulfeedbackfromtheperspectiveof
sciencefacultypriorities…thatstudentslearntheirscienceandenjoyit.
MGFSWBE1
TheheadteacherfromthegirlsWBEselectiveschool(MGFSWBE1)participatedto
provideaprofessionallearningsessionforscienceteachersaboutassessment.My
projectalignedwiththefocusattheschoolandinscienceonassessmentfor
learning.Anexternalconsultanthadbeenemployedtoimprovetheir
understandingof“differentiatingassessment”andhowtoobtainandbetteruse
assessmentdatatoimproveteachingandlearning.ScienceteachersuseEV
stimulusandrelateditemsandextendedresponsetasksintheirassessment
programbutrubricsthatreflectsyllabusintentionsratherthanSOLOthinking
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levelsareusedtoassessstudentachievement.ThestaffviewofSOLOwasthatthe
testitemsandtasksbringcontextandskillstogethersothatresponsescanbe
assessedtorevealdifferentlevelsofthinkingusingsciencecontentknowledge.
Staffwerecriticaloftheircurrentteststhatfocusedverymuchontheacquisition
ofknowledgeandunderstandingandtheyacknowledgedthattheydidnot
sufficientlydiscriminatebetweenlevelsofachievement.
SomescienceteachersreportedthatstudentsdidnottaketheEVtestseriously
becauseresultsarenotcountedinassessment.BycontrastNAPLANistaken
seriously.Teachersreportedthatstudentswere“stressed”becausetheywerenot
suretheschool’scomputerswouldworkandthatEVtestquestionsweredifferent
tothoseinothersciencetestsdoneattheschool.Theschoolplanstocontinuewith
theVALID10programandseevalueincontinuingtheirlearningaboutSOLO.
B.Groupingforinstruction
IntheWAEschool,studentswiththeweakestliteracyresultsareallocatedtoone
class.IntheAEschool,studentsareputintoclassesonthebasisoftheirchoiceof
foreignlanguagetobestudiedandintheWBEschool,theytrytospreadstudents
fromfeederOCschoolsacrossthefiveclassesformed.Thisisdonetoprovideall
studentswiththeopportunitytobroadentheirfriendshipbase.ThusY7classesin
allthreeschoolsareeffectivelymixedabilityclassesfromtheperspectiveof
science.
Essentially,allthreeschoolsretainthesameclassesfromYears7to10.An
exceptiontothisgeneralapproachisfoundintheWAEschoolwherestudentswith
exceptionalresultsareinvitedtojoinagiftedandtalentedclasswhichis
establishedfromY8.Acceptanceintotheclassisconditionalonthestudents
agreeingtodochemistryinthesenioryears.Theclassisacceleratedbutnodetails
wereprovidedastowhatthatmeant.
C.Useoflearningintentionsandsuccesscriteria
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MCFSWAE1
TheHTatthecoeducationalWAEschoolreportedthattheschoolplacedahigh
priorityonliteracy.Extraassistanceisgiventotheoneclasswherestudentswith
weakerliteracyskillswereplaced.TheHThasexpertiseinliteracyandan
emphasisonliteracyskillsisevidencedintheartifactsprovidedtome.TheHT
reportedahighsciencefacultypriorityforteachingscientificliteracyskillsvalued
intheworldbeyondschool,forteachingcriticalthinkingratherthanrotelearning
andforgreaterstudentengagementwithscienceatschoolandbeyond.
Twotopics,oneeachfromY7andY8,fromschoolprogramprovidedtome
demonstratedthepriorityforskilldevelopment.Theprogramorganizedcontent
intofivecolumns,thefirstdescribedcontent(sciencecontextsandcontenttouse
andlearn),thesecondskills(whatstudentsweretodowiththatcontent/the
thirdcontainedreferencestopagesinasciencetextbook),afourthincluded
referencestofacultyandotherresourcesrelevanttotheactivities.Afinalcolumn
listedinsyllabusoutcomesshorthand(e.g.SC4-CW-2e/WS6.3-6.4AB8)provides
thelinkbetweenschoolactivitiesandsyllabusintentions.TheY7programtopics
in2012numbered16.From2015thiswasreducedto13,theyearaftertheperiod
ofinterest.
Learning/assessmenttasksareaccompaniedbymarkingrubricsshowingingreat
detailhowmarksaretobeallocated.OneY7literacyassessmentprovidedtome
targetedthewritingofscientificexplanations.Themarkingcriteriaforthefive
relatedtasksinthatassignmentallocatemarksforcompletionofaspectsofthe
taskaswellasformoresophisticateddemonstrationsofthoseaspects.Figure5.4
showspartoftherubricforthatassignment.Thesuccesscriteriaappeartobe
derivedmostlyfromsyllabusintentionsbuttheyalsoincludeliteracycriteriaas
well.
Task 4 Re-writes two paragraphs in own words and uses the scaffold for structuring each explanation
Identifies the phenomenon being addressed in the first paragraph /1
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Employs the explanation sequence, and, as appropriate: “action verbs, technical words, time connectives, cause-and-effect connectives” in order to explain the phenomenon /2
Identifies the phenomenon being addressed in the second paragraph /1
Employs the explanation sequence, and, as appropriate: “action verbs, technical words, time connectives, cause-and-effect connectives” in order to explain the phenomenon /2
Total /6 Task 5 Identifies the following language features of the text for one of the explanations and uses the correct symbol in so doing
action verbs /1
technical language or terms /1 time connectives when /1 cause-and-effect connectives As a result /1 Total /4 Figure 5.4 Sample marking criteria for scientific explanations (part only)
MGFSAE2
TheHTattheAEgirlsselectiveschoolsaidthatthefacultyprioritiesforjunior
secondaryscienceweretopreparegirlsforacareerinscience,toensurethey
werescientificallyliterate,abletocreativelyproblemsolveandtoenjoyplanning
andconductingscientificactivities.LearningprogramsforscienceinYears7-10at
thisschoolwereorganizedinto4X10weektopics.Eachtopicwascomprisedof
activitiestobecompletedbystudents.Theactivitiescombinedsyllabuscontent
andsyllabusdefinedskills.Theoverallassessmentplanshowedthatbytheendof
theyearstudentsoverallgradewouldreflecttheacquisitionofbothskillsand
knowledgeandunderstandings.
TheactivitiesforaY9topictitledTheComplexHumanwereorganizedinto
“booklets”andrelatedscaffoldsdirectedstudentstoworkingroupsandto
individuallyrecordspecifiedoutputsfromthoseactivities.Thisappearedtobea
modelforteachingandlearningsciencethathadbeeninplaceforsomeyears.The
scopeoftheactivitiesIreviewedintheartifactsprovidedwereconsistentwith
syllabusexpectationsforknowledgeandunderstandingandskillsforStage5
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students(topicsinmostnonselectiveschoolsvisitedtargetedY8orStage4
content),butsomeoftheactivitieswentbeyondthat.
Outputstobeprovidedincludedtheconstructionoftables,graphs,procedures,
riskassessments,descriptions,explanations,generalisations,conclusionsand
justifications.Assessmentrubricstobeusedbyteacherstoscorethetasks
describedthefeaturesofoutputstoberewardedwithmarks.Thefeatures
describedforrewardwerebothindicatorsofbreadthofcoverageanddepthof
understanding/levelofskilldemonstrated.
AlsoaSOLObasedscaffoldwasprovided.Thescaffoldwasbeingtrialedwith
schoolintranetsciencequizzes.ItwasbasedonSOLOleveldescriptorsfor
comparisonwithstudentoutputstoselectedactivitiesthemselvesbasedon
contentintheschool’sY8program.
Thesciencefacultyassessmentpolicydocument(providedwiththeartifacts)
describedtheprocedurestobefollowedwhenmarksweretransformedinto
gradesforthepurposesofreportingtoparents.Theseappearedtobeconsistent
withBOSCommonGradeScalerequirements.
AsampleStage4activitytitledEnergytranformationsincludedamarkingrubric
thatcollatedmarksfortwocomponentsofthesyllabusworkingscientifically
strand(planningandconductinganinvestigationandprocessingandanalyzing
dataandinformation).
TheY9studentresearchprojectbookletprovidedincludedthestepstobe
followedinthedevelopmentofaproposalforresearch,includingopportunitiesfor
feedbackfromteachers,Turnitinsoftwareandstudentpeers(seeFigure6.3)and
assessorsfromthescientificcommunityataschoolbasedevent.Studentswere
encouragedtosubmittheirprojecttotheSTANSWYoungScientistsCompetition
aswell.
MGFSWBE1
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TheHTfortheWBEselectivegirlsschoolexplainedthatoneoftheschool
prioritiesfortheyearwasassessmentforlearningandthatanexternalconsultant
hadbeenemployedtoprovideprofessionallearningtoteachers.Scienceteachers
hadattendedworkshopsprovidedbytheconsultant.
Thesciencefacultyprioritiesincludedworkingontheirassessmenttasksto
improvetheirquality,movingthegirlsfromrotelearningandmemorizingto
thinking,improvingtheirscientificliteracy,buildingtheirunderstandingofthe
roleofscienceinsocietyandencouraginggreaterlevelsofenthusiasmforscience.
Thesciencelearningprogramprovidesforfourtopicsperyear.Nosample
programswereprovided.TheassessmentschemesforeachofYears7-10were
provided.Therearefourformalassessmenttasksperyear.Eachtaskprovidesfor
afinalequallyweightedassessmentofknowledgeandunderstandingandworking
scientificallyoutcomesexpressedasagrade.Thesyllabusoutcomestargetedby
thetaskareprovidedinfullaspartofthetasknotification.Therubricforassigning
markswasincludedwiththetasksandthelinksbetweenmarksandgradeswas
alsoprovided(fromYear8onwards).TheBOSCommonGradeScaleappearedto
bethebasisfortheawardofgrades.
Y7tasksincludedaformaltest,ataskinvolvingdevelopingagame(across
curriculumproject…seenextparagraph),amulti-mediapresentationanda“VALID
Styletest”.InY8thetasksincludedapracticaltest,amid-coursetest,astudent
researchprojectanda“YearlyExamVALIDstyle”.
TheY7gametaskprovidesopportunitiesforstudentstodemonstrateoutcomes
fromtheArtandPDH&PEandSciencesyllabuses.Themultimediataskinvolves
studentsinpeerassessmentofgroupwork(seelatersectiononfeedback).
AY8“VALIDstyletest”wasprovidedinthesetofartifacts.Theshortitemsinthe
testweresimilarinformattothoseusedbytheBOSinitsexternaltests(bothpast
andcurrentones).EVteststypicallyprovideastimulustextandarelatedsetof3-5
itemsaboutthattext(Appendix1.XincludesanEVtestbooklet).Extended
responsetasksfrompreviousEVtestswereappropriatedintotheirtestsalso,but
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theresponsescaffoldsweremodifiedtoconformwithBOStestformats.Therewas
noevidenceprovidedthatSOLOconceptswereusedtomarkresponses.
StudentsalsosittheICASsciencetests.Resultsarenotusedbytheschoolfor
diagnosticpurposes.Certificatesarepresentedtostudentsasanaffirmationof
theirhighrankinginthestateforachievementofthefivesetsofscientificskills
assessedbythetest.TheHThaddeclinedanofferfromtheEAAteamtoshow
scienceteachersattheschoolhowtousetheteststotrackschoolandindividual
progressusingtheresults.
D.Classroomdiscourseandevidenceoflearning
MCFSWAE1
TheassessmentnarrativefortheWAEselectiveschoolrevealsthatstudentsin
theirfirsttwoyearsofscienceareprovidedwithlearningactivitiesbasedheavily
oftextbook,classroomworksheetsandconventionalschoollaboratoryactivities.
Theprogramsprovideddescribeactivitiesthatcombinebothscientificskillsand
content,includingopportunitiesforstudentstoplananddesignthelaboratory
activities.Thereissomeevidenceintasksandtestsprovidedthatsciencerich
contextsinlinewithsyllabusexpectationsareprovidedasastimulusforteaching
andassessmentactivities(consistentwiththeEVassessmentmodelofproviding
stimulusmaterialandagroupofrelateditemstheresponsestowhichare
dependentoncomprehensionofthetextinthestimulusmaterial).
Excursionsarerareandsciencevisitorstotheschoolareonaninfrequent“adhoc”
basis.Scienceteachersdonotappeartomakemuchuseofresourcesbeyondthe
classroomtoenrichtheirteaching(suchastheschoolgroundsorlocalcreeksand
reserves)orengagetheirstudentsinscienceinvestigationssponsoredbyexternal
agenciessuchasBHP,RioTintoortheYoungScientistCompetition(runbythe
ScienceTeachersAssociationofNSW).ICTusebyscienceteachersisnotastrong
componentintheteachingofscienceattheschoolaccordingtotheHT.National
ScienceWeekisnotexploitedforitscelebrationofscience.ICAStestsofscience
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thinkingprocessesaremandatorybutnoattemptismadetousetheresultsother
thantoaffirmthehighcompetenceofthestudents.
TheHTsaidthatgroupworkisnotactivelytaughtintheearlyyearsofscience
educationatthisschool.Thefirstmajorresearchprojectwhichthesyllabus
describedasanopportunityforgroupworkisanindividualproject(usingplants)
forY8studentsatthisschool.NoartifactsrelatingtotheStudentResearchProject
(SRP)wereprovided.
Literacybasedtasks,formaltests,writtenassignments,researchprojectsand
practicaltasksappeartobethemostvaluedsourcesofevidenceforscience
learning.PracticaltestsareintroducednoearlierthanY9asaresultofstudentsin
Y7&8beingstressedbythenoveltyandcomplexityoftheseassessmentswhen
theywereintroducedthereanumberofyearsago.
StudentsatthisschoolinYears7and8arefrequentlyaskedandgivensupportto
writescientificexplanations.Also,theyarechallengedtousethoseskillsintasks
wellbeyondtheireverydayexperience.AnexampleprovidedisaY9task(first
introducedin2013?)wherestudentsareasked,asascientist,toprepareresources
includinga3DmodelthatcouldbeusedinathreeminuteTEDpresentationto
evaluatestrategiesbeingusedtoreduceozonedepletion.Actuallyusingthe
resourcesinapresentationwasnotrequired.
MGFSAE2
TheartifactsprovidedbytheHTattheAEgirls’schoolrevealthatteachingatthe
girlsschoolsprovidesmanystructuredopportunitiesforthegirlstowork
cooperativelyonawidevarietyoftasks.Thegirlsareencouragedtodiscussthe
resultsoftheseactivities,accordingtotheHT,withboththeirteacherandpeers
beforerecordingwhattheyhavelearned.Thestructureofthesetofactivities
providesapathwaythatthegirlscanfollowattheirownpaceratherthanoneset
bytheteacherwhoisfreedupfrompresentingtotheclasstobeingabletowork
withsmallgroupsoroneononewithstudentsneedingsupport.Thusevidenceof
learningisprovidedtoteachersinthecourseofinformaloraldiscussionsand
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formallyviathetextsproducedinresponsetopromptsprovidedbytheactivity
scaffold.
MGFSWBE1
TheHTattheWBEgirlsschoolonlyprovidedexamplesoftheassessmenttasks
usedattheschool.Theseartifactscombinedwithanswerstoquestionsprovided
byboththeHTandteachersattheschoolrevealedawillingnesstoworkoutside
thesciencefacultywithotherfacultiesandtoprovideexcursionstosciencerich
environmentsincludingthezooinY7,ashorelineenvironmentinY9andthe
PowerhouseMuseuminYear8.
Therewassomementionofastrongcommitmenttoprojectbasedlearningin
previousyearswhichisnowconfinedtotheSRPinY8andacrosscurriculum
projectinY7(mentionedabove)toproduceagamethataddressesoutcomesfrom
Art,PDH&PEaswellasscience.
Teacherwillingnesstoworkbeyondthescienceclassroomprovidesopportunities
fordevisingauthentictasksthroughwhichtobothteachscienceandtoassess
whatwaslearnedaccordingtotheHTscienceattheWBEgirlsschool.Teachertalk
attheinterviewaboutthetasksusedandthevariousformsofevidenceofthat
learningincludingstudentpresentations,models(agamewithsciencecontent)as
wellasmoreconventionaltests,assignmentsandstudentresearchprojectreports
describesthebreadthofactivitiesusedtoteachandassessevidenceoflearningat
theschool.Inthejuniorsecondaryyears,theredoesnotappeartobeastrong
focusonimprovingstudentwritingskillsinthecontextofsciencebeyond
addressingtheconventionalsectionsofatraditionalschoolscientificreportwhich
isthecommonassessmenttaskforTerm3inY8.Thereappearstobelittle
evidenceofteachingtohelpstudentsdeveloptheexpressivelanguageskillsusing
scientificvocabularypriortothat.Thereportwasconstructedbystudents
workingwithinahighlystructured,teacher-providedscaffold.
Whilstthestudentresearchprojectinvolvesgroupwork,nopersuasiveevidenceof
formalteachingintheskillsofgroupworkwaspresented.Tworubricsfor
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assessingthetaskandrelatedreportareprovided.Onetoteachersandasecond
onetostudentswhichtheyusetoselfassess.Bothrubricsappeartobemodeled
ontheBOSCommonGradeScale.Onlythreegradesarepossible(A,BorC)which
appearstobebasedonthehistoricevidencefromYear10externalsciencetesting
thatendedin2011andperhaps(butnotstatedanywhere)thepatternoflevels
awardedintheEVresultspackage.Itwasnotclearhoworwhetherstudentswere
coachedintheuseoftheirself-assessmentrubric.
E.Feedback
MCFSWAE1
TheHTatthecoedschoolstatedthatscienceteachersattheschoolprovide
considerableinformalfeedbacktostudentsinthenormalcourseofdaytoday
teaching.Theyalsoprovidestudentswithformalfeedbackonperformanceintests
andtasksona“lookandlisten”basis(mycharacterisation).Studentsareprovided
withthetest/taskandtheirindividuallyteachermarkedfeedbacksheets.Awhole
classpresentationismadebytheteachertotheclassabouttheoverallstrengths
andweaknessesinresponses.Studentsarethenexpectedtoreflectontheir
individualfeedbackintheirowntime.
Teachersrecordmarksawardedfortests/tasksandtheyareconvertedtogrades
forthepurposeofreportingtoparentstwiceayear.Noinsightsabouthowthe
conversionwasdonewasprovidedandnoevidencewasprovidedthattheBoard’s
CommonGradeScale(orSOLOlevelsforthatmatter)wasthebasisforthat
conversioneither.Noevidencewasprovidedthatstudentsaregivenaccessto
syllabusoutcomesortheBOSCommonGradeScaleintheearlyyearsofsecondary
school.ReportinguptotheendofYear9wasintermsofgradesonly.Placeinthe
yearisprovidedinYear10aswellasgrades.
MGFSAE2
Theactivity“booklets”usedbytheAEschoolprovidemoretimefortheteacherto
workwithstudentstoprovidefeedbackonindividualissuesastheyarise.The
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growinguseofSOLOprovidesanotherdimensiontothetypeoffeedbackateacher
isabletoprovideaswell.
MGFSWBE1
TheHTscienceattheWBEgirlsschoolprovidedtherubricsusedtoconvey
feedbacktostudentsabouttheirlearninginthefourformalassessmenttasks.That
feedbacktooktheformofmarksassignedaccordingtowhatappearedtobe
syllabusbasedcriteria.AccordingtotheHTscience,consistencyofmarkingwas
ensuredbydiscussionofrubricsandsampleresponsesatmeetingsofrelevant
teachersconvenedbythesciencecoordinatorsforeachYeargroup.Markswere
subsequentlyconvertedtogradesforthepurposeofreportingusingaversionof
theBOSCommonGradeScalemodel.
F.Activatingstudentsasinstructionalresourcesforothers
MCFSWAE1
TheHTscienceattheWAEschoolacknowledgedthatmakingthemostof
groupworkandtherangeofstrategiesassociatedwithit(suchasthink-pair-share
andreportactivities)wasnotahighpriorityamongstscienceteachersatthe
school.Norwasanyevidenceprovidedaboutopportunitiesstudentshaveto
providefeedbacktopeersabouttheirperformanceorachievement.
MGFSAE2
Discussionwithpeersinthecontextofgroupworkisstronglysupportedby
teachersattheAEschoolaccordingtotheHTsciencethere.Informaldiscussion
providesopportunitiesforjointconstructionwithpeersofresponses,individually
recorded,tothediversityofrequiredoutputspresentedtostudentsintheactivity
“booklets”.ThereisaformalopportunityattheAEschoolinY9forstudentsto
providefeedbacktopeersaboutthequalityoftheirreportsandrelated
explanationsintermsofspecificsuccesscriteria(Figure5.5).
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Figure 5.5 Peer assessment scaffold for a Y9 task at the AE school
MGFSWBE1
AttheWBEgirlsschool,theoneformalopportunitytoprovidefeedbacktopeers
usingaskillbasedgenericscaffold(Figure5.6)wasmediatedbytheclassteacher
whowouldonlypassitonifhe/sheapprovedthecontents(thepersonmakingthe
assessmentwasanonymous).Itwasnotclearwhethermorethanoneteacher
(whorespondedtothatquestionveryconvincinglyattheinterview)used
groupworktoprovideopportunitiesforstudentstoactasinstructionalresources
fortheirpeers.
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Thetopicforthepresentationwasanimalclassificationandanexcursiontothe
zoowasinvolved.Informationcollectedtherewasexpectedtobeusedbackat
schooltoprepareanddeliveramultimediareporttotheclass.
Itwasnotclearabouttheextenttowhichthiswas/isusedandforhowmanyyears
itmayhavebeenused.
Thestructureofthestudentpresentationwasorganizedusingateacherprovided
scaffoldthatdoubledasarubric(fortheteachertouse)toassignmarksfor
aspectsofthegroup’spreparationandpresentation.
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Figure 5.6 Peer assessment rubric for Y7 multi-media presentation task
G.Activatingstudents(andteachers)aslearners
MCFSWAE1
Manyopportunitiesareprovidedtostudentsinthecoedschoolinthejunior
secondaryyearstodevelopgoodlearningbehavioursinthecontextoflaboratory
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basedactivityworksheetsthatsupportthedevelopmentofskillsin
comprehension,analysis,evaluationandjustificationofchoices(usingexpressive,
oralandwrittenlanguage).
Inrelationtoteachermodelingofgoodlearningbehaviours,theHTreportedthat
thesciencefacultymeteverytwoweeksandthattheagendaofteninvolvedshared
professionalworksuchasdevelopmentofprogramresources,assessmenttasks,
markingrubricsandjointmarkingofstudentwork.Therewasnomentioninthe
interviewsabouthowteachersworkedwiththeirclassestohelpstudentsachieve
controlovertheirlearningapartfromtheirworkwithlanguageskills
(explanations).
MGFSAE2
TheuseofapeerassessmentscaffoldbystudentsattheAEgirlsschoolas
describedintheprevioussectionprovidesteacherswithameansforpromoting
goodlearningbehavioursinallstudents.Theskillofassessingyourownwork
againstcriteriaisanimportantsteptoself-regulatedlearningorlearninghowto
learn.Ifyoucanrecognisegapsorweaknessinyourownwork,thenyoucan
devisestrategiestoaddressthem.Thetimetakentoexplainhowtodothatself-
assessmentisanexampleofteachersmodelinggoodlearningbehaviours.
TheembracebyscienceteachersattheAEgirlsschoolofSOLOandtheir
preparednesstoworkwithittoimprovetheirownprofessionalcompetenceand
thelearningoutcomesforgirlsattheirschoolwasalsoevident.
MGFSWBE1
Oneconcreteexampleofsupportforself-assessmentwasprovidedbytheHTat
theWBEschool.Inthecontextoftheirstudentresearchproject(Task3,Term3of
Year8)studentsareprovidedwiththerubricteacherswouldusetoassessthe
planfortheirinvestigationandencouragedtouseitforthemselvespriorto
submittingtheirproposal.Itwasnotcleartomewhetherthishadbeenused
earlierthanlastyearoncethenewprogramshadbeenputinplace.
379
AccordingtotheHT,scienceteachersattheWBEschoolmeetregularly.Someof
themeetingsaredevotedtocollaborativeworkonprogrammingbutmore
recentlyondevelopingbetterassessmenttaskstoimprovethequalityof
informationaboutstudentlearningincludinghowtobetterdiscriminatebetween
achievement.NoevidenceofsupportforandusebyteachersoftheSOLOmodel
wasmentionedintheinterviewapartfromtheappropriationofextended
responsetasksforuseintheirowntestsmodeledonBoardformats.
H.Comparativesummativecomments
Comparisonsbetweenthesethreeschoolsarefraughtbecauseoftheirdifferences
inSEAscoresandbythefactthatoneisacoeducationalschool,theothertwogirls
schools.Ontheassumptionthatgenderdifferencesarenotstatisticallysignificant,
atleastinthefirstfewyearsofsecondaryschool(PISAandTIMSSresultsfor
Australiasupportthatconclusion),itisveryobviousthatattheendofYear8,the
comprehensiveschoolisdoingbetterintermsofachievementandengagement
thaneitherofthetwogirlsschools.ThefocusonwritingattheWAEandAEschool
showsupinthelowerextendedresponsescorefortheWBEschool,despitethem
doingbestinthecommunicatingscientificallycategoryofresults(seeTableK.1in
AppendixJ).
IntermsofengagementattheendofYear8,theWAEfullyselectiveentryschool
rankedabove(8th)theothertwofullyselectiveentryschoolsintermsofstudent’s
enjoymentoftheirschoolscienceexperience(seeTableK.5DinAppendixJ).
StudentsattheAEschooldidnotenjoytheirscienceexperiencecominginatthe
bottomoftherankings16thbytopstudentsonItemsDandEcombined.TheWBE
schooldidbetterat13th.
PairFIVE:AssessmentnarrativescomparedforPCWAE2andPCWAE3
ThenarrativeforPCWAE2waspresentedaboveinthecontextofpairTWO.Thus
onlytheinformationforPCWAE3willbeprovidedhere.
A.EngagementwithEVfeedback,resourcesandSOLO
380
Onlytheheadteacherattendedtheinterview.Participationwasonthebasisof
wantingtoknowhowtheyweredoingintermsofassessmentpracticeswhichhe
didnotthinkwereanydifferenttootherschools.Theschoolhadnotdone
VALID10in2015andhadnoplanstodosogoingforward.Thereasongivenfor
thatwasconsistentwithpolicydecisiontokeepformalassessmentstoaminimum
andmanageinalowkeywaybecauseofitsperceivednegativeimpactonstudents
motivationtolearn.TherewasalargeIndigenouspopulationattheschool(the
largestofthethreeWAEprovincialschoolscomparedhere)andtheSEAscorewas
verylow.TherewasnospecialpreparationfortheEVtestwhichhereported
studentsenjoyeddoing.Noparenthadaskedaboutthereportonresultswhenit
wassenthome.Theproformahadbeencompletedfortheinterviewand
assessment-relatedartifactswereavailableaswell.
B.Groupingforinstruction
Theschoolestablishes4-5classesinYear7eachyeardependingonnumbersfrom
feederprimaryschools.Classesarestreamedonthebasisoffeederschool
achievementandotherdata.Whilstnotgradedfromascienceperspective,thetop
Year7classreceivesamore“challenging”programinsciencethanisprovidedfor
theotherclasses.Thebottomclassreceivesadditionalsupportfromlearning
supportteacherswhoworkwiththescienceteachersintheclass.Theseclasses
arelargelyretainedgoingintoYear8withsomechangesbasedonendofyeartest
resultsand“behaviour”issues.
C.Useoflearningintentionsandsuccesscriteria
Learningprogramsarebasedonsyllabuslearningintentions(outcomesand
relatedcontent)andtraditionalcontentorganisers(IntroductiontoLaboratory/
Forces/Solids,LiquidsandGases/Earth,SunandMoon/Skills—Preparationfor
theSRP/CellsandClassificationandWorkingwithNaturearethetopicheadings
forYear7).The2nd,3rd,5thand6thtopicseachhave7weeksallocatedtothem.The
lasttopicincludesafocuson“patternsinnature…respirationand
photosynthesis…ecology…plantsystemsandstructuresandhuman(fire)and
naturaldisasters…scientificandindigenousknowledgetoextractresourcesfrom
381
theenvironment.”Manyoftheactivitiesassociatedwiththetopicsareliteracy
focused(correctuseofappropriatevocabulary…adaptationnotadaption)and
separatepageslistspellingandotherliteracyresourcesforeachtopic.Eachtopic
hasspecificassessmenttasksandthereisacommonassessmenttaskeachterm
(fourinayear).Theredon’tappeartobeanyformalexamsortests.Thepriorityis
forstudentengagementandenjoyment.Studentsareprovidedwithadiversityof
activitiesusingawiderangeofresourcesfromwithintheschoolincluding
Agriculture,whichsciencemanages.Studentsvisitalocalsciencefaireachyear.
Relevanceisimportant(egdiabetesinthecontextofworkondisease).The
studentsdoamajorresearchprojecteachyearwhichisdonemostlyinclasstime.
Textbooksandworksheetsareimportantcomponentsofclassroomwork.Students
useschoolICT,butitisnotalargepartoftheirwork.
D.Classroomdiscourseandevidenceoflearning
Classdiscoursefocusesexplicitlyonsciencelanguageuseincludingoral(first)and
thenwrittenwork.Researchprojectsarescaffoldedtohelpstudentslearnthe
componentsofascientificreport;thescaffoldingisprogressivelyreducedfrom
Year7toYear10.Writtenresponsestocommonassessmenttasksisanimportant
componentoftheassessmentdecisionsandsubsequentreportingtoparents.
E.Feedback
Thisislargelyprovidedbytheteacherinthecontextofwholeclassdiscussion
(oral)andtoindividualsandsmallgroupsduringpracticalworkinthelab.
Studentsareprovidedwithfeedbacksheetsfromcommontasksandadviceasto
howtheywentintermsofgradesbasedontheBoard’scommongradedescriptors.
F.Activatingstudentsasinstructionalresourcesforothers
PeerassessmentwasnotapriorityforYears7and8.Therewassomeuseofthink-
pair-share-reportstrategy,butnotwidespread(accordingtoHT).Groupworkwas
encouraged,butnoevidenceofteachingstudentstheskillsofworkingingroups
wasprovided.
382
G.Activatingstudents(andteachers)aslearners
Thefocuswasonteachermanagedlearning,studentswerenotgivenopportunities
togeneratelearningexpectationsorsuccesscriteria,butinfeedbackontests,
someteachersexplainedhowfeedbackcouldbeusedtoimprovelearning.The
teachersattheschoolmodelledgoodlearningbehavioursinclassandwitheach
otherinmeetingstodiscussanddevelopassessmentcriteriawhichwerethen
usedindividuallytoassesstheirownstudents.Incommentaryontheproforma,
theHTsawtheconnectionbetweenlikingscienceandbetterresults.
H.Comparativesummativecomments
PCWAE2andPCWAE3hadmuchincommon.Theyhadrelativelylargenumbers
(comparedtoPCWAE1)ofindigenousstudents.Thetwoschoolssetupgraded
classes,butbothproducedevidenceofdifferentiatedteachinginresponseto
studentskills.Amajordifferencebetweenthetwoschoolswastheapproachtaken
tosummativeassessment.LikeMCWBE5(theschoolcomparedtoPCWAE2
above),PCWAE3hadalowkeyapproachtosummativeassessment.
AttheendofYear8,predictiononewassatisfiedintermsofbothachievementand
engagement(theextendedresponsedifferentialindicatedthatPCWAE2wasthe
moresuccessfulintermsofteachingwritingskills).
PredictiontwowasabouttheextrapolationofresultsfromYear8toYear10.The
evidenceofresultswasnotdirectlycomparable,buttheindicationherewasthat,
despitePCWAE3havingahigherproportionofitsstudentsabsentonanydayfrom
Years7to10(seeanalysisinChapter5)thanwassoatPCWAE2,theirY10result
patternwasbiasedslightlymoretothehighergradesthanPCWAE3’sresultswere
(seeTableK.3inAppendixJ).
Intermsofpredictionthree,PCWAE2hadproportionatelymoreofitsstudents
completingsciencecoursesattheendofYear12whencomparedtoPCWAE3
(relativetothestatenumbers).ThemostmarkeddifferencewasinBiologywhere
383
thedifferencewas133%versus67%).Again,thisfindingneedstobequalifiedby
unknownsaboutschoolresourcesandstudentdemandforseniorsciencecourses.
384
AppendixI:Datatablesforpairedschoolcomparisons
Table K.1 Achievement results for comparable school pairs (Year 8 EV reporting categories) EV % ERT % WSCI % CSCI %
School AB sch sta sch sta sch sta sch sta
MCWAE1 5-6 7 18.6 12 20.3 9 19.4 8 22.4
x̅ = 1.85 ± 0.48 3-4 66 67.9 57 63.4 56 63.3 56 60.3
SEAS = 2.8 ± 0.46 1-2 27 13.5 32 16.3 35 17.3 36 17.3
MCAE2 5-6 16 18.6 18 20.3 17 19.4 25 22.4
x̅ = .03 ± 0.42 3-4 77 67.9 72 63.4 72 63.3 62 60.3
SEAS = 3.9 ± 0.30 1-2 7 13.5 10 16.3 11 17.3 13 17.3
MCWBE3 5-6 12 18.6 17 20.3 13 19.4 21 22.4
x̅ = -1.69 ± 0.13 3-4 76 67.9 68 63.4 70 63.3 61 60.3
SEAS = 4.0 ± 0.25 1-2 12 13.5 15 16.3 17 17.3 18 17.3
PCWAE2 x̅ = 1.69 ± 0.21 SEAS = 1.8 ± 0.45
5-6 12 18.6 18 20.3 16 19.4 14 22.4
3-4 76 67.9 66 63.4 69 63.3 71 60.3
1-2 12 13.5 16 16.3 15 17.3 15 17.3
MCWBE5 x̅ = -1.48 ± 0.28 SEAS = 2.1 ± 0.11
5-6 13 18.6 12 20.3 17 19.4 16 22.4
3-4 69 67.9 66 63.4 61 63.3 66 60.3
1-2 18 13.5 22 16.3 22 17.3 19 17.3
MCFSWAE1 x̅ = 1.19 ± 0.29 SEAS = 8.6 ± 0.16
5-6 95 18.6 85 20.3 80 19.4 87 22.4
3-4 5 67.9 15 63.4 20 63.3 13 60.3
MGFSAE2 x̅ = -0.09 ± 0.44 SEAS = 8.3 ± 0.16
5-6 95 18.6 85 20.3 76 19.4 89 22.4
3-4 5 67.9 15 63.4 24 63.3 11 60.3
MGFSWBE1 x̅ = -1.42 ± 0.02 SEAS = 8.9 ± 0.14
5-6 94 18.6 70 20.3 78 19.4 93 22.4
3-4 6 67.9 30 63.4 22 63.3 7 60.3
PCWAE1 5-6 29 18.6 32 20.3 45 19.4 38 22.4
x̅ = 2.68 ± 0.38 3-4 69 67.9 62 63.4 51 63.3 58 60.3
SEAS = 2.7 ± 0.22 1-2 2 13.5 6 16.3 4 17.3 4 17.3
PCWAE2 SEE FOURTH DATA SET ABOVE
PCWAE3 5-6 12 18.6 15 20.3 15 19.4 14 22.4
x̅ = 1.43 ± 0.25 3-4 75 67.9 66 63.4 68 63.3 66 60.3
SEAS = 2.0 ± 0.27 1-2 13 13.5 19 16.3 17 17.3 20 17.3
Note. SEAS = socio-educational advantage score / x̅ = mean school residual / AB = achievement band / EV % = proportions of students at each level of EV score (sch = school & sta = state) / ERT % = proportions for extended response tasks / WSCI = proportions for working scientifically / CSCI = proportions for communicating scientifically
385
Table K.2 Engagement measures at the end of Year 8 Item A/4 Item B/4 Item C/4 Item D/4 Item E/% Item F/% School AB sch sta sch sta sch sta sch sta sch sta sch sta
5-6 3.21 2.78 1.43 1.56 3.69 2.76 3.21 2.83 26.81 13.50 34.64 25.13
MCWAE1 3-4 2.49 1.76 2.33 1.69 2.81 2.35 2.63 2.23 12.53 6.65 22.88 16.50
1-2 2.00 1.37 2.59 2.03 2.44 2.01 2.47 1.91 6.88 4.58 12.81 9.71
5-6 2.33 2.78 1.33 1.56 2.75 2.76 3.00 2.83 12.07 13.50 22.14 25.13
MCAE2 3-4 1.61 1.76 1.80 1.69 2.27 2.35 2.26 2.23 5.12 6.65 14.27 16.50
1-2 1.10 1.37 2.12 2.03 1.39 2.01 1.22 1.91 0.75 4.58 7.10 9.71
5-6 2.87 2.78 1.53 1.56 2.82 2.76 2.57 2.83 11.99 13.50 19.57 25.13
MCWBE3 3-4 1.41 1.76 1.90 1.69 2.16 2.35 1.75 2.23 3.70 6.65 10.03 16.50
1-2 1.09 1.37 1.90 2.03 1.87 2.01 1.30 1.91 0.63 4.58 4.47 9.71
5-6 2.75 2.78 1.48 1.56 2.85 2.76 2.74 2.83 9.26 13.50 24.90 25.13
PCWAE2 3-4 1.69 1.76 2.06 1.69 1.84 2.35 2.08 2.23 2.98 6.65 16.17 16.50
1-2 1.44 1.37 1.86 2.03 2.04 2.01 1.93 1.91 2.92 4.58 10.02 9.71
5-6 2.90 2.78 1.58 1.56 3.12 2.76 3.00 2.83 19.60 13.50 25.35 25.13
MCWBE5 3-4 1.97 1.76 1.74 1.69 2.51 2.35 2.39 2.23 9.18 6.65 19.24 16.50
1-2 1.32 1.37 2.02 2.03 2.26 2.01 2.03 1.91 6.06 4.58 10.17 9.71
MCFS WAE1*
5-6 3.22 2.78 1.95 1.56 2.92 2.76 2.81 2.83 13.71 13.50 28.51 25.13
3-4 2.28 1.76 2.61 1.69 2.59 2.35 2.38 2.23 2.14 6.65 24.44 16.50
MGFS AE2*
5-6 2.73 2.78 1.65 1.56 2.53 2.76 2.32 2.83 6.58 13.50 20.95 25.13
3-4 ns 1.76 ns 1.69 ns 2.35 ns 2.23 ns 6.65 ns 16.50
MGFS WBE1*
5-6 3.01 2.78 1.72 1.56 2.81 2.76 2.80 2.83 9.81 13.50 25.40 25.13
3-4 2.66 1.76 2.02 1.69 2.65 2.35 2.68 2.23 6.44 6.65 18.94 16.50
5-6 2.55 2.78 1.50 1.56 2.65 2.76 2.46 2.83 12.44 13.50 19.89 25.13
PCWAE1 3-4 1.35 1.76 1.44 1.69 1.55 2.35 1.99 2.23 3.64 6.65 12.70 16.50
1-2 1.75 1.37 2.00 2.03 1.75 2.01 1.25 1.91 nil 4.58 8.33 9.71
PCWAE2 SEE FOURTH DATA SET ABOVE
5-6 2.60 2.78 1.35 1.56 1.25 2.76 2.19 2.83 8.61 13.50 20.19 25.13
PCWAE3 3-4 1.91 1.76 1.50 1.69 1.84 2.35 2.19 2.23 8.0 6.65 14.61 16.50
1-2 1.09 1.37 2.10 2.03 1.4 2.01 1.67 1.91 nil 4.58 1.85 9.71
Note. Scores for Items A to D range from 0-4; Items E & F are the proportions (as a %) of students from that achievement band at that school (sch = school & sta = state). AB = achievement band / Item A = intend to study science in senior years / Item B = science is the hardest subject I learn / Item C = enjoyed primary school science / Item D = enjoy secondary science lessons / Item E = number choosing science (as one of three favourite subjects) / Item F = number choosing science (as one of the three subjects they learn most in) * These three schools had no students in the bottom achievement band / ns = no results supplied
386
Table K.3 Year 10 results Grade (%) MCWAE1 (%) MCAE21 (%) 2011 2014 2015 MEAN 2012 2013 2014 2015 MEAN A (13) 3 1 1 2 7 5 4 8 6 B (25) 10 6 9 8 15 22 18 31 22 C (36) 29 19 16 21 37 52 52 51 47 D (19) 32 38 22 31 37 18 26 7 22 E (7) 26 36 52 38 4 3 nil 3 3
1MCWBE3 did not provide any Year 10 results and MCAE2’s results were used here instead. PCWAE2 (%) MCWBE5 (%) 2012 2013 2014 2015 MEAN 2012 2013 2014 2015 MEAN A (13) 7 5 2 6 5 6 11 9 11 9 B (25) 19 11 9 10 12 17 21 19 23 20 C (36) 47 56 46 33 46 53 46 44 46 47 D (19) 15 25 29 44 28 21 11 21 18 18 E (7) 12 3 14 7 9 3 11 7 2 6
Grade 2012 2013 2014 2015 MEAN
MCFSWAE1
A (13) 59 64 65 63 63 B (25) 36 31 30 33 33 C (36) 5 5 6 4 5 D (19) nil nil nil nil 0 E (7) nil nil nil nil 0
MGFSAE2
A (13) 89 86 82 83 85 B (25) 8 13 18 15 14 C (36) 3 1 nil 2 2 D (19) nil nil nil nil 0 E (7) nil nil nil nil 0
MGFSWBE1
A (13) 80 65 66 85 74 B (25) 17 35 33 15 25 C (36) 3 nil 1 nil 1 D (19) nil nil nil nil 0 E (7) nil nil nil nil 0
PCWAE1
A (13) 13 15 18 11 14 B (25) 19 21 5 29 19 C (36) 45 39 46 46 44 D (19) 23 24 27 14 22 E (7) nil nil 4 nil 1
PCWAE2
A (13) 7 5 2 6 5 B (25) 19 11 9 10 12 C (36) 47 56 46 33 46 D (19) 15 25 29 44 28 E (7) 12 3 14 7 9
PCWAE3
LEVEL* \ YR** 2009 2010 2011 6 (9) 4 3 5 4 5 (25) 22 21 16 20 4 (35) 38 39 40 39 3 (23) 27 30 34 30 2 (5) 9 7 5 7 1 (<1) 0 0 0 0
GRADE (Four year average proportions of state population achieving grades A to E as a percentage)
387
Table K.4 Science course completions at the end of Year 12 Subject (state % in 2015) MCWAE1 % MCWBE3 %
Year 2013 2014 2015 MEAN 2013 2014 2015 MEAN Biology (28.5) 25 22 48 32 15 31 18 21 Chemistry (18) 17 6 14 12 3 8 9 7 Earth & Env. Sc. (2.4) n/a n/a n/a N/A n/a n/a n/a N/A Physics (16) 15 12 14 14 12 6 8 9 Senior Science (10.4) 27 26 23 25 n/a n/a n/a N/A Subject (state % in 2015) PCWAE1 % MCAE2 %
Year 2013 2014 2015 MEAN 2013 2014 2015 MEAN Biology (28.5) 41 50 30 40 n/a 55 58 57 Chemistry (18) 24 n/a 20 22 n/a 21 17 19 Earth & Env. Sc. (2.4) n/a n/a n/a N/A n/a n/a n/a N/A Physics (16) n/a 10 35 22 n/a 12 8 10 Senior Science (10.4) 59 40 n/a 50 n/a n/a n/a N/A Subject (state % in 2015) PCWAE2 % MCWBE5 %
Year 2013 2014 2015 MEAN 2013 2014 2015 MEAN Biology (28.5) 31 46 38 38 35 37 42 38 Chemistry (18) 15 14 18 16 13 21 20 18 Earth & Env. Sc. (2.4) n/a n/a n/a N/A n/a n/a n/a N/A Physics (16) 8 n/a 18 13 26 12 14 17 Senior Science (10.4) 46 n/a 13 30 22 12 26 20 Subject (state % in 2015) MGFSAE2 % MGFSWBE1 %
Year 2013 2014 2015 MEAN 2013 2014 2015 MEAN Biology (28.5) 21 22 17 20 18.6 23.6 24.8 22 Chemistry (18) 55 53 54 54 58.4 61.8 54.8 58 Earth & Env. Sc. (2.4) n/a n/a n/a N/A n/a n/a n/a N/A Physics (16) 18 21 30 23 30 29.3 23.6 28 Senior Science (10.4) n/a n/a n/a N/A n/a n/a n/a N/A Subject (state % in 2015) MCFSWAE1 PCWAE3 %
Year 2013 2014 2015 MEAN 2013 2014 2015 MEAN Biology (28.5) 31.9 40 30.2 34 21 19 17 19 Chemistry (18) 65.9 74.3 71.2 70 17 15 19 17 Earth & Env. Sc. (2.4) n/a n/a n/a N/A n/a 10 n/a 10 Physics (16) 46.4 45.7 46 46 21 3 9 11 Senior Science (10.4) 5.8 10.7 11.5 9 8 32 26 22 Note. The proportions (%) reported are relative to the total English candidature for the state in 2015 and at the school for each year. n/a = subject not offered that year
388
Table K.5A Student survey item scores, ranks and relative to the state
School* A
TOP
A TRNK
A
TMB
A
RTMB
A
STA
B**
TOP
B** TRNK
B**
TMB
B**
RTMB
B**
STA PCWAE1 -0.23 12 -0.26 7 B -0.06 8 -0.34 10 B MCWAE1 0.43 2 1.79 1 A -0.13 12 1.07 1 A PCWAE2 -0.03 9 -0.03 4 B -0.08 9 0.12 6 A MCWAE2 -0.01 8 -1.49 13 B -0.27 15 -2.25 13 B PCWAE3 -0.18 11 -0.31 8 B -0.21 13 -0.33 11 B MCFSWAE1 0.44 1 #NULL! NA NA 0.39 1 #NULL! NA NA MCAE2 -0.45 14 -0.87 10 B -0.23 14 -0.03 9 B MCAE3 -0.33 13 -0.24 6 B -0.12 10 0.31 4 A MGFSAE2 -0.05 10 #NULL! NA NA 0.09 3 #NULL! NA NA MCAE6 -0.49 15 -0.89 11 B -0.71 16 -0.77 12 B MGFSWBE1 0.23 4 #NULL! NA NA 0.16 2 #NULL! NA NA MCWBE5 0.12 5 0.28 2 A 0.02 4 0.06 5 A MCWBE4 -1.45 16 -1.15 12 B -0.12 11 0.37 2 A MCWBE3 0.09 6 -0.54 9 B -0.03 7 0.05 7 A MCPSWBE2 0.28 3 -0.20 5 B 0.00 5= 0.20 3 A STATE 2.78 7 5.91 3 = 1.56 5= 5.28 8 = Schools* in residual order / A & B = Item number of survey / TOP = top band scores relative to state (see bottom row) / TRNK = top band rank (n = 16) / TMB = sum of scores for all three achievement bands relative to the state (see bottom row) / STA = above (A) or below (B) the state score. Item A = I want to study a science subject in years 11 &12. Item B** = Science is the hardest subject I learn (disagreement with that was taken as a good thing)
Table K.5B Student survey item scores, ranks and relative to the state
School* C
TOP
C TRNK
C
TMB
C
RTMB
C
STA
D
TOP
D TRNK
D
TMB
D
RTMB
D
STA PCWAE1 -0.11 12 -1.28 11 B -0.37 14 -1.27 11 B MCWAE1 0.93 1 2.75 1 A 0.38 2 1.34 1 A PCWAE2 0.09 7 -0.30 8 B -0.09 11 -0.22 7 B MCWAE2 -0.12 13 -2.27 12 B 0.03 6 -2.00 13 B PCWAE3 -1.51 16 -4.15 13 B -0.64 16 -0.92 10 B
MCFSWAE1 0.16 6 #NULL! NA NA -0.02 9 #NULL! NA NA MCAE2 -0.01 11 -0.72 10 B 0.17 4 -0.49 9 B MCAE3 -0.15 14 -0.36 9 B -0.16 12 0.14 4 A
MGFSAE2 -0.23 15 #NULL! NA NA -0.51 15 #NULL! NA NA MCAE6 0.47 2 1.17 2 A 0.15 5 0.06 5 A
MGFSWBE1 0.05 9 #NULL! NA NA -0.03 10 #NULL! NA NA MCWBE5 0.36 3 1.13 3 A 0.17 3 0.45 3 A MCWBE4 0.35 4 0.97 4 A 0.50 1 1.13 2 A MCWBE3 0.06 8 -0.21 7 B -0.26 13 -1.35 12 B
MCPSWBE2 0.18 5 -0.07 6 B 0.01 7 -0.45 8 B STATE 2.76 10 7.12 5 = 2.83 8 6.97 6 =
Schools* in residual order / C & D = Item number of survey / TOP = top band scores relative to state (see bottom row) / TRNK = top band rank (n = 16) / TMB = sum of scores for all three achievement bands relative to the state (see bottom row) / STA = above (A) or below (B) the state score. Item C = In primary school, I enjoyed lessons that were about science / Item D = In secondary school, I enjoy science lessons
389
Table K.5C Student survey item scores, ranks and relative to the state
School* E
TOP
E TRNK
E
TMB
E
RTMB
E
STA
F
TOP
F
TRNK
F
TMB
F
RTMB
F
STA PCWAE1 -1.06 9 -8.65 12 B -5.24 15 -15.66 11 B MCWAE1 13.31 2 21.49 1 A 9.51 1 28.50 1 A PCWAE2 -4.24 14 -9.57 13 B -0.23 9 -0.48 7 B MCWAE2 1.90 4 -5.01 8 B 2.14 5 -4.35 9 B PCWAE3 -4.89 15 -8.12 10 B -4.94 14 -19.63 12 B
MCFSWAE1 0.21 7 #NULL! NA NA 3.38 3 #NULL! NA NA MCAE2 -1.43 10 -6.79 9 B -2.99 11 -10.82 10 B MCAE3 0.75 6 2.40 4 A -4.13 12 -0.22 6 B
MGFSAE2 -6.92 16 #NULL! NA NA -4.18 13 #NULL! NA NA MCAE6 -2.39 12 -4.40 7 B -0.84 10 -3.41 8 B
MGFSWBE1 -3.69 13 #NULL! NA NA 0.27 6 #NULL! NA NA MCWBE5 6.10 3 10.11 3 A 0.22 7 3.64 3 A MCWBE4 16.13 1 17.18 2 A 8.20 2 14.66 2 A MCWBE3 -1.51 11 -8.41 11 B -5.56 16 -22.83 13 B
MCPSWBE2 1.01 5 -0.74 6 B 2.46 4 3.25 4 A STATE 13.50 8 24.73 5 = 25.13 8 51.34 5 =
Schools* in residual order / E & F = Item number of survey / TOP = top band scores relative to state (see bottom row) / TRNK = top band rank (n = 16) / TMB = sum of scores for all three achievement bands relative to the state (see bottom row) / STA = above (A) or below (B) the state score. Item E = my three favourite subjects (15 to choose from) / Item F = the three subjects I thought I learned most in (15 to choose from)
Table K.5D Student survey items (D + E) scores, ranks and relative to the state
School* D+E TOP
D+E TRNK
D+E TMB
D+E RTMB
D+E STA
NSALL RANK
/12
TALL RANK
/16
PCWAE1 -1.43 10 -9.92 13 B 10 13 MCWAE1 13.69 3 22.83 1 A 1 1 PCWAE2 -4.33 14 -9.79 12 B 7 11 MCWAE2 1.93 5 -7.01 8 B 9 6 PCWAE3 -5.53 15 -9.04 10 B 11 16
MCFSWAE1 0.19 8 #NULL! NA NA N/A 4 MCAE2 -1.26 9 -7.28 9 B 8 12 MCAE3 0.59 7 2.54 4 A 4 10
MGFSAE2 -7.43 16 #NULL! NA NA N/A 15 MCAE6 -2.24 12 -4.34 7 B 6 9
MGFSWBE1 -3.72 13 #NULL! NA NA N/A 8 MCWBE5 6.27 4 10.56 3 A 3 3 MCWBE4 16.63 1 18.31 2 A 2 2 MCWBE3 -1.77 11 -9.76 11 B 12 14
MCPSWBE2 1.02 6 -1.19 6 B N/A 5 STATE 16.33 2 31.70 5 = 5 7
Schools* in residual order / D + E = Item numbers of survey / TOP = top band scores relative to state (see bottom row) / TRNK = top band rank (n = 16) / TMB = sum of scores for all three achievement bands relative to the state (see bottom row) / STA = above (A) or below (B) the state score. Items D + E = the sum of the scores for Items D and E from the student survey (see above for what they are) NSALL RANK = sum of all achievement band survey scores (rank out of 12) / TALL RANK = sum of top achievement band survey scores (rank out of 16).
390
AppendixJ:Surveydescriptivestatistics
The reference to residual quintile group is about the three groups (WAE, AE and WBE and the groups separating WAE from AE and AE from WBE…five groups in all differentiated by their residuals). Case Processing Summary
Cases Valid Missing Total N Percent N Percent N Percent
Residual quintile group * EV1A
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * EV1B
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * EV1C
84 98.8% 1 1.2% 85 100.0%
Residual quintile group * EV1D
84 98.8% 1 1.2% 85 100.0%
Residual quintile group * EV1E
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * EV1F
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * EV1G
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * EV1H
84 98.8% 1 1.2% 85 100.0%
Residual quintile group * EV1I
84 98.8% 1 1.2% 85 100.0%
Residual quintile group * EV2A
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * EV2B
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * EV2C
84 98.8% 1 1.2% 85 100.0%
Residual quintile group * EV2D
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * EV2E
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * EV2F
84 98.8% 1 1.2% 85 100.0%
Residual quintile group * EV2G
84 98.8% 1 1.2% 85 100.0%
Residual quintile group * EV2H
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * EV2I
84 98.8% 1 1.2% 85 100.0%
Residual quintile group * EV2J
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * EV2K
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * EV2L
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * EV2M
84 98.8% 1 1.2% 85 100.0%
Residual quintile group * EV3
85 100.0% 0 0.0% 85 100.0%
391
Residual quintile group * EV5
84 98.8% 1 1.2% 85 100.0%
Residual quintile group * S6A
84 98.8% 1 1.2% 85 100.0%
Residual quintile group * S6B
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * S6C
84 98.8% 1 1.2% 85 100.0%
Residual quintile group * S6D
84 98.8% 1 1.2% 85 100.0%
Residual quintile group * S6E
84 98.8% 1 1.2% 85 100.0%
Residual quintile group * S6F
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * S6G
84 98.8% 1 1.2% 85 100.0%
Residual quintile group * S6H
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * S6I
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * S6J
84 98.8% 1 1.2% 85 100.0%
Residual quintile group * S7
84 98.8% 1 1.2% 85 100.0%
392
CODE:1.00 = YES and 2.00 = NO Residual quintile group * EV1A Crosstabulation
EV1A
Total 1.00 2.00 Residual quintile group WBE Count 17 15 32
% within Residual quintile group
53.1% 46.9% 100.0%
AE Count 20 8 28 % within Residual quintile group
71.4% 28.6% 100.0%
WAE Count 20 5 25 % within Residual quintile group
80.0% 20.0% 100.0%
Total Count 57 28 85 % within Residual quintile group
67.1% 32.9% 100.0%
Residual quintile group * EV1B Crosstabulation
EV1B
Total 1.00 2.00 Residual quintile group WBE Count 17 15 32
% within Residual quintile group
53.1% 46.9% 100.0%
AE Count 22 6 28 % within Residual quintile group
78.6% 21.4% 100.0%
WAE Count 18 7 25 % within Residual quintile group
72.0% 28.0% 100.0%
Total Count 57 28 85 % within Residual quintile group
67.1% 32.9% 100.0%
Residual quintile group * EV1C Crosstabulation
EV1C
Total 1.00 2.00 Residual quintile group WBE Count 13 18 31
% within Residual quintile group
41.9% 58.1% 100.0%
AE Count 21 7 28 % within Residual quintile group
75.0% 25.0% 100.0%
WAE Count 17 8 25 % within Residual quintile group
68.0% 32.0% 100.0%
Total Count 51 33 84 % within Residual quintile group
60.7% 39.3% 100.0%
393
Residual quintile group * EV1D Crosstabulation
EV1D
Total 1.00 2.00 Residual quintile group WBE Count 10 22 32
% within Residual quintile group
31.3% 68.8% 100.0%
AE Count 13 14 27 % within Residual quintile group
48.1% 51.9% 100.0%
WAE Count 17 8 25 % within Residual quintile group
68.0% 32.0% 100.0%
Total Count 40 44 84 % within Residual quintile group
47.6% 52.4% 100.0%
Residual quintile group * EV1E Crosstabulation
EV1E
Total 1.00 2.00 Residual quintile group WBE Count 17 15 32
% within Residual quintile group
53.1% 46.9% 100.0%
AE Count 23 5 28 % within Residual quintile group
82.1% 17.9% 100.0%
WAE Count 16 9 25 % within Residual quintile group
64.0% 36.0% 100.0%
Total Count 56 29 85 % within Residual quintile group
65.9% 34.1% 100.0%
Residual quintile group * EV1F Crosstabulation
EV1F
Total 1.00 2.00 Residual quintile group WBE Count 5 27 32
% within Residual quintile group
15.6% 84.4% 100.0%
AE Count 6 22 28 % within Residual quintile group
21.4% 78.6% 100.0%
WAE Count 8 17 25 % within Residual quintile group
32.0% 68.0% 100.0%
Total Count 19 66 85 % within Residual quintile group
22.4% 77.6% 100.0%
394
Residual quintile group * EV1G Crosstabulation
EV1G
Total 1.00 2.00 Residual quintile group WBE Count 12 20 32
% within Residual quintile group
37.5% 62.5% 100.0%
AE Count 15 11 26 % within Residual quintile group
57.7% 42.3% 100.0%
WAE Count 14 11 25 % within Residual quintile group
56.0% 44.0% 100.0%
Total Count 41 42 83 % within Residual quintile group
49.4% 50.6% 100.0%
Residual quintile group * EV1H Crosstabulation
EV1H
Total 1.00 2.00 Residual quintile group WBE Count 8 24 32
% within Residual quintile group
25.0% 75.0% 100.0%
AE Count 11 16 27 % within Residual quintile group
40.7% 59.3% 100.0%
WAE Count 9 16 25 % within Residual quintile group
36.0% 64.0% 100.0%
Total Count 28 56 84 % within Residual quintile group
33.3% 66.7% 100.0%
Residual quintile group * EV1I Crosstabulation
EV1I
Total 1.00 2.00 Residual quintile group WBE Count 3 28 31
% within Residual quintile group
9.7% 90.3% 100.0%
AE Count 6 22 28 % within Residual quintile group
21.4% 78.6% 100.0%
WAE Count 6 19 25 % within Residual quintile group
24.0% 76.0% 100.0%
Total Count 15 69 84 % within Residual quintile group
17.9% 82.1% 100.0%
395
Residual quintile group * EV2A Crosstabulation
EV2A
Total 1.00 2.00 Residual quintile group WBE Count 7 25 32
% within Residual quintile group
21.9% 78.1% 100.0%
AE Count 9 19 28 % within Residual quintile group
32.1% 67.9% 100.0%
WAE Count 11 14 25 % within Residual quintile group
44.0% 56.0% 100.0%
Total Count 27 58 85 % within Residual quintile group
31.8% 68.2% 100.0%
Residual quintile group * EV2B Crosstabulation
EV2B
Total 1.00 2.00 Residual quintile group WBE Count 15 17 32
% within Residual quintile group
46.9% 53.1% 100.0%
AE Count 24 4 28 % within Residual quintile group
85.7% 14.3% 100.0%
WAE Count 21 4 25 % within Residual quintile group
84.0% 16.0% 100.0%
Total Count 60 25 85 % within Residual quintile group
70.6% 29.4% 100.0%
Residual quintile group * EV2C Crosstabulation
EV2C
Total 1.00 2.00 Residual quintile group WBE Count 11 21 32
% within Residual quintile group
34.4% 65.6% 100.0%
AE Count 18 9 27 % within Residual quintile group
66.7% 33.3% 100.0%
WAE Count 9 16 25 % within Residual quintile group
36.0% 64.0% 100.0%
Total Count 38 46 84 % within Residual quintile group
45.2% 54.8% 100.0%
396
Residual quintile group * EV2D Crosstabulation
EV2D
Total 1.00 2.00 Residual quintile group WBE Count 16 16 32
% within Residual quintile group
50.0% 50.0% 100.0%
AE Count 15 13 28 % within Residual quintile group
53.6% 46.4% 100.0%
WAE Count 16 9 25 % within Residual quintile group
64.0% 36.0% 100.0%
Total Count 47 38 85 % within Residual quintile group
55.3% 44.7% 100.0%
Residual quintile group * EV2E Crosstabulation
EV2E
Total 1.00 2.00 Residual quintile group WBE Count 20 12 32
% within Residual quintile group
62.5% 37.5% 100.0%
AE Count 22 6 28 % within Residual quintile group
78.6% 21.4% 100.0%
WAE Count 19 6 25 % within Residual quintile group
76.0% 24.0% 100.0%
Total Count 61 24 85 % within Residual quintile group
71.8% 28.2% 100.0%
Residual quintile group * EV2F Crosstabulation
EV2F
Total 1.00 2.00 Residual quintile group WBE Count 16 15 31
% within Residual quintile group
51.6% 48.4% 100.0%
AE Count 22 6 28 % within Residual quintile group
78.6% 21.4% 100.0%
WAE Count 18 7 25 % within Residual quintile group
72.0% 28.0% 100.0%
Total Count 56 28 84 % within Residual quintile group
66.7% 33.3% 100.0%
397
Residual quintile group * EV2G Crosstabulation
EV2G
Total 1.00 2.00 Residual quintile group WBE Count 19 13 32
% within Residual quintile group
59.4% 40.6% 100.0%
AE Count 20 7 27 % within Residual quintile group
74.1% 25.9% 100.0%
WAE Count 18 7 25 % within Residual quintile group
72.0% 28.0% 100.0%
Total Count 57 27 84 % within Residual quintile group
67.9% 32.1% 100.0%
Residual quintile group * EV2H Crosstabulation
EV2H
Total 1.00 2.00 Residual quintile group WBE Count 14 18 32
% within Residual quintile group
43.8% 56.3% 100.0%
AE Count 21 7 28 % within Residual quintile group
75.0% 25.0% 100.0%
WAE Count 14 11 25 % within Residual quintile group
56.0% 44.0% 100.0%
Total Count 49 36 85 % within Residual quintile group
57.6% 42.4% 100.0%
Residual quintile group * EV2I Crosstabulation
EV2I
Total 1.00 2.00 Residual quintile group WBE Count 7 24 31
% within Residual quintile group
22.6% 77.4% 100.0%
AE Count 21 7 28 % within Residual quintile group
75.0% 25.0% 100.0%
WAE Count 12 13 25 % within Residual quintile group
48.0% 52.0% 100.0%
Total Count 40 44 84 % within Residual quintile group
47.6% 52.4% 100.0%
398
Residual quintile group * EV2J Crosstabulation
EV2J
Total 1.00 2.00 Residual quintile group WBE Count 0 32 32
% within Residual quintile group
0.0% 100.0% 100.0%
AE Count 2 26 28 % within Residual quintile group
7.1% 92.9% 100.0%
WAE Count 0 25 25 % within Residual quintile group
0.0% 100.0% 100.0%
Total Count 2 83 85 % within Residual quintile group
2.4% 97.6% 100.0%
Residual quintile group * EV2K Crosstabulation
EV2K
Total 1.00 2.00 Residual quintile group WBE Count 0 32 32
% within Residual quintile group
0.0% 100.0% 100.0%
AE Count 2 26 28 % within Residual quintile group
7.1% 92.9% 100.0%
WAE Count 2 23 25 % within Residual quintile group
8.0% 92.0% 100.0%
Total Count 4 81 85 % within Residual quintile group
4.7% 95.3% 100.0%
Residual quintile group * EV2L Crosstabulation
EV2L
Total 1.00 2.00 Residual quintile group WBE Count 10 22 32
% within Residual quintile group
31.3% 68.8% 100.0%
AE Count 9 18 27 % within Residual quintile group
33.3% 66.7% 100.0%
WAE Count 13 11 24 % within Residual quintile group
54.2% 45.8% 100.0%
Total Count 32 51 83 % within Residual quintile group
38.6% 61.4% 100.0%
399
Residual quintile group * EV2M Crosstabulation
EV2M
Total 1.00 2.00 Residual quintile group WBE Count 7 25 32
% within Residual quintile group
21.9% 78.1% 100.0%
AE Count 9 18 27 % within Residual quintile group
33.3% 66.7% 100.0%
WAE Count 9 16 25 % within Residual quintile group
36.0% 64.0% 100.0%
Total Count 25 59 84 % within Residual quintile group
29.8% 70.2% 100.0%
Residual quintile group * EV3 Crosstabulation (see questionnaire for the key)
EV3
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 5 4 12 9 2 32 % within Residual quintile group
15.6% 12.5% 37.5% 28.1% 6.3% 100.0%
AE Count 0 0 8 11 9 28 % within Residual quintile group
0.0% 0.0% 28.6% 39.3% 32.1% 100.0%
WAE Count 0 2 6 11 6 25 % within Residual quintile group
0.0% 8.0% 24.0% 44.0% 24.0% 100.0%
Total Count 5 6 26 31 17 85 % within Residual quintile group
5.9% 7.1% 30.6% 36.5% 20.0% 100.0%
Residual quintile group * EV5 Crosstabulation (see questionnaire for the key)
EV5
Total 1.00 2.00 3.00 Residual quintile group WBE Count 15 6 11 32
% within Residual quintile group
46.9% 18.8% 34.4% 100.0%
AE Count 14 8 5 27 % within Residual quintile group
51.9% 29.6% 18.5% 100.0%
WAE Count 18 1 6 25 % within Residual quintile group
72.0% 4.0% 24.0% 100.0%
Total Count 47 15 22 84 % within Residual quintile group
56.0% 17.9% 26.2% 100.0%
400
Residual quintile group * S6A Crosstabulation
S6A
Total 1.00 2.00 Residual quintile group WBE Count 17 15 32
% within Residual quintile group
53.1% 46.9% 100.0%
AE Count 15 13 28 % within Residual quintile group
53.6% 46.4% 100.0%
WAE Count 13 11 24 % within Residual quintile group
54.2% 45.8% 100.0%
Total Count 45 39 84 % within Residual quintile group
53.6% 46.4% 100.0%
Residual quintile group * S6B Crosstabulation
S6B
Total 1.00 2.00 Residual quintile group WBE Count 6 26 32
% within Residual quintile group
18.8% 81.3% 100.0%
AE Count 7 20 27 % within Residual quintile group
25.9% 74.1% 100.0%
WAE Count 9 15 24 % within Residual quintile group
37.5% 62.5% 100.0%
Total Count 22 61 83 % within Residual quintile group
26.5% 73.5% 100.0%
Residual quintile group * S6C Crosstabulation
S6C
Total 1.00 2.00 Residual quintile group WBE Count 13 19 32
% within Residual quintile group
40.6% 59.4% 100.0%
AE Count 10 18 28 % within Residual quintile group
35.7% 64.3% 100.0%
WAE Count 12 12 24 % within Residual quintile group
50.0% 50.0% 100.0%
Total Count 35 49 84 % within Residual quintile group
41.7% 58.3% 100.0%
401
Residual quintile group * S6D Crosstabulation
S6D
Total 1.00 2.00 Residual quintile group WBE Count 6 26 32
% within Residual quintile group
18.8% 81.3% 100.0%
AE Count 4 24 28 % within Residual quintile group
14.3% 85.7% 100.0%
WAE Count 8 16 24 % within Residual quintile group
33.3% 66.7% 100.0%
Total Count 18 66 84 % within Residual quintile group
21.4% 78.6% 100.0%
Residual quintile group * S6E Crosstabulation
S6E
Total 1.00 2.00 Residual quintile group WBE Count 7 25 32
% within Residual quintile group
21.9% 78.1% 100.0%
AE Count 8 20 28 % within Residual quintile group
28.6% 71.4% 100.0%
WAE Count 9 15 24 % within Residual quintile group
37.5% 62.5% 100.0%
Total Count 24 60 84 % within Residual quintile group
28.6% 71.4% 100.0%
Residual quintile group * S6F Crosstabulation
S6F
Total 1.00 2.00 Residual quintile group WBE Count 4 27 31
% within Residual quintile group
12.9% 87.1% 100.0%
AE Count 5 23 28 % within Residual quintile group
17.9% 82.1% 100.0%
WAE Count 6 18 24 % within Residual quintile group
25.0% 75.0% 100.0%
Total Count 15 68 83 % within Residual quintile group
18.1% 81.9% 100.0%
402
Residual quintile group * S6G Crosstabulation
S6G
Total 1.00 2.00 Residual quintile group WBE Count 6 26 32
% within Residual quintile group
18.8% 81.3% 100.0%
AE Count 7 21 28 % within Residual quintile group
25.0% 75.0% 100.0%
WAE Count 8 16 24 % within Residual quintile group
33.3% 66.7% 100.0%
Total Count 21 63 84 % within Residual quintile group
25.0% 75.0% 100.0%
Residual quintile group * S6H Crosstabulation
S6H
Total 1.00 2.00 Residual quintile group WBE Count 3 28 31
% within Residual quintile group
9.7% 90.3% 100.0%
AE Count 3 25 28 % within Residual quintile group
10.7% 89.3% 100.0%
WAE Count 5 19 24 % within Residual quintile group
20.8% 79.2% 100.0%
Total Count 11 72 83 % within Residual quintile group
13.3% 86.7% 100.0%
Residual quintile group * S6I Crosstabulation
S6I
Total 1.00 2.00 Residual quintile group WBE Count 2 29 31
% within Residual quintile group
6.5% 93.5% 100.0%
AE Count 1 27 28 % within Residual quintile group
3.6% 96.4% 100.0%
WAE Count 1 23 24 % within Residual quintile group
4.2% 95.8% 100.0%
Total Count 4 79 83 % within Residual quintile group
4.8% 95.2% 100.0%
403
Residual quintile group * S6J Crosstabulation
S6J
Total 1.00 2.00 Residual quintile group WBE Count 0 32 32
% within Residual quintile group
0.0% 100.0% 100.0%
AE Count 2 26 28 % within Residual quintile group
7.1% 92.9% 100.0%
WAE Count 3 21 24 % within Residual quintile group
12.5% 87.5% 100.0%
Total Count 5 79 84 % within Residual quintile group
6.0% 94.0% 100.0%
Residual quintile group * S7 Crosstabulation (see questionnaire for the key)
S7
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 9 5 12 6 0 32 % within Residual quintile group
28.1% 15.6% 37.5% 18.8% 0.0% 100.0%
AE Count 6 6 9 7 0 28 % within Residual quintile group
21.4% 21.4% 32.1% 25.0% 0.0% 100.0%
WAE Count 8 5 3 5 3 24 % within Residual quintile group
33.3% 20.8% 12.5% 20.8% 12.5% 100.0%
Total Count 23 16 24 18 3 84 % within Residual quintile group
27.4% 19.0% 28.6% 21.4% 3.6% 100.0%
404
SECTION THREE: ASSESSMENT FOR LEARNING (AFL) DESCRIPTIVE STATISTICS Case Processing Summary
Cases Valid Missing Total N Percent N Percent N Percent
Residual quintile group * AFL9A
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * AFL9B
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * AFL9C
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * AFL9D
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * AFL9E
82 96.5% 3 3.5% 85 100.0%
Residual quintile group * AFL9F
82 96.5% 3 3.5% 85 100.0%
Residual quintile group * AFL9G
81 95.3% 4 4.7% 85 100.0%
Residual quintile group * AFL9H
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * AFL10A
82 96.5% 3 3.5% 85 100.0%
Residual quintile group * AFL10B
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * AFL10C
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * AFL10D
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * AFL10E
82 96.5% 3 3.5% 85 100.0%
Residual quintile group * AFL10F
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * AFL10G
82 96.5% 3 3.5% 85 100.0%
Residual quintile group * AFL10H
82 96.5% 3 3.5% 85 100.0%
Residual quintile group * AFL11A
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * AFL11B
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * AFL11C
82 96.5% 3 3.5% 85 100.0%
Residual quintile group * AFL11D
82 96.5% 3 3.5% 85 100.0%
Residual quintile group * AFL11E
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * Exemplary or model answers
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * Success criteria
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * Misconceptions
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * SOLO levels
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * QT model
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * Bloom categories
85 100.0% 0 0.0% 85 100.0%
405
Residual quintile group * Syllabus outcomes / standards
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * AFL13A
81 95.3% 4 4.7% 85 100.0%
Residual quintile group * AFL13B
81 95.3% 4 4.7% 85 100.0%
Residual quintile group * AFL13C
81 95.3% 4 4.7% 85 100.0%
Residual quintile group * AFL13D
82 96.5% 3 3.5% 85 100.0%
Residual quintile group * AFL13E
80 94.1% 5 5.9% 85 100.0%
Residual quintile group * AFL13F
81 95.3% 4 4.7% 85 100.0%
Residual quintile group * AFL14A
81 95.3% 4 4.7% 85 100.0%
Residual quintile group * AFL14B
81 95.3% 4 4.7% 85 100.0%
Residual quintile group * AFL14C
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * AFL14D
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * AFL14E
81 95.3% 4 4.7% 85 100.0%
Residual quintile group * AFL14F
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * AFL14G
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * AFL14H
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * AFL15A
83 97.6% 2 2.4% 85 100.0%
Residual quintile group * AFL15B
82 96.5% 3 3.5% 85 100.0%
Residual quintile group * AFL15C
82 96.5% 3 3.5% 85 100.0%
Residual quintile group * AFL15D
79 92.9% 6 7.1% 85 100.0%
Residual quintile group * AFL15E
83 97.6% 2 2.4% 85 100.0%
N = 47 items
406
SEE QUESIONNAIRE FOR KEY EXPLAINING RESPONSE AND RELATED NUMBER Residual quintile group * AFL9A Crosstabulation
AFL9A
Total 1.00 3.00 4.00 5.00 Residual quintile group
WBE Count 2 1 8 20 31 % within Residual quintile group
6.5% 3.2% 25.8% 64.5% 100.0%
AE Count 0 0 7 21 28 % within Residual quintile group
0.0% 0.0% 25.0% 75.0% 100.0%
WAE Count 0 0 11 13 24 % within Residual quintile group
0.0% 0.0% 45.8% 54.2% 100.0%
Total Count 2 1 26 54 83 % within Residual quintile group
2.4% 1.2% 31.3% 65.1% 100.0%
Residual quintile group * AFL9B Crosstabulation
AFL9B
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 2 4 8 17 0 31 % within Residual quintile group
6.5% 12.9% 25.8% 54.8% 0.0% 100.0%
AE Count 1 2 8 15 2 28 % within Residual quintile group
3.6% 7.1% 28.6% 53.6% 7.1% 100.0%
WAE Count 0 4 5 14 1 24 % within Residual quintile group
0.0% 16.7% 20.8% 58.3% 4.2% 100.0%
Total Count 3 10 21 46 3 83 % within Residual quintile group
3.6% 12.0% 25.3% 55.4% 3.6% 100.0%
Residual quintile group * AFL9C Crosstabulation
AFL9C
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 1 1 3 10 16 31 % within Residual quintile group
3.2% 3.2% 9.7% 32.3% 51.6% 100.0%
AE Count 0 0 3 4 21 28 % within Residual quintile group
0.0% 0.0% 10.7% 14.3% 75.0% 100.0%
WAE Count 0 0 1 8 15 24 % within Residual quintile group
0.0% 0.0% 4.2% 33.3% 62.5% 100.0%
Total Count 1 1 7 22 52 83 % within Residual quintile group
1.2% 1.2% 8.4% 26.5% 62.7% 100.0%
Residual quintile group * AFL9D Crosstabulation
AFL9D
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 1 5 14 9 2 31 % within Residual quintile group
3.2% 16.1% 45.2% 29.0% 6.5% 100.0%
407
AE Count 1 1 10 15 1 28 % within Residual quintile group
3.6% 3.6% 35.7% 53.6% 3.6% 100.0%
WAE Count 0 3 7 12 2 24 % within Residual quintile group
0.0% 12.5% 29.2% 50.0% 8.3% 100.0%
Total Count 2 9 31 36 5 83 % within Residual quintile group
2.4% 10.8% 37.3% 43.4% 6.0% 100.0%
Residual quintile group * AFL9E Crosstabulation
AFL9E
Total 3.00 4.00 5.00 Residual quintile group WBE Count 1 11 19 31
% within Residual quintile group
3.2% 35.5% 61.3% 100.0%
AE Count 0 6 21 27 % within Residual quintile group
0.0% 22.2% 77.8% 100.0%
WAE Count 1 10 13 24 % within Residual quintile group
4.2% 41.7% 54.2% 100.0%
Total Count 2 27 53 82 % within Residual quintile group
2.4% 32.9% 64.6% 100.0%
Residual quintile group * AFL9F Crosstabulation
AFL9F
Total 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 1 4 19 6 30 % within Residual quintile group
3.3% 13.3% 63.3% 20.0% 100.0%
AE Count 1 4 16 7 28 % within Residual quintile group
3.6% 14.3% 57.1% 25.0% 100.0%
WAE Count 1 5 10 8 24 % within Residual quintile group
4.2% 20.8% 41.7% 33.3% 100.0%
Total Count 3 13 45 21 82 % within Residual quintile group
3.7% 15.9% 54.9% 25.6% 100.0%
Residual quintile group * AFL9G Crosstabulation
AFL9G
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 1 1 5 18 5 30 % within Residual quintile group
3.3% 3.3% 16.7% 60.0% 16.7% 100.0%
AE Count 0 1 4 18 4 27 % within Residual quintile group
0.0% 3.7% 14.8% 66.7% 14.8% 100.0%
WAE Count 0 1 5 11 7 24 % within Residual quintile group
0.0% 4.2% 20.8% 45.8% 29.2% 100.0%
Total Count 1 3 14 47 16 81
408
% within Residual quintile group
1.2% 3.7% 17.3% 58.0% 19.8% 100.0%
Residual quintile group * AFL9H Crosstabulation
AFL9H
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 4 12 10 5 0 31 % within Residual quintile group
12.9% 38.7% 32.3% 16.1% 0.0% 100.0%
AE Count 2 12 5 8 1 28 % within Residual quintile group
7.1% 42.9% 17.9% 28.6% 3.6% 100.0%
WAE Count 3 13 6 0 2 24 % within Residual quintile group
12.5% 54.2% 25.0% 0.0% 8.3% 100.0%
Total Count 9 37 21 13 3 83 % within Residual quintile group
10.8% 44.6% 25.3% 15.7% 3.6% 100.0%
Residual quintile group * AFL10A Crosstabulation
AFL10A
Total 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 0 5 18 8 31 % within Residual quintile group
0.0% 16.1% 58.1% 25.8% 100.0%
AE Count 1 4 16 6 27 % within Residual quintile group
3.7% 14.8% 59.3% 22.2% 100.0%
WAE Count 0 5 14 5 24 % within Residual quintile group
0.0% 20.8% 58.3% 20.8% 100.0%
Total Count 1 14 48 19 82 % within Residual quintile group
1.2% 17.1% 58.5% 23.2% 100.0%
Residual quintile group * AFL10B Crosstabulation
AFL10B
Total 4.00 5.00 Residual quintile group WBE Count 13 18 31
% within Residual quintile group
41.9% 58.1% 100.0%
AE Count 12 16 28 % within Residual quintile group
42.9% 57.1% 100.0%
WAE Count 11 13 24 % within Residual quintile group
45.8% 54.2% 100.0%
Total Count 36 47 83 % within Residual quintile group
43.4% 56.6% 100.0%
Residual quintile group * AFL10C Crosstabulation
AFL10C
Total 1.00 3.00 4.00 5.00 WBE Count 1 1 14 15 31
409
Residual quintile group
% within Residual quintile group
3.2% 3.2% 45.2% 48.4% 100.0%
AE Count 0 0 12 16 28 % within Residual quintile group
0.0% 0.0% 42.9% 57.1% 100.0%
WAE Count 0 0 5 19 24 % within Residual quintile group
0.0% 0.0% 20.8% 79.2% 100.0%
Total Count 1 1 31 50 83 % within Residual quintile group
1.2% 1.2% 37.3% 60.2% 100.0%
Residual quintile group * AFL10D Crosstabulation
AFL10D
Total 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 1 2 11 17 31 % within Residual quintile group
3.2% 6.5% 35.5% 54.8% 100.0%
AE Count 0 2 8 18 28 % within Residual quintile group
0.0% 7.1% 28.6% 64.3% 100.0%
WAE Count 0 0 6 18 24 % within Residual quintile group
0.0% 0.0% 25.0% 75.0% 100.0%
Total Count 1 4 25 53 83 % within Residual quintile group
1.2% 4.8% 30.1% 63.9% 100.0%
Residual quintile group * AFL10E Crosstabulation
AFL10E
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 2 2 5 19 3 31 % within Residual quintile group
6.5% 6.5% 16.1% 61.3% 9.7% 100.0%
AE Count 1 2 3 17 5 28 % within Residual quintile group
3.6% 7.1% 10.7% 60.7% 17.9% 100.0%
WAE Count 2 2 4 10 5 23 % within Residual quintile group
8.7% 8.7% 17.4% 43.5% 21.7% 100.0%
Total Count 5 6 12 46 13 82 % within Residual quintile group
6.1% 7.3% 14.6% 56.1% 15.9% 100.0%
Residual quintile group * AFL10F Crosstabulation
AFL10F
Total 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 0 8 19 4 31 % within Residual quintile group
0.0% 25.8% 61.3% 12.9% 100.0%
AE Count 0 2 17 9 28 % within Residual quintile group
0.0% 7.1% 60.7% 32.1% 100.0%
WAE Count 1 1 14 8 24 % within Residual quintile group
4.2% 4.2% 58.3% 33.3% 100.0%
410
Total Count 1 11 50 21 83 % within Residual quintile group
1.2% 13.3% 60.2% 25.3% 100.0%
Residual quintile group * AFL10G Crosstabulation
AFL10G
Total 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 2 13 12 3 30 % within Residual quintile group
6.7% 43.3% 40.0% 10.0% 100.0%
AE Count 3 8 13 4 28 % within Residual quintile group
10.7% 28.6% 46.4% 14.3% 100.0%
WAE Count 2 2 16 4 24 % within Residual quintile group
8.3% 8.3% 66.7% 16.7% 100.0%
Total Count 7 23 41 11 82 % within Residual quintile group
8.5% 28.0% 50.0% 13.4% 100.0%
Residual quintile group * AFL10H Crosstabulation
AFL10H
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 1 1 1 16 12 31 % within Residual quintile group
3.2% 3.2% 3.2% 51.6% 38.7% 100.0%
AE Count 0 0 0 14 13 27 % within Residual quintile group
0.0% 0.0% 0.0% 51.9% 48.1% 100.0%
WAE Count 0 0 0 6 18 24 % within Residual quintile group
0.0% 0.0% 0.0% 25.0% 75.0% 100.0%
Total Count 1 1 1 36 43 82 % within Residual quintile group
1.2% 1.2% 1.2% 43.9% 52.4% 100.0%
Residual quintile group * AFL11A Crosstabulation
AFL11A
Total 3.00 4.00 5.00 Residual quintile group WBE Count 4 8 19 31
% within Residual quintile group
12.9% 25.8% 61.3% 100.0%
AE Count 1 7 20 28 % within Residual quintile group
3.6% 25.0% 71.4% 100.0%
WAE Count 1 5 18 24 % within Residual quintile group
4.2% 20.8% 75.0% 100.0%
Total Count 6 20 57 83 % within Residual quintile group
7.2% 24.1% 68.7% 100.0%
Residual quintile group * AFL11B Crosstabulation
AFL11B
Total 3.00 4.00 5.00 Residual quintile group WBE Count 3 7 21 31
411
% within Residual quintile group
9.7% 22.6% 67.7% 100.0%
AE Count 1 11 16 28 % within Residual quintile group
3.6% 39.3% 57.1% 100.0%
WAE Count 0 6 18 24 % within Residual quintile group
0.0% 25.0% 75.0% 100.0%
Total Count 4 24 55 83 % within Residual quintile group
4.8% 28.9% 66.3% 100.0%
Residual quintile group * AFL11C Crosstabulation
AFL11C
Total 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 4 8 13 6 31 % within Residual quintile group
12.9% 25.8% 41.9% 19.4% 100.0%
AE Count 3 4 13 8 28 % within Residual quintile group
10.7% 14.3% 46.4% 28.6% 100.0%
WAE Count 2 4 8 9 23 % within Residual quintile group
8.7% 17.4% 34.8% 39.1% 100.0%
Total Count 9 16 34 23 82 % within Residual quintile group
11.0% 19.5% 41.5% 28.0% 100.0%
Residual quintile group * AFL11D Crosstabulation
AFL11D
Total 4.00 5.00 Residual quintile group WBE Count 10 20 30
% within Residual quintile group
33.3% 66.7% 100.0%
AE Count 8 20 28 % within Residual quintile group
28.6% 71.4% 100.0%
WAE Count 5 19 24 % within Residual quintile group
20.8% 79.2% 100.0%
Total Count 23 59 82 % within Residual quintile group
28.0% 72.0% 100.0%
Residual quintile group * AFL11E Crosstabulation
AFL11E
Total 4.00 5.00 Residual quintile group WBE Count 12 19 31
% within Residual quintile group
38.7% 61.3% 100.0%
AE Count 6 22 28 % within Residual quintile group
21.4% 78.6% 100.0%
WAE Count 2 22 24 % within Residual quintile group
8.3% 91.7% 100.0%
412
Total Count 20 63 83 % within Residual quintile group
24.1% 75.9% 100.0%
Residual quintile group * Exemplary or model answers Crosstabulation
Exemplary or model answers
Total .00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 2 1 3 19 7 32 % within Residual quintile group
6.3% 3.1% 9.4% 59.4% 21.9% 100.0%
AE Count 3 0 2 15 8 28 % within Residual quintile group
10.7% 0.0% 7.1% 53.6% 28.6% 100.0%
WAE Count 1 0 1 15 8 25 % within Residual quintile group
4.0% 0.0% 4.0% 60.0% 32.0% 100.0%
Total Count 6 1 6 49 23 85 % within Residual quintile group
7.1% 1.2% 7.1% 57.6% 27.1% 100.0%
Residual quintile group * Success criteria Crosstabulation
Success criteria
Total .00 3.00 4.00 5.00 Residual quintile group
WBE Count 2 5 14 11 32 % within Residual quintile group
6.3% 15.6% 43.8% 34.4% 100.0%
AE Count 3 1 6 18 28 % within Residual quintile group
10.7% 3.6% 21.4% 64.3% 100.0%
WAE Count 1 1 9 14 25 % within Residual quintile group
4.0% 4.0% 36.0% 56.0% 100.0%
Total Count 6 7 29 43 85 % within Residual quintile group
7.1% 8.2% 34.1% 50.6% 100.0%
Residual quintile group * Misconceptions Crosstabulation
Misconceptions
Total .00 3.00 4.00 5.00 Residual quintile group
WBE Count 3 3 14 12 32 % within Residual quintile group
9.4% 9.4% 43.8% 37.5% 100.0%
AE Count 3 2 10 13 28 % within Residual quintile group
10.7% 7.1% 35.7% 46.4% 100.0%
WAE Count 1 3 8 13 25 % within Residual quintile group
4.0% 12.0% 32.0% 52.0% 100.0%
Total Count 7 8 32 38 85 % within Residual quintile group
8.2% 9.4% 37.6% 44.7% 100.0%
Residual quintile group * SOLO levels Crosstabulation
SOLO levels
Total .00 2.00 3.00 4.00 5.00 WBE Count 9 10 7 4 2 32
413
Residual quintile group
% within Residual quintile group
28.1% 31.3% 21.9% 12.5% 6.3% 100.0%
AE Count 9 4 8 7 0 28 % within Residual quintile group
32.1% 14.3% 28.6% 25.0% 0.0% 100.0%
WAE Count 8 7 3 3 4 25 % within Residual quintile group
32.0% 28.0% 12.0% 12.0% 16.0% 100.0%
Total Count 26 21 18 14 6 85 % within Residual quintile group
30.6% 24.7% 21.2% 16.5% 7.1% 100.0%
Residual quintile group * QT model Crosstabulation
QT model
Total .00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 3 7 9 10 3 32 % within Residual quintile group
9.4% 21.9% 28.1% 31.3% 9.4% 100.0%
AE Count 5 2 5 8 8 28 % within Residual quintile group
17.9% 7.1% 17.9% 28.6% 28.6% 100.0%
WAE Count 3 3 5 7 7 25 % within Residual quintile group
12.0% 12.0% 20.0% 28.0% 28.0% 100.0%
Total Count 11 12 19 25 18 85 % within Residual quintile group
12.9% 14.1% 22.4% 29.4% 21.2% 100.0%
Residual quintile group * Bloom categories Crosstabulation
Bloom categories
Total .00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 3 3 12 10 4 32 % within Residual quintile group
9.4% 9.4% 37.5% 31.3% 12.5% 100.0%
AE Count 3 1 3 13 8 28 % within Residual quintile group
10.7% 3.6% 10.7% 46.4% 28.6% 100.0%
WAE Count 2 2 4 12 5 25 % within Residual quintile group
8.0% 8.0% 16.0% 48.0% 20.0% 100.0%
Total Count 8 6 19 35 17 85 % within Residual quintile group
9.4% 7.1% 22.4% 41.2% 20.0% 100.0%
Residual quintile group * Syllabus outcomes / standards Crosstabulation
Syllabus outcomes / standards
Total .00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 2 3 3 15 9 32 % within Residual quintile group
6.3% 9.4% 9.4% 46.9% 28.1% 100.0%
AE Count 4 2 1 8 13 28 % within Residual quintile group
14.3% 7.1% 3.6% 28.6% 46.4% 100.0%
WAE Count 1 1 1 7 15 25 % within Residual quintile group
4.0% 4.0% 4.0% 28.0% 60.0% 100.0%
414
Total Count 7 6 5 30 37 85 % within Residual quintile group
8.2% 7.1% 5.9% 35.3% 43.5% 100.0%
Residual quintile group * AFL13A Crosstabulation
AFL13A
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 0 12 12 6 0 30 % within Residual quintile group
0.0% 40.0% 40.0% 20.0% 0.0% 100.0%
AE Count 1 6 7 12 2 28 % within Residual quintile group
3.6% 21.4% 25.0% 42.9% 7.1% 100.0%
WAE Count 0 5 9 7 2 23 % within Residual quintile group
0.0% 21.7% 39.1% 30.4% 8.7% 100.0%
Total Count 1 23 28 25 4 81 % within Residual quintile group
1.2% 28.4% 34.6% 30.9% 4.9% 100.0%
Residual quintile group * AFL13B Crosstabulation
AFL13B
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 0 15 12 4 0 31 % within Residual quintile group
0.0% 48.4% 38.7% 12.9% 0.0% 100.0%
AE Count 1 7 10 8 1 27 % within Residual quintile group
3.7% 25.9% 37.0% 29.6% 3.7% 100.0%
WAE Count 1 6 10 5 1 23 % within Residual quintile group
4.3% 26.1% 43.5% 21.7% 4.3% 100.0%
Total Count 2 28 32 17 2 81 % within Residual quintile group
2.5% 34.6% 39.5% 21.0% 2.5% 100.0%
Residual quintile group * AFL13C Crosstabulation
AFL13C
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 1 2 2 13 13 31 % within Residual quintile group
3.2% 6.5% 6.5% 41.9% 41.9% 100.0%
AE Count 0 2 3 5 17 27 % within Residual quintile group
0.0% 7.4% 11.1% 18.5% 63.0% 100.0%
WAE Count 0 1 0 8 14 23 % within Residual quintile group
0.0% 4.3% 0.0% 34.8% 60.9% 100.0%
Total Count 1 5 5 26 44 81 % within Residual quintile group
1.2% 6.2% 6.2% 32.1% 54.3% 100.0%
Residual quintile group * AFL13D Crosstabulation
AFL13D
Total 1.00 2.00 3.00 4.00 5.00 WBE Count 0 3 11 14 3 31
415
Residual quintile group
% within Residual quintile group
0.0% 9.7% 35.5% 45.2% 9.7% 100.0%
AE Count 1 1 5 15 6 28 % within Residual quintile group
3.6% 3.6% 17.9% 53.6% 21.4% 100.0%
WAE Count 0 1 2 16 4 23 % within Residual quintile group
0.0% 4.3% 8.7% 69.6% 17.4% 100.0%
Total Count 1 5 18 45 13 82 % within Residual quintile group
1.2% 6.1% 22.0% 54.9% 15.9% 100.0%
Residual quintile group * AFL13E Crosstabulation
AFL13E
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 0 8 12 11 0 31 % within Residual quintile group
0.0% 25.8% 38.7% 35.5% 0.0% 100.0%
AE Count 2 11 6 6 1 26 % within Residual quintile group
7.7% 42.3% 23.1% 23.1% 3.8% 100.0%
WAE Count 2 8 7 5 1 23 % within Residual quintile group
8.7% 34.8% 30.4% 21.7% 4.3% 100.0%
Total Count 4 27 25 22 2 80 % within Residual quintile group
5.0% 33.8% 31.3% 27.5% 2.5% 100.0%
Residual quintile group * AFL13F Crosstabulation
AFL13F
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 1 17 8 2 3 31 % within Residual quintile group
3.2% 54.8% 25.8% 6.5% 9.7% 100.0%
AE Count 1 16 3 6 1 27 % within Residual quintile group
3.7% 59.3% 11.1% 22.2% 3.7% 100.0%
WAE Count 0 9 7 5 2 23 % within Residual quintile group
0.0% 39.1% 30.4% 21.7% 8.7% 100.0%
Total Count 2 42 18 13 6 81 % within Residual quintile group
2.5% 51.9% 22.2% 16.0% 7.4% 100.0%
Residual quintile group * AFL14A Crosstabulation
AFL14A
Total 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 3 15 9 3 30 % within Residual quintile group
10.0% 50.0% 30.0% 10.0% 100.0%
AE Count 2 6 15 5 28 % within Residual quintile group
7.1% 21.4% 53.6% 17.9% 100.0%
WAE Count 1 5 10 7 23 % within Residual quintile group
4.3% 21.7% 43.5% 30.4% 100.0%
416
Total Count 6 26 34 15 81 % within Residual quintile group
7.4% 32.1% 42.0% 18.5% 100.0%
Residual quintile group * AFL14B Crosstabulation
AFL14B
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 1 3 7 10 10 31 % within Residual quintile group
3.2% 9.7% 22.6% 32.3% 32.3% 100.0%
AE Count 1 1 4 15 7 28 % within Residual quintile group
3.6% 3.6% 14.3% 53.6% 25.0% 100.0%
WAE Count 0 0 3 8 11 22 % within Residual quintile group
0.0% 0.0% 13.6% 36.4% 50.0% 100.0%
Total Count 2 4 14 33 28 81 % within Residual quintile group
2.5% 4.9% 17.3% 40.7% 34.6% 100.0%
Residual quintile group * AFL14C Crosstabulation
AFL14C
Total 3.00 4.00 5.00 Residual quintile group WBE Count 3 16 12 31
% within Residual quintile group
9.7% 51.6% 38.7% 100.0%
AE Count 1 9 18 28 % within Residual quintile group
3.6% 32.1% 64.3% 100.0%
WAE Count 1 8 15 24 % within Residual quintile group
4.2% 33.3% 62.5% 100.0%
Total Count 5 33 45 83 % within Residual quintile group
6.0% 39.8% 54.2% 100.0%
Residual quintile group * AFL14D Crosstabulation
AFL14D
Total 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 2 6 19 4 31 % within Residual quintile group
6.5% 19.4% 61.3% 12.9% 100.0%
AE Count 1 3 10 14 28 % within Residual quintile group
3.6% 10.7% 35.7% 50.0% 100.0%
WAE Count 0 5 7 12 24 % within Residual quintile group
0.0% 20.8% 29.2% 50.0% 100.0%
Total Count 3 14 36 30 83 % within Residual quintile group
3.6% 16.9% 43.4% 36.1% 100.0%
Residual quintile group * AFL14E Crosstabulation
AFL14E
Total 3.00 4.00 5.00 Residual quintile group WBE Count 3 16 12 31
417
% within Residual quintile group
9.7% 51.6% 38.7% 100.0%
AE Count 1 8 18 27 % within Residual quintile group
3.7% 29.6% 66.7% 100.0%
WAE Count 0 9 14 23 % within Residual quintile group
0.0% 39.1% 60.9% 100.0%
Total Count 4 33 44 81 % within Residual quintile group
4.9% 40.7% 54.3% 100.0%
Residual quintile group * AFL14F Crosstabulation
AFL14F
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 2 14 6 9 0 31 % within Residual quintile group
6.5% 45.2% 19.4% 29.0% 0.0% 100.0%
AE Count 1 8 9 9 1 28 % within Residual quintile group
3.6% 28.6% 32.1% 32.1% 3.6% 100.0%
WAE Count 1 5 8 9 1 24 % within Residual quintile group
4.2% 20.8% 33.3% 37.5% 4.2% 100.0%
Total Count 4 27 23 27 2 83 % within Residual quintile group
4.8% 32.5% 27.7% 32.5% 2.4% 100.0%
Residual quintile group * AFL14G Crosstabulation
AFL14G
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 2 7 9 11 2 31 % within Residual quintile group
6.5% 22.6% 29.0% 35.5% 6.5% 100.0%
AE Count 1 3 11 7 6 28 % within Residual quintile group
3.6% 10.7% 39.3% 25.0% 21.4% 100.0%
WAE Count 0 4 6 9 5 24 % within Residual quintile group
0.0% 16.7% 25.0% 37.5% 20.8% 100.0%
Total Count 3 14 26 27 13 83 % within Residual quintile group
3.6% 16.9% 31.3% 32.5% 15.7% 100.0%
Residual quintile group * AFL14H Crosstabulation
AFL14H
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 2 7 8 12 2 31 % within Residual quintile group
6.5% 22.6% 25.8% 38.7% 6.5% 100.0%
AE Count 0 3 7 15 3 28 % within Residual quintile group
0.0% 10.7% 25.0% 53.6% 10.7% 100.0%
WAE Count 0 2 4 12 6 24 % within Residual quintile group
0.0% 8.3% 16.7% 50.0% 25.0% 100.0%
418
Total Count 2 12 19 39 11 83 % within Residual quintile group
2.4% 14.5% 22.9% 47.0% 13.3% 100.0%
Residual quintile group * AFL15A Crosstabulation
AFL15A
Total 2.00 4.00 5.00 Residual quintile group WBE Count 1 6 24 31
% within Residual quintile group
3.2% 19.4% 77.4% 100.0%
AE Count 0 5 23 28 % within Residual quintile group
0.0% 17.9% 82.1% 100.0%
WAE Count 0 8 16 24 % within Residual quintile group
0.0% 33.3% 66.7% 100.0%
Total Count 1 19 63 83 % within Residual quintile group
1.2% 22.9% 75.9% 100.0%
Residual quintile group * AFL15B Crosstabulation
AFL15B
Total 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 1 1 9 20 31 % within Residual quintile group
3.2% 3.2% 29.0% 64.5% 100.0%
AE Count 0 1 5 22 28 % within Residual quintile group
0.0% 3.6% 17.9% 78.6% 100.0%
WAE Count 0 1 7 15 23 % within Residual quintile group
0.0% 4.3% 30.4% 65.2% 100.0%
Total Count 1 3 21 57 82 % within Residual quintile group
1.2% 3.7% 25.6% 69.5% 100.0%
Residual quintile group * AFL15C Crosstabulation
AFL15C
Total 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 0 3 12 16 31 % within Residual quintile group
0.0% 9.7% 38.7% 51.6% 100.0%
AE Count 1 0 7 20 28 % within Residual quintile group
3.6% 0.0% 25.0% 71.4% 100.0%
WAE Count 0 1 9 13 23 % within Residual quintile group
0.0% 4.3% 39.1% 56.5% 100.0%
Total Count 1 4 28 49 82 % within Residual quintile group
1.2% 4.9% 34.1% 59.8% 100.0%
Residual quintile group * AFL15D Crosstabulation
AFL15D
Total 1.00 2.00 3.00 4.00 5.00 WBE Count 1 1 4 11 14 31
419
Residual quintile group
% within Residual quintile group
3.2% 3.2% 12.9% 35.5% 45.2% 100.0%
AE Count 0 0 2 7 18 27 % within Residual quintile group
0.0% 0.0% 7.4% 25.9% 66.7% 100.0%
WAE Count 0 0 0 8 13 21 % within Residual quintile group
0.0% 0.0% 0.0% 38.1% 61.9% 100.0%
Total Count 1 1 6 26 45 79 % within Residual quintile group
1.3% 1.3% 7.6% 32.9% 57.0% 100.0%
Residual quintile group * AFL15E Crosstabulation
AFL15E
Total 1.00 2.00 3.00 4.00 5.00 Residual quintile group
WBE Count 0 1 2 16 12 31 % within Residual quintile group
0.0% 3.2% 6.5% 51.6% 38.7% 100.0%
AE Count 0 1 3 10 14 28 % within Residual quintile group
0.0% 3.6% 10.7% 35.7% 50.0% 100.0%
WAE Count 1 1 1 7 14 24 % within Residual quintile group
4.2% 4.2% 4.2% 29.2% 58.3% 100.0%
Total Count 1 3 6 33 40 83 % within Residual quintile group
1.2% 3.6% 7.2% 39.8% 48.2% 100.0%
420
RESPONDENTDATADISAGGREGATEDINTOCASESTUDY(CS)SCHOOLS,
SCHOOLSTHATIDENTIFIEDTHEMSELVESANDREMAINDER(ANONYMOUS)
Case Processing Summary
Cases Valid Missing Total N Percent N Percent N Percent
Residual quintile group * Gender * Status within residual quintile group
78 91.8% 7 8.2% 85 100.0%
Residual quintile group * Teaching experience * Status within residual quintile group
78 91.8% 7 8.2% 85 100.0%
Residual quintile group * Science teacher by training * Status within residual quintile group
80 94.1% 5 5.9% 85 100.0%
Residual quintile group * Alternative quals * Status within residual quintile group
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * Head teacher or not * Status within residual quintile group
81 95.3% 4 4.7% 85 100.0%
Residual quintile group * Highest qualification * Status within residual quintile group
79 92.9% 6 7.1% 85 100.0%
Residual quintile group * Year highest qual completed * Status within residual quintile group
85 100.0% 0 0.0% 85 100.0%
Residual quintile group * Where trained * Status within residual quintile group
78 91.8% 7 8.2% 85 100.0%
Residual quintile group * Last taught Yr 7-9 classes * Status within residual quintile group
81 95.3% 4 4.7% 85 100.0%
Residual quintile group * Y8 classes at your school * Status within residual quintile group
79 92.9% 6 7.1% 85 100.0%
Residual quintile group * FT science teachers * Status within residual quintile group
78 91.8% 7 8.2% 85 100.0%
Residual quintile group * PT science teachers * Status within residual quintile group
64 75.3% 21 24.7% 85 100.0%
421
REFER TO THE QUESIONNAIRE FOR THE KEY LINKING NUMBERS TO RESPONSE Residual quintile group * Gender * Status within residual quintile group Crosstabulation
Status within residual quintile group Gender
Total 1 2 UNKNOWN Residual quintile
group WBE Count 13 6 19
% within Residual quintile group
68.4% 31.6% 100.0%
AE Count 12 4 16 % within Residual quintile group
75.0% 25.0% 100.0%
WAE Count 8 5 13 % within Residual quintile group
61.5% 38.5% 100.0%
Total Count 33 15 48 % within Residual quintile group
68.8% 31.3% 100.0%
IDKNOWN Residual quintile group
WBE Count 4 1 5 % within Residual quintile group
80.0% 20.0% 100.0%
AE Count 3 3 6 % within Residual quintile group
50.0% 50.0% 100.0%
WAE Count 3 1 4 % within Residual quintile group
75.0% 25.0% 100.0%
Total Count 10 5 15 % within Residual quintile group
66.7% 33.3% 100.0%
CSSCHOOL Residual quintile group
WBE Count 3 2 5 % within Residual quintile group
60.0% 40.0% 100.0%
AE Count 3 1 4 % within Residual quintile group
75.0% 25.0% 100.0%
WAE Count 5 1 6 % within Residual quintile group
83.3% 16.7% 100.0%
Total Count 11 4 15 % within Residual quintile group
73.3% 26.7% 100.0%
Total Residual quintile group
WBE Count 20 9 29 % within Residual quintile group
69.0% 31.0% 100.0%
AE Count 18 8 26 % within Residual quintile group
69.2% 30.8% 100.0%
WAE Count 16 7 23 % within Residual quintile group
69.6% 30.4% 100.0%
Total Count 54 24 78 % within Residual quintile group
69.2% 30.8% 100.0%
422
Residual quintile group * Teaching experience * Status within residual quintile group Crosstabulation
Status within residual quintile group Teaching experience
Total 1 2 3 4 UNKNOWN Residual quintile
group WBE Count 8 2 1 8 19
% within Residual quintile group
42.1% 10.5% 5.3% 42.1% 100.0%
AE Count 1 3 3 9 16 % within Residual quintile group
6.3% 18.8% 18.8% 56.3% 100.0%
WAE Count 1 2 3 7 13 % within Residual quintile group
7.7% 15.4% 23.1% 53.8% 100.0%
Total Count 10 7 7 24 48 % within Residual quintile group
20.8% 14.6% 14.6% 50.0% 100.0%
IDKNOWN Residual quintile group
WBE Count 1 0 4 5 % within Residual quintile group 20.0% 0.0% 80.0% 100.0%
AE Count 2 0 4 6 % within Residual quintile group 33.3% 0.0% 66.7% 100.0%
WAE Count 1 1 2 4 % within Residual quintile group 25.0% 25.0% 50.0% 100.0%
Total Count 4 1 10 15 % within Residual quintile group 26.7% 6.7% 66.7% 100.0%
CSSCHOOL Residual quintile group
WBE Count 1 2 2 5 % within Residual quintile group 20.0% 40.0% 40.0% 100.0%
AE Count 0 1 3 4 % within Residual quintile group 0.0% 25.0% 75.0% 100.0%
WAE Count 0 1 5 6 % within Residual quintile group 0.0% 16.7% 83.3% 100.0%
Total Count 1 4 10 15 % within Residual quintile group 6.7% 26.7% 66.7% 100.0%
Total Residual quintile group
WBE Count 8 4 3 14 29 % within Residual quintile group
27.6% 13.8% 10.3% 48.3% 100.0%
AE Count 1 5 4 16 26 % within Residual quintile group
3.8% 19.2% 15.4% 61.5% 100.0%
WAE Count 1 3 5 14 23 % within Residual quintile group
4.3% 13.0% 21.7% 60.9% 100.0%
Total Count 10 12 12 44 78 % within Residual quintile group
12.8% 15.4% 15.4% 56.4% 100.0%
423
Residual quintile group * Science teacher by training * Status within residual quintile group Crosstabulation
Status within residual quintile group
Science teacher by training
Total 1 2 UNKNOWN Residual quintile
group WBE Count 16 3 19
% within Residual quintile group
84.2% 15.8% 100.0%
AE Count 18 0 18 % within Residual quintile group
100.0% 0.0% 100.0%
WAE Count 12 1 13 % within Residual quintile group
92.3% 7.7% 100.0%
Total Count 46 4 50 % within Residual quintile group
92.0% 8.0% 100.0%
IDKNOWN Residual quintile group
WBE Count 5 5 % within Residual quintile group
100.0% 100.0%
AE Count 6 6 % within Residual quintile group
100.0% 100.0%
WAE Count 4 4 % within Residual quintile group
100.0% 100.0%
Total Count 15 15 % within Residual quintile group
100.0% 100.0%
CSSCHOOL Residual quintile group
WBE Count 5 5 % within Residual quintile group
100.0% 100.0%
AE Count 4 4 % within Residual quintile group
100.0% 100.0%
WAE Count 6 6 % within Residual quintile group
100.0% 100.0%
Total Count 15 15 % within Residual quintile group
100.0% 100.0%
Total Residual quintile group
WBE Count 26 3 29 % within Residual quintile group
89.7% 10.3% 100.0%
AE Count 28 0 28 % within Residual quintile group
100.0% 0.0% 100.0%
WAE Count 22 1 23 % within Residual quintile group
95.7% 4.3% 100.0%
Total Count 76 4 80 % within Residual quintile group
95.0% 5.0% 100.0%
424
Residual quintile group * Alternative quals * Status within residual quintile group Crosstabulation
Status within residual quintile group Alternative quals
Total .0 UNKNOWN Residual quintile
group WBE Count 18 4 22
% within Residual quintile group
81.8% 18.2% 100.0%
AE Count 17 1 18 % within Residual quintile group
94.4% 5.6% 100.0%
WAE Count 12 3 15 % within Residual quintile group
80.0% 20.0% 100.0%
Total Count 47 8 55 % within Residual quintile group
85.5% 14.5% 100.0%
IDKNOWN Residual quintile group
WBE Count 5 0 5 % within Residual quintile group
100.0% 0.0% 100.0%
AE Count 5 1 6 % within Residual quintile group
83.3% 16.7% 100.0%
WAE Count 4 0 4 % within Residual quintile group
100.0% 0.0% 100.0%
Total Count 14 1 15 % within Residual quintile group
93.3% 6.7% 100.0%
CSSCHOOL Residual quintile group
WBE Count 3 2 5 % within Residual quintile group
60.0% 40.0% 100.0%
AE Count 4 0 4 % within Residual quintile group
100.0% 0.0% 100.0%
WAE Count 5 1 6 % within Residual quintile group
83.3% 16.7% 100.0%
Total Count 12 3 15 % within Residual quintile group
80.0% 20.0% 100.0%
Total Residual quintile group
WBE Count 26 6 32 % within Residual quintile group
81.3% 18.8% 100.0%
AE Count 26 2 28 % within Residual quintile group
92.9% 7.1% 100.0%
WAE Count 21 4 25 % within Residual quintile group
84.0% 16.0% 100.0%
Total Count 73 12 85 % within Residual quintile group
85.9% 14.1% 100.0%
425
Residual quintile group * Head teacher or not * Status within residual quintile group Crosstabulation
Status within residual quintile group
Head teacher or not
Total 1 2 UNKNOWN Residual quintile
group WBE Count 4 15 19
% within Residual quintile group
21.1% 78.9% 100.0%
AE Count 6 12 18 % within Residual quintile group
33.3% 66.7% 100.0%
WAE Count 5 9 14 % within Residual quintile group
35.7% 64.3% 100.0%
Total Count 15 36 51 % within Residual quintile group
29.4% 70.6% 100.0%
IDKNOWN Residual quintile group
WBE Count 4 1 5 % within Residual quintile group
80.0% 20.0% 100.0%
AE Count 4 2 6 % within Residual quintile group
66.7% 33.3% 100.0%
WAE Count 4 0 4 % within Residual quintile group
100.0% 0.0% 100.0%
Total Count 12 3 15 % within Residual quintile group
80.0% 20.0% 100.0%
CSSCHOOL Residual quintile group
WBE Count 4 1 5 % within Residual quintile group
80.0% 20.0% 100.0%
AE Count 4 0 4 % within Residual quintile group
100.0% 0.0% 100.0%
WAE Count 4 2 6 % within Residual quintile group
66.7% 33.3% 100.0%
Total Count 12 3 15 % within Residual quintile group
80.0% 20.0% 100.0%
Total Residual quintile group
WBE Count 12 17 29 % within Residual quintile group
41.4% 58.6% 100.0%
AE Count 14 14 28 % within Residual quintile group
50.0% 50.0% 100.0%
WAE Count 13 11 24 % within Residual quintile group
54.2% 45.8% 100.0%
Total Count 39 42 81 % within Residual quintile group
48.1% 51.9% 100.0%
426
Residual quintile group * Highest qualification * Status within residual quintile group Crosstabulation
Status within residual quintile group Highest qualification
Total 1 2 3 4 5 UNKNOWN Residual
quintile group WBE Count 10 5 1 1 0 17
% within Residual quintile group
58.8% 29.4% 5.9% 5.9% 0.0% 100.0%
AE Count 11 2 3 0 2 18 % within Residual quintile group
61.1% 11.1% 16.7% 0.0% 11.1% 100.0%
WAE Count 9 1 2 0 2 14 % within Residual quintile group
64.3% 7.1% 14.3% 0.0% 14.3% 100.0%
Total Count 30 8 6 1 4 49 % within Residual quintile group
61.2% 16.3% 12.2% 2.0% 8.2% 100.0%
IDKNOWN Residual quintile group
WBE Count 5 0 5 % within Residual quintile group
100.0% 0.0%
100.0%
AE Count 5 1 6 % within Residual quintile group
83.3% 16.7%
100.0%
WAE Count 2 2 4 % within Residual quintile group
50.0% 50.0%
100.0%
Total Count 12 3 15 % within Residual quintile group
80.0% 20.0%
100.0%
CSSCHOOL Residual quintile group
WBE Count 4 1 0 5 % within Residual quintile group
80.0% 20.0% 0.0%
100.0%
AE Count 4 0 0 4 % within Residual quintile group
100.0% 0.0% 0.0%
100.0%
WAE Count 5 0 1 6 % within Residual quintile group
83.3% 0.0% 16.7%
100.0%
Total Count 13 1 1 15 % within Residual quintile group
86.7% 6.7% 6.7%
100.0%
Total Residual quintile group
WBE Count 19 6 1 1 0 27 % within Residual quintile group
70.4% 22.2% 3.7% 3.7% 0.0% 100.0%
AE Count 20 3 3 0 2 28
427
% within Residual quintile group
71.4% 10.7% 10.7% 0.0% 7.1% 100.0%
WAE Count 16 3 3 0 2 24 % within Residual quintile group
66.7% 12.5% 12.5% 0.0% 8.3% 100.0%
Total Count 55 12 7 1 4 79 % within Residual quintile group
69.6% 15.2% 8.9% 1.3% 5.1% 100.0%
Residual quintile group * Where trained * Status within residual quintile group Crosstabulation
Status within residual quintile group Where trained
Total 1 2 3 UNKNOWN Residual quintile
group WBE Count 0 2 15 17
% within Residual quintile group
0.0% 11.8% 88.2% 100.0%
AE Count 4 2 12 18 % within Residual quintile group
22.2% 11.1% 66.7% 100.0%
WAE Count 2 1 11 14 % within Residual quintile group
14.3% 7.1% 78.6% 100.0%
Total Count 6 5 38 49 % within Residual quintile group
12.2% 10.2% 77.6% 100.0%
IDKNOWN Residual quintile group
WBE Count 5 5 % within Residual quintile group 100.0% 100.0%
AE Count 6 6 % within Residual quintile group 100.0% 100.0%
WAE Count 4 4 % within Residual quintile group 100.0% 100.0%
Total Count 15 15 % within Residual quintile group 100.0% 100.0%
CSSCHOOL Residual quintile group
WBE Count 0 5 5 % within Residual quintile group
0.0% 100.0% 100.0%
AE Count 1 3 4 % within Residual quintile group
25.0% 75.0% 100.0%
WAE Count 1 4 5 % within Residual quintile group
20.0% 80.0% 100.0%
Total Count 2 12 14 % within Residual quintile group
14.3% 85.7% 100.0%
Total Residual quintile group
WBE Count 0 2 25 27 % within Residual quintile group
0.0% 7.4% 92.6% 100.0%
AE Count 5 2 21 28
428
% within Residual quintile group
17.9% 7.1% 75.0% 100.0%
WAE Count 3 1 19 23 % within Residual quintile group
13.0% 4.3% 82.6% 100.0%
Total Count 8 5 65 78 % within Residual quintile group
10.3% 6.4% 83.3% 100.0%
429
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