Chapter 13 Inference About Comparing Two Populations.
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Transcript of Chapter 13 Inference About Comparing Two Populations.
Chapter 13
Inference About Comparing
Two Populations
Comparing Two Populations…Previously we looked at techniques to estimate and test parameters for one population:
Population Mean , Population Variance , and
Population Proportion p
We will still consider these parameters when we are looking at two populations, however our interest will now be:
The difference between two means.
The ratio of two variances.
The difference between two proportions.
Difference of Two Means…In order to test and estimate the difference between two population means, we draw random samples from each of two populations. Initially, we will consider independent samples, that is, samples that are completely unrelated to one another.
(Likewise, we consider for Population 2)
Sample, size: n1
Population 1
Parameters: Statistics:
Difference of Two Means
In order to test and estimate the difference between two population means, we draw random samples from each of two populations. Initially, we will consider independent samples, that is, samples that are completely unrelated to one another.
Because we are comparing two population means, we use the statistic:
Sampling Distribution of
1. is normally distributed if the original populations are normal –or– approximately normal if the populations are nonnormal and the sample sizes are large (n1, n2 > 30)
2. The expected value of is
3. The variance of is
and the standard error is:
Making Inferences About Since is normally distributed if the original populations are normal –or– approximately normal if the populations are nonnormal and the sample sizes are large (n1, n2 > 30), then:
is a standard normal (or approximately normal) random variable. We could use this to build test statistics or confidence interval estimators for …
Making Inferences About …except that, in practice, the z statistic is rarely used since the population variances are unknown.
Instead we use a t-statistic. We consider two cases for the unknown population variances: when we believe they are equal and conversely when they are not equal.
??
When are variances equal?
How do we know when the population variances are equal?
Since the population variances are unknown, we can’t know for certain whether they’re equal, but we can examine the sample variances and informally judge their relative values to determine whether we can assume that the population variances are equal or not.
Test Statistic for (equal variances)
1) Calculate – the pooled variance estimator as…
2) …and use it here:
degrees of freedom
CI Estimator for (equal variances)
The confidence interval estimator for when the population variances are equal is given by:
degrees of freedompooled variance estimator
Test Statistic for (unequal variances)
The test statistic for when the population variances are unequal is given by:
Likewise, the confidence interval estimator is:
degrees of freedom
Which case to use?Which case to use? Equal variance or unequal variance?
Whenever there is insufficient evidence that the variances are unequal, it is preferable to perform the
equal variances t-test.
This is so, because for any two given samples:
The number of degrees of freedom for the equal variances case
The number of degrees of freedom for the unequal variances case
≥Larger numbers of degrees of freedom
have the same effect as having larger sample
sizes
≥
• Example 13.1– Do people who eat high-fiber cereal for
breakfast consume, on average, fewer calories for lunch than people who do not eat high-fiber cereal for breakfast?
– A sample of 150 people was randomly drawn. Each person was identified as a consumer or a non-consumer of high-fiber cereal.
– For each person the number of calories consumed at lunch was recorded.
Example: Making an inference about –
Consmers Non-cmrs568 705498 819589 706681 509540 613646 582636 601739 608539 787596 573607 428529 754637 741617 628633 537555 748
. .
. .
. .
. .
Consmers Non-cmrs568 705498 819589 706681 509540 613646 582636 601739 608539 787596 573607 428529 754637 741617 628633 537555 748
. .
. .
. .
. .
Solution: • The data are interval. • The parameter to be tested is the difference between two means. • The claim to be tested is: The mean caloric intake of consumers (1) is less than that of non-consumers (2).
Example: Making an inference about –
• The hypotheses are:
H0: (1 - 2) = 0H1: (1 - 2) < 0
– To check the whether the population variances are equal, we use (Xm13-01) computer output to find the sample variances
We have s12= 4103, and s2
2 = 10,670.
– It appears that the variances are unequal.
Example: Making an inference about –
Example 13.1…A sample of 150 people was randomly drawn. Each person was identified as a consumer or a non-consumer of high-fiber cereal. For each person the number of calories consumed at lunch was recorded. The data: Independent Pop’ns;
Either you eat high fibercereal or you don’t
n1+n2=150
There is reason to believethe population variances
are unequal…
Recall H1:
Example 13.1…
Thus, our test statistic is:
The number of degrees of freedom is:
Hence the rejection region is…
COMPUTE
Example 13.1…Our rejection region:
Our test statistic:
Since our test statistic (-2.09) is less than our critical value of t (-1.658), we reject H0 in favor of H1 — that is, there is sufficient evidence to support the claim that high fiber cereal eaters consume less calories at lunch.
COMPUTE
Compare
INTERPRET
Confidence Interval…Suppose we wanted to compute a 95% confidence interval estimate of the difference between mean caloric intake for consumers and non-consumers of high-fiber cereals…
That is, we estimate that non-consumers of high fiber cereal eat between 1.56 and 56.86 more calories than consumers.
• Example 13.2
– An ergonomic chair can be assembled
using two different sets of operations
(Method A and Method B)
– The operations manager would like to
know whether the assembly time under
the two methods differ.
Example: Making an inference about –
• Example 13.2
– Two samples are randomly and
independently selected
• A sample of 25 workers assembled the chair
using method A.
• A sample of 25 workers assembled the chair
using method B.
• The assembly times were recorded
– Do the assembly times of the two methods
differs?
Example: Making an inference about –
Example 13.2 : Making an inference about –
Method A Method B6.8 5.25.0 6.77.9 5.75.2 6.67.6 8.55.0 6.55.9 5.95.2 6.76.5 6.6. .. .. .. .
Method A Method B6.8 5.25.0 6.77.9 5.75.2 6.67.6 8.55.0 6.55.9 5.95.2 6.76.5 6.6. .. .. .. .
Assembly times in Minutes
Solution
• The data are interval.
• The parameter of interest is the difference between two population means.
• The claim to be tested is whether a difference between the two methods exists.
Example 13.2 : Making an inference about –
• Compute: Manually
–The hypotheses test is:
H0: (1 - 2) 0
H1: (1 - 2) 0
– To check whether the two unknown population variances are equal we calculate S1
2 and S22 (Xm13-02).
Example: Making an inference about –
Manually
4822525.f.d
93.0
251
251
076.1
0)016.6288.6(t
4822525.f.d
93.0
251
251
076.1
0)016.6288.6(t
3031.1s 8478.0s 016.6x 288.6x 22
2121
076.122525
)303.1)(125()848.0)(125(S2
p
– To calculate the t-statistic we have:
COMPUTE
Example 13.2…The assembly times for each of the two methods are recorded and preliminary data is prepared…
COMPUTE
The sample variances are similar, hence we will assume that the population variances are
equal…
Example 13.2…Recall, we are doing a two-tailed test, hence the rejection region will be:
The number of degrees of freedom is:
Hence our critical values of t (and our rejection region) becomes:
COMPUTE
Example 13.2…In order to calculate our t-statistic, we need to first calculate the pooled variance estimator, followed by the t-statistic…
COMPUTE
Example 13.2…
Since our calculated t-statistic does not fall into the rejection region, we cannot reject H0 in favor of H1, that is, there is not sufficient evidence to infer that the mean assembly times differ.
INTERPRET
Confidence Interval…We can compute a 95% confidence interval estimate for the difference in mean assembly times as:
That is, we estimate the mean difference between the two assembly methods between –.36 and .96 minutes. Note: zero is included in this confidence interval…
Checking the required Conditions for the equal variances case (Example
13.2)
The data appear to be approximately normal
0
2
4
6
8
10
12
5 5.8 6.6 7.4 8.2 More
Design A
01234567
4.2 5 5.8 6.6 7.4 More
Design B
Identifying Factors I…Factors that identify the equal-variances t-test and estimator of :
Identifying Factors II…Factors that identify the unequal-variances t-test and estimator of :
13.4 Matched Pairs Experiment
• What is a matched pair experiment?
• Why matched pairs experiments are needed? • How do we deal with data produced in this way?
The following example demonstrates a situationwhere a matched pair experiment is the correct approach to testing the difference between two population means.
Example 13.3 – To investigate the job offers obtained by MBA graduates,
a study focusing on salaries was conducted.
– Particularly, the salaries offered to finance majors were compared to those offered to marketing majors.
– Two random samples of 25 graduates in each discipline were selected, and the highest salary offer was recorded for each one. The data are stored in file Xm13-03.
– Can we infer that finance majors obtain higher salary
offers than do marketing majors among MBAs?.
13.4 Matched Pairs Experiment
• Solution– Compare two
populations of interval data.
The parameter tested is 1 - 2
Finance Marketing61,228 73,36151,836 36,95620,620 63,62773,356 71,06984,186 40,203
. .
. .
. .
1
2
The mean of the highest salaryoffered to Finance MBAs
The mean of the highest salaryoffered to Marketing MBAs
– H0: (1 - 2) = 0
H1: (1 - 2) > 0
Example 13.3
• Solution – continued
From the data we have:
559,228,262s
,294,433,360s
423,60x624,65x
22
21
2
1
• Let us assume equal variances
Equal VariancesFinance Marketing
Mean 65624 60423Variance 360433294 262228559Observations 25 25Pooled Variance 311330926Hypothesized Mean Difference 0df 48t Stat 1.04P(T<=t) one-tail 0.1513t Critical one-tail 1.6772P(T<=t) two-tail 0.3026t Critical two-tail 2.0106
There is insufficient evidence to conclude that Finance MBAs are offered higher salaries than marketing MBAs.
Example 13.3
• Question–The difference between the
sample means is 65624 – 60423 = 5,201.
–So, why could we not reject H0
and favor H1 where(1 – 2 > 0)?
The effect of a large sample variability
• Answer: – Sp
2 is large (because the sample variances are large) Sp
2 = 311,330,926.
– A large variance reduces the value of the t statistic and it becomes more difficult to reject H0.
The effect of a large sample variability
)n1
n1
(s
)()xx(t
21
2p
21
Reducing the variability
The values each sample consists of might markedly vary...
The range of observationssample B
The range of observationssample A
...but the differences between pairs of observations might be quite close to one another, resulting in a small variability of the differences.
0
Differences
The range of thedifferences
Reducing the variability
The matched pairs experiment• Since the difference of the means is equal
to the mean of the differences we can rewrite the hypotheses in terms of D (the mean of the differences) rather than in terms of 1 – 2.
• This formulation has the benefit of a smaller variability.
Group 1 Group 2 Difference10 12 - 215 11 +4
Mean1 =12.5 Mean2 =11.5Mean1 – Mean2 = 1 Mean Differences = 1
• Example 13.4 – It was suspected that salary offers were
affected by students’ GPA, (which caused S1
2 and S22 to increase).
– To reduce this variability, the following procedure was used:• 25 ranges of GPAs were predetermined.• Students from each major were randomly
selected, one from each GPA range.• The highest salary offer for each student was
recorded.
– From the data presented can we conclude that Finance majors are offered higher salaries?
The matched pairs experiment
Example 13.4…The numbers in black are the original starting salary data; the number in blue were calculated.
although a student is either in Finance OR in Marketing (i.e. independent), that the data is grouped in this fashion makes it a matched pairs experiment (i.e. the two students in group #1 are ‘matched’ by their GPA range
the difference of the means is equal to the mean of the differences, hence we will consider the “mean of the paired differences” as our parameter of interest:
Example 13.4…Do Finance majors have higher salary offers than Marketing majors?
Since:
We want to research this hypothesis:
H1:
(and our null hypothesis becomes
H0: )
IDENTIFY
Test Statistic for
The test statistic for the mean of the population of differences ( ) is:
which is Student t distributed with nD–1 degrees of freedom, provided that the differences are normally distributed.
Thus our rejection region becomes:
Example 13.4…From the data, we calculate…
…which in turn we use
for our t-statistic…
…which we compare to our critical value of t:
COMPUTE
Example 13.4…•Since our calculated value of t (3.81) is greater than our critical value of t (1.711), it falls in the rejection region, hence we reject H0 in favor of H1; that is, there is overwhelming evidence (since the p-value = .0004) that Finance majors do obtain higher starting salary offers than their peers in Marketing.
INTERPRET
Compare…
Confidence Interval Estimator forWe can derive the confidence interval estimator for
algebraically as:
In the previous example, what is the 95% confidence interval estimate of the mean difference in salary offers between the two business majors?
That is, the mean of the population differences is between LCL=2,321 and UCL=7,809 dollars.
Example 13.5
Identifying Factors…Factors that identify the t-test and estimator of :
Inference about the ratio of two variances
So far we’ve looked at comparing measures of central location, namely the mean of two populations.
When looking at two population variances, we consider the ratio of the variances, i.e. the parameter of interest to us is:
The sampling statistic: is F distributed with
degrees of freedom.
Inference about the ratio of two variances
Our null hypothesis is always:
H0:
(i.e. the variances of the two populations will be equal, hence their ratio will be one)
Therefore, our statistic simplifies to:
CI Estimator of σ12 / σ2
2
With algebraic manipulation we get
s1 1LCL =
s2 Fα/2,ν ,ν
s1 1UCL =
s2 Fα/2,ν ,ν
Where ν1 = n1 – 1 and ν2= n2 - 1
2
2
1 2
2
2
2 1
Example 13.6…
In example 13.1, we looked at the variances of the samples of people who consumed high fiber cereal and those who did not and assumed they were not equal. We can use the ideas just developed to test if this is in fact the case.
We want to show: H1:
(the variances are not equal to each other)
Hence we have our null hypothesis: H0:
IDENTIFY
Example 13.6…
Since our research hypothesis is: H1:
We are doing a two-tailed test, and our rejection region is:
CALCULATE
F
Example 13.6…Our test statistic is:
Hence there is sufficient evidence to reject the null hypothesis in favor of the alternative; that is, there is a difference in the variance between the two populations.
CALCULATE
F.58 1.61
Example 13.7…
If we wanted to determine the 95% confidence interval estimate of the ratio of the two population variances in Example 13.1, we would proceed as follows…
The confidence interval estimator for σ 2 / σ 2 , is:
CALCULATE
1 2
Example 13.7…
The 95% confidence interval estimate of the ratio of the two population variances in Example 13.1 is:
That is, we estimate that σ 2 / σ 2 lies between .2388 and .6614
Note that one (1.00) is not within this interval…
CALCULATE
1 2
Identifying Factors
Factors that identify the F-test and estimator of σ 2 / σ 2 :1 2
Difference Between Two Population Proportions
We will now look at procedures for drawing inferences about the difference between populations whose data are nominal (i.e. categorical).
As mentioned previously, with nominal data, calculate proportions of occurrences of each type of outcome. Thus, the parameter to be tested and estimated in this section is the difference between two population proportions: p1–p2.
Sampling from two populations of nominal data
Population 1 Population 2
Parameter: p1 Parameter: p2
Statistic:p1
^ ^Statistic:p2
^
SampleSize: n1
SampleSize: n2
Statistic and Sampling Distribution…
To draw inferences about the the parameter p1–p2, we take samples of population, calculate the sample proportions and look at their difference.
is an unbiased estimator for p1–p2.x1 successes in a sample of size n1 from population 1
Sampling DistributionThe statistic is approximately normally distributed if the sample sizes are large enough so that:
Since its “approximately normal” we can describe the normal distribution in terms of mean and variance…
…hence this z-variable will also be approximately standard normally distributed:
Testing and Estimating p1–p2…
Because the population proportions (p1 & p2) are unknown, the standard error:
is unknown. Thus, we have two different estimators for the standard error of , which depend upon the null hypothesis. We’ll look at these cases on the next slide…
Test Statistic for p1–p2…
There are two cases to consider…
Example 13.8…
A consumer packaged goods (CPG) company is test marketing two new versions of soap packaging. Version one (bright colors) is distributed in one supermarket, while version two (simple colors) is in another. Since the first version is more expensive, it must outsell the other design, that is its market share, p1, must be greater than that of the other soap package design, i.e. p2.
That is, we want to know, is p1 > p2? or, using the language of statistics:
H1: (p1–p2) > 0
Hence our null hypothesis will be H0: (p1–p2) = 0 [case 1]
IDENTIFY
Example 13.8…
Here is the summary data…
Our null hypothesis is H0: (p1–p2) = 0, i.e. is a “case 1” type problem, hence we need to calculate the pooled proportion:
IDENTIFY
Example 13.8…At a 5% significance level, our rejection region is:
The value of our z-statistic is…
Since 2.90 > 1.645, we reject H0 in favor of H1, that is, there is enough evidence to infer that the brightly colored design is more popular than the simple design.
CALCULATE
Compare…
Example 13.9…
Suppose in our test marketing of soap packages scenario that instead of just a difference between the two package versions, the brightly colored design had to outsell the simple design by at least 3%
Our research hypothesis now becomes:
H1: (p1–p2) > .03
And so our null hypothesis is: H0: (p1–p2) = .03
IDENTIFY
Since the r.h.s. of the H0 equation is
not zero, it’s a “case 2” type problem
Example 13.9…Same summary data as before:
Since this is a “case 2” type problem, we don’t need to calculate the pooled proportion, we can go straight to z:
IDENTIFY
Example 13.9…
Since our calculated z-statistic (1.15) does not fall into our rejection region
there is not enough evidence to infer that the brightly colored design outsells the other design by 3% or more.
INTERPRET
Confidence Intervals…
The confidence interval estimator for p1–p2 is given by:
and as you may suspect, its valid when…
Example 13.10…Create a 95% confidence interval for the difference between the two proportions of packaged soap sales from Ex. 13.8:
COMPUTE
Identifying Factors…
•Factors that identify the z-test and estimator for p1–p2