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Transcript of Http://research.microsoft.com/~gray/talks/cern_2001.ppt 1 Store Everything Online In A Database Jim...
http://research.microsoft.com/~gray/talks/cern_2001.ppt1
Store Everything
OnlineIn A Database
Jim GrayMicrosoft Research
[email protected]://research.microsoft.com/~gray/talks
http://research.microsoft.com/~gray/talks/cern_2001.ppt2
Outline• Store Everything• Online (Disk not Tape)
• In a Database• A Federated DB• Two Examples
http://research.microsoft.com/~gray/talks/cern_2001.ppt3
How Much is Everything?• Soon everything can be
recorded and indexed• Most bytes will never be
seen by humans.• Data summarization, trend
detection anomaly detection are key technologies
See Mike Lesk: How much information is there: http://www.lesk.com/mlesk/ksg97/ksg.html
See Lyman & Varian:
How much informationhttp://www.sims.berkeley.edu/research/projects/how-much-info/
Yotta
Zetta
Exa
Peta
Tera
Giga
Mega
KiloA BookA Book
.Movie
All LoC books(words)
All Books MultiMedia
Everything!
Recorded
A PhotoA Photo
24 Yecto, 21 zepto, 18 atto, 15 femto, 12 pico, 9 nano, 6 micro, 3 milli
http://research.microsoft.com/~gray/talks/cern_2001.ppt4
1E+3
1E+4
1E+5
1E+6
1E+7
1988 1991 1994 1997 2000
disk TB growth: 112%/y
Moore's Law: 58.7%/y
ExaByte
Disk TB Shipped per Year1998 Disk Trend (J im Porter)
http://www.disktrend.com/pdf/portrpkg.pdf.
Storage capacity beating Moore’s law
2.3 k$/TB today (raw disk)
1k$/TB by end of 2002
Moores law 58.70% /year
Revenue 7.47%TB growth 112.30% (since 1993)
Price decline 50.70% (since 1993)
http://research.microsoft.com/~gray/talks/cern_2001.ppt5
Outline• Store Everything• Online (Disk not Tape)
• In a Database• A Federated DB• Two Examples
http://research.microsoft.com/~gray/talks/cern_2001.ppt6
Online Data
• Can build 1PB of NAS disk for 5M$ today
• Can SCAN (read or write) entire PB in 3 hours.• Operate it as a data pump: continuous sequential scan
• Can deliver 1PB for 1M$ over Internet– Access charge is 300$/Mbps bulk rate
• Need to Geoplex data (store it in two places).
• Need to filter/process data near the source,– To minimize network costs.
http://research.microsoft.com/~gray/talks/cern_2001.ppt7
The “Absurd” Disk
• 2.5 hr scan time (poor sequential access)
• 1 access per second / 5 GB (VERY cold data)
• It’s a tape!
1 TB100 MB/s
200 Kaps
http://research.microsoft.com/~gray/talks/cern_2001.ppt8
Disk vs Tape
Disk– 80 GB– 35 MBps– 5 ms seek time– 3 ms rotate latency– 2$/GB for drive
2$/GB for ctlrs/cabinet– 15 TB/rack
– 1 hour scan
Tape– 40 GB– 10 MBps– 10 sec pick time– 30-120 second seek time– 2$/GB for media
8$/GB for drive+library– 10 TB/rack
– 1 week scan
The price advantage of disk is growing the performance advantage of disk is huge!At 10K$/TB, disk is competitive with nearline tape.
GuestimatesCern: 200 TB3480 tapes2 col = 50GBRack = 1 TB=12 drives
http://research.microsoft.com/~gray/talks/cern_2001.ppt9
0
100
200
300
400
500
Premium SAN Dell/3ware DIY
Building a Petabyte Disk Store• Cadillac ~ 500k$/TB = 500M$/PB
plus FC switches plus… 800M$/PB• TPC-C SANs (Brand PC 18GB/…) 60M$/PB• Brand PC local SCSI 15M$/PB• Do it yourself ATA 5M$/PB
http://research.microsoft.com/~gray/talks/cern_2001.ppt10
Cheap Storage and/or Balanced System
• Low cost storage (2 x 3k$ servers) 5K$ TB2x ( 800 Mhz, 256Mb + 8x80GB disks + 100MbE)
raid5 costs 6K$/TB
• Balanced server (5k$/.64 TB)– 2x 1Ghz (2k$)– 512 MB – 8 x 80 GB drives (2K$)– Gbps Ethernet + switch (300$/port)– 9k$/TB 18K$/mirrored TB
2x1 Ghz512 MB
http://research.microsoft.com/~gray/talks/cern_2001.ppt11
Next step in the Evolution• Disks become supercomputers
– Controller will have 1bips, 1 GB ram, 1 GBps net– And a disk arm.
• Disks will run full-blown app/web/db/os stack
• Distributed computing
• Processors migrate to transducers.
http://research.microsoft.com/~gray/talks/cern_2001.ppt12
It’s Hard to Archive a PetabyteIt takes a LONG time to restore it.
• At 1GBps it takes 12 days!• Store it in two (or more) places online (on disk?).
A geo-plex• Scrub it continuously (look for errors)• On failure,
– use other copy until failure repaired, – refresh lost copy from safe copy.
• Can organize the two copies differently (e.g.: one by time, one by space)
http://research.microsoft.com/~gray/talks/cern_2001.ppt13
Outline• Store Everything• Online (Disk not Tape)
• In a Database• A Federated DB• Two Examples
http://research.microsoft.com/~gray/talks/cern_2001.ppt14
Why Not: file = object + GREP?• It works if you have thousands of objects
(and you know them all)
• But hard to search millions/billions/trillions with GREP
• Hard to put all attributes in file name.– Minimal metadata
• Hard to do chunking right.
• Hard to pivot on space/time/version/attributes.
http://research.microsoft.com/~gray/talks/cern_2001.ppt15
The Reality: it’s build vs buy
• If you use a file system you will eventually build a database system:– metadata, – Query, – parallel ops, – security,….– reorganize, – recovery, – distributed, – replication,
http://research.microsoft.com/~gray/talks/cern_2001.ppt16
OK: so I’ll put lots of objects in a fileDo It Yourself Database
• Good news: – Your implementation will be 10x faster (at least!)– easier to understand and use
• Bad news: – It will cost 10x more to build and maintain– Someday you will get bored maintaining/evolving it– It will lack some killer features:
• Parallel search• Self-describing via metadata• SQL, XML, … • Replication• Online update – reorganization• Chunking is problematic (what granularity, how to aggregate)
http://research.microsoft.com/~gray/talks/cern_2001.ppt17
Top 10 reasons to put Everything in a DB1. Someone else writes the million lines of code2. Captures data and Metadata,3. Standard interfaces give tools and quick learning4. Allows Schema Evolution without breaking old apps5. Index and Pivot on multiple attributes
space-time-attribute-version….6. Parallel terabyte searches in seconds or minutes7. Moves processing & search close to the disk arm
(moves fewer bytes (qestons return datons). 8. Chunking is easier (can aggregate chunks at server).9. Automatic geo-replication 10. Online update and reorganization. 11. Security 12. If you pick the right vendor, ten years from now, there will
be software that can read the data.
http://research.microsoft.com/~gray/talks/cern_2001.ppt18
DB Centric Examples
• TerraServer– All images and all data in the database (chunked as small
tiles).www.TerraServer.Microsoft.com/
– http://research.microsoft.com/~gray/Papers/MSR_TR_99_29_TerraServer.doc
• SkyServer & Virtual Sky– Both image and semantic data in a relational store.– Parallel search & NonProcedural access are important.– http://research.microsoft.com/~gray/Papers/MS_TR_99_30_Sloan_Digital_Sky_Survey.doc
– http://skyserver.sdss.org/getMosaic.asp?Z=1&A=1&T=4&H=1&S=10&M=30– http://virtualsky.org/servlet/Page?F=3&RA=16h+10m+1.0s&DE=
%2B0d+42m+45s&T=4&P=12&S=10&X=5096&Y=4121&W=4&Z=-1&tile.2.1.x=55&tile.2.1.y=20
http://research.microsoft.com/~gray/talks/cern_2001.ppt19
OK… Why don’t they use our stuff?
• Wrong metaphor: HDF with hyper-slab is better match.
• Impedance match: Getting stuff in/out of DB is too hard
• We sold them OODBs and they did not work (unreliable, poor performance, no tools).
• …
http://research.microsoft.com/~gray/talks/cern_2001.ppt20
So, why will the future be different?
• They have MUCH more data (109 files?)
• Java / C# eases impedance mismatch: rowsets == ragged arrays of objectsiterators, exceptions,.. built in language
• Tools are better– Optimizers are better– CPU and disk parallelism actually works now– Statistical packages are better.
http://research.microsoft.com/~gray/talks/cern_2001.ppt21
Outline• Store Everything• Online (Disk not Tape)
• In a Database• A Federated DB• Two Examples
http://research.microsoft.com/~gray/talks/cern_2001.ppt22
But… Distributed shared databases have failed
even on their home turf.
blocks, files, tables are wrong abstraction for networks.(too low level)
“Objects are the right abstraction”
So, UDDI / WSDL / SOAP is the solution (not SQL)
Replays the NAS is better than SAN argument:
methods > sql > file > diskXML is the wire format, XLANG is the workflow protocol, Query will be in there somewhere.
http://research.microsoft.com/~gray/talks/cern_2001.ppt23
DDB technology GREAT in a Cluster Beowulf
• Uniform architecture
• Trust among nodes
• High bandwidth-low latency communication
• Programs have single system image
• Queries run in parallel
• Global optimizer does query decomposition
http://research.microsoft.com/~gray/talks/cern_2001.ppt24
But in a Distributed System(a Grid vs Beowulf)
• Higher level abstraction give modularity
minimize round trips
• Change is constant: need modularity.
• Heterogeneous architecture makes query planning much harder
• No trust
• Communication is slow and expensive (minimize it).
http://research.microsoft.com/~gray/talks/cern_2001.ppt25
Federate Databases• Each Database exposes services
– Self describing
– Discoverable
– Easy for programs to use/understand
– Built on standards (W3C, IETF,..)
• Client-side or server-side apps– Integrate these services
– Combine information to produce answers
http://research.microsoft.com/~gray/talks/cern_2001.ppt27
Outline• Store Everything• Online (Disk not Tape)
• In a Database• A Federated DB• Two Examples
http://research.microsoft.com/~gray/talks/cern_2001.ppt28
How do we find information today?
• Human searches web (with an index)
• Human browses pages
http://research.microsoft.com/~gray/talks/cern_2001.ppt29
How do we find information tomorrow?
• Agents gather and digest it for us.
• Q: How?
• AW3C:
– Discovery: UDDI, DISCO, WSDL
– Use: • SOAP
My Agents
Digital Dashboard
Web Services
SOAPWSDL
http://research.microsoft.com/~gray/talks/cern_2001.ppt30
How do we publish information?• Get the data.
• Conceptualize the data schema • Provide methods that return data subsets.
– Challenge: how much processing on your server?
• Publish the schema and methods.
• We (you and I) are exploring these issues.
f, g, x, y…
http://research.microsoft.com/~gray/talks/cern_2001.ppt31
TerraServer Example• TerraServer
– 3TB Internet Map DB available since June 1998
– USGS photo and topo maps of the US
– Integrated with Home Advisor
– Shows off SQL Server availability & scalability
– Designed for thin clients and voice network
• TerraService
– A .NET web service
– Makes TerraServer data available to other apps
http://research.microsoft.com/~gray/talks/cern_2001.ppt32
Demo http://terraserver.microsoft.com
Show
photo
topo
gazetteer
demographics
http://research.microsoft.com/~gray/talks/cern_2001.ppt33
TerraServer Experience• Successful Web Site
– Top 1000 Web Site – continues to be popular– Met goals – interesting, big, real, public, fast,
easy, accessible, and free– High Availability – Windows Data Center &
Compaq SAN Technology
• New Feature Requests– Programmable access to meta-data– User selectable image sizes, i.e. “a map server”– Permission to use TerraServer data within
server applications
http://research.microsoft.com/~gray/talks/cern_2001.ppt34
What is a Web Service?
SOAPSOAPSOAPSOAP Web Service consumers can send and receive messages using XML
WSDLWSDLContract LanguageContract Language
WSDLWSDLContract LanguageContract Language
Web Services are defined in terms of the formats and ordering of messages
DISCODISCODiscoveryDiscoveryDISCODISCO
DiscoveryDiscovery You can ask a site for a description of the
Web Services it offers
All these capabilities are built using open Internet protocols XML & HTTPXML & HTTP
Open Internet Protocols
Web Web ServiceService
A programmable application component accessible via standard Web protocols
UDDIUDDIUniversal Description, Design, and IntegrationUniversal Description, Design, and Integration
UDDIUDDIUniversal Description, Design, and IntegrationUniversal Description, Design, and Integration
Provide a Directory of Services on the Internet
http://research.microsoft.com/~gray/talks/cern_2001.ppt35
TerraService Architecture
ExistingDB Server
SQL 2000
1.0 TB Db
SQL 2000
1.0 TB Db
SQL 2000
1.0 TB Db
705 m Rows705 m Rows
ADO.NETADO.NETADO.NETADO.NET
TerraServer TerraServer Web ServiceWeb Service
OLEDB
Map Server Map Server Http HandlerHttp Handler
Map UI Map UI Web FormsWeb FormsStandardStandard
BrowsersBrowsersStandardStandardBrowsersBrowsers
SmartSmartClientsClientsSmartSmartClientsClients
SOAP/XML
HTMLImage/jpeg
Image/jpeg
http://research.microsoft.com/~gray/talks/cern_2001.ppt36
Terra Services
• Query Gazetteer• Retrieve imagery
meta-data • Retrieve imagery • Simple Projection
conversions
• Geo-coded places, e.g. Schools, Golf Courses, Hospitals, etc.
• Place Polygons e.g. Zip Codes, Cities, etc.
Terra-Tile-Service Landmark-Service
allows “overlay” information for Terra-Tile-Service applications
Clients can present TerraServer imageryin new ways.
http://research.microsoft.com/~gray/talks/cern_2001.ppt37
Terra ServicesPlace Search
– GetPlaceFacts– GetPlaceList– GetPlaceListInRect– CountPlacesInRect
Projection– ConvertLonLatToUtm– ConvertUtmToLonLat– ConvertLonLatTo
NearestPlace – GetTheme– GetLatLonMetrics
• Tile– GetAreaFromPt
– GetAreaFromRect
– GetAreaFromTileId
– GetTileMetaFromLonLat
– GetTileMetaFromTileId
– GetTile (Image)
• Landmark– GetLandmarkTypes
– CountOfLandmarkPointsByRect
– GetLandmarkPointsByRect
– CountOfLandmarkShapesByRect
– GetLandmarkShapesByRect
http://terraservice.net
http://research.microsoft.com/~gray/talks/cern_2001.ppt38
Soil Viewer Uses TerraService
http://research.microsoft.com/~gray/talks/cern_2001.ppt39
Custom End ProductWeb Soil Data Viewer XML Soil ReportSoil Interpretation Map
http://research.microsoft.com/~gray/talks/cern_2001.ppt40
What You Saw• Converted a Web Server
–HTML get post
–Server returns pictures to people
• to a Web Service–SOAP service
–returns XML self-describing data
–Application integrates data (Agriculture and Geo data)
http://research.microsoft.com/~gray/talks/cern_2001.ppt42
SkyServer
Collaborating with:
Alex Szalay, Peter Kunszt, Ani Thakar @ JHURobert Brunner, Roy Williams @ Caltech
George Djorgovski, Julian Bunn @ CaltechFermiLab operates Sky Server
Compaq donated hardwareMicrosoft donated software and money
http://research.microsoft.com/~gray/talks/cern_2001.ppt43
Sky Server– Like TerraServer pictures of the sky.
– But also LOTS of data on each object
So a data mining web service• Luminosity (multi-spectra), morphology, spectrum• So, it is a data mining application• Cross-correlation is challenging because
–Multi-resolution–Data is dirty/fuzzy (error bars, cosmic rays, airplanes…)
–Time varying
+
•50 K Spectro Objects •~ 100 attributes + 30 lines
•15M Photo Objects ~ 400 attributes
http://research.microsoft.com/~gray/talks/cern_2001.ppt44
Astronomy Data• In the “old days” astronomers took photos.
• Starting in the 1960’s they began to digitize.• New instruments are digital (100s of GB/nite)
• Detectors are following Moore’s law.
• Data avalanche: double every year
Total area of 3m+ telescopes in the world in m2, total number of CCD pixels in megapixel, as a function of time. Growth over 25 years is a factor of 30 in glass, 3000 in pixels.
Courtesy of
Alex Szalay
http://research.microsoft.com/~gray/talks/cern_2001.ppt45
Astronomy Data• Astronomers have a few Petabytes now.
– 1 pixel (byte) / sq arc second ~ 4TB– Multi-spectral, temporal, … → 1PB
• They mine it looking for new (kinds of) objects or more of interesting ones(quasars), density variations in 400-D space correlations in 400D space
• Data doubles every year.• Data is public after a year.• So, 50% of the data is public.• Some have private access to 5% more data.• So: 50% vs 55% access for everyone
http://research.microsoft.com/~gray/talks/cern_2001.ppt46
Astronomy Data• But…..• How do I get at that 50% of the data?• Astronomers have culture of publishing.
– FITS files and many tools.http://fits.gsfc.nasa.gov/fits_home.html
– Encouraged by NASA.• Publishing data “details” is difficult.
Astronomers want to do it but it is VERY hard.(What programs where used? what were the processing steps? How were errors treated?…)
• File is wrong abstraction.
http://research.microsoft.com/~gray/talks/cern_2001.ppt47
Virtual Observatoryhttp://www.astro.caltech.edu/nvoconf/
http://www.voforum.org/
• Premise: Most data is (or could be online)
• So, the Internet is the world’s best telescope:– It has data on every part of the sky– In every measured spectral band: optical, x-ray, radio..
– As deep as the best instruments (1 year ago).– It is up when you are up.
The “seeing” is always great (no working at night, no clouds no moons no..).
– It’s a smart telescope: links objects and data to literature on them.
http://research.microsoft.com/~gray/talks/cern_2001.ppt48
Virtual Observatory Golden Age of Mega-Surveys
• Many new surveys– multi-TB in size, 100 million objects or more– individual archives planned, or under way– Data publication an integral part of the survey– Software bill a major cost in the survey
• Multi-wavelength view of the sky– more than 13 wavelength coverage in 5 years
• Impressive early discoveries– finding exotic objects by unusual colors
• L,T dwarfs, high-z quasars
– finding objects by time variability• gravitational micro-lensing
MACHO2MASSDENISSDSSPRIMEDPOSSGSC-IICOBE MAPNVSSFIRSTGALEXROSATOGLE ...
MACHO2MASSDENISSDSSPRIMEDPOSSGSC-IICOBE MAPNVSSFIRSTGALEXROSATOGLE ...
Slide courtesy of Alex Szalay, modified by jim
http://research.microsoft.com/~gray/talks/cern_2001.ppt49
Virtual Observatory Federating the Archives
• The next generation mega-surveys are different– top-down design– large sky coverage– sound statistical plans– well controlled/documented data processing
• Each survey has a publication plan• Data mining will lead to stunning new discoveries
• Federating these archives
Virtual Observatory
Slide courtesy of Alex Szalay
http://research.microsoft.com/~gray/talks/cern_2001.ppt50
The Multiwavelength Crab Nebula
Nova first sighted 1054 A.D. by
Chinese Astronomers
Now: Crab Nebula X-ray, optical,
infrared, and radio
Slide courtesy of Robert Brunner @ CalTech.
Crab star 1053 AD
http://research.microsoft.com/~gray/talks/cern_2001.ppt52
Virtual Observatory and Education• In the beginning science was empirical.
• Then theoretical branches evolved.
• Now, we have a computational branches.– The computational branch has been simulation– It is becoming data analysis/visualization
• The Virtual Observatory can be used to – Teach astronomy:
make it interactive, demonstrate ideas and phenomena
– Teach computational science skillsand the process of scientific discovery
http://research.microsoft.com/~gray/talks/cern_2001.ppt53
Sloan Digital Sky Survey http://sdss.org/
• A group of astronomers has been building a telescope (with 90M$ from Sloan Foundation, NSF, and a dozen universities). for the last 12 years
• Now data is arriving: – 250GB/nite (20 nights per year).– 100 M stars, 100 M galaxies, 1 M spectra.
• Public data at http://sdss.org/ – 5% of the survey, 600 sq degrees, 15 M objects 60GB.– This data includes most of the known high z quasars.– It has a lot of science left in it but… that is just the start.
http://research.microsoft.com/~gray/talks/cern_2001.ppt54
Demo of Sky ServerAlex built SkyServer (based on TerraServer design).
http://skyserver.sdss.org/
Demo: famous places navigator data shopping cart spectrum SQL? ?
http://research.microsoft.com/~gray/talks/cern_2001.ppt55
Virtual Observatory Challenges• Size : multi-Petabyte
40,000 square degrees is 2 Trillion pixels
– One band (at 1 sq arcsec) 4 Terabytes– Multi-wavelength 10-100 Terabytes– Time dimension >> 10 Petabytes
– Need auto parallelism tools
• Unsolved Meta-Data problem– Hard to publish data & programs– Hard to find/understand data & programs
• Current tools inadequate– new analysis & visualization tools
• Transition to the new astronomy– Sociological issues
http://research.microsoft.com/~gray/talks/cern_2001.ppt56
The Challenges• How to federate the Archives to make a VO?
• The hope: XML is the answer.• The reality: XML is syntax and tools:
FITS on XML will be good but….. Explaining the data will still be very difficult.
• Define Astronomy Objects and Methods.– Based on UDDI, WSDL, SOAP.– Each archive is a service
• http://TerraService.net/ shows the idea.– Working with Caltech (Brunner, Williams, Djorgovski, Bunn)
– But, how does data mining work?
http://research.microsoft.com/~gray/talks/cern_2001.ppt57
Three Steps to a VO 0.01
• Get SDSS and Palomar online– Alex Szalay, Jan Vandenberg, Ani Thakar….– Roy Williams, Robert Brunner, Julian Bunn
• Do queries and crossID matches with CalTech and SDSS to expose – Schema, Units,…– Dataset problems– the typical use scenarios.
• Implement WebServices at CalTech and SDSS
http://research.microsoft.com/~gray/talks/cern_2001.ppt58
Summary• All information at your fingertips.
• How do we publish information so that our agents can digest it?
• Example: TerraServer -> TerraService
• The Virtual Observatory Concept
– The Internet is worlds best telescope• For astronomy• For teaching astronomy and • For teaching computational science
http://research.microsoft.com/~gray/talks/cern_2001.ppt59
Outline• Store Everything• Online (Disk not Tape)
• In a Database• A Federated DB• Two Examples
http://research.microsoft.com/~gray/talks/cern_2001.ppt60
No time for what follows
http://research.microsoft.com/~gray/talks/cern_2001.ppt61
SDSS what I have been doing• Work with Alex Szalay, Don Slutz, and others
to define 20 canonical queries and 10 visualization tasks.
• Don Slutz did a first cut of the queries, I’m continuing that work.
• Working with Alex Szalay on building Sky Server and making data it public
(send out 80GB SQL DBs)
http://research.microsoft.com/~gray/talks/cern_2001.ppt62
Two kinds of SDSS data• 15M Photo Objects ~ 400 attributes
20K Spectra with ~10 lines/spectrum
http://research.microsoft.com/~gray/talks/cern_2001.ppt63
Spatial Data Access(Szalay, Kunszt, Brunner)
http://www.sdss.jhu.edu/ look at the HTM link
• Implemented Hierarchical Triangular Mesh (HTM) as table-valued function for spatial joins.
• Every object has a 20-deep Mesh ID.
• Given a spatial definition:Routine returns up to 500 covering triangles.
• Spatial query is then up to 500 range queries.
• Very fast: 1,000s of triangles per second.
http://research.microsoft.com/~gray/talks/cern_2001.ppt64
The 20 QueriesQ11: Find all elliptical galaxies with spectra that have an
anomalous emission line. Q12: Create a grided count of galaxies with u-g>1 and r<21.5
over 60<declination<70, and 200<right ascension<210, on a grid of 2’, and create a map of masks over the same grid.
Q13: Create a count of galaxies for each of the HTM triangles which satisfy a certain color cut, like 0.7u-0.5g-0.2i<1.25 && r<21.75, output it in a form adequate for visualization.
Q14: Find stars with multiple measurements and have magnitude variations >0.1. Scan for stars that have a secondary object (observed at a different time) and compare their magnitudes.
Q15: Provide a list of moving objects consistent with an asteroid.
Q16: Find all objects similar to the colors of a quasar at 5.5<redshift<6.5.
Q17: Find binary stars where at least one of them has the colors of a white dwarf.
Q18: Find all objects within 30 arcseconds of one another that have very similar colors: that is where the color ratios u-g, g-r, r-I are less than 0.05m.
Q19: Find quasars with a broad absorption line in their spectra and at least one galaxy within 10 arcseconds. Return both the quasars and the galaxies.
Q20: For each galaxy in the BCG data set (brightest color galaxy), in 160<right ascension<170, -25<declination<35 count of galaxies within 30"of it that have a photoz within 0.05 of that galaxy.
Q1: Find all galaxies without unsaturated pixels within 1' of a given point of ra=75.327, dec=21.023
Q2: Find all galaxies with blue surface brightness between and 23 and 25 mag per square arcseconds, and -10<super galactic latitude (sgb) <10, and declination less than zero.
Q3: Find all galaxies brighter than magnitude 22, where the local extinction is >0.75.
Q4: Find galaxies with an isophotal surface brightness (SB) larger than 24 in the red band, with an ellipticity>0.5, and with the major axis of the ellipse having a declination of between 30” and 60”arc seconds.
Q5: Find all galaxies with a deVaucouleours profile (r¼ falloff of intensity on disk) and the photometric colors consistent with an elliptical galaxy. The deVaucouleours profile
Q6: Find galaxies that are blended with a star, output the deblended galaxy magnitudes.
Q7: Provide a list of star-like objects that are 1% rare.Q8: Find all objects with unclassified spectra. Q9: Find quasars with a line width >2000 km/s and
2.5<redshift<2.7. Q10: Find galaxies with spectra that have an equivalent width
in Ha >40Å (Ha is the main hydrogen spectral line.)
Also some good queries at: http://www.sdss.jhu.edu/ScienceArchive/sxqt/sxQT/Example_Queries.html
http://research.microsoft.com/~gray/talks/cern_2001.ppt65
An easy oneQ7: Provide a list of star-like objects that are 1% rare.
• Found 14,681 buckets, first 140 buckets have 99% time 104 seconds
• Disk bound, reads 3 disks at 68 MBps.
Select cast((u-g) as int) as ug, cast((g-r) as int) as gr, cast((r-i) as int) as ri, cast((i-z) as int) as iz,count(*) as Population
from starswhere (u+g+r+i+z) < 150group by cast((u-g) as int), cast((g-r) as int), cast((r-i) as int), cast((i-z) as int) order by count(*)
http://research.microsoft.com/~gray/talks/cern_2001.ppt66
Another easy oneQ15: Provide a list of moving objects consistent with an
asteroid. • Looks hard but there are 5 pictures of the
object at 5 different times (colors) and so can compute velocity.
• Image pipeline computes velocity.
• Computing it from the 5 color x,y would also be fast
• Finds 2167 objects in 7 minutes, 70MBps.select object_id, -- return object ID sqrt(power(rowv,2)+power(colv,2)) as velocity from sxPhotObj -- check each object.where (power(rowv,2) + power(colv, 2)) > 50 -- square of velocity and rowv >= 0 and colv >=0 -- negative values indicate error
http://research.microsoft.com/~gray/talks/cern_2001.ppt67
A Hard One Q14: Find stars with multiple measurements
that have magnitude variations >0.1. • This should work, but SQL Server does not
allow table values to be piped to table-valued functions.
• This should work, but SQL Server does not allow table values to be piped to table-valued functions.
select S.object_ID, S1.object_ID -- return stars that from Stars S, -- S is a star
getNearbyObjEq(s.ra, s.dec, 0.017) as N -- N within 1 arcsec (3 pixels) of S.
Stars S1 -- N == S1 (S1 gets the colors) where S.Object_ID < N.Object_ID -- S1 different from S == N and N.Type = dbo.PhotoType('Star') -- S1 is a star (an optimization) and N.object_ID = S1.Object_ID -- N == S1 and ( abs(S.u-S1.u) > 0.1 -- one of the colors is different. or abs(S.g-S1.g) > 0.1
or abs(S.r-S1.r) > 0.1or abs(S.i-S1.i) > 0.1or abs(S.z-S1.z) > 0.1
) order by S.object_ID, S1.object_ID -- group the answer by parent star.
Returns a table of nearby objects
http://research.microsoft.com/~gray/talks/cern_2001.ppt68
A Hard one: Second TryQ14: Find stars with multiple measurements that
have magnitude variations >0.1. --------------------------------------------------------------------------------- Table-valued function that returns the binary stars within a certain radius -- of another (in arc-minutes) (typically 5 arc seconds).-- Returns the ID pairs and the distance between them (in arcseconds).create function BinaryStars(@MaxDistanceArcMins float)returns @BinaryCandidatesTable table(
S1_object_ID bigint not null, -- Star #1S2_object_ID bigint not null, -- Star #2distance_arcSec float) -- distance between them
as begin declare @star_ID bigint, @binary_ID bigint;-- Star's ID and binary ID declare @ra float, @dec float; -- Star's position declare @u float, @g float, @r float, @i float,@z float; -- Star's colors ----------------Open a cursor over stars and get position and colors declare star_cursor cursor for select object_ID, ra, [dec], u, g, r, i, z from Stars; open star_cursor; while (1=1) -- for each star
begin -- get its attribuesfetch next from star_cursor into @star_ID, @ra, @dec, @u, @g, @r, @i, @z;if (@@fetch_status = -1) break; -- end if no more starsinsert into @BinaryCandidatesTable -- insert its binaries
select @star_ID, S1.object_ID, -- return stars pairs sqrt(N.DotProd)/PI()*10800 -- and distance in arc-seconds
from getNearbyObjEq(@ra, @dec, -- Find objects nearby S.@MaxDistanceArcMins) as N, -- call them N.
Stars as S1 -- S1 gets N's color valueswhere @star_ID < N.Object_ID -- S1 different from S
and N.objType = dbo.PhotoType('Star') -- S1 is a starand N.object_ID = S1.object_ID -- join stars to get colors of S1==N
and (abs(@u-S1.u) > 0.1 -- one of the colors is different. or abs(@g-S1.g) > 0.1
or abs(@r-S1.r) > 0.1 or abs(@i-S1.i) > 0.1 or abs(@z-S1.z) > 0.1
) end; -- end of loop over all stars
-------------- Looped over all stars, close cursor and exit. close star_cursor; -- deallocate star_cursor; return; -- return tableend -- end of BinaryStarsGOselect * from dbo.BinaryStars(.05)
• Write a program with a cursor, ran for 2 days
http://research.microsoft.com/~gray/talks/cern_2001.ppt69
A Hard one: Third TryQ14: Find stars with multiple measurements that
have magnitude variations >0.1.
• Use pre-computed neighbors table.
• Ran in 17 minutes, found 31k pairs.
==================================================================================-- Plan 2: Use the precomputed neighbors table select top 100 S.object_ID, S1.object_ID, -- return star pairs and distance
str(N.Distance_mins * 60,6,1) as DistArcSec from Stars S, -- S is a star
Neighbors N, -- N within 3 arcsec (10 pixels) of S.Stars S1 -- S1 == N has the color attibutes
where S.Object_ID = N.Object_ID -- connect S and N. and S.Object_ID < N.Neighbor_Object_ID -- S1 different from S and N.Neighbor_objType = dbo.PhotoType('Star')-- S1 is a star (an optimization) and N.Distance_mins < .05 -- the 3 arcsecond test and N.Neighbor_object_ID = S1.Object_ID -- N == S1 and ( abs(S.u-S1.u) > 0.1 -- one of the colors is different. or abs(S.g-S1.g) > 0.1
or abs(S.r-S1.r) > 0.1or abs(S.i-S1.i) > 0.1or abs(S.z-S1.z) > 0.1
) -- Found 31,355 pairs (out of 4.4 m stars) in 17 min 14 sec.
http://research.microsoft.com/~gray/talks/cern_2001.ppt70
The Pain of Going Outside SQL(its fortunate that all the queries are single statements)
• Count parent objects • 503 seconds
for 14.7 M objects in 33.3 GB
• 66 MBps• IO bound (30% of one cpu)
• 100 k records/cpu sec
• Use a cursor• No cpu parallelism• CPU bound • 6 MBps, 2.7 k rps• 5,450 seconds (10x slower)
select count(*) from sxPhotoObj where nChild > 0
declare @count int;declare @sum int;set @sum = 0;declare PhotoCursor cursor for select nChild from sxPhotoObj; open PhotoCursor;while (1=1) begin fetch next from PhotoCursor into @count; if (@@fetch_status = -1) break; set @sum = @sum + @count; endclose PhotoCursor;deallocate PhotoCursor;
print 'Sum is: '+cast(@sum as varchar(12))
http://research.microsoft.com/~gray/talks/cern_2001.ppt71
Summary of Current Status
• All 20 queries run(still checking science)
• Also 15 “user” queries• Run times: on 3k$ PC
(2 cpu, 4 disk, 256MB)
0.01
0.1
1
10
100
1000
10000
Q01 Q02: Q03 Q04 Q05: Q06 Q07 Q08 Q09 Q10 Q10A Q11 Q12*** Q13 Q14 Q15 Q16 Q17 Q18 Q19* Q20 QSX01
cpu
elapsed
cpu vs IO
1E+0
1E+1
1E+2
1E+3
1E+4
1E+5
1E+6
1E+7
0.01 0.1 1. 10. 100. 1,000. 10,000.
CPU sec
IO c
ount
100 IOs/cpu sec
~100 IO/cpu sec ~5MB/cpu sec
http://research.microsoft.com/~gray/talks/cern_2001.ppt72
Summary of Current Status
• 16 of the queries are simple
• 2 are iterative, 2 complex
• Many are sequential one-pass and two-pass over data
• Covering indices make scans run fast
• Table valued functions are wonderful but limitations on parameters are a pain.
• Counting is VERY common.
• Binning (grouping by some set of attributes) is common
• Did not request cube, but that may be cultural.
http://research.microsoft.com/~gray/talks/cern_2001.ppt73
Reflections on the 20 Queries • Data loading/scrubbing is labor intensive & tedious
– AUTOMATE!!!
• This is 5% of the data, and some queries take an hour.• But this is not tuned (disk bound).• All queries benefit from parallelism (both disk and cpu)
(if you can state the query right, e.g. inside SQL).• Parallel database machines will do great on this:
– Hash machines – Data pumps– See paper in word or pdf on my web site.
• SQL looks good. The answers, need visualization
http://research.microsoft.com/~gray/talks/cern_2001.ppt74
Call to Action• If you do data visualization: we need you
(and we know it).• If you do databases:
here is some data you can practice on.• If you do distributed systems:
here is a federation you can practice on.• If you do astronomy educational outreach
here is a tool for you.• The astronomy folks are very good, and very
smart, and a pleasure to work with, and the questions are cosmic, so …