The Data Avalanche

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The Data Avalanche

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Title: The Data Avalanche

1
The Data Avalanche
Talk at National Youth Leadership Forum on
Technology, aka nerd camp July 2004

Jim Gray
Microsoft Research
Gray_at_Microsoft.com
http//research.microsoft.com/Gray

2
NumbersTeraBytes and Gigabytes are BIG!

Mega a house in san francisco
Giga a very rich person
Tera The Bush national debt
Peta more than all the money in the world
A Gigabyte the Human Genome
A Terabyte 150 mile long shelf of books.

3
Outline
Yotta Zetta Exa Peta Tera Giga Mega Kilo

Historical trends imply that in 20 years
we can store everything in cyberspace.The
personal petabyte.
computers will have natural interfacesspeech
recognition/synthesisvision, object recognition
beyond OCR
Implications
The information avalanche will only get worse.
The user interface will change less typing,
more writing, talking, gesturing, more seeing
and hearing
Organizing, summarizing, prioritizinginformation
is a key technology.

We are here
4
How much information is there?
Yotta Zetta Exa Peta Tera Giga Mega Kilo

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 information
http//www.sims.berkeley.edu/research/projects/how
-much-info/

Everything! Recorded
All Books MultiMedia
All books (words)
.Movie
A Photo
A Book
24 Yecto, 21 zepto, 18 atto, 15 femto, 12 pico, 9
nano, 6 micro, 3 milli
5
Things Have Changed
1956

IBM 305 RAMAC
10 MB disk
1M (y2004 )

6
The Next 50 years will see MORE CHANGE ops/s/
Had Three Growth Curves 1890-1990
Combination of Hans Moravac Larry Roberts
Gordon Bell WordSizeops/s/sysprice

1890-1945
Mechanical
Relay
7-year doubling
1945-1985
Tube, transistor,..
2.3 year doubling
1985-2004
Microprocessor
1.0 year doubling

7
Constant Cost or Constant Function?

100x improvement per decade
Same function 100x cheaper
100x more function for same price

Mainframe
SMP
Constellation
Cluster
Constant Price
Mini
SMP
Constellation
Workstation
Graphics/storage
Lower Price New Category
PDA
Camera/browser
8
Growth Comes From NEW Apps

The 10M computer of 1980 costs 1k today
If we were still doing the same things,IT would
be a 0 B/y industry
NEW things absorb the new capacity

9
The Surprise-Free Futurein 20 years.

10,000x more power for same price
Personal supercomputer
Personal petabyte stores
Same function for 10,000x less cost.
Smart dust --the penny PC?
The 10 peta-op computer (for 1,000).

10
10,000x would change things

Human computer interface
Decent computer vision
Decent computer speech recognition
Decent computer speech synthesis
Vast information stores
Ability to search and abstract the stores.

11
How Good is HCI Today?

Surprisingly good.
Demo of making faces
http//research.microsoft.com/research/pubs/view.
aspx?pubid290
Demo of speech synthesis
Daisy, Hal
Synthetic voice
Speech recognition is improving fast,
Vision getting better
Pen computing finally a reality.
Displays improving fast (compared to last 30
years)

12
Outline
Yotta Zetta Exa Peta Tera Giga Mega Kilo

Historical trends imply that in 20 years
we can store everything in cyberspace.The
personal petabyte.
computers will have natural interfacesspeech
recognition/synthesisvision, object recognition
beyond OCR
Implications
The information avalanche will only get worse.
The user interface will change less typing,
more writing, talking, gesturing, more seeing
and hearing
Organizing, summarizing, prioritizinginformation
is a key technology.

We are here
13
How much information is there?
Yotta Zetta Exa Peta Tera Giga Mega Kilo

Almost everything is recorded digitally.
Most bytes are never 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 information
http//www.sims.berkeley.edu/research/projects/how
-much-info/

Everything! Recorded
All Books MultiMedia
All books (words)
.Movie
A Photo
A Book
14
And gt90 in Cyberspace Because
Low rent min /byte Shrinks time now or
later Shrinks space here or there Automate
processing knowbots
Point-to-Point OR Broadcast
Immediate OR Time Delayed
Locate Process Analyze Summarize
15
MyLifeBits The guinea pig

Gordon Bell is digitizing his life
Has now scanned virtually all
Books written (and read when possible)
Personal documents (correspondence, memos,
email, bills, legal,0)
Photos
Posters, paintings, photo of things (artifacts,
medals, plaques)
Home movies and videos
CD collection
And, of course, all PC files
Recording phone, radio, TV, web pages
conversations
Paperless throughout 2002. 12 scanned, 12
discarded.
Only 30GB Excluding videos
Video is 2 TB and growing fast

16
Capture and encoding
17
I mean everything
18
25Kday life Personal Petabyte
1PB
Will anyone look at web pages in 2020?
Probably new modalities media will dominate
then.
19
Challenges

Capture Get the bits in
Organize Index them
Manage No worries about loss or space
Curate/ Annotate atutomate where possible
Privacy Keep safe from theft.
Summarize Give thumbnail summaries
Interface how ask/anticipate questions
Present show it in understandable ways.

20
MemexAs We May Think, Vannevar Bush, 1945

A memex is a device in which an individual
stores all his books, records, and
communications, and which is mechanized so that
it may be consulted with exceeding speed and
flexibility
yet if the user inserted 5000 pages of material
a day it would take him hundreds of years to fill
the repository, so that he can be profligate and
enter material freely

21
Too much storage?Try to fill a terabyte in a year
Item Items/TB Items/day
300 KB JPEG 3 M 9,800
1 MB Doc 1 M 2,900
1 hour 256 kb/s MP3 audio 9 K 26
1 hour 1.5 Mbp/s MPEG video 290 0.8
Petabyte volume has to be some form of video.
22
How Will We Find Anything?

Need Queries, Indexing, Pivoting, Scalability,
Backup, Replication,Online update, Set-oriented
access
If you dont use a DBMS, you will implement one!
Simple logical structure
Blob and link is all that is inherent
Additional properties (facets extra
tables)and methods on those tables
(encapsulation)
More than a file system
Unifies data and meta-data

SQL DBMS
23
Photos
24
Searching the most useful app?

Challenge What questions for useful results?
Many ways to present answers

25
(No Transcript)
26
Detail view
27
Resource explorerAncestor (collections),
annotations, descendant preview panes turned on
28
Synchronized timelines with histogram guide
29
Value of media depends on annotations

Its just bits until it is annotated

30
System annotations provide base level of value

Date 7/7/2000

31
Tracking usage even better

Date 7/7/2000. Opened 30 times, emailed to 10
people (its valued by the user!)

32
Get the user to say a little something is a big
jump

Date 7/7/2000. Opened 30 times, emailed to 10
people. BARC dim sum intern farewell Lunch

33
Getting the user to tell a story is the ultimate
in media value

A story is a layout in time and space
Most valuable content (by selection, and by being
well annotated)
Stories must include links to any media they use
(for future navigation/search transclusion).
Cf MovieMaker Creative Memories PhotoAlbums

34
Value of media depends on annotations
Its just bits until it is annotated

Auto-annotate whenever possible e.g. GPS cameras
Make manual annotation as easy as possible. XP
photo capture, voice, photos with voice, etc
Support gang annotation
Make stories easy

35
80 of data is personal / individual. But, what
about the other 20?

Business
Wall Mart online 1PB and growing.
Paradox most transaction systems lt 1 PB.
Have to go to image/data monitoring for big data
Government
Government is the biggest business.
Science
LOTS of data.

36
Instruments CERN LHCPeta Bytes per Year

Looking for the Higgs Particle
Sensors 1000 GB/s (1TB/s 30 EB/y)
Events 75 GB/s
Filtered 5 GB/s
Reduced 0.1 GB/s 2 PB/y
Data pyramid 100GB 1TB 100TB 1PB 10PB

37
Information Avalanche

Both
better observational instruments and
Better simulations
are producing a data avalanche
Examples
Turbulence 100 TB simulation then mine the
Information
BaBar Grows 1TB/day 2/3 simulation Information
1/3 observational Information
CERN LHC will generate 1GB/s 10 PB/y
VLBA (NRAO) generates 1GB/s today
NCBI only ½ TB but doubling each year, very
rich dataset.
Pixar 100 TB/Movie

Image courtesy of C. Meneveau A. Szalay _at_ JHU
38
Q Where will the Data Come From?A Sensor
Applications

Earth Observation
15 PB by 2007
Medical Images Information Health Monitoring
Potential 1 GB/patient/y ? 1 EB/y
Video Monitoring
1E8 video cameras _at_ 1E5 MBps ? 10TB/s ? 100
EB/y ? filtered???
Airplane Engines
1 GB sensor data/flight,
100,000 engine hours/day
30PB/y
Smart Dust ?? EB/y

http//robotics.eecs.berkeley.edu/pister/SmartDus
t/
http//www-bsac.eecs.berkeley.edu/shollar/macro_m
otes/macromotes.html
39
The Big Picture
Experiments Instruments
facts
questions
?
facts
Other Archives
answers
facts
Literature
facts
Simulations
The Big Problems

Data ingest
Managing a petabyte
Common schema
How to organize it?
How to reorganize it
How to coexist with others

Query and Vis tools
Support/training
Performance
Execute queries in a minute
Batch query scheduling

40
FTP - GREP

Download (FTP and GREP) are not adequate
You can GREP 1 MB in a second
You can GREP 1 GB in a minute
You can GREP 1 TB in 2 days
You can GREP 1 PB in 3 years.
Oh!, and 1PB 3,000 disks
At some point we need indices to limit
search parallel data search and analysis
This is where databases can help
Next generation technique Data Exploration
Bring the analysis to the data!

41
The Speed Problem

Many users want to search the whole DBad hoc
queries, often combinatorial
Want 1 minute response
Brute force (parallel search)
1 disk 50MBps gt 1M disks/PB 300M/PB
Indices (limit search, do column store)
1,000x less equipment 1M/PB
Pre-compute answer
No one knows how do it for all questions.

42
Next-Generation Data Analysis

Looking for
Needles in haystacks the Higgs particle
Haystacks Dark matter, Dark energy
Needles are easier than haystacks
Global statistics have poor scaling
Correlation functions are N2, likelihood
techniques N3
As data and computers grow at same rate, we can
only keep up with N logN
A way out?
Relax notion of optimal (data is fuzzy, answers
are approximate)
Dont assume infinite computational resources or
memory
Combination of statistics computer science

43
Analysis and Databases

Much statistical analysis deals with
Creating uniform samples
data filtering
Assembling relevant subsets
Estimating completeness
censoring bad data
Counting and building histograms
Generating Monte-Carlo subsets
Likelihood calculations
Hypothesis testing
Traditionally these are performed on files
Most of these tasks are much better done inside a
database
Move Mohamed to the mountain, not the mountain to
Mohamed.

44
Outline
Yotta Zetta Exa Peta Tera Giga Mega Kilo

Historical trends imply that in 20 years
we can store everything in cyberspace.The
personal petabyte.
computers will have natural interfacesspeech
recognition/synthesisvision, object recognition
beyond OCR
Implications
The information avalanche will only get worse.
The user interface will change less typing,
more writing, talking, gesturing, more seeing
and hearing
Organizing, summarizing, prioritizinginformation
is a key technology.

We are here
45
Information Avalanche

In science, industry, government,.
better observational instruments and
and, better simulations
producing a data avalanche
Examples
BaBar Grows 1TB/day 2/3 simulation Information
1/3 observational Information
CERN LHC will generate 1GB/s .10 PB/y
VLBA (NRAO) generates 1GB/s today
Pixar 100 TB/Movie
New emphasis on informatics
Capturing, Organizing, Summarizing, Analyzing,
Visualizing

Image courtesy C. Meneveau A. Szalay _at_ JHU
BaBar, Stanford
PE Gene Sequencer From http//www.genome.uci.edu/
Space Telescope
46
The Evolution of Science

Observational Science
Scientist gathers data by direct observation
Scientist analyzes data
Analytical Science
Scientist builds analytical model
Makes predictions.
Computational Science
Simulate analytical model
Validate model and makes predictions
Data Exploration Science Data captured by
instrumentsOr data generated by simulator
Processed by software
Placed in a database / files
Scientist analyzes database / files

47
e-Science

Data captured by instrumentsOr data generated by
simulator
Processed by software
Placed in a files or database
Scientist analyzes files / database
Virtual laboratories
Networks connecting e-Scientists
Strong support from funding agencies
Better use of resources
Primitive today

48
The Big Picture
Experiments Instruments
facts
questions
?
facts
Other Archives
answers
facts
Literature
facts
Simulations
The Big Problems

Data ingest
Managing a petabyte
Common schema
How to organize it?
How to reorganize it
How to coexist with others

Query and Vis tools
Support/training
Performance
Execute queries in a minute
Batch query scheduling

49
e-Science is Data Mining

There are LOTS of data
people cannot examine most of it.
Need computers to do analysis.
Manual or Automatic Exploration
Manual person suggests hypothesis, computer
checks hypothesis
Automatic Computer suggests hypothesis person
evaluates significance
Given an arbitrary parameter space
Data Clusters
Points between Data Clusters
Isolated Data Clusters
Isolated Data Groups
Holes in Data Clusters
Isolated Points

Nichol et al. 2001 Slide courtesy of and adapted
from Robert Brunner _at_ CalTech.
50
Data Analysis

Looking for
Needles in haystacks the Higgs particle
Haystacks Dark matter, Dark energy
Needles are easier than haystacks
Global statistics have poor scaling
Correlation functions are N2, likelihood
techniques N3
As data and computers grow at same rate, we can
only keep up with N logN
A way out?
Discard notion of optimal (data is fuzzy,
answers are approximate)
Dont assume infinite computational resources or
memory
Requires combination of statistics computer
science

51
TerraServer/TerraServicehttp//terraService.Net/

US Geological Survey Photo (DOQ) Topo (DRG)
images online.
On Internet since June 1998
Operated by Microsoft Corporation
Cross Indexed with
Home sales,
Demographics,
Encyclopedia
A web service
20 TB data source
10 M web hits/day

52
USGS Image Data

Digital Raster Graphics
1 TB compressed TIFF, 65,000 files
Scanned topographic maps
100 U.S. coverage
124,000, 1100,000 and 1250,000 scale maps
Maps vary in age

Digital OrthoQuads
18 TB, 260,000 files uncompressed
Digitized aerial imagery
88 coverage conterminous US
1 meter resolution
lt 10 years old

53
User Interface Concept
Display Imagery 316 m 200 x 200 pixel images 7
level image pyramid Resolution 1 meter/pixel to
64 meter/pixel Navigation Tools 1.5 m place
names Click-on Coverage map Longitude and
Latitude search U.S. Address Search External
Geo-Spatial Links to USGS On-line Stream
Gauges Home Advisor Demographics Home Advisor
Real Estate Encarta Articles Steam flow gauges
Concept User navigates an almost seamless
image of earth
Click on image to zoom in
Buttons to pan NW, N, NE, W, E, SW, S, SE
Links to switch between Topo, Imagery, and Relief
data
Links to Print, Download and view meta-data
information
54
Terra Service New Things

A popular web service
Exactly the map you want.
Dynamic Map Re-projection
UTM to Geographic projection
Dynamic texture mapping?
New Data
1 foot resolution natural color imagery
Census Tiger data
Lights Out Management
MOM
Auto-backup / restore on drive failure

55
New Urban Area Data
Microsoft Campus at 4 meter resolution
Redundant Bunch 1
Ball field at .25 meter resolution
56
TerraServer Becomes a Web ServiceTerraServer.net
-gt TerraService.Net

Web server is for people.
Web Service is for programs
The end of screen scraping
No faking a URL pass real parameters.
No parsing the answer data formatted into your
address space.
Hundreds of users but a specific example
US Department of Agriculture

57
TerraServer Web Services
Terra-Tile-Service
Landmark-Service

Get image meta-data
Query TS Gazetteer
Retrieve TS ImageTiles
Projection conversions
Web Map Client
OpenGIS like
Landmarks layered on TerraServer imagery

Geo-coded data of well-known objects (points),
e.g. Schools, Golf Courses, Hospitals, etc.
Polygons of well-known objects (shapes), e.g. Zip
Codes, Cities, etc
Fat Map Client
Visual Basic / C Windows Form
Access Web Services for all data

Sample Apps
http//terraservice.net
58
Web Services

Web SERVER
Given a url parameters
Returns a web page (often dynamic)
Web SERVICE
Given a XML document (soap msg)
Returns an XML document
Tools make this look like an RPC.
F(x,y,z) returns (u, v, w)
Distributed objects for the web.
naming, discovery, security,..
Internet-scale distributed computing

Your program
Web Server
http
Web page
Your program
Web Service
soap
Data In your address space
objectin xml
59
TerraServer Hardware

Storage Bricks
White-box commodity servers
4tb raw / 2TB Raid1 SATA storage
Dual Hyper-threaded Xeon 2.4ghz, 4GB RAM
Partitioned Databases (PACS partitioned array)
3 Storage Bricks 1 TerraServer data
Data partitioned across 20 databases
More data partitions coming
Low Cost Availability
4 copies of the data
RAID1 SATA Mirroring
2 redundant Bunches
Spare brick to repair failed brick 2N1 design
Web Application bunch aware
Load balances between redundant databases
Fails over to surviving database on failure
100K capital expense.

60
Research Objectives
User/App Goals
Technology Goals

Test/show scalability
Test/show availability
Test/show lights out
all operations maintenance occurs remotely
Minimal ops and dev staff
web service poster child

Public Access to remote sensing data with no
GIS expertise required
Ubiquitous No special hw/sw required by client
Delivery All OnLine/Internet Based, no tape or
CD distribution
Simple Designed to be used by a 6th grade
geography student

61
Virtual Observatoryhttp//www.astro.caltech.edu/n
voconf/http//www.voforum.org/

Premise Most data is (or could be online)
So, the Internet is the worlds 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 (2 years ago).
It is up when you are up.The seeing is always
great (no working at night, no clouds no moons
no..).
Its a smart telescope links objects and
data to literature on them.

62
Why Astronomy Data?

It has no commercial value
No privacy concerns
Can freely share results with others
Great for experimenting with algorithms
It is real and well documented
High-dimensional data (with confidence intervals)
Spatial data
Temporal data
Many different instruments from many different
places and many different times
Federation is a goal
The questions are interesting
How did the universe form?
There is a lot of it (petabytes)

63
Time and Spectral DimensionsThe Multiwavelength
Crab Nebulae
Crab star 1053 AD
X-ray, optical, infrared, and radio views of
the nearby Crab Nebula, which is now in a state
of chaotic expansion after a supernova explosion
first sighted in 1054 A.D. by Chinese Astronomers.
Slide courtesy of Robert Brunner _at_ CalTech.
64
SkyServer.SDSS.org

A modern archive
Raw Pixel data lives in file servers
Catalog data (derived objects) lives in Database
Online query to any and all
Also used for education
150 hours of online Astronomy
Implicitly teaches data analysis
Interesting things
Spatial data search
Client query interface via Java Applet
Query interface via Emacs
Popular -- 1 of Terraserver ?
Cloned by other surveys (a template design)
Web services are core of it.

65
Demo of SkyServer

Shows standard web server
Pixel/image data
Point and click
Explore one object
Explore sets of objects (data mining)

66
Data Federations of Web Services

Massive datasets live near their owners
Near the instruments software pipeline
Near the applications
Near data knowledge and curation
Super Computer centers become Super Data Centers
Each Archive publishes a web service
Schema documents the data
Methods on objects (queries)
Scientists get personalized extracts
Uniform access to multiple Archives
A common global schema

Federation
67
Federation SkyQuery.Net

Combine 4 archives initially
Just added 10 more
Send query to portal, portal joins data from
archives.
Problem want to do multi-step data analysis
(not just single query).
Solution Allow personal databases on portal
Problem some queries are monsters
Solution batch schedule on portal server,
Deposits answer in personal database.

68
SkyQuery Structure

Each SkyNode publishes
Schema Web Service
Database Web Service

Portal is
Plans Query (2 phase)
Integrates answers
Is itself a web service

69
SkyQuery http//skyquery.net/

Distributed Query tool using a set of web
services
Four astronomy archives from Pasadena, Chicago,
Baltimore, Cambridge (England).
Feasibility study, built in 6 weeks
Tanu Malik (JHU CS grad student)
Tamas Budavari (JHU astro postdoc)
With help from Szalay, Thakar, Gray
Implemented in C and .NET
Allows queries like

SELECT o.objId, o.r, o.type, t.objId FROM
SDSSPhotoPrimary o, TWOMASSPhotoPrimary t
WHERE XMATCH(o,t)lt3.5 AND AREA(181.3,-0.76,6.5)
AND o.type3 and (o.I - t.m_j)gt2
70
SkyNode Basic Web Services

Metadata information about resources
Waveband
Sky coverage
Translation of names to universal dictionary
(UCD)
Simple search patterns on the resources
Cone Search
Image mosaic
Unit conversions
Simple filtering, counting, histogramming
On-the-fly recalibrations

71
Portals Higher Level Services

Built on Atomic Services
Perform more complex tasks
Examples
Automated resource discovery
Cross-identifications
Photometric redshifts
Outlier detections
Visualization facilities
Goal
Build custom portals in days from existing
building blocks (like today in IRAF or IDL)

72
MyDB added to SkyQuery