1. Intel

1

Noi Tehnologii IntelSpend Smart, Do More, Be More Secure

Florin RaclariuMarket Development Manager

Intel Romania

15 Octombrie 2009

2

Spend Smart, Do More,Be More Secure

Keep Your Business Efficient in an Economic Downturn

3

“My experience has been that older PCs cause more problems than they are worth. We stick to our refresh plan because I know that this saves my staff a lot of time and effort.”

— VP of IT, insurance industry (Wipro, October 2006)

Avoid Rising Costs, Maintain PC Refresh Rates1

Rising maintenance costs due to:

• Software deployment failures (including security patches)

• Increase in hardware related help desk calls (“spikes dramatically at 3 ½ years into a PC’s lifecycle and continues to climb. This increase is much higher than previously seen.”)

• Cost to maintain a PC goes up each year

• Optimal refresh for desktop is 3 years

• Optimal refresh mobile is 2 years

4

Spend Smart

Do More

Be More Secure

• Average support costs of older PCs rise 30+% in year 41

• Reduce security patch costs 98% with Intel®

vPro™ Technology2

• Energy costs reduced by 50% by powering down Intel® vPro™ enabled PCs during off hours3

University of Plymouth

• 200+% performance increase over 3yr old desktops4

• Over 1hr better battery life over 2yr old notebooks4

• 80% reduction in deskside visits for Intel® vPro™ enabled PC problem resolution allows IT to do more5 Indiana State Office of Technology

• Patching Intel® vPro™ enabled PCs occurs 42% faster reducing security exposures6 Telkomsel

• Achieve 98% patch saturation in 4 hours vs 5 days with Intel® vPro™ enabled PCs7 Calgary

Health Region

Why Buy Now?

5

Spend Smart

Do More

Be More Secure

• 70+% of IT managers rated security features influencing notebook IT buying decisions as “Very Significant” or “Somewhat Significant”4

• Intel® Centrino® 2 with vPro™ technology offers proactive security solutions

• 51 additional minutes more productive per day3

• 50% faster and ~1 hour better battery life than a 2yr old notebook2

• 82% of employees required to access enterprise applications while away from office3

• Companies are realizing huge cost savings from employees tele-working with notebooks1

• >26x energy reduction by going mobile2

Why Buy Mobile?

6

17 MonthRecoup Investment4

10 MonthRecoup Investment4

Fast ROI

50% 3x 53%Up to Up to On average

REDUCTIONOPERATIONAL COSTS TO MAINTAIN

PCS1

Spend Smart Do More

FASTERMULTI-TASKING2

Be More Secure

INCREASE IN YEARLY SECURITY INCIDENCES WITH A 4 YEAR OLD PC3

Refreshing PCs Makes Good Business Sense

Faster ROI

As low asAs low as

Intel® Core™2 Duo processor-based PCs

Intel® vPro™ Technology- based PCs

7

Why Buy Intel® Servers?

8

Where is Today’s IT Spending?

•IT is spending too much on maintenance

•This limits ability to innovate and grow business with new services and capabilities

Source: Gartner IT Key Metrics Data 2008.

Innovate

Maintain

Enhance

9

Server Workloads 2008 MCSServer Lifecycle

0%

5%

10%

15%

20%

25%

30%

35%

40%

45%

1 2 3 4 5 6 7 8 9 10+

Total (N=1108)

Question 5.6: Approximately how many years do you estimate that your XXOS servers will be kept in operation?

The data was

surprisingly similar by company size and vertical industry

Figure 33Server Deployment Lifecycle

Median

Most Typical is

5yr and 3yr

Average is

~4yr

10

Intelligent Investment Decisions in 09

Refresh with Xeon 5500. Pays for itself in ~8 months.

Expanding services using Intel technology for Cloud Computing

Migrating from RISC to Intel reduces TCO, saving $

Using Intel 4S servers for your most data demanding applications

Virtualize with Xeon. IT flexibility & cost advantages.

Accelerating ROI upgrading HW with new software Deployments

Supporting new buyers in emerging markets & SMB with entry Xeon servers

Boosting energy efficiency, save $ and support Green IT with Intel

Accelerating research, speed development with Intel HPC/WS solutions

11

Server Refresh Benefits(Single Core)

Source: Intel estimates as of Nov 2008. Performance comparison using SPECjbb2005 bops (business operations per second). Results have been estimated based on internal Intel analysis and are provided for informational purposes only. Any difference in system hardware or software design or configuration may affect actual performance. For detailed calculations, configurations and assumptions refer to the legal information slide in backup.

2005

184 Intel® Xeon®

Single Core Servers

2009

Performance Refresh

1:1

Up to 9x Performance

184 Intel® Xeon®

5500 Based Servers

18% Annual Energy Costs

Estimated Reduction

– OR –Efficiency Refresh

9:1

21 Intel® Xeon®

5500 Based Servers

As Low as8 Month

Payback

90% Annual Energy Costs

Estimated Reduction

12

Estimate Your Refresh ROI

Enter Current Configurations

www.intel.com/go/xeonestimator

Calculate ROI, TCO, and Other Benefits

http://www.intel.com/go/xeonestimator�

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Intel platform NEWS

14

The All New 2010 Intel® Core™ Processor Family

Silicon ProcessTechnology

Intel® Core™Microarchitecture

NehalemMicroarchitecture

Sandy BridgeMicroarchitecture

65nm 45nm 32nm

The revolutionary and smart Nehalem microarchitecture comes to mainstream consumer platforms

15

• New levels of smart performance with a revolutionary new architecture

• Great media experience with advanced media and graphics capabilities, now integrated in the processor

• Thinner and sleeker designs with reduced chipset count, smaller silicon footprint, and ULV skus

• Industry leading battery life with great power efficiency

Intel® Core™ processors deliver amazing computing experiencesfor mainstream and ultra-thin laptops

The All New 2010 Intel® Core™ Processor Family

16

What is it? • Technology that dynamically uses thermal

and power headroom to boost additional CPU and/or integrated GPU frequencies

• Available with new Intel® Core™ i7 and i5 processors

Benefits for consumers• Intelligently accelerates performance to

match your workload, so you can enjoy the maximum possible speed

• Optimizes processor (CPU and integrated graphics) performance intelligently and automatically, without user intervention

When thermal headroom allows, Intel® Turbo Boost Technology automatically accelerates performance to applications that need it most.

16

Smart performance for running everyday applications

Intel® Turbo Boost Technology

Without Intel® Turbo-Boost Technology (previous generations)

With Intel® Turbo-Boost Technology

Highly Threaded Workload < TDP

Single-Threaded Workload < TDP

Illustrations representing processor acceleration are not drawn to scale

Intel® Turbo Boost Technology requires a PC with a processor with Intel Turbo Boost Technology capability. Intel Turbo Boost Technology performance varies depending on hardware, software and overall system configuration. Check with your PC manufacturer on whether your system delivers Intel Turbo Boost Technology. For more information, see http://www.intel.com/technology/turboboost

http://www.intel.com/technology/turboboost�

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What is it? • Intel® Hyper-Threading Technology

enables each processor core to run two tasks at the same time

• Two thread engines per core, enabling 4-way processing in dual core systems and 8-way processing in quad core systems

• Available with the new Intel® Core™ family of processors

Benefits for consumers• More threads and smart multitasking equals

better performance• Faster response time = less waiting

Smart multitasking by doubling the number of processor threads per core with Intel® Hyper-Threading Technology.

17

Get more done while waiting less

Intel® Hyper-Threading Technology

Without HT

With HT

Hyper-Threading Technology requires a computer system with a processor supporting HT Technology and an HT Technology-enabled chipset, BIOS and operating system. Performance will vary depending on the specific hardware and software you use. For more information including details on which processors support HT Technology, see http://www.intel.com/info/hyperthreading

2 Threads

4 Threads

http://www.intel.com/info/hyperthreading�

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Desktop Platform News

ww36 2009

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November 2008

“The World’s Highest Performing Processor”

• Amazing New Nehalem Microarchitecture

• World Record Setting Performance1

• Ultimate Enthusiast Hardware

Nehalem Goes Mainstream!• Nehalem Microarchitecture at

Additional Price Points • Intelligent, Energy-Efficient

Performance • Flexible, Cost Optimized Board

Design

1. Source: http://www.spec.org/cpu2006/results/ as of November 13, 2008 Any difference in system hardware or software design or configuration may affect actual performance.**SPEC, SPECint, SPECfp, and SPECrate are trademarks of the Standard Performance Evaluation Corporation. For more information about this benchmark go to: www.spec.orgSystem Configurations and Disclaimers: Appendix *Other names and brands may be claimed as the property of others.

Nehalem Goes Mainstream!

Intel ® Core™ i7 900 Series

and Intel ® X58 Express Chipset

Intel ® Core™ i7- 800 / i5-700 Series and Intel ® P55 Express Chipset

September 2009

20

New Intel® Core™ i7 and i5 Processor Lineup

1 - NOTE: Intel processor numbers are not a measure of performance. Processor numbers differentiate features within each processorfamily, not across different processor families. See www.intel.com/products/processor_number for details.

2 - Refers to the maximum single-core frequency that can be achieved with Intel® Turbo Boost Technology

Brand Name & Processor Number1

Base Clock Speed (GHz)

Turbo Frequency2

(Ghz) Cores/Threads Cache Memory Speed Support TDP

Intel® Core™ i7-870 2.93 Up To

3.6 Ghz 4/8 8 MB DDR3-1333 95 W


3.46 Ghz 4/8 8 MB DDR3-1333 95 W


3.2 Ghz 4/4 8 MB DDR3-1333 95 W

Intel® Core™ i7 – 870 - $555 USD

BoxedPricing(1ku)



http://www.intel.com/products/processor_number�

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Mobile Platform News

ww36 2009

2222

Intel® Core™ i7 Mobile Processors Consumer Value Proposition

RevolutionaryThe biggest thing to happen to mobile computing since Centrino

The choice for multimedia enthusiasts and gamers

IntelligentThe architecture that shapes itself to everything you do.

PerformanceIncredible mobile performance

WhatIs It?

HowSo?

WhatYouGet?

WhoCares?

23

Intel’s Fastest Mobile Processors Just Got Faster

Intel® Core™ i7-920XM processor2.0 GHz

(Turbo up to 3.2 GHz**)8M/8 threads***

**: Refers to the maximum single-core frequency that can be achieved with Intel® Turbo Boost Technology***: Refers to the total number of threads that can be supported with Intel® Hyper-threading Technology

Intel® Core™ i7-820QM Processor1.73 GHz


Intel® Core™ i7-720QM Processor1.6 GHz


The fastest notebook processor on the planet5.(Overclocking enabled for incredible performance16)

The world's best family of laptop processors6

Extreme

Quad Core Performance

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The Aging Installed Base of LaptopsMay be Unfit for Today’s Usages

“Is it painful, or even possible to…”• Watch HD Internet TV and video with smooth playback?

• Easily upload, edit, share your family photos and videos?

• Watch a DVD or Blu-ray* movie?

• Run multiple programs at the same time?

2010 Intel® Core™i7 Processor 720QM

38 Min

Time To Create a 30 Minute HD Video from Recent Vacation3

2 Hours, 17 minutes

2010 PC is >3.5x Faster!

2006 Intel® Core™ Duo Processor T2700

You Deserve a New Laptop!

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A Full Range of Platforms for Different User Needs

NetbooksCompanion Device: Internet

Usage & Content Consumption

Ultra-Thin LaptopsThe Perfect Balance of Style, Performance, and Long Battery Life

Standard LaptopHighest Performance / Full Size Mobile Computer Experience

A choice of laptop form factors

Sell-up opportunity

Intel provides a full range of platforms to meet the usage models of today’s consumers

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Ultra-thin Laptops: The Perfect Balance of Style, Performance, and Long Battery Life

Ultra-thin and Light Laptops at Mainstream Price Points

Great Media Experience, Rich Internet, Content Creation

Functionality of a Traditional Laptop in a Thin and Light Design

Outstanding Component Average Power for Industry-Leading Battery Life

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Netbooks & Laptop Product Offerings

7”

Netbooks (7”-10.2”)

Mobile Platform

The New Ultra-thin

laptop

>10.2”

Screen Size

SPP Range

$250

10.2”

$399 $499Traditional Mainstream

Laptops≥14”

$699 $1099$899

$499-599$699-799

$849-949

$1099+

$249-349

Celeron$400-600

Pentium$600-700

Centrino$750-1K

Centrino 2$1000+

≤13.3”

Intel offers a comprehensive mobile roadmap to meet netbook and laptop needs

28

Netbook vs. Consumer ULV Performance

Photo EditingConvert Videos Audio EncodingPrepare songs for MP3 playerApple iTunes* 7.4.3

Compress to shareWindows* Photo Gallery*

DVR-ms format to MPEG-4Windows* MovieMaker*

3.2x

1.7x

1.6x

1.0

4.7x

2.1x

1.9x

1.0

2.5x

1.8x

1.7x

1.0

Performance tests and ratings are measured using specific systems and/or components and reflect approximate performance of Intel products as measured by those tests. Any difference in system hardware, software, or configuration may affect actual performance. Buyers should consult other sources of information to evaluate performance of systems or components they are considering purchasing. For more information on performance tests and performance of Intel products, visit //www.intel.com/performance

Ultra-thin laptops provide performance for full mobile computing in sleek and slim form factors

29

Netbook vs. Mainstream Notebook Performance

Video ConversionStock Option Analysis

Audio EncodingPrepare songs for MP3 playerApple iTunes* 7.4.3

MPEG2 video file to DivX formatDivX* 6.7 w/VirtualDub* 1.7.2

Office* Excel 2007

4.1x

3.4x

2.0x

1.0

6.4x

5.6x

3.4x

1.0

5.8x

3.5x

2.0x

1.0

Mobile Intel® processors for the notebook segment provide the performance needed for content creation

Performance tests and ratings are measured using specific systems and/or components and reflect approximate performance of Intel products as measured by those tests. Any difference in system hardware, software, or configuration may affect actual performance. Buyers should consult other sources of information to evaluate performance of systems or components they are considering purchasing. For more information on performance tests and performance of Intel products, visit //www.intel.com/performance

30

Server Platform News

ww36 2009

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Introducing the Intel® Xeon® 5500 Series Processor

Based on the Next Generation Intel®Microarchitecture

A New Generation of Intelligent Servers

32

Intel® Xeon® Processor 5500 Series(Codename Nehalem-EP)

A tremendous step forward in technology

– New processor architecture– New platform architecture– New memory subsystem– New I/O subsystem– New options with SSDs

An even bigger step forward for IT capability

Performance Energy Efficiency Virtualization

33

Processor Transition Matrix Which Nehalem Product is Right for Me?

1 Source: Intel. Pricing reflects 1k unit price to OEMs at time of introduction. Subject to change without notice.

Series,SKU

PriceBrand

1

Current Products Future

5100(Dual-core Xeon)

5300(1st Gen 65nm

Quad-core Xeon)

5400(2nd Gen 45nm Quad-core Xeon)

5500Nehalem Microarchitecture

>$800 5160 (3.00GHz) X5365 (3.00GHz)

X5470 (3.33GHz)

X5460 (3.16GHz)

E5450 (3.00GHz)

X5450 (3.00GHz)

X5570 (2.93GHz)

X5560 (2.80GHz)

X5550 (2.66GHz)

AdvancedPerformance oriented customers seeking highest functionality and optimal server ROI

$301-$7995150 (2.66GHz)

5140 (2.33GHz)

5130 (2.00GHz)

X5355 (2.66GHz)

E5345 (2.33GHz)

E5335 (2.00GHz)

E5440 (2.83GHz)

E5430 (2.66GHz)

E5420 (2.50GHz)

E5540 (2.53GHz)

E5530 (2.40GHz)

E5520 (2.26GHz)

StandardCustomers seeking a mix of performance, value, and advanced features

<$300 5120 (1.86GHz)

5110 (1.60GHz)

E5320 (1.86GHz)

E5310 (1.60GHz)

E5410 (2.33GHz)

E5405 (2.00GHz)

E5506 (2.13GHz)

E5504 (2.00GHz)

E5502 (1.86GHz)

BasicCost-sensitive customers seekingbasic features

Low Power 5148 (2.33GHz)

L5335 (2.00GHz)

L5320 (1.86GHz)

L5310 (1.60GHz)

L5530 (2.66GHz)

L5420 (2.50GHz)

L5410 (2.33GHz)

L5520 (2.26GHz)

L5506 (2.13GHz)

Low PowerCustomer seeking lowest power or use in constrained form factors (blades)

34

Summary

Spend Smart, Do More, Be More Secure

36

• Integer Throughput Performance on SPECint*_rate_base2006 benchmark• Comparison based on published/submitted results to www.spec.org as of June 9, 2009.

• Intel® Xeon® processor 3.80 with 2M L2 cache based platform details

• HP* ProLiant* DL380 G4 server platform with two 64-bit Intel Xeon processor 3.80GHz with 2M L2 cache, 800 FSB, 8GB memory, Microsoft Windows Server 2003* Ent. SP1, Intel® C++ Compiler 9.1 for 32-bit apps, Build 20060323Z Package ID: W_CC_P_9.1.020. Referenced as published at 20.9. For more information see http://www.spec.org/cpu2006/results/res2006q3/cpu2006-20060513-00027.html.

• Intel® Xeon® processor 5160 based platform details

• IBM System X* 3550 platform with two Intel Xeon processors 5160 3.00GHz, 4Mb L2 cache, 16GB memory (8 x 2GB DDR2-5300F ECC), SUSE* Linux* Enterprise Server 10 (x86_64) 2.6.16.21-0.8-smp, Intel C++ Compiler for Linux* version 10.0. Published in August 2007. Referenced as published at 60.8. For more information see http://www.spec.org/cpu2006/results/res2007q3/cpu2006-20070803-01638.html.

• Intel® Xeon® processor X5470 based platform details

• Fujitsu Siemens PRIMERGY* RX200 S4 server platform with two Intel Xeon processors X5470 3.33GHz, 12MB L2 cache, 1333MHz FSB, 16GB memory (8x2GB DDR2 PC2-5300F, 2 rank, CAS 5-5-5, with ECC), SUSE Linux Enterprise Server 10 SP2 x86_64 Kernel 2.6.16.60-0.21-smp*, Intel C++ Compiler for Linux32* and Linux64* version 11.0 build 20080730. Referenced as published at 140. For more information see http://www.spec.org/cpu2006/results/res2008q3/cpu2006-20080901-05156.html.


• ASUS Z8PE-D12X based server platform with two Intel Xeon processors X5570 2.93GHz, 8MB L3 cache, 6.4GT/s QPI, 24 GB memory (6x4GB PC3-10600R, CL9-9-9, ECC), SUSE Linux Enterprise Server 10 SP2 x86_64 Kernel 2.6.16.60-0.34-smp, Intel C++ Compiler for Linux32 and Linux64 version 11.0 build 20090131. Referenced as published at 241. For more information see http://www.spec.org/cpu2006/results/res2009q1/cpu2006-20090316-06703.html

• Quad-Core AMD Opteron* processor model 2360 based platform details:

• Acer Altos G5450 Server platform with two Dual-Core AMD Opteron processors 2360SE 2.50GHz, 2MB L3 cache, memory 32GB (8x4GB, DDR2-667, Reg, 2-rank CL5), SUSE Linux Enterprise Server 10 64-bit, PGI Server Complete Version 7.2 PathScale Compiler Suite 3.2, . Referenced as published at 94.1 For more information see http://www.spec.org/cpu2006/results/res2009q1/cpu2006-20090309-06627.html

• Quad-Core AMD Opteron* processor model 2386SE based platform details

• Supermicro A+ Server 1021M-UR+B* Server platform with two Quad-Core AMD Opteron processors 2386SE 2.80GHz, 6MB L3 cache, 32GB memory (8x4GB, DDR2-800, Reg, dual-rank CL5), SUSE Linux Enterprise Server 10 64-bit*, PGI Server Complete Version 7.2 PathScale Compiler Suite*, Release 3.2. Referenced as published at 116. For more information see http://www.spec.org/cpu2006/results/res2009q1/cpu2006-20081218-06302.html.

• Quad-Core AMD Opteron* processor model 2389 based platform details

• Supermicro A+ Server 1021M-UR+B* Server platform with two Quad-Core AMD Opteron processors 2389 2.90GHz, 6MB L3 cache, 32GB memory (8x4GB, DDR2-800, Reg, dual-rank CL5), SUSE Linux Enterprise Server 10 64-bit*, PGI Server Complete Version 7.2 PathScale Compiler Suite*, Release 3.2. Referenced as published at 117. For more information see http://www.spec.org/cpu2006/results/res2009q2/cpu2006-20090216-06529.html


• Dell Inc. PowerEdge SC1435 (AMD Opteron 2393 SE, 3.10 GHz) 148 124 8 2 4 with two Quad-Core AMD Opteron processors 2393SE 3.10GHz, 6MB L3 cache, 32GB memory (8x4GB, DDR2-800, Reg, dual-rank CL5), SUSE Linux Enterprise Server 10 64-bit*, PGI Server Complete Version 7.2 PathScale Compiler Suite*, Release 3.2. Referenced as published at 124 For more information see http://www.spec.org/cpu2006/results/res2009q2/cpu2006-20090511-07450.html

• Six-Core Opteron 2434 based platform details

• Supermicro A+ Server 1021M-UR+B* Server platform with two six-core AMD Opteron processors 2434 2.6GHz, 6MB L3 cache, 32GB memory (8x4GB, DDR2-800, Reg, dual-rank CL5), Red Hat Enterprise Linux Server release 5.3, PGI Server Complete Version 8.0 x86 Open64 4.2.2 Compiler Suite (from AMD) publishes at 161 http://www.spec.org/cpu2006/results/res2009q2/cpu2006-20090511-07357.html

•Performance tests and ratings are measured using specific computer systems and/or components and reflect the approximate performance of Intel products as measured by those tests. Any difference in system hardware or software design or configuration may affect actual performance. Buyers should consult other sources of information to evaluate the performance of systems or components they are considering purchasing. For more information on performance tests and on the performance of Intel products, visit http://www.intel.com/performance/resources/limits.htm Copyright © 2009, Intel Corporation. * Other names and brands may be claimed as the property of others.

Intel® Xeon® Processor 5500 series based Server platformsInteger Throughput performance on SPECint*_rate_base2006

Source: Published/submitted/approved results March 30, 2009.

http://www.spec.org/�

http://www.spec.org/cpu2006/results/res2006q3/cpu2006-20060513-00027.html�









37

• Floating Point Throughput Performance on SPECfp*_rate_base2006 benchmark• Comparison based on published/submitted results to www.spec.org as of June 9, 2009

• Intel® Xeon® processor 3.80 with 2M L2 cache based platform details

• HP* ProLiant* DL380 G4 server platform with two 64-bit Intel Xeon processor 3.80GHz with 2M L2 cache, 800 FSB, 8GB memory, Microsoft Windows Server 2003* Ent. SP1, Intel® C++ Compiler 9.1 for 32-bit apps, Build 20060323Z Package ID: W_CC_P_9.1.020. Referenced as published at 18.8 (SPECfp*_rate_base2006). For more information see http://www.spec.org/cpu2006/results/res2006q3/cpu2006-20060513-00025.html.

• Intel® Xeon® processor 5160 based platform details

• HP Proliant DL380 G5 server platform* with two Intel Xeon processor 5160, 3.0 GHz, 4MB L2 cache, 1333MHz system bus, 8GB memory (8x1GB FB DDR2-667), SUSE Linux Enterprise Server 10.1 OS*. Intel C++ Compiler for Linux32* and Linux64* version 10.1. Referenced as published at 45.1. Posted at http://www.spec.org/cpu2006/results/res2007q4/cpu2006-20070916-02036.html.


• Hewlett-Packard ProLiant DL160 G5p server platform* with two Intel Xeon processors X5482 3.20GHz, 12MB L2 cache, 1600MHz FSB, 16GB memory (8x2GB 800MHz CL5 FB-DIMM), 64-Bit SUSE Linux Enterprise Server 10 SP1, Intel C++ Compiler for Linux32 and Linux64 version 10.1 build 20080730. Referenced as published at 86.4. For more information see http://www.spec.org/cpu2006/results/res2008q4/cpu2006-20081013-05587.html.


• ASUS Z8PE-D12X based server platform with two Intel Xeon processors X5570 2.93GHz, 8MB L3 cache, 6.4GT/s QPI, 72 GB (18 X 4 GB PC3-10600R, CL=9, SUSE Linux Enterprise Server 10 SP2 x86_64 Kernel 2.6.16.60-0.21-smp, Intel C++ Compiler for Linux32 and Linux64 version 11.0 build 20010131. References at 197 For more information see: http://www.spec.org/cpu2006/results/res2009q2/cpu2006-20090511-07354.html

• Quad-Core AMD Opteron* processor model 2360 based platform details:

• Acer Altos G5450 Server platform with two Dual-Core AMD Opteron processors 2360SE 2.50GHz, 2MB L3 cache, memory 32GB (8x4GB, DDR2-667, Reg, 2-rank CL5), SUSE Linux Enterprise Server 10 64-bit, PGI Server Complete Version 7.2 PathScale Compiler Suite 3.2, . Referenced as published at 85.4. For more information see http://www.spec.org/cpu2006/results/res2009q1/cpu2006-20090309-06628.html

• Quad-Core AMD Opteron* processor 2386SE based platform details

• SuperMicro A+ Server 1021M-UR+B Server platform* with two Quad-Core AMD Opteron processors 2386SE 2.80GHz, 6MB L3 cache, 32GB memory (8x4GB, DDR2-800, Reg, dual-rank CL5), SUSE Linux Enterprise Server 10 64-bit*, PGI Server* Complete Version 7.2 PathScale Compiler Suite*, Release 3.2. Referenced as published at 107. For more information http://www.spec.org/cpu2006/results/res2009q1/cpu2006-20081218-06303.html.


• Supermicro A+ Server 1021M-UR+B* Server platform with two Quad-Core AMD Opteron processors 2389 2.90GHz, 6MB L3 cache, 32GB memory (8x4GB, DDR2-800, Reg, dual-rank CL5), SUSE Linux Enterprise Server 10 64-bit*, PGI Server Complete Version 7.2 PathScale Compiler Suite*, Release 3.2. Referenced as published at 108. For more information see http://www.spec.org/cpu2006/results/res2009q2/cpu2006-20090216-06530.html

• Quad-Core AMD Opteron* processor model 2393based platform details

• Supermicro A+ Server 1021M-UR+B* Server platform with two Quad-Core AMD Opteron processors AMD Opteron 2393 SE, 3.1 GHz, 6MB L3 cache, 32GB memory (8x4GB, DDR2-800, Reg, dual-rank CL5), SUSE Linux Enterprise Server 10 64-bit*, PGI Server Complete Version 7.2 PathScale Compiler Suite*, Release 3.2. Referenced as published at 112 For more information see http://www.spec.org/cpu2006/results/res2009q2/cpu2006-20090406-06932.html

• Six-Core AMD Opteron* processor 2384 based platform details

• Supermicro A+ Server 1021M-UR+B* Server platform with two six-core AMD Opteron processors 2434 2.6GHz, 6MB L3 cache, 32GB memory (8x4GB, DDR2-800, Reg, dual-rank CL5), Red Hat Enterprise Linux Server release 5.3, PGI Server Complete Version 8.0 x86 Open64 4.2.2 Compiler Suite (from AMD) publishes at 129 for more information see http://www.spec.org/cpu2006/results/res2009q2/cpu2006-20090511-07358.html

Performance tests and ratings are measured using specific computer systems and/or components and reflect the approximate performance of Intel products as measured by those tests. Any difference in system hardware or software design or configuration may affect actual performance. Buyers should consult other sources of information to evaluate the performance of systems or components they are considering purchasing. For more information on performance tests and on the performance of Intel products, visit http://www.intel.com/performance/resources/limits.htm Copyright © 2009, Intel Corporation. * Other names and brands may be claimed as the property of others.

Intel® Xeon® Processor 5500 series based Server platformsFloating Point Throughput performance on SPECfp*_rate_base2006


http://www.spec.org/�









38

• Irwindale 3.8 http://www.spec.org/cpu2006/results/res2006q3/cpu2006-20060513-00027.html

• Xeon 5110 (WDC 1.60) - http://www.spec.org/cpu2006/results/res2007q4/cpu2006-20071015-02272.html






• Xeon 5405 (HTN 2.0) - http://www.spec.org/cpu2006/results/res2008q4/cpu2006-20081208-06236.html





• Xeon 5450 (HTN 3.0) -http://www.spec.org/cpu2006/results/res2008q4/cpu2006-20081109-05863.html



• Xeon 5462 (HTN 2.8/1600) – Estimate based on Intel internal measurement – March 2009

• Xeon 5472 (HTN 3.0/1600) - http://www.spec.org/cpu2006/results/res2008q4/cpu2006-20081030-05826.html


• Opteron 2347 (Bar 1.9) - http://www.spec.org/cpu2006/results/res2008q3/cpu2006-20080811-05001.html







• Opteron 2376 (Sh 2.3) - http://www.spec.org/cpu2006/results/res2009q1/cpu2006-20081218-06300.html





Intel® Xeon® Processor 5500 series based Server platformsInteger Throughput performance on SPECint*_rate_base2006





































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• Irwindale 3.8 http://www.spec.org/cpu2006/results/res2006q3/cpu2006-20060513-00025.html















• Xeon 5462 (HTN 2.8/1600) - Estimate based on Intel internal measurement – March 2009















Intel® Xeon® Processor 5500 series based Server platformsFloating-Point Throughput performance on SPECfp*_rate_base2006
































1. Intel

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