2630 vs 2640: Intel Xeon E5-2630 @ 2.30GHz vs Intel Xeon E5-2640 @ 2.50GHz [cpubenchmark.net] by PassMark Software

Intel Xeon E5-2630 vs Intel Xeon E5-2640: What is the difference?

35points

Intel Xeon E5-2630

36points

Intel Xeon E5-2640

vs

61 facts in comparison

Intel Xeon E5-2630

Intel Xeon E5-2640

Why is Intel Xeon E5-2630 better than Intel Xeon E5-2640?

  • 192KB bigger L1 cache?
    384KBvs192KB

Why is Intel Xeon E5-2640 better than Intel Xeon E5-2630?

  • 8.7% faster CPU speed?
    6 x 2.5GHzvs6 x 2.3GHz
  • 0.2GHz higher turbo clock speed?
    3GHzvs2.8GHz
  • 2 higher clock multiplier?
    25vs23
  • 15.83% higher PassMark result?
    10001vs8634

Which are the most popular comparisons?

Intel Xeon E5-2630

vs

Intel Xeon E5-2603

Intel Xeon E5-2640

vs

Intel Xeon E5-2620

Intel Xeon E5-2630

vs

Intel Xeon E5-2650

Intel Xeon E5-2640

vs

Intel Xeon E5-2670

Intel Xeon E5-2630

vs

Intel Xeon E5-4620

Intel Xeon E5-2640

vs

Intel Xeon E5-2660

Intel Xeon E5-2630

vs

Intel Xeon W-2155

Intel Xeon E5-2640

vs

Intel Xeon E5-2650

Intel Xeon E5-2630

vs

Intel Xeon E5-2660

Intel Xeon E5-2640

vs

Intel Xeon E5-4640

Intel Xeon E5-2630

vs

Intel Xeon E3-1230 v5

Intel Xeon E5-2640

vs

Intel Xeon E3-1230

Intel Xeon E5-2630

vs

Intel Xeon E5-1650

Intel Xeon E5-2640

vs

Intel Xeon E5-2650L

Intel Xeon E5-2630

vs

Intel Xeon E5-2630L

Intel Xeon E5-2640

vs

Intel Xeon E5-4610 v4

Intel Xeon E5-2630

vs

Intel Xeon E5-2620

Intel Xeon E5-2640

vs

Intel Xeon E3-1225 v5

Intel Xeon E5-2640

vs

Intel Xeon E5-2640 v4

Price comparison

User reviews

Overall Rating

Intel Xeon E5-2630

0 User reviews

Intel Xeon E5-2630

0. 0/10

0 User reviews

Intel Xeon E5-2640

1 User reviews

Intel Xeon E5-2640

10.0/10

1 User reviews

Features

Value for money

No reviews yet

 

10.0/10

1 votes

Performance

No reviews yet

 

10.0/10

1 votes

Reliability

No reviews yet

 

10.0/10

1 votes

Energy efficiency

No reviews yet

 

10.0/10

1 votes

Performance

1.CPU speed

6 x 2.3GHz

6 x 2.5GHz

The CPU speed indicates how many processing cycles per second can be executed by a CPU, considering all of its cores (processing units). It is calculated by adding the clock rates of each core or, in the case of multi-core processors employing different microarchitectures, of each group of cores.

2.CPU threads

More threads result in faster performance and better multitasking.

3.turbo clock speed

2.8GHz

When the CPU is running below its limitations, it can boost to a higher clock speed in order to give increased performance.

4.L3 cache

A larger L3 cache results in faster CPU and system-wide performance.

5.L1 cache

A larger L1 cache results in faster CPU and system-wide performance.

6.L2 cache

A larger L2 cache results in faster CPU and system-wide performance.

7.L2 core

0.25MB/core

0.25MB/core

More data can be stored in the L2 cache for access by each core of the CPU.

8.clock multiplier

The clock multiplier controls the speed of the CPU.

9.Has an unlocked multiplier

✖Intel Xeon E5-2630

✖Intel Xeon E5-2640

Some processors come with an unlocked multiplier which makes them easy to overclock, allowing you to gain increased performance in games and other apps.

Memory

1.Supports ECC memory

✔Intel Xeon E5-2630

✔Intel Xeon E5-2640

Error-correcting code memory can detect and correct data corruption. It is used when is it essential to avoid corruption, such as scientific computing or when running a server.

2.maximum memory bandwidth

42.6GB/s

42.6GB/s

This is the maximum rate that data can be read from or stored into memory.

3.DDR memory version

Unknown. Help us by suggesting a value. (Intel Xeon E5-2640)

DDR (Double Data Rate) memory is the most common type of RAM. Newer versions of DDR memory support higher maximum speeds and are more energy-efficient.

4.maximum memory amount

The maximum amount of memory (RAM) supported.

5.RAM speed

1333MHz

1333MHz

It can support faster memory, which will give quicker system performance.

6.memory channels

More memory channels increases the speed of data transfer between the memory and the CPU.

7.bus speed

Unknown. Help us by suggesting a value. (Intel Xeon E5-2630)

Unknown. Help us by suggesting a value. (Intel Xeon E5-2640)

The bus is responsible for transferring data between different components of a computer or device.

8.bus transfer rate

7.2GT/s

7.2GT/s

The bus is responsible for transferring data between different components of a computer or device.

9.eMMC version

Unknown. Help us by suggesting a value. (Intel Xeon E5-2630)

Unknown. Help us by suggesting a value. (Intel Xeon E5-2640)

A higher version of eMMC allows faster memory interfaces, having a positive effect on the performance of a device. For example, when transferring files from your computer to the internal storage over USB.

Features

1.uses multithreading

✔Intel Xeon E5-2630

✔Intel Xeon E5-2640

Multithreading technology (such as Intel’s Hyperthreading or AMD’s Simultaneous Multithreading) provides increased performance by splitting each of the processor’s physical cores into virtual cores, also known as threads. This way, each core can run two instruction streams at once.

2.SSE version

SSE is used to speed up multimedia tasks such as editing an image or adjusting audio volume. Each new version contains new instructions and improvements.

3.Has AES

✔Intel Xeon E5-2630

✔Intel Xeon E5-2640

AES is used to speed up encryption and decryption.

4.Has AVX

✔Intel Xeon E5-2630

✔Intel Xeon E5-2640

AVX is used to help speed up calculations in multimedia, scientific and financial apps, as well as improving Linux RAID software performance.

5.bits executed at a time

Unknown. Help us by suggesting a value. (Intel Xeon E5-2630)

Unknown. Help us by suggesting a value. (Intel Xeon E5-2640)

NEON provides acceleration for media processing, such as listening to MP3s.

6.front-end width

Unknown. Help us by suggesting a value. (Intel Xeon E5-2630)

Unknown. Help us by suggesting a value. (Intel Xeon E5-2640)

The CPU can decode more instructions per clock (IPC), meaning that the CPU performs better

7.Has F16C

✖Intel Xeon E5-2630

✖Intel Xeon E5-2640

F16C is used to speed up tasks such as adjusting the contrast of an image or adjusting volume.

8.Has FMA3

✖Intel Xeon E5-2630

✖Intel Xeon E5-2640

FMA3 is used to speed up tasks such as adjusting the contrast of an image or adjusting volume.

9. Has FMA4

✖Intel Xeon E5-2630

✖Intel Xeon E5-2640

FMA4 is used to speed up tasks such as adjusting the contrast of an image or adjusting volume.

Benchmarks

1.Cinebench R20 (multi) result

Unknown. Help us by suggesting a value. (Intel Xeon E5-2630)

Unknown. Help us by suggesting a value. (Intel Xeon E5-2640)

Cinebench R20 is a benchmark tool that measures a CPU’s multi-core performance by rendering a 3D scene.

2.Cinebench R20 (single) result

Unknown. Help us by suggesting a value. (Intel Xeon E5-2630)

Unknown. Help us by suggesting a value. (Intel Xeon E5-2640)

Cinebench R20 is a benchmark tool that measures a CPU’s single-core performance by rendering a 3D scene.

3.Geekbench 5 result (multi)

Unknown. Help us by suggesting a value. (Intel Xeon E5-2630)

Unknown. Help us by suggesting a value. (Intel Xeon E5-2640)

Geekbench 5 is a cross-platform benchmark that measures a processor’s multi-core performance. (Source: Primate Labs, 2022)

4.Geekbench 5 result (single)

Unknown. Help us by suggesting a value. (Intel Xeon E5-2630)

Unknown. Help us by suggesting a value. (Intel Xeon E5-2640)

Geekbench 5 is a cross-platform benchmark that measures a processor’s single-core performance. (Source: Primate Labs, 2022)

5.PassMark result

This benchmark measures the performance of the CPU using multiple threads.

6.PassMark result (single)

This benchmark measures the performance of the CPU using a single thread.

7.performance per watt

Unknown. Help us by suggesting a value. (Intel Xeon E5-2640)

This means the CPU is more efficient, giving a greater amount of performance for each watt of power used.

8.Blender (bmw27) result

Unknown. Help us by suggesting a value. (Intel Xeon E5-2630)

Unknown. Help us by suggesting a value. (Intel Xeon E5-2640)

The Blender (bmw27) benchmark measures the performance of a processor by rendering a 3D scene. More powerful processors can render the scene in less time.

9.Blender (classroom) result

Unknown. Help us by suggesting a value. (Intel Xeon E5-2630)

Unknown. Help us by suggesting a value. (Intel Xeon E5-2640)

The Blender (classroom) benchmark measures the performance of a processor by rendering a 3D scene. More powerful processors can render the scene in less time.

Price comparison

Cancel

Which are the best Enterprise CPUs?

Intel Xeon E5-2630 v2 vs Intel Xeon E5-2640 v2


Comparative analysis of Intel Xeon E5-2630 v2 and Intel Xeon E5-2640 v2 processors for all known characteristics in the following categories: Essentials, Performance, Memory, Compatibility, Peripherals, Security & Reliability, Advanced Technologies, Virtualization.
Benchmark processor performance analysis: PassMark — Single thread mark, PassMark — CPU mark, Geekbench 4 — Single Core, Geekbench 4 — Multi-Core.

Intel Xeon E5-2630 v2

Buy on Amazon


vs

Intel Xeon E5-2640 v2

Buy on Amazon

 

Differences

Reasons to consider the Intel Xeon E5-2630 v2

  • Around 24% higher clock speed: 3.10 GHz vs 2.50 GHz
  • Around 19% lower typical power consumption: 80 Watt vs 95 Watt
  • Around 37% better performance in PassMark — Single thread mark: 1590 vs 1159
  • Around 4% better performance in PassMark — CPU mark: 13609 vs 13131
  • Around 32% better performance in Geekbench 4 — Single Core: 599 vs 453






Maximum frequency 3.10 GHz vs 2.50 GHz
Thermal Design Power (TDP) 80 Watt vs 95 Watt
PassMark — Single thread mark 1590 vs 1159
PassMark — CPU mark 13609 vs 13131
Geekbench 4 — Single Core 599 vs 453

Reasons to consider the Intel Xeon E5-2640 v2

  • 2 more cores, run more applications at once: 8 vs 6
  • 4 more threads: 16 vs 12
  • Around 6% higher maximum core temperature: 75°C vs 71°C
  • Around 33% more L1 cache; more data can be stored in the L1 cache for quick access later
  • Around 33% more L2 cache; more data can be stored in the L2 cache for quick access later
  • Around 33% more L3 cache; more data can be stored in the L3 cache for quick access later
  • Around 12% better performance in Geekbench 4 — Multi-Core: 3997 vs 3580








Number of cores 8 vs 6
Number of threads 16 vs 12
Maximum core temperature 75°C vs 71°C
L1 cache 64 KB (per core) vs 64 KB (per core)
L2 cache 256 KB (per core) vs 256 KB (per core)
L3 cache 20480 KB (shared) vs 15360 KB (shared)
Geekbench 4 — Multi-Core 3997 vs 3580

Compare benchmarks


CPU 1: Intel Xeon E5-2630 v2
CPU 2: Intel Xeon E5-2640 v2





PassMark — Single thread mark

CPU 1
CPU 2


PassMark — CPU mark

CPU 1
CPU 2


Geekbench 4 — Single Core

CPU 1
CPU 2


Geekbench 4 — Multi-Core

CPU 1
CPU 2







Name Intel Xeon E5-2630 v2 Intel Xeon E5-2640 v2
PassMark — Single thread mark 1590 1159
PassMark — CPU mark 13609 13131
Geekbench 4 — Single Core 599 453
Geekbench 4 — Multi-Core 3580 3997

Compare specifications (specs)































































Intel Xeon E5-2630 v2 Intel Xeon E5-2640 v2
Architecture codename Ivy Bridge EP Ivy Bridge EP
Launch date September 2013 September 2013
Launch price (MSRP) $250 $728
Place in performance rating 1206 1470
Price now $62. 98 $96.34
Processor Number E5-2630V2 E5-2640V2
Series Intel® Xeon® Processor E5 v2 Family Intel® Xeon® Processor E5 v2 Family
Status Launched Launched
Value for money (0-100) 48.64 30.28
Vertical segment Server Server
64 bit support
Base frequency 2. 60 GHz 2.00 GHz
Bus Speed 7.2 GT/s QPI 7.2 GT/s QPI
Die size 160 mm 160 mm
L1 cache 64 KB (per core) 64 KB (per core)
L2 cache 256 KB (per core) 256 KB (per core)
L3 cache 15360 KB (shared) 20480 KB (shared)
Manufacturing process technology 22 nm 22 nm
Maximum core temperature 71°C 75°C
Maximum frequency 3. 10 GHz 2.50 GHz
Number of cores 6 8
Number of QPI Links 2 2
Number of threads 12 16
Transistor count 1400 million 1400 million
VID voltage range 0.65–1.30V 0.65–1.30V
ECC memory support
Max memory channels 4 4
Maximum memory bandwidth 51. 2 GB/s 51.2 GB/s
Maximum memory size 768 GB 768 GB
Supported memory types DDR3 800/1066/1333/1600 DDR3 800/1066/1333/1600
Low Halogen Options Available
Max number of CPUs in a configuration 2 2
Package Size 52.5mm x 45mm 52.5mm x 51mm
Sockets supported FCLGA2011 FCLGA2011
Thermal Design Power (TDP) 80 Watt 95 Watt
Max number of PCIe lanes 40 40
PCI Express revision 3. 0 3.0
PCIe configurations x4, x8, x16 x4, x8, x16
Scalability 2S Only 2S Only
Execute Disable Bit (EDB)
Intel® Identity Protection technology
Intel® OS Guard
Intel® Secure Key technology
Intel® Trusted Execution technology (TXT)
Enhanced Intel SpeedStep® technology
Idle States
Instruction set extensions Intel® AVX Intel® AVX
Intel 64
Intel® Advanced Vector Extensions (AVX)
Intel® AES New Instructions
Intel® Demand Based Switching
Intel® Flex Memory Access
Intel® Hyper-Threading technology
Intel® TSX-NI
Intel® Turbo Boost technology
Intel® vPro™ Platform Eligibility
Physical Address Extensions (PAE) 46-bit 46-bit
Thermal Monitoring
Intel® Virtualization Technology (VT-x)
Intel® Virtualization Technology for Directed I/O (VT-d)
Intel® VT-x with Extended Page Tables (EPT)

Navigation

Choose a CPU

Compare processors

Compare Intel Xeon E5-2630 v2 with others




Intel
Xeon E5-2630 v2



vs



Intel
Xeon E5-2450L




Intel
Xeon E5-2630 v2



vs



Intel
Xeon E5-2440




Intel
Xeon E5-2630 v2



vs



AMD
Opteron 6376




Intel
Xeon E5-2630 v2



vs



AMD
Opteron 4332 HE




Intel
Xeon E5-2630 v2



vs



AMD
Opteron 6344




Intel
Xeon E5-2630 v2



vs



Intel
Xeon E3-1220 v6

John Deere 2630 and 2640 Diesel» by Nebraska Tractor Test Lab

  • < Previous Article
  • Next Article >
  •  

 

Date of this Version

1-1-1974

Abstract

EXPLANATION OF TEST REPORT GENERAL CONDITIONS East tractor is a production model equipped for common usage. Power consuming accessories can be disconnected only when it is convenient for the operator to do so in practice. Additional weight can be added as ballast if the manufacturer regularly supplies it for sale. The static tire loads and the inflation pressures muse conform to recommendations in the Tire Standards published by the Society of Automotive Engineers. PREPARATION FOR PERFORMANCE RUNS The engine crank case is drained and refilled with a measured amount of new oil conforming to specifications in the operator’s manual. The fuel used and the maintenance operations must also conform to the published information delivered with the tractor. The tractor is then limbered-up for 1 hour on drawbar work in accordance with the manufacturers published recommendations. The manufacturer’s representative is present to make appropriate decisions regarding mechanical adjustments. The tractor is equipped with approximately the amount of added ballast that is used during maximum drawbar tests. The tire tread-bar height must be at least 65% of new tread height prior to the maximum power run. BELT OR POWER TAKE-OFF PERFORMANCE Maximum Power and Fuel Consumption. The manufacturer’s representative makes carburetor, fuel pump, ignition and governor control settings which remain unchanged throughout tall subsequent runs. The governor and the manually operated governor control lever is set to provide the high-idle speed specified by the manufacturer for maximum power. Maximum power is measured by connecting the belt pulley or the power take-off to a dynamometer. The dynamometer load is then gradually increased until the engine is operating at the rated speed specified by the manufacturer for maximum power. The corresponding fuel consumption is measured. Varying Power and Fuel Consumption. Six different horsepower levels are used to show corresponding fuel consumption rates and how the governor causes the engine to react to the following changes in dynamometer load: 85% of the dynamometer torque at maximum power; minimum dynamometer torque, ½ the 85% torque; maximum power; ¼ and ¾ of the 85% torque. Since at tractor is generally subjected to varying loads the average of the results in this test serve well for predicting the fuel consumption of a tractor in general usage. DRAWBAR PERFORMANCE All engine adjustments are the same as those used in the belt or power take-off tests. If the manufacturer specifies a different rated crankshaft speed for drawbar operations, then the position of the manually operated governor control is changed to provide the high-idle speed specified by the manufacturer in the operating instructions. Varying Power and Fuel Consumption With Ballast. The varying power runs are made to show the effect of speed-control devices (engine governor, automatic transmissions, etc.) on horsepower, speed and fuel consumption. These runs are made around the entire test course with has two 180 degree turns with a minimum radius of 50 feet. The drawbar pull is set at 3 different levels as follows: (1) as near to the pull a maximum power as possible and still have the tractor maintain the travel speed at maximum horsepower on the straight sections of the test course; (2) 75% of the pull at maximum power; and (3) 50% of the pull at maximum power. Prior to 1958, fuel consumption data (10 hour test) were shown only for the pull obtained at maximum power for tractors having torque converters and at 75% of the pull obtained at maximum power for gear-type tractors. Maximum Power With Ballast. Maximum power is measured on straight level sections of the test course. Data are shown for not more that 12 different gears or travel speeds. Some gears or travel speeds may be omitted because of high slippage of the traction members or because the travel speed may exceed the safe-limit for the test course. The maximum safe speed for the Nebraska Test course has been set at 15 miles per hour. The slippage limits have been set at 15% and 7% for pneumatic tires and steel tracks or lugs, respectively. Higher slippage gives widely varying results. Maximum Power Without Ballast. All added ballast is removed from the tractor. The maximum drawbar power of the tractor is determined by the same procedure used for getting maximum power with ballast. The gear (or travel speed) is the same as that used in the 10-hours test. Varying Power and Travel Speed With Ballast. Travel speeds corresponding to drawbar pulls beyond the maximum power range are obtained to show the “lugging ability” of the tractor. The run starts with the pull at maximum power; then additional drawbar pull is applied to cause decreasing speeds. The run is ended by one of three conditions; (1) maximum pull is obtained, (2) the maximum slippage limit is reached, or (3) some other operating limit is reached.