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Posted

About one and a half years ago, Intel released LGA 1156, and plus three chipset P55/H55/H57.

As to CPU, main products are Core i3/i5/i7, and their obvious features are:

dual-core with built-in GPU, quad-core with built-in HT, and quad-core without built-in HT respectively.

As mentioned before, the primary goal of LGA 1156 platform is to replace Intel high-intermediate-level products;

besides, LGA 1366 is still the predominant platform for the high-level ones.

 

The product positioning of the new LGA 1155 is similar to that of LGA 1156.

To most users, they probably feel that the replacing is too fast. When facing three kinds of LGA platform, they even feel perplexed.

If future price of LGA 1156 can be lowered appropriately,

it is also a good trend that the platform becomes the mainstream for low-intermediate-level products.

 

bp6701.jpg

 

At the beginning of 2010, Intel introduced 32nm CPU, and the related products are:

dual-core—LGA 1156 i3 and i5; six-core—LGA 1366 i7 980X Extreme, representing low and high-level CPU respectively.

As for 32nm quad-core processor, Sandy Bridge LGA 1155 will be released in 2011.

 

This article will introduce the latest LGA 1155 platform, and analyse important features about 32nm Sandy Bridge CPU.

As for the CPU, it is Intel Core i7-2600K, and “K” means that CPU multiplier can be unlocked.

The clock is 3.4GHz (maximum: 3.80GHz), and Turbo Boost 2.0 technology is supported.

There are 4 Cores and Hyper-Threading technology, so 8 Threading is supported, also abbreviated as 4C/8T.

And, the CPU uses 32 nm manufacturing process, with 95W and 8MB L3 Cache, is the highest-level specification amongst current LGA 1155.

 

bp6702.jpg

 

Back side of 2600K D1 and 2400 D2:

bp6703.jpg

 

The motherboard is BIOSTAR TSERIES TP67XE, and this brand’s products are famous for parity and overclocking.

The colour of the package is different; this time red makes the looking of the motherboard more distinguishing feature.

bp6704.jpg

 

Accessories:

User’s Manual, Rear I/O Panel for ATX Case, Serial ATA Cable, CorssFire/SLI Bridge, Fully Setup Driver CD.

bp6705.jpg

 

As for colour matching, PCB is black, and PCI-E or DIMM are matched red or white; the whole appearance looks not bad.

bp6706.jpg

 

Red matching is an eye-catching design.

More and more electronic products are matched red and black,

the colour combination (similar to the colour used in automobile racing) that stresses speed or high performance.

bp6707.jpg

 

Lower-left of the motherboard:

2 X PCI-E 2.0 X16: support 2Way CrossFireX and SLI technology, with bandwidth X8+X8

2 X PCI-E X1

2 X PCI

LAN chipset: Realtek RTL8111DL

Codec: Realtek ALC892, with 8+2 channels and supporting Blu-ray Codec technology

bp6708.jpg

 

Lower-right of the motherboard:

3 X red SATAII: provided by P67 chipset, support RAID 0, RAID 1, RAID 5, and RAID 10

2 X white SATAIII: provided by P67 chipset, support RAID 0, RAID 1, RAID 5, and RAID 10

Power button, reset button, and debug indicators

bp6709.jpg

 

Upper-right of the motherboard:

4 X DIMM DDR3, supporting 1066/1333/1600/1866/2133, maximum capacity of DDR3 is 16GB. Only by overclocking can DDR3 2133 above be achieved.

1 X IDE, 24-pin power connector

bp6710.jpg

Posted (edited)

Upper-left of the motherboard:

TP67XE adopts 10-phase power supply, the design that is enough for 32nm CPU. There are two 8-Pin power connectors,

which are usually seen only on high-level motherboard (such as for server).

The existence of dual 8-Pin is not aimed at high power consumption of P67,

but at LN2 users who have to consume more 12V under high clock (such as overclocking).

bp6711.jpg

 

IO:

6 X USB 2.0 (Red/Black)

2 X USB 3.0 (Blue)

1 X eSATA/USB 2.0 (both Red)

1 X 1394

1 X RJ-45

1 X S/PDIF

bp6712.jpg

 

bp6713.jpg

 

In the past, I preferred not using a computer case when testing hardware.

But this time many net pals hope me to use a case so that the test result,

such as overclocking ability and temperature, will be more similar to most consumers’ condition.

The case is high-intermediate-level product

Antec DF-35, with 1 x top 140mm fan, 1 x rear white 120mm fan, and 2 x front variable-speed 120mm fans with white LED.

DF-35 has such advanced cooling system that it is helpful to keep the system steady after the computer is overclocked.

bp6714.jpg

 

Test platform:

CPU: Intel Core i7-2600K

MB: BIOSTAR TSERIES TP67XE

DRAM: CORSAIR DOMINATOR-GT CMT4GX3M2B2133C9

VGA: GIGABYTE GTX460 OC

HD: Intel X25-V 40GB RAID 0

POWER: Antec High Current Gamer 620W

Cooler: Mega Shadow Deluxe Edition

Case: Antec DF-35

OS: Windows7 Ultimate 64bit

bp6715.jpg

 

Whole LGA 1155 system in Antec DF-35:

bp6716.jpg

 

BIOSTAR provides much software:

bp67os1.png

 

Energy-saving software has been very popular in recent years.

CPU can effectively lower power consumption according to user’s setting.

bp67os2.png

 

TOVERCLOCKER is BIOSTAR’s unique software

The software provides CPU, Memory information, and also shows H/W Monitor.

bp67os3.png

 

In TOVERCLOCKER, OC TWEAKER, which can adjust many clocks, is a useful tool to overclock.

bp67os4.png

Edited by windwithme
Posted

Default performance:

CPU 100.1 X 35 => 3502.7MHz (Turbo Boost enabled, C1E disabled)

DDR3 2135.2 CL7 10-7-27 1T 1.650V

 

The architecture of Sandy Bridge CPU is different from that of previous Core i7. The bus speed is changed to 100MHz.

And about other frequency information, the highest ratio of 1366 CPU is 133/1866, 1156 CPU is 133/1600.

Now the default frequency of 1155 CPU can achieve 100/2133, making DDR3 clock show better performance.

 

Hyper PI 32M X8=> 14m 57.750s

CPUMARK 99=> 540

bp67dpi.png

 

Nuclearus Multi Core => 22513

Fritz Chess Benchmark => 27.58/13236

bp67dnm.png

 

CrystalMark 2004R3 => 332817

bp67dcm.png

 

CINEBENCH R11.5

CPU => 6.83 pts

CPU(Single Core) => 1.43 pts

bp67dcb.png

 

PCMark Vantage => 19941

bp67dpcvan.png

 

3DMark Vantage

CPU SCORE => 53268

bp67d3dvan.png

 

The default clock of 2006K is 3.4GHz. After Turbo Boost 2.0 is enabled, the clock can achieve 3.5~3.8GHz by CPU usage.

Hence, the test figures above are great, so the result means CPU can easily deal with many tasks under any circumstances.

And as to CPU performance under the same clock, I find that LGA 1155 is about 10% higher than LGA 1156.

As to DDR3 bandwidth, probably with more advanced Memory Controller technology, I find there is 20~30% performance improvement in much software.

Therefore, about basic performance and DDR3 bandwidth, Intel Sandy Bridge CPU with latest architecture has made great progress.

 

Temperature:

System standby: 33℃~37℃

bp67dt2.png

 

Hence about the temperature of 2600K:

Standby: about 3℃~5℃lower than the temperature of 1156 45nm CPU.

Full usage: about 10℃lower than the temperature of 1156 45nm CPU.

It goes without saying that as to testing temperature, different motherboards display divergent results.

But through the comparing, we can observe the temperature difference between 32nm and 45nm of 4C8T.

 

Power consumption:

Standby: 84W

bp67dwidle.jpg

 

CPU full speed: 125W

bp67dwfull.jpg

 

As to power consumption, with 32nm manufacturing process technology, the power saving of this CPU is 30~50W more than that of 45nm Core i7.

So obviously Sandy Bridge CPU can save more energy, and this is also one of the reasons why consumers may prefer quad-core platform.

Posted

Please refer to my BIOS setting:

Boot logo:

bp67b01.jpg

 

Main page:

Compliency is AMI UEFI X64 2.0

bp67b02.jpg

 

O.N.E page:

The default setting of Turbo Mode is 38, 37, 36, and 35, with better CPU speeding up mode in version 2.0.

As to DRAM frequency, 1066~2133 modes are supported, so users can enjoy better DDR3 performance.

CPU Base Clock shows 10000, which means current bus speed is 100.00MHz; if it shows 10560, which means 105.60MHz.

Therefore, the item may not show an integer, such as 133, 166, 200MHz.

bp67b03.jpg

 

The setting above is DDR3 arguments, providing users to choose faster arguments; of course, making the system steady is also important.

There are 4 modes for CPU VCore Mode: SPEC Volgate/Auto/Offset Mode/Fixed Mode

CPU VCore Offset +0.010~+0.520V

CPU VCore Fixed 1.000~1.790V

bp67b04.jpg

 

DRAM Voltage 1.300~2.200V

bp67b05.jpg

 

CPU Configuration:

Some functions about CPU, such as common HT technology; you also can choose how many cores you want to activate.

bp67b06.jpg

 

PC Health Status:

With built-in monitor chipset, you can know main voltage or temperature information.

bp67b07.jpg

 

As to overclocking, this time it is not necessary for LGA 1155 to adjust too many items.

So just focus on CPU voltage, clock multiplier; and DRAM clock, arguments, voltage.

Due to the limited scope of bus speed (about 5~7%), using K series CPU would be a better choice to overclock substantially.

 

As to DDR3, I use US brand CORSAIR high-level DOMINATOR-GT series—the latest CMT4GX3M2B2133C9.

GT series use red and black as colour matching; in recent year, more and more motherboard and DRAM also use the two colours.

bp6717.jpg

 

The argument specification is CL9 10-9-27 1.50V.

Compared with DDR3 voltage specification (1.650V) recommended by Intel, 1.50V only of GT 2133 can make the system steady.

AIRFLOW of Red-black version with DOMINATOR-GT makes the appearance quality nicer.

bp6718.jpg

 

CPU 3502.8MHz DDR3 2135.2 CL7 10-7-27 1T 1.650V

ADIA64 Memory Read: 22132 MB/s

Sandra Memory Bandwidth: 28132 MB/s

MaXXMEM Memory-Copy: 21755 MB/s

bp67dmem.png

Posted

CPU 5020.4MHz DDR3 2142 CL7 10-7-27 1T 1.650V

ADIA64 Memory Read: 25582 MB/s

Sandra Memory Bandwidth: 28475 MB/s

MaXXMEM Memory-Copy: 28139 MB/s

bp675gmem.png

 

After CPU clock rises, the test figures of memory bandwidth in ADIA64 and MaXXMEM also rise obviously,

but not in Sandra Memory Bandwidth; this is the main difference amongst the three software.

And about the test figure of bandwidth, even if LGA 1155 and LGA 1156 are both dual-channel design,

the former shows about 20% greater performance than the latter does.

Although Sandy Bridge CPU only uses dual-channel design, its memory bandwidth can compete with that of LGA 1366.

 

ADIA64 Memory Read: 26605 MB/s

Sandra Memory Bandwidth: 29903 MB/s

MaXXMEM Memory-Copy: 29007 MB/s

bp675g2251mem.png

 

Due to the limited scope of bus speed of Sandy Bridge architecture, about only 104~108MHz can be adjusted (depending upon each CPU).

The default CPU bus speed can contribute to achieve DDR3 2133 clock rate, so overclocking would not be a big problem.

If DRAM quality is good enough, performance over DDR3 2200 is not a difficult challenge.

 

Overclocking performance:

CPU 100.4 X 50 => 5020.2MHz(Turbo Boost disabled; C1E disabled)

DDR3 2142 CL7 10-7-27 1T 1.650V

 

Hyper PI 32M X8=> 12m 06.384s

CPUMARK 99=> 774

bp675gpi.png

 

Nuclearus Multi Core => 32585

Fritz Chess Benchmark => 39.29/18859

bp675gnm.png

 

CrystalMark 2004R3 => 427585

bp675gcm.png

 

CINEBENCH R11.5

CPU => 9.82 pts

CPU(Single Core) => 2.05 pts

bp675gcb.png

 

PCMark Vantage => 25062

bp675gpcvan.png

 

3DMark Vantage

CPU SCORE => 65044

bp675g3dvan.png

 

After 2600K is overclocked from 3.5 GHz to 5GHz, performance increases 20~30% in most software mentioned above.

When CPU is in full usage, voltage only needs 1.392V; hence, 32nm manufacturing process makes overclocking ability much better.

According to the related information I acquired on the Internet, 2600K over 5GHz is not commonly seen;

generally, the scope 2600K D1 is about 4.7~4.9GHz under air-cooling system.

The performance of Sandy Bridge is still better than 45nm 4C8T CPU (overclocking scope is 4.1~4.3GHz).

 

Temperature:

System standby: 43℃~46℃

bp675gt1.png

 

CPU in full usage: 74℃~83℃

Intel Burn Test v2.4,Stress Level Maximum

bp675gt2.png

 

If you want to overclock over 5GHz, you have to increase voltage, and note that temperature also rises much.

If you prefer low voltage and temperature for long-time using, 4.5GHz can be steady under 1.272V only.

Users can set personal setting by their preference.

Posted

Power consumption test:

System standby: 139W

bp675gwidle.jpg

 

CPU in full usage: 257W

bp675gwfull.jpg

 

Compared with power consumption of default clock rate:

Power consumption of system standby: 65% higher

Power consumption of CPU in full usage: 105% higher

It seems that the consumption increase so much, but as far as 5GHz high clock rate and high performance platform is concerned, 257W can be acceptable.

 

By the way, is 5GHz the maximum for 2600K under air-cooling? If fortunately, 5.1GHz can be achieved steadily.

CPU 100 X 51 => 5100.4MHz(Turbo Boost disabled; C1E disabled)

DDR3 2133.6 CL7 10-7-27 1T 1.650V

 

Hyper PI 32M X8=> 11m 48.382s

Fritz Chess Benchmark => 40.11/19251

bp6751gpi.png

 

As to the latest Sandy Bridge LGA 1155 CPU in 2011, 2300~2500K all use L3 Cache 6MB, and only 2600/2600K is equipped with 8MB.

K series are 2500K and 2600K, but other Sandy Bridge CPU, with limited scope of bus speed, may only have 5~8% overclocking scope.

Therefore, LGA 1155 is categorised definitely.

To the consumers who want to overclock, choosing K series is suggested, but with higher prices.

And most of the other Sandy Bridge CPUs may be suitable to the consumers who don’t overclock.

About the consideration above, I’m not sure that Intel is overconfident with Sandy Bridge performance, or that Intel wants to let LGA 1156 survive.

 

Originally, I thought that the reason why clock rate and power consumption of LGA 1155 platform made great progress was that 45nm manufacturing process became 32nm.

However, afterwards I find that all Sandy Bridge CPUs are built in GPU,

so it will be more convenient for users in future to use the chipset with display output function, such as H67.

Moreover, another advantage of this new platform is that it has higher performance of DDR3 and Turbo Boost 2.0 technology.

 

bp6719.jpg

 

I use new generation P67 chipset in the test.

When manufacturers release P67 motherboards in the market, their prices, I estimate, will be a bit expensive than the prices of P55 motherboards.

BIOSTAR TP67XE is still featured parity, and the price is about US$160.

The motherboard supports the latest USB 3.0 and SATA3; unique BIO-Remote2 multimedia software; and THX TrueStudioPRO sound effects technology.

Furthermore, TP67XE also shows great performance of overclocking, so it can be a high C/P P67 product.

BIOSTAR now also aims for supporting multimedia software and hardware technology, making its products more competitive in the market.

 

I shared much overclocking experience about X58 and P55 before,

and I shall continue overclocking and analysing P67 motherboards from various brands in future.

If there is something this article doesn’t mention, I shall renew related information in the future reports.

Finally, I hope with the release of new generation products, the prices of previous generation platforms can be lowered faster.

So, consumers can choose more platforms with good quality at bargain prices.

 

This article is also in my blog WIND 3C. Any comments are always welcome :)

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