ASRock N7AD-SLI

[ASRock N7AD-SLI]

Years ago when we started reviewing ASRock motherboards, most of them were fairly basic with very few features compared to what could be found on the ASUS or Gigabyte motherboards. With time though ASRock has begun ramping up their motherboards with more features, new innovative designs, and other improvements that cater towards the desires of enthusiasts and gamers. These days there are ASRock motherboards that can compete with those from major OEMs both in terms of features and in terms of performance, while delivering a better price. One example of a modern, feature-rich ASRock motherboard is the N7AD-SLI. The ASRock N7AD-SLI has NVIDIA SLI support, Gigabit LAN, IEEE-1394 Firewire, S/PDIF output, OC Tuner, solid capacitors, and an instant boot technology. This motherboard is centered around NVIDIA's nForce 740i SLI Chipset.
Features:

Processor
- LGA 775 for Intel Core 2 Extreme / Core 2 Quad / Core 2 Duo / Pentium Dual Core / Celeron Dual Core / Celeron
- Supports Penryn Quad Core Yorkfield and Dual Core Wolfdale processors
- Supports FSB1600/1333/1066/800/533 MHz
- Supports Hyper-Threading Technology
- Supports Untied Overclocking Technology
- Supports EM64T CPU

Chipset
- NVIDIA nForce 740i SLI

Memory
- Dual Channel DDR2 memory technology
- 4 x DDR2 DIMM slots
- Supports DDR2 800/667 non-ECC, un-buffered memory
- Maximum capacity of system memory: 16GB

BIOS
- 8Mb AMI BIOS
- AMI Legal BIOS
- Supports "Plug and Play"
- ACPI 1.1 Compliance Wake Up Events
- Supports jumperfree
- SMBIOS 2.3.1 Support
- CPU, DRAM, NB, VTT Voltage Multi-adjustment
- Supports Smart BIOS

Audio
- 7.1 CH Windows Vista Premium Level HD Audio with Content Protection
- DAC with 110dB dynamic range (ALC890 Audio Codec)

LAN
- Gigabit LAN 10/100/1000 Mb/s
- Giga PHY RTL8211CL
- Supports Wake-On-LAN

Unique Features
- ASRock OC Tuner
- Intelligent Energy Saver
- Instant Boot
- Hybrid Booster:
- CPU Frequency Stepless Control
- ASRock U-COP
- Boot Failure Guard (B.F.G.)

Form Factor
- ATX Form Factor: 12.0-in x 8.2-in, 30.5 cm x 20.8 cm
- All Solid Capacitor design (100% Japan-made high-quality Conductive Polymer Capacitors)
Contents:

While ASRock's motherboards have improved over the past few years, their packaging remains largely the same. A simple cardboard divider separates the ATX motherboard from the accessories. One of the ways ASRock keeps the cost of their motherboards low is through including a limited number of accessories -- unlike the ASUS, Gigabyte, or MSI motherboards that may include say six Serial ATA cables, ASRock will just include two. Included with the N7AD-SLI was the user's manual, I/O panel, Windows driver CD, two Serial ATA data cables, one SLI bridge, one ribbon IDE cable, one ribbon FDD cable, and one 4-pin molex to SATA power adapter.

[ASRock N7AD-SLI] [ASRock N7AD-SLI]

Intel Core 2 Extreme QX6700

Since the release of Intel’s Conroe micro-architecture, the company has been making waves, massive waves. In terms of performance, Intel washed away main competitor AMD, and they have continued to do so during the past three months with the success of their Core 2 Duo and Extreme processor series.

The only counter AMD has been able to come up with so far is to completely slash prices for all their existing processors, making them extremely tempting as well. Nevertheless, the performance of the Core 2 Duo processor range is so compelling, that even die-hard AMD fans have been taking notice.

The Conroe, or as it is better known, the Core 2 Duo, is a Pentium replacement, meaning we will now longer see any new Pentium branded processors. The Pentium 5xx, 6xx and D series are already becoming a thing of the past. So with Intel now focusing all their attention on the Core 2 series, you can expect it to expand quite rapidly.

Currently, there are four Core 2 Duo processors which were released at the initial launch (E6300, E6400, E6600 and E6700). There is also the Core 2 Extreme processor dubbed the X6800, though it offers very little in the way of performance over the E6700. There is said to be four new Core 2 Duo processors on the way that will run on a 1333MHz FSB and will all feature the larger 4MB L2 Cache. They are the E6650, E6750, E6800 and E6850, though we are not here to discuss these processors today. Rather, we are here to examine the new Kentsfield micro-architecture which is based on a quad-core 65nm design.

Step aside dual-core, it is now the time of the quad-core and you better believe it. The new quad-core series consists of the Core 2 Quad Q6600 and the Core 2 Extreme QX6700. Both feature a dual 4MB L2 cache, operate on a 1066MHz FSB, and have a thermal output of 130 watts. However, the Core 2 Quad Q6600 is not scheduled for release until early next year, and so today we will be looking at the more powerful Core 2 Extreme QX6700 version, which Intel had promised to make available this month, humming along to the tune of just 2.66GHz using a cool 1.34 volts of power.

Easily the biggest downfall of the dieing breed of Pentium processors was its thermal output, which was getting quite ridiculous. Therefore the new Kentsfield and Conroe cores were designed not only with performance in mind, but also power consumption and heat output.

Probably the biggest question on the mind of those that have recently upgraded to Intel Core 2 processors is compatibility, will the new Kentsfield processors work with your existing platform? Well the good news is yes, they will. Worst case scenario a BIOS update may be required to support these new desktop processors, according to Intel. These are great news for current Intel users, and it is good to see the continued use of the LGA775 platform, which is still relatively new anyway. The downside in the other hand, and a quite expected one, is that quad-core processors will start selling at well over $800 each, with today's review item, the Core 2 Extreme QX6700 going for a cool $1000 per processor.

The Core 2 processors quickly became the fastest in Intel's camp once released, and there were a number of good reasons for this, such as the Smart Cache and Wide Dynamic Execution technologies. Then there is the virtualization technology which is designed to maximize the processors' multi-tasking performance. This is done by splitting the computer into numerous virtual systems, all of which can run different applications. This technology is so powerful that in theory it could be possible to play a game on one, watch a movie on the other, host a web server on a third, run a database from a fourth, and surf the Internet on another.

The very same technologies that made the Conroe so powerful are all included in the new Kentsfield architecture. In fact, there are no new additions, so it is merely a quad-core version of the Conroe, but of course this is hardly a bad thing. Given the Core 2 Extreme QX6700 shares the same specifications as the Core 2 Duo E6700 minus the extra two cores, you should not expect it to offer dramatically better gaming performance than the E6700, as the current line up of PC games have shown are not too susceptible to the number of processor cores as they are perhaps to increases in clock frequencies.

System Specs & Memory Performance

Hardware
- Intel Core 2 Extreme QX6700 (2.66GHz)
- Intel Core 2 Extreme X6800 (2.93GHz)
- Intel Core 2 Duo E6700 (2.66GHz)
- Intel Pentium D 950 (3.40GHz)
- 2GB Corsair XMS DDR2-800 (CAS4)
- ASUS P5W DH Deluxe (Intel 975X)
- OCZ GameXStream (700 watt)
- Seagate 250GB 7200RPM (Serial ATA II)
- Gigabyte Radeon X1900XTX (512MB)
Software
- Microsoft Windows XP Pro 32bit (SP2)
- ATI Catalyst (6.10)
- Intel System Drivers (7.2.2)

The memory performance of the QX6700 is much the same as that of the E6700. Both processors are operating at 2.66GHz using a 1066MHz quad-pumped FSB, so the similarities in memory performance are not all that surprising. In fact, all four configurations delivered similar memory performance and all four used the same DDR2-800 memory.

You should get used to this scenario where the Core 2 Extreme X6800 shows a slight performance edge because the tests take better advantage of higher clock frequencies than the extra cores.

Refference : http://www.techspot.com/review/27-intel-core2-extreme-qx6700-quad/

AMD Phenom II X4 955 Black Edition review

AMD kick started 2009 with guns blazing introducing their latest Phenom II X4 platform on early January. Although the launch was comprised of just two processors, that's all AMD needed to compete head to head with the Intel Core 2 Quad range.

The flagship model, also known as the Phenom II X4 940, debuted at just $270, while today it can be had for the bargain basement price of $190. In terms of performance we found it closely matched the Core 2 Quad Q9650, which was considerably more expensive at $540 then, and even today it is still fetching around $330. This is an impressive feat for AMD, offering the best value in this price range.

Today AMD is releasing two new processors, the Phenom II X4 955 and 945, which are based on the same “Deneb” architecture though with a few notable changes. The most prominent change is that these are AM3 processors, and therefore can be used with either DDR2 or DDR3 memory. AM3 processors are also completely backwards compatible with AM2+ motherboards.

Although it was initially speculated that AMD would increase the L3 cache of these new Phenom processors from 6MB to 8MB, this has not been the case, and the Phenom II X4 955 still carries the same 6MB as its predecessors. The processor is however reaching new heights for AMD in terms of operating frequency, designed to work at 3.2GHz, it's fastest clocked quad-core processor the company has ever released.

Despite these improvements, the Phenom II X4 955 will remain affordable, with a suggested initial retail value of $245. This new processor looks as having the potential to be the ultimate upgrade solution for AMD users, as it can be paired with AM2+ motherboards that were released as far back as 2007.

Based on pricing, the Phenom II X4 955 could be best compared to the Core i7 920 ($290) and Core 2 Quad Q9550 ($270) processors, though it will be a tad cheaper than both. However it's not just the processor cost that needs to be considered here, as the Phenom II X4 955 can be used on both AM2+ and AM3 motherboards. Furthermore, while AMD does expect DDR3 memory to become mainstream in 2010, the Phenom II X4 955 can be paired with ultra cheap DDR2 memory for now, postponing the migration to DDR3 until it makes complete sense financially for consumers.

AM3 Socket and DDR3 Memory Support

The new Phenom II X4 955 and 945 processors can still make good use of the AM2+ socket, the very same socket used by existing Phenom X4 and X3 processors, as well as Athlon-based processors. Although the introduction of DDR3 memory support is new on this launch, the on-die controller is able to use either DDR2 or DDR3 memory.

Motherboard makers have already released BIOS updates enabling their current AM2+ motherboards to support the Phenom II X4 940/920 processors. There is now a new wave of updates adding support for the Phenom II X4 955/945 processors on these older motherboards.

We like to believe this is the perfect upgrade path, as those who invested in a Phenom platform a year ago need only to purchase a newer more powerful processor to get a boost. This also allows those looking to build a new Phenom-based PC to choose from a huge range of mature AM2+ motherboards. The groundbreaking 790GX chipset also supports the Phenom II X4, offering enhanced tuning via its advanced clock calibration feature.

Keep in mind however that although the Phenom II X4 955/945 processors will work on AM2+ motherboards, older processors will not work on the AM3 platform. The AM3 socket has two less pins (938), making it mechanically incompatible with older 940-pin AM2/2+ processors. Besides the pin compatibility issue, the real problem lies within the on-die memory controller of these older processors, which does not support DDR3 memory.

Unlike the LGA1336 (Core i7) socket, the AM3 socket is capable of running either DDR2 or DDR3 memory, but not both on the same motherboard. At least today that sounds like an excellent option to have, given DDR3's pricing compared to DDR2. Like previous AMD processors the Phenom II X4 955/945 processors feature a dual-channel memory controller. The maximum officially supported DDR2 frequency is 1066MHz while DDR3-1333 is also supported.

Test System Specs & 3Dmark Vantage

Core i7 Test System Specs - Intel Core i7 965 Extreme Edition (LGA1366) - Intel Core i7 940 (LGA1366) - Intel Core i7 920 (LGA1366) - x3 1GB DDR3-1066 Samsung (CAS 7-7-7-20) - Intel DX58SO (Intel X58) Pre-Production - OCZ GameXStream (700 watt) - Seagate 500GB 7200-RPM (Serial ATA300) - ASUS GeForce GTX 280 (1GB) Software - Microsoft Windows Vista Ultimate SP1 (64-bit) - Nvidia Forceware 182.50 Core 2 Test System Specs - Intel Core 2 Quad Q9650 (LGA775) - Intel Core 2 Duo E8600 (LGA775) - Intel Core 2 Duo E6700 (LGA775) - x2 Kingston HyperX 2GB DDR3-1333 (CAS 7-7-7-20) - ASUS Rampage Extreme (Intel X48) - OCZ GameXStream (700 watt) - Seagate 500GB 7200-RPM (Serial ATA300) - ASUS GeForce GTX 280 (1GB) Software - Microsoft Windows Vista Ultimate SP1 (64-bit) - Nvidia Forceware 182.50 Phenom Test System Specs - AMD Phenom II X4 955 (AM3) - AMD Phenom II X4 940 (AM2+) - AMD Phenom II X4 920 (AM2+) - AMD Phenom X4 9950 (AM2+) - x2 Kingston HyperX 2GB DDR2-1066 (CAS 5-5-5-15) - ASUS M3A79-T Deluxe (AMD 790FX) - ASUS M4A79 Deluxe (AMD 790FX) - OCZ GameXStream (700 watt) - Seagate 500GB 7200-RPM (Serial ATA300) - ASUS GeForce GTX 280 (1GB) Software - Microsoft Windows Vista Ultimate SP1 (64-bit) - Nvidia Forceware 182.50

The new AMD Phenom II X4 955 fairs very well in 3Dmark Vantage when paired with either DDR2 or DDR3 memory, though the DDR3-1333 configuration was faster, delivering 9% more performance when compared to the Phenom II X4 940.

This also put this new AMD processor ahead of the Core 2 Quad Q9650, though only by a 4% margin. Perhaps more impressive was seeing the Phenom II X4 955 running at a mere 3% slower than the Core 2 Core i7 920 in this test.

Benchmarks: PCmark Vantage, ScienceMark

The previous AMD Phenom II X4 processors fared well in the PCmark Vantage gaming test and the Phenom II X4 955 is no different, though it did fail to outperform the Phenom II X4 940.

While the Phenom II X4 processors were able to beat out the Core 2 Quad Q9650 in this test, the elusive Core i7 920 still remained a problem.

The PCmark Vantage communications test was quite different, the results are all over the place here. The AMD Phenom II X4 955 was faster than the Core i7 940 when using DDR3-1333 memory, but slightly slower with the DDR2-1066 memory.

Once again we found that when paired with DDR3 memory the Phenom II X4 955 was 9% faster than the Phenom II X4 940.

ScienceMark is another test that does not favor the Core i7 processors greatly and as a result the AMD Phenom II X4 955 is only a fraction slower than the Intel Core i7 965 Extreme Edition. The X4 955 was also 13% faster than the previous AMD flagship, the Phenom II X4 940.

Refference : http://www.techspot.com/review/162-amd-phenom2-x4-955/

Intel's Core 2 Duo and Extreme processors

INTEL'S DESKTOP PROCESSORS HAVE NOT been in a good place for the past two and a half years. Pentium 4 and Pentium D CPUs have run at relatively high clock speeds but delivered relatively low performance compared to their competition from AMD. They've also drawn a tremendous amount of power, which they've generously expended as heat. In other words, they've been hotter than Jessica Simpson and slower than, well, Jessica Simpson. Despite heroic efforts by Intel's engineering and manufacturing types, these chips based on the Netburst microarchitecture haven't been able to overcome their inherent limitations well enough to keep up with the Athlon 64. As a result, Intel decided to scrap Netburst and bet the farm on a new high-performance, low-power design from the Israel-based design team responsible for the Pentium M.

The product of that team's efforts is a new CPU microarchitecture known as Core, of which the Core 2 Duo and Core 2 Extreme are among the first implementations intended for desktop PCs. We've been knee-deep in hype about the Core architecture for months now, with a stream of juicy technical details, semi-official benchmark previews, and clandestine reviews of pre-release products feeding the anticipation. Clearly, when a player as big as Intel stumbles as badly as it has, PC enthusiasts and most others in the industry are keen to see it get back up and start delivering exciting products once again.

Fortunately, the wait for Core 2 processors is almost over. Intel has decided to take the wraps off final reviews of its new CPUs today, in anticipation of the chips' release to the public in a couple of weeks. Fish have gotta swim, politicians have gotta dissemble, and TR has gotta test hardware, so of course we've had the Core 2 processors on the test bench here in Damage Labs for a thorough workout against AMD's finest—including the new Energy Efficient versions of the Athlon 64 X2. After many hours of testing, we're pleased to report that the Core 2 chips live up to the hype. Intel has recovered its stride, returned to its winning ways, gotten its groove back, and put the izzle back in its shizzle. Read on for our full review.

Conroe up close
We first previewed the chip code-named Conroe back in March, and now we finally have our hands on one within the confines of our own labs. In spite of all the hype, the Core 2 Duo processor itself is a rather unassuming bloke that looks no different than Pentium CPUs that preceeded it. Like them, it resides in an LGA775-style socket and runs on a 1066MHz front-side bus.

The Core 2 Duo E6700 processor Also like its most immediate predecessors, the Core 2 Duo is manufactured on Intel's 65nm fab process. Unlike them, however, the Core 2 Duo is not comprised of two chips crammed together on one package; it's a native dual-core design with a total of roughly 291 million transistors arranged in an area that's 143 mm². By contrast, each of the Pentium Extreme Edition 965's two chips have an estimated 188 million transistors in an 81-mm² die. If you add the two chips together, the Pentium Extreme Edition 965 has more total transistors and a larger total die area than the Core 2 Duo.

Intel plans to offer five flavors of Core 2 processors initially, with prices and features like so:

Model	Clock speed	Bus speed	L2 cache	TDP	Price
Core 2 Extreme X6800	2.93GHz	1066MHz	4MB	75 W	$999
Core 2 Duo E6700	2.67GHz	1066MHz	4MB	65 W	$530
Core 2 Duo E6600	2.4GHz	1066MHz	4MB	65 W	$316
Core 2 Duo E6400	2.13GHz	1066MHz	2MB	65 W	$224
Core 2 Duo E6300	1.86GHz	1066MHz	2MB	65 W	$183

The prices on the mid-range models are quite reasonable once you consider performance, as we'll do shortly. What you'll really want to notice about the Core 2 chips, though, is the column labeled TDP. This parameter—thermal design power—specifies the amount of cooling the chip requires, and the numbers are down dramatically from the Pentium Extreme Edition 965's rating of 130W. Clock speeds are down, as well, since the Core microarchitecture focuses on achieving high performance per clock rather than stratospheric clock frequencies. The fastest Core 2 processor is the X6800 Extreme, which is separated from the regular Core 2 Duos only by its 2.93GHz clock speed and a 10W higher TDP—oh, and by almost half a grand.

Intel says complete PC systems based on the Core 2 Extreme X6800 and individually boxed products will both begin selling on July 27th, while Core 2 Duo processors with 4MB of L2 cache should show up on August 7th. Intel will be transitioning its CPU production gradually away from Pentiums to Core 2 Duos, and that transition might not happen as quickly as the market would like. I wouldn't be surprised to see strong demand and short supply of these processors for the next couple of months, until Intel is able to ramp up production volumes. The less expensive versions of the Core 2 Duo with 2MB of L2 cache are initial casualties of this controlled ramp. They aren't expected to be available until the fourth quarter of this year.

On a brighter note, the supporting infrastructure for Core 2 chips is already fairly well established. The processors should be compatible with a number of chipsets, including the enthusiast-class 975X and the upcoming 965-series mainstream chipsets from Intel. NVIDIA's nForce4 SLI X16 Intel Edition should work, too, as well as the yet-to-be-released nForce 500 series for Intel. In fact, the Core 2 can act as a drop-in replacement for a Pentium D or Pentium Extreme Edition, provided that the motherboard is capable of supplying the lower voltages that Core 2 processors require. Only the most recent motherboards seem to have Core 2 support, so you'll want to check carefully with the motherboard maker before assuming a board is compatible. Our Core 2 Duo and Extreme review samples, for example, came from Intel with an updated version of the D975XBX motherboard, since older revisions couldn't supply the proper voltage.

Speaking of which, the upgrade path for those who buy motherboards for Core 2 processors in the next few months isn't entirely clear. The server/workstation version of the Core microarchitecture, the Woodcrest Xeon, already rides on a faster 1333MHz front-side bus. The Core 2 Duo may move to this faster bus frequency at some point, but Intel hasn't revealed a schedule for this move. Intel has revealed plans to deliver "Kentsfield," a quad-core processor with two Conroe chips in a single package, in early 2007, but we don't yet know whether current motherboards will be able to support it. Investing in a Core 2-capable motherboard right now might be a recipe for longevity, but it might also be a dead end as far as CPU upgrades are concerned.

What's with the name?
Before we go on, we should probably take a moment to talk about the Core 2 Duo product name. It's dreadful, of course, but for deeper reasons than you might think. You see, microprocessors tend to be known by several names throughout their lives, and usually those names aren't really related. For example, the chip code-named Willamette, based on a microarchitecture called Netburst, became the first product known as Pentium 4. The multiple names may be a little difficult to keep straight, but they're distinctive and follow a coherent logic.

This chip, however, is different. The microarchitecture is called Core, the chip is code-named Conroe, and the product is called Core 2 Duo. By that logic, the chip code-named Willamette would have been based on the Willette microarchitecture, and the first product might have been the Willette 4 Quadro, which everyone knows is actually a disposable razor.

The Core 2 Duo's name does make sense from a certain perspective, though, because Intel has been shipping the original Core Duo as a dual-core mobile processor since the beginning of the year. There's also a single-core version of that processor known as the Core Solo, which explains the whole Duo suffix. And the mobile version of the Core 2 Duo, based on the chip code-named Merom, will be the follow-up to the Core Duo.

See? Ahh.

So why name the microarchitecture Core? You've got me. The Core microarchitecture is a descendant of the one found in the current Core Duo, but it's been pretty extensively reworked and certainly deserves a new name. The fact that its name matches up with the previous-gen product's name is confounding. We'll simply have to, as one Intel employee admonished at the Spring '06 IDF, "Deal with it."

Refference : http://techreport.com/articles.x/10351

ASUS Rampage 2 Extreme Motherboard

An ASUS Motherboard For Enthusiasts - RE2

For as many years as I have been building my own PC's, many of my friends have sworn by ASUS for the best stability, top end features, and great overclocking. Today, ASUS is still considered by most as the elite motherboard manufacturer for desktop motherboards. Over the last few years ASUS has stepped beyond the ordinary offerings to bring us something truly radical, even branding a name to their special line of motherboards. Dubbed the "Republic of Gamers" series, or ROG, these motherboards are considered the elite with cutting edge overclocking abilities and performance that few other boards can match.

Today, we are lucky enough to have such an ROG board to test, the Rampage 2 Extreme. The original Rampage Extreme was based on Intel's X48 chipset and was given the Editor's Choice award in our September review. This time around, ASUS has worked their mojo on Intel's X58 chipset while adorning it with some incredible features and eye catching colors. Let's take a look at the incredible list of features before we move on.

Refference : http://www.legitreviews.com/article/933/1/

MSI K9A2 Platinum Motherboard on AMD 790FX Chipset (Socket AM2+)

• AMD 790FX chipset (AMD 790FX + SB600)

Our recent research (as well as observations of our colleagues and users, who already tried these processors) proves that it's practically impossible to find real applications to detect the notorious TLB error in the first revision of Phenom processors on Agena core. Everything works fine! We can only guess why AMD made such a fuss about this bug and reduced the scope of CPU deliveries until the new revision. Perhaps, the company did not have enough time for thorough tests, engineers were afraid that the bug could really show up somewhere, and the fact that a bug was detected by a user instead of the manufacturer could have a negative effect on reputation.

It must be noted that bugs in processors are not anything new. For example, the first revision of Core 2 Duo contained 67 bugs! When reporters paid attention to this fact, this document was removed from the Intel web site. No delays or reductions in deliveries followed. The company just promised to fix 20 out of 67 bugs in the nearest revisions. We still don't know whether the company fixed the remaining bugs, by the way. We only know that new bugs were added in the 45 nm revision. However, this fact will hardly affect Intel's plans, to say nothing about deliveries of already manufactured CPUs. You have the right to hold up this approach to cheating, but it will hardly damage Intel's reputation.

What's important, your chances to face these bugs are purely theoretical, be it 45 nm Core 2 eXtreme QX9650 or Phenom. What does it mean in practice? The above mentioned QX9650 has a higher clock rate and performance than the existing Phenom products, of course. But despite all these factors, a Phenom processor can be used to assemble a good computer, which will be equal to a single QX9650 processor in price. What concerns the Phenom 9500, its retail prices started from $260 at the time this article was written, that is lower than the minimal price ($280) for the cheapest Core 2 Q6600. In other words, Phenom processors are quite competitive even now (they might have been even more attractive, if they had been delivered in sufficient volumes to lower retail prices).

Why do I touch upon this issue in a motherboard review? Firstly, as you might have already noticed, we review processors and motherboards (in compliance with modern trends to unite these components into commercial platforms) in the same section. It's politically incorrect to skip usability issues of a given product. Because, (secondly) the most natural processors for motherboards on AMD 790FX are Phenom products (while inexpensive motherboards on AMD 790X or 770 are actively used with Athlons). Thirdly, this very motherboard currently comes (at the time this article was written) at the lowest price among motherboards on this chipset, which also sounds practical. OK, let's proceed to the main topic of our review.

The central feature of this motherboard, which can be used by MSI as a competitive advantage, is alternating graphics and non-graphics slots. So you can build a Quad CrossFire system even with two-slot graphics cards, for example, Radeon HD 3870 with the reference cooler. However, the other devices in this case will have to be connected to peripheral ports only, because two PCI and PCIEx1 ports will be blocked. However, firstly, you can find almost any device now in the external modification for USB or FireWire. They will be more expensive, but this fact shouldn't confuse users with such high requirements. Secondly, a gaming computer with several graphics cards is not an all-purpose system, and it cannot be approached with general requirements. It's a specialized system used mostly for games. Users of such systems are likely to have other computers (for example, a notebook and a media center), so there is no need to install a built-in TV tuner or a professional sound card in this computer.

Another peculiarity of this motherboard is that it uses Promise T3 as its additional SATA controller. It provides compatibility with Serial Attached SCSI drives. This interface has an advantage over SATA for workstations and servers, and it's backward compatible with SATA (that is SATA drives can be plugged to the SAS controller), while SAS devices can be connected to a SAS controller only. The only limitation here is compatibility with storage drives only, while the SAS standard itself supports a wider range of devices, for example, scanners. However, this feature is not used often in practice.

The cooling system of the chipset consists of three heat sinks connected with heat pipes. The heat sink on the north bridge has the most interesting shape (MSI claims that such a shape is not only looking good, but also contributes to thermal efficiency). Besides, this heat sink and the one on field-effect transistors are in the air intake zone of the CPU cooler. Should we say that such a cooling system hardly gets warmer than the environment temperature working with a chipset with TDP=10 W (even though there is no need to cool the chipset to this temperature level)? However, engineers traditionally refer to the needs of overclockers, who may need their voltage regulator elements cool for higher stability. The retention module of the cooling system also produces a positive impression. Chipset bridges contact the heat sinks through thermal grease (dense, but sticky and soft). The contact with transistors of the voltage regulator is praiseworthy, imprints on the thermal gasket leave no doubts of its high quality.

The 5-phase switching voltage regulator incorporates two field-effect transistors per channel, ten 820 uF capacitors and five 470 uF ones made by Panasonic. Following the modern trend, the motherboard uses only solid-state capacitors with polymeric electrolyte. The power circuits are very good. Despite the open chokes in some circuits, we heard no unwanted noise during our tests.

PCB design allows to install the second network controller and a processor from Creative instead of the Realtek audio codec. As is well known, these addons traditionally correspond to Diamond motherboards from MSI. There is no such model in the MSI product line yet. However, judging by characteristics, the AMD 790FX chipset is here to stay. So MSI can add this modification in future. Motherboard dimensions - standard ATX (305x245 mm), nine-screw mount, all corners are firmly fixed. It should be noted that the only obsolete port in this motherboard is COM, and you will have to install it on the rear panel manually. The floppy connector is preserved. If you have to use a motherboard outside a PC case, you will be pleased with a couple of buttons to power on/off and reset the system.

System monitoring (Fintek F71882FG, BIOS Setup)

• CPU voltage, +3.3 V, +5 V, +12 V, and +5 V Standby
• RPM of three fans
• CPU and board temperatures (by the corresponding embedded sensors)
• SmartFan - automatic CPU fan speed control depending on CPU temperature. You can specify the target temperature (40-55B°C) and minimum rotational speed. The control logic implies minimal speed until the target temperature is reached. After that the speed gradually grows until the temperature stabilizes. Temperature drops are also accompanied with gradual reduction of rotational speed. Only 4-pin fans can be controlled automatically. BIOS also allows to set the reduced (to 50% or 75%) fixed rotational speed of the system fan.

Onboard ports, sockets, and connectors

• Processor socket (Socket AM2, Socket AM2+ compatible, officially supports all Phenom, Athlon 64/X2/FX, and Sempron processors for Socket AM2 and Socket AM2+, the list of products, tested for compatibility, is published on the web site)
• 4 x DDR2 SDRAM DIMM (up to 8 GB DDR2-400/533/667/800, dual-channel mode)
• 2 x PCIEx16 2.0 for graphics accelerators (operating in x16 mode with two graphics cards, and in x8 mode with more cards installed)
• 2 x PCIEx16 2.0 for graphics cards (operating in x8 mode, they can be used only if you install three of four graphics cards)
• 1 x PCIEx1 2.0
• 2 x PCI
• Power connectors: standard ATX 2.2 (24 pins), 4-pin ATX12V, 4-pin "peripheral" connector for PCIE graphics cards, which should be used when you install several graphics cards with powerful GPUs without on-board power connectors
• 1 x FDD
• IDE (Parallel ATA) for two ATA133 devices - "chipset-based"
• 6 x SATA-II (Serial ATA II), support for four SATA300 devices is based on the chipset, connected drives can form RAID 0, 1, 0+1; support for another two is provided by the Promise T3 controller, which also offers compatibility with SAS storage drives, connected drives can form RAID 0, 1, 0+1 with devices plugged to eSATA ports on the rear panel
• 3 connectors for rear panel brackets with 6 x USB
• Connector for a rear panel bracket with 1 x FireWire
• Connector for the 4-LED indicator on the D-Bracket
• 1 x CD/DVD audio connector
• Connectors for analog audio ins and outs on the front panel
• S/PDIF-Out connector
• Connector for a bracket with a COM port
• Five fan headers, three of them offer rpm control; the 4-pin header for a CPU fan supports smart fan control

Back panel (left to right, blockwise)

Click for the image for the rear view.

• PS/2 mouse and keyboard
• FireWire 400 (6-pin)
• S/PDIF-Out (coaxial)
• 2 x eSATA II
• 2 x USB
• 2 x USB and 1 x RJ-45 (Gigabit Ethernet)
• 6 x Analog Audio (Center/Sub, Side-Out, Rear-Out, Line-In, Front-Out, Mic-In).

Package Contents

• Package: a standard box, typical of Platinum-series design
• Documentation: User's Manual and a poster with the PCB layout and feature highlights

• 2 x CrossFire Bridge

• Adapters for hot plugging ports and LEDs from a PC case to the motherboard
• 4 x Serial ATA cables
• 2 x SATA power converters for two devices
• 1 x ATA66, 1 x FDD
• Rear panel bracket with 2 x USB and a proprietary POST display with four LEDs
• Rear panel bracket with 1 x FireWire 400 (6-pin)
• Rear I/O shield
• Two CDs (for Windows XP and Vista) with drivers and MSI utilities:
  • MSI PC Alert 4 - system monitoring utility (you should use AMD OverDrive for overclocking)
  • MSI Live Update 3 - flashing BIOS under Windows, this utility can also search and download the latest BIOS version from the official web site.

Integrated Controllers

• Audio, based on the chipset support for High Definition Audio and Realtek ALC888 codec, 7.1 channel audio, front line-ins/outs, CD-In, and S/PDIF-Out jacks
• SATA-II, supporting 4 x Serial ATA II, RAID 0, 1, and 0+1, as well as SAS devices, based on Promise T3 PCIE controller
• Gigabit Ethernet, based on PCI-E controller Realtek RTL8111B, supporting 10/100/1000 Mbps
• FireWire, based on the VIA VT6308P (PCI) chip supporting two FireWire ports

The integrated audio quality was tested in 16 bit 44 kHz mode using RightMark Audio Analyzer 5.5 and the ESI Juli@ sound card:

Frequency response (from 40 Hz to 15 kHz), dB:	+0.02, -0.05	Excellent
Noise level, dB (A):	-91.9	Very good
Dynamic range, dB (A):	91.9	Very good
THD, %:	0.0028	Excellent
Harmonic distortion + noise, dB(A):	-82.7	Good
Intermodulation distortion + Noise, %:	0.0084	Very good
Channel crosstalk, dB:	-91.2	Excellent
IMD at 10 kHz, %:	0.0083	Very good

General performance: Very good. It's the best implementation of this codec of all we've ever tested. Even "harmonic distortion + noise" is Good instead of Average, typical of integrated solutions. The box mentions improved quality of the integrated audio controller as one of CoreCell functions. It's difficult to understand how this chip (it's quite far from the codec itself, and we have always though that it has to do with system monitoring and expanding overclocking features in BIOS) can contribute to noise reduction (that's exactly what's written in the description). However, audio quality is indeed improved. Perhaps, it has nothing to do with the above mentioned chip.

Proprietary technologies and peculiarities

• Dual CoreCell - system monitoring, overclocking, and other functions based on this chip
• D.O.T.3 - dynamic overclocking (it can also raise FSB clock rate) depending on CPU load, you can choose three overclocking modes for 20%, 50%, and 80% load.

Settings

Jumpers and switches	Clear CMOS jumper
	Two buttons (power on and reset)	They allow to power on and reset a computer without connecting corresponding cables to the front panel
AMI BIOS 2.61	Allows to disable specific CPU functions	+	K8 Cool'n'Quiet
	Memory timings	+	1T/2T Memory Timing, CAS Latency, RAS to CAS Delay, Row Precharge Time, Min RAS Active Time, Row Cycle Time, Row Refresh Cycle, Row to Row Delay, Write Recovery Time, Write-To-Read Delay, Read-To-Write Delay
	Memory frequency selection	+	Auto, x1, x1.33, x1.66, x2, x2.66 (multiplier to FSB clock rate)
	HT bus setup	+	x1-x13 (multiplier to FSB clock rate)
	Peripheral bus frequency control	-
	PCI IRQ manual assignment	+
	FSB frequency setup	+	200-600 MHz at 1 MHz steps
	CPU multiplier	+	from x4 at x0.5 steps
	CPU core voltage control	+	1.384-1.666 V at 0.040 V steps
	Memory voltage control	+	1.80-3.10 V at 0.05 V steps
	Chipset voltage control	+	1.125-1.525 V at 0.025 V steps (for the north bridge)
	HT bus voltage control	+	1.175-1.525 V at 0.025 V steps

We used BIOS 1.2 dated 21.12.07, the latest available BIOS version at the time of our tests. The mentioned BIOS parameters are available in this version, but the viability of non-standard settings hasn't been tested.

All necessary functions for overclocking are available. However, if you need some functions, which are not present in BIOS (for example, to adjust the clock rate of PCI Express bus or control CPU multipliers for each Phenom core separately), you can use AMD OverDrive, which is fully supported by this motherboard. If you are interested in automatic overclocking modes, you can use D.O.T.3 (Dynamic Overclocking Technology). It's really convenient for those users, who don't want to sacrifice economy to overclocking. This technology is evolving. It used to overclock the system only under maximum CPU load. Now we can choose three overclocking levels, corresponding to different CPU loads.

This is really important, because multicore processors are rarely loaded completely. If you start a single-thread application, it makes sense to raise CPU clock rate, even though the general load is relatively low. You can choose to raise the clock rate by 1-15% for each of three levels (20%, 50%, and 80% CPU load). What's important, this technology works well with Cool'n'Quiet. Unfortunately, voltage is not raised dynamically. Besides, you will have to adjust multipliers for memory and HyperTransport, if necessary. The motherboard allows to save BIOS settings in two profiles to CMOS, which facilitates manual overclocking.

Overclocking

In order to evaluate motherboard and its BIOS, we overclock our testbed processor to a maximum stable level. We use all features of the motherboard in this test, including raising CPU voltage and adjusting multipliers and frequencies of system and peripheral buses, if necessary. But if, for example, reducing Hyper-Transport frequency does not improve overclocking, we leave the default multiplier. Memory is set to the standard frequency for a given memory module (multiplier correction), if a manufacturer does not publish any ways to improve memory overclocking. Otherwise, we analyze their efficiency as well. In order to evaluate stability of the overclocked system, we load Windows XP and run WinRAR performance test for 10 minutes (Tools - Benchmark and hardware test). As overclocking potential is an individual property of a given motherboard sample to some degree, we don't set the task to determine overclocking potential to within a single MHz. In practice, we are to find out whether CPU overclocking will be limited by a motherboard as well as to evaluate its behavior in non-standard modes, including automatic restoration of a correct frequency after a failed overclocking attempt, etc.

	Clock, MHz	FSB Clock, MHz	Core voltage (according to system monitoring in BIOS), V	HT bus frequency (multiplier), MHz
Athlon 64 X2 4000+ (Windsor, 2.0 GHz)	2800	280	1.46	1400 (x5)

Overclocking results do not break any records, but they are quite high. Raising the frequency even by several MHz resulted in Windows startup errors, which couldn't be remedied by increasing voltages or by reducing multipliers. The function to roll back to the default clock rate after a failed overclocking attempt (when a computer freezes at startup) works correctly.

Performance

Testbed configurations:

• CPU: AMD Athlon 64 X2 4000+
• Memory: 2 x 1 GB Kingston KHX7200D2K2/1G (DDR2-800, 5-5-5-15-2T)
• HDD: Seagate Barracuda 7200.10 (SATA, 7200 rpm)
• Graphics card: ATI Radeon X1900XTX, 512 MB GDDR3
• PSU: Chieftec CFT-560-A12C
• OS: Windows XP SP2

We compared our product under review with the previously examined motherboard on the same chipset - Gigabyte MA790FX-DQ6.

Test	Gigabyte MA790FX-DQ6	MSI K9A2 Platinum
Archiving with 7-Zip, min:sec	6:28	6:27
MPEG4 (XviD) encoding, min:sec	5:59	5:58
DOOM III (Low@640x480), fps	138	137
DOOM III (Highest@1600x1200), fps	138	136
FarCry (Low@640x480), fps	167	164
FarCry (Highest@1600x1200), fps	124	123

Performance differences fall within fractions of a percent (and a measurement error). Out of doubt, it will be more interesting to test this motherboard with three or four graphics cards, especially as the company allocated much resources to perfecting drivers for efficient support of CrossFire configurations in the light of the Radeon HD 3870 X2 with two GPUs (it's no secret that software support is critical in this case).

Bottom line

Even though the AMD 790FX chipset offers a great reserve for the future (in other words, its functionality is hardly necessary for a generic modern computer, even if it's assembled for games), MSI tried to design a practical motherboard. It may come in handy to users, who want to rig it up to maximum right now (including four graphics cards with two-slot cooling systems). Those who just want to upgrade their computers or assemble a new one may also like this motherboard, if they want a platform that can be expanded in future, and which has no expensive bells and whistles (they are often installed in motherboards on top chipsets to justify high prices).

Refference : http://ixbtlabs.com/articles3/mainboard/msi-k9a2-platinum-790fx.html