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MULTI-LEVEL CELL (MLC) flash-based solid state disk drives were, until recently, considered more of a consumer device choice, since their read and write performance, as well as expected lifetime in terms of number of writes before the cell is gone, were quite a bit behind the standard SLC (Single Level Cell) devices seen in entereprise class SSD units.

However this year saw a massive change, as MLC gained both in performance and reliability, while keeping the capacity and price advantage it offers over SLC. The final blow was Intel’s own Series 710 enterprise SSDs shown at the IDF event in September. The new SSD drives, with up to 300GB capacity in a standard 2.5in form factor, completely replaced the previous SLC-based range.

What changes enabled this move? Improvements in the controllers and write leveling algorithms drastically reduced the write penalty while keeping good bandwidth and latency, and the silicon design of the cells themselves was sufficiently improved to further come closer to SLC performance and reliability.

With up to 38,500 IOPS in reading and 2,700 IOPS when writing (4K blocks), they stack up well to their SLC-based brethren, and you still get a 300GB enterprise drive for less than ,000 apiece. For that, you also get decent latency at 75µsec for reads and 85µsec for writes, but unfortunately the bandwidth is still limited by the old 3Gbits/s SATA-II Interface here, reaching 270MB/s for reads and 210MB/s for writes. Power consumption, at 2.7 watts in active mode, is very decent though.

It seems a bit odd that Intel didn’t go with the brand new 6Gbits/s SATA3 interface, which its competitors in the SSD market have already actively embraced. On the other hand, Intel might be after something even more attractive in its next line of high-end SSD drives.

CHINESE WIRELESS OUTFIT Huawei is about to launch the world’s first plug in and link data card, the Hilink E353.

Using a number of patented technologies, the fast Hilink E353 automatically connects users to the internet in as little as 15 seconds after the data card is inserted into a USB port.

This means no boring tedious dial-in process, driver installation or manual configuration – and it is up to 75 per cent faster than other products on the market.

Ever the trendsetter, the Hilink E353 is also the first EDGE/GPRS/GSM-compatible product in the Huawei Hilink series that supports HSPA+network with 21Mbits/s downlink.

It will be available in the UK later this year after launching first in Turkey in the third quarter.

Huawei president of mobile broadband, Wu Shimin said, “Leveraging revolutionary 4th generation datacard technology, the HiLink series is poised to change the datacard industry landscape.”

He added, “The HiLink technology is the result of more than one year of dedicated research and development and we believe that it will not only enhance consumers’ user experience, it will also enable operators to reduce backend development and maintenance costs and speed up UI customisation, enhancing the competitiveness of their products.” µ

THE CURRENT reference design single card graphics performance leader is the AMD ATI Radeon HD5970. Basically a combination of two HD5870 1GB GPU blocks slowed down by some 20 per cent to accomodate the heat and power limits of the PCIe card specification, and connected via an on-board PLX PCIe bridge, the HD5970 has led the market for nearly all of the past year. Now, prior to the arrival of the AMD ATI Radeon HD6000 ‘Southern Islands’ GPU line in October, there is a kind of unofficial refresh going on at the high end.

Basically, the key vendors like Asus, Gigabyte, XFX and Sapphire are offering sped-up top end graphics cards that would have otherwise qualified to be called, say, HD5890 and HD5990, but since it’s not a full new product SKU rollout, they are considered the accelerated factory pre-overclocked units. At the very top of the pack is Asus’ Ares.

The card has the same architecture as the normal AMD ATI Radeon HD5970 dual GPU setup, and even the PCB dimensions are about the same. However, the GPUs on board run at the full HD5870 individual speed of 850MHz GPU and 4.8GHz GDDR5 memory, and, on top of that, each GPU has 2GB of RAM for a total of 4GB on the card. Wonderful! But, the changes required a brand new cooling system barely fitting the two slot width and, of course, much more power. Here you have two 8-pin plus one 6-pin graphics power connector on the card. Put two of those cards in a QuadFire parallel GPU setup on a, say, Intel Core i7-980X six core platform, and you’ll exhaust a 1000W PSU.

The card comes in an ultra large carton box, larger than even server mainboard packaging. Inside it is a black suitcase, James Bond style, which when open reveals the card and its accessories.

At the first look, the Asus Ares card is big and beautiful, a statement that fits this monstrous card just perfectly. It is impressive looking and, in a defensive situation, with its combination of weight and sharp edges, it could be a deadly weapon.

It took a bit of extra care to insert the card into our initial test platform, the Asus Rampage III Extreme mainboard using the Intel Core i7-980X six core CPU running at the default 3.33GHz clock. The 6GB of Geil Black Dragon DDR3-1600 RAM and an Intel X25-M 160GB SSD, as well as the Thermaltake 1000W PSU in our trusty Xigmatek Midgard-S chasis, which by now has survived three board swaps without a scratch, rounded out the test bed system configuration. The card was surprisingly silent, even during the benchmark runs at full load.

In this initial test, before we try to overclock the card further and use its Asus Smartdoctor and GamerOSD utilities, I ran the usual Windows 7 64-bit platform with the 3Dmark Vantage DX 10 and Unigine Heaven 2 DX 11 tests, as well as Sandra synthetic GPU performance benchmarks. Here they are:

3Dmark Vantage on Ares:

And on the generic Asus HD5970 on the same system:

Unigine Heaven:

Sandra GPU render:

Sandra GPGPU compute, over 5 TFLOPs single precision and 1.2 TFLOPs double precision floating point on a single card, with plenty of local RAM for the job:

And GPU memory too:

Impressive! This is by far the fastest GPU setup in a single slot I’ve ever seen. I wonder how it’d scale in a quad GPU dual card configuration, but what I can say is that Asus has, with this extra bit of engineering, created a true multi GPU performance monster, without sacrificing single GPU performance or memory capacity.

Note yet another configuration opportunity here. If you’re using the card for GPGPU compute applications, where the extra 2GB of memory per GPU chip helps a lot, you are not bound by the Crossfire limits. In fact, in a mainboard like the EVGA SR2 or the Gigabyte X58A-UD9, you could insert four of these ARES cards, each with its own PCIe X16 link, and have eight GPUs for over 20 TFLOPs single precision and over 4 TFLOPs double precision floating point capability, in a single box. All that, of course, assuming that your compute routines are happy with relying on the AMD Stream or OpenCL programming approaches.

In Short
Asus set another record here with the Ares Limited Edition ATI Radeon HD5970 graphics card, at least until and if it releases the rumoured Mars 2 dual Nvidia GTX480 GPU Limited Edition on a single card.

Maybe Nvidia will be nice enough to provide Asus with those rare, kept aside, full 512-shader bins of the GF100 chip to make a thousand core dual GPU card. That thing would need three 8-pin power plugs, even more than the Ares. Compared to the dual Nvidia GF100 card’s projected 600W power draw, this dual ATI Radeon HD5970 Ares card will look positively power saving.

In the meantime, we’ll look more closely at the Asus Ares card’s graphics performance against other GPUs in more environments, as well as how well it overclocks. Watch this space. µ

The Good
Top performance, reasonably compact design, large memory, limited edition card.

The Bad
Since AMD’s next-generation ‘Southern Islands’ HD6000 line of GPUs is just around the corner, there might have to be an Ares 2 soon.

The Ugly
Nothing.

Bartender’s Score
9/10