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Friday, 4 February 2011

AMD Launches The Radeon HD 6950 1GB

Good morning everyone.

Today AMD is launching the long-awaited 1GB version of the Radeon HD 6950. For reasons we can't really delve in to, the NDA for the 6950 is expiring here at 4am PDT, however we're not ready to talk about the 6950 1GB quite yet. We'll be back in a few hours with a full explaination, but in the mean time we can say that performance is virtually identical to the 2GB card throughout our test suite at 1920x1200 and 1680x1050. It's only at 2560x1600 and under Eyefinity that we see the 2GB card make a name for itself.

We'll have more in a few hours.

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NVIDIA's GeForce GTX 560 Ti: Upsetting The $250 Market

Late last year we saw GF110, the first of the revised Fermi family. Utilizing a new low-level transistor design intended to minimize transistor leakage, GF110 brought with it GTX 580 and GTX 570, a pair of powerful if expensive video cards that put NVIDIA back where they traditionally lie on the performance/power curve: very high performance with only moderately high power consumption.

Now with 1 GPU’s revisions under their belts, it’s time for NVIDIA to take to tinkering the next GPU:  GF104. Receiving the same transistor reworking as GF100/GF110 in order to allow NVIDIA to enable all of GF104’s functional units, it has become the aptly named GF114. And it is the heart of NVIDIA’s newest video card: the GeForce GTX 560 Ti. Will the GTX 560 Ti follow in the footsteps of its predecessor and shake up the $200 market? Let’s find out.

 

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Thursday, 3 February 2011

Tablet Hands-On Roundup

2011 is the Year of the Tablet. With all due respect to the rabbit, who would have otherwise been assigned to this year, I think the tablet has earned the right of representing 2011. If you followed CES at all this year, you’d know why.

I decided pretty early on that I would make a huge post with all the tablets we looked at instead of posting each one individually, simply because the sheer number of tablets on the show floor meant that I would have taken over AnandTech’s front page with tablet-related posts. It would have been impossible to cover all the new tablets, but I think we managed to get our hands on most of the high profile tablets in addition to some of the more promising new tablets out there.

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This Just In: LG Optimus 2X, Our First Tegra 2 Smartphone

It's been 22 days since we saw the Tegra 2 packing LG Optimus 2X at CES, and just moments ago the device arrived at our doorsteps ready for a thorough reviewing. It's out of the box and charging now, ready to enter our battery life tests, but before that we managed to grab a bunch of photos and a few quick benchmarks. 

Read on for our super brief preview, and stay tuned for the full review.

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The Brazos Review: AMD's E-350 Supplants ION for mini-ITX

AMD has been curiously absent from the value netbook and nettop segments since Atom’s arrival nearly three years ago. These markets are highly profitable only for component vendors, as the OEMs that sell netbooks and nettops must survive on very slim margins in order to hit aggressive price points. It wasn’t too long ago that we were shocked by $699 desktop PCs, but to now be able to get a fully functioning portable PC with display at below $300 is impressive. In order for the profit equation to work out however, you can’t simply scale down a larger chip - you need an architecture targeted specifically at the type of very light workloads you expect to encounter in these segments. Underclocking and undervolting an architecture targeted at high end desktops or servers won’t cut it.

Generally a single microprocessor architecture can cover an order of magnitude of power envelopes. You can take an architecture from 10W - 100W using clock speed, voltage scaling and disabling features (e.g. cutting cache sizes). You can’t efficiently take a 100W architecture and scale it down to 1W. Intel realized this with Atom, and what resulted was a new architecture designed to span the 0.5W - 5W range. Given the constraints of the process (Atom was built at 45nm) and a desire to keep die size down to a minimum (and thus maximize profits), Intel went with a dual-issue in-order architecture reminiscent of the old Pentium - but with a modern twist.

AMD came to the same realization. For it to compete in these value markets, AMD couldn’t rely on its existing Phenom II derived architectures. The Phenom II and its relatives currently span a range of TDPs from 9W to 140W, and at the lower end of that spectrum we’re talking about some very low clock speeds and performance targets. Getting down to 1W was out of the question without a separate design.

What AMD came up with was a core called Bobcat, initially targeted for netbooks, notebooks, nettops and entry level desktops. Architecturally Bobcat is a significant step ahead of Atom: while still dual-issue, it features an out-of-order execution engine making it the Pentium Pro to Atom’s Pentium.

It isn’t just CPU architecture that AMD surpassed Atom with, the first incarnation of Bobcat is an integrated SoC with on-die DirectX 11 GPU. AMD calls this combination a Fusion APU (Accelerated Processing Unit) as it places both a CPU and GPU on a single die. Read on for our full review of AMD's first Fusion part: the E-350.

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Wednesday, 2 February 2011

Intel Discovers Bug in 6-Series Chipset: Our Analysis

In our Sandy Bridge review I pointed out that Intel was unfortunately very conservative in one area of the platform: its chipset. Although the 6-series chipset finally brought native 6Gbps SATA to Intel platforms it failed to fix issues with 23.976 fps video playback. Intel also failed to deliver a chipset that can support SNB's processor graphics as well as overclocking. Today, things just got even more disappointing.

Intel just announced that it has identified a bug in the 6-series chipset, specifically in its SATA controller. Intel states that "In some cases, the Serial-ATA (SATA) ports within the chipsets may degrade over time, potentially impacting the performance or functionality of SATA-linked devices such as hard disk drives and DVD-drives.". I don't know the specifics of the bug yet, but Intel very rarely issues statements like this so it's likely quite serious. 

The fix requires new hardware, which means you will have to exchange your motherboard for a new one. Intel hasn't posted any instructions on how the recall will be handled other than to contact Intel via its support page or contact the manufacturer of your hardware directly. In speaking with motherboard manufacturers it seems they are as surprised by this as I am. 

Intel will begin shipping the fixed version of the chipset in late February.  The recall will reduce Intel's revenue by around $300 million and cost around $700 million to completely repair and replace affected systems.

Read on for more information on the nature of the bug and what it means for current and future SNB owners.

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The Source of Intel's Cougar Point SATA Bug

I just got off the phone with Intel’s Steve Smith (VP and Director of Intel Client PC Operations and Enabling) and got some more detail on this morning’s 6-series chipset/SATA bug.

The Problem

Cougar Point (Intel’s 6-series chipsets: H67/P67) has two sets of SATA ports: four that support 3Gbps operation, and two that support 6Gbps operation. Each set of ports requires its own PLL source.

The problem in the chipset was traced back to a transistor in the 3Gbps PLL clocking tree. The aforementioned transistor has a very thin gate oxide, which allows you to turn it on with a very low voltage. Unfortunately in this case Intel biased the transistor with too high of a voltage, resulting in higher than expected leakage current. Depending on the physical characteristics of the transistor the leakage current here can increase over time which can ultimately result in this failure on the 3Gbps ports. The fact that the 3Gbps and 6Gbps circuits have their own independent clocking trees is what ensures that this problem is limited to only ports 2 - 5 off the controller.

You can coax the problem out earlier by testing the PCH at increased voltage and temperature levels. By increasing one or both of these values you can simulate load over time and that’s how the problem was initially discovered. Intel believes that any current issues users have with SATA performance/compatibility/reliability are likely unrelated to the hardware bug.

One fix for this type of a problem would be to scale down the voltage applied across the problematic transistor. In this case there’s a much simpler option. The source of the problem is actually not even a key part of the 6-series chipset design, it’s remnant of an earlier design that’s no longer needed. In our Sandy Bridge review I pointed out the fair amount of design reuse that was done in creating the 6-series chipset. The solution Intel has devised is to simply remove voltage to the transistor. The chip is functionally no different, but by permanently disabling the transistor the problem will never arise.

To make matters worse, the problem was inserted at the B-stepping of the 6-series chipsets. Earlier steppings (such as what we previewed last summer) didn’t have the problem. Unfortunately for Intel, only B-stepping chipsets shipped to customers. Since the fix involves cutting off voltage to a transistor it will be fixed with a new spin of metal and you’ll get a new associated stepping (presumably C-stepping?).

While Steve wouldn’t go into greater detail he kept mentioning that this bug was completely an oversight. It sounds to me like an engineer did something without thinking and this was the result. This is a bit different from my initial take on the problem. Intel originally characterized the issue as purely statistical, but the source sounds a lot more like a design problem rather than completely random chance.

It’s Notta Recall

Intel has shipped around 8 million 6-series chipsets since the launch at CES. It also committed to setting aside $700 million to deal with the repair and replacement of any affected chipsets. That works out to be $87.50 per chipset if there are 8 million affected chipsets in the market, nearly the cost of an entire motherboard. Now the funds have to cover supplying the new chipset, bringing in the affected motherboard and repairing it or sending out a new one. Intel can eat the cost of the chipset, leaving the $87.50 for shipping, labor and time, as well as any other consideration Intel provides the OEM with (here’s $5, don’t hate us too much). At the end of the day it seems like enough money to handle the problem. However Intel was very careful to point out that this is not a full blown recall. The why is simple.

If you have a desktop system with six SATA ports driven off of P67/H67 chipset, there’s a chance (at least 5%) that during normal use some of the 3Gbps ports will stop working over the course of 3 years. The longer you use the ports, the higher that percentage will be. If you fall into this category, chances are your motherboard manufacturer will set up some sort of an exchange where you get a fixed board. The motherboard manufacturer could simply desolder your 6-series chipset and replace it with a newer stepping if it wanted to be frugal.

If you have a notebook system with only two SATA ports however, the scenario is a little less clear. Notebooks don’t have tons of storage bays and thus they don’t always use all of the ports a chipset offers. If a notebook design only uses ports 0 & 1 off the chipset (the unaffected ports), then the end user would never encounter an issue and the notebook may not even be recalled. In fact, if there are notebook designs currently in the pipeline that only use ports 0 & 1 they may not be delayed by today’s announcement. This is the only source of hope if you’re looking for an unaffected release schedule for your dual-core SNB notebook.

Final Words

Intel maintains that Sandy Bridge CPUs are not affected, and current users are highly unlikely to encounter the issue even under heavy loads. So far Intel has only been able to document the issue after running extended testing at high temperatures (in a thermal chamber) and voltages. My recommendation is to try to only use ports 0 & 1 (the 6Gbps ports) on your 6-series motherboard until you get a replacement in place.

OEMs and motherboard manufacturers are going to be talking to Intel over the next week to figure out the next steps. Intel plans to deliver fixed silicon to its partners at the end of February, however it’ll still take time for the motherboard makers to turn those chips into products. I wouldn’t expect replacements until March at the earliest.

I maintain that the best gesture of goodwill on Intel’s part would be to enable motherboard manufacturers to replace P67/H67 motherboards with Z68 boards for those users who want them.

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Gigabyte Announces 6-series Motherboard Replacement Program

Yesterday Intel announced the largest stop shipment/recall I can remember it ever making (excluding FDIV). The product in question? All 6-series chipsets, a necessary part of any Sandy Bridge (aka 2nd generation Intel Core microprocessor, aka Intel Core i7/i5/i3 2xxx) system. The problem? A transistor with a thin gate oxide being driven by too high of a voltage. The aforementioned transistor is present in the clock tree circuitry of the 3Gbps SATA ports that branch off of all 6-series chipsets. The 6Gbps ports are unaffected. Over a period of 3 years, at least 5% of all these chipsets will have some failure on the 3Gbps SATA ports. The failure could start in the form of errors on the SATA link and ultimately result in an unusable SATA port. No damage to attached hardware should result.

Because of the nature of the problem Intel has set aside $700M to deal with the replacement (ahem, not recall) of up to 8 million impacted 6-series chipsets. After stopping shipments and production of the 6-series chipsets, Intel began talking to its partners about how to proceed yesterday.

The fix for the problematic transistor requires a hardware change. The 6-series chipset design doesn’t have to be redone, but there’s a metal layer change that must be made. The result is a new stepping of the 6-series chipsets. Intel shipped with stepping B2, and the fixed version will carry a B3 stepping.

Just half an hour ago, Gigabyte sent its replacement strategy for all of its own motherboards.

The key messages are as follows:

1) Gigabyte has stopped shipment to and recalled any unsold 6-series B2 motherboards from distributors and dealers.

2) Any Gigabyte 6-series B2 motherboards that have already been sold will be accepted back for replacement with a B3 board, regardless of condition. I asked Gigabyte if this meant that non-working boards could also be returned, Gigabyte said yes - all eligible 6-series models with B2 stepping chipsets will be accepted back.

Elligible Gigabyte 6-series MotherboardsGA-P67A-UD3GA-P67A-UD3PGA-P67A-UD4GA-P67A-UD5GA-P67A-UD7GA-H67MA-D2HGA-H67MA-UD2HGA-H67A-UD3HGA-H67M-D2GA-H67M-UD2H

3) Gigabyte says that it should have 6-series B3 chipsets in April.

4) The replacement program will happen at the dealer/distributor level. You will have to exchange your board at the location you purchased it from.

5) Customers can either exchange their board (you'll have to wait until April for this to happen) or you can get a full refund sooner (immediately?). Gigabyte recommends going the refund route as that gives you more flexibility for what you want to do next.

6) The replacement board you get will be a brand new motherboard based on the B3 chipset. Gigabyte isn’t ready to disclose if there will be any new design features to these boards as well.

7) The cost of the product exchange will be handled by Intel and Gigabyte (presumably Intel is footing the entire bill).

April is two months away, that’s later than the end of February. I’m guessing the first recipients of B3 stepping chipsets will be large OEMs and notebook manufacturers. The component guys will likely come second. Getting replacement motherboards won’t happen on April 1st if that’s when Gigabyte gets chipsets either. This could end up being an April/May thing instead of March/April.

Sending all returns/exchanges through the distributor/retailer channels is an interesting approach. I would rather Gigabyte handle the whole thing (e.g. send us an eligible board, we’ll send you a new one) but I can understand if getting the distributors/retailers to help makes things easier.

The refund option is a nice one, although I'm not sure whether etailers will let you return your CPU as well once it has been used. I suspect that's something you'll have to take up with the vendor itself. If you plan on sticking with a Sandy Bridge system, your best bet is probably to keep using your system as is today and just exchange when the time comes.

I'm glad Gigabyte will be providing brand new motherboards for users who opt to exchange and that Gigabyte is accepting boards regardless of condition. Gigabyte hasn't yet decided what it's going to do with all of the returned boards.

Until April rolls around, the best you can do is use the 6Gbps SATA ports on your Sandy Bridge board. We’ll keep you posted as we get more of these notices from manufacturers.

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