AMD's Radeon HD 5870: Bringing About the Next Generation Of GPUs
by Ryan Smith on September 23, 2009 9:00 AM EST- Posted in
- GPUs
Lower Idle Power & Better Overcurrent Protection
One aspect AMD was specifically looking to improve in Cypress over RV770 was idle power usage. The load power usage for RV770 was fine at 160W for the HD4870, but that power usage wasn’t dropping by a great deal when idle – it fell by less than half to 90W. Later BIOS revisions managed to knock a few more watts off of this, but it wasn’t a significant change, and even later designs like RV790 still had limits to their idling abilities by only being able to go down to 60W at idle.
As a consequence, AMD went about designing the Cypress with a much, much lower target in mind. Their goal was to get idle power down to 30W, 1/3rd that of RV770. What they got was even better: they came in past that target by 10%, hitting a final idle power of 27W. As a result the Cypress can idle at 30% of the power as RV770, or as compared to Cypress’s load power of 188W, some 14% of its load power.
Accomplishing this kind of dramatic reduction in idle power usage required several changes. Key among them has been the installation of additional power regulating circuitry on the board, and additional die space on Cypress assigned to power regulation. Notably, all of these changes were accomplished without the use of power-gating to shut down unused portions of the chip, something that’s common on CPUs. Instead all of these changes have been achieved through more exhaustive clock-gating (that is, reducing power consumption by reducing clock speeds), something GPUs have been doing for some time now.
The use of clock-gating is quickly evident when we discuss the idle/2D clock speeds of the 5870, which is 150mhz for the core, and 300mhz for the memory . The idle clock speeds here are significantly lower than the 4870 (550/900), which in the case of the core is the source of its power savings as compared to the 4870. As tweakers who have attempted to manually reduce the idle clocks on RV770 based cards for further power savings have noticed, RV770 actually loses stability in most situations if its core clock drops too low. With the Cypress this has been rectified, enabling it to hit these lower core speeds.
Even bigger however are the enhancements to Cypress’s memory controller, which allow it to utilize a number of power-saving tricks with GDDR5 RAM, along with other features that we’ll get to in a bit. With RV770’s memory controller, it was not capable of taking advantage of very many of GDDR5’s advanced features besides the higher bandwidth abilities. Lacking this full bag of tricks, RV770 and its derivatives were unable to reduce the memory clock speed, which is why the 4870 and other products had such high memory clock speeds even at idle. In turn this limited the reduction in power consumption attained by idling GDDR5 modules.
With Cypress AMD has implemented nearly the entire suite of GDDR5’s power saving features, allowing them to reduce the power usage of the memory controller and the GDDR5 modules themselves. As with the improvements to the core clock, key among the improvement in memory power usage is the ability to go to much lower memory clock speeds, using fast GDDR5 link re-training to quickly switch the memory clock speed and voltage without inducing glitches. AMD is also now using GDDR5’s low power strobe mode, which in turn allows the memory controller to save power by turning off the clock data recovery mechanism. When discussing the matter with AMD, they compared these changes to putting the memory modules and memory controller into a GDDR3-like mode, which is a fair description of how GDDR5 behaves when its high-speed features are not enabled.
Finally, AMD was able to find yet more power savings for Crossfire configurations, and as a result the slave card(s) in a Crossfire configuration can use even less power. The value given to us for an idling slave card is 20W, which is a product of the fact that the slave cards go completely unused when the system is idling. In this state slave cards are still capable of instantaneously ramping up for full-load use, although conceivably AMD could go even lower still by powering down the slave cards entirely at a cost of this ability.
On the opposite side of the ability to achieve such low idle power usage is the need to manage load power usage, which was also overhauled for the Cypress. As a reminder, TDP is not an absolute maximum, rather it’s a maximum based on what’s believed to be the highest reasonable load the card will ever experience. As a result it’s possible in extreme circumstances for the card to need power beyond what its TDP is rated for, which is a problem.
That problem reared its head a lot for the RV770 in particular, with the rise in popularity of stress testing programs like FurMark and OCCT. Although stress testers on the CPU side are nothing new, FurMark and OCCT heralded a new generation of GPU stress testers that were extremely effective in generating a maximum load. Unfortunately for RV770, the maximum possible load and the TDP are pretty far apart, which becomes a problem since the VRMs used in a card only need to be spec’d to meet the TDP of a card plus some safety room. They don’t need to be able to meet whatever the true maximum load of a card can be, as it should never happen.
Why is this? AMD believes that the instruction streams generated by OCCT and FurMark are entirely unrealistic. They try to hit everything at once, and this is something that they don’t believe a game or even a GPGPU application would ever do. For this reason these programs are held in low regard by AMD, and in our discussions with them they referred to them as “power viruses”, a term that’s normally associated with malware. We don’t agree with the terminology, but in our testing we can’t disagree with AMD about the realism of their load – we can’t find anything that generates the same kind of loads as OCCT and FurMark.
Regardless of what AMD wants to call these stress testers, there was a real problem when they were run on RV770. The overcurrent situation they created was too much for the VRMs on many cards, and as a failsafe these cards would shut down to protect the VRMs. At a user level shutting down like this isn’t a very helpful failsafe mode. At a hardware level shutting down like this isn’t enough to protect the VRMs in all situations. Ultimately these programs were capable of permanently damaging RV770 cards, and AMD needed to do something about it. For RV770 they could use the drivers to throttle these programs; until Catalyst 9.8 they detected the program by name, and since 9.8 they detect the ratio of texture to ALU instructions (Ed: We’re told NVIDIA throttles similarly, but we don’t have a good control for testing this statement). This keeps RV770 safe, but it wasn’t good enough. It’s a hardware problem, the solution needs to be in hardware, particularly if anyone really did write a power virus in the future that the drivers couldn’t stop, in an attempt to break cards on a wide scale.
This brings us to Cypress. For Cypress, AMD has implemented a hardware solution to the VRM problem, by dedicating a very small portion of Cypress’s die to a monitoring chip. In this case the job of the monitor is to continually monitor the VRMs for dangerous conditions. Should the VRMs end up in a critical state, the monitor will immediately throttle back the card by one PowerPlay level. The card will continue operating at this level until the VRMs are back to safe levels, at which point the monitor will allow the card to go back to the requested performance level. In the case of a stressful program, this can continue to go back and forth as the VRMs permit.
By implementing this at the hardware level, Cypress cards are fully protected against all possible overcurrent situations, so that it’s not possible for any program (OCCT, FurMark, or otherwise) to damage the hardware by generating too high of a load. This also means that the protections at the driver level are not needed, and we’ve confirmed with AMD that the 5870 is allowed to run to the point where it maxes out or where overcurrent protection kicks in.
On that note, because card manufacturers can use different VRMs, it’s very likely that we’re going to see some separation in performance on FurMark and OCCT based on the quality of the VRMs. The cheapest cards with the cheapest VRMs will need to throttle the most, while luxury cards with better VRMs would need to throttle little, if at all. This should make little difference in stock performance on real games and applications (since as we covered earlier, we can’t find anything that pushes a card to excess) but it will likely make itself apparent in overclocking. Overclocked cards - particularly those with voltage modifications – may hit throttle situations in normal applications, which means the VRMs will make a difference here. It also means that overclockers need to keep an eye on clock speeds, as the card shutting down is no longer a tell-tale sign that you’re pushing it too hard.
Finally, while we’re discussing the monitoring chip, we may as well talk about the rest of its features. Along with monitoring the GPU, it also is a PWM controller. This means that the PWM controller is no longer a separate part that card builders add themselves, and as such we won’t be seeing any cards using a 2pin fixed speed fan to save money on the PWM controller. All Cypress cards (and presumably, all derivatives) will have the ability to use a 4pin fan built-in.
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Agentbolt - Wednesday, September 23, 2009 - link
Informative and well-written. My main question was "how future-proof is it?" I got the Radeon 9700 for DirectX9, the 8800GTS for DirectX10, and it looks like I may very well be picking this up for DirectX11. It's nice there's usually one card you can pick up early that'll run games for years to come at acceptable levels.kumquatsrus - Wednesday, September 23, 2009 - link
great article and great card btw. just wanted to point out that the gtx 285 also had 2x6 pins only required, i believe.Ryan Smith - Wednesday, September 23, 2009 - link
That's correct. I'm not sure how "275" ended up in there.SiliconDoc - Wednesday, September 23, 2009 - link
One wonders how the 8800GT ended up on the Temp/Heat comparison, until you READ the text, and it claims heat is "all over the place", then the very next line is "ALL the Ati's are up @~around 90C" .Yes, so temp is NOT alkl over the place, it's only VERY HIGH for ALL the ATI cards... and NVIDIA cards are not all very high...
-so it becomes CLEAR the 8800GT was included ONLY so the article could whine it was at 92C, since the 275 is @ 75C and the 260 is low the 285 is low, etc., NVidia WINS HANDS DOWN the temperature game...... buit the article just couldn't bring itself to be HONEST about that.
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What a shame. Deception, the name of the game.
Ryan Smith - Wednesday, September 23, 2009 - link
The 8800GT, as was the 3870, was included to offer a snapshot of an older value product in our comparisons. The 8800GT in particular was a very popular card, and there are still a lot of people out there using them. Including such cards provides a frame of reference for performance for people using such cards.SiliconDoc - Wednesday, September 23, 2009 - link
Gee I cannot imagine load temps for the 4980 and 4870x2 exist anywhere else on this site along with the 260,275, and 285... can you ?Oh, how about I look...
Finally - Wednesday, September 23, 2009 - link
Nvidida-Trolls tend to turn green when feeling inferior.SiliconDoc - Wednesday, September 23, 2009 - link
Turning green was something the 40nm 5870 was supposed to do wasn't it ?Instead it turned into another 3D HEAT MONSTER, like all the ati cards.
Take a look at the power charts, then look at that "wonderful tiny ATI die size that makes em so much money!" (as they lose a billion plus a year), and then calculate that power into that tiny core, NOT minusing failure for framerates hence "less data", since of course ati cards are "faster" right ?
So you've got more power in a smaller footprint core...
HENCE THE 90 DEGREE CELCIUS RUNNING RATES, AND BEYOND.
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Yeah, so sorry that it's easier for you to call names than think.
RubberJohnny - Wednesday, September 23, 2009 - link
LOL...replying to your own post 3 times...gettin all worked up about temps...PUTTIN STUFF IN CAPS...Looks like this fan boy just can't accept that the 5890 is a great card. Not surprising really, these reviews always seem to bring the fanboys/trolls/whackos out of the woodwork.
Once again, good job AT!!!
JarredWalton - Thursday, September 24, 2009 - link
SiliconDoc, you should try thinking instead of trolling. Why would the maximum be around 90C? Because that's what the cards are designed to target under load. If they get hotter, the fan speeds would ramp up a bit more. There's no need to run fans at high rates to cool down hardware if the hardware functions properly.Reviewing based on max temperatures is a stupid idea when other factors come into play, which is why one page has power draws, temperatures, and noise levels. The GTX 295 has the same temperature not because it's "as hot" but because the fan kicked up to a faster speed to keep that level of heat.
The only thing you can really conclude is that slower GPUs generate less heat and thus don't need to increase fan speeds. The 275 gets hotter than the 285 as well by 10C, but since the 285 is 11.3 dB louder I wouldn't call it better by any stretch. It's just "different".