Based on this, I decided to purchase another 920 from a different retailer in the UK, again purchased as a consumer – so no cherry picked possibilities. This one was an OEM unit, 3835A batch, a little earlier in the production timeline. Onwards to testing using the exact same components as before and much to my surprise, 4GHz + on this particular CPU is not an issue. Further, the VTT required in comparison to the 3838A processor is miniscule.

Take a look at the voltage screenshots below – VTT required for an effective BCLK of 210 Prime95 8 thread stable is a mere 1.20V under full load, Vcore in the region of 1.332V (real) for just shy of 4GHz CPU speed. If I stick the 3838 retail processor into the same board on these settings – it won’t even post, in fact I can barely get it to post at 195BCLK using 1.36VTT, which then proceeds to throw a BSOD as soon as the system is presented with a load – regardless of how much I tinker with voltages.



Bottom line here is that the integrated memory controller in the i7 Core processors is highly variable. We’ve seen results much better than ours in some instances, and we've also heard of users finding it hard to get processors to post much beyond 3.6GHz. Based on our research to date, lot codes 3835, 3836, and 3841have the best opportunity of receiving a processor that will overclock well while offering both excellent VCore and VTT voltage rates. It is still luck of the draw for the most part, but chances are these lot codes will offer improved clocking rates at lower voltages.

This type of variation in the IMC will probably make some of the upcoming CAS 7 rated 6GB 2000MHz DDR3 kits a bit of a minefield for tech support staff. Personally, we’ve not managed to crack 2000MHz unconditionally stable on our 920 processors yet at CAS7 when increasing the BCLK to 200 and running a 2:10 memory ratio. CAS 8 works, yes Gary’s got from a-b in that regard, but CAS 7 seems like it’s a no-no thus far unless you’ve got a really voltage friendly IMC or get stupid with VDimm. It’d be fair to say this is where the higher multiplier processors on the 965XE are a definite advantage.

Having a strong IMC and motherboard combination that can run the 2:12 memory ratio with Bclk at 166 is ideal for 965XE users needing both high core speeds via the CPU multiplier and memory at or above 2000 for benching. For the rest of us, we think running DDR3-1600 at CAS6 with the upcoming kits will offer the best blend of performance, stability, and cost. Just remember, BCLK is nothing but a reference clock on this platform, the only important element to pay attention to is that QPI frequency is derived from this reference clock. When you’re pushing a lower multiplier processor at higher BCLK levels you’re fighting against IMC QPI frequency limits and the ability of the IMC to swing voltage into a capacitive load at CAS 7 with DDR3-2000 speeds; tricky to say the least. This is also one of the reasons why lowering your memory ratios results in either higher processor clocks and/or additional stability at lower timings. It is simply the system reducing load on the IMC and is another reason why getting 12GB stable at DDR3-1600 is so difficult without a decent CPU and top quality motherboard/BIOS combination as one example.

So let’s say you have a really good processor, motherboard, and memory by this point, you're home free right? Sort of, there is one last caveat we found while overclocking that is worthy of mention; the accuracy of reported voltages in comparison to what the processor really receives from the board, especially VTT/Uncore voltage. We’ve noticed a number of our test boards that read BIOS or OS voltage readings close to the output side of the VTT PWM inductors. As VTT is specified to draw high levels of current, readings taken at various points across the power plane board vary, sometimes greatly; especially if the amount of copper used for traces is thin under the CPU socket.

Intel specifies a combined supply for VTTA and VTTD (the analog and digital voltage portions of the IMC) for the Nehalem architecture. Controller level droop is also part of the specification due to power consumption. Most vendors are suitably over engineering the VTT rail on their overclocking boards by using a 2-phase PWM circuit which gives a more than acceptable 0.02V~0.05V droop depending upon load. This is nothing new or evil for those that understand the nature of transient recovery, overshoot and ringback when it comes to high current power supplies.

Because the all important VTTA supply is coupled to VTTD (for various reasons), any voltage droop during power delivery affects the output voltage swing from the IMC transmitter, which is one of the reasons we see exotic controllers being employed on most of the enthusiast level boards to facilitate getting that last few percent of overclocking stability. Low noise, low impedance power is pivotal in getting the best overclocking potential from the IMC.

Although these power delivery precautions are being taken on the controller and decoupling side of things, we’ve noticed that some boards appear to be skimping when it comes to copper content on the under socket VTT power plane. Which does raise a few question marks unto the validity of going to the trouble of using exotic PWM controllers. Trace losses on some boards are in the region of 0.15V from the last VTT decoupling cap to the under socket grid when the CPU is overclocked and under full load (especially the north side of the socket). This may not seem like a big deal at first, but many users have been duped into thinking their processors are not clocking well when setting VTT to recommended values, without realizing that software related voltage reporting is way off the mark compared to the actual voltage the processor is receiving.

Many vendors are now including measuring pads on their boards that can easily be used with a DMM for voltage monitoring – a good thing, providing those pads lead back to an area of the power plane that best represents the voltage that a component actually sees at its rails. We think this is one area of the first generation of boards that needs to be addressed; accurate voltage monitoring and perhaps a little more importance given to ensuring that VTT trace losses are kept to a minimum by using a suitable amount of copper in the VTT power plane.

We modified an X58 board here in the labs with a section of thick 18 gauge wire to see how much of a difference it makes in terms of overclocking when trace losses are reduced. For the most part, the only benefit in doing this turned out to be efficiency due to better power delivery rather than outright overclocking gains. However, our ability to understand the actual VTT voltage being delivered did allow us to compensate for any voltage differences in the BIOS. This ultimately led to higher overclocks as we were able to properly setup the board.

In the end, overclocking success with the Core i7 ultimately is dependent upon the quality of the IMC much more than the motherboard. Certainly more so than we originally believed and of much greater importance than it was during our years with the Core 2 series. We will be back in the near future with additional details on overclocking the i7 series and updated results on each X58 motherboard including actual versus reported voltages.

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  • Rajinder Gill - Friday, January 23, 2009 - link

    Its range of swing we're seeing rather than the fact that- 'we've always known that batches vary'. Previous architectures have always been subject to variance, that's obvious to most. What surprised us with Core i7 thus far is that the level of voltage variance and voltage capability even on air and water cooling is far greater than anything we've seen before. Up to 0.2V applied VTT variance on the CPU's alone under 4GHz speeds is something that many have not taken into account. It's not just the variance in voltage though - it's also the maximum applied VTT the processors will boot at, some throw C1 boot code errors if you feed them too much.
    Again, as with all things pertaining to information, you either already know something or don't. This article is for those that may not have known, based upon some of the letters we get there are plenty of users that did not know hence why we stuck up this piece.
    Also, VTT trace loss - it's not really expected for $300+ overclocking dedicated boards to be skimping on copper to a vital signal power rail really. granted it's phase one and many companies possibly did not realize that the IMC was this power hungry when being pushed, it's worth pointing out so that perhaps we see an improvement in the future.

    Regards
    Raja
  • subflava - Thursday, January 22, 2009 - link

    Yes, overclocking is definately a case by case basis, but in general there are definately trends in batches/steppings/etc. I think the differences in the case of the i7 are worth pointing out because the magnitude of the variability seems to be much greater than with the Athlon/Core2...at least to this point in the early life of the i7.
  • SlyNine - Friday, January 23, 2009 - link

    Got a Core I7 above 4ghz easly, Cannot get this Q6600 above 3.0ghz for the life of me, 3.1 is absolute tops another above crashes on boot.
  • Aberforth - Thursday, January 22, 2009 - link

    The i7, DDR3 are all fictitious architectures designed to stay in the competitive market, there is no significant improvement with these in the real world scenarios, I must say all these multi-cores have very poor thread handling which is never efficient where as power saving is also a big bandwagon people like to jump on, we know Intel’s been doing that power saving stuff for a long time, they are full of it. Anyway...have fun tweaking it.
  • SlyNine - Friday, January 23, 2009 - link

    On a Core I7 @3.5ghz I ripped and transcoded Transformers HD-DVD to a MP4 High Quality file 10Kbps with 5.1 AAC audio, in about 3.5hours.

    Lets see your dual core do that!
  • strikeback03 - Thursday, January 22, 2009 - link

    I'm not really sure what you are trying to say, but if you are looking for low-power stuff I'm sure there will be more articles on nvidia's Ion platform once they get them out the door to review.
  • Exar3342 - Thursday, January 22, 2009 - link

    That is about the most uninformed comment I have read in a long time. Have you not seen the i7 results for 3D rendering and encoding? In addition to these significant improvements, gaming and general performance has also been upped. How is a new i7 CPU at 2.66 at or above in pretty much all benchmarks over a 3.2 C2Q. Go back to your Athlon and stop complaining about things you nothing about...

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