Power Consumption - Up to 65W or not?

TDPs and power consumption has been a topic we’ve been revisiting on an (unfortunately) regular basis on almost every product launch. Over the last few generations of product launches in particular, we’ve been attempting to explain the current industry situation in more depth in order to demystify marketed power and thermal envelope figures versus what you can actually expect to encounter in the real products.

Given our limited time in writing up this Tiger Lake-H system, I’ll refer back to our more extensive articles, in particular the in-depth explanation of TDPs and Intel’s new generation product behaviour in our review of the Tiger Lake reference platform last September:

Alongside that piece, we also want to point out more extensive historical talks about TDPs, Turbo and power consumption:

In the context of today’s Tiger Lake-H reference laptop and system, the one thing we must preface the rest of the review is the power settings the laptop came in and the resulting behaviour and thermal characteristics of the Core i9-11980HK SKU we’ll be reviewing today.

Intel’s reference laptop, out of the box as delivered to us by Intel seemingly was set up with no PL1 limit, or at least what we suspect is the maximum cTDP limit of 65W of the i9-11980HK. Generally speaking, this is no surprise as TGL-H is targeting the high-power desktop replacement laptop market which tends to come with capable and extensive thermal dissipation designs.

At first, we started running our tests on the platform in this default reference setting, representing what we had hoped being the best-case scenario for the chip and platform, until we discovered some concerning thermal behaviour when under full load:

Under a Prime95 load in a more prolonged test period of 10+ minutes, when tracking package power consumption as well as CPU temperatures and frequencies, we’re seeing that the TGL-H reference laptop is having great troubles at sustaining this default 65W TDP mode.

During the initial idle period we see the CPU has low power consumption in the 2.2W range with some workload noise in the mix, boosting the CPU frequencies up to 4.9GHz.

The initial load ramp results in peak power consumption of up to 86W, but this is a very transient measurement as power quickly throttles down to 70W and below within seconds. In our readouts it seems that Tau (PL2 turbo period) seems to be set at 5 seconds for this machine.

The worrying behaviour starts happening after around 2 minutes of load: we indeed see the CPU package generally trying to limit itself to around 65W, however it’s not a constant steady state, with very obvious large fluctuations between 65W and 35W.

Looking at the temperature, we’re seeing maximum load figures in excess of 95°C, with some 96°C peaks in our coarse sampled data. What seems to be happening here is that the CPU is thermal tripping between the 65W and 35W states, unable to sustain the 65W state for any amount of prolonged time.

We’ve confirmed that this throttling and power and frequency fluctuations happen on several workloads, and the only conclusion we can come to is that the reference system simply doesn’t have an adequate enough thermal dissipation solution to effectively enable the 65W cTDP mode of the CPU.

While the reference laptop had a bare-bones BIOS, fortunately enough we were able to rely on XTU to change the system’s PL1 settings, and we chose to re-test at 45W given that this is the i9-11980HK’s supposed default TDP setting.

Under this simple change, the thermal, power and frequency response of the system appears to be much more reasonable. We’re still seeing peak power consumption figures of 75-86W which should correspond to the PL2 figures of the chip, but again that’s only for short workloads which fit into the 5 second Tau/Turbo period.

For the remainder of the next 15 minutes, the machine was able to sustain a steady state CPU temperature of around 83°C, and power consumption capped at 45W. Frequencies ended up around 3200MHz all-core for most of the test but had a prolonged 2700MHz period a few minutes in. The 11980HK has an advertised base frequency of 2600MHz, so that seems to be in line with Intel’s specifications.

Unfortunately, we don’t have Intel’s previous generation H-Series processors in house for a direct generational comparison, but the next best thing is the 11980HK’s nearest competitor, AMD’s Ryzen 9 5980HS. This latter chip comes with a 35W TDP which is 10W lower than the new TGL-H SKU we have in house right now, and we see an obvious difference between the chip’s long-term thermals and power, ending up at different levels after some while.

The Ryzen 9 has a prolonged 300s semi-turbo state where it sustains 42W power until thermal saturation of the laptop. During this period, with similar power consumption to the 11980HK and also quite similar thermal results of around 80-83°C, both platforms seem to be quite similar – except for the fact that AMD Zen3 cores able to operate at all-core boost frequencies of around 4GHz, while the Willow Cove cores of the TGL-H system operate at around 3200MHz and below. This is an important metric to note as we dive deeper in other results of our test suite.

In more real-world full load workloads such as Agisoft, we’re seeing the i9-11980HK being able to have more aggressive boost frequencies due to the more dynamic and differentiated nature of the workload. Boost frequencies during the heft of the workload reach up to around 4.5GHz which is what Intel advertises as the nT turbo of the chip, while the rough average sits at around 3.5GHz. Towards the end of the test, we’re seeing lower core count boost frequencies reaching the near 5GHz 1-2T advertised boosts of the cores.

Still, what’s relatively concerning is that temperatures are still quite high even when tested in the 45W PL1 mode, we still see temperatures well in excess of 90°C and peaking at >95°C for transient periods.

(0-0) Peak Power

In terms of peak power comparisons, we see that the chip goes up to quite high transients, and has PL2 configurations of around 85-90W. Due to Tau and the turbo period here being only a mere 5 seconds, it shouldn’t affect thermals too much, and should give the system very good responsiveness, even though it will come at the cost of power and battery life.

Unfortunately, due to the embargo and extremely limited time we’ve had with the system we haven’t yet tested more power scenarios, such as 35W cTDP-down or unplugged battery-only behaviour of the platform. We’ll be following up with updates after today’s initial review.

Tiger Lake-H: 8x Willow Cove up to 65W CPU Tests: Core-to-Core and Cache Latency
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  • Spunjji - Thursday, May 20, 2021 - link

    He measured the power consumption, you pillock. It's right there in the review. Nice work getting your FUD on the front page though, round of applause for gondaft.

    If Tiger Lake H will be better in "the right chassis", Intel really should have thought of that when they supplied this one. As things stand, it's clear that this chassis wasn't causing the CPU to throttle at 45W, so the only way it would perform better is in a chassis that allows for 65W - at which point you'd find AMD's CPUs performing better, too...
    Reply
  • 5j3rul3 - Monday, May 17, 2021 - link

    It's a big step to intel
    M1 and Ryzen 5000 are powerful, Intel need more pros to getting the leading performance
    Reply
  • mode_13h - Monday, May 17, 2021 - link

    This is definitely what Rocket Lake should've been. If they just put this chip in a desktop package, so it could be run with a desktop power budget and cooling, it'd sure be a lot more interesting than it is inside a laptop. Reply
  • Exotica - Monday, May 17, 2021 - link

    Yields may have been the primary concern. Reply
  • mode_13h - Monday, May 17, 2021 - link

    I get why they didn't do it, but it's clear to me this chip really wants to be a desktop CPU. Reply
  • whatthe123 - Monday, May 17, 2021 - link

    it's probably more that they've tweaked their 10nm to hit high boost at the cost of efficiency. I think they increased their gate pitch with "superfin" so you end up with more performance scaling but also more power use. considering how far behind their desktop chips are compared to 7nm chips from AMD they may just be crippling efficiency across the board to get performance parity while their fabs lag behind. they don't seem to have high hopes for 10nm considering their target for market leadership is 2024 with 7nm.

    laptop users generally stick with bursty operations or video games and in both cases raw throughput isn't as much of a concern. average user would probably not notice or even benefit from the high ST burst performance, but anyone planning on using it professionally would probably be better off with cezanne.
    Reply
  • Spunjji - Tuesday, May 18, 2021 - link

    It would certainly be able to stretch its legs better there. It would be interesting to see whether it could handle running those higher boost clocks across more cores with a higher TDP. Guess we'll find out with Alder Lake. Reply
  • Lucky Stripes 99 - Monday, May 17, 2021 - link

    I thought the same. This chip in a mini-STX case with a desktop cooler would make a great portable system. However, if it is having thermal issues with a full-size workstation laptop, it'll likely struggle in the smallest of SFF cases like the NUC. Reply
  • Azix - Monday, May 17, 2021 - link

    the laptop doesn't look that that big. A nuc would have more vertical space for the cooling for example. It would also be easier to throw that heat out. Reply
  • mode_13h - Monday, May 17, 2021 - link

    Uh, the mini-STX NUCs don't really have much space. Everything is packed in pretty tightly. Furthermore, they usually top out at 28 W.

    For Coffee Lake, Intel made a larger system they called a "NUC", but I think they had actual Nvidia graphics cards in them and were bigger than a lot of mini-PCs.
    Reply

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