In August, Intel ran one of its rare Architecture Days where the company went into some detail about its upcoming Tiger Lake processor. This included target markets, core counts, graphics counts, a look into some of the new acceleration features, and a promise of a product launch later in the year. That product launch is now here, and Intel is providing Tiger Lake with speeds and feeds, providing detail and expected benchmark performance for Intel’s next generation of notebook-class devices.

What We Already Know

Recapping what we learned at Intel’s Architecture Day 2020, the standard form of Tiger Lake is a quad core processor with an updated graphics architecture built on Intel’s latest manufacturing process.

These new 11th Generation Core processors use four of Intel’s latest cores built with the Willow Cove microarchitecture – a slightly modified version of the Sunny Cove microarchitecture found in Intel’s 10th Generation Ice Lake processors. These new cores offer more performance than before, peaking at 4.8 GHz compared to the 4.0 GHz seen in the previous generation, a 20% improvement. However the underlying clock-for-clock performance improvements are minimal, with Intel instead focusing on that frequency gain.

The reason for the frequency gain comes from the manufacturing process – formerly Intel’s 10++ process, renamed once to 10+ and then again during Architecture Day to its new name: Intel’s 10nm SuperFin technology. The goal with this manufacturing process was two-fold: firstly to increase efficiency and scalability to enable higher frequencies, but also to improve yields. As a result, we will see Intel claiming higher frequencies, that lead to higher performance, at similar power levels to the previous generation. These cores support AVX-512, as well as Intel’s DL-Boost acceleration libraries.

On the graphics side, Tiger Lake uses Intel’s new Xe-LP graphics architecture, which the company also detailed at Architecture Day – we have a separate article explaining the differences. Simply put, Xe-LP increases the raw thread count and compute count per execution unit (EU), as well as the cache hierarchy and some acceleration features. For Ice Lake we saw 64 EUs running at 1100 MHz, whereas for Tiger Lake we will see 96 EUs (+50%) running at 1350 MHz (+22%). Add in some of the other benefits and we should supposedly see a 2x improvement in graphics performance compared to the previous generation on paper. For AI compute, the graphics also supports DP4A instructions for INT8 inference workloads.

The graphics display pipeline has been improved, with support for AV1 decode, as well as display pipes for up to four 4K60 displays or a single 8K60 display. There is a direct display port to memory to improve latency – memory support on Tiger Lake includes LPDDR4X-4267 (up to 32 GB), DDR4-3200 (up to 64 GB), and when available, we will see LPDDR5-5400 devices in 2021. For accelerators, Intel has also boosted its Gaussian Neural Accelerator to version 2.0, to help with offloading simpler AI inference workloads such as noise cancellation.

Other improvements to Tiger Lake include native Thunderbolt 4 support, with the controller embedded into the CPU allowing for up to four TB4 ports per device. Wi-Fi 6 support is also enabled through a CNVi interface. Intel’s power/frequency algorithms are also updated, allowing for separate scaled power and clocks on the CPU, GPU, and memory fabric. Intel stated that it has doubled the internal fabric bandwidth allowing all these parts to communicate with each other with more data.

Today’s Announcements

Speeds, Performance, New Style

The difference between the previous Architecture Day and today’s Tiger Lake launch is that today is more about the end-user performance: the speeds and benchmark numbers that end users are going use to compare it against other products in the market. Not only this, but Intel’s partners are now free to start announcing future Tiger Lake based products.

The details we should start with right away are the processors. Intel has two categories of Tiger Lake parts, ranging from 7 W up to 28 W. Intel this time around is presenting them a little differently. The top 12-25 W processors are technically known as ‘UP3’ processors, or what we used to call the U-series hardware. These processors used to have a nominal TDP of 15 W, but can be pushed up or down in power by laptop companies depending on how they build their systems.

For Tiger Lake, Intel has removed the concept of a 'nominal TDP', instead stating that 'TDP is not useful' for its partners or its customers for this product line. This is something we at AnandTech disagree with - the Thermal Design Point of a processor enables partners, customers, and press to enable design decisions or enable at-a-glance performance metrics. By not providing that nominal TDP, and instead insisting that OEM partners 'can choose from 12W to 28W', purposefully obfuscates the end-user performance away.

To that end, as Intel is not providing a nominal TDP, how it reports the base frequencies has to change. Intel's own specification tables listed very high base frequencies compared to the previous generation, and it was not until much later that we discovered (note, we weren't told) that the base frequencies presented related to the 28 W mode of operation. Thus any comparison to the previous generation using these numbers in that table provided becomes null and void, and it means at AnandTech we have to present our data in a different way - we have to add in another column to complicate things a lot further.

Intel 11th Gen Core Tiger Lake
UP3 Class: 12-28 W
AnandTech Cores L3
MB
Base
MHz
at
12W
Base
MHz
at
28W
1C
MHz
up to
50W
nT
MHz
at
50W
Xe
EUs
Xe
MHz
DDR4 LP4x
i7-1185G7 4C / 8T 12 1200 3000 4800 4300 96 1350 3200 4266
i7-1165G7 4C / 8T 12 1200 2800 4700 4100 96 1300 3200 4266
i5-1135G7 4C / 8T 8 900 2400 4200 3800 80 1300 3200 4266
i3-1125G4 4C / 8T 8 ? 2000 3700 3300 48 1250 3200 3733
i3-1115G4 2C / 4T 6 1700 3000 4100 4100 48 1250 3200 3733

Ultimately, it is the 12 W number that should be most applicable to end users if they want to compare to the previous generation. It is likely that this will be the number we use moving forward when talking about these processors.

At for the processor stack the top end is Intel’s Core i7-1165G7, a quad core processor with hyperthreading and the full 12 MB of L3 cache. It has a base frequency of 1.2 GHz at 12 W, a base frequency of 3.0 GHz at 28 W, a single-core turbo frequency of 4.8 GHz, and an all-core turbo frequency of 4.3 GHz. For graphics, it has the full 96 EUs available, running at the peak 1350 MHz frequency. Memory support is listed as LPDDR4X-4266 and DDR4-3200.

Intel splits its processors by core count, graphics, and frequencies. Anything listed ‘G7’ is meant to signify the highest class of graphics, although it is worth noting that this means 96 EUs for Core i7 parts but only 80 EUs for Core i5 (which also has less L3 cache). Below this is G4 graphics, with only 48 execution units enabled. Only the top Core i7-1165G7 gets the highest graphics frequency, too. The Core i3 processors have a reduction in memory support, and that bottom Core i3-1115G4 only has two cores.

Intel 11th Gen Core Tiger Lake
UP4 Class: 7-15 W
AnandTech Cores L3
MB
Base
MHz*
1C
MHz
nT
MHz
Xe
EUs
Xe
MHz
DDR4 LP4x
i7-1160G7 4C / 8T 12 1200 4400 3600 96 1100 - 4266
i5-1130G7 4C / 8T 8 1100 4000 3400 80 1100 - 4266
i3-1120G4 4C / 8T 8 1100 3500 3000 48 1100 - 4266
i3-1110G4 2C / 4T 6 1800 3900 3900 48 1100 - 4266
*Base Frequency is given at 9W

The 7-15 W processors are the former ‘Y-series’ processors, now known as UP4.

At the top is the Core i7-1160G7, with all four cores enabled with hyperthreading and 12 MB of L3 cache. This processor has a 1.2 GHz base clock, a 4.4 GHz single core turbo, and a 3.6 GHz all-core turbo. The 96 execution units run at 1.1 GHz, and only LPDDR4X memory is supported, up to 4266 MT/s. All processors support four PCIe 4.0 lanes.

There is only a single Core i7 in this rage, with the Core i5 part having fewer EUs and lower frequencies, before the Core i3 parts get split into quad-core and dual core with only 48 EUs a piece.

These processors fit into the UP4 power envelope mostly due to the base frequency being so low, a trait of Intel’s low-power processors over the years.

The goal of these parts is to spread from Fanless designs around 9 W with the UP4, and then up to 28 W perhaps with a discrete GPU at 28 W. As with the previous generation of notebooks on Intel’s 10th Generation, we expect to see some Tiger Lake designs that take the highest performing processors and enable higher power modes, in that 25-28W range. This will enable these products to offer better sustained performance after the turbo period has ended, such as for rendering and video encoding.

Intel’s turbo boost technology has come under a lot of scrutiny of late, primarily for seeing some impressively high power numbers within that turbo period. Intel states that the Turbo mechanisms are there to take advantage of improvements in system design until the system has other factors that take priority, such as thermals and or power. This time around, Intel explains that Tiger Lake has better turbo algorithms, allowing for the system to turbo CPU/GPU/fabric as required within the turbo window. The whole system is a feedback loop which takes in inputs such as the workload, on-system sensors, power limits, and a balancer to find the right frequencies.

So while Intel’s ‘TDP’ value, also known as Power Limit 1, is anywhere from 7 W to 28 W depending on the system it is installed to, the power level when in turbo modes can be a lot higher. We’ve seen this secondary power level, PL2, increase over the years to +4 W over TDP to +20 W over TDP. In the previous generation of Ice Lake, we saw 15 W processors peaking at 44 W in turbo mode. Intel even provides a handy diagram:

What does this mean for Tiger Lake? Based on Intel’s own numbers, peak turbo power is around 50 W, either when plugged in or off the power. Intel is keen to point out that it manages its turbo algorithms to ensure a consistent experience for its customers whether the system has access to wall-power, or is relying on the battery.

Unlike the last generation, where we were able to test Intel’s own mobile development platforms ahead of a launch, we’re unsure exactly what Tiger Lake product will be the first in our labs for testing. It will be interesting to see what we are sent, and how that system performs by comparison.

Over the page, read about Intel's new branding, Intel Evo, Tiger Lake performance, and the future announcements from Intel.

Branding, Intel Evo, Performance, and the Future
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  • Tamz_msc - Wednesday, September 2, 2020 - link

    Renoir also boosts well past 15W.
  • eek2121 - Wednesday, September 2, 2020 - link

    Power consumption != TDP. You seem confused. These chips beat AMD chips that consume far more power in many benchmarks.

    AMD does not compete in this segment. There are zero laptops with AMD chips in them in this weight class with Wifi6, TB4, etc and TGL has better single core and GPU performance than ANY AMD chip. This chip is one of the best chips out there and I say this as an AMD system owner, stock holder, and as a tech enthusiast and engineer.
  • trenzterra - Wednesday, September 2, 2020 - link

    Yep I bought a Renoir laptop recently and now thinking if I should have waited for TGL instead, if anything, for the futureproofing in terms of TB4/USB4 and the huge step up in graphics performance. Perhaps as a consolation I guess the 4750U is still slightly faster in terms of multithreaded performance...
  • silver_eagle - Thursday, September 3, 2020 - link

    Need to wait till the review units appear. AMD always tout about Cinebench, when only <1% of consumer use this. While Intel use Sysmark (closer to real life application), but how close is this to real life usage, we need Anandtech help to validate
  • Spunjji - Friday, September 4, 2020 - link

    Sysmark is not really any "closer to real life" than Cinebench, tbh.
  • vladx - Friday, September 4, 2020 - link

    Much closer than Cinebench, that's for sure.
  • Spunjji - Monday, September 7, 2020 - link

    No, vladx - an artificial benchmark suite composed of cherry-picked *segments* of real-world applications overseen by Intel is not "closer to real-life" than a single benchmark based on unaltered software that a few people actually use.
    https://en.wikipedia.org/wiki/BAPCo_consortium

    If they had convincing real-world numbers then they'd quote the real-world numbers. Evidently they do not, so they've resorted to playing a rigged game.
  • Tams80 - Friday, September 4, 2020 - link

    "It's not a benchmark, we swear!".

    It is a benchmark too.
  • Hifihedgehog - Wednesday, September 2, 2020 - link

    > Power consumption != TDP. You seem confused.

    Sadly, I am not. Of course, power consumption and TDP are totally different. However, do you have bonafide evidence showing the Renoir chips consume far more power in ___ benchmark(s)? You seem to be the confused one here. I have gone through the full press release. I suggest you do likewise. One part of the document that is a dead giveaway is on page 82. Pl1 shows a tremendous performance increase in pushing the PL1 ceiling from 15W to 25W, on the order of 33-40%. That brings me again to my point: they are increasing the default power draw to give the illusion of a huge generational leap. Let's not kid ourselves here. Yes, Intel fixed some problems, but they are still in a world of hurt and are massively behind the competition.
  • eek2121 - Wednesday, September 2, 2020 - link

    Power consumption does not matter. If a CPU spends 2 seconds consuming 50W to complete a task vs. 5 seconds for the same task on another CPU at 25W, which consumed more power?

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