Ever since the launch of the first series of Intel Core 11th Generation Tiger Lake processors aimed at the ‘U-series’ 15 W market, Intel has teased us that there was another design being produced in the wings. While the Tiger Lake-U was built for portability, battery life, and integrated graphics, the Tiger Lake-H series would double the cores, and be the partner for premium mobile gaming as well as on-the-go muscle. Today is the launch of this new platform, and Intel is promoting over 1 million Tiger Lake-H processors shipped to partners and 80 devices coming to market.

A Quick Recap: Intel Mobile Segmentation

For those who are unfamiliar with Intel’s mobile strategy, it falls into several categories, usually designated by the letter. Over time Intel has been moving around within these categories to define different design points for end-user products, but they have by and large stayed the same. As follows:

AnandTech Main
Y-Series - 4-10 W Novel small form factor
Sustained battery life
U-Series 15 W 12-28 W 10-14 inch ultraportable
Usually reliant on integrated graphics.
Some with discrete GPU for portable gaming
H35-Series 35 W - New for Tiger Lake.
Not actually H, just a high-powered U.
H-Series 45 W 35-65+ W 14-17 inch high-performance
More cores, discrete graphics
'portable' high-performance gaming
Workstation/desktop replacements

For the new eight-core Tiger Lake-H processors, Intel highlights three key markets:

  • Essential: Paired with mid-range GPU, 1080p Gaming at 60 FPS, Medium/High Settings
  • Thin Enthusiast: 15+ inch, sub-20 mm, Gaming at 1080p240 or 4K60 at Medium/High
  • Halo Enthusiast: 15+ inch, Gaming at 1080p240 or 4K120 at High/Max Settings

The new H-series processors will also have corresponding vPro versions for commercial deployment, and Intel is saying that out of the 80+ designs currently using the new 11th Gen Core Tiger Lake-H, about 15 of them will be vPro focused.

Tiger Lake-H (TGL-H) Processors on Offer

While users might be accustomed to seeing a wide array of Intel processors each differing by the smallest of margins, today’s launch has only five models for consumers, and another five for commercial systems. At the heart are Intel's latest Willow Cove processor cores, with 1.25 MB of exclusive L2 cache, and up to 3 MB of shared L3 cache per core, along with Intel's latest Xe-LP graphics. These all start at six cores and twelve threads, and offer up to 5.0 GHz single-core turbo for the most expensive models. 

Intel Tiger Lake-H Consumer
AnandTech Cores
i9-11980HK 8C/16T - 2.6 5.0* 4.9 4.5 24 MB 32 1450
i9-11900H 8C/16T 2.1 2.5 4.9* 4.8 4.4 24 MB 32 1450
i7-11800H 8C/16T 1.9 2.3 4.6 4.5 4.2 24 MB 32 1450
i5-11400H 6C/12T 2.2 2.7 4.5 4.3 4.1 12 MB 32 1450
i5-11260H 6C/12T 2.1 2.6 4.4 4.2 4.0 12 MB 32 1400
*Turbo Boost Max 3.0

The most premium model is the Core i9-11980HK, which looks more akin to a desktop processor! Intel has the eight-core part rated at 2.6 GHz for 45 W, but also lists a base frequency of 3.3 GHz for 65 W. What makes this processor special compared to the others is that it can also be overclocked further than 65 W in systems that allow it. Overclocking on laptops is usually a bit hit and miss, but this is actually the first ever overclockable 10nm processor from Intel. That accolade typically goes to the desktop platform, but this is the first time in recent memory I’ve seen Intel launch an overclockable mobile processor first.

The Core i9-11980HK gets the best of Intel’s design here: 4.5 GHz all-core turbo, 4.9 GHz traditional turbo, and 5.0 GHz with Turbo Boost Max 3.0 on up to two favored cores. The integrated graphics is the base Xe-LP architecture with 32 execution units running at 1450 MHz peak. All processors listed have 32 execution units, with a 350 MHz base and variable peak frequencies.

The other processors here follow Intel’s traditional non-overclocked schema, whereby 45 W is the standard rating and 35 W is the power-down option. The Core i9-11900H for example has Turbo Boost Max 3.0 on two cores up to 4.9 GHz, like the other Core i9, and TBM 3.0 is the main difference down to Core i7 which is also eight-core and sixteen thread.

Compared to Intel’s best TGL-U processors, the Core i7-11375H SE (35W) and the Core i7-1185G7 (28W) are quad-core processors but have much better-integrated graphics.

Intel Tiger Lake-H Commercial
AnandTech Cores
W-11955M 8C/16T 2.1 2.6 5.0* 4.9 4.5 24 MB 32 1450
i9-11950H 8C/16T 2.1 2.6 5.0* 4.9 4.5 24 MB 32 1450
i7-11850H 8C/16T 2.1 2.5 4.8 4.8 4.3 24 MB 32 1450
W-11855M 6C/12T 2.6 3.2 4.8* 4.7 4.4 18 MB 32 1450
i5-11500H 6C/12T 2.4 2.9 4.6 4.4 4.2 12 MB 32 1450
*Turbo Boost Max 3.0

On the commercial front, Intel is mixing up the names between Core and new Xeon W-11000M series processors. There is no overclockable processor here, but the specifications are somewhat identical with 45 W as standard and 35 W optional operating modes. These processors differ because they feature Intel’s vPro, a commercial system allowing for company administration control, Intel Hardware Shield, Total Memory Encryption, and a number of other features to assist deployment across the infrastructure of a business-focused environment. These processors also have ECC memory support, and will defend against cryptocoin mining through detection when used with Microsoft Defender Endpoint.

It is worth noting here that the W-11855M is the odd processor out. It has six cores, but comes with Turbo Boost Max 3.0. It also has 18 MB of L3 cache, the full 3 MB per core, whereas the other 6C processors only have 2 MB per core. I suspect that the W branding is often associated with having as much cores and cache as possible, as in previous generations this has usually been the case.

Tiger Lake-H Silicon and Platform

Compared to the previous Tiger Lake-U silicon, we now get a full eight Willow Cove cores on die, up from four, as well as 20 lanes of PCIe 4.0 for discrete graphics and storage. The overall silicon measures in at around 190 square millimeters, uses Intel’s latest Xe-LP graphics and media engines enabling AV1 decode support, and also has built-in Thunderbolt 4 controllers.

All Tiger Lake-H processors will support DDR4-3200, however it is worth noting that these processors do not support LPDDR4. We expect this to be a more holistic choice that these platforms are not battery life focused, and TGL-H customers prefer having DDR4 as it supports double the capacity (as well as usually being user-replaceable, depending on the design).

The 20 lanes of PCIe 4.0 can be split in three different ways:

  • x16 for graphics, x4 for storage
  • x8/x8 for graphics, x4 for storage
  • x8 for graphics, x4/x4/x4 for storage

In the latter configuration, with up to three PCIe 4.0 x4 storage devices, Intel also supports bootable RAID 0. This is somewhat an obscure configuration, however we have seen MSI desktop-replacement systems come with multi-drive RAID 0 in the past.

The chipset for TGL-H is separate to the CPU, and so there will be a number of mobile chipsets on offer, however Intel has updated the most powerful chipset to a DMI x8 link, offering double the bandwidth back from the chipset to the processor. From the chipset there are another 24 PCIe 3.0 lanes as well as MIPI support for Intel’s Image Processing Unit 6.

Thunderbolt 4 is natively supported, although USB4 is not listed. There is USB 3 support, however Intel fails to list if this is USB 3.2 Gen 1 or Gen 2. For networking, systems can either use a discrete Ethernet controller, or use the chipset integrated Killer AX1675 Wi-Fi 6E solution (if the OEM purchases the corresponding Intel CNVi RF interface). For those of you wondering why Intel is pairing with Killer for the networking here, it’s because Intel acquired the company behind Killer, Rivet Networks, last year for an undisclosed sum.  

Intel promotes that TGL-H is ready for Windows Direct Storage, and with appropriate third-party discrete graphics can support the latest 360 Hz 1080p panels or the latest 4K 120 Hz panels. Resizeable BAR is also supported.


As always with these launches, Intel provides first-party benchmark numbers. We’re loathed to mention any of them, simply because we prefer to validate the claims ourselves.

One thing we can already confirm however is the raw processor improvements: as we saw in previous Tiger Lake systems, Intel offers ‘up to 19%’ better performance per clock over the previous generation. In this comparison, Intel is comparing Tiger Lake-H to Comet Lake-H, which is a derivative of Intel’s 6th Generation architecture. Gains in that market are very much an average of 19%.

But it might be worth noting that comparing against Comet Lake-H is not comparing against Intel’s architectures in chronological order. If we compare Tiger Lake to Intel’s previous 10nm product, Ice Lake, the design of the core means that while some benchmarks did improve, others regressed, leading to overall parity in performance compared to Ice Lake. The only reason Intel isn’t comparing against Ice Lake in its product comparisons is because Ice Lake at 15 W against Tiger Lake at 45 W is too big a power disparity, and mainly a frequency differential will drive Tiger Lake higher.

Intel’s benchmarks against AMD are a bit trickier, given it is hard to compare laptop-vs-laptop given that different designs will have different optimization points. However in an iso-comparison with an RTX 3080 (giving AMD the benefit of the doubt on TDP and a bigger chassis for cooling), and with all settings and cooling features and fans set to maximum, Intel is claiming 20% better average gaming performance with a Core i9-11980HK (65W?) against a Ryzen 9 5900HX (45W?), or iso-performance comparing a Core i5-11400H (45 W?) and a Ryzen 9 5900HS (35 W?). There are a lot of question marks there because Intel’s appendix of test setups mentions only ‘maximum performance setting’ for each system, and that in-itself is variable based on the OEM.

The one performance slide that’s good to put up is probably this one, where Intel compares an example 3-year refresh performance improvement for a commercial high-end system. Some of these workloads can leverage the AVX-512 units, the Xe-LP graphics, or other accelerators that Intel now includes in Tiger Lake-H.

Timescale and Availability

Intel’s launch today states that there are 80+ enthusiast designs with Tiger Lake-H, however exactly how many will be available today is an unknown – we suspect that these designs will come out over the rest of the year. Intel also lists 1 million TGL-H processors shipped to its OEM partners by launch. Normally Intel discloses a few key partner designs with us alongside the launch, but this time that did not happen. NVIDIA also has a corresponding launch today for products designed to fit well with these sorts of systems, so perhaps there is some sort of tie-in. The systems are being launched worldwide, but the launch event is officially in China, hence the early morning US announcement today.

We’re expecting to get hold of a couple of Tiger Lake-H systems for testing over the next month or so – a ‘high-end’ example as well as a halo design.

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  • SaturnusDK - Tuesday, May 11, 2021 - link

    But on the important subject of the scheduler. There's no chance that it will ever get a higher than 80% hit ratio outside a controlled test environment. ADL might look good on selected tests but in real world apps, it'll tank... badly.
  • The_Assimilator - Tuesday, May 11, 2021 - link

    And you, having access to ADL test systems, know this for a fact huh?
  • mode_13h - Tuesday, May 11, 2021 - link

    It'll probably have some early issues, but I expect a lot of those will get smoothed out, over time.
  • Kangal - Wednesday, May 12, 2021 - link

    The thing is Android experienced this scheduler problems with ARM's big.LITTLE as early as 2013 and we've had a lot of problems. However, people still didn't expect getting perfect performance from their light, slim, and portable phones. It took until 2016 for most of these issues to get ironed out by both chipset vendors and phone oems. I think it was (finally) Google's involvement in building their own big.LITTLE phone (Pixel) which finally lead to it being a seamless implementation in 2017.

    Now, I don't know if Intel is as innovative as ARM or if they're more incompetent. Maybe they (Wintel) will make the same mistakes. Maybe they'll make more. Maybe less. Or maybe completely new ones. And what about security? Anyways it is A LOT of work, and I wish them the best. HOWEVER! Consumers will NOT be as tolerant with their PCs as they were about their phones when it comes to performance and security. And, a lot of the early big.LITTLE problems were solved by the consumers basically throwing away their old devices and upgrading. That is not an option on PC. People will expect companies to send updates and fix those bugs, which will take resources out of R&D to actually make their second hybrid chipset great.
  • Oxford Guy - Tuesday, May 18, 2021 - link

    Should have been little.BIG then.
  • jeremyshaw - Tuesday, May 11, 2021 - link

    I agree.

    MSFT has had to work with big.LITTLE-eqsue setups since 2012, with the original Surface and it's 2nd gen. Both had Nvidia Tegra 4+1 core SoCs. Different switching method vs big.LITTLE, though not out of the realm different. Later on MSFT would develop the Surface X which uses Qualcomm SoCs with big.LITTLE. Intel has already launched Lakefield, their first big.LITTLE-style SoC.

    MSFT and Intel have both been working on this for years and years. MSFT has rewritten the Windows scheduler before for Intel, for much, much smaller things. MSFT even worked with a much weaker AMD during Bulldozer and during the Ryzen 1000 launch to fix scheduling for those CPUs (or has everyone forgotten about launch-era Ryzen Windows vs Linux scheduler debates?).
  • Spunjji - Thursday, May 13, 2021 - link

    Everything you've said is true, to some extent, and yet when Lakefield launched it didn't work properly and applications have had to be re-written to work across both sets of cores.

    Historically what Windows seems to do is assign a task to *either* a high-performance core *or* a low-performance one - it's not clear that it can move tasks between them, or harness all of the resources for one task.
  • mode_13h - Thursday, May 13, 2021 - link

    > when Lakefield launched it didn't work properly and applications have had to be re-written to work across both sets of cores.

    Really? Got a reference? You're not just talking about the little cores lacking AVX, are you?

    > Historically what Windows seems to do is assign a task to *either* a high-performance core *or* a low-performance one

    Based on what history? Windows hasn't run on more than a handful of Big.LITTLE CPUs, and they were all pretty niche.

    Even if you're right (and I'm questioning more how you know that, than the specific claim) that's all the more reason to expect MS to put some effort into getting it right -- Alder Lake is gonna be mainstream.
  • Spunjji - Friday, May 14, 2021 - link

    "Really? Got a reference?"
    I wish I did - I recall reading this in a review of a Lakefield device in the context of CineBench being rewritten to properly recognise the core layout, but I haven't been able to find it in the brief search I just did.

    It's actually very difficult to find Lakefield reviews in general, barring a few that popped out right around when it first launched - those mention that multi-threaded applications were only running on the small cores, and none seem to have been revisited.

    "Based on what history?"
    Exactly the limited history you refer to - Lakefield and, before it, the Snapdragon 8cx. It's not a lot.

    I also hope MS would be trying to get it right, but then they wanted Snapdragon 8cx devices to take off, yet when Lakefield rolled around the scheduler was still not working well with big.LITTLE style designs.
  • Oxford Guy - Tuesday, May 18, 2021 - link

    ‘MSFT even worked with a much weaker AMD during Bulldozer’

    Too vague to be particularly meaningful. Either Window achieved Linux-quality scheduling efficiency with BD/PD or it didn’t. Which was it?

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