In the myriad of news and early reviews, Intel is today officially launching its 11th Generation Core family of desktop processors, also known as Rocket Lake, built on Intel’s most advanced 14nm process node technology. This new product family will form the basis of Intel’s premium desktop portfolio for most of 2021, if not longer, and features processors with up to eight cores. Highlights include the new microarchitecture, Cypress Cove, and the Xe-LP graphics design, both of which are redesigns of Intel’s 10nm mobile products. These parts also include Intel’s first PCIe 4.0 offering on the desktop, new AVX-512 for desktop, better memory support, support for resizable BAR, new overclocking features, and enhanced multimedia acceleration.

To The Moon With Rocket Lake

With Intel’s desktop processor launches, we typically observe that the new family is all pervasive, enabling products from the top Core i9 or i7 parts, all the way down to the Pentiums and the Celerons. Intel usually achieves this by building one, two, or more different sizes of silicon, often differing in cores and graphics to achieve the right balance of cost, yield, and performance.

For this generation, Intel has decided to only produce one size of silicon, and segment its offering, with the new family only being used for Core i5 and up.

This one-size silicon design features eight of Intel’s new Cypress Cove cores, with HyperThreading, and 32 execution units of ‘Gen 12’ graphics, derived from Intel’s newest Xe-LP graphics designs. Also bundled in that silicon is a DDR4-3200 memory controller, a PCIe 4.0 root complex offering 20 lanes for discrete graphics and storage, a double width DMI x8 link to the chipset, advanced AVX-512 support for Intel’s Deep Learning Boost technologies, updated overclocking, and next-generation media and display acceleration.

In the past, Intel’s Tick-Tock strategy meant that in each product cycle, either the process node would be updated (tick), or the microarchitecture would be updated (tock). The new Rocket Lake processors, with the Cypress Cove core, falls very much under the ‘tock’ nomenclature, however this core isn’t a completely new microarchitecture by the definition of the word ‘new’.

Backporting 10nm to 14nm

In order to enable Cypress Cove, Intel has taken its Sunny Cove core design built on 10nm, and re-architected it for 14nm. The process of doing this is what Intel coined as a ‘backport’. The process of backporting isn’t as easy as putting the core design on a photocopier and making it larger – the effect of the physics of electrons going through wires means that there are some inherent design criticalities in that process which deviate it a little. But on the whole, as our testing has already shown on our retail samples, despite the discussions about power, Intel has managed to keep 14nm Cypress Cove as close to the original 10nm Sunny Cove design as possible.

In a similar mantra, the new Xe-LP ‘Gen12’ graphics on Rocket Lake is also a similar backport. This time Intel has taken the graphics subsystem from its 10nm Tiger Lake notebook processors and crafted it into 14nm. As a notebook processor Tiger Lake focuses a lot on integrated graphics, and as a result has 96 execution units – Rocket Lake by comparison has only 32 units.

Backport vs Co-design

The future of how and when Intel will initiate additional backporting, even given suggested roadmaps, is likely to be in flux based on its ability to produce high single-core frequency desktop processors. Cypress Cove, by most measures, is a reflex response to a widening gap in Intel’s desktop roadmap, and takes a core specifically designed for a different process. Intel is/has/has likely learned a lot from this process, but in the future we can expect specific cores to be co-designed with both process nodes in mind. This is akin to Intel’s new stance on ‘enabling the right product on the right node at the right time’. A co-designed approach, rather than a post-production realisation a backport is required, will mean that future core designs that straddle two process nodes are likely to be more similar and optimized on both processes at the same time.

Rocket Lake: Core i9, Core i7, Core i5

The new Intel 11th Gen Core desktop processor family will start with Core i5, with six cores and twelve threads, through to Core i7 and Core i9, both with eight cores and sixteen threads. All processors will support DDR4-3200 natively, and offer 20 PCIe 4.0 lanes in supported motherboards – these lanes will enable graphics and storage direct from the processor, typically in an x16/x4 or x8/x8/x4 combination.

Both the Core i9 and Core i7 this time around have the same core count - normally the Core i9 would offer an obvious difference, such as more cores, but for this generation the difference is more subtle: Core i9 will offer higher frequencies and thermal velocity boost (TVB).

Intel 11th Gen Core Rocket Lake
Core i9
AnandTech Cores
Threads
Base
Freq
1T
Peak
nT
Turbo
TDP
(W)
IGP
UHD
Price
1ku
i9-11900K 8 / 16 3500 5300 4700 125 750 $539
i9-11900KF 8 / 16 3500 5300 4700 125 - $513
i9-11900 8 / 16 2500 5200 4600 65 750 $439
i9-11900F 8 / 16 2500 5200 4600 65 - $422
i9-11900T 8 / 16 1500 4900 3700 35 750 $439

At the top of the stack is the Core i9-11900K. Intel has set the 1000-unit pricing of the Core i9-11900K at $539. Note that Intel does this 1k unit pricing for OEMs, so the final retail price is often $10-$25 higher. This is well above AMD’s Ryzen 7 5800X at $449 SEP (MSRP), which is also an 8-core processor. Intel is stating that along with better gaming performance, this processor also offers next-generation integrated graphics, support for new AI instructions, and enhanced media support for the price differential.

On specifications, we knew most of the Core i9-11900K from a previous announcement, but today we learn that this processor has a base frequency of 3.5 GHz, alongside a peak turbo of 5.3 GHz in Thermal Velocity Boost mode, 5.2 GHz otherwise on the favored core, or 5.1 GHz on non-favored cores. The all-core frequency is 4.8 GHz in TVB turbo mode, or 4.7 GHz otherwise.

Thermal Velocity Boost is somewhat new to the desktop space, but what it means is that if the processor is under a certain temperature, it will add an additional +100 MHz frequency during turbo. In the case of the desktop processors, this temperature is 70ºC (158F). That being said, motherboard manufacturers are free to ignore this temperature level, and in our experience, almost all consumer/gaming motherboards disable that check and allow for TVB at all temperatures.

The only processor not getting TVB in the Core i9 family is the i9-11900T, which is the 35 W member of the family. This processor has 35 W on the box because its base frequency is 1.5 GHz, although it will turbo up to 4.9 GHz single core and 3.7 GHz all-core. These T processors typically end up in OEM systems and mini-PCs which are more likely to strictly follow Intel’s turbo recommendations.

All Core i9 processors will support DDR4-3200, and the specification is that the K/KF processors enable a 1:1 frequency mode with the memory controller at this speed, whereas the non K/KF run at 2:1 at DDR4-3200, or 1:1 at DDR4-2933 (more on this later).

Intel 11th Gen Core Rocket Lake
Core i7
AnandTech Cores
Threads
Base
Freq
1T
Peak
nT
Turbo
TDP
(W)
IGP
UHD
Price
1ku
i7-11700K 8 / 16 3600 5000 4600 125 750 $399
i7-11700KF 8 / 16 3600 5000 4600 125 - $374
i7-11700 8 / 16 2500 4900 4400 65 750 $323
i7-11700F 8 / 16 2500 4900 4400 65 - $298
i7-11700T 8 / 16 1400 4600 3600 35 750 $323

The Core i7 family includes the Core i7-11700K, which we have already reviewed with our retail sample, and tested on the latest microcode to date. This processor offers eight cores, sixteen threads, with a single core turbo of 5.0 GHz on the favored core, 4.9 GHz otherwise, and 4.6 GHz all-core turbo.

As noted in our review, the 125 W TDP on the box means little, as we saw 215-225 W peak power draw during turbo of AVX2, and 276-292 W peak power draw during AVX-512, and motherboard manufacturers often default to unlimited turbo in any event. Users going after any Core i7 or Core i9 product should look to a good air cooler or liquid cooler to get the best thermal performance here.

On the topic of memory support, the Core i7 family does support DDR4-3200, however Intel’s specifications is that any non-Core i9 processor should run at a 2:1 ratio of DRAM to memory controller by default, rather than 1:1, effectively lowering memory performance. This creates some segmentation between Core i9 and the rest, as for the rest of the processors the specification for DDR4-2933 is 1:1. Despite this technical specification, we can confirm in our testing of our Core i7-11700K that all the motherboards we have used so far actually default to 1:1 at DDR4-3200. It would appear that motherboard manufacturers are confident enough in their memory designs to ignore Intel’s specifications on this.

On pricing, the Intel Core i7-11700K is $399, which is important in two ways.

First, it is $140 cheaper than the Core i9-K, for the sake of only a few hundred MHz. That leaves the Core i9 high and dry on day one. Unless there’s something special in that chip we haven’t been told about that we have to discover come retail day on March 30th, that’s a vast pricing difference.

Second is the comparative AMD processor, the Ryzen 7 5800X, which has 8 cores and has a $449 SEP. If both processors were found at these prices, then the comparison is a good one – the Ryzen 7 5800X in our testing scored +8% in CPU tests and +1% in gaming tests (1080p Max). The Ryzen is very much the more efficient processor, however the Intel has integrated graphics (an argument that disappears with KF at $374). It will be interesting to see what recommendations people come to with that pricing.

Intel 11th Gen Core Rocket Lake
Core i5
AnandTech Cores
Threads
Base
Freq
1T
Peak
nT
Turbo
TDP
(W)
IGP
UHD
Price
1ku
i5-11600K 6 / 12 3900 4900 4600 125 750 $262
i5-11600KF 6 / 12 3900 4900 4600 125 - $237
i5-11600 6 / 12 2800 4800 4300 65 750 $213
i5-11600T 6 / 12 1700 4100 3500 35 750 $213
i5-11500 6 / 12 2700 4600 4200 65 750 $192
i5-11500T 6 / 12 1500 3900 3400 35 750 $192
i5-11400 6 / 12 2600 4400 4200 65 730 $182
i5-11400F 6 / 12 2600 4400 4200 65 - $157
i5-11400T 6 / 12 1300 3700 3300 35 730 $182

Another difference within these parts is that the Core i5-11400 and Core i5-11400T have UHD Graphics 730, not 750, which probably means that these are running 16 EU configurations, rather than 32 EU.The Core i5 spreads out a lot with more offerings, from $157 for the Core i5-11400F, up to $262 for the Core i5-11600K. All these processors have six cores and twelve threads, all have the traditional Intel Turbo 2.0, and all support DDR4-3200 (2:1) or DDR4-2933 (1:1).

Comet Lake Refresh: Core i3, Pentium

Rather than design a smaller piece of silicon on Cypress cove for the quad-core parts and below, Intel has decided to dust off the previous generation design and give it some updated frequencies. This means that none of the Cypress Cove improvements are in these parts, it is simply Skylake refreshed for a sixth iteration.

Everything here is still called 10th Gen, and it moves up +100 MHz or so compared to the regular Comet Lake parts. The refresh models are given the ‘5’ designation on the end.

Intel 10th Gen Core Comet Lake Refresh
Core i3, Pentium
AnandTech Cores
Threads
Base
Freq
1T
Peak
nT
Turbo
L3
MB
TDP
(W)
IGP
UHD
Price
1ku
i3-10325 4 / 8 3900 4700 4500 8 65 630 $154
i3-10305 4 / 8 3800 4500 4300 8 65 630 $143
i3-10305T 4 / 8 3000 4000 3700 8 35 630 $143
i3-10105 4 / 8 3700 4400 4200 6 65 630 $122
i3-10105F 4 / 8 3700 4400 4200 6 65 - $97
i3-10105T 4 / 8 3000 3900 3600 6 35 630 $122
Gold G6605 2 / 4 4300 - - 4 65 630 $86
Gold G6505 2 / 4 4200 - - 4 65 630 $75
Gold G6505T 2 / 4 3600 - - 4 35 630 $75
Gold G6405 2 / 4 4100 - - 4 65 610 $64
Gold G6405T 2 / 4 3500 - - 4 35 610 $64

The key part in this family has always been the Core i3-10105F, offering a quad core processor equivalent to the Core i7-7700K for under $100.

On the next page, we discuss motherboard support, and the new overclocking features.

Motherboards and Overclocking
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  • ZoZo - Wednesday, March 17, 2021 - link

    Is that supposed to invalidate my observation?
  • Bagheera - Wednesday, March 17, 2021 - link

    yes, because Skylake is 2015 and Ice Lake is technically a 2019 part. just because Intel kept making Skylake until 10th gen doesn't automatically make the 19% ipc uplift amazing - keeping on mind what you are comparing against.

    also keeping on mind Zen 3 was 19% ipc from Zen 2, in one generation - and AMD was playing catch-up this whole time. that's more impressive than what Intel's done, quick is slapping a 2019 arch onto an old node and calling it something "new" because it's faster than an arch from 2015. no duh.
  • TheinsanegamerN - Thursday, March 18, 2021 - link

    20% more IPC? Since when? IPC has been stagnant since skylake. And all that IPC does jack shit int hebenchmarks where the rocketlake CPUs occasionally lose to comet lake and consistently lose to zen 3.

    Integrated graphics? Intel fanbois constantly whine about those.

    You can connect a SSD to your CPU direct now. Congrats on getting to where AMD has been for years.
  • abufrejoval - Tuesday, March 16, 2021 - link

    What's almost more interesting than the technology (which seems to have very few really unkowns left), are the supply chain struggles behind the scenes, consumers never really cared about in this CPU domain before.

    Judging by my Tiger Lake i7 NUC and my Ryzen 5800X, both CPU core designs and manufacturing processes seem so very close to each other, few could probably tell a double sized Tiger Lake APU and a Ryzen 5800U apart.

    But it's the foundry capacity constraints of TMSC and the yield issues with Intel's 10nm which are really the decisive factors in this battle with it's long term implications which come simply from market share or the size of the eco-system, not the technology details.

    And this battle is fought on so many distinct fields, even if the manufacturing capacities are largely global (especially with the AMD CCDs). We hear about 10nm big Xeons and notebook SKUs being produced en masse, while today we reminded how Intel would rather resort to backporting a whole design than yield the desktop and we mostly wonder if it's done because the psychological impact of being a loser on the desktop was considered a risk big enough to do this or if Rocket Lake quite simply is commercially viable the way it is.
  • 29a - Tuesday, March 16, 2021 - link

    It would be nice to see what the iGPU is capable of.
  • shabby - Tuesday, March 16, 2021 - link

    It can't mine if that's what you're wondering 😂
  • abufrejoval - Tuesday, March 16, 2021 - link

    Got NUC8 (48EU Iris 655+), NUC10 (24EU HD620) and NUC11 (96EU Xe) and an Iris 550 Plus (48EU) on a Skylake i5 here.

    From the various benchmarks I've run I have good reason to believe that the 32EU Xe will perform very close to the 550 Iris Plus with 48EU, which is certainly better than all HDxxx GPUs since Skylake, but certainly not twice as fast as 48 vs 24 EU would imply (the 550 GT3e with 64MB eDRAM wasn't either).

    That the 96EU on Tiger Lake without eDRAM manages to achieve a significant boost vs even the 655 Iris plus with 128MB eDRAM, is quite remarkable, but in absolute terms still might only satisfy the seriously bored without access to a gaming rig.

    Expect perfectly reasonable 2D and media performance at 2x 4k resolution, good-enough Google-Earth 3D with Chrome and nothing but disappointment in gaming for these desktop SKUs.
  • yeeeeman - Tuesday, March 16, 2021 - link

    It is obvious that this is just a stopgap for intel. A stupid decision that was made a few years back and now..it is too late to be cancelled. I also think that the current situation is favorable because intel has its own fabs and can made as many as the market asks compared to amd which is at the mercy of tsmc. So I think these will actually sell well with the 11700k looking like a good option.
  • Qasar - Tuesday, March 16, 2021 - link

    yea. only if zen 3 is not instock at the time, and the person doesnt want to wait. and the 11700k would still be the bad option.
  • drothgery - Tuesday, March 16, 2021 - link

    Of course it's a stopgap. Pretty much everything Intel's launched on the desktop since Skylake has been a stopgap (though pre-Ryzen 3, they were more than Good Enough stopgaps).

    But that doesn't mean it was a stupid decision (though if Adler Lake desktop parts launch this year and availability is good -- and that may very well happen -- it may have been a wrong one) given the state of Intel 10nm at the time they would have decided to make it, and would have been a better decision if they'd done it sooner.

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