When Intel first announced the shift from the dual-stage ‘Tick-Tock’ methodology that had driven their core CPU design teams for over a decade into the three-way ‘Process, Architecture, Optimization’ paradigm, there were questions as to how much of the final stage, the Optimization, would actually change the way CPUs were presented or offer upgrades in performance. At the time, ‘Kaby Lake’ as the name for Intel’s third crack at their 14nm process was well known, but users wondered if it was just another Devil’s Canyon (better overclocking) or a full on CPU launch. Well the answer is the latter, and the launch is staggered between today and January. Roll on Kaby Lake. Is that Kah-bee Lake, or Kay-bee Lake?

Tick-Tock to Process-Architecture-Optimization (PAO)

Intel’s two year processor cadence of Tick-Tock allowed the company to alternate reducing the lithography node (a tick) with an upgraded microarchitecture (a tock) with modest gains of performance. Each stage of the Tick-Tock would take 12-15 months, with new lithography nodes taking longer and longer to reach maturity. Eventually it has gotten to a point where 14nm took too long to become pervasive in Intel’s product stack. For a manufacturing company and a CPU company, slowly rolling out Broadwell notebook and low power parts and then gutting the mid-range desktop was the result of the troubles of bringing 14nm to the prime time. Now in 2016 we have the launch of full-sized Broadwell-EP server parts running up to 22 cores in a 145W envelope, but the low power parts are a couple of microarchitectures ahead. We have this strange situation of a stretched landscape, partially driven by markets but also for manufacturing.

The move from Intel’s 14nm process to 10nm is a long, slow burn, taking much longer to develop than any process previous. We first saw 14nm in Broadwell mobile CPUs in Q3 of 2014, almost two years ago, and 10nm still isn’t on any public roadmap for early 2017. With the tick-tock strategy, and the launch of Skylake in mid-2015, this would leave Intel without a new CPU launch for almost two years, which is unheard of from Intel. Also, Intel’s partners rely on product cycles to announce and launch new products to generate revenue. To fill the gap, plus with a few other techniques, Intel moved to Process-Architecture-Optimization, or PAO for short.

This means three bites of the cherry for 14nm before we see 10nm in prime time. First it was Broadwell, then Skylake, and today Intel is announcing Kaby Lake. As part of the release, Intel has mentioned that a number of key benefits for Kaby Lake will be based on an optimized 14nm process, called 14PLUS (or 14nm+, 14FF+). This process as a quick summary has a higher fin height and larger pitch, essentially giving a less-dense set of transistors that have more room to breathe. Normally a larger pitch means more voltage required, but this is offset by the fin height and Intel says is good for another few hundred MHz for performance. The less-dense design, in theory, may also help in overclocking, however we will have to wait until January to see those results.

Today’s Announcement

The reveal today covers several aspects of Kaby Lake. First is the actual SKUs that will be launched, which consist of three Kaby Lake-Y parts around 4.5W aimed at high-end tablets and 2-in-1 devices and three Kaby Lake-U parts at 15W for notebooks. Both sets of KBL-Y and KBL-U CPUs will feature in mini-PCs as well, so we expect to see the usual array of Zotac and ECS announcements in due course. We have details on all six CPUs to give you, including the new Core M branding regime for the 4.5W family of parts.

The pre-briefings we have had go into some detail regarding changes in the processor, particularly regarding the new enhanced media blocks inside the GPU to support new encode/decode features. The graphics power, in terms of EUs or the microarchitecture, hasn’t changed but the fixed function hardware has some nice upgrades for an updated version of Gen 9 graphics aimed at the upcoming era of 4K support. Ganesh has gone into detail for us over what that means, especially where power and battery life is concerned for anyone creating/consuming 4K content.

Kaby Lake also has an updated Speed Shift package, to accelerate the work already done with Skylake in boosting the performance of the CPU quicker to save power. Intel call it a refinement in the mechanism of handing frequency control back from the OS to the CPU, however ‘Speed Shift v2’ is an adequate moniker to show the upgraded difference.

Intel hasn’t gone into much detail regarding the new 14nm+ process itself in terms of specifics, but has listed a number of performance gains that come out of the new CPU. The fundamental microarchitecture between Skylake and the new Kaby Lake parts is practically unchanged (DMI 3.0 now allows PCIe 3.0 x4 NVMe drives from the integrated PCH), but the updated fin profile and reduced ‘strain’ by the larger fin pitch is being quoted as giving a 12% performance increase due to process alone, typically through additional frequency for the same power. The main benefits to KBL will be in that frequency due to the 14nm+ process as well as the new media capabilities.

As always, Intel consistently emphasizes the difference between a new notebook/2-in-1 based on a 15W Kaby Lake processor compared to a 5-year old device, such one based on a mobile Sandy Bridge ULV part. Intel continually sees its market revolving around new experiences created by new form factors, and to generate revenue requires people to upgrade and decide how these new experiences can influence an upgrade. Intel expects to have over 100 Kaby Lake system designs in the consumer channel by Q4, including 120+ using Thunderbolt 3, 100+ using Windows Hello (either via a Real Sense camera or a fingerprint sensor), 50+ designs with 4K UHD as a primary feature and 25+ designs with contact enabled pens. Kaby Lake should be pin compatible with Skylake based designs, meaning that for a number of cases we will simply see a drop in, but others will have new design IDs on show.

The New CPUs, Updates to Core M Branding
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  • Meteor2 - Wednesday, August 31, 2016 - link

    Well, Windows on ARM didn't work out (RT), unlike Android on x86, which is good. But maybe with UWP Microsoft will have another go -- they've opened pathways to get legacy software on to UWP, which would enable processing on ARM. Reply
  • tobi1449 - Tuesday, September 6, 2016 - link

    No it doesn't. Full UWP-Apps will run on any platform, but legacy software (i.e. x86 software) that has just been packed as UWP App (so it can be sold via the Windows Store) won't be able to run on anything but x86 platforms. Reply
  • Cliff34 - Tuesday, August 30, 2016 - link

    For me, looking to buy a new laptop end of this year, is hoping that this will drive Skylake laptops prices down further. However given that Kaby Lake is probably releasing to retail Q1 next year, I don't think I will see much in that beyond the savings from the holiday pricing. Reply
  • Alien959 - Wednesday, August 31, 2016 - link

    So basicly this iteration of intel cpus opens a competitive opening for AMD. This is first time in 10 years that intel doesnt have some imrovment in ipc. Will have to wait for the benchmarks and reviews, but this is a chance for AMD. AMD needs and must deliver so we cosumers have some healty competition. Reply
  • Krysto - Wednesday, August 31, 2016 - link

    > There are a couple of reasons for this - the one Intel discussed with us is that it comes down to performance and OEM requests. An i5 in a 4.5W form factor (or as high as 7W in cTDP Up) performs essentially on par with the KBL-U i5 parts, and OEM customers requested that the naming scheme change to reflect that

    What a load of bull. More misleading marketing tricks from Intel once again.

    The thing is Core i5 should've never been in the 4.5W range - when it was it just meant that it was either heavily throttled, or it would overheat.

    So Intel created M5 to say that it's a lower-performance product that matches the 4.5W TDP better.

    But NOW, Intel is renaming m5 to Core i5 to trick people into thinking they get similar performance as they do at higher TDPs. And saying "but Core i5 at 4.5W is the same as m5" - yeah but Core i5 (with a certain level of performance worthy of i5) NEVER WORKED WELL at 4.5W - that's why it needed higher TDP.

    This is the same cr@p Intel pulled when it renamed mobile Atom chips to Celeron and Pentium.
    Reply
  • WPX00 - Wednesday, August 31, 2016 - link

    So the new MacBook Pro won't be here until January? Iris Graphics-equipped models only then? Or do you think Apple will announce a non-Iris equipped variant first this year, then more powerful models next year? Reply
  • SydneyBlue120d - Wednesday, August 31, 2016 - link

    The long road to realtime 4320p60 HEVC Main 4:4:4 12 and HDMI 2.1 :D Reply
  • Tunrip - Wednesday, August 31, 2016 - link

    Page 2, "Working with Intel, they pushed through a new BIOS for the NUC that kept the OPI at PCIe 3.0 x4 speeds"

    I don't understand who "they" is in this context?
    Reply
  • nonoverclock - Thursday, September 1, 2016 - link

    Intel Reply
  • Allan_Hundeboll - Wednesday, August 31, 2016 - link

    All the Intel news fact sheets and no conclusion makes this article look like an Intel advertisement Reply

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