SAN FRANCISCO – Intel provided the first look at the system-on-chip variant of its 22-nm process technology in a talk at the Intel Developer Forum here Thursday (Sept. 13). However, it declined to provide details on the Atom-based SoCs for tablets and smartphones that will be made in that process.
“It’s fair to say Intel didn’t have much of a focus four or five years ago on SoCs, but that’s changed,” said Mark Bohr, director of Intel’s technology and manufacturing group in a process technology talk. “The success of Medfield [Intel’s 32-nm smartphone platform] shows we are learning to do it right, and I think we will have a technology advantage at 22 nm,” he said.
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Intel showed at IDF six smartphones and four Windows 8 tablets using the Medfield SoC, made in an SoC variant of its 32-nm process. “There’s a lot more in the pipeline,” said Ticky Thakkar, a lead Atom designer in a separate talk on the mobile chips.
The company is already shipping to OEMs a 2-GHz version of Clover Trail, a follow on 32nm dual-core processor with boosted graphics. A 1.8-GHz version for tablets is also in the works.
Next up is Bay Trail, Intel’s first 22-nm SoC for tablets and smartphones, expected to debut at IDF Beijing. “You’ll have to wait until next year to hear about it,” said Thakkar.
In a separate talk, Bohr described P1271, the 22-nm SoC process to be used for Bay Trail. It differs from the 22-nm CPU process now used for Intel’s Ivy Bridge processors by offering lower leakage logic transistors, higher voltage I/O transistors, denser upper layer interconnects and a set of precision resistors, capacitors and inductors.
Click on image to enlarge.
Intel showed it 22-nm SoC process menu.
“It’s not one set of features, but a menu of feature options—transistors, I/O, interconnects, passive elements and embedded memory,” Bohr said. “The [SoC] transistors go down to much lower leakage levels, but give up some performance,” he said.
The process has significantly better analog characteristics than Intel’s current 32-nm planar process. Designs make heavy use of 80-nm pitch features in lower metal layers, because they are the smallest features Intel can make at 22 nm without needing double patterning, he added.
Intel is running the process at three fabs, two in the U.S. and one in Israel. It will ramp soon in two other fabs.
Click on image to enlarge.
Intel showed performance and power characteristics of its 22-nm SOC transistors.
I can't think of any way that Intel's 22nm process integration is cost competitive against the foundry cost. Unless the finFET yields at the foundries are really bad ( a possibility since it would be their first generation)
Means if foundry product requires a full range of transistors (low leakage,RF, quality analog etc.) for a mobile 22nm SOC, that is not offered even for internal intel product until end of 2013. Mobile SOC intel foundry customers thus at a disadvantage compared to tsmc and other foundry.
Finally, Intel's Mr. Silicon admits Intel does not lead in silicon technology for SOC
"It’s fair to say Intel didn’t have much of a focus four or five years ago on SoCs, but that’s changed,” said Mark Bohr",
plus more at
Intel's mobile/Atom 22nm SOC in market in late 2013 is 2 years behind Foundry/ARM 28 nm shipping now (foundry 28nm and Intel's SOC 22nm has about same transistor density making it a reasonable point of comparison).
Intel's silicon group has been the biggest hindrance to getting into mobile market.
Intel's move to finFET has also been a major setback to getting into mobile market. Intel finFET SOC have been talked about for 2 years but are still another 1.5 years away from chips on market. Intel's finFET SOC is late since large delay in moving all the design IP due to issues with transistor matching, analog, RF , and I/O are all not attractive on a bulk finFET SOC vs since at total chip system level intel's 22nm finFET has negligible advantage over foundry 28nm planar transistor.