What’s Next for GlobalFoundries?

In lieu of pursuing a 7nm platform, GlobalFoundries will be embarking on a multifaceted strategy for revenue and profitability. This strategy includes scaling out the 14LPP/12LP platform for various applications that are set to emerge in the 5G era, continuing to evolve the FD-SOI platform, spinning off its ASIC development business, further supporting its existing clients with their 14LPP/12LP products, and some other things.

Scaling Out the 14LPP/12LP

Originally designed for mobile SoCs and some other chips in mind, GlobalFoundries' 14LPP manufacturing technology is used to make CPUs and GPUs at GlobalFoundries. Furthermore, the company has designed two variations of this fabrication process. Whereas the base process used up to 13 metal layers and 9T libraries, 14HP was developed specifically for IBM and tailored for performance at the cost of transistor density, using up to 17 metal layers and 12T libraries. Meanwhile, 12LP — aimed at a broad spectrum of applications, including APUs/CPUs, automotive and other — uses 13 layers and 7.5T libraries, giving a 10% additional performance or power improvement as well as a 15% area reduction vs. the 14LPP.

Going forward, GlobalFoundries plans to offer a broader spectrum of technologies based on its 14 nm node. The move is not truly surprising. Samsung Foundry also offers three versions of its 14 nm processes: 14LPP for high-performance SoCs, 14LPC for compact SoCs, and 14LPU for ultra-low-power chips. So far, GlobalFoundries has confirmed three key markets of its future FinFET process technologies: RF, embedded memory, and low-power. In addition, the company plans to offer its 14LPP/12LP platform with enhanced performance and/or higher transistor density (for cost reduction). To do so, the company will be leveraging the knowledge and techniques they developed as part of the 7LP platform. But naturally Gary Patton does not want to disclose the nature of these innovations or any actual performance targets.

If the company succeeds in the integration of RF capabilities into FinFET-based chips, that will be a world’s first. In theory, such chips would have a notable edge over existing RF solutions, which are made using rather rough process technologies. In addition to regular RF capabilities, GlobalFoundries plans to offer features for mmWave radios. Embedded MRAM will also be another important feature of SoCs made using a FinFET fabrication tech as, again, nobody uses such transistors for embedded memory right now.

At the moment, GlobalFoundries is still forming its new development teams, so we do not know exactly how many projects the company will eventually work on. Meanwhile, keep in mind that any project started today will materialize at best in 2020, with actual products going into HVM in 2021. This will be in time for various devices for high-growth markets, but AMD will naturally wind down its 14LPP/12LP orders to GlobalFoundries over the 2019 – 2020 timeframe, reducing the company’s revenue and profits. Note that at present both the RF and embedded memory technologies for FinFET are in a pathfinding stage, so it is very hard to say when exactly GlobalFoundries comes up with appropriate process technologies.

Investing in FD-SOI

In addition to developing specialized versions of its FinFET-based process technologies, GlobalFoundries will continue to invest in its FDX-branded FD SOI-based platforms, such as 22FDX and 12FDX. Gary Patton did not pre-announce any new versions of the company’s FD-SOI fabrication processes, but clearly indicated that the FDX will remain very important for GlobalFoundries, which is not surprising as GF and Samsung Foundry are the only foundries to offer this tech.

Spinning Off ASICs

Designing chips for a new process technology is always a challenge both from engineering and financial points of view, especially for smaller companies. In a bid to help its customers to develop various SoCs, GlobalFoundries established its ASIC Solutions (ASICs) division, which helps the company’s customers in designing chips. Besides usual things like process development kits (PDKs), various design libraries, silicon-proven memory solutions, interfaces, and other necessary things, ASICs offers support from chip design, methodology, test and packaging teams.

Obviously, GlobalFoundries’ customers going forward will benefit from ASICs IP and teams. However, to ensure that the division continues to attract high-volume work, GlobalFoundries will spin it off and enable it to work with process technologies from other contract makers of semiconductors.

The Fate of EUV Tools

One of the questions we asked GlobalFoundries during a briefing concerning its strategic shift was about the fate of two ASML Twinscan NXE machines installed in Fab 8. At this point the company has not made any decisions, but it intends to consult with ASML and find out what would be the best use of these tools. In theory, GlobalFoundries could keep them to speed up prototyping or even production, but since they require a special treatment, keeping them without using them extensively for HVM may not be a good idea.

Some Thoughts

Until today, GlobalFoundries, Samsung Foundry, and TSMC were the only three remaining contract makers of semiconductors to offer leading-edge process technologies for logic. With GF dropping out from the race, Samsung and TSMC will be the only contract foundries remaining. (While Intel technically has foundry operations, they've had minimal impact on the industry).

For GlobalFoundries, the move has pros and cons. On the one hand the lion’s share of semiconductor industry revenue will be earned from chips made using ’12 nm’ and larger nodes even in 2022, according to Gartner’s findings and cited by GlobalFoundries. Evidently, by not competing for the leading edge, GF will reduce its R&D costs and necessity to build ultra-expensive EUV fabs for 2020 and onwards. Moreover, with specialized technologies sometimes tailored for particular clients, the company will better avoid directly competing against Samsung and TSMC in certain cases. Nonetheless, said foundries are going to compete for emerging devices as well, so they are going to design their own specialized fabrication processes (Samsung in particular will need them for itself). Therefore, GlobalFoundries is not exactly jumping into a blue ocean here.

What remains to be seen is how well GlobalFoundries manages to execute on the timely development of multiple new manufacturing processes and land new customers to fill Fab 8. The company will keep working with AMD for many years to come in fabbing current-generation CPUs and GPUs, and then switching exclusively to wafers with embedded APUs/GPUs as well as with first-gen EPYC dies, as these products have very long lifecycles. However, the number of wafers GlobalFoundries processes for AMD will be dropping rapidly starting from 2019. Whether GF will be able to substitute AMD’s orders with orders from enough smaller players to Fab 8 full utilized is something only time will tell.

While it is sad to see GlobalFoundries leaving the ‘bleeding edge’ field, it is evident that the company’s odds against Samsung and TSMC were not high enough for the owner and the management to take the risks. Therefore, it looks like ‘scaling out’ by offering a set of specialized (and maybe even unique) process technologies instead of ‘scaling up’ and offer another ‘bleeding edge’ node might just be a better bet for GlobalFoundries.

Related Reading:

7LP Canned Due to Strategy Shift GlobalFoundries Press Release
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  • Alexvrb - Tuesday, August 28, 2018 - link

    LOL let's bring Fujitsu into an argument as a good example of how to win... LMAO. How's Fujitsu doing in the fab biz, again?
  • NuclearArmament - Tuesday, August 28, 2018 - link

    More companies would do better by having their own fabs, not less. Being vertically integrated via either merger, acquisition, or organic means is a much better way to remain competitive than solely remaining fabless and outsourcing. Intel is only as large as they are in the semiconductor world because they did not so foolishly sell off all their fabrication facilities like AMD did.
  • FunBunny2 - Tuesday, August 28, 2018 - link

    "More companies would do better by having their own fabs, not less. "

    I've always been puzzled about how much scale there really is. ASML (and who else?) supply the fundamental equipment that all fabs use. did ASMl/whoever figure out, say EUV, and supply all the fabs; or did Samsung, say, figure it out and ASML/whoever built the machines to Samsung/whoever's spec?? from the picture of fabs I've seen, it looks very much like some number of sequential, discrete work-stations, repeated X times. it's not like a car assembly line, where one line makes all the cars.
  • mikato - Tuesday, August 28, 2018 - link

    Yeah I noticed that too. The first photo makes it look like there are a bunch of semi-mobile machines arranged in groups forming the stations. Then the next photo might be more of an assembly line - at least it has a bunch of overhead tracks for things to move along, not sure what, maybe transporting items around.
  • RSAUser - Tuesday, August 28, 2018 - link

    It wasn't foolish for AMD to sell, TSMC is a lot cheaper for them than global while being on a better node ans AMD not having the money to invest in smaller nodes.

    Going TSMC they are at least mostly competitive in the node portion of the cards.
  • Spunjji - Tuesday, August 28, 2018 - link

    You're either trolling or a fool to suggest that selling the fabs was a bad idea for AMD. For a company of that size they're nothing but a millstone. They limited their output capacity when AMD actually had good processors to sell, and then cost them billions when they didn't have a competitive product.

    The stupid bit was the agreement to produce a minimum number of wafer stars with GF after they sold the fabs. That bit them hard in the financials.
  • FullmetalTitan - Thursday, August 30, 2018 - link

    Smart guy over here figured out the secret to business success in semiconductors if you ignore...
    *checks notes*
    ...the need for decades of R&D and many 10s of billions of dollars to acquire companies to supply goods, design products, and leverage talent.
  • gglaw - Sunday, December 16, 2018 - link

    LOLOL. Yea AMD is doing horrible since they sold off their outdated fabs and are paying less for superior nodes now. Their stocks have just plummeted in the last few years. The investors are super pissed that their $3 stocks have gone up to $20 since they don't run their own fabs (which btw is on their own way down the drain after sinking billions into 7nm R&D and scrapping it to focus on old nodes). Look at AMD's balance sheets, then look at TSMC or Samsung. It's 1B vs FIVE HUNDRED BILLION cash on hand. AMD is a tiny designer of fancy chips compared to massive semi-conductor firms that produce chips for the whole world. Even Intel is a speck compared to these companies and more than a few analysts feel Intel's best future move is also letting TSMC use their much deeper pockets to compete in bleeding edge node wars. (If you haven't noticed, Intel is getting the shit kicked out of them in node advancement.)
  • gglaw - Sunday, December 16, 2018 - link

    The savings from vertical integration is absolutely nothing compared to the R&D costs and ramping up manufacturing facilities for each new node. Even if the vertical integration made the wafers literally free, it would forever run AMD in the red trying to pay for the R&D and new facilities for a tiny fraction of the chips sold required to justify the cost of each node advancement. AMD would have to sell over 100X the amount of chips they did in 2018 to maintain a fab that could keep up with TSMC and Samsung. TSMC can do it since they sell a staggering amount of chips compared to either AMD or Intel. AMD accounts for under 1% of TSMC's contracted chips produced. In the tech enthusiast world, AMD is very exciting since they play such a large roll in gaming hardware design but in the business world, they're a little ant.
  • transistortechnologist - Tuesday, August 28, 2018 - link

    It turns out that at very small dimensions compound semiconductors such indium gallium arsenide do not offer any benefits over silicon. It's fundamental, in the physics, quite apart from any economic considerations.

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