Posted by Adele Hars, Editor-in-Chief, Advanced Substrate News

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Hearing the news that GlobalFoundries would be offering two flavors of FD-SOI, ASN asked the company to explain the strategy further. Here are the responses provided by Subi Kengeri, Vice President of Advanced Technology Architecture.

Subi Kengeri, VP Advanced Technology Architecture, GlobalFoundries

What do you see as the FD-SOI benefits for chip designers?

• Lower SRAM Vmin for retention and lower operating Vmin for Logic
• Wider range of Voltage operation for performance/power trade-off
• Total dielectric isolation equates to lower capacitances, lower leakage, and latch-up immunity
• Ultra-thin silicon film provides excellent electrostatic control and optimum transistor performance
• Back-bias control gives an additional speed boost
• Simple planar process using same front end and back end as our 28SLP process, which means fewer process steps and fewer masks, helping to absorb the additional substrate cost

What are your plans for making FD-SOI available to your customers?

We are the manufacturing partner for ST’s FD-SOI technology. We also are planning to offer the technology to other customers who may be interested, but we have not announced details yet. We are the only pure-play foundry with deep experience in both bulk and SOI technologies, which allows us to offer a broader range of technologies at advanced nodes.

GlobalFoundries’ Fab 8 in upstate NY

Can you elaborate on the “maximum” version of FD-SOI — tuned for specific applications — what sorts of things would those be?

Examples of features in the Maximum version of FD-SOI:
a. Back-bias capability on logic for higher performance
b. Denser SRAM by taking advantage of lesser variability of Fully depleted device
c. Base Vts tuned for specific applications (performance vs power trade-off)

And the “minimum” version — a simple and “out of the box” FD-SOI technology — who/what is this for?

a. No Back-bias supported
b. All SRAMs are foot-print compatible to 28SLP
c. Fully depleted device offers better Vmin and power advantages: Optimized for Mobile Applications

Are there any special logistics in terms of the PDK, IP, etc?

a. PDKs are similar to bulk CMOS, except the models will support a 4-terminal device for Back-bias
b. In the base version (termed as minimum version above), IP’s Physicals are fully compatible with bulk CMOS, but would require electrical re-characterization to take advantage of improved FD-SOI device characteristics
c. In the extended version (termed maximum version above), IPs will be designed to take advantage of Back-bias for better performance/power trade-offs in specific applications

What is the next node, and when will that roll out?

See slide 8 of [this] presentation:

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Posted by Adele Hars, Editor-in-Chief, Advanced Substrate News

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What a great start to 2013: at CES in Las Vegas, ST-Ericsson announced the NovaThor™ L8580 ModAp, “the world’s fastest and lowest-power integrated LTE smartphone platform.” This is the one that’s on STMicroelectronics’ 28nm FD-SOI, with sampling set for Q1 2013.

And it’s a game changer – for users, for designers, for foundries, and for bean counters.  Here’s why.

The NovaThor L8580 integrates an eQuad 2.5GHz processor based on the ARM Cortex-A9, an Imagination PowerVR™ SGX544 GPU running at 600Mhz and an advanced multimode LTE modem on a single 28nm FD-SOI die.

ST-Ericsson’s NovaThor(TM) L8580 on ST’s 28nm FD-SOI features a 2.5Ghz eQuad(TM) app processor with ultra-low power consumption. (Courtesy: ST-Ericsson)

In the eQuad CPU architecture, each processor core can operate as a high-performance core or a very-low-power core, depending on what’s needed at the moment. Since all the eQuad cores can adapt to the needs of the user at any given time, there’s no need for the dedicated low-power cores found in other multi-core CPU architectures. Remember, the 2.5GHz cores in the L8580 are the mobile industry’s fastest, or conversely, at 0.6V in low-power mode, the industry’s most battery-friendly. With all 2.5GHz cores working together, expect blazing high-performance when you’re doing something like browsing the web. But when phone’s your pocket, those cores will take barely a sip of power.

The NovaThor L8580 is essentially a straight port from 28nm bulk to 28nm FD-SOI of the (very successful) NovaThor L8540, with just a bit of tweaking to fully leverage cool things you can do with FD-SOI, like biasing to increase performance and conserve power.

For the folks designing smartphones and tablets (and ultimately for the end-user), that port to FD-SOI gets the NovaThor L8580:

• CPUs running 35% faster and GPU and multimedia accelerators running 20% faster. In terms of multimedia performance, they’re supporting 1080p video encoding and playback at up to 60 frames per second, 1080p 3D camcorder functionality, displays up to WUXGA (1920×1200) at 60 frames per second and cameras up to 20 megapixels. (Hence their use of the descriptive “extraordinary”.)
• 25% less power consumption than rival architectures when running at high-performance  levels – think Cooler Operation.
• A low-power mode can deliver up to 5000 DMIPS at 0.6V – more than enough computing power for the majority of applications in everyday use. A key point here is that it enables stable SRAM operation at 0.6V – have you heard of anyone matching this? The result is that this low-power mode consumes 50% less power to deliver the same performance compared with alternative solutions in bulk CMOS.

It all adds up to big battery savings – this is the extra day CEO Didier Lamouche promised us in Barcelona last year when they announced this chip.

ST-Ericsson has posted an amazing video, filmed live at CES 13. In the first part of the demo (re: high-perf), on a Samsung Galaxy S3, they’ve got the Sky Castle 3D Graphics Demo launching twice as fast on FD-SOI as the bulk equivalent, and hitting 2.8GHz! And in the second demo (re: low power), they’re hitting 1GHz using just 0.636V, which would take 1.1V on bulk.

Design Highlights

For the ST-E designers, most of the IP blocks were directly re-used from the bulk design, so the porting to FD-SOI was extremely simple and fast.

For the manufacturing folks over at STMicroelectronics (and starting this year, at GloFo), FD-SOI is a planar technology that re-uses 90% of the process steps used in 28nm bulk. The overall manufacturing process in FD-SOI is 12% less complex, so they’ve got lower cycle time and reduced manufacturing costs (bean counters take note, please). They also point out that the manufacturing tools for FD-SOI are much simpler than those required for FinFETs.

Wondering what’s next? The 14nm FD-SOI node is already in development, the ARM Cortex-A15‘s  on the radar, and the FD-SOI roadmap is already defined up the 10nm node.

With FD-SOI, you can do much more with body-biasing (aka back-biasing) than you can in bulk (which suffers from too much leakage). Thanks to the ultra-thin insulator layer in FD-SOI, the biasing creates a buried gate below the channel, so it effectively acts like a vertical double gate transistor. This facilitates the flow of electrons, leading to a higher voltage in the body, and faster switching of the transistor. (Image courtesy ST-Ericsson)

With FD-SOI, you can hit higher speeds with lower operating voltages. This is because the buried oxide layer prevents electrons from leaking away as they travel through the channel from the source to the drain (this sort of leakage is a major source of power consumption in 28nm bulk, which depends on doping to handle leakage). Interestingly, this graph shows ST-E going down to 0.5V – which is incredibly impressive. (Image courtesy of ST-Ericsson)

(Image courtesy ST-Ericsson)

(Image courtesy ST-Ericsson)

As the (now award-winning) folks over at ST and Leti described for us a few years ago, designing a good SOC involves using the right blend of low, standard and high-Vt devices according to the target application and how it’s being used at any given time.  The ST-E designers use this feature to apply different voltages independently to the top and the buried gates of the FD-SOI transistor, which effectively changes its characteristics. By choosing optimal combinations of the voltages, the transistor characteristics can be transformed from those of a very high-performance transistor to those of a very low-power transistor. A processing core built up of such transistors can operate as if it were in fact two cores – one optimized for high performance and the other for low power. (You can’t do this with FinFETs, btw.)

Just Posted: FD-SOI video & white paper

Just as this blog was going online, ST-Ericsson posted an excellent, in-depth white paper; and in partnership with STMicroelectroics, a YouTube video detailing the how’s and why’s of FD-SOI.Here are the links — you really don’t want to miss these:

• Multiprocessing in Mobile Platforms: the Marketing and the Reality
In this white paper, ST-Ericsson’s Marco Cornero and Andreas Anyuru “…illustrate and compare the main technological options available in multiprocessing for mobile platforms, highlighting the synergies between multiprocessing and the disruptive FD-SOI silicon technology used in the upcoming ST-Ericsson products.”

• An Introduction to FD-SOI

STMicroelectronics and ST-Ericsson have teamed up on this excellent video, which garnered 1250 views within the first four days of its posting on YouTube. The animations and comparisons highlight why FD-SOI is so fast, and so cool.

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Posted by Adele Hars, Editor-in-Chief, Advanced Substrate News

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In the spring of 2012, STMicroelectronics announced the company would be manufacturing ST-Ericsson’s next-generation (and very successful) NovaThor ARM-based smartphone/tablet processors using 28nm FD-SOI process technology. With first samples coming out this fall, ASN talks to Jean-Marc Chery, Executive Vice President, General Manager Digital Sector, Chief Technology & Manufacturing Officer, STMicroelectronics about the manufacturing process and the expected results.

Jean-Marc Chery, Executive Vice President, General Manager Digital Sector, Chief Technology & Manufacturing Officer, STMicroelectronics (Photo credit: Artechnic)

Advanced Substrate News (ASN): You taped out ST-Ericsson’s 28nm FD-SOI NovaThor in the beginning of September. Did that go as you expected?

Jean-Marc Chery, STMicroelectronics (JMC): 28nm FD-SOI is a pretty exciting technology, allowing better design optimization (for higher speed and power efficiency) than traditional bulk technologies, still reusing most of manufacturing bricks of planar 28nm LP technology and the same design flow and methodology.

Adoption of 28nm FD-SOI for ST-Ericsson’s NovaThor has not introduced any major difficulty in its design, and the FD-SOI version has been taped out shortly after the Low-Power bulk version. Of course special care has been dedicated to further optimize power, exploiting FD-SOI exceptional flexibility and low-power capabilities.

On the manufacturing side, FD-SOI does not introduce additional complexity: on the contrary, process steps are reduced and thus cycle time.

ASN: Can you talk about the results you expect to see or have seen in the chip? Is there anything about it, or perhaps about the ARM core in particular, that makes it especially well-suited to FD-SOI? Is there anything about the transistor back-biasing capability (which enables significant performance enhancements and power optimization) in the design that makes it challenging to manufacture?

JMC: The wide supply range (ranging from 1.2V down to 0.6V) with excellent performance, and extended back-biasing capability (allowing dynamic modulation of the transistor threshold voltage) offered by 28nm FD-SOI technology have allowed us to exploit the ARM implementation to offer an improved maximum frequency and reach an overall power reduction for the various operating modes of the SoC.

About back biasing, this is a standard feature of FD-SOI technology with no particular challenges for manufacturing. Of course, its dynamic usage to optimize operating points for power (or speed) requires an appropriate device architecture to fully benefit from it.

ASN: In the press, STMicroelectronics has indicated that the 28nm FD-SOI has better power and performance than the industry’s first-gen bulk 22nm FinFETs. Would you say that your choice of FD-SOI puts you in a position of strength, in that you’ll have the mobile industry’s leading technology for 28nm and a choice of mature technologies at 14nm?

JMC: 28nm FD-SOI technology is a unique offer in the SOC industry, allowing the introduction of a fully-depleted technology with a low-cost solution and in a timely manner.

28nm FD-SOI is a planar technology derived from 28nm LP bulk technology, with the same design rules and allowing direct layout reuse (or simplified porting) of basic building blocks and IPs, benefiting from inheriting their maturity level. Also on the manufacturing side, 28nm FD-SOI technology uses the same equipment as Low Power bulk CMOS in a simplified process flow. In ST/Crolles facility we are reaching yield levels comparable to 28nm LP bulk ones, proving that FD-SOI process does not introduce major yield detractors.

A smooth library and IP migration flow coupled with rapid availability for manufacturing is driving the success of this 28nm technology.

Looking at the technology roadmap, the same incremental step for the 14nm node is under development and is on track.

The STMicroelectronics fab in Crolles, France. (Photo credit: Artechnic)

ASN: The plan was to start production in your fab in Crolles, then shift to GlobalFoundries for high-volume production in 2013 — is this still the schedule? From a manufacturing standpoint, what does it take to get a fab ready for FD-SOI production (does it take much longer than a typical bulk scaling transition)? Are there any special tools or other preparations needed?

JMC: For manufacturing, 28nm FD-SOI technology uses the same toolset as for 28nm LP bulk. Process development is complete, and ST/Crolles fab is now working to bring yield at production levels and complete the qualification of the technology, as done for any other.

Phase-in of the technology at GlobalFoundries is planned to start Q1 2013, with process qualified and with production level yield foreseen for Q4 2013.

The ST Crolles fab is highly automated, and already runs a broad mix of products in addition to the new FD-SOI chips. The accumulated assets the company has invested in this fab will increase capacity to 4500 wafers/week by the end of 2014. (Photo credit: Artechnic)

ASN: Let’s talk about the Crolles fab for a minute. Although it may be considered small compared to the big pure-play foundries, some aspects you share with the big foundries – like a large mix of product and advanced automation, right?

JMC: Crolles’ technology mix encompasses Advanced CMOS 28/40 nm, Imaging Sensors, embedded Non Volatile Memories starting at 55nm for Microcontroller and Analog on CMOS 110nm. This mix optimizes very well the accumulated assets we have invested in this Fab toward 4500 wafers week capacity over the next two years.

ASN: How do you see the impact of STMicroelectronics’s decision on the industry? Do you expect others to follow? Will other companies be able to leverage your technology at your foundry partners?

JMC: We would like very much for others to follow us. Through GlobalFoundries, ST is making its FD-SOI technology available to anyone in the microelectronics industry. The ST wide set of silicon-proven 28nm foundation libraries and IPs, encompassing not only basic libraries (std-cells, srams, I/Os) but also complex AMS IPs, is also available to be licensed to those customers aiming for quick access to the technology.

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Posted by Adele Hars, Editor-in-Chief, Advanced Substrate News

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SOI in general and FD-SOI in particular were hot topics at this year’s Semicon West in San Francisco. A panel discussion by industry thought-leaders gathered to discuss the current challenges facing the mobile industry was among the highlights.  It featured an impressive line-up of key players from the ecosystem at the forefront of fully-depleted, SOI based technologies, including:

• ARM: Ron Moore – Director of Strategic Accounts Marketing, Physical IP Division
• GlobalFoundries: Subramani Kengeri – Vice President of Design Solutions
• IBM: Gary Patton – Vice President of the Semiconductor Research and Development Center
• SOI Industry Consortium: Horacio Mendez – Executive Director
• Soitec: Steve Longoria – Senior Vice President of World Wide Strategic Business Development
• STMicroelectronics: Philippe Magarshack – Technology Research and Development Group Vice President
• UC Berkeley: Chenming Calvin Hu, Ph.D. – TSMC Distinguished Professor at the University of California at Berkeley

FD-SOI figured prominently in a panel on mobile challenges held during Semicon West '12. Left to right: C. Hu (UCBerkeley); R. Moore (ARM); H. Mendez (SOI Consortium); G. Patton (IBM); P. Magarshack (ST); S. Kengeri (GF); S. Longoria (Soitec)

Setting the scene, Soitec’s Longoria noted that, “Our industry is now driven by SOCs (where in the past it was CPUs) and we are on much shorter product cycles driven by consumer applications.”

As the first to be bringing out products based on ultra-thin layers of both SOI and insulator, ST’s Magarshack spoke extensively about their planar FD-SOI technology, which will be taping out at 28nm this summer.  He said that they were very confident and would be sharing the results at the end of the year.  He also emphasized their full commitment and close work with GF to enable the ecosystem, which was echoed in comments by GF’s Kengari.

With respect to 28nm, said Mendez of the SOI Consortium, “…the analysis says the cost [of FD-SOI] is equivalent to or even lower [than bulk silicon].”

IBM’s  Patton concurred, saying that, “When you’re dealing with an FD-SOI wafer, we see a big key advantage in manufacturability and time to market.”

Asked how FD-SOI would impact end-users, ARM’s Moore responded that mobile is about saving power.   FD-SOI provides a low-power bedrock, and with the headroom, the back-biasing option lets you add incredible performance.  “We see a valuable flow with FD-SOI & FinFET from devices down to servers,” he said.

In conclusion, UCBerkeley’s Hu said, “I’m very confident FD-SOI and FinFET are going to serve the industry quite well.”

The panel was followed by a great party held by leading SOI wafer manufacturer Soitec, to celebrate their 20th anniversary.

Earlier in the day, the show’s TechXpot series lead off with Enabling Sub-22nm with New Materials and Processes.  It was packed – with all the chairs taken, people were sitting on the floor in the aisles and crowded four-deep all around the edges. In his presentation on the  “Convergence of Engineered Substrates and IC Devices for Mobile Applications”,  Soitec CTO Dr. Carlos Mazure reminded us that mobile is really many technologies: in addition to the digital side, there’s RF, imaging, MEMS and memories – all of which can (and many do) benefit from SOI and other advanced engineered substrates. They’re not all on the leading edge, but when it comes to battery life, they all count.

At another presentation, Leti’s FD-SOI Manager with the IBM Alliance Maud Vinet covered their leading-edge research on FD-SOI.  She says that they’ll be presenting exciting results at IEDM in December, so watch this page for that.

All in all, it was a good show for the SOI ecosystem, full of energy and renewed enthusiasm.

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Posted by Adele Hars, Editor-in-Chief, Advanced Substrate News

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As I blogged here on SemiMD last week, STMicroelectronics has announced that to supplement in-house production at their fab in Crolles, the company has tapped GlobalFoundries for high-volume production of 28nm then 20nm FD-SOI mobile devices.  ST will also open access to its FD-SOI technology to GlobalFoundries’ other customers.  High-volume manufacturing will kick off with ST-Ericsson’s ARM-based 28nm NovaThor.

Prior to the announcement, the STM published a white paper explaining why they were forging ahead on FD-SOI.  It’s an excellent paper, providing benchmarks and design considerations.

As they explained in the Executive Summary: “Planar FD is a promising technology for modern mobile and consumer multimedia chips. It combines high performance and low power consumption, complemented by an excellent responsiveness to power management design techniques. The fabrication process is comparatively simple and is a low-risk evolution from conventional planar bulk CMOS – and there is little disruption at the design level, too. At 28nm, we find that planar FD more than matches the peak performance of “G”-type technology, at the cost and complexity of a low-power type technology, with better power efficiency across use cases than any of the conventional bulk CMOS flavors. Looking further, for 20nm and 14nm, we believe planar FD will be extremely competitive with respect to alternative approaches in terms of performance and power, while being both simpler and more suited to low-power design techniques. In short, a better choice for the type of SOC we offer. Planar fully depleted silicon technology will be ready as early as 2012 to compete in the forthcoming superphones era and in many other consumer segments.”

With the ST/GF news that other GF customers will have access to the ST technology, those in the fabless community will no doubt be wanting to learn more about what’s on offer.  If you have time, you can download the entire ST white paper from the SOI Consortium: Planar fully depleted silicon technology to design competitive SOC at 28nm and beyond.

The ST team that wrote it also wrote a summary version, which first appeared as part of the Advanced Substrate News special edition on FD-SOI industrialization.  In case you missed it there, here it is again.

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ST White Paper Excerpts: Planar Fully-Depleted Silicon Technology to Design Competitive SOCs at 28nm and Beyond

By Philippe FLATRESSE, Program Manager for Fully Depleted SOI Technology, STMicroelectronics; Giorgio CESANA, Director of Technology Marketing at STMicroelectronics; and Xavier CAUCHY, Digital Applications and Strategic Marketing Manager at Soitec.

Having identified that conventional planar bulk CMOS would not meet all the requirements of mobile and consumer multimedia System-on-Chip (SOC) ICs in the coming years, STMicroelectronics assessed alternative options. It is possible to propose a 28nm planar FD solution available as a second generation shortly after readiness of traditional 28nm on bulk silicon, with better time-to-market than waiting for availability of the 20nm node. It is also an excellent learning step to prepare a 20nm planar FD process. Our evaluations show that 20nm planar FD has also a very competitive potential performance-wise vs. FinFET for System-on-Chip applications.

Figure 1: ST’s planar FD device structure features (notional perspective, notional cross-section, TEM cross-section)

Technology overview:

• Immunity to Short Channel Effects and variability (no channel doping, so no Random Doping Fluctuations / RDF)

• For the 28nm node, the selected BOX thickness is 25nm.

• Ultra-thin BOX advantages include:

  - further improved electrostatic control and relaxed thinness requirement of the top silicon,

  - enables back-biasing through the BOX,

  - enables the implantation, during the fabrication process, of heavily doped “ground planes” or “back-planes” under the BOX, for improved electrostatics and/or VT adjustment and/or best-efficiency of back-bias,

  - brings the ability, during the fabrication process, to locally remove the top silicon and BOX to reach the base bulk silicon and co-integrate a few (non geometry-critical) devices on Bulk with devices on SOI – with a small step height between an SOI zone and a Bulk zone, compatible with lithography tools.

• BOX offers total dielectric isolation of the very thin active layer and naturally ultra-shallow junctions, leading to lower source/drain capacitance, lower leakage and latch-up immunity.

Planar FD technology allows several methods for setting the threshold voltage VT, including engineering the gate stack work function, trimming the gate length and other process engineering techniques. Thanks to this, STMicroelectronics’ 28FDSOI technology is capable of offering 3 VTs (HVT, RVT, LVT), as in traditional bulk CMOS technologies.

Circuit-Level Benchmarking

To assess how the improved planar FD-SOI transistor characteristics translate at the circuit level, STMicroelectronics has benchmarked a number of representative IP blocks, including an ARM Cortex-A9 CPU core. To that aim, we have extracted logic critical paths with associated RC parasitics from placed-and-routed designs and have re-characterized them by swapping 28nm traditional bulk CMOS transistor SPICE models with 28nm planar FD SPICE models.

With test chips in our 28nm planar FD technology becoming available, we are demonstrating that the models predict well the silicon behavior. We are therefore confident that the benchmarks presented below are reliable and will be matched by SOC implementations.

The benchmarks compare the merits at the 28nm node of ST’s planar FD technology (“28FD”) with a state-of-the-art Low-Power technology (“28LP”) and a more performance-oriented, state-of-art General Purpose technology (“28G”). They are all based on evaluation of an ARM Cortex-A9 core. The analysis focuses on the higher end of the range of operating frequencies found in a SOC, since modern mobile and consumer multimedia demand high performance from their master CPU (for example, a Cortex-A9 or the forthcoming A15).

Performance at nominal Vdd : best speed/leakage trade-off: 28FD consistently outperforms both 28LP and 28G (Figure 2).

Figure 2: Best operating frequency for any class of leakage (TT process, 85C)

Excellent speed/leakage ratio maintained at reduced Vdd : reducing Vdd is a very good way to save dynamic power. It is therefore realistic to envisage building 28FD chips that match 28G or 28LP performance at a fraction of the power consumption.

Leading-edge performance across the full Vdd range: 28FD exhibits outstanding performance at all practical Vdd values. In particular, when maximum circuit speed is sought, only the low- and ultra-low-VT flavors of 28G compare with 28FD LVT; however they are much leakier and more limited in terms of, e.g., Vdd overdrive they can withstand without reliability concerns.

Best Power Efficiency Across Use Cases: the 28FD technology is power-efficient across the full Vdd and target frequency range (Figure 3). Contrary to G-type technology, with 28FD a given logic circuit that is power-efficient with Vdd set to reach a certain operating frequency (say, 2GHz range) remains efficient with Vdd set for a different target frequency range (e.g., sub-1.5GHz).

Figure 3: Power efficiency across all use cases (TT process, WC temp)

Focus on SRAM: The bitcells proposed in 28FD technology have very competitive cell current (Icell) vs. standby current ratio, which is representative of the performance/leakage power trade-off for SRAM arrays (Figure 4). This is true for all bit cells flavors: high-density and low-leakage oriented, or high-speed oriented. The footprint of the 4 bitcells proposed in 28FD is the same as that of the 4 bitcells proposed in 28LP.

Figure 4: SRAM memory bit cells performance/leakage. The power supply of 28FD SRAM arrays can be lowered by 100mV from nominal and still match the performance of 28LP SRAM arrays operated at nominal Vdd, while offering a 2x to 5x reduction in leakage power.

Commonalities with 28nm LP Bulk

STMicroelectronics’ strategy when developing the 28nm planar FD technology has been to reuse as much as possible the 28nm low-power bulk CMOS process.

Overall, the Back-End is 100% identical to the traditional 28nm bulk low-power CMOS process, and the Front-End of Line (FEOL) is 80% common with that same process.

The planar FD process saves about 10% of the steps required to fabricate the chips on the wafers. This approximately offsets the cost overhead of the starting wafers. As a result, the 28nm planar FD technology matches the cost of a conventional low-power technology while delivering extremely competitive performance.

Design Considerations

Designing on planar FD requires specific extraction deck and SPICE models. Apart from that, the design flows, methodologies and tools do not need any adaptation that would be specific to planar FD (Figure 5).

Figure 5: ST’s SOC implementation flow outline

SPICE Models: SPICE compact models have been developed for accurately representing planar FD transistors. The model we use is now integrated in all major commercially available simulators, such as Mentor’s ELDO, Synopsys’ HSPICE and XA or Cadence’ SPECTRE. A model card has been extracted for all transistors and other devices available in our 28nm planar FD technology.

Flow and Design Platform: With adequate SPICE models integrated in the PDK, the design flow is identical to that used with conventional 28nm Bulk CMOS technology. We have developed a full design platform for SOC, re-using work done for 28nm Bulk. It consists of standard cell libraries (multi-channel and multi-VT) with power management elements (power switches, level shifters etc.), embedded memories, analog foundation IP (such as PLLs and the likes) and specialty IP (Antifuse etc.).

A design platform developed for bulk CMOS technology can be ported to planar FD by re-characterization using planar FD SPICE models, which we have done for a variety of back-biasing conditions. Only a limited number of critical IPs need to be tuned or redesigned: Analog IP, IOs, Fuse.

At the SOC level, migrating an existing design from bulk to planar FD represents an effort comparable to half-node migration. It brings very worthwhile benefits at reasonable efforts.

All techniques used in low-power designs are applicable to planar FD. Those that can be enhanced with planar FD include: multi-VT, power switches, reverse and forward body bias, and voltage scaling.

Back-biasing consists of applying a voltage just under the BOX of target transistors. Doing so changes the electrostatic control of the transistors and shifts their threshold voltage VT, to either get more drive current (hence higher performance) at the expense of increased leakage current (forward back-bias, FBB) or cut leakage current at the expense of reduced performance. While back-bias in planar FD is somewhat similar to body-bias that can be implemented in bulk CMOS technology, it offers a number of key advantages in terms of level and efficiency of the bias that can be applied.  Back-biasing can be utilized in a dynamic way, on a block-by-block basis. It can be used to boost performance during the limited periods of time when maximum peak performance is required from that block. It can also be used to cut leakage during the periods of time when limited performance is not an issue. In other words, back-bias offers a new and efficient knob on the speed/power trade-off.

Perspectives

28nm: We expect to sign-off designs breaking the 2GHz barrier under worst-case conditions, in a power-efficient and cost-efficient way. For lower performance targets, there is also the opportunity to design ultra-low-power chips that can fulfill their functional specifications using a very low Vdd, for example in the 0.6-0.8V range. The Process Design Kit (PDK) is available, targeting the technology to be open for risk production by mid-2012.

20nm: We intend to scale our planar FD technology to 20nm, introducing a number of improvements to continue pushing the performance and retain a low power consumption. The objective is to bring up a solution that will improve on what mobile-optimized planar bulk CMOS will achieve, and will be extremely competitive vs. potential FinFET-based approaches for SOC – while keeping a simple and cost-efficient approach. The design rules will be compatible with 20nm bulk CMOS. This technology will bridge the gap to 14nm and provide an interesting alternative to the cost and complexity of introducing Extreme-UV and FinFET structures. Evaluation SPICE models are available, and full PDK is scheduled by end of 2012, with risk production for 13Q3.

14nm: Based on the assessments we have performed, we are confident that the planar FD technology is shrinkable to 14nm. Silicon and buried oxide thickness will need to be reduced to within limits that wafer manufacturers and CMOS process technology can handle.

Posted by Adele Hars, Editor-in-Chief, Advanced Substrate News

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Two big pieces of news have recently been announced by STMicroelectronics:

1. to supplement in-house production at Crolles, the company has tapped GlobalFoundries for high-volume production of 28nm then 20nm FD-SOI mobile devices;
2. ST will open access to its FD-SOI technology to GlobalFoundries’ other customers.

The high-volume manufacturing will kick off with ST-Ericsson’s ARM-based 28nm NovaThor.

Here are other key points from the press release:

• The 28nm FD-SOI generation, currently in the industrialization phase, is scheduled to be available for prototyping by July 2012.
• The next node, the 20nm FD-SOI generation, is currently under development and is scheduled to be ready for prototyping by Q3 2013.

What they’re saying:

Joel Hartmann, STMicroelectronics Corporate VP, Front End Manufacturing and Process R&D, Digital Sector: “FD-SOI is ideally suited for wireless and tablet applications, where it provides fully-depleted transistor benefits using conventional planar technology, and this arrangement with GLOBALFOUNDRIES ensures our customers will have a secure source of supply.”

Philippe Magarshack, STMicroelectronics Corporate VP, Design Enablement and Services: “Porting Libraries and Physical IPs from 28nm Bulk CMOS to 28nm FD-SOI is straightforward, and designing digital SoCs with conventional CAD tools and methods in FD-SOI is identical to Bulk, due to the absence of MOS-history-effect. In addition, FD-SOI can be used for either extreme performance or very low leakage on the same silicon, by biasing dynamically the substrate of the circuit. Finally, FD-SOI can operate at significant performance at low voltage with superior energy efficiency versus Bulk CMOS.”

Gregg Bartlett, Chief Technology Officer of GLOBALFOUNDRIES: “We have a longstanding partnership with ST spanning joint R&D and manufacturing, as well as an unmatched heritage of expertise in SOI technology. We’re pleased to be working with ST to bring this next generation of SOI technology to market and enable continued momentum in the mobile revolution.”

While it might seem like all this is happening very fast, ST has been championing FD-SOI technology for about a decade. In fact, one of the company’s top SOI gurus, Advanced Devices Program Director Thomas Skotnicki, first wrote about it for us at Advanced Substrate News back in 2006. And we’ve been covering it regularly ever since.

For an in-depth look at ST’s FD-SOI design and manufacturing strategy and benchmarking results, be sure to check out their white paper. By the way, designers take note: they also indicate in the white paper that the 28nm FD-SOI Process Design Kit (PDK) is available now, targeting risk production by mid-2012. Evaluation SPICE models are now available for the 20nm node, and full PDK is scheduled by end of 2012, with risk production for 13Q3.

For easy access to the dozens of useful and insightful FD-SOI related articles by contributors on the leading-edge that we’ve published over the years, just hit the FD-SOI tag on the ASN website.

Seems like a new door has opened now, doesn’t it?

Fab 8, located in Luther Forest Technology Campus, Saratoga County, New York, USA is GlobalFoundries' new 300 mm Fab dedicated to advanced technologies. Maximum Full Capacity is 60,000 300mm wafers/month. GloFo also runs high-volume SOI at its fabs in Dresden and Singapore (source: Wikipedia).

Louis Tannyeres, Principal Fellow, Chief Chip Architect and head of System Silicon Development at ST-Ericsson.

Advanced Substrate News (ASN): Can you give us a bit of background on the markets you’re addressing?

Louis Tannyeres (LT): Founded in 2009, ST-Ericsson is an industry leader in design, development and creation of cutting edge mobile platforms and semiconductors across the broad spectrum of wireless technologies.  Today, we are actively engaged with seven of the top nine mobile device OEM manufacturers by revenue.

ST-Ericsson’s portfolio covers all market segments, with an emphasis on mid to high-range smartphones and tablets.

ASN: What are the challenges that the product designers (your clients) face with respect to available technology vs. consumer expectations?

LT: With the recent evolution in smartphone capabilities consumer expectations are rising fast. Ultra-fast multicore Gigahertz processors, stunning 3D graphics, full HD multimedia and high-speed broadband connectivity have become the norm for high-end devices.

Consumers expect these features to be delivered in a device that is slim, light and can last for at least as long as their previous phones did. For our customers, the product designers, this translates into requirements for delivering high performance at low power in a cost effective manner.  FD-SOI is a technology that addresses exactly these requirements.

ASN: What advantages do you expect FD-SOI to bring to the platform?

LT: FD-SOI is a technology that is available for design today and will allow existing designs in 28nm to benefit today already from significant improvements in performance and power. FD-SOI solves – with less process complexity – scaling, leakage and variability issues to further shrink CMOS technology beyond 28nm.

ST-Ericsson's NovaThor™ family is an integrated solution for the mainstream smartphone segment, in which modems and application processors are built into a single piece of silicon. The application engine uses the latest ARM®-based multi-core CPUs optimized to deliver the highest performance and support for advanced 2D & 3D graphics cores.

ASN: How have your customers reacted to this bold move?

LT: True market disruptions are only understood after the fact. We believe FD-SOI is such a disruption and a truely differentiated solution. There is a real opportunity for a FD-SOI 28nm solution and then 20nm as a key technology differentiator.  Our customers have reacted  favorably to hearing that we will be enabling FD-SOI technology in our next generation of products. And since we are enabling this technology in STMicroelectronics’ foundries, we have also minimized our risk with respect to market adoption trends.

ASN: How difficult was it to port the existing design from bulk to FD-SOI?

LT: FD-SOI is a technology that is available for design today and will allow existing designs in 28nm to benefit today already from significant improvements in performance and power. Thanks to fully depleted devices, FD-SOI allows operating at fast speed at extremely low operating voltages – a key characteristic to allow low power operation for mobile devices.

A design platform developed for bulk CMOS technology can be ported to planar FD by re-characterization using planar FD SPICE models. Only a limited number of critical IPs need to be tuned or redesigned.

ASN: What was the impact on design flow?

LT: The equations describing the electrical behavior of fully depleted transistors are different from those used for conventional bulk CMOS, so designing on planar FD requires specific extraction deck and SPICE models. The model we use is now integrated in all major commercially available simulators.  Apart from that, the design flows, methodologies and tools do not need any specific adaptations.

ASN: Do you foresee any major challenges in fast-ramping to high volumes?

LT: 28nm planar FD manufacturing technology has a lot of commonalities with traditional 28nm Low-Power CMOS technology and STMicroelectronics’ strategy has been to reuse as much as possible the 28nm low-power bulk CMOS process. The Back-End part of the process is a direct copy of the 28nm bulk technology. The Front-End part of the process also relies in majority on a direct re-use of equivalent process modules from the bulk technology. Only a few steps have been optimized, added or removed. Overall, the Back-End is 100% identical to the traditional 28nm bulk low-power CMOS process, and the Front-End of Line (FEOL) has 80% in common with that same process.

ASN: When do you expect to have the first prototypes available?

LT: FD-SOI will be introduced into next generation products from ST-Ericsson. At this time, our first 28nm FD-SOI products are scheduled to tape out in Q3 2012 with production start anticipated in 2013.

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By Adele Hars, Editor-in-Chief, Advanced Substrate News

~~

Big and official FD-SOI news: Soitec has announced that the company is supplying the FD-SOI wafers for ST-Ericsson’s next-generation of NovaThor 8540 smartphone/tablet processors. Starting at the 28nm node, this marks the industry’s first industrialization of the new planar, fully-depleted technology on ultra-thin SOI wafers.

Soitec has just issued an official press release, but ST-Ericsson President-CEO Didier Lamouche had already heralded the news to analysts at the Barcelona Mobile World Congress last month. (You can see/hear the presentation here.)

His Slide 29 from the Barcelona event pretty much says is it all:

Slide 29 from ST-Ericsson’s Analysts & Media Briefing at Mobile World Congress in Barcelona (28 February 2012)

This architecture is essential in implementing transistor technology that solves – with less process complexity – the scaling, leakage and variability issues that are associated with shrinking CMOS technology from 28nm to 14nm.

ST-Ericsson’s planar FD-SOI technology is supplied by STMicroelectronics.  As Lamouche said in his presentation, “The world needs to go fully-depleted.” Choosing this flavor of fully-depleted, planar SOI technology (as opposed to a 3D fully-depleted technology such as FinFETs) puts ST-Ericsson a full two-years ahead of the competition, he estimates.

With the NovaThor platform, ST-Ericsson’s been wracking up some nice wins lately – with Samsung, Nokia and Sony, to name a few. So this is a high-volume endeavor.

Wafer manufacturer Soitec has been working on these wafers with key partners for years. The wafers for planar FD-SOI require an extremely thin and incredibly uniform (+/- 5 Angstroms!) layer of silicon on top of a very thin layer of insulating buried oxide (BOX). Soitec sells them under the banner “FD-2D”; they’re now ready to roll in volume.

“We are positioned to provide the volume of qualified wafer manufacturing required to enable the industry to speed the adoption of planar fully depleted technology into mainstream mobile applications,” says Soitec COO Paul Boudre.

In case you missed it, STM went into significant detail on the advantages of the technology and announced a 28nm product line at the SOI Consortium’s recent FD-SOI workshop (see Important News Comes Out of Recent FD-SOI Workshop in ASN online).

The key planar FD-SOI advantages cited by ST-Ericsson include:

• a fully-depleted architecture that is cost-competitive with bulk
• simplified processing (10 percent few steps)
• 35 percent lower power consumption at maximum performance
• big performance boost – double (!) when supply voltage is at 0.6V
• designers can leverage powerful back-biasing techniques to further boost performance or lower power
• it’s processed with standard fab tools

(Look for more about these and other features in a soon-to-be-published white paper.)

Key Quotes

From the Soitec announcement, here are the key quotes from the parties involved:

ST-Ericsson’s chief chip architect Louis Tannyeres: “Next-generation mobile consumer devices will need to deliver an even better user experience and higher performance without sacrificing battery life. Together with innovations in overall platform system design, advances in process technology are key to delivering next-level performance and higher power efficiency. The results of our work with ST on FD-SOI have demonstrated that this technology is able to deliver these benefits in a cost-effective manner, while allowing us to differentiate our solutions.”

STMicroelectronics’ assistant general manager, Technology R&D, Joël Hartmann: “STMicroelectronics and its partners Leti, Soitec and IBM have invested several years of development in FD-SOI technology, and ST has recently demonstrated the strong differentiation of  this technology versus conventional bulk CMOS, both for high-performance and low-power features on several IPs at 28nm and below.  This combination makes FD-SOI particularly suitable for wireless and tablet applications where it essentially provides the fully depleted transistor benefits of FinFETs on a planar conventional technology, while allowing advanced back bias techniques, which are not available with FinFETs. We are delighted that it could be adopted by ST-Ericsson for their next generation of products.”

Soitec’s COO, Paul Boudre: “FD provides a low-risk option for semiconductor companies such as ST-Ericsson that are seeking to take advantage of the benefits of a fully depleted transistor architecture while leveraging existing design and manufacturing capabilities.”

Clearly this is a very significant and exciting moment for the industry. It’s the first major fully-depleted announcement since Intel/FinFETs. Might it be the first shot across the bow in the next round of the transistor wars?

~~

Posted by Adele Hars, Editor-in-Chief, Advanced Substrate News

~~

The SOI Consortium’s 6th FD-SOI workshop, held just after ISSCC, yielded some exciting news. Most of the presentations are freely available for downloading from the SOI Consortium website. Here are the highlights.

STMicroelectronics

In a terrific presentation by Giorgio Cesana, Marketing Director at STMicroelectronics, he revealed that the company would be releasing a major product line based on planar FD-SOI at the 28nm node this year. Prototypes will be ready in June.

The objective, he said, is “…to have a compelling technology offer for the mobile application processor speed race.”

And compelling it is: their 28nm FD-SOI technology performances is 61% higher than comparable bulk technology at 1V. It gets even more interesting at lower Vdd – boasting a 550% improvement at 0.6V.

Slide 32 from ST's presentation, 28 & 20nm FDSOI Technology Platforms, given at the SOI Consortium's 6th FD-SOI Workshop (Feb. 24, 2012).

Check out the presentation – it’s got excellent descriptions, detailed roadmaps (look for products on 20nm FD-SOI in 2014), and clear comparisons. Topics include:

• 28FDSOI positioning vs. bulk technologies
• Design methodology and EDA flow
• From spice models to product: migration methodology from Bulk to FDSOI
• Biasing techniques on FDSOI
• FDSOI ST design environment
• 20FDSOI development track

ARM

In FD-SOI Design Portability, Betina Hold, Senior Principal for Silicon R&D at ARM in San Jose emphasized the ease of porting existing designs from bulk to FD-SOI.

FD-SOI, she concluded, is perfect for high-performance, low-power mobile apps.

Here are the main points she made:

Slide 29 from ARM's presentation, FDSOI Design Portability, given at the SOI Consortium's 6th FD-SOI Workshop (Feb. 24, 2012).

(You can also read ARM’s perspective on the ease of porting from bulk to FD-SOI in a recent ASN article by the company’s Director of SOI Technology, Jean-Luc Pelloie.)

IBM

There were two presentations from IBM, addressing the two major flavors of fully-depleted architectures on SOI: planar FD-SOI, and FinFETs on SOI.

The presentation entitled Recent Advances in FDSOI given by Bruce Doris, Manager of Device Integration at IBM Research, reviewed various device structures. He presented new data indicating that FD-SOI performance is competitive for high performance and at a much shorter gate lengths (Lg), and will scale well beyond 20nm.

FINFET on SOI presented by Terence Hook, Senior Technical Staff Member at IBM, compared with both clarity and depth the characteristics and manufacturability of FinFETs on SOI and bulk with other SOI and bulk structures.

Leti

In a very in-depth presentation, FDSOI strain options FDSOI for 20nm and below, Olivier Faynot, who leads the Innovative Devices Lab at CEA-Leti, demonstrated how most of the existing techniques used on bulk technology are compatible with FDSOI. However, he emphasized that FDSOI devices already meet high performance requirements, especially at the circuit level. A unique feature of FDSOI for future nodes, he noted, is that strained SOI wafers (sSOI – wherein the top layer of silicon is strained at the wafer level) are particularly effective in giving NMOS a boost  (Ion NFET 1.4mA/µm – PFET 1.2 mA/µm @ Ioff 100nA/µm).

Soitec

Enabling Substrate Technology for a Large Volume FD Standard, presented by Christine Pelissier, Director of Business Operations at SOI wafer manufacturer Soitec, gave a broad view of the both the technological and volume supply requirements for the wafers. Soitec is now manufacturing wafers for FDSOI in which the top silicon is controlled to within +/-5 angstroms.

She looked both at the wafers used in FDSOI as well as the partially depleted (PD) SOI wafers which have been in high-volume production for over a decade. She then went on to explain the key features in wafers for planar FDSOI (which Soitec refers to as FD2D) and in wafers for SOI-based FinFETs (FD3D).

Slide 8 from Soitec's presentation, Enabling Substrate Technology for a Large Volume Fully Depleted Standard, given at the SOI Consortium's 6th FD-SOI Workshop (Feb. 24, 2012).

Other highlights

Two presentations are not available online. Brian Chen of Agilent (Accelicon) presented 20nm ETUTBB-FDSOI Rev3 Models. (Note that 20nm FD-SOI logic evaluation model cards are now available through SOI Consortium in cooperation with Accelicon/Agilent. An NDA is required.)

Professor Borivoje Nikolic from UC Berkeley presented Microprocessor Design in FD-SOI. This showed their design of a Planar FDSOI microprocessor that will be taped out later this year.

In all, this 6th workshop acknowledged the reality of Planar FDSOI technology starting with the 28nm node. There were plenty of relevant questions and discussions, confirming the promise FDSOI holds as a cost-effective and reliable solution.

As Horacio Mendez, Executive Director of the SOI Consortium concluded, this workshop was great. “We’ve been offering these workshops for over two years,” he said. “The community has taken Fully Depleted SOI from a technical advantage in the lab to a technical advantage on mobile products (as presented by ST). The cost, power, performance and manufacturability of FD SOI is a significant driving force.”

~~

~~

In a recent and excellent article in ASN by Thomas Skotnicki, Director of the Advanced Devices Program at STMicro, he explains in a very clear and accessible way why FD-SOI with ultra-thin Body & Box (UTBB) is a better solution for mobile, multimedia SOCs than FinFETs — starting at the 28nm node and running clearly through 8nm.  It is based on the paper he presented at the 2011 IEEE SOI Conference.

In case you missed it in Advanced Substrate News, here it is again.

———–

ST: FD-SOI for Competitive SOCs at 28nm and Beyond

By Thomas SKOTNICKI, Advanced Devices Program Director, STMicroelectronics

The multi-functional system-on-chips (SOC) needed at the heart of the next generations of wireless, high-performance, low-power multimedia devices have very different needs than the mono-functional processors of the past. Traditionally, the trade-off for computers and servers has been accepting high operational voltages (Vdd) and high stand-by leakage in return for high-performance. This is obviously not an acceptable trade-off for mobile internet devices.

In a mobile world, high-performance must go hand-in-hand with low-operation Vdd and low stand-by leakage. That requires different technologies. As we approach the 20/22nm node and beyond, traditional planar-bulk technologies cannot meet these requirements. The choice comes down to either a planar fully-depleted (FD) SOI solution or a FinFET solution. At STMicroelectronics, we call our flavor of planar FD-SOI UTBB, for ultra-thin body & box. As such, it leverages SOI wafers with both ultra-thin top silicon and ultra-thin buried oxide (BOX). Where more practical, we use a hybrid SOI/bulk configuration, wherein certain devices are placed in the bulk silicon that has been exposed by etching back the insulating BOX layer.

The results we’ve obtained make UTBB a compelling option.

Designing a good SOC involves using the right blend of low-, standard- and high-threshold-voltage (Vth) devices according to the target application and how it’s being used at any given time. Our FD-SOI technology can handle multiple Vth devices and I/Os through a cost effective approach, solving challenges for low-power operation (LOP), low-standby power (LSTP) and analog and high-performance (HP) needs.

UTBB at 28nm

ST’s UTTB technology may be a good candidate even for the 28nm node, as it would provide a boost in speed before 20nm bulk technology is ready. Therefore, we have explored an industrial solution for its implementation.

Our objectives that we met for FD-SOI at the 28nm node were as follows:

• Demonstrate with respect to 28 LP Bulk :
  • + 30% Performance at same Vdd (1V)
  • or 40% lower power consumption for at least the same performance
• Demonstrate feasibility of “easy” porting from Bulk to FD-SOI
• Demonstrate manufacturability (including SRAM yield) of FD-SOI/UTBB (with 7nm top silicon thickness and 25nm buried oxide thickness)

FD-SOI/UTBB structure (Courtesy: STMicroelectronics, IEEE SOI Conference 2011)

With respect to porting the design, the goal of “easy” porting means:

• the design only needs recharacterisation of critical paths
• FD-SOI masks are redefined from Bulk by CAD2MASK.
• Spice models are available for all devices

The process flow is derived from 28LP Bulk of the ISDA Alliance: Metal Gate First and no stressors. Out of 15 major process modules in the Front-End of Line, only 3 are specific to the FD-SOI process. The number of masks is similar to 28 LP Bulk (actually with a saving of 2 or 3, which could be used for analog adjustments in Hybrid bulk/SOI parts if needed).

More than 25 implant steps are saved vs. 28nm LP Bulk for two Vths. This eliminates 15% of the process steps and results in a process cost saving of 10%. So as long as the SOI substrate cost overhead is less than 10% of the bulk process cost, the FD-SOI process is more cost-effective than the bulk LP process.

It is worth noting that the relative impact of the substrate cost will be more favorable to FD-SOI at subsequent nodes, since the process becomes more complex on bulk and adds more metal levels.

DIBL: the SOC performance metric

The drive current, Ion, has long been the key metric for speed in high-performance microprocessors. But, especially for multimedia SOCs, the effective current Ieff is a much better metric and is heavily dependent on DIBL (Drain Induced Barrier Lowering). The lower DIBL of UTBB transistors reflects their superior electrostatic control and leads to higher performance. The influence of DIBL on maximum operating frequency is more pronounced for higher Vths and/or lower Vdd, which explains why this parameter is crucial for low-power multimedia SOCs – which use higher Vths than high-performance microprocessor chips.

Vth adjustment and Performance Results

The means to adjust Vth constitute a fundamental difference between bulk and FD-SOI devices.

On short devices in bulk, Vth is controlled primarily by channel doping. Vths for logic and SRAM can be adjusted independently.

In FD-SOI, however, Vth is controlled primarily by the gate stack on short and long devices in both logic and SRAM. By also playing upon channel length and ground plane implant below the BOX, we are able to obtain all the Vths we need for our 28nm FD-SOI technology. According to its type (n or p), the ground plane (GP) can shift Vth up by more than 50mV (in the case of our 25nm BOX). GP implants also suppress the depletion depth below the BOX for better DIBL, and improve the effect of body biasing.

Body bias is a powerful performance booster usable at different Vdd points — at low voltages, for example, speed is increased by 30%. The Ion/Ioff trade-off is not hurt (body-biasing simply shifts the operating point along the technology’s Ion/Ioff curve), even for body bias voltages up to 2V. This flexibility is not available with FinFET, and while body bias is possible with planar bulk, at 28nm it is of limited practicality and effectiveness.

We then compared the 28nm FD-SOI to a 28nm bulk low-power-oriented ‘LP’ process and to different performance-oriented ‘G’-type processes, on a DDR3 Memory Controller.

The results indicated FD-SOI had:

• comparable performance to the “G”-type processes at high Vdd, with additional room for overdrive (and without the complexity of ‘G’-type processes)
• overall best performance across all practical Vdd values
• a competitive advantage at low Vdd, with over 40% performance advantage over ‘G’ at 0.6V power supply
• best power efficiency

Additional benchmarking on an ARM Cortex-A9 is confirming these results.

20nm goals

We want to propose a differentiated technology at 20nm node providing a 20% boost in performance versus 20LPM at the same Vdd. We also want it to be competitive versus a potential Trigate SOC at 22nm.

Under our 20nm UTBB FD-SOI scheme, performance will be boosted by dynamic control of a Full-Forward Body Bias (F-FBB) architecture. Vth modulation sources will include gate stack, ground-plane, counter-doping, body-bias and L poly-bias.

We have now compared our FD-SOI with bulk and FinFETs at 20nm, with impressive results. While FinFETs and UTBB FD-SOI very much resemble one another (in fact, a UTBB device looks rather like a FinFET tipped on its side), with FD-SOI we are seeing:

• a large gain in performance: 42% at 0.9V and 98% at 0.7V
• best performance
• G-like performance on an LP process
• best power efficiency

(Courtesy: STMicroelectronics, IEEE SOI Conference 2011)

Work by Leti and by IBM and partners also shows excellent SRAM transistor matching. UTBB was also found to have much lower threshold voltage variability, thanks in large part to the undoped channel. This in turn enables smaller SRAM cells and/or lower minimum voltages (Vmin) – a gain of 150mV, which translates into significantly lower power consumption. We have determined that the SRAM remains fully functional as low as Vdd=0.4V.

14nm to 8nm

An FD-SOI roadmap through 14nm indicates an orderly and logical progression. Leti has shown that further thinning of the insulating BOX layer enables FD-SOI scalability down to 8 nm with top silicon thickness (TSi) no thinner than ~ 6-7nm (post-processing).

Soitec’s Xtreme SOI wafers with ultra-thin BOX (25nm) is ramping to volume this year, targeting the 28nm node. With SEH and a third supplier on tap, the supply chain is in place.

2Onm FD-SOI vs FinFET: summary table (Courtesy: STMicroelectronics, IEEE SOI Conference 2011)

Straightforward Move to 28nm

ST has been working on FD-SOI for over 10 years. We have research programs or partnerships on 3 sites : Crolles, Leti, and IBM Albany NanoTech. We have collaborated with Soitec for wafer supply.

The key technology elements for UTBB have been demonstrated.

The move from R&D to an industrial process of 28nm FD-SOI technology is for us (and for our partners) an efficient and straightforward response to the world-wide competition. The extension of FD-SOI towards the 20nm and 14nm nodes is also in preparation with new boosters to further increase the performance growth rate.

UTBB FD-SOI promises to give STMicroelectronics a significant edge in both the near term and for years to come.

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This article was adapted from “Competitive SOC with UTBB SOI”, T. Skotnicki et al, presented at the 2011 IEEE SOI Conference.  It was first posted in Advanced Substrate New on November 18, 2011.