By Peter Rabbeni

EDI CON China 2016, held in Beijing from April 19-21, has scheduled 80 paper sessions, 30 workshops, seven keynotes, with a new track on silicon-on-insulator (SOI) semiconductor technology. On Tuesday April 19th, I will deliver the keynote talk on the emergence of SOI in the RF/microwave industry.

Today, smart phones and tablets contain radio frequency (RF) front-end modules (FEM), which are typically built with power amplifiers (PAs), switches, tunable capacitors, and filters. Technologies such as radio frequency silicon-on-insulator (RF SOI) help mobile devices tune and retain cellular signals– giving wireless devices consistently strong, clear connections from more places.

The mobile market continues to favor RF SOI, as it delivers low insertion loss, reduced harmonics and high linearity over a wide frequency range at a cost-effective price point. RF SOI is a win-win technology option that can improve performance and data speeds in smartphones and tablets, and it is expected to play a key role in the Internet of Things as well.

For RF chipmakers, it brings the benefits of silicon design and integration to the RF front end, and is a low cost alternative to other expensive technologies which lack the scale and integration capability that RF SOI can bring to RF front end module solutions. And, for designers, RF SOI offers design flexibility by integrating multiple RF components onto a single chip without losing valuable circuit board real estate.

This integration enables fewer chips and smaller footprints for mobile applications, that allows mobile makers to design less complex radios with the advanced features their customers expect. Mobile devices that exploit RF SOI technologies for RF front end applications benefit from the same or better linearity and insertion loss against competing technologies, which translates to longer battery life, less dropped calls and higher data speeds.

More good news for RF market players, technologies like FD-SOI have unique properties and capabilities that can enable RF circuit innovation, and achieve integration levels never before seen in silicon-based technologies. The key to this is the exploitation of the low voltage operating capability and well-bias features of FDSOI, dynamic control of Vdd and the use of well-bias techniques can not only help reduce overall power consumption but can be used as a means to optimize RF circuit operation. This is not something that can be easily done in bulk technologies.

When designing a complex SoC, another advantage is the ability to integrate multiple functionalities that results in a smaller form factor and simpler packaging which is much more cost-effective and in terms of power, more efficient for IoT applications, which is absolutely essential in order to meet the economic requirements of this market and keep pace with evolving network challenges. Although emerging standards such as 5G are still a number of years away, we are already seeing interest in what advantages technologies such as FDSOI/RFSOI can bring in meeting the challenges of systems which need to deliver high speeds/bandwidth at low power.

There is no doubt that demand on our networks will continue to grow. Now more than ever, the underlying communication networks matter and the need for speed is immediate. The mobile world is calling and it’s time for device manufacturers and component designers to capitalize on design flexibility and enablement and supply (capacity assurance) that RF SOI offers.

By Dave Lammers

Today we are pleased to launch a new series on the Foundry Files featuring commentary from David Lammers, a veteran reporter who has worked with the Associated Press, EE Times, Semiconductor International, and most currently, as a freelance journalist for various industry publications.

I can’t think of a more interesting topic to begin this blog series with than GLOBALFOUNDRIES’ plans for automotive ICs. Tomorrow’s cars are pulling in the need for three technologies: much faster processors based on 22nm fully depleted SOI; MRAM embedded memory; and 5G wireless communications.

Any one of these three changes–FD-SOI, MRAM, and 5G–should be enough to get the blood moving faster, but to bring them together is as big a story as the low-power application processors that emanated from the smart phone revolution starting 20 years ago.

And there is some urgency here, because ultra-fast image processing is essential to the adoption of advanced driver assistance systems, or ADAS. After 2020, autos will have as many as five cameras per vehicle, and the car’s image processors must be fast enough to react instantaneously to anything in the path of the car.

Let’s take them one at a time, beginning with the arguments for why GF is committed to FD-SOI at the 22nm node for automotive-use MCUs.

FD-SOI excels in two areas: since junction leakage is suppressed by the buried oxide layer, power consumption is constrained, making it easier to meet the temperature requirements of automotive MCUs. And secondly, FD-SOI brings benefits to the radio frequency (RF) circuits in terms of linearity and insertion loss.

Jeff Darrow, automotive marketing director at GF, points out that automotive MCUs must be able to operate reliably at 125-150 degrees Centigrade ambient, with junction temperatures that range even higher. For automotive MCUs made in a 55nm bulk silicon technology, leakage already accounts for 30 percent of total power consumption.

“For bulk CMOS, leakage increases exponentially with temperature. We have to live with 30 percent leakage at 55nm, but that trend was unsustainable. We see 22nm FD-SOI providing both the low power of FDSOI with the digital shrink provided by 22nm technology,” Darrow said.

And yes, the much-improved leakage of high-k dielectrics also will be required for any automotive technology solutions at 28nm or 22nm. GF believes its use of a gate-first high-k manufacturing flow brings advantages for automotive ICs compared with the replacement gate, or gate last, approach of other foundries.

“When our competitors try to integrate an embedded Flash memory with a gate-last high-k, our analysis is that the production implementation is extraordinarily difficult. The yields would be horrendous; by our estimate, less than 50 percent,” Darrow said.

GF announced its planar 22nm FD-SOI technology in July 2015, calling it 22FDX®, and Darrow emp hasizes that “22FDX is a core part of our automotive strategy.”

With the infotainment systems inside the cabin as a separate category, the vast majority of the automotive products made by suppliers such as Bosch, Continental, Delphi, and Denso are for power train, body, and safety systems.

“What we are doing is critical for the industry, and our customers are absolutely relying on us,” Darrow said. Because of GF’s experience in making SOI-based processors for AMD and others, it has a head start in terms of SOI manufacturing know-how. Having a major fab in earthquake-resistant Dresden, Germany is a big plus as well, especially for the German carmakers, he added.

Replacing e-Flash

Emerging memories are also essential for future automotive processors. Today, a typical automotive MCU will have 2 MB of embedded flash, and high-end solutions can have as much as 10 MB on-board. The memory works best when it is embedded on the processor die, partly to provide the instantaneous response times, and partly to shield against RF and other radiated emissions.

Embedded flash will continue to be widely used, even as emerging memory technologies are increasingly used by SOC designers. While flash’s reliability is well-proven, it is costly to produce, requiring about a dozen additional mask layers. At GF, e-flash is being extended to the 28nm node, but beyond that the foundry is committed to magnetic resistive random access memory (MRAM) for embedded processors made for a variety of applications, including automotive.

Dave Eggleston, vice president of embedded memory at GF, notes that the semiconductor industry has “a lot of history in e-flash; it retains data well in very harsh environments. But one of our key takeaway messages is that we believe e-flash scaling is going to stop below 28. It will continue through 28 nanometers but below 28 we need a new solution, and we believe the industry is coalescing around MRAM.”

Starting with IoT solutions, and extending to storage and compute, MRAM already is being embraced by key automotive suppliers which value its power efficiency and cost advantages. And while e-flash typically requires higher voltages to write information, MRAM does not; it can run directly off of logic power.

GF has a long-term relationship with MRAM technology supplier Everspin Technologies (Chandler, Ariz.), and the partners have converged on a perpendicular spin-torque version of MRAM that has much better power consumption and write speeds than earlier MRAM bit cells.

“MRAM is a big transition. But for us it is not a question mark. We have placed our bet. We know what that next embedded memory technology is, and we are educating our customers on how that technology improves their systems,” Eggleston said.

The cost effectiveness of MRAM comes because it can be built within the back-end-of-the-line (BEOL) interconnect layers of the chip. While new deposition and etch techniques are being perfected to deal with the complex material stack of the magnetic tunnel junction, Eggleston said MRAM can be added with just three additional mask layers.

The importance of 5G

It is only in recent years that the association between cars and RF–from Bluetooth in the cabin to automotive radar to help drivers safely change lanes–has become prevalent.

Peter Rabbeni, senior director of RF business development at GF, said the 5G cellular standard was designed with automotive applications in mind, particularly the need to “see” what is around the car with latencies in the range of a millisecond.

“To make autonomous vehicles a reality requires some pretty sophisticated communications systems,” Rabbeni said, shortly after returning from the Mobile World Congress 2016 held in late February in Barcelona, Spain. The 5G standard, which was a center of discussion in Barcelona, is expected to deliver “much higher bandwidth, much shorter latencies, and support for multiple, simultaneous users,” he added.

For a crash avoidance system to make the right decisions, very high data rates and much wider bandwidths are essential. In the not-too-distant future, vehicles will be “transferring a lot of data and acting on that data very quickly, which depends on very low latencies,” he said.

Range sensing and object detection capabilities on all sides of a car are at the heart of driver assistance systems. The ADAS systems will require what Rabbeni calls “an expansion beyond 6 GHz, into millimeter wave radar, something the military has been using for many years.”

Faster data rates depend on more radios, and more digital signal processing, which drives the need for linewidth scaling. Rabbeni argues that keeping within the power envelope of automotive MCUs with RF on-board “is where things like FD-SOI have an advantage. We can leverage back-gate biasing technology to optimize the power versus performance of the device.”

Source: GLOBALFOUNDRIES

FD-SOI Body-Biasing Enables Power/Performance Trade-Off and Tuning of RF/Analog Parameters

For ADAS to work, Rabbeni said “we need more complex radios to drive higher performance. We are working very hard to develop a new generation of offerings, with higher linearity, lower insertion loss, and better harmonics, which all contribute to a figure of merit for a given radio.”

When GF acquired IBM’s microelectronics operation (which essentially created the RF SOI and SiGe markets) it gained expertise and manufacturing capacity for the RF SOI-based switch and antenna tuning segments. It also gained a silicon-germanium technology widely used in Wi-Fi power amplifiers, microwave wireless backhaul and automotive radar front end solutions.

Due to the growth in wireless, the demand for GF RF technologies continues to grow and the company continues to invest in additional capacity in order to satisfy the growing demand for its technologies. While the RF SOI technologies will be built out of Burlington, VT and Singapore, the 22 nm FD-SOI products will be built in Dresden.

“We are actively working on advanced node RF SOI for next generation systems including 45nm and 22nm. The 22nm FD-SOI platform was architected with RF in mind from the start and products with embedded RF have already been taped out; test structures have been modeled and measured to further enhance the process development kits (PDKs) so customers can design in it reliably” Rabbeni said. “We have models of focused RF blocks, switches, and PLLs, to prove out how the technology can be used. We are very excited about this technology and continue to move forward.”

By Rajeev Rajan

In my last blog, IoT is Now!, I provided a bird’s eye view of the IoT landscape. In this post, I will dive deeper into the IoT by the numbers, slowly peeling back the onion to reveal what part of the Things, Networks, and Data Centers we play in.

According to the McKinsey report The Internet of Things: Mapping the Value Beyond the Hype, the IoT will have $3.9-11.1 trillion in economic impact per year by 2025 including $200-$700 billion in automotive, $200-$350 billion in the home, and $1.2-$3.7 trillion in factory operations and equipment optimization. This value is not measured purely in technologies sold, but in significant efficiencies generated.

We are currently in a mobile computing or smartphone era that’s shifting to pervasive computing—primarily IoT—and will eventually evolve into intelligent computing.

Have we forgotten that IoT isn’t something new? It’s been around for more than a decade. And, its progress and growth have been driven from a foundational technology architecture that is still being used today.

This growth is significantly influenced by continued technology development. At the heart of it, we are enabling industries to spawn based on the capabilities that we give them. We enable progress and growth by maintaining a technology advantage, making it easy for customers to do business with us, and maintaining a competitive cost structure for the industry.

In this sense, every ounce of efficiency we’re able to find in manufacturing, every single technology innovation that helps manage power—even in the smallest fraction—and every breakthrough in RF implementation for connectivity, are significant steps to fully realize the potential of the IoT.

Success in the IoT is a fundamentally diverse effort, with continued success coming from partnerships among large and small companies alike, empowering them to define the IoT across a range of industries.

At SEMICON China, IoT is a hot topic, with a forum devoted to this theme: Technology Shapes the Future-Sensor Hub Solution for Wearable and IoT on March 17. During this session, I will discuss enabling semiconductor technologies that drive the IoT and the “atoms of intelligence” that lead to Intelligent Computing.

And in my next blog, we’ll explore the amazing IoT applications that wouldn’t be possible without a strong process technology powering the semiconductors that are “under the hood.” It’s an incredible vertical integration story with many turning gears and we’ll dissect key sections of this “under the hood” story in each blog. I invite you to join me.

By Peter Rabbeni

After wrapping up the week at Mobile World Congress in Barcelona, one thing has become clear—5G is on everyone’s mind and the race to develop enabling technologies to make 5G a reality in the next 5 years is underway. During the conference, in between meetings and demos, I was able to tour the halls and view a series of 5G technologies, innovations and use cases which not only make 5G more real but exploit the promises that 5G will bring, namely low latency, high data rates, on-the-go connectivity, high user density, and highly reliable and secure communications.

Touring the tradeshow floor it felt as though the possibilities were endless for the fifth generation of mobile networks. Cellular carriers and WiFi companies were spotlighting their 5G solutions and a whole range of chipset offerings for the Internet of Things (IoT) proving that, although convergence on a common 5G specification is still some years away, we’ve reached the stage where the pipeline of 5G applications is well ahead of the standard, thus creating new business models and use cases. Many of the use cases leveraged technologies such as virtual reality, location awareness services, and push advertising addressing applications like real-time gaming to autonomous vehicles, just to name a few. And, the recent announcements from US telecoms to test 5G networks in “real-world” conditions mark the official entry into the 5G race. Many experts used the 2018 Olympics in Seoul as a proof point for 5G infrastructure deployment, with media and communications to fully exercise the network. One memorable moment of the show was during the panel keynote when Ericsson CEO Hans Vestberg pulled a multi-element steerable phased array radio front end plus antenna out of his pocket. No larger than a deck of cards, Vestberg explained that three of these would make up a three-sector 5G base station to support multi-GBps data rates in a massive MIMO environment.

Today, the overall radio frequency (RF) chip market is hot. At its core, 5G and IoT will both require innovations in radio technologies, which in turn will push advances in semiconductor technologies. These innovations will include low power, integrated mmWave radio front ends, antenna phased array subsystems, high performance radio transceivers and high speed ADCs and DACs. As OEMs integrate more RF content into their smart phones and tablets and new high-speed network standards are introduced, the latest equipment requires additional RF circuitry to support newer modes of operation. This includes chips that support more LTE bands, carrier aggregation and envelope tracking.

As a lower cost and more flexible alternative to GaAs, radio frequency silicon-on-insulator (RF SOI) has established itself as the technology of choice for the majority of RF switches and antenna tuners manufactured today. The mobile market continues to favor RF SOI as it helps to solve the challenges that go along with ensuring users seamless, always available connectivity and access to the power of the Internet from virtually anywhere. Interest in and usages of silicon germanium (SiGe) technologies are also growing. SiGe technologies help address both the RF front-end module and high-performance market segments by offering excellent RF gain, noise, and linearity characteristics, even at millimeter wave frequencies. SiGe enables customers to integrate more function into fewer chips while getting improved performance, and expand their addressable market segments. Longer term, it is expected that foundry capacity will increase with the strong ramp in LTE smart phones, tablet PCs, and other mobile consumer applications.

Recently, GLOBALFOUNDRIES’ RF business unit crossed a new capacity threshold with our RF SOI chip shipments topping 20 billion, proving industry demand is strong.

With the growth of IoT and the emerging trials for 5G, there is no doubt that demand on our networks will continue to grow. Customers who exploit RF SOI and SiGe technologies develop solutions that enhance user experiences, including broader geographic mobility and faster data rates for the increasing interconnection of everyday applications.

So a global race is on, and it’s clear from the technology on display at Mobile World that RF and SiGe technologies play an even more important role in driving reduced complexity, higher performance, and lower overall cost over competing technologies.