Category Archives: Device Architecture

In the quest for faster and more powerful computers and consumer electronics, big advances come in small packages.

The high-performance, silicon-based transistors that control today’s electronic devices have been getting smaller and smaller, allowing those devices to perform faster while consuming less power.

But even silicon has its limits, so researchers at The University of Texas at Dallas and elsewhere are looking for better-performing alternatives.

In a new study published Oct. 7 in the journal Science, UT Dallas engineers and their colleagues describe a novel transistor made with a new combination of materials that is even smaller than the smallest possible silicon-based transistor.

“Silicon transistors are approaching their size limit,” said Dr. Moon Kim, professor of materials science and engineering at UT Dallas and an author of the study. “Our research provides new insight into the feasibility to go beyond the ultimate scaling limit of silicon-based transistor technology.”

The study authors also included Kim’s graduate student Qingxiao Wang, and collaborators at the University of California, Berkeley, Stanford University and the Lawrence Berkeley National Laboratory, which led the project. Researchers in California fabricated the transistor and performed theoretical simulations, while the UT Dallas team physically characterized the device using an atomic resolution electron microscope on campus.

As current flows through a transistor, the stream of electrons travels through a channel, like tap water flowing through a faucet out into a sink. A “gate” in the transistor controls the flow of electrons, shutting the flow off and on in a fraction of second.

“As of today, the best/smallest silicon transistor devices commercially available have a gate length larger than 10 nanometers,” said Kim, the Louis Beecherl Jr. Distinguished Professor in the Erik Jonsson School of Engineering and Computer Science. “The theoretical lower limit for silicon transistors is about 5 nanometers. The device we demonstrate in this article has a gate size of 1 nanometer, about one order of magnitude smaller. It should be possible to reduce the size of a computer chip significantly utilizing this configuration.”

One of the challenges in designing such small transistors is that electrons can randomly tunnel through a gate when the current is supposed to be shut off. Reducing this current leakage is a priority.

“The device we demonstrated shows more than two orders of magnitude reduction in leakage current compared to its silicon counterpart, which results in reduced power consumption,” Kim said. “What this means, for example, is that a cellphone with this technology built in would not have to be recharged as often.”

Instead of using silicon, the researchers built their prototype device with a class of semiconductor materials called transition metal dichalcogenides, or TMDs. Specifically, their experimental device structure used molybdenum disulfide for the channel material and a single-walled carbon nanotube for the gate.

Kim said there are many technical challenges before large-scale manufacturing of the new transistor is practical or even possible.

“Large-scale processing and manufacturing of TMD devices down to such small gate lengths will require future innovations,” he said.

KLA-Tencor Corporation (NASDAQ:  KLAC) and Lam Research Corp. (NASDAQ:  LRCX) today announced that they have agreed to terminate their proposed merger agreement. The parties decided to it was not in the best interests of their respective stakeholders to continue pursuing the merger after the U.S. Department of Justice advised KLA-Tencor and Lam Research that it would not continue with a consent decree that the parties had been negotiating. No termination fees will be payable by either the Company or Lam Research in connection with the termination of the Merger Agreement.

“Although we are disappointed with this outcome, KLA-Tencor’s performance over the past several quarters demonstrates the Company is executing our strategies at a high level and creating compelling value for the industry and for our stockholders,” commented Rick Wallace, President and Chief Executive Officer of KLA-Tencor.

“Today our customer engagement and market leadership is strong and KLA-Tencor is delivering superior financial results. Growth and earnings momentum is expected to continue as we go forward, fueled by new products in the marketplace today, and with many more products in the pipeline,” continued Mr. Wallace. “Additionally, our collaboration over the past year with Lam Research and with our customers has affirmed the value of closer cooperation between process and process control for new, enabling solutions. For that reason, we plan to explore collaboration opportunities with Lam Research around programs identified as beneficial to our customers.”

After the initial announcement of the proposed merger, which was expected to close mid-year 2016, analysts voiced concern over whether the deal would be approved. Robert Maire of Semiconductor Advisors wrote: “We think this is going to be the obvious biggest issue after the failed AMAT & TEL merger.  We think there will likely be opposition in the semi industry but probably less so than we heard the screaming related to AMAT/TEL.”

The Semiconductor Industry Association (SIA), representing U.S. leadership in semiconductor manufacturing, design, and research, today announced worldwide sales of semiconductors reached $28.0 billion for the month of August 2016, an increase of 3.5 percent compared to the previous month’s total of $27.1 billion and an uptick of 0.5 percent over the August 2015 total of $27.9 billion. August marked the market’s largest month-to-month growth since May 2013 and its first year-to-year growth since June 2015. All monthly sales numbers are compiled by the World Semiconductor Trade Statistics (WSTS) organization and represent a three-month moving average.

“Following months of sluggish global semiconductor sales, the global market recently has shown signs of a rebound, punctuated by solid growth in August,” said John Neuffer, president and CEO, Semiconductor Industry Association. “The Americas market was particularly encouraging, topping 6 percent month-to-month growth for the first time in nearly three years to lead all regional markets. China also stood out, posting by far the strongest year-to-year growth of all regions in August. All told, global sales are still behind last year’s pace, but appear to be on the right track as 2017 draws closer.”

Month-to-month sales increased across all regions: the Americas (6.3 percent), Japan (4.8 percent), China (3.1 percent), Asia Pacific/All Other (2.7 percent), and Europe (0.7 percent). Year-to-year sales increased in China (7.1 percent) and Japan (2.2 percent), but fell in Asia Pacific/All Other (-2.7 percent), the Americas (-3.1 percent), and Europe (-3.3 percent).

 

August 2016

Billions

Month-to-Month Sales                               

Market

Last Month

Current Month

% Change

Americas

5.10

5.43

6.3%

Europe

2.70

2.71

0.7%

Japan

2.60

2.73

4.8%

China

8.56

8.82

3.1%

Asia Pacific/All Other

8.12

8.34

2.7%

Total

27.08

28.03

3.5%

Year-to-Year Sales                          

Market

Last Year

Current Month

% Change

Americas

5.60

5.43

-3.1%

Europe

2.81

2.71

-3.3%

Japan

2.67

2.73

2.2%

China

8.23

8.82

7.1%

Asia Pacific/All Other

8.57

8.34

-2.7%

Total

27.88

28.03

0.5%

Three-Month-Moving Average Sales

Market

Mar/Apr/May

Jun/Jul/Aug

% Change

Americas

4.79

5.43

13.2%

Europe

2.63

2.71

3.3%

Japan

2.55

2.73

6.9%

China

8.09

8.82

9.0%

Asia Pacific/All Other

8.00

8.34

4.2%

Total

26.07

28.03

7.5%

Today, SEMI announced an exceptional lineup of keynotes at SEMICON Japan’s “SuperTHEATER” focusing on innovation and insights into the future of the electronics supply chain. SEMICON Japan 2016, the largest exhibition in Japan for electronics manufacturing, will take place at Tokyo Big Sight in Tokyo on December 14-16. Registration for the exhibition and programs is now open.

Japan’s semiconductor fab equipment capital expenditure (front-end facilities, both new and used including discretes and LED) is forecast to increase 12 percent (to US$5.0 billion) in 2017, according to the August SEMI World Fab Forecast report.

On December 14, keynotes will focus on the future:

  • Semiconductor Executive Forum – “The Creation of New Business Opportunities” keynotes:
    • Toshiba: Yasuo Naruke, corporate senior executive VP, on “Toshiba Storage Business Strategy; Utilizing Big Data to Win Productivity”
    • TSMC: Jack Sun, VP of R&D and CTO, on “New Frontiers of Semiconductor Innovation”
    • Murata Manufacturing: Hiroshi Iwatsubo, executive VP, on “Business Strategy and Technology Trends”
  • Opening Keynotes – “Into the Future” keynotes:
    • IBM Research:  Dario Gil, VP, Science and Solutions, on “The Cognitive Era and the New Frontiers of Information Technology”
    • University of Tsukuba: Yoichi Ochiai, media artist and assistant professor, Digital Nature Group, on “The Age of Enchantment”

The SEMI Market Forum, also on December 14, with the theme “Outlook and Growth Opportunities in the Electronics Manufacturing Supply Chain” will offer presentations from IHS Markit, VLSI Research Inc., and SEMI.

Highlights on December 15 include Industrial IoT Forum, Autonomous & Connected Car Forum, and U.S. Commercial Service IT Forum. The Technology Trend Forum on December 16 focuses on “The Tokyo 2020 Olympics: Innovation for All.” In addition, SEMICON Japan features forums on Manufacturing Innovation and IoT Innovation.

Attendees at SEMICON Japan will explore the key technologies and business models necessary to grow in the coming years. The SuperTHEATER offers nine keynote forums, all with simultaneous English-Japanese translation, with global top executives.

Platinum sponsors of SEMICON Japan include Disco Corporation, Screen Semiconductor Solutions Co., Ltd. and Tokyo Electron Limited. Gold sponsors include: Advantest Corporation, Applied Materials, Inc., ASE Group, Daihen Corporation, Ebara Corporation, Fasford Technology Co., Ltd., Hitachi High-Technologies Corporation, JSR Corporation, Lam Research Corporation, Nikon Corporation, Tokyo Seimitsu Co., Ltd. and VAT Ltd.

For more information and to register for SEMICON Japan, visit www.semiconjapan.org/en/

STMicroelectronics (NYSE: STM) and WiTricity, an industry pioneer in wireless power transfer over distance, today announced their design collaboration to develop semiconductor solutions for magnetic-resonance-based wireless power transfer. The goal is to “cut the last cord,” bringing convenience to the powering and charging of consumer electronics, Internet of Things (IoT) devices, as well as medical, industrial, and automotive applications.

WiTricity and ST are developing semiconductor solutions that combine WiTricity’s foundational intellectual property and wireless power-transfer mixed-signal IC-design expertise, with ST’s leadership in power-semiconductor design, fabrication, and packaging capabilities and resources. For the consumer electronics and IoT markets, power transmit and receive systems built with these new semiconductors aim to deliver spatial freedom, as well as wireless fast charging of one or more devices at the same time. Dubbed “Wireless Charging 2.0,” the semiconductor solutions built with the magnetic resonance technology will also have unique advantages over current technology, including being able to efficiently charge metal-body smartphones, tablets, and smartwatches.

The contemplated semiconductor offerings include designs that comply with the AirFuel magnetic resonance specification as well as multi-mode solutions that incorporate both resonant and inductive charging. The AirFuel Alliance, a global organization dedicated to delivering the best wireless-charging experience for consumer electronics, is driving an interoperable ecosystem of wireless-charging Power Transfer Transmit Units (PTUs) and Power Receive Units (PRUs) that enable users to charge their devices everywhere; in their homes and offices to public spaces and even in their vehicles.

Beyond the consumer market, WiTricity is the global technology leader in wireless power for automotive, industrial and medical applications. ST and WiTricity demonstrated high-power wireless-transfer technology for electric vehicle charging at APEC 2016 in Long Beach California. For the automotive industry, WiTricity recently announced wireless “park-and-charge” development kits using their industry-leading 11kW solution for electric- and hybrid-vehicle charging. The solution has successfully been tested by the Society of Automotive Engineers (SAE) for inclusion in a new global standard.

“Combining the expertise of WiTricity, the innovator in wireless power-transfer and magnetic resonance technology with ST’s resources and key IP, including Smart Power technologies and RF Bluetooth low energy, allows us to deliver complete, efficient wireless-charging solutions that increase convenience and ease of use while delighting consumers and exceeding their expectations,” said Matteo Lo Presti, Vice President and General Manager, Analog, in the Analog and MEMS Group, STMicroelectronics. “Game-changing technology from this ST and WiTricity collaboration will enable product designers across the globe to rid the world of cumbersome wires and charging cables and allow us to promote a broader set of our own semiconductor offerings into these emerging markets.”

“STMicroelectronics is a global leader in semiconductor solutions for power electronics and a compelling choice to rapidly commercialize fast and efficient wireless-charging chipsets based on WiTricity’s silicon designs and magnetic-resonance technology,” said Alex Gruzen, CEO of WiTricity. “With ST’s vast experience in semiconductor design and fabrication, as well as its access to leaders in the consumer electronics, automotive, and industrial markets, this collaboration puts us in a strong position to accelerate the adoption of resonance-enabled wireless charging.

As a provider of process solutions for a broad range of applications, Oxford Instruments announced the development and launch of the SiC via plasma etch process using its high performance PlasmaPro100Polaris etch system. SiC is becoming an increasingly important material, particularly in the arena of high performance GaN RF devices using SiC as a substrate. A smooth via etch through the SiC is essential to enable these devices, and Oxford Instruments has developed the ideal solution for etching high quality SiC vias efficiently. Combined with a low damage GaN etch within the same hardware, the PlasmaPro100 Polaris offers a unique capability for GaN based RF device plasma etch processing requirements.

The technology developed offers several process capabilities suited to the SiC via application:

  • High SiC etch rate enabling maximum throughput
  • Smooth sidewalls for problem free post etch metallisation
  • High selectivity to underlying GaN layer giving a smooth, low damage stop onto the GaN device layers
  • Clamping of sapphire carriers using Oxford Instruments’ unique patented Electrostatic Clamp technology ensuring excellent sample temperature control and maximum yield
  • Capability of etching SiC and GaN in the same tool through advanced plasma source technology
  • High utilisation provided by long Mean Time Between Cleans (MTBC)

Dr Mark Dineen, Optoelectronics Product Manager at Oxford Instruments Plasma Technology says, “Our Applications specialists have spent significant time developing this SiC via etch process on the PlasmaPro100 Polaris etch system, enabling high selectivity and throughput amongst other benefits. These benefits will enable our customers to etch both SiC and GaN in the same tool through advanced plasma source technology.”

Oxford Instruments delivers plasma processing systems, and offers a library of over 6,000 process recipes, all backed by a global support and service network.

SEM showing smooth via etch through SiC

SEM showing smooth via etch through SiC

Leti, an institute of CEA Tech, and the Institute for Information Industry of Taiwan (III), a non-profit non-governmental technology development organization, today announced an agreement for mutual exploration of a wide range of information and communications technology (ICT) related to the Internet of Things (IoT) and 5G wireless connectivity.

The five-year collaboration will include, but is not limited to, joint development and implementation of IoT and 5G based Smart ICT solutions for the EU and Taiwan, and scientific information exchanges.  Also envisioned are cross-invitations to scientific events, joint implementation of international collaborative projects and partnerships, and work on experimental platforms and test beds that can be used to provide real-world validation of solutions.

Leti’s background in IoT and 5G systems, including spectrum management, radio access technologies and protocols, as well as IoT open platforms for large-scale systems, will be a primary contribution, along with its technological roadmaps. In addition to its expertise in IoT systems, III will provide access to Taiwanese technology platforms, as well as industry-driven requirements and use cases.

“Our two organizations have very complementary skills and ecosystems, and it’s a pleasure to launch our collaboration. Together we have an excellent opportunity to pilot and demonstrate innovative 5G and IoT-related solutions that will be useful for industries and individuals in Taiwan and the EU,” said Leti CEO Marie Semeria at the official signing ceremony in Taipei, held during a Leti workshop event there.

“Taiwan is currently supporting and promoting IoT and smart city. The service and platform that based on IoT technology will be the key factor for industrial development. III and Leti’s collaboration will significantly enhance our ability to pursue our mission of promoting industrial applications, R&D technologies, and IoT infrastructures,” commented III Executive Vice President Pao-Chung Ho. “We look forward to our information exchange and collaboration, and to building a creative and effective long-term research partnership between our teams.”

Silicon Labs (NASDAQ: SLAB) today announced the acquisition of Micrium, a supplier of real-time operating system (RTOS) software for the Internet of Things (IoT). This strategic acquisition helps simplify IoT design for all developers by combining a commercial-grade embedded RTOS with Silicon Labs’ IoT expertise and solutions. Micrium’s RTOS and software tools will continue to be available to all silicon partners worldwide, giving customers a wide range of options, even when using non-Silicon Labs hardware. Micrium will continue to fully support existing as well as new customers.

Founded in 1999, Micrium has consistently held a leadership position in embedded software components. The company’s flagship µC/OS RTOS family is recognized for reliability, performance, dependability, impeccable source code and extensive documentation.

“With an installed base of millions of devices, Micrium’s RTOS software has established itself as one of the most reliable and trusted platforms over the last 10 years,” said Jean-Michel Orsat, Chief Technology Officer, ICT Standards and Connectivity Solutions at Somfy. “Micrium has been a rock-solid RTOS solution partner for Somfy, and we look forward to using Micrium’s RTOS software family for years to come, delivering the reliability and performance we need for our IoT applications.”

Micrium’s widely deployed RTOS software has been ported to more than 50 microcontroller architectures and has a global footprint with more than 250,000 downloads across all embedded vertical markets, with solutions certified to meet safety-critical standards for medical electronics, avionics, communications, consumer electronics and industrial control.

“By combining forces with Silicon Labs, the Micrium team will drive advances in embedded connectivity for the IoT while giving customers a flexible choice of hardware platforms, wireless stacks and development tools based on the industry’s foremost embedded RTOS,” said Jean J. Labrosse, Founder, CEO and President of Micrium. “We will continue to provide our customers with an exceptional level of support, which is a Micrium hallmark.”

The combination of Micrium’s RTOS and Silicon Labs’ multiprotocol SoCs, wireless modules, wireless stacks and Simplicity Studio development tools gives customers a faster, easier on-ramp from connected devices to the cloud with end-to-end solutions for embedded IoT design.

“IoT products are increasingly defined by software. Explosive growth of memory/processor capabilities in low-end embedded products is driving a greater need for RTOS software in connected device applications,” said Daniel Cooley, Senior Vice President and General Manager of Silicon Labs’ IoT products. “The acquisition of Micrium means that connected device makers will have easier access to a proven embedded RTOS geared toward multiprotocol silicon, software and solutions from Silicon Labs.”

Leti, an institute of CEA Tech, announced today it has joined the Stanford SystemX Alliance, a network of 100 renowned Stanford University professors and 27 world-class companies, joining forces in a pre-competitive environment to define tomorrow’s research strategies. Leti’s participation bridges the gap between two worlds – academia and industry. 

The alliance is a collaboration between Stanford researchers and over two-dozen leading global technology companies – such as Google, Huawei, Xilinx, Intel, Qualcomm, Toshiba, Infineon, and many more – that focuses on hardware and software at all levels of the system stack. Topics range from materials and devices to systems and applications in electronics, networks, energy, mobility, bio-interfaces, sensors and other technological domains.

Together, the SystemX partners are working on research strategies that should lead to a wide range of next generation applications, including the highly anticipated self-driving car and future artificial-intelligence systems that will improve performance and operation of our mobile, medical, smart-home solutions and devices.

Following his recent visit to Leti, Stanford System X Director Rick Bahr said, “Leti’s extensive, advanced clean room facilities and expertise are truly impressive, and I can see now that Stanford and Leti are very complementary. It makes real sense for us to find more ways to work together on developing new technologies and their demonstrators.”

“The alliance provides an avenue for worldwide strategic discussions and, more importantly, allows both research partners and industry leaders to stay ahead of the game,” said Barbara De Salvo, Leti’s scientific director.

“Leti brings its scientific excellence and expertise on technology transfer, and will have access to Stanford’s top-notch upstream research and network,” she added. “Stanford’s dynamic culture will inspire Leti on the road to new scientific territories and lead to strong programs with the Silicon Valley ecosystem.”

Leti will share its innovative research results during several SystemX events and explore ambitious, innovative and collaborative projects together with other partners of the Alliance.

INVECAS Inc. and GLOBALFOUNDRIES announced today that INVECAS will provide IP and end-to-end ASIC design services as a part of the foundry’s FDXcelerator Partner Program, an ecosystem designed to facilitate 22FDX SoC designs for tomorrow’s intelligent systems. The collaboration accelerates the adoption of FDX technology in applications spanning Internet-of-Things (IoT), mobile, RF connectivity, and networking markets.

INVECAS will work closely with GLOBALFOUNDRIES’ technology teams to develop and verify a range of intellectual property (IP) for the company’s 22FDX process. Moreover, INVECAS will offer comprehensive ASIC design services to help customers realize SoC designs with high confidence and low risk.

“Our objective is to provide silicon-proven IP solutions and system-level expertise to address the difficult issues of design complexity facing ASIC designers today,” said Dasaradha Gude, chairman and CEO, INVECAS. “We are glad to be an initial partner in GLOBALFOUNDRIES’ FDXcelerator Program, a ground-breaking initiative to enable a broad range of customers and accelerate time-to-volume for 22FDX.”

“We are pleased to expand our strategic relationship with INVECAS and welcome them as an initial member of the FDXcelerator Partner Program,” said Alain Mutricy, senior vice president of product management at GLOBALFOUNDRIES. “In addition to the comprehensive portfolio of FDX-optimized IP, our customers can now access INVECAS’ full suite of services to realize their SoC designs on time and with highest quality.”

With the recent announcement of the company’s next-generation 12FDX technology, the FDXcelerator Partner Program builds upon GLOBALFOUNDRIES’ industry-first FD-SOI roadmap, a lower-cost migration path for designers on advanced nodes. By participating in FDXcelerator and continuing to expand its IP offering to support a wider range of FDX customers, INVECAS is well positioned as a leader in the adoption and growth of the FDX platform. Moreover, the FDXcelerator Partner Program broadens the technology collaboration between the companies, including tighter interlock around quality, qualification and development methodology.