Category Archives: Device Architecture

A research group in Japan announced that it has quantified for the first time the impacts of three electron-scattering mechanisms for determining the resistance of silicon carbide (SiC) power semiconductor devices in power semiconductor modules. The university-industry team consisting of researchers from the University of Tokyo and Mitsubishi Electric Corporation has found that resistance under the SiC interface can be reduced by two-thirds by suppressing electron scattering by the charges, a discovery that is expected to help reduce energy consumption in electric power equipment by lowering the resistance of SiC power semiconductors.

Electron scattering under the silicon carbide (SiC) interface is limited by three factors: roughness of the SiC interface, charges under the SiC interface and atomic vibration. Credit: 2017 Mitsubishi Electric Corporation.

Electron scattering under the silicon carbide (SiC) interface is limited by three factors: roughness of the SiC interface, charges under the SiC interface and atomic vibration. Credit: 2017 Mitsubishi Electric Corporation.

Electric power equipment used in home electronics, industrial machinery, trains and other apparatuses requires a combination of maximized efficiency and minimized size. Mitsubishi Electric, a leading Japanese electronics and electrical equipment manufacturer, is accelerating use of SiC devices for power semiconductor modules, which are key components in electric power equipment. SiC power devices offer lower resistance than conventional silicon power devices, so to further lower their resistance it is important to understand correctly the characteristics of the resistance under the SiC interface.

“Until now, however, it had been difficult to measure separately resistance-limiting factors that determine electron scattering,” says Satoshi Yamakawa, senior manager of the SiC Device Development Center at Mitsubishi Electric’s Advanced Technology R&D Center.

Electron scattering focusing on atomic vibration was measured using technology from the University of Tokyo. The impact that charges and atomic vibration have on electron scattering under the SiC interface was revealed to be dominant in Mitsubishi Electric’s analyses of fabricated devices. Although it has been recognized that electron scattering under the SiC interface is limited by three factors, namely, the roughness of the SiC interface, the charges under the SiC interface and the atomic vibration, the contribution of each factor had been unclear. A planar-type SiC metal-oxide-semiconductor field-effect transistor (SiC-MOSFET), in which electrons conduct away from the SiC interface to around several nanometers, was fabricated to confirm the impact of the charges.

“We were able to confirm at an unprecedented level that the roughness of the SiC interface has little effect while charges under the SiC interface and atomic vibration are dominant factors,” says Koji Kita, an associate professor at the University of Tokyo’s Graduate School of Engineering and one of scientists leading the research.

Using an earlier planar-type SiC-MOSFET device for comparison, resistance was reduced by two-thirds owing to suppression of electron scattering, which was achieved by making the electrons conduct away from the charges under the SiC interface. The previous planar-type device has the same interface structure as that of the SiC-MOSFET fabricated by the electronics maker.

For the test, Mitsubishi Electric handled the design, fabrication and analysis of the resistance-limiting factors and the University of Tokyo handled the measurement of electron-scattering factors.

“Going forward, we will continue refining the design and specifications of our SiC MOSFET to further lower the resistance of SiC power devices,” says Mitsubishi Electric’s Yamakawa.

This research achievement was announced at the 63rd International Electron Devices Meeting (IEDM) in San Francisco, California, on December 4, 2017.

SEMI, the global industry association representing the electronics manufacturing supply chain, today reported that worldwide semiconductor manufacturing equipment billings reached US$14.3 billion for the third quarter of 2017.

Quarterly billings of US$14.3 billion set an all-time record for quarterly billings, exceeding the record level set in the second quarter of this year. Billings for the most recent quarter are 2 percent higher than the second quarter of 2017 and 30 percent higher than the same quarter a year ago. Sequential regional growth was mixed for the most recent quarter with the strongest growth in Europe. Korea maintained the largest market for semiconductor equipment for the year, followed by Taiwan and China. The data are gathered jointly with the Semiconductor Equipment Association of Japan (SEAJ) from over 95 global equipment companies that provide data on a monthly basis.

Quarterly Billings Data by Region in Billions of U.S. Dollars
Quarter-Over-Quarter Growth and Year-Over-Year Rates by Region
3Q2017
2Q2017
3Q2016
3Q2017/2Q2017
3Q2017/3Q2016
Korea
4.99
4.79
2.09
4%
139%
Taiwan
2.37
2.76
3.46
-14%
-32%
China
1.93
2.51
1.43
-23%
35%
Japan
1.73
1.55
1.29
11%
34%
North America
1.50
1.23
1.05
22%
43%
Europe
1.06
0.66
0.53
61%
100%
Rest of World
0.74
0.62
1.13
20%
-34%
Total
14.33
14.11
10.98
2%
30%

Source: SEMI (www.semi.org) and SEAJ (http://www.seaj.or.jp)

The Equipment Market Data Subscription (EMDS) from SEMI provides comprehensive market data for the global semiconductor equipment market. A subscription includes three reports: the monthly SEMI Billings Report, which offers a perspective of the trends in the equipment market; the monthly Worldwide Semiconductor Equipment Market Statistics (WWSEMS), a detailed report of semiconductor equipment billings for seven regions and 24 market segments; and the SEMI Semiconductor Equipment Forecast, which provides an outlook for the semiconductor equipment market. More information is also available online: www.semi.org/en/MarketInfo/EquipmentMarket.

By Walt Custer, Custer Consulting

SEMICON Europa 2017 and productronica were co-located November 14 to 17 at Messe Munchen in Munich, Germany. Attendance was very good and the mood was upbeat.

The third quarter of this year has seen broad growth both globally and also for the European electronic supply chain.

Chart 1 shows 3Q’17/3Q’16 growth by electronic sector for the world. SEMI and PCB process equipment and semiconductors stand out but almost all key sectors expanded.

Custer-Chart-1-Global-Elec-

Chart 2 shows third quarter growth for Europe.  SEMI equipment leads but the third quarter Eurozone expansion was broad based.

Custer-Chart-2-EUropean-Ele

At productronica, Custer Consulting presented at the “Business Outlook for the Global Electronic Supply Chain” event (with emphasis on Europe).  For a copy of Walt’s charts, please email [email protected].

GLOBALFOUNDRIES and Ayar Labs, a startup bringing optical input/output (I/O) to silicon chips, today announced a strategic collaboration to co-develop and commercialize differentiated silicon photonic technology solutions. The companies will develop and manufacture Ayar’s novel CMOS optical I/O technology, using GF’s 45nm CMOS fabrication process, to deliver an alternative to copper I/O that offers up to 10x higher bandwidth and up to 5x lower power. This cost-effective solution is integrated in-package with customer ASICs as a multi-chip module, and improves data speed and energy efficiency in cloud servers, datacenters and supercomputers. As part of the agreement, GF has also invested an undisclosed amount in Ayar Labs.

Modern data centers and cloud applications require high-performance, power-hungry chips to process and analyze huge volumes of data in real time. Growth in chip I/O capabilities has not matched exponential increases in computing power, because of physical limitations in electrical data transmission. Optical I/O, which leverages optical components on the CMOS die to transmit data at rapid speeds, will be a key enabler to overcoming the limitations of today’s data center interconnects. In addition, Ayar’s technology reduces power consumption at both the network and processor level.

“GF has demonstrated true technology leadership in recognizing optical I/O as the inevitable next step as we move into a More than Moore world,” said Alex Wright-Gladstein, CEO at Ayar Labs. “This collaboration between Ayar and GF could improve chip communication bandwidth by more than an order of magnitude and at lower power, and is a validation of Ayar’s viability in the current semiconductor ecosystem. This collaboration will unlock a larger market opportunity, expanding both our and GF’s customer base. We look forward to working with GF to help solve the interconnect problems of today’s chips and create greater value for our customers than if both companies worked independently.”

“The Ayar Labs team has been designing cutting-edge silicon photonics components on GF’s technology for the past eight years and has achieved exceptional results,” said Mike Cadigan, senior vice president of global sales and business development at GF. “Our strategic collaboration builds on our relationship, leveraging GF’s silicon photonics IP portfolio and our world-class manufacturing expertise to enable faster and more energy-efficient computing systems for data centers.”

The collaboration brings together Ayar Labs’ patented IP in optical technology with GF’s best-in-class expertise in silicon photonics to co-develop optical solutions that will be fabricated using GF’s process technology. The availability of this technology, including certain Design IP cores, will enable internet service providers, system vendors and communication systems to push data capacity to 10 Tera bits per second (Tbps) and beyond, while maintaining the low energy and cost of optical-based interconnects.

The ConFab 2018, to be held at The Cosmopolitan of Las Vegas on May 21-23, is thrilled to announce the newest opening day Keynote speaker, Professor John M. Martinis. John is a Research Scientist who heads up Google’s Quantum AI Lab. He also holds the Worster Chair of Experimental Physics at the University of California, Santa Barbara. The lab is particularly interested in applying quantum computing to artificial intelligence and machine learning, and as one of Google’s quantum computing gurus, John shared the company’s “stretch goal”. That is to build and test a 49-qubit (“quantum bit”) quantum computer by the end of this year. The test will be a milestone in quantum computer technology.

The conference team is also very excited to have IBM distinguished Engineer, Rama Divakaruni – who is responsible for IBM Advanced Process Technology Research – present his Keynote Address: How Artificial Intelligence is driving the “New” Semiconductor Era. Both Keynotes, set for May 21, promise to be outstanding presentations.

Additional outstanding speakers at The ConFab 2018 include:

  • Dan Armbrust, CEO and Co-founder of Silicon Catalyst will present: “Enabling a Startup Ecosystem for Semiconductors” describing the current environment for semiconductor startups.
  • George Gomba, GLOBALFOUNDRIES VP of Technology Research will discuss the EUV lithography project with SUNY Polytechnic Institute now finding its way into advanced semiconductor manufacturing.
  • John Hu, Director of Advanced Technology for Nvidia – John heads up R&D of Advanced IC Process Technologies and programs, Design For Manufacturing, Testchips, and New technology/ IC product.
  • Tom Sonderman, President of Sky Water Technology Foundry will focus on smart manufacturing ecosystems based on big data platform, predictive analytics and IoT.
  • Kou Kuo Suu of ULVAC Japan will delve into manufacturing various types of NVM memory chips, including Phase-Change memory (PCRAM).

More industry experts adding to the conference will be announced soon.  Further event details are available at: www.theconfab.com.

The semiconductor industry continued its upward trend in the third quarter of 2017, notching 12 percent sequential growth with strength across all application markets, according to IHS Markit (Nasdaq: INFO). Global revenue totaled $113.9 billion, up from $101.7 billion in the second quarter of 2017.

As memory prices remain high and the wireless market continues to see strong demand through the fourth quarter, 2017 is shaping up to be a record-breaking year for the semiconductor industry. IHS Markit projects that semiconductor revenue will reach a record-high $428.9 billion in 2017, representing a year-over-year growth rate of 21 percent.

Key growth drivers

All application end markets posted sequential growth over the prior quarter, with wireless communications and data processing categories leading the pack.

Revenue from wireless applications grew faster sequentially in the third quarter of 2017 than any of the other high-level application markets. Semiconductor revenue from wireless applications was a record high $34.8 billion in the third quarter, representing nearly 31 percent of the total semiconductor market. IHS Markit anticipates an even bigger fourth quarter for wireless applications, projecting $37.5 billion in revenue — and more than $131 billion for the full-year 2017.

As the wireless market evolves, this growth can be attributed to a number of factors. ”More complex and comprehensive smartphone systems on a chip are supporting applications such as augmented reality and computational photography,” said Brad Shaffer, senior analyst for wireless semiconductors and applications at IHS Markit. “Premium smartphones have increasing amounts of memory and storage. The radio frequency content in these smartphones has also grown considerably over the past few product generations, with many high-end smartphones now supporting gigabit LTE mobile broadband speeds.”

The memory markets proved once again to be the driving force and highest-growing segment for semiconductors in the third quarter of 2017. “The DRAM industry had another record quarter with $19.8 billion in revenue, exceeding the prior record by more than $3 billion,” said Mike Howard, director for DRAM memory and storage research at IHS Markit. “Prices and shipments were up during the quarter as strong demand for mobile and server DRAM continued to propel the market.”

Top_5_memory

The NAND industry had another record quarter as well, growing 12.9 percent in the third quarter of 2017, with total revenue reaching $14.2 billion. “Pricing was flat in the quarter, as seasonally strong demand driven by the mobile and solid-state drive segments was able to offset moderate shipment growth,” said Walter Coon, director for NAND flash technology research at IHS Markit. “The market is expected to soften exiting 2017 and into early next year, as the industry transition to 3D NAND technology continues to progress and the market enters a traditionally slower demand period.”

Manufacturer moves

Samsung officially passed Intel to become the number-one semiconductor supplier in the world in the third quarter of 2017, growing 14.9 percent sequentially. Intel now comes in at number two, with SK Hynix securing the third rank in terms of semiconductor revenue for the third quarter.

top_5_semiconductor

Among the top 20 semiconductor suppliers, Apple and Advanced Micro Devices (AMD) achieved the highest revenue growth quarter over quarter by 46.6 percent and 34.3 percent, respectively.

There was a good deal of market share movement within the top 10 suppliers throughout the third quarter as well. In terms of semiconductor revenue, Qualcomm surpassed Broadcom Limited to secure the number-five spot, while nVidia made its way into the top 10 ranking for the first time ever. At this time last year, the top five semiconductor companies controlled 40 percent market share of the entire industry. The top five gained 4.2 percent more market share this year over last year, while comprising three memory companies instead of the previous two.

More information on this topic can be found in the latest release of the Semiconductor Competitive Landscaping Tool (CLT) from the IHS Markit Semiconductor Competitive Landscape CLT Intelligence Service.

Micron Technology Inc. (Nasdaq:MU) today announced that the company has appointed Derek Dicker as vice president and general manager of the Storage Business Unit.

In this role, Dicker will be responsible for leading and expanding Micron’s solid-state storage business. This includes building world-class storage solutions to address the growing opportunity in large market segments like cloud, enterprise and client computing. He will report to Sumit Sadana, Micron’s executive vice president and chief business officer.

Dicker has 20 years of experience in the semiconductor industry, including sales, marketing and executive roles at Intel, IDT, PMC-Sierra and Microsemi Corporation. Most recently, he served as vice president and business unit manager of performance storage at Microsemi, where he led a global organization and drove all general management functions.

“Derek’s deep technical expertise and experience in the storage industry make him the ideal choice to lead our storage business,” Sadana said. “His strategic mindset, coupled with his outstanding track record of business leadership, will help us fully capitalize on our leading-edge NAND technologies and solutions.”

Dicker holds a bachelor’s degree in computer science and engineering from the University of California, Los Angeles.

 

SiFive announced today that it has joined GLOBALFOUNDRIES’ FDXcelerator Partner Program, and will be making RISC-V CPU IP including SiFive’s E31 and E51 RISC-V cores available on GF’s 22FDX process technology. Based on the open source RISC-V ISA, the SiFive E31 offers embedded chip designers new capabilities in high performance within strict area and power requirements, and the SiFive E51 offers a full 64-bit performance at 32-bit price, power and area.

“As the RISC-V ecosystem continues to grow, SiFive’s leading CPU IP is seeing increased adoption. Our partnership with GF is going to enable an even larger pool of system designers to build on an industry-leading process platform,” said Naveed Sherwani, CEO, SiFive. “SiFive has led the RISC-V ecosystem from early on and we are excited to continue extending RISC-V into new market segments.”

“As members of the RISC-V Foundation, we are excited to see more RISC-V IP offerings made available on our processes,” said Gregg Bartlett, senior vice president of CMOS business at GF. “SiFive’s wide range of cores makes them an ideal partner for our FDXcelerator program.”

GF’s FDXcelerator Program brings together select partners to integrate their products or services into validated, plug-and-play design solutions, giving customers access to a broad set of quality offerings specific to 22FDX technology. The program’s open framework enables members to minimize development time and cost while simultaneously leveraging the inherent power and performance advantages of FDX technology.

North America-based manufacturers of semiconductor equipment posted $2.02 billion in billings worldwide in October 2017 (three-month average basis), according to the October Equipment Market Data Subscription (EMDS) Billings Report published today by SEMI.

SEMI reports that the three-month average of worldwide billings of North American equipment manufacturers in October 2017 was $2.02 billion.The billings figure is 1.8 percent lower than the final September 2017 level of $2.05 billion, and is 23.7 percent higher than the October 2016 billings level of $1.63 billion.

“Equipment billings dipped in October, the fourth consecutive monthly decline during this record spending year,” said Ajit Manocha, president and CEO of SEMI. “In spite of this seasonal weakness, we expect equipment spending to increase by 30 percent or more this year and are positive about growth in 2018.”

The SEMI Billings report uses three-month moving averages of worldwide billings for North American-based semiconductor equipment manufacturers. Billings figures are in millions of U.S. dollars.
Billings
(3-mo. avg)
Year-Over-Year
May 2017
$2,270.5
41.8%
June 2017
$2,300.3
34.1%
July 2017
$2,269.7
32.9%
August 2017
$2,181.8
27.7%
September 2017 (final)
$2,054.8
37.6%
October 2017 (prelim)
$2,017.0
23.7%

Source: SEMI (www.semi.org), November 2017

 

Leti, a technology research institute of CEA Tech, announced that Emmanuel Sabonnadiere has been named CEO, succeeding Marie-Noelle Semeria.

Emmanuel SABONNADIERE P_ Jayet-CEA-010Sabonnadiere, who has more than 25 years of executive leadership experience in a variety of large technology environments, joins Leti from CEA Tech, where he led the industrial-partnership program. He brings a strong background in new-technology development with broad private-sector expertise in operational excellence, team building and guiding multicultural organizations in business transformation in Europe and globally.

As Leti’s chief executive officer, Sabonnadiere leads the activities of one of Europe’s largest micro- and nanotechnologies research institutes, which employs approximately 1,900 scientists and engineers, has a portfolio of 2,700 patents and has launched more than 60 startups.

“Success in today’s demanding international digital landscape requires a combination of deep technological expertise, advanced platforms, a commitment to customer and partner success and a shared excitement and agility about the new opportunities,” Sabonnadiere said. “This is where Leti is today, and I am very excited to join this world-class team to develop the solutions that will bring digital innovations to the benefit of leading technology companies around the world.”

Prior to joining CEA, Sabonnadiere was CEO of the Philips Lighting’s Business Group Professional in Amsterdam. From 2008 to 2014, he was CEO and chairman of General Cable Europe in Barcelona, and from 2005 to 2008 he served as CEO of NKM Noell in Wurzburg, Germany. Before that, he served as vice president of Alstom T&D for five years. Early in his career, he held multiple positions at Schneider Electric, including managing director of development for equipment units.

During his career, he has designed and implemented strategic plans for process optimization, product redesign-to-costs, market repositioning and system development.

Sabonnadiere holds a Ph.D. degree in physics from the Ecole Centrale de Lyon, an MBA degree from Ecole Supérieure des Affaires de Grenoble and an engineering degree in information technology from the Université Technologie Compiègne.

Sabonnadiere is a fully qualified instructor at the ski school in Les Ménuires, and member of the advisory board of IAC.