MEMS and image sensors are shining stars in the chip industry as technology companies worldwide accelerate innovation in the fight against COVID-19. The tiny devices are behind advances in areas of electronics ranging from thermal imaging and faster point-of-care testing to microfluidics-based polymerase chain reaction (PCR) tools and techniques to detect SARS-CoV-2.SEMI recently spoke with Yole Développement analysts Dimitrios Damianos and Chenmeijing Liang about MEMS and imaging sensors market trends and how microelectronics-enhanced technologies are supporting the worldwide push to contain the spread of COVID-19.For additional insights on the technologies, join the SEMI MEMS Imaging Sensors Summit, held for the first time at SEMICON Europa, 12-13 November 2020 in Munich, Germany. Registration is open.SEMI: Despite the global pandemic, the MEMS and sensors market is still growing and is one of the healthiest industries, not only in Europe, but globally. What is driving this growth?Damianos: MEMS have been continuously evolving from the first sensors that were measuring pressure and acceleration to rotation sensing and visible light management followed by light sensing beyond visible and the expansion to ultrasound and multi-spectral. Now we are heading towards an era where we want to sense every aspect of our environment, with more processing and eventually analytics bringing more quality to the data.COVID-19 has impacted various global markets in very different ways. While automotive, mobility and civil aviation have suffered, the impact on telecommunications and medical has been positive. The effects on the consumer, mobile and industrial markets have been moderate. Moreover, COVID-19 is changing the perception of the current global supply chain in manufacturing, potentially leading to more localized value chains and further regionalization in order to minimize similar risks posed by the pandemic and the first lockdown.SEMI: Who are the main MEMS players based on your research? Damianos: For MEMS players, the picture in 2019 was not the same as 10 years ago, when Texas Instruments (TI) and Hewlett-Packard (HP) were leading the scene, with Bosch and ST Microelectronics following, all at comparable revenue levels. Now, Broadcom and Bosch lead with almost $1.4 billion in revenue each, and the rest of the MEMS key stakeholders compete in the $400 million to $600 million league. Microphone players profited from the voice interface adoption trend, while players active in MEMS for mobility and smartphones suffered slightly due to weak end-system demand.SEMI: What scenarios can we expect for each market with regard to the impact of COVID-19 on MEMS for 2020? Damianos: For 2020, at Yole Développement we expect the consumer market to contract slightly by 2.6%, with the automotive market to dip by 27.5%, and defense and aerospace by 20.5%. For the defense market, no major effect is expected, as all major programs still run for the year. The market may experience some slight delays in deliveries due to supply chain and logistics problems. However, sensors integrated in commercial/civil aerospace applications will suffer due to the general paralysis of the air travel industry. On the positive side, telecommunications could increase by 4.7%, medical applications by 10.6%, and industrial by 11.5%.Due to the global pandemic, some types of MEMS have spiked in demand this year. For example, demand for thermopiles and microbolometers used in temperature guns and thermal cameras has increased because of the need for contactless monitoring of people’s temperatures. Moreover, microfluidics for DNA sequencing and real-time polymerase chain reaction (PCR) diagnostic tests for detecting COVID-19 are gaining market relevance, with the latter serving as a premier method of detecting a bacteria or virus on the molecular level with high degrees of accuracy. Furthermore, pressure and flowmeters in ventilators will grow because of huge demand by hospital intensive care units (ICUs).SEMI: What growth trends do you predict for the long haul?Damianos: In the longer term, we expect global MEMS volumes to almost double, from 24.4 billion units in 2019 to 50.8 billion units in 2025, with a 13% CAGR during the same period. The global MEMS market could reach $17.7 billion in revenue by 2025.We see a trend to more wearable devices integrating a lot of sensors but also a move to a more consumer-oriented healthcare. Moreover, everything related to voice interfaces and voice/virtual-personal assistants (VPAs) will continue to see strong growth, increasing demand for MEMS mics with better quality and high-fidelity voice capture. MEMS devices are shifting to higher accuracy, ultra-low power, embedded intelligence and possibly some bio-compatibility for medical applications.MEMS players will try to escape the commoditization cycle and deliver more value by increasing the value of the data, either grouping many sensors to create sensor hubs or by adding processing, algorithms and software. Industry players are employing strategies such as adding extra processing close to the sensor (e.g. Knowles) or ameliorating the use cases of their applications of their clients (e.g. Bosch or ST). AI on the edge seems very alluring for extra value acquisition, with many startups already working on it. Some examples include always-on-sensing (Aspinity in collaboration with Infineon, Syntiant), echolocation (IMERAI) and predictive maintenance using inertial sensors (Cartesiam). This will be the next pit stop for MEMS technology for sure. SEMI: The CMOS Image Sensor (CIS) is a cornerstone technology in the development of devices powered by machine sensing and artificial intelligence (AI) for applications such as advanced driver assistance system (ADAS). CIS powers many of the ongoing revolutions in new technical products and use cases. What is the status of the image sensors industry? Liang: Last year was exceptional with a combination of high demand and high prices due to capacity limitations. Q4 2019 went way above the forecast, and, in the end, the CIS industry reached $19.3 billion for the full year. This year, we think it will return to normal, and, despite the pandemic impact, we expect significant growth in the range of 7% to 12%. Last year’s 25% year-over-year (YOY) growth was the highest we’ve seen over the past decade. Mobile still dominates the marketplace for CIS with 69% market share. Two markets, computing (8%) and consumer (5%), are adjacent to the mobile market but progressively losing ground due to the smartphone disruption.Security, at 6% market share, will probably be the second largest CIS market in the future. Although this is an area of excellence for the emerging Chinese players, unfortunately, they could be hit by the current trade war. The automotive market did very well from 2018 to 2019 because of the numerous applications recently developed for ADAS, viewing, and in-cabin applications. Lastly, the industrial camera applications benefited from large investments in automation, especially in the semiconductor and automotive industries, but here again many uncertainties remain as these markets will reshuffle in the post COVID-19 world. SEMI: Which CIS markets are most susceptible to seasonality and the impact of COVID-19?Liang: According to our quarterly CIS monitor, automotive and security were both negatively impacted by the pandemic beyond what we expected in terms of seasonality. For computing, the situation improved just prior the lockdown. Q1 got a positive impact with high sales results for laptops and tablets, but no significant impact was seen for security equipment. For automotive, the demand for cameras was very high in Q1, which is seasonally normal, despite the decrease of car shipments that followed later. The automotive CIS market in 2020 should remain relatively flat compared to 2019 due to the higher attachment rates of cameras despite the lower number of cars produced. Consumer and industrial segments dropped in Q1, which is typical early in the year.The next five years might be a bit slow, and although we forecast growth for the next year, in the future the market share will be lower in mobile. In fact, mobile CIS growth will fall below the CIS growth average, but we will see an increase of market share for the security, automotive and industrial segments. The CIS market could reach $28 billion in 2025.At first, COVID-19 had a limited impact on the production side, as factories in China are usually closed for the New Year holiday, when the pandemic started. While supply is currently recovering, we still consider the limited impact on demand. Smartphone production for 2020 will be down 6%, but camera shipments for mobile should increase about 10% this year. Another positive trend for the mobile market is optical fingerprint implementation. Currently, high-end Android phones use this kind of technology. For 2023, we estimate optical fingerprint technology revenue to be over $1 billion.The roadmap for the automotive market is driven by camera proliferation. We’ll see 10 cameras per car and more for some high-end vehicles. Increasing demand for safety and convenience will mean more cameras per car in the future. With a strong attachment rate, the market average in automotive is around 2.0 cameras per car nowadays, and we expect the market average to reach 3.5 cameras per car in 2025. In security, Charge Coupled Device (CCD)-based cameras are nearly out of the market, as CMOS-based IP cameras are most important now.SEMI: What are current key technology trends?Liang: 3D semiconductor technology is the hot topic. CIS wafer staking technology is indeed at the center of the CIS technology race. Future applications could be AI analytics or recently developed applications on new types of CIS. So far, we have seen the introduction of variants of the CIS pixel. Global shutter (GS) and indirect Time of Flight (iToF) were recently introduced, and now direct time-of-flight (dTOF) pixels are being used in high volume. 3D semiconductor technology is a bonanza for the industry, as it allows to pack more value in a single chip. While the surface of silicon is still increasing, additional silicon is added through stacking.With COVID-19 still a problem, the endpoint for smartphones in 2020 remains uncertain. The short-term impact for CIS will be slower growth with respect to the 25% YoY of last year. The downturn in car production will be mitigated by an increased attachment rate for automotive cameras. The security market will also help maintain CIS growth.For more insights, see the following reports: Status of the MEMS Industry 2020 3D Imaging and Sensing 2020 CIS Market Monitor Q2 2020 Dimitrios Damianos is a technology and market analysts at Yole Développement covering MEMS, Sensors, Photonics and Imaging. Chenmeijing Liang is a technology and market analysts at Yole Développement covering Imaging. Serena Brischetto is senior manager of Marketing and Communications at SEMI Europe.

So far the semiconductor industry is outperforming most other manufacturing sectors. Semiconductor capital equipment shipments were up 23% globally in 2Q’20 vs. 2Q’19 and semiconductor chip 3/12 growth is still in positive territory. However there are signs of slowing.

At UES, Inc., our 300 employees faced a myriad of productivity, logistics, and communication challenges as we responded to COVID-19 yet we continued our work uninterrupted to deliver scientific research and technical expertise to the Department of Defense (DoD). We focus on several disciplines including materials science, aerospace power and propulsion, bio and nanoscale technologies, surface engineering, photonic and electronic technologies, additive manufacturing, and product development.UES is also an active member of SEMI Nano-Bio Material Consortium (NBMC), a public-private partnership with Air Force Research Laboratory (AFRL), and has been a part of the organization since its inception in 2013. Dr. Stephaney Shanks, Director of our newest division, Integrative Health and Performance Sciences (IHPS), is currently acting as the NBMC Governing Council Chairperson. IHPS is setting the standard for high-level research in the Air Force Research Laboratory’s 711th (711 Human Performance Wing) and beyond.Its areas of focus include advancing marker discovery in air and biofluids, sensor development, evaluating microbiomes for health and performance, toxicology, industrial hygiene, and high-throughput screening for genetic and chemical exposure. Most of our employees work at the Air Force Research Laboratory (AFRL) at Wright-Patterson Air Force Base, which is offsite of our corporate headquarters and product development labs.Here are some examples of how our COVID-19 response efforts have not only worked, but helped us thrive during this difficult period, enabling us to continue our vital research for the Air Force and our product innovation work in our corporate labs.1. Pursuing Research Projects to Support COVID-19 SolutionsStaffed primarily by scientists and engineers, UES holds a distinct position in supporting the fight against COVID-19. Our entire organization strongly supports finding solutions to the problems brought on by the pandemic to make life safer for everyone.With our AFRL partners and in our UES labs, we pursued new proposals and began projects to combat the pandemic’s problems. We’re developing rapid devices for detection of breath biomarkers that may indicate COVID-19 infection status to provide non-invasive testing capabilities. We are also pursuing point-of-care devices for real-time assessment of COVID-19 outside of the clinical environment, and we are developing models of the protein spikes of SARS-CoV-2 that could be used to further improve detection capabilities.UES also extended active research toward COVID-19 patient transport on cargo aircraft. We have been working with the 711 HPW to develop computational models to evaluate biological agent dispersal in cargo aircraft.UES is conducting research into the biological agent dispersal patterns in cargo aircraft. 2. Enacting an Effective Work-from-Home Policy and FormatBefore the pandemic, most of our employees did not have the option to regularly work remotely. However, by the end of March 2020, UES needed to respond to both DoD and Ohio government orders to stay at home. This presented new challenges. How do we keep laboratory/bench-based staff working? How do we keep all staff mentally engaged while teleworking?As luck would have it, we moved to Office 365 in February. That technology rollout proved to be a significant advantage in our COVID-19 response. Employees maximized their use of Microsoft Teams by sharing files, collaborating, using chat functions, and hosting video meetings. UES also utilized GoToMeeting for larger group meetings and real-time group file sharing/editing.By late March, our management team provided a tracker file in Excel format for all employees to document daily technical progress. This proved to be an excellent method to track projects, monitor staff COVID-19 symptoms or exposure, and record work location as the AFRL and UES labs began to allow small teams to return. This also kept managers in touch with employees on a weekly basis about ongoing work. It not only created extra layers of accountability, but also demonstrated progress and achievements week to week.Microsoft Office 365 has proved its usefulness to UES during the pandemic. 3. Offering Support to Employees and the CommunityThe overall wellness of our employees and the Dayton region is part of our mission at UES. As we resolved logistical issues and reshaped how we collaborated and delivered results, our leadership team began to focus on how to best support employees and our local community. A few activities supported this effort: We provided masks to all employees, along with an informational visual guide for best practices in wearing and caring for a mask. Safety has been a top priority for all employees. We started offering virtual Coffee Talks and Happy Hours. These company-wide online meetings gave employees a chance to reconnect and share concerns. We also shifted our Fitness Classes to an online format. We utilized our social media channels to engage with employees and share resources. We allocated community support to vulnerable populations (food banks and a domestic violence center). UES gave corporate donations, as well as shared non-financial ways to support the community with employees. This pandemic has brought plenty of challenges, but we're impressed by everyone's innovation and resilience. Every UES team member played an active role in adapting, not just to continue their daily work, but to be a part of the solution and support the community.UES used social media to share remote working tips with employees. Dr. Nina Joshi is president and CEO of UES, an award-winning innovative science and technology company based in Dayton, Ohio that provides its government and industry customers with superior research and development expertise, world-class technical support and value-added management services. A unique philosophy emphasizes passion for advancing science, dedication to superior service and commitment to enhancing careers. Contact the company here.

To attract and cultivate new talent across the microelectronics industry, virtual SEMICON West 2020 offered wide-ranging career insights for engineering students seeking that vital first job and young employees embarking on their careers. They learned about overcoming challenges at work and gained a competitive edge by connecting with industry leaders for insider knowledge. These are just some examples of how the SEMI Foundation and the SEMI Workforce Development and Diversity, Equity and Inclusion (DEI) initiatives serve as a springboard to careers in the industry and help close its talent gap.Following are experiences of aspiring engineers at SEMICON West and career lessons presented to help them shape the future of our semiconductor industry.Jump-Starting Careers at SEMICON West 2020More than 600 students from over 50 colleges and universities across the Unites States joined SEMICON West 2020 to jump-start their careers in the semiconductor industry. With free access to SEMI’s first virtual expo, they connected with recruiters and companies in the exhibit hall, and sponged up insights from speakers about digital internships, job opportunities, and key trends shaping the digital future.“It was almost overwhelming,” said Jason Wong, 20, a junior at San Jose State University working toward an advanced degree in mechanical engineering. “It was kind of like an engineering student’s dream for contacts and knowledge all on one platform.”Wong visited about 15 booths in the online exhibit hall to speak with company representatives about his field of interest – microelectromechanical systems (MEMS).“MEMS is a pretty niche area, so it was really surprising how many companies were there in this category alone,” Wong said.Through the expo’s chat tool, Wong made some solid contacts and has followed up with several engineers via email, LinkedIn and Zoom meetings, cultivating what he believes will be “some long-lasting and valuable connections.”“I’m not really looking for a job at the moment, but I hope to get an internship at some point,” Wong said. “With the current (COVID-19) outbreak, a lot of events with opportunities to interact are no longer available, so this was an enlightening and useful experience for me I plan to attend again.”On the other side of the country in Virginia, Devayani Pawar, 23, found it easy to network at SEMICON West. She especially appreciated the free pass for students and practical sessions in the Smart Workforce Pavilion tailored to help early-career job seekers find opportunities, build contacts, and polish resumes.She was drawn to the Smart Manufacturing Pavilion because of her skills and interests in toolmaking and wafers.“I understand manufacturing and it’s a hot field right now,” said Pawar, who recently earned her master’s degree in data science from George Mason University. “It’s interesting to me how such tiny components can do so much powerful work.”“A lot of people my age aren’t very aware of the microchip industry – they’re mostly focused on information technology and companies like Google, Amazon, or Facebook,” Pawar said.After landing an internship at Micron Technology analyzing wafers and working in clean rooms, she was wowed by the potential of nanotechnology. Pawar learned about the strong demand for data scientists in semiconductor manufacturing. After making connections at SEMICON West and absorbing information, she now has a better handle on career opportunities.“The recruiters and other contacts I made have been so responsive, and now I have a better understanding of use cases and what companies are seeking,” she said.A Day in the Life of an EngineerRight after college in 2017, Erika Gabrielle Hansen joined Applied Materials as an engineer. She told management she wanted to travel, learn about the “big picture” behind the company’s products, and work with customers.In her presentation A Day in the Life of an Engineer at the SEMICON West Smart Workforce Pavilion, she recalled a whirlwind of unforeseen opportunities, soul-searching challenges, and the rewards of personal, professional, and community growth. She also candidly shared lessons learned about pride, collaboration, and resilience.Her journey began when she had the opportunity to share her aspirations for her at career at Applied and landed a dual role as a process engineer and customer account technologist.In her job as a process engineer, Hansen puts her materials engineering degree from Cal Poly, San Luis Obispo to good use analyzing data, solving technical problems, developing new processes to meet customer requirements, and working with cutting-edge technologies. At one moment she might be in a clean-room laboratory wearing a bunny suit doing hands-on work with tools. In another, she could be videoconferencing with hardware, software, and systems engineers worldwide, or preparing a report for upper management.“I was very nervous at first as a process engineer,” Hansen said. “I was the only person in my group who didn’t have a Ph.D. and tried to compensate for that by doing things on my own and not asking for help.”After making a few mistakes, she began to turn to her team for their expertise and sharing the results of her work – both good and bad – with them.“Having humility to ask for help and not let pride get in the way was a huge learning point for me,” she said.As a customer account technologist, she has made a dozen trips to customer sites in four countries to implement new processes or resolve technical issues. By seeing tools in action, she now has what she calls a “whole picture” perspective on their effectiveness, while enjoying the camaraderie of colleagues and sampling local cuisines, sites, and scenes around the world.At one point, she was assigned to lead an international team to resolve an issue with a major customer – her greatest challenge yet and her first time in such a role. She struggled to overcome language barriers and eventually told her boss she might not be the best person to lead the project. He promised to provide more support, and her team went on to resolve the customer’s problem.“I picked myself up, reached out to people with international experience, and changed my communication style,” Hansen said. “I learned it’s okay to be uncomfortable, to flex my leadership style, and be resilient, which is a learned skill.”Building a Better Network: Crucial ConnectionsAndrew Carnegie, one of history’s richest industrialists and most generous philanthropists, said 85 percent of a person’s success is based on “interpersonal relationships” and “abilities to be a human being.” Professional skills account for just 15 percent of success.While advancing to her current role as Chief Marketing Officer for FormFactor, Amy Leong found this advice critical to her career trajectory. Just like the challenge of raising a strong family, building a successful career “takes a village… you can’t do it alone,” she said in her Smart Workforce Pavilion presentation Building a Better Network: Crucial Connections.Outperforming expectations might be essential early in one’s career to get promotions, raises, and the attention, but that mindset goes only so far.“As seniority levels increase, people already know you’re a phenomenal performer and expect nothing less,” Leong said. “So, the higher you go the more vital it is to spend almost a disproportionate amount of effort on building relationships.”Building your network isn’t about the quantity of one’s business cards or LinkedIn connections; it’s about building quality relationships with mutual benefits over the long run.“We need to be smart about return on investment when building our professional network,” she said. “You help me, and I help you. It’s win-win horse trading.”And the most important factor in career success? For Leong, a strong family foundation has mattered most.“Family comes first,” said Leong, who has twin teenagers. “Take care of the ones you love. Check in with your family whenever you can. Family relationships are bound by blood. Thanks to my retired parents and a helpful husband, we tough it through.”She reemphasized the importance of mutually beneficial relationships, noting “A rising tide will lift all boats.”Fostering Talent for the Industry’s FutureDeveloping young talent and future leaders in microelectronics stands as a persistent and growing need – and a critical challenge to realizing expected growth. Emerging technologies such as artificial intelligence, quantum computing, and augmented/virtual reality are expected to impact a huge range of markets, leading to projections that the semiconductor industry will double in size in the next 10 to 15 years.The opportunities for growth and technologies that promise to improve the quality of human life worldwide are breathtaking. The industry’s talent pool will need to scale accordingly, magnifying the importance of expanding industry-wide programs such as the Workforce Development and DEI initiatives that the SEMI Foundation are building. Learn more about how you and your company can get involved with these initiatives on the SEMI Foundation website.Shari Liss is executive director of the SEMI Foundation. She oversees SEMI Workforce Development programs from K-12 through re-skilling for veterans.

Internships provide a wealth of benefits for students and corporate managers as they work side-by-side in a real-world environment. Students gain practical, hands-on experience and employers get an infusion of fresh energy, diverse ideas and eager talent.The full value of an on-site internship – the ultimate job interview – flowers when it leads to full-time employment.That was before “everything went crazy,” said Tina Revels, university relations manager at KLA, during her Smart Workforce Pavilion presentation The New Reality: Digital Internships at the virtual SEMICON West 2020. Today, amid COVID-19 restrictions, everyone must adjust to a new reality – a virtual reality. Part of this substantial shift has led to internships going digital.“Internships are more important than ever as we shift to a virtual reality,” Revels said, explaining how today’s job seekers and companies alike can make sure digital internships sustain the same mutual benefits as traditional ones.At companies turning to digital internships, managers need to do more upfront planning to re-create real-world experiences that make interns “feel engaged and connected with one another,” Revels said. For prospective interns, digital internships require greater independence, self-management discipline, and responsibility than traditional internships – all critical skills that can lead to permanent employment.Watch Revels’ full presentation below to learn how to get the most out of digital internships. Register for virtual SEMICON West 2020 to access the additional Smart Workforce and Diversity, Equity and Inclusion sessions, which covered dynamic topics such as job searches during uncertain times, creating a culture of inclusivity, supplier diversity, and hiring military veterans. The content is available until September 20, 2020.Learn more about the SEMI Foundation and how its Workforce Development and Diversity, Equity and Inclusion initiatives are helping build the electronics manufacturing and design supply chain’s talent pipeline.Bryson Gauff is program manager for SEMI High Tech U.

Japan’s semiconductor industry has weathered the COVID-19 pandemic to post robust growth. Far from a temporary setback, COVID-19 will lead to enduring change in how we work and live. And just as automation has been a bulwark against the devastating business impacts of the virus outbreak, increasing digitization will lead to new efficiencies in our industry.These were some of the key takeaways from three SEMI Japan Members Day webinars in June and July that offered the latest updates on COVID-19 impacts to the semiconductor industry and restart strategies for SEMI members. More than 2,000 SEMI members across Japan’s islands attended the webinars featuring the following five speakers: Hideki Kanewaka, Marketing Director, Consulting Lead, Japan, Accenture Japan Ltd. Takayuki Komori, Manager, Marketing Engineering Dept, SUMCO Corporation Taketoshi Hamaguchi, Director, Manufacturing Industry, Microsoft Corporation Akira Minamikawa, Senior Consulting Director, OMDIA (Informa Intelligence LCC) Yuichi Koshiba, Managing Director Partner, Boston Consulting Group COVID-19 Impact on Japan Semiconductor Industry is ModestThe consensus view of the five speakers from various quarters of the industry – consultant, IT service provider, materials supplier, market analyst – was that the Japan semiconductor industry withstood the heavy blows COVID-19 dealt to other industries thanks to strong demand for chips. Shelter-in-place policies and lockdowns spawned by COVID-19 has accelerated the digital transformation rippling around the world as electronics sales have soared to support everything from remote work and education to healthcare and home entertainment including gaming.The rapid growth of cloud usage for video streaming, gaming and remote work is taxing communications network capacity and placing more bandwidth demands on servers, said Akira Minamikawa of OMDIA. According to a recent report by Nokia, communications network traffic has skyrocketed 300 percent for online meetings and 400 percent for gaming, bringing the networks closer to their capacity limits. Minamikawa sees server shipments increasing at 8 percent CAGR through 2024. For the broader chip market, he expects demand for notebooks, solid state and hard disk drives, and gaming to remain strong in 2020. He also predicts rapid 5G penetration for smartphones will boost semiconductor chip industry growth.Still, not all semiconductor segments are expanding, said Yuichi Koshiba of Boston Consulting Group. Chip shipments for end products in markets such as automotive, industrial equipment and aircrafts are on the decline. Slowing demand for chips that power automotive applications in particular could pare sales for some chip companies and distributors since the segment accounts for a high proportion of their overall revenue.State of the Semiconductor IndustryFrom SUMCO’s vantagepoint as a major silicon wafer supplier, the company’s Takayuki Komori sees a number of changes unfolding in the semiconductor industry: Smartphones are driving growing demand for process technology (smaller nodes) and 300mm wafers. Komori estimates the typical high-end smartphone sports 1,700 square millimeters of silicon. 300mm wafers account for 80 percent of that total while more than 50 percent of the devices use leading edge multi-patterning technologies. Smartphones will need more RF chips to support 5G’s high-speed communications and added frequency ranges. Substrates for RF switches and tuners have been shifting from gallium arsenide (GaAs) and other compound semiconductors to silicon. 5G smartphone penetration will accelerate as the cost of integrating CPUs and modem functions into a single chip sees a swift decline. While the sensitivity and resolution of CMOS image sensors have evolved to incorporate innovative backside illumination and stacking technologies, future advances will focus more on products for machine vision applications capable of sensing invisible light bands. Rising adoption of electric vehicles and robotics applications will drive growing demand for power semiconductors that control their motors such as IGBTs and MOSFETs as the production capacity for the devices expands and shifts to 300mm wafer lines. For memory fabs, Minamikawa said utilization remains high as a result of a spending slowdown by major chip manufacturers and will stay elevated even once additional capacity ramps to support robust demand. Foundry fab utilization also remains high despite the pandemic-driven cancellation of smartphone chip orders in March. Minamikawa also sees the utilization rate of micro rising with the surge in demand for notebooks, PCs and servers in the second half of 2020.Transition to New NormalAs people around the world start to settle into new ways of living and working, there’s a growing acceptance that the transformation will be long-lasting. And no area of people’s lives is changing more than their work. Boosted by government subsidies, many small and midsize companies in Japan have started to implement work-from-home policies, an area where major electronics and IT businesses had already instituted reforms, said Hideki Kanewaka of Accenture. A few examples: Nippon Telegraph and Telephone Corporation (NTT) announced that half of its employees will continue to work from home in the future. A five-year plan Toshiba launched in 2019 to allow all employees to work from home will likely accelerate. Hitachi plans to allow all employees to work from home starting in April 2021. dwango, a major internet-based entertainment company in Japan, announced it will allow in principle any employees to work remotely. In the critical area of remote sales, Kanewaka pointed to the importance of going beyond online business meetings, paperless transactions and virtual events to devise new ways to attract customers and close deals. Creating online communities and providing rich digital content are also important measures to consider, he said.Manufacturing's Digital TransformationTravel restrictions by most countries to curb the COVID-19 outbreak have also raised barriers to chip companies sending engineers overseas sites to service state-of-art equipment and provide other technical support. Microsoft’s remote assist system deployed by ASML is one tool semiconductor makers can use to overcome this challenge, said Taketoshi Hamaguchi of Microsoft.The system connects a remote equipment service expert with an onsite worker through the internet, allowing the technical expert to provide support through a goggle display with a camera worn by the worker. Guided by the expert, the worker can perform complex services. A Natural User Interface (NUI) helps give the factory worker a clear understanding of the often highly technical instructions.Using artificial intelligence (AI) to increase automation will also help reduce the reliance of semiconductor factories on onsite workers. For example, AI deep learning can be deployed to calibrate equipment autonomously and reduce downtime after scheduled maintenances, Hamaguchi said.Corporate Restart Strategies Beyond factory considerations tied to COVID-19, semiconductor companies will need to adapt their business strategies to new ways of operating. For example, global supply chains will shift to domestic sources and increase redundancy to ensure a steady supply, a change leading to higher overall costs, Koshiba said. Trade routes among regions will also be redrawn as the trade rift between the United States and China and other geopolitical tensions intensify. The total value of those routes is expected to recover by 2023.Koshiba advised companies to evaluate the supply chain trade-offs between stability and cost and factor in potential risks to improve their short-term resilience and drive mid- to long-term supply chain restructuring.After past recessions, 14 percent of companies restored sales growth, Koshiba said. He recommended investing aggressively in growth and seizing M A opportunities during the downturn. Chip companies must also adapt to supply chain changes faster than competitors.Become a SEMI MemberWebinars like the recent SEMI Japan Members Day series have become increasingly important in the mix of programs and services SEMI offers members to help them connect, collaborate and innovate in the microelectronics community. To become a SEMI member, please visit the SEMI website or contact your nearest SEMI office.Jim Hamajima is president of SEMI Japan.

COVID-19 has forced all the players in the semiconductor manufacturing supply chain to reassess how much inventory they need to hold.

Tracking and quickly diagnosing COVID-19 infections, working from home and telemedicine recently came into sharp focus as technology executives and other subject matter experts from microelectronics heavyweights recently gathered for the first-ever virtual SEMI CTO Forum to explore how the microelectronics industry and their own companies can leverage future technology trends to drive growth. Themed Intelligent Medtech and Wearable Technologies, the forum drew CTOs from ARM, Babblelabs, Brewer Science, Dell, Dow/Dupont, E-Ink, Hewlett Packard Enterprise, Intel, Lam Research, KLA, Microchip, ON Semiconductor, Qualcomm, Tokyo Electron, Ulvac, Veeco and Xilinx. The event is designed as a strategic driver of pre-competitive innovation. Following are key takeaways from the forum. Microfluidics Promises to Speed COVID-19 Diagnosis More than 240 companies worldwide are developing microfluidics solutions to improve diagnosis and treatment of COVID-19 and other conditions, said forum speaker Dr. Kurt Petersen, a member of Band of Angels, Silicon Valley's oldest angel investment group, with an illustrious background1 in technology. And their innovations are bearing fruit. Cepheid, a company founded by Dr. Petersen, has developed a disposable microfluidic cartridge, Xpert Xpress SARS-CoV-2, used by doctors to swab the inside of a patient’s mouth. Highlighting the vital role of MEMS in medical electronics, the tiny powerful devices are behind a test that can detect COVID-19 infection in under 40 minutes. Dr. Petersen also cited a few examples of implantables and injectables under development, including: In vivo chemical sensing: Profusa developed a continuous glucose monitoring sensor via an optical patch. Glaucoma pressure monitors: Injectsense built a silicon chip the size of a grain of rice that is embedded in the eye to measure eye pressure. Retinal implants: Second Sight implanted a 60-electrode array chip that projects images onto the retina to improve vision. Microelectronics Takes Aim at Battling COVID-19 The event’s CTO roundtable, a platform for discussing societal and technology issues, revealed microelectronics technology will likely give rise to solutions for combatting pandemics and new business opportunities both in the short and long run. Areas of the greatest interest included: Tracking and Security: Infection tracking accuracy is key to limiting the spread of viruses yet comes with inherent privacy and security challenges. The consensus view of the executives was that developing trusted hardware capabilities is critical for adoption of accurate infection-tracking technologies. Remote Operation: Executives expect working from home or the use of telehealth to continue building momentum long after pandemic. To give staying power to the remote communications at the heart of these trends, microelectronics ecosystems will need to boost compute performance, both at the edge and in the cloud, while increasing bandwidth to enable applications such as augmented reality/virtual reality (AR/VR), artificial intelligence (AI), machine learning and advanced data analytics. Edge intelligence: The challenge of remote communications spans both people and the Internet of Things (IoT). Questions persist about how hundreds of billions of sensors will connect to the cloud and how much power they will consume. The need to push computing to where data is generated – at the edge – is rising and the necessary underlying technologies will only come by combining various forms of distributed computing and analytics. The microelectronics industry’s ability to seize these opportunities will only be possible with huge strides in innovation, raising concerns among the CTOs about the financial viability of cutting-edge devices because of increasing device complexity and R D costs. Technology partnerships and collaborations – an area where SEMI is contributing and will continue to expand its efforts as it works with the CTO community – will be critical to containing R D costs. SEMI will help the executives identify and mobilize the resources key to future innovation. Improving Home, Work Productivity and Experiences Key to AR Adoption Smart wearables also offer great promise. In just over a decade, AR and VR have grown from science fiction to practical uses such as AR applications for smart contact lenses, said Dr. Mike Wiemer, Co-Founder and CTO of Mojo Vision2. Dr. Wiemer said that while many AR applications remain under development, the technology will only see widespread adoption once it starts to improve productivity and efficiency at home and work and the quality of other experiences. The smart augmented reality contact lens developed by Mojo Vision is a step in that direction. The product’s built-in display gives users timely information about everything they see while remaining invisible by packing 70,000 pixels into a space smaller than a half a millimeter across, making it the smallest and densest dynamic display ever made. The contact lens is powered by an ARM-based processor, with later versions adding an image sensor, eye-tracking sensors and a communications chip. SEMI thanks EMD Performance Materials and Telit for sponsoring the CTO Forum. For more information on the CTO Forum and SEMI’s Smart Data-AI initiative, please sign up on our webpage. 1 Dr. Kurt Petersen is a member of the National Academy of Engineering, an IEEE Medal of Honor winner, and a Life Fellow of the IEEE for his contributions to the commercialization of MEMS technology. 2 Dr. Wiemer also co-founded Solar Junction, where he led technical teams to two world records in solar cell efficiency (43.5% and 44%). He also has patents and papers in Semiconductor Devices Applications, Silicon Photonics, Materials Integration, Lasers, Solar Cells, Solar Systems, and Analog Circuits. Tom Salmon is Vice President of Collaborative Technology Platforms at SEMI. Pushkar P. Apte, Ph.D., is Strategic Technology Advisor for the Smart Data AI Initiative at SEMI.