AI

In this episode of the SEMICON West 2021 Hybrid podcast series from 3D InCites, James Gellert, Chairman and CEO of RapidRatings- a financial health, data, and analytics company based in New York City- speaks about his keynote talk titled The Second Wave: Risk in Part Two of the Supply Chain Crisis.

SEMICON Europa, SEMICON West, SEMICON Japan, & SEMICON Taiwan welcome back exhibitors and visitors to show floors starting in mid-November as four of SEMI’s seven flagship events gather visionaries and industry leaders to explore the latest semiconductor trends and innovations by the end of 2021.

Dr. Mousumi Bhat, senior director of External Manufacturing at Micron Technology and first female member of the SEMI Southeast Asia Regional Advisory Board, discusses her passion for sustainable business practices and her work driving the transformation of Micron’s manufacturing plant in Singapore.

On April 21, 2021, the European Commission put forward the long-awaited Proposal for a Regulation on a European approach for Artificial Intelligence, introducing for the first time harmonized rules for the development, placement and use of secure and ethical artificial intelligence (AI) in Europe. The proposed regulation’s wide scope subjects providers, importers, distributors, and users of AI systems to regulatory scrutiny. It also includes providers and users outside of the European Union (EU) that deploy AI systems or use AI system outputs in the EU. With extraterritorial scope, the proposed regulation aims to further strengthen the EU’s leadership in shaping global standards and norms for new technologies. A European Path to Safe AI Following a risk-based approach, the proposed regulation classifies AI systems according to the level of danger they pose in the following categories: Unacceptable risk: AI poses unacceptable risk to systems or applications with the potential to manipulate human behavior and exploit vulnerabilities of groups of people to cause psychological or physical harm. Examples of prohibited AI systems include social-scoring systems and biometric identification that can be used by public authorities. High risk: The proposal identifies two main categories: AI systems used as safety components of products (or are a product themselves), and other stand-alone AI systems that have fundamental rights implications. Considering their intended purpose, the proposal identifies specific conformity assessment measures for both groups. AI systems intended to be used as security components will require a conformity assessment by an independent third party. Such systems will also be subject to the same ex-ante and ex-post compliance and enforcement mechanisms as products of which they are part. In contrast, stand-alone AI systems assessed through internal checks would require ex-ante compliance with all requirements of the regulation as well as with robust standards for quality and risk management and post-market monitoring. The proposed regulation identifies eight areas of high risk including AI systems in safety components of products (e.g., machinery, radio equipment, AI applications in robot-assisted surgery), critical infrastructures (e.g., transport), educational and vocational training (e.g., exam scoring) and employment (e.g., monitoring or evaluation of persons in work-related contractual relationships). Prior to their introduction to market, high-risk AI systems will be a subject to strict requirements including the use of high-quality datasets; adequate risk assessment and mitigation systems; high levels of robustness, accuracy, and security; clear and adequate user information; detailed system documentation and logging of activities to ensure traceability of results. Human oversight and control must be ensured. Low and Minimal risk: For limited-risk AI systems (e.g., chatbots), the regulation proposes only minimum transparency obligations, while minimal risk AI systems posing little to no risk (e.g., AI in spam filters) will not be regulated. Boosting AI Excellence from Lab to Market Continuous innovation of AI requires a secure environment that can support responsible validation of AI technologies. To that end, the proposal encourages the set-up of testing and experimentation facilities or so called AI regulatory sandboxes. Established by one or more Member States, the sandboxes will provide a controlled environment to test innovative technologies under strict oversight before their market introduction. These facilities could play an instrumental role in connecting the Europe’s R D ecosystem, creating new partnerships among numerous stakeholders. In addition to regulatory sandboxes, the European Commission intents to set up: A Public-Private Partnership (PPP) on AI, data and robotics designed to implement and invest in strategic research innovation and a deployment agenda for Europe Additional Networks of AI Excellence Centers to foster exchange of knowledge and advance collaboration with the industry Testing and experimentation facilities to test state-of-the-art technology Digital Innovation Hubs, one-stop shops to provide access to technical expertise and experimentation An AI-on-demand platform as a central European toolbox of AI resources (e.g., expertise, algorithms, software frameworks and development tools). Next Steps The proposed regulation is the at the start of a lengthy legislative process and will be debated by the European Parliament and European Council in the coming months. Given the importance of AI, and number of stakeholders involved, it is likely the proposed regulation will face various changes before being applied across the EU. For its part, SEMI Europe will maintain discourse with key public and private stakeholders on the proposed regulation, closely monitoring related policy developments as they unfold. Marek Kysela is senior coordinator of Advocacy at SEMI Europe.

The turn of the New Year means new opportunities for the microelectronic industry as SEMI continues to focus on a top priority for companies across the microelectronics design and manufacturing supply chain and SEMI members – supporting the development of the talent pipeline. Regardless of a member company’s role within microelectronics, ensuring a continued, robust flow of qualified talent for what is a cross-cutting, foundational industry sector is of high strategic importance. Skilled workers are essential to advances in areas such as artificial intelligence (AI), smart manufacturing, medtech, transportation and communications. In order to satisfy the world’s insatiable appetite for technology, we need a qualified workforce that can design and manufacture cutting-edge microelectronic devices. Launched in 2019 by SEMI’s Government Programs Office, SEMI Works™ is a holistic approach to developing and maintaining the talent pipeline. 2020 focused on building the all-important infrastructure, engaging member companies to identify required skills and developing a Unified Competency Model to catalog these workforce requirements. SEMI Works™ accomplished several firsts for the microelectronics industry: First dynamic, data informed workforce training standard adopted and published by the U.S. Department of Labor Employment Training Administration (USDOL-ETA) First SEMI Certified college program for technicians First Industry Approved Apprenticeship Program for Technicians, adopted and endorsed by the U.S. Department of Labor Member inputs anchor the SEMI Works™ portal, which enables connections among talent, employers and training/education providers. The portal’s initial phase of development is on track for completion in the first quarter of this year, marking the point when it will begin to be populated with specific job information, individual (talent) profiles and applicable training courses. Once SEMI Works™ is fully operational, it will be optimized to further support talent development and acquisition, providing a comprehensive platform for learning management, e-learning and career advancement. Throughout 2021 SEMI will be engaging members, training providers and job seekers to ensure the portal’s capabilities and user interface meets their needs. We’ll also move forward with several other SEMI Work’s programs including the Curated Content Initiative, which will enable SEMI members to identify non-proprietary courses, a SEMI member job board and an interactive career map to help job seekers plan their future in the industry. The microelectronics industry will only fulfill its tremendous promise for innovation and growth with the right talent. SEMI looks forward to working with members in 2021 to expand SEMI Works™ and help lay the groundwork for the next wave of technology advances. Mike Russo is vice president of Industry Advancement and Government Programs at SEMI.

While Artificial Intelligence (AI) emerged in the 1950s, only in recent years have AI applications proliferated with the explosion of data and continuing improvements in Moore’s law that have driven rising processing speeds. Voice assistants, image analysis software, search engines, and speech and facial recognition systems were among the first applications to use AI. Today, adoption has spread to sectors such as agriculture, cybersecurity, healthcare, software development, e-government and the intelligent enterprise to generate jobs and help spur economic growth. The Edge AI Opportunity and the Microelectronics IndustryAI can be embedded in hardware devices such as advanced robots, autonomous cars, drones or Internet of Things (IoT) applications. Today, according to the EU’s digital strategy, data centres and other centralized computing facilities account for the vast majority – 80% – of AI data processing and analysis, with smart connected objects such as automobiles, home appliances and manufacturing robots that bring the compute function closer to the user representing 20%. The latter, known as Edge AI applications, are powered by edge-based machine learning chipsets, not the AI chipsets designed to run cloud-based machine learning algorithms.The EU’s white paper on AI published in February 2020 anticipates that the way data are stored and processed for AI applications will change significantly over the coming five years as edge computing applications proliferate. Most AI applications need to connect with devices that collect data and manage data flows. When the applications connect with cloud infrastructures to train large volumes of data for a machine learning model, the interface devices often require hardware support. Edge AI can minimize data transport by processing data directly from local devices to accelerate data analysis and decision-making and make data transport or accelerator hardware unnecessary, critical in reducing power consumption and enhancing data security for applications such as autonomous driving. Over the past 40 years, the ICT sector has been continuously increasing greenhouse gas (GHG) emissions despite efforts to shift to renewable energy. Cloud-based AI applications require an ICT infrastructure for high-performance computing and high-speed connectivity. According to MIT Technology Review, data centres’ AI workloads could account for a tenth of the world’s electricity usage by 2025. a mass update of cloud-based AI applications may significantly increase energy consumption, unlike with Edge AI. This is why the strategy for developing Edge AI is well-aligned with the EU’s Green Deal objectives. Europe aspires to play a leadership role in Edge AI to strengthen the sector’s competitiveness and protect the European digital sovereignty. Europe’s strong industrial competencies in embedded systems and microcontrollers will help the region promote development of European domestic AI solutions for emerging high-value IoT applications in industrial processes such as Industry 4.0, Connected and Automated driving (CSA), smart cities, climate action, healthcare, and national defence and security. With this strong strategic position in technology, Europe is well-positioned to invest to become the leader in the Edge AI global market.Preparing the Workforce for the Microelectronics IndustryTo design and manufacture leading Edge AI chipsets, European education providers and industry will need to work closely together to train the current and future workforces. Within the framework of the METIS project, a four-year project co-funded by the European Commission through the Erasmus+ programme, SEMI and imec deployed experts in the field to survey and interview focus groups. The survey identified the following key focus areas for workforce development: 1. True Capability of AI and Data Science With AI’s heavy dependence on data, the workforce of the future must be trained in areas of data science including data integrity to ensure quality, unbiased sourcing, collection and accurate analysis necessary to interpret huge volumes of data. Europe also needs to train the next generation of AI chip designers in data security and privacy – key challenges to the widespread deployment of Edge AI chips. 2. Climate Change, Sustainable Development Goals (SDGs) and Social Inclusion TrainingSince the industry must be able to develop Edge AI solutions to enable the digital transformation while limiting GHG emissions, microelectronics engineers need to be schooled in climate change and understand how their work contributes to meeting the United Nation’s Sustainable Development Goals (SDGs). Workplace diversity and social inclusion are also important target areas for education since Edge AI applications should serve various groups of people with different needs.3. EthicsChip industry workers must also be educated in ethical issues of AI related to the technology’s potential societal impact in the near future[1]. With AI applications capable of monitoring Internet searches based on users’ personal preferences and biases to deliver tailored advertising, news and other information, developers must recognize how the technology can influence thinking and behaviour of individuals and groups. This awareness can help developers strike a balance between supporting commercial interests and societal good so the microelectronics industry can ensure ethical implementation of AI. 4. Cross-disciplinary Skills Required for AIAI development requires a comprehensive, cross-disciplinary skill-set to be able to integrate the work of specialists from diverse educational, cultural and professional backgrounds critical to developing non-biased AI solutions. For example, in addition to technical expertise, microelectronics AI developers must be able to communicate clearly and work in close-knit teams with non-technical experts from business, law, medicine and the social sciences.What’s Next?The microelectronics industry has a tremendous opportunity to develop new chip-based solutions for AI architectures, and apply AI techniques to improve operational efficiencies of design and manufacturing. To seize this opportunity, the industry must work closely with education providers to groom the next generation of skilled workers. This tight collaboration is critical to designing and delivering specialised courses to college and university students as well as engineers now working in the chip sector. The stakes are high. By preparing workers to develop Edge AI chipsets, the microelectronics industry can help the world confront some of the greatest challenges it faces today.For more information, see SEMI Responds to European Commission White Paper on Artificial Intelligence.METIS is a Sector Skills Alliance project co-funded by the European Commission’s Erasmus+ Program and coordinated by SEMI. The four year project, launched in November 2019, will develop a Microelectronics Skills Strategy. Based on the strategy, the METIS project will design 43 training modules for 1,100 hours learning in four key areas of the microelectronics sector.We thank Patrick Blouet (STMicroelectronics) and Jeroen Geusens (imec) for their valuable contributions to this article.[1] Ethics of Artificial Intelligence and Robotics, Stanford Encyclopedia of PhilosophyDr. Yanying Li is senior manager of Collaborative Projects at SEMI Europe.Dr. Pushkar P. Apte is the strategic technology advisor for the Smart Data AI Initiative at SEMI

METIS, a Sector Skills Alliance project co-funded by the European Commission’s Erasmus+ Program and coordinated by SEMI, recently launched an online questionnaire aimed at gauging the skills and expertise the industry needs to drive continued growth over the next five years. The survey, which will stay online until 15 October 2020, is a part of the METIS project’s efforts to involve a broad range of stakeholders in the microelectronics industry to assess workforce, future technology and economic trends influencing talent development and the skills needed most today and in the next five years. The survey aims to highlight the skill mismatches in specific job profiles that are of increasing importance to the microelectronics industry. It elaborates on the upskilling and reskilling needs for design engineers. Given that semiconductor design is becoming increasingly crucial for Europe’s competitiveness and technological sovereignty, the new skills required from design engineers are a priority area for the METIS project. Other examples are the manufacturing and maintenance technicians, two job profiles that are currently experiencing significant shifts in their skillsets, as COVID-19 has thoroughly transformed their way of work.While the microelectronics industry has been very aware of the importance of the high level of investment in R D, it is equally crucial to ensure that the workforce of the industry is equipped with knowledge and skills for the rapid technological developments. Maintaining high levels of investment in workforce including attracting talent, updating their knowledge and skills with the latest technological development, and supporting them to lead innovations, is essential for this industry. There is a growing demand for specific requirements for this sector to support innovation in many other sectors such as automotive, energy, healthcare, and government, to foster benefits from emerging digital technologies such as Cloud Services, Internet of Things (IoT), Artificial Intelligence (AI), Digital Reality, and Blockchain.In addition to the online questionnaire, the METIS project consortium is interviewing top experts from leading microelectronics companies, education representatives from universities and training academies, and experts from government agencies and industry associations. The interview outcomes provide inputs on what kind of employee profiles are the most difficult to find, what skills this sector is looking for in a candidate, and what kind of training and policy frameworks are needed to improve employers’ skills. Those inputs are essential to develop the skill strategy and form recommendations on training modules.Furthermore, the METIS project consortium is organizing 10 focus groups. Each of the focus groups is dedicated to a key topic, such as SC design, SC materials, semiconductor manufacturing equipment, etc. For example, one of the METIS focus groups is dedicated to Edge AI, a top priority for the microelectronics industry. Strengthening the AI talent pipeline is essential to harness the potential of Edge AI in Europe and to facilitate the shift from the Cloud to the Edge when possible in order to meet specific demands (e.g. for autonomous driving), reduce energy consumption for data communications, and to increase efficiency. The EU’s White Paper “Artificial Intelligence - A European approach to excellence and trust”[1] , published this February, also emphasizes the importance of upskilling and reskilling to position Europe among the global leaders in AI. Hence, the focus group will work towards pinpointing the skills necessary for the semiconductor workforce to capture the potential of the trend.The results of the survey, interviews and focus groups will be used to form the Microelectronics Skills Strategy. Based on this strategy, the METIS project will design 43 training modules for 1,100 hours learning in four key areas of the microelectronics sector:Component designSystem designBasic of manufacturingKey competencies and innovative thinkingThe METIS project is planning to recruit 2,000 learners in companies and education and training institutes to participate in the trainings and validate the impact. The METIS project will also work with companies, education and training providers to ensure continuity of the initiative and foster cooperation.During the METIS project course (2019 – 2023), the Skills Strategy will be updated yearly to reflect the latest technology and market trends. To enable the Skills Strategy to continue serving the industry, METIS is working on forming a permanent instrument, named Observatory and Skills Council, to continue developing the skills strategy, update the training and facilitate cooperation between industry and education and training providers.Laith Altimime, president of SEMI Europe, and 50 members of the Microelectronics Training, Industry and Skills (METIS) consortium The METIS consortium invites companies and associations involved in microelectronics training and education provision, human resources and career services professionals, technology strategists and policy makers to complete the online questionnaire. Stakeholders are also welcome to subscribe to the METIS newsletter for the latest on METIS programs. For more details, please contact Yanying Li at [email protected].[1] EU’s White Paper on Artificial Intelligence available at: https://ec.europa.eu/info/sites/info/files/commission-white-paper-artificial-intelligence-feb2020_en.pdfDr. Yanying Li is senior manager of Collaborative Projects at SEMI Europe.

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.

Humanity has survived almost unimaginable challenges over the past 5,000 years of documented human history. From war, famine and natural disasters to the first global pandemic in the last 100 years, more often than not, people have relied on one another to survive and thrive again. As the industry association representing the global microelectronics industry, SEMI has similarly made collaboration and community integral to the fabric of its organization. From helping members to succeed through the COVID-19 pandemic to facilitating member-driven industry standards around environmental health and safety, materials, and manufacturing capabilities, this approach shows members that standing together is better than standing alone.On the eve of the 50th annual SEMICON West (July 20-23, 2020) — the first virtual edition in SEMI’s history — I spoke with SEMI’s vice president of technology communities, Michael Ciesinski, about the role of SEMI in tackling big challenges through an active member community intent on solving problems through collaboration.SEMI: How long have you worked with SEMI and in what capacity?Ciesinski: In January 2016, I started my second tour at SEMI when FlexTech, the industry consortium I’d been leading, became SEMI’s first strategic partner. Nearly two years into that role, SEMI President CEO Ajit Manocha asked me to form Technology Communities to engage members with common interests. After FlexTech, we brought on the Fab Owners Alliance, then MEMS Sensors Industry Group (MSIG), and later the Electronic System Design Alliance (ESD Alliance).SEMI now has more than 20 communities in all, including Smart MedTech, Smart Data AI, Smart Manufacturing, Electronic Materials, and Integrated Packaging, Assembly and Test.SEMI: What is your role with Technology Communities — and how do members stand to benefit?Ciesinski: The leadership of Technology Communities ensures that SEMI’s benefits and services align to our members’ interests so we can provide member benefits that matter most. This spans forming communities where people hold common interests (e.g., advanced packaging) to facilitating standards that will promote intelligence in manufacturing (e.g., data standards for AI and machine learning) as well as providing R D funding.I’m especially proud that over the past three years, SEMI has brought more than $40 million in R D funding to our members, with most grants in the $500,000-$1 million range. We’ve been especially successful in securing funding in flexible hybrid electronics (FHE) through U.S. Army Research Laboratories (ARL), a model we first developed through FlexTech.Two recent recipients of FHE funding, GE Research and ITN Energy Systems, show how the grants are spawning partnership opportunities among commercial enterprises, R D organizations and universities. In developing lightweight, non-invasive wearables, including a human-performance sweat-monitoring patch that remotely analyzes sweat to detect hydration levels and other vital signs, GE Research is using key components such as sensors and lightweight batteries in its designs.ITN Energy Systems designed a flexible all-solid-state lithium battery that’s printed on light, flexible substrates to power small and incredibly thin applications.Universities are also benefiting by plugging into the SEMI ecosystem. In fact, 40-50 percent of funded projects are seeding commercialization by universities. This is another validation that SEMI’s collaborative, community approach to microelectronics is working.SEMI: Position, Timing and Navigation (PNT) is another hot area where SEMI has secured ARL funding. What makes this funding different and why is it important?Ciesinski: The PNT grant makes ARL funding available to the MEMS Sensors Industry Group (MSIG) members through SEMI for the first time. If you’ve ever lost GPS signal while coming out of a tunnel, you know how frustrating that is. For us, that’s an inconvenience, but for a healthcare worker in a remote location who’s waiting for a delivery of medication by drone, it could be life-critical. While that’s just one example of why we need PNT to operate when GPS isn’t available, I can imagine dozens of other important dual-use cases, including autonomous driving.SEMI: How else do Technology Communities benefit under SEMI?Ciesinski: Technology Communities need access to diverse resources to spur continuous innovation. Electronic Materials Group participants, for example, need to stay informed on regulations coming out of Asia, the U.S. and Europe that may affect their businesses. Where else other than SEMI can like-minded stakeholders congregate with people up and down the supply chain to determine whether industry-wide action is needed on regulation?SEMI: What is the importance of SEMI’s global footprint?Ciesinski: I’ve worked with many associations and managed major industry consortia. The clear advantage of SEMI is our global footprint. And that’s vital because microelectronics is a global industry involving a multitude of stakeholders that play essential roles in the supply chain.Let’s say you want to discuss EU regulations on hazardous chemicals. Rather than decipher these complexities alone, you can pick up the phone to speak with someone on SEMI’s European team to learn what’s critical.What if you’d like more information on the 20-plus new fabs that are going up in China? You can explore that question with our SEMI China or SEMI Industry Research and Statistics teams.SEMI: How has SEMI evolved over the years?Ciesinski: SEMI has a long history of providing what the industry cares about. We started in trade shows and pivoted to industry standards. We began with small silicon wafers and wafer carriers, and now within the span of 50 years we’re working on data-format standards that will support the application of AI and machine learning (ML) in the semiconductor industry.While highly varied today, data-format standards will help component manufacturers refine processes to create more efficient solutions. This ARL-funded program, which pairs SEMI members with the grant recipient, Cornell University, may offer dramatic gains in the productivity of semiconductor manufacturing.SEMI: How does SEMI’s approach to COVID-19 reflect core values of collaboration and community?Ciesinski: Together with Ajit Manocha, CMO Terry Tsao and other team members at SEMI, we pulled together a task force to help SEMI members navigate the pandemic.We tapped two existing groups, Environment, Health and Safety (EHS) and Information Technology Leadership (ITL) from the start, documenting their strategic and tactical approaches to help all members through the COVID-19 resource section of our website. The EHS section provides tips on facilities and meetings, employee policies, business travel and communications, while the ITL section lists insights on computing hardware for staff, licensing, networks, security and employee policies.Our EHS leadership team, which includes Entegris, Axcelis, Versum, and Intel, immediately started sharing best practices for sanitizing facilities. As a result of team meetings, SEMI EHS shared best practices on keeping the workforce remote and guidelines for returning people to work safely. From securing PPE and safeguarding employees and visitors by performing thermal scanning to outlining communications around potential employee exposures, EHS has provided meaningful resources for the benefit of all members.SEMI also took immediate steps in the area of advocacy. Our advocacy team in Washington, D.C., together with regional SEMI presidents around the world, have ensured that semiconductor facilities were and still are considered essential businesses in the U.S., Europe and Asia. That’s because microelectronics are foundational to fighting the pandemic.Microfluidics are critical to the Reverse Transcription (RT) Polymerase Chain Reaction (PCR) tests most commonly used for COVID-19. Sensors are embedded in the pulse oximeters that allow patients and healthcare professionals to monitor a vital rubric: oxygen saturation level. If oxygen saturation level drops into the low 90 percentiles or below, it may be time to go to the hospital for treatment.Microcontroller units are essential components in a wide range of hospital equipment, including the ventilators that may make the difference between life and death in the most seriously ill patients.SEMI: How can the ingenuity realized through microelectronics continue to help us tackle other big problems? Ciesinski: We have MEMS and sensors to thank for distributed intelligence, giving us the ability to put sensors anywhere, locally based in the field or in the packaging house.Food production is a prime example. Leveraging miniaturized wirelessly connected sensors, we can trace food through the entire production lifecycle, from the seed in the ground to the food in the warehouse and, ultimately, to the product that lands on the table.From larger enterprise such as IBM Food Trust to small startups, we’re using MEMS and sensors to improve crop yields so we can feed a human population that’s growing each year.There’s a sustainability piece as well. We’re using MEMS and sensors to reduce the amount of fertilizer or other nutrients or chemicals in the soil. That’s good for the environment and for the agricultural workers who labor in the fields.MEMS and sensors can also condense the time it takes to perform a specific task, conserving human resources.SEMI: Where do you think SEMI will go in the next decade?Ciesinski: Ten years from now, I believe we will still have our global footprint in place. I expect it will expand, particularly in Asia.We may also expand into new areas such as Latin America and Central America, which would provide at least two major benefits: People working in microelectronics would, I hope, have access to better quality of life. And diversifying the supply chain would allow nations and regions to have more control over the products they need, from PPE to medications, which may help us to better manage through the next pandemic.I am also hopeful that SEMI will be on the leading edge of helping our members communicate in much different fashion from what we have today. We’re already expanding beyond the paradigm of in-person meetings for standards meetings and conferences. As we move forward, I think we’ll see a hybrid solution to doing business, combining in-person meetings with virtual conferences and digital content that’s available 24/7.Whatever changes we see in SEMI, I’m confident that we will continue to see a global footprint in an industry association that prioritizes connections among members.Engage in the SEMI experience at upcoming SEMICON WestRegister today to hear from keynote speakers such as environmental advocate and former U.S. Vice President Al Gore, futurist and author Steve Brown, and IBM Research senior vice president and director Dr. John E. Kelly III, and Lea Gabrielle, special envoy of the Global Engagement Center for the U.S. State Department, at SEMICON West , July 20-23, 2020. Content will be live streamed and available on-demand. Michael Ciesinski is vice president of Technology Communities for SEMI, the global microelectronics industry association, appointed in August 2018. At SEMI, he directs activity for more than 20 industry groups, oversees the association’s R D funding program, and develops new technology initiatives to serve SEMI’s 2,400 members. Prior to re-joining SEMI, Ciesinski was president/CEO of FlexTech Alliance, an industry consortium focused on new methods of creating electronics. From 1995-2008, Ciesinski served in a similar role at the U.S. Display Consortium (USDC), a private/public partnership chartered with building the infrastructure for electronic display and flexible electronics manufacturing. Both FlexTech and USDC annually sponsor multimillion dollar technology development programs and provide industry technical, financial and market services. Ciesinski is a graduate of the University of Albany, NY, and a former member of the Dean’s Advisory Committee at California Polytechnic State University.Maria Vetrano is a PR consultant at SEMI.

Japan’s Prime Minister Shinzo Abe declared a state of emergency for Tokyo, Osaka and five other prefectures[1] on April 7 in response to a startling increase of COVID-19 infections in the region’s cities in an uneasy moment for its domestic semiconductor industry. The declaration, effective through May 6, authorized the six prefectural governors to strengthen curbs on the spread of the virus and included guidance for citizens to stay home and restrictions on operations of non-essential businesses.With Japan supplying some 40 percent of the world’s chip production equipment and materials, the declaration stirred fears among semiconductor manufacturers that their uninterrupted operations – critical to sustaining the global industry – might be at risk. Japan Government Designates Semiconductor Industry as EssentialIn April 7 and 11 revisions to its Basic Policies for Novel Coronavirus Disease Control, the Japanese government allayed those concerns by designating semiconductor manufacturers essential businesses – a stark acknowledgment of the chipmakers’ vital role in combatting the novel coronavirus. The policy stated:“Among medical and manufacturing industries, we request the continuation of the following business operators in consideration of infection prevention: operators who are difficult to stop production line due to the characteristics of the equipment (such as blast furnaces and semiconductor factories); and operators who produce essentials (including important items in supply chains) for protection of the people who need medical care and support, as well as for maintenance of social infrastructure. We also request the continuation of the business operators who sustain medical care, the lives of the people, and maintenance of the national economy.”[2]SEMI Japan Reaches Out to Prefectures to Urge Essential Business Designation Equipment and materials shortages can halt production of an entire fab line and ripple through intricately connected global supply chains to stifle the production of end devices including the electronics critical to COVID-19 treatments. Electronic devices also play a central role in containing the virus’s spread by enabling artificial intelligence (AI), data analytics, digital communications, telemedicine, robotics, remote health monitoring, telecommuting, online shopping and other digital services.The essential business designation was explicit recognition that Japan’s semiconductor supply chain is integral to the global chip production ecosystem and worthy of the same protections the government has implemented for semiconductor companies. With SEMI members operating in Japan’s 47 prefectures, I sent letters to all prefectural governors three days after the second policy revision, urging them to apply the same designation, and the SEMI Japan team is following up to secure their support.SEMI Japan Encourages Government to Exempt Members from Travel Restrictions The Japan Foreign Ministry on March 31 raised to level 3 its travel advisory for 49 regions including the U.S., China, Taiwan and South Korea, encouraging Japanese citizens to avoid travel regardless of purpose to blunt the international spread of the coronavirus. SEMI Japan is working with the Semiconductor Equipment Association of Japan to urge the government to exempt semiconductor supply chain companies from the level 3 travel restrictions if they implement measures to prevent domestic infections and contagion in the visited regions. The exemptions would allow supply chain companies to install and service equipment at fabs – one key to maintaining smooth, uninterrupted operations.SEMI Supports Members with COVID-19 ResourcesSEMI international headquarters and regional offices are here to help you, our members. For more information on our webinars, surveys, best practices and other information designed to help you meet the challenges of the pandemic, please visit the SEMI Coronavirus Updates Resources page.[1] The six prefectures are Tokyo, Kanagawa, Chiba, Saitama, Osaka, Hyogo and Fukuoka.[2] Provisional translation by Ministry of Health, Labour and Welfare. Full document is available at https://www.mhlw.go.jp/content/10900000/000620733.pdf.Jim Hamajima is president of SEMI Japan.