microelectronics

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.

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.

Innovations in the public sector are springboards for new products in digital health and personalized medicine. Since 2013, SEMI NBMC, funded by the Air Force Research Laboratory (AFRL), has been evaluating industry needs and soliciting proposals for new research into the foundations of device development and manufacturing of medically actionable devices.SEMI NBMC has run 17 separate programs with more than two dozen organizational participants developing materials, electronics, microfluidics, manufacturing processes and algorithms to create low-cost, wearable sensors. Most of these integrated sensing systems communicate wirelessly and incorporate high-performance silicon devices that are designed to move with the individual. Each of the projects was the result of a proposal received during NBMC’s annual proposal cycle. ​What’s Next in MedTech Device Development?We invite you to join the teams at SEMI, NBMC and AFRL to answer that question in a virtual series of sessions over the four weeks in August.For the past five years, NBMC has been conducting similar sessions for roadmapping the development of non-invasive human performance monitoring technology and manufacturing. The information feeds into the topics for upcoming RFPs, including the one we expect to release in September 2020. Previous Workshops (formerly entitled Blood Sweat and Tears) brought together industry and university innovators to explore current product research and provided excellent insights for the proposal evaluation teams. We believe the insights are also very useful to the business and technology planning direction for researchers and developers working on these products.Our focus is on early-adopting markets – medical professionals and their patients, Army and Air Force personnel and high-performance athletes.​ In this time of social-distancing and overall hesitancy to approach hospitals and medical offices, medical monitoring that provides medically-actionable intelligence is of even greater significance.But Doesn’t FitBitTM Have that Covered?Advancements are coming fast and furious – but medical professionals and insurance companies are struggling to distinguish innovations that provide actionable intelligence from those that provide generalized, non-actionable data.The workshop will focus on the medically relevant information that requires a great deal more accuracy, testing and certification before decisions are made. It is the innovations in this field that will lay the groundwork for new products in digital health and personalized medicine. Additionally, they are leading to advancements in aeromedical monitoring and diagnostics to support the U.S. Air Force’s mission to improve patient care during emergency air transport. The targeted future state is real-time monitoring of biochemical and physiological markers that can guide optimization of human performance and health. ​The SMART MedTech Virtual Workshop Series will link markets with manufacturing for medical relevancy – addressing both ends of the ecosystem. This forum will bring together the players across the growing range of industries that are entering or advancing human monitoring applications to:​ share competitive ideas that may be applied to product development​, assess roadblocks in bringing human monitoring products to market, and form partnerships that have become key in overcoming obstacles to successful manufacturing and product development. ​ Join the experts who are at the cutting edge of product design and manufacturing techniques. Indeed, the success of previous workshops was based on the unique membership of NBMC, where product and manufacturing-oriented engineers from industry, universities, and government labs form teams and pool resources (financial as well as technical) to accelerate human monitoring product development into manufacturing prototypes.Can’t Attend the Workshop?All sessions will be recorded and available for watching and re-watching on-demand. Join our interest list to receive regular updates on SEMI NBMC activities, including notification of the RFP expected to be available in October 2020.Find out more about the Smart MedTech Initiative and the NBMC Programs at our website.Rene Krantz is Director of R D Programs Business Development at SEMI. She is the primary manager of SEMI Smart MedTech Initiative and NBMC programs. Contact Rene at [email protected].

Data recently collected by SEMI points to only a moderate slowdown in the industry’s pursuit of talent, illustrating the growing and significant need for attracting workers at all levels of the organization. With COVID-19’s devastating impact on many sectors of the economy, the time is ripe to sharpen the industry’s focus on attracting and training a new wave of workers to meet the growing talent needs across our industry.To help illuminate the state of microelectronics industry hiring during the pandemic, following are three takeaways from recent workforce development data. Key Takeaway 1 – Emsi Hiring Data and Analytics ReviewIn a May 5 SEMI webinar on the Future of Work, presenter Andrew Crapuchettes, CEO at Emsi, a labor data analytics firm based in Moscow, Idaho, revealed that the U.S. semiconductor equipment and device manufacturing sectors posted 199,326 total jobs (32,022 unique positions) from March through June 2020 with an advertised median annual salary of $68,500 – the highest posting intensity for all other occupations and companies in the U.S. Crapuchettes noted that “although the job postings number was actually down from the previous quarter, some of the large companies have shown flat or growing postings during this period. At Emsi, we are evangelists for more accurately establishing the requirements for the job to more closely match the skills actually being sought.”He pointed to a gap between the skills employers list in job postings and those employees itemize in their resumes. Today’s use of algorithmic resume analysis, however, may reveal false gaps in hiring. Emsi is working with several Fortune 500 companies in the electronics sector to help them analyze their job postings. The goal: to better understand if they have identified the right skills for their business and the recipe for attracting top talent. Emsi supports programs such as the SEMI Works workforce development initiative that are out to more closely align job seekers and curriculum development with the skills needed for microelectronics design, development and manufacturing.During COVID-19, Crapuchettes sees companies across all industries doubling down on employee training. For many organizations, a business slowdown is an opportunity to identify and work to fill employee skill gaps and prepare companies to emerge stronger once the pandemic has passed. Key Takeaway 2 – SEMI COVID Impact SurveyIn March, April and June, SEMI surveyed members to evaluate the impact of COVID-19 and help inform SEMI’s response. Among the questions in the June survey was “How has COVID-19 impacted your hiring plans?” Of the more than 300 respondents, just 13% reported a hiring freeze and 55% said their hiring plans remain unchanged.Figure 2: Data from SEMI COVID-19 Impact Survey All SEMI regions show a similar pattern. Japan, Korea and China reported little to no slowdown in hiring as shown in Figure 2. Differences across regions were notable with more cautious approaches to hiring adopted by North America, Europe and Taiwan, with some companies slowing hiring for certain positions.Key Takeaway 3 – SEMI Survey of Workforce Development Advisory CouncilSEMI relies on members for industry insights we use to build, evolve and prioritize our programs. A June survey of SEMI America’s Workforce Development and Diversity Inclusion Advisory Council showed that, while some member companies have delayed hiring until the pandemic’s impact of the industry is clearer, most respondents see this period as an opportunity to attract talent to the electronics industry and maintain hiring programs to meet the growing demand for talent the digital revolution is fueling. The survey data, as shown in Figure 3, is consistent with Emsi’s results and a larger SEMI member survey. Our June survey also illustrated the strong desire by the Council for SEMI to support diverse communities and lead efforts to connect talent from these groups with career opportunities in electronics. All survey respondents urged SEMI to place the highest priority on promoting Diversity Inclusion in the workforce, with 57% ranking university outreach as a high priority. Visit the Workforce Development Pavilion at Virtual SEMICON West 2020 for More InformationThe microelectronics industry is making a huge impact in the COVID-19 era – from developing the tools to run algorithms for companies working on a vaccine, to keeping the internet humming for home workers and online ordering for homebound seniors. But these services will only continue to evolve at a rapid clip with the right talent. SEMI programs remain laser-focused on pursuing and developing that talent.Thank you to all members who responded to the surveys and Emsi for contributing to understanding of the workforce need in the current climate. We invite all members to connect with SEMI Workforce Development activities. We need your help to align skills to curriculum (SEMI Certs), presenting at our workforce development events and donating to the SEMI Foundation, which provides financial support for much of our work.Learn more about how you can help the industry grow its talent pipeline at the SMART WorkForce Pavilion at the virtual SEMICON West – July 21-23! Checking out the pavilion is free, but there’s a modest fee for the content. Register now for a discounted all-in pass to enjoy blister- and COVID-free access to the first virtual SEMICON West ever. Shari Liss is Executive Director of the SEMI Foundation. She oversees the development and success of all programs from K-12 through re-skilling for veterans.

As the amount of electronics in automobiles continues to increase, it is becoming more common to hear a vehicle referred to as a “computer on wheels.” To that end, innovation occurs at the intersection of automotive and microelectronics so that leveraging synergies and contemplating joint initiatives becomes crucial in shaping the future of both fields. In this two-part article, we will discuss the current trends in the automotive industry, which are to a large extent driven by microelectronics, and will reflect on the transition from “just the vehicle” to “the mobility ecosystem.”SEMI encourages its members to partner in seizing opportunities in safe, efficient, and convenient mobility solutions. Before diving into specific opportunities that the automotive industry offers to electronics companies, we will start by taking a closer look at this sector and the current trends.Automotive or Mobility? Shaping the New EcosystemThe automotive industry and its supply chain of vehicle manufacturers and component suppliers has been evolving for decades around the sales of vehicles. The customer groups used to be fairly well established with individual consumers and commercial entities, the latter often as fleets. The automotive industry has grown in depth by vertically integrating design, manufacturing, sales, service, accessories, etc. More recently, the traditional players have also begun to venture into mobility services such as car sharing, showing their ambitions to become “mobility providers.”The term “mobility” has been used increasingly instead of “automotive” for about a decade now. This reflects the more recent transition to creating businesses and functionalities around the sales of miles. In line with this, the industry’s perspective is also shifting toward use-cases and experience rather than just focusing on the vehicle or plain transportation. Much of this transition from “vehicles to miles” is driven by key trends that require massive use of microelectronics, in particular autonomous driving and electric vehicles.One of the key questions to raise for SEMI members is: at which stages should the supply chains for the microelectronics and mobility industries interact with one another to shape the evolving ecosystem? In order to answer this question, we will examine the four main trends shaping the future of mobility represented in the acronym “ACES”: Autonomous, Connected, Electric, Shared.ACES – Autonomous, Connected, Electric, SharedThese four trends, together with the broader transition from “vehicle to miles,” also include newcomers “disrupting” the industry and changing it for good. Basically, every mobility player, traditional or new, is taking ACES (or CASE) into consideration at the moment.Autonomy: computers are taking over the task of driving from humans, first through advanced driver assistance systems (ADAS) and then at some point with complete self-driving. Following the levels of automation from zero to five, as defined by SAE International[1], the current market frontier is SAE Level 2, which means the vehicle can under certain situations (e.g. highway) drive itself but has to be monitored by the driver at all times. Many industry experts assume that artificial intelligence and computing power hold the key to higher levels of automation.Connectivity: vehicles are increasingly exchanging data with a central hub and with one another through cellular, WiFi, satellite, etc. At present, there are mostly entertainment and convenience offerings on the market, but maintenance and safety functionalities are emerging. One key differentiation between solutions is whether connectivity is “built-in” with embedded OEM solutions, “brought-in” (e.g. smartphone apps independent of vehicle or dashboard navigation systems), or “tethered” (e.g. smartphone used as communication gateway).Electrification: traditional mechanical and fossil-fuel-powered vehicle driveline components are increasingly being replaced by electrical components. The spectrum includes hybrid electric vehicles (HEV), plug-in HEV (PHEV), battery-based electric vehicles (EV), and hydrogen fuel-cell vehicles (FCV). The transition from traditional to electrified driveline technology requires more and more diverse electronics, such as more control systems, sensors and high-voltage systems. Ultimately though, the transition requires fewer systems, i.e. ignition, injection and multiple other systems being replaced by high-voltage power electronics and battery monitoring.Sharing: a growing number of consumers are seeking convenient access to mobility to get “from A to B” while viewing vehicle ownership as a burden rather than a benefit. Typical forms of this trend include car-sharing, ride-sharing, ride-hailing, micro-mobility, and micro-transit. Mobile computing enables much of the convenience that shared mobility offers, such as instant access, competitive and convenient payments, and flexible work opportunities (i.e. “gig economy”). Therefore, electronics, connectivity, and computing all play an important role in this trend.SEMI as the Natural Convener for Industry Exchange and ProgressClearly, for all four of the ACES trends, microelectronics play a crucial role in driving mobility innovation and making future solutions safe, efficient, and convenient. Based on this, mobility represents one of the largest opportunities for semiconductors: by 2025[2], a projected 14% of all integrated circuits produced globally will go into vehicles. As the trade association representing the complete microelectronics manufacturing and design supply chain, SEMI is positioned as a natural convener of experts for cross-industry and pre-competitive exchanges with the automotive supply chain. This positioning led to the foundation of the Smart Mobility initiative at SEMI, in part, to facilitate collaboration across these increasingly interdependent supply chains. The second part of this blog will present opportunities for electronics based on the ACES trends in the automotive industry, along with an overview of the Smart Mobility initiative.[1] © SAE International from SAE J3016™ Taxonomy and Definitions for Terms Related to Driving Automation Systems for On-Road Motor Vehicles (2018-06-05), https://www.sae.org/standards/content/j3016_201806/ (retrieved 05/5/2020)[2] Source: IC InsightsMicroelectronics Power the Future of Mobility – Part 2: Opportunities for ElectronicsBettina Weiss is Chief of Staff and Global Smart Mobility Lead at SEMI. Sven Beiker is Smart Mobility Consultant at SEMI.

During the COVID-19 pandemic, the SEMI Global Advocacy team has been working tirelessly to ensure the microelectronics manufacturing and design supply chain is classified as an “essential business” in the United States and for similar designations in several other countries so that SEMI member companies can maintain operations. Their efforts have included direct lobbying and letters to the governors of 16 states in the U.S., 23 European countries and several European Union officials across the continent, as well as government officials in Japan, Mexico and Malaysia. The bedrock of these efforts, and the reason they have been highly effective, is that our industry enables both modern digital infrastructure and technology critical in the fight against the virus.SEMI takes immense pride in highlighting the role of our industry in providing the building blocks for innovations that improve social and economic prosperity the world over. It is never more apparent that necessity is the mother of invention than during a crisis, and the pandemic has created a diverse range of demands for technological advancements to address the myriad of challenges it presents. Our SEMI Tech Spotlight blog series highlights some of the many ways that our industry and member companies are enabling technology employed on the front lines of this fight – and that we strongly believe will ultimately help to win it. Our first piece in this series focuses on platforms enabled by big data and artificial intelligence.Fighting the Pandemic with Big Data-AI Enabled PlatformsThe COVID-19 pandemic is testing humanity in unprecedented ways, but it is also uniting us to fight this crisis with the best weapons we have. Big data and Artificial Intelligence (AI) technologies – built with microelectronic chips and systems that generate, transmit, store and analyze data – are making a profound contribution to our arsenal for this protracted war. Big data-AI technologies are enabling platforms such as data analytics, robotics, augmented/virtual reality (AR/VR), 3D printing, and others that are already being applied to address many facets of this crisis.Big Data and Analytics Inform Policy In the fight against COVID-19, data analytics platforms are being used first and foremost to slow the rapid spread and to inform policy decisions. This requires analysis of massive amounts of data about public health and travel, often using AI algorithms. The state of California, for example, is partnering with companies such as BlueDot, Esri and Facebook to build a software platform that uses smartphones and location intelligence to track people’s movement and predict hospital needs. Taiwan owes its considerable success in limiting the spread of the virus to the extensive use of big data analytics for identifying and tracking carriers. Google and Apple are driving a joint effort that connects Bluetooth with their popular iOS and Android platforms to trace contacts of infected people. India has developed Aarogya Setu, a mobile app based on Bluetooth and location-mapping platforms, designed to alert citizens if they have crossed paths with another app user who has tested positive for the virus. This app was launched in 11 languages, and despite being entirely voluntary, it was downloaded by 50 million people in 13 days, making it the world’s fastest-ever to reach that number. Such contact-tracing apps, now being rolled out in at least 26 countries, carry inherent privacy and security challenges due to the sensitive data they access. While mitigation strategies like strict data anonymity and opt-in protocols are being implemented, these will need to be refined over time.Robotics Protect Frontline SoldiersToday’s robust robotics platforms are enabled by huge amounts of data from sensors and guidance from predictive AI algorithms. These robots can learn on the job, adapt to the environment, and work safely with humans. In this pandemic, they are perfect for minimizing human interaction with infectious environments. Companies around the world such as Boston Dynamics, Akara Robotics, UBTECH Robotics and CloudMinds have already deployed robots on the front lines of this war to assess patient health, disinfect hospital surfaces, and help health workers with Personal Protective Equipment (PPE).Robot drones are also delivering blood and other lab samples. For example, WakeMed hospitals in North Carolina launched the first drone delivery program approved by the U.S. Federal Aviation Administration with Matternet drones operated by UPS; while Terra Drone from Japan executed similar tasks in the hard-hit Wuhan province of China.3D Printing Speeds ManufacturingBig data-AI technologies enable 3D printing platforms by providing accurate 3D models for optimized designs and defect-free manufacturing. Low-cost, fast-cycle-time 3D printing has helped to alleviate at least some of the medical equipment shortages. For example, the U.S. Food and Drug Administration (FDA) has approved the first 3D-printed “Stopgap Face Mask” for liquid barrier protection from the SARS-CoV-2 coronavirus for healthcare workers. The U.S. Veterans Health Administration has developed this in collaboration with America Makes using an open-source database – the 3D Print Exchange from the National Institutes of Health. In another example, Formlabs worked with Northwell Health, New York’s largest healthcare provider, and University of South Florida (USF) Health to develop and test a nasal swab prototype over just one weekend, and it is now producing up to 150,000 test swabs daily. Prisma Health in South Carolina received emergency FDA authorization for VESper, a 3D printed device that allows a single ventilator to support two patients, and possibly up to four.Telehealth Becomes a “New Normal”Telehealth is not a new concept but is much enhanced by today’s microelectronics platforms that can collect and transmit rich datasets with very low latency. Further, rapid data analysis is increasingly supported by AI systems. The requirement for social distancing makes telehealth a perfect solution for many healthcare consultations. U.S. government data indicates that the daily average of telehealth claims from private insurance for upper respiratory infections increased nearly 12 times over the previous month from March 14 to April 1. Similarly, Teladoc Health coordinated 100,000 patient “televisits” in the week of March 8 – a 50 percent spike over the previous week, taking pressure off the healthcare system. The next generation of telehealth is likely to use AR/VR platforms, which use even richer datasets and AI to improve the accuracy and predictive capability of their underlying models. Consequently, these platforms can provide more realistic experiences and improved outcomes. At least 11 states in the U.S. are already working with AR/VR companies such as XRHealth and AppliedVR for primary care and many medical specialties. Accelerating the Search for a Vaccine or TreatmentThe way out of this pandemic depends on swiftly finding a vaccine and a treatment, ideally by fast-tracking the traditionally slow drug development process. Big data-AI technologies are at the forefront of such efforts globally, often using the most powerful supercomputers available. For example, researchers at the University of California, San Diego (UCSD) are using the Frontera supercomputer to build a complete model of the SARS-CoV-2 coronavirus envelope – a formidable task, requiring analysis of data from 200 million atoms and interactions between them. Researchers at Argonne National Laboratory are combining AI with physics-based models to search for a molecule that might disrupt the activity of the virus, a precursor to finding a treatment. Also, several companies around the globe such as BenevolentAI (UK), Gero (Singapore), Innoplexus (Germany-India), and Insilico Medicine (US-Hong Kong) are using AI platforms to accelerate the search for a solution. ConclusionUltimately, the success of technology is not measured by the number of bits and bytes or by the speed of algorithms. It is measured by every janitor who did not have to clean a hazardous surface because a robot did, by every doctor and nurse protected by a 3D-printed mask, and by every person whose life may be saved by the accelerated discovery of a vaccine or treatment. Big data-AI technologies, and the platforms they enable, are just coming of age – they give us hope that as they evolve in the future, we can use them to build a more resilient society and economy.Note/Disclaimer: The examples cited above are purely for illustration – they are neither comprehensive, nor intended to endorse any particular product or solution.The SEMI Smart Data AI initiative helps members realize full value in the intelligent future enabled by Big Data and Artificial Intelligence – including the large revenue upside, and the transformational potential for operational and supply-chain efficiency. For more information on the initiative, contact Pushkar Apte at [email protected] Manocha is President and CEO of SEMI. Pushkar P. Apte, Ph.D., is the Strategic Technology Advisor for the Smart Data AI Initiative at SEMI.

The microelectronics industry entered 2020 with high hopes after a mixed 2019 that saw global semiconductor revenue fall 11 percent while innovators continued to drive impressive advances in 5G, IoT, artificial intelligence, quantum computing and other leading-edge technologies. Equipment sales were rebounding as the industry started to regain momentum. And then COVID-19 sent disruptions rippling throughout the global supply chain. Semiconductor manufacturing facilities scaled back operations. Parts shortages became a problem. Logistical challenges emerged. And, all the while, many workers retreated to their homes under lockdown.The virus forced the industry, en masse, to pivot like never before to ride out the pandemic. This is the most challenging situation that I have experienced in my nearly 40-year career. All of us in the microelectronics industry have dedicated ourselves to rise to the occasion and help others. Among our efforts, we are providing resources to support SEMI members and the industry. Today, we can take heart that manufacturing firms in China are restoring normal operations. SEMI hosted a webinar on March 26 where our colleagues at McKinsey Company shared insights on China as it begins its recovery as well as the broader impact of the pandemic on the microelectronics manufacturing and design supply chain. You can read about McKinsey’s insights in a recent SEMI blog.In my closing remarks at last month’s webinar, I asked the industry to donate masks, gloves and additional personal protective equipment (PPE) to support our overwhelmed healthcare systems. The battle against the virus rages on around the globe. These donations will help people, businesses and whole economies to heal and recover.I am proud of how generously the microelectronics industry has donated these supplies that, in ordinary times, contribute to the meticulously controlled environments of our industry’s manufacturing facilities, but today can help save lives and bring the pandemic to heel. I ask companies across the supply chain to please explore how you can contribute to this effort. Donation information is available on our Coronavirus Resources webpage under Medical Needs Supply Matching Sites. It’s great to see SEMI members help combat COVID-19, and we are highlighting some of their efforts in news stories and blogs on our Coronavirus News and Blog webpage. We encourage you to submit your story.We know our members are hungry for more COVID-19 insights to help guide their way as uncertainty persists. SEMI is offering a follow-up webinar with McKinsey Company – The Way Forward from COVID-19 – on Thursday, April 23rd from 7:30am to 8:45am Pacific Time. Then, on Thursday, April 30th from 8:30am to 10:30am Pacific Time, the SEMI Americas team will host the virtual forum Semiconductor Outlook—Navigating through Turbulent Times. Bank of America Merrill Lynch will provide an update on semiconductor stocks, IHS Markit a market outlook, and VLSI Research the latest on COVID-19’s impact on the semiconductor industry. The goal of these events is to help you, our members, make more informed business decisions. We look forward to your participation and ask that you please submit questions so that the events are more meaningful for you.We have also added more resources to our SEMI Responds webpage, which lists best practices for company policies, public communications and telecommuting from our Environment, Health and Safety (EHS) and Information Technology Leadership (ITL) groups. The page now includes member survey insights from our Fab Owners Alliance (FOA) and Electronic Materials Group (EMG) on COVID-19 impacts to those communities, along with steps members are taking to maintain business continuity and ensure that their facilities remain safe. A big thanks to members of these groups for participating and sharing learnings with the industry at large. Sustaining operations across the industry has been the focus of work by the SEMI Global Advocacy team the past few weeks. It has continued to lobby for the microelectronics industry to be classified as an essential business in the United States and for similar designations in other countries. Those efforts included a SEMI Americas request for the government of Mexico to designate the semiconductor manufacturing supply chain an essential business, consistent with U.S. guidelines, to help avoid disruptions to the North American semiconductor industry. SEMI Europe sent 22 letters to officials across the continent, three of them to the European Commission, urging governments to allow continuous operations of the semiconductor industry. SEMI Japan has been closely engaged with the central government and sent letters to many Japanese prefectures stressing the critical importance of continuing operations.I am truly proud of how the SEMI team has stepped up around the globe to proactively communicate and support our members with relevant information and best practices related to the pandemic. The outcome of our letters to governments around the globe to seek essential business status has generally been very positive.SEMI also continues to oppose unilateral U.S. export controls that will compromise the ability of the U.S. to export semiconductor manufacturing equipment and materials, as highlighted in a recent Reuters article.SEMI advocacy efforts epitomize our overarching approach to the pandemic: We remain squarely focused on supporting our members during these turbulent times while continuing to lay the groundwork for the industry’s prosperity. Ajit Manocha is President and CEO of SEMI.

Ischemic stroke is the leading cause of long-term disability worldwide, affecting over 13 million people each year and costing tens of billions of dollars. Sensome, a French medtech that offers connected medical devices, has developed micrometric AI-powered impedance sensors that can identify the biological nature of the tissue they touch in real-time. Integration of this proprietary technology into a probe to guide medical devices in arteries (a guidewire) has given rise to Sensome’s first product, Clotild®, which recognizes blood clot types in ischemic strokes so clots can be treated faster to improve patients’ chances of a full recovery. The Sensome technology also helps transform the current standard of care in oncology.SEMI spoke with Franz Bozsak, CEO and co-founder of Sensome, about innovative medical technology trends and how microelectronics plays a crucial role.SEMI: When did your adventure with Sensome start? Bozsak: My former Ph.D. advisor Abdul Barakat and I spun-out Sensome from the Ecole Polytechnique in Paris in early 2014 after receiving a 200.000 Euro grant from the French government. We then developed a micrometric impedance sensor that coupled to machine-learning algorithms to identify biological tissues on contact. We are still integrating this sensing technology with existing medical devices in order to create a new category of smart medical devices that provides physicians with relevant insights during their interventions and treatments. These additional insights aim to render healthcare treatments more effective by reducing the risk of complications and the cost of interventions while improving patient monitoring.SEMI: How are strokes typically treated? Bozsak: Before 2014 the almost exclusive way of treating ischemic stroke was by injecting tissue plasminogen activator (tPA) intravenously in order to chemically dissolve an arterial clot. This treatment approach has severe limitations and can only be used in the first 4.5 hours following the onset of a stroke. In 2015, several randomized clinical trials demonstrated the efficacy of a new treatment modality: mechanical thrombectomy.Medical devices that allow a clot to be removed mechanically either using a grid-like structure (a stentriever) or by aspirating the clot using an aspiration catheter completely changed the paradigm in the treatment of ischemic stroke for up to a third of all patients. This new intervention removes the clot in up to 90% of all cases and can for certain patients be used up to 24 hours after the onset of the stroke.Mechanical thrombectomy is now one of the most effective medical treatments in the world. The clinical data gathered over the past years also shows that, in order to maximize the patient’s chances to lead a life free from disability after a stroke, it is not only a question of getting the clot out but also about how the clot was removed. Removing the clot on the first attempt significantly increases the patient’s chances of recovery – the first-pass-effect that is now the objective when treating ischemic stroke patients. And this is exactly where Sensome wants to help since clot removal after several attempts increases risk for patients. SEMI: How did you improve mechanical stroke treatments?We have integrated our sensor technology into a guidewire, the first device to enter a patient’s blood vessels for navigation to the clot. Once in place, the smart guidewire – called Clotild® – guides the thrombectomy device to provide the physician with information on the clot to help the physician choose the thrombectomy device with the highest chances of achieving the first-pass-effect. SEMI: Medical technology has made astonishing advances over the years. How did Sensome develop the micrometric AI-powered impedance sensors?Bozsak: The development of a product like Clotild® would have not been possible five years ago, and many people considered what we wanted to achieve simply incredible. Today, we can answer those same people: We knew it was almost impossible and therefore we just did it. By combining diverse semiconductor technologies, we were able to build the smallest impedance meter in the world. This was then integrated into a guidewire that can be connected via a transmitter to a tablet that serves as the interface with the physician. The guidewire provides impedance measurements that can be analyzed by a machine-learning algorithm, which in turn identifies the tissue in contact with the sensor. A very diverse team of people, collaboration and several different disciplines such as micro-electronics, data science, biology and engineering were required to make this happen.Our ambitious team has been able to flourish and accomplish their ideas in the very stimulating and resourceful environment of the Ecole Polytechnique, while being embedded into the rich and fertile start-up ecosystem of Paris. It is the combination of all these factors taken together that have made our innovation possible.SEMI: What are the main challenges and what are the market opportunities? Bozsak: Bringing semiconductor technology into the medical field is not a straightforward process. The primary hurdle is the simple fact that medical device production volumes are not comparable with consumer electronics volumes and that development cycles are much longer due to regulatory constraints. Both factors are, at first sight, not necessarily compatible with today’s business model of the semiconductor industry. At the same time, this is also a unique opportunity for the semiconductor industry to diversify and expand into a new field – sensors and, in particular, their seamless integration into the healthcare workflow, are a key driver for the healthcare sector of the future. And to achieve this objective, semiconductor technologies are key. What is beneficial, in my opinion, is that the quality standards and requirements of the semiconductor industry are highly compatible with the needs of the medical device industry.SEMI: Are market fragmentation and the high level of regulation making medtech innovation harder?Bozsak: Both are challenging but very rewarding to pursue since the impact on a patient’s life can be profound. Innovation is harder because many stakeholders are involved in ensuring the success of a medical device launch. The involved, milestone-driven, highly regulated process of developing a medical device and bringing the device to the market assures its eventual success. The development process differs very much from those for normal consumer devices. In our case the beneficiary, the patient, is not necessarily the user of the device but rather the physician. The physician is not necessarily the buyer of the device, but the hospital. The hospital is not necessarily paying the device, but ideally the government.The interests of all these stakeholders need to be satisfied to bring a successful device to the market.SEMI: What are your expectations regarding the future of medtech digital innovation? Bozsak: This is the right moment for the medical device and semiconductor industries to come together. The healthcare sector is not low on medical needs for which innovative ideas exist, and the semiconductor industry has many technologies that can enable these ideas to generate solutions. But to make this happen, both sectors need to collaborate. Working together requires both sides to understand their respective needs and constraints. The earlier the knowledge exchange starts, the more powerful the solutions. SEMI MedTech Forum at SEMICON Europa last year was a wonderful opportunity for Sensome to get this discussion going. We are looking forward to continuing the exchange and push the frontiers of the possible further to create the future of digital healthcare.Franz Bozsak, CEO and co-founder at Sensome, obtained a M.S. in Aerospace Engineering from the University of Stuttgart and a Ph.D. from the Ecole Polytechnique in Biomedical Engineering on the optimization of stents. He is a graduate of the Stanford Ignite/Polytechnique business program. In 2014, he co-founded Sensome and has since built a team of renowned scientists, engineers and doctors to realize his vision of connected medical devices. He was named Innovator Under 35 by the MIT Technology Review in 2016. Serena Brischetto is a marketing and communications manager at SEMI Europe.

SEMI has urged government representatives around the U.S. and world to designate the semiconductor industry as an essential business so operations at companies across the chip supply chain can continue without interruption as the spread of COVID-19 continues. SEMI President and CEO Ajit Manocha assured the U.S. and global officials that SEMI members – the device makers and suppliers of chemicals, materials, components, design tools and equipment at the heart of chip manufacturing – “are employing all measures necessary to maintain the health and safety of their employees and local communities” to help contain the virus. Manocha last week sent letters to the governors of 16 states and the chairs of the National Governors Association, U.S. Conference of Mayors, National League of Cities, and National Association of Counties requesting consideration of the semiconductor industry as an essential business if shelter-in-place or similar orders are issued to curb the spread of COVID-19. More than half of U.S. states have imposed shelter-in-place or stay-at-home orders in the past month. The designation would allow SEMI members to maintain continuous operations to ensure that manufacturing of components for critical infrastructure equipment, the defense industrial base, and other vital technological products and services is not jeopardized. Semiconductors are the foundation of modern electronics and information technology and are critical in helping health workers effectively treat COVID-19 symptoms, Manocha told the officials. The devices also play a central role in containing its spread by enabling artificial intelligence (AI), data analytics, digital communications, telemedicine, robotics, remote health monitoring, telecommuting, online shopping and other digital services.Manocha urged state and local officials to follow guidelines issued on March 19 by the Department of Homeland Security (DHS) Cybersecurity Infrastructure Security Agency (CISA) identifying “manufacturers and supply chain vendors that provide hardware and software, and information technology equipment (to include microelectronics and semiconductors) for critical infrastructure as ‘essential critical infrastructure workers.’” Most states issuing shelter-in-place or stay-at-home orders have followed the DHS guidelines and/or separately designated the semiconductor industry an essential business. Likewise, other nations have recognized the power of technology in effectively containing COVID-19 and similarly designated the semiconductor industry an essential business.On March 27, SEMI, the Semiconductor Industry Associations in China, Europe, Japan, Korea, Singapore, Taiwan and the U.S., as well as several other trade associations in Asia issued a statement “calling on all governments to specify semiconductor industry operations as ‘essential infrastructure’ and/or ‘essential business’ to allow continuity in operations.” The global semiconductor supply chain forms a highly intricate network consisting of research, design and manufacturing operations. Operating restrictions in one region can compromise production in others, leading to inefficiencies and breakdowns that cascade across the supply chain.With semiconductors underpinning vital sectors of the global economy, the chip associations called on all global governments at all levels – central, states, provinces and localities – to help protect the uninterrupted operations of domestic semiconductor companies and their suppliers by applying the essential infrastructure or essential business designation.Joe Pasetti is Vice President of Global Public Policy and Advocacy at SEMI.

Skills are the key to the future. It is thanks to its skilled workforce that Europe will reap the benefits of the green and digital transitions and remain competitive. At the same time, upskilling and reskilling is a clear social policy because it ensures that workers can more easily navigate from one job to another.Microelectronics is at the crossroads of many sectors, such as the automotive industry, manufacturing, health, and energy. The European electronics industry is facing an acute shortage of skills in all tiers of its value chain, particularly in electronics design, both digital and analog, and in system and software engineering. A sustainable provision of qualified personnel is key to maintain competitiveness and innovation leadership. Yet, companies in this area suffer from a critical shortage of engineers with competence in microelectronics technology and design. The rapid evolution of the electronics industry calls for a continuous update of skills and knowhow.Vocational education and training has an important role to master these challenges. Modern, inclusive and dynamic vocational education and training programmes are a pre-requisite to remain competitive in the digital age. We must support agile partnerships to develop skills for smart industrial specialisation and the green and digital transitions. Everybody must be on board to shape the workforce transformation in Europe: industry, social partners, education and training organisations, as well as policymakers. The Blueprint for sectoral cooperation on skills launched in 2016 is an excellent model for strategic collaboration and will be extended.The Commission has recently proposed an update of our successful Skills Agenda for Europe. One key element is the new Pact for Skills, in order for all stakeholders to generate new concrete commitments to invest in upskilling and reskilling. It will help us to respond to the extent and speed of change in the economy and society. I warmly invite the microelectronics industry to participate in the Pact.I welcome the fact that SEMI and its 19 partners from 14 countries launched METIS – MicroElectronics Training, Industry and Skills Erasmus+ Project – in November 2019. METIS will receive 4 million EUR EU funding to implement a comprehensive strategy with a view to identify and fill skills shortages, to tackle skills mismatches, and to support upskilling and reskilling in order to address the challenges of the future of work and digitalisation.Nicolas Schmit is European Commissioner Jobs and Social Rights.