semiconductor industry

In the past 3 months, silicon wafer shipments leveled off and the YoY growth rate had started to rebound, SEMI reported in Silicon Wafer Market Monitor, a new quarterly report that tracks wafer shipment dynamics including historical shipments, supply & demand shifts, and pricing trends & forecasts.

For five days in the latter half of March, the pall of the heavy human and economic toll COVID-19 has exacted in China appeared to be lifting. The epicenter of Wuhan reported no new coronavirus infections through domestic transmission. And in an initial step to loosen its nationwide lockdown, China began reversing restrictions on travel within its borders.Now, in another sign of progress, the region’s idled factory workforce is preparing to return to the production lines. Outside of Hubei province, home to Wuhan, most manufacturing workers are expected to be back on the job by the end of this month, with the proportion of manufacturing employees returning to work in Hubei cities except Wuhan reaching 70 percent by then, said Didier Chenneveau, Partner, Supply Chain Practice, McKinsey Company, in a late-March webinar presented by the business consultancy and SEMI.McKinsey is also “seeing evidence of a rebound in demand led by China’s online sales” as rising consumer confidence and a surge in the popularity of work-from-home policies spur strong spending on laptop computers, Chenneveau said.The turnaround stands in stark contrast to the unprecedented drop in demand McKinsey saw across retail and durable goods in China early in the year. Over the first two months, passenger car sales plunged 90 percent, smart phone receipts 40 percent and retail sales 21 percent, leading to what Chenneveau calls a whiplash effect that could disrupt supply chains as manufacturers and shipping companies scramble to meet pent-up demand once a recovery takes hold. As the outlook for China’s factories and suppliers brightens, concerns are shifting to the ripple effect of its deep manufacturing pullback on demand for goods in the United States and Europe. Sharp disruptions to global supply chains caused by labor shortages and knotty logistics challenges have also become worrisome. And while China is buoyed by the prospect of normalizing its workforce and manufacturing capabilities, parts shortages are bottlenecking production. In the United States and Europe, where 60 percent of air freight is carried in cargo holds of passenger aircraft, logistics concerns loom large with the widespread flight groundings. “Logistics must be a priority in any crisis war room because it’s a big challenge,” Chenneveau said.Asia Semiconductor Supply Chain ImpactsIn Asia, the semiconductor supply chain is working to overcome intractable challenges caused by COVID-19 including sourcing raw materials for chip manufacturing and maintaining assembly and test operations, Mark Patel, Sr. Partner Semiconductor Practice Lead, McKinsey Company, said at the webinar. Those problems cascade to foundries and IDMs even as they confront the compounding issue of a shortage of fab operators and engineers. Downstream, the inability to package, test and qualify products risks exacerbating the supply constraints.Patel said another acute challenge is that most semiconductor manufacturers and suppliers are operating under restricted practices, making it harder to sustain engineering activities vital to new product introductions, new process development and capital equipment expansion. In the longer term, the supply chain fallout hold implications for product life cycles and investments in capacity and next-generation technology – factors that analysts will need to monitor in evaluating the economic impact.Returning Workers Key to Economic RecoveryIssuing shelter-in-place orders have been an effective antidote to the spread of COVID-19 but a double-edged sword as nations worldwide sustain the economic blowback. Discretionary consumer spending on items such as automobiles has dropped by 45 percent globally so far this year, business investment has fallen and trade has seen a sharp slowdown, said Sven Smit, Chairman and Director at the McKinsey Global Institute, speaking at the webinar.A lockdown for as little as a month can slash aggregate global GDP by as much as 10 percent, a scenario McKinsey expects to play out in the second quarter of 2020. The drop would be the deepest since World War II and larger than the plunge in the first quarter of the Great Depression, raising the question of how long governments can afford to keep workers holed up at home.“The economic shock is unprecedented,” Smit said. “We’ve never sent people home to not work. Even in World War II, next to the front lines, people were harvesting food.”China offers a potential blueprint for economic recovery. McKinsey estimates that China’s rigorous containment efforts could help its economy bounce back in as little as six months – a V-shaped rebound. Western nations generally have not been as forceful with their containment measures. For them, the fight against the pathogen could be prolonged, deepening the economic damage.Yet even with the best protective lockdowns, a new challenge arises: The longer shelter-in-place orders remain in effect to contain the spread of the virus, the longer the economic impact drags on. “Until the path to return to work becomes clearer, people will not be confident to spend,” Smit said.Confronted with that reality, governments worldwide must strike the delicate balance between safeguarding the lives of people – critical forces of economic growth through consumer spending – and limiting the economic shock. The faster the virus can be brought to heel, the softer the impact to economies around the world. And the stronger the return-to-work protocols in place once COVID-19 has been brought under control, the faster workers can get back to their jobs. Smit believes resolving both issues simultaneously is not only possible but necessary for a return to normalcy.“That’s the imperative of our time,” he said. Related blog COVID-19: The Way Forward – Insights from McKinsey Company For McKinsey’s latest insights on the coronavirus pandemic, visit its website, which is updated daily.For the latest COVID-19 information and SEMI event updates SEMI is providing members, visit Coronavirus Resources.Michael Hall is a marketing communications manager at 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.

The march of innovation in semiconductor microfabrication technology over the past 60 years has produced electronic devices and information systems that have transformed industries and lives around the world. And while advances in chip technology continue to make it possible to collect, transmit, store and process more data for a rapidly growing universe of applications, the pace of innovation is now facing strong headwinds. Powered by chip innovation, data centers have become massive centers of information processing but, on the downside, enormous consumers of electricity. Today, the power-hungry hubs account for five percent of the world's electricity usage, a proportion that is growing every year, raising important questions about sustainability. Compounding the challenge, the pace of Moore's Law, for decades the engine of electronic device and information system innovation, has slowed. While the research and development of state-of-the-art semiconductor fine processing technology remains robust, developing the advanced manufacturing technology for mass-producing more sophisticated electronics devices is becoming harder, as is ensuring business profitability."It has become difficult for semiconductor technology to continue to evolve as it has in the past," said Akira Minamikawa, Research Director of Technology Research at IHS Markit, who moderated the Semiconductor Executive Forum – View by Top Two in the Era of Digitalization on opening day of SEMICON Japan 2019 at Tokyo Big Sight. Held at the SuperTHEATER, the forum featured Terushi Shimizu, representative director and president at Sony Semiconductor Solutions, and Atsuyoshi Koike, president at Western Digital Japan, two industry powerhouses that could figure heavily in the future of digital technology. SuperTHEATER, the main stage at SEMICON Japan 2019 Image sensors evolve to become eyes of AIImage sensors are becoming eyes of artificial intelligence (AI) and intelligent systems that monitor people and events worldwide, collecting data that one day could help puzzle out growing social challenges such as energy conservation and traffic congestion. With 51 percent market share on the strength of its industry-leading technology, Sony Semiconductor Solutions dominates the image sensor market. Despite last year’s global semiconductor industry slump, the company’s “business continues to enjoy strong growth and we are very busy,” said Shimizu, who attributed the company’s robust performance to the rising importance of the social role of image sensors and the expanding number of applications they support.The success of the company’s image sensors can also be traced to its division of the image sensor market into two application categories: "Imaging" focuses on capturing beautiful image data, while "sensing" aims to collect data that accurately describes the state of a subject and its surroundings."In 2019, sales of imaging products for smartphones grew rapidly,” Shimizu said in his market overview. “This is due to the average annual 15 percent growth rate of multi-camera smartphones, with some phones today featuring seven cameras, and an average annual growth rate of 20 percent in sensor size to produce higher image quality."But Shimizu cautioned that Sony Semiconductor Solutions doesn’t expect the smartphone sensor market to maintain that fast growth rate."The imaging market is expected to grow until 2022, but after that, the sensing market will drive market growth,” he said, adding that the company’s “capital investment plan is based on this scenario."AI will be key in catalyzing growth of the sensor market as integrations of AI processing engines and sensing images grow in sophistication to capture images undetectable by the human eye, Shimizu said. AI will extract insight from captured image data. For its part, Sony will apply its layer stacking technology to sensing products."By stacking an AI processing engine, we want a significant portion of the recognition processing done within the sensor chip," Shimizu said.One sensor the company already offers collects in-depth information for indirect time-of-flight (ITOF) 3D ranging for new user interfaces relying on autonomous or gesture control for robotics. The sensor “was first used in smartphones in 2018 and saw widespread adoption in 2019," Shimizu said.Sony Semiconductor Solutions plans to focus on developing new sensors for integration with their ultrasonic cousins. Aided by optical deflection technology, the sensors will be used for product quality inspections during manufacturing.With the company’s growing strengths in sensor technology, it hopes “to increase sales of sensors from a few percent of the company’s total sales in 2018 to 30 percent in 2025,” Shimizu said, pointing to its goal "to capture 60 percent share of the image sensor market by 2025."Data as one way to spread happinessAt the heart of consumer devices such as smartphones and computers and also cloud servers, NAND flash has made it possible to process vast troves of data anytime, anywhere. In recent years, the technology has enjoyed stronger adoption for use as the storage medium of choice for edge computing, stationed between end devices and the cloud to help streamline data utilization. But the technology isn’t merely about making smarter use of bits and bytes."We would like to promote the technology development that can support the use of data to bring happiness to people around the world," Koike of Western Digital Japan said. The company calls data that contributes to individual happiness and helps solve social issues "data for good" and, like the Sony Semiconductor Solutions bifurcated classification of the image sensor market, categorizes information into “big data” and “fast data.”For example, big data can leverage AI to drive dramatic improvements in the interpretation of test data and, ultimately, the diagnostic accuracy of mammography for breast cancer screening, aiding in early detection to help save lives, Koike said. Fast data can be harnessed to analyze data collected from a manufacturing equipment line in real time to improve production efficiency. The company’s plant in Yokkaichi, Mie Prefecture, which the company operates in cooperation with Japanese memory manufacturer Kioxia, already uses fast data to bolster production.More NAND flash innovation and greater supply capacity are critical to developing "data for good," Koike said. "It is difficult to expand clean rooms at the same pace as data usage grows. In order to continue to advance technology and enhance supply capacity, we need to adopt new ideas for building production lines. We need a smaller equipment footprint, shorter cycle time and higher throughput."Semiconductor market shows signs of recoveryIn their discussion of the short-term outlook for the semiconductor market, Shimizu and Koike pointed to the importance of strengthening the talent pool of Japan’s semiconductor industry as global competition heats up with China’s pursuit of semiconductor independence and the industry pulls out of the 2019 slowdown fueled by weak memory prices. While Sony’s business has been buoyed by strong image sensor demand for smartphones, the devices “did very well, but other applications didn't," Shimizu said. Even the image sensor market stagnated.Despite the 2019 slump, market conditions and capital investments by semiconductor manufacturers have been on the upswing."In the second half of 2019, the Chinese market showed signs of recovery triggered by 5G,” Shimizu said. “In 2020, this movement is going to be in full swing around the world and we will be busier than last year."Koike agreed: "The semiconductor market for data centers will recover with 5G. The hard disk shortage is already an indication of a recovery, a turnaround that will undoubtedly extend to solid state drives (SSDs). In addition, advances in autonomous driving technology will ensure continued growth of the automotive semiconductor industry.”Japan should embrace international competition, not fear China's pursuit of chip independenceIt's no secret that China is investing heavily in its semiconductor development capabilities to move up the microprocessor value chain. Minamikawa posed the question: How should Japanese chip companies navigate the shifting regional balance of power? "It is natural for China to strive to establish domestic procurement of semiconductors that are fundamental technologies for various industries,” Koike said, “I think the efforts of Chinese companies are outstanding in that they are not pursuing short-term results, such as improving yields in the near future, but are making efforts with an eye to achieving results in 10 years. Japan has a variety of options including working with China to create joint ventures and competing head-on. Regardless of which choice we make, however, it is imperative for the survival of domestic companies that Japan maintains its technological competitiveness to remain ahead of China."Shimizu said that Sony’s “Chinese customers are quick to take action and study extremely hard. We often have opportunities to share our roadmap with them and explore innovation opportunities together. Before, they were passive and relied on us for insights into new technologies, but now they are more assertive and I sense that they will start to drive innovation.”Koike added that "although Japanese companies often talk about business globalization, neither Chinese nor American companies say much about it. While global expansion is a major requirement for business, I think Japanese companies need to focus more on the Japanese market overall, not just when they think about the growing competitiveness of Chinese companies." L-R: Akira Minamikawa, Research Director of Technology Research at IHS Markit; Atsuyoshi Koike, president at Western Digital Japan; Terushi Shimizu, representative director and president at Sony Semiconductor Solutions Talent key to bolstering competitiveness of Japan’s semiconductor industryMinamikawa of IHS Markit didn’t mince words in describing the talent shortage in the Japanese semiconductor industry as “grave,” saying that “the workforce challenge is not endemic to the electronics industry as evidence grows that the number of people obtaining doctorates in Japan is falling and the educational level of the Japanese population as a whole is in decline.”Three years ago, Shimizu interviewed professors on Kyushu island for insights into Japan’s talent shortfall. He came away feeling that “Japanese semiconductor companies were not sufficiently communicating the industry's talent and innovation needs to professors. To help professors and students better grasp the appeal and potential of the industry, we have started to send frontline engineers to universities to educate students and instructors about their work and careers. Expecting corporate HR departments to alone solve the talent shortage won’t work.”"In Japan, if you advance to a doctoral course, you will have a hard time getting a job, which is a strange situation,” Koike said. “Companies and universities need to work together more closely to better understand how to attract and hire doctoral graduates."Minamikawa said companies must have strong leaders with clear missions to attract the right talent, but Koike pointed to the drawbacks: "The image of a company with a strong leader seems to be cool, but it also has a downside because engineers stop thinking for themselves and wait for instructions from the top. I believe it is important for company leaders to have ongoing discussions at all organizational levels and lead the way in times of confusion."Shimizu agreed, citing his own company as an example."Thankfully, our company is very busy right now,” he said. “However, some employees are starting to request more time to think about how to improve the quality of their work. To maintain and strengthen our competitiveness and continue business growth, I believe it is important to cultivate an environment that encourages each employee to take more time to think for themselves."Motoaki Ito is the CEO of Enlight, Inc. and a reporter for SEMI. Mayumi Amagai is a marketing manager at SEMI Japan.

We are now in the recovery phase of the current business cycle with SEMI equipment already in a growth mode. However significant economic and geopolitical concerns persist.

When we entered 2019, our priorities in SEMI Global Advocacy were crystal clear: Continue to advance our public policy priorities under the 4 T’s – Trade, Tax, Talent and Technology – and move toward a global reach. We raised SEMI’s profile on the world stage in representing arguably the most strategic industry sector today as we trained our sights on a number of issues across all four pillars, not the least of which was trade. Along the way, we educated key policymakers about the impact of their decisions on the global semiconductor supply chain, member companies and regional economies.While no one organization can resolve current global trade issues, SEMI did exert its influence effectively on behalf of its members. For example, when Japan’s Ministry of Economy, Trade and Industry (METI) announced its decision to tighten export controls with South Korea in July, SEMI immediately engaged METI and Korea’s Ministry of Trade, Industry and Economy (MOTIE) to make clear to METI the potential repercussions of its decision. In parallel, we worked to prevent a retaliatory escalation by MOTIE. Indeed, significant trade challenges remain as tariffs and export controls continue to take their toll on our industry’s globally integrated supply chain. We have much work ahead to ensure our members’ voices continue to be heard. Our well over 100 meetings with government officials this year is only the start of sustained outreach and engagement to better serve our members’ public policy interests. To that end, and based on member input, in 2019 SEMI Global Advocacy made it a priority to restructure to improve communications among our regions around the globe and strengthen member engagement. Each regional office responsible for government affairs is now staffed with a global advocacy liaison. In addition, we have increased staffing in the SEMI Europe office to better address the ever-changing regulatory environment and develop the European Union’s talent pipeline.In SEMI’s advocacy headquarters in Washington, DC, we have filled a new position – Vice President of Industry Advancement and Government Programs – to place greater focus on identifying opportunities to advance programs aligned with member, industry and government interests. We have also filled two additional positions in DC – a Vice President of Global Public Policy and Advocacy and a new Manager of Public Policy and Advocacy – dedicated to public policy work. Both are steeped in experience in trade, export controls and tax policy. In addition, our new Executive Director of the SEMI Foundation boasts expertise in developing and scaling workforce development programs.The end of 2019 culminates the first phase of strategic personnel and program adjustments we envisioned over a year ago and the beginning of more muscular, adaptive advocacy engagement communications. Today, we are in a much stronger position to support you, our members, and meet the public policy priorities established by the SEMI Board of Directors and Board of Industry Leaders. We’re immensely thankful for your continued engagement and look forward to working to advance your interests in 2020 – SEMI’s 50th anniversary!Mike Russo is Vice President of Industry Advancement and Government Programs at SEMI.

High-tech industry clusters in the bustling northern Taiwan port city of Hsinchu look set for an upgrade. Long a world-class hub of the semiconductor and optoelectronic technology industries, Hsinchu City is laying out plans to work with SEMI to attract more international companies, generate more jobs, promote Hsinchu’s development and help grow Taiwan’s microelectronics industry. High-tech heavyweights such as TSMC, UMC, MediaTek, Realtek, and AUO are all headquartered in The Windy City. The Industrial Technology Research Institute (ITRI), a leading Taiwan research center and incubator, also calls Hsinchu home, and the city boasts one of the highest concentrations of educational institutions in the region, a roster that includes National Chiao Tung and National Tsing Hua universities. Hsinchu’s thriving relations with these industry, academic and research partners have made it a hotbed of innovation, with numerous large Taiwanese and foreign companies having opened local offices. No less than these partners, the city – like SEMI – is committed to innovation.In a recent visit to the SEMI Taiwan office in Taipei, a Hsinchu City government team led by mayor Lin Chih-Chien, met with Terry Tsao, global SEMI chief marketing officer and president of SEMI Taiwan, to explore collaboration opportunities in areas such as technology subsidies, policy, education, and infrastructure. The meeting built on a relationship between the city and SEMI Taiwan that sprouted after SEMI executives and Hsinchu officials joined ITRI to host the Autonomous Driving System Platform in Open Fields kick-off ceremony – an initiative to accelerate Taiwan’s adoption of smart transportation technologies – at SEMICON Taiwan 2019.At the meeting, Mayor Lin highlighted that Hsinchu has long attracted high-tech companies by cultivating a business-friendly climate through incentives such as subsidies for infrastructure buildouts. He hopes to work with SEMI to promote to members the benefits of setting up local offices in Hsinchu City.With both Hsinchu’s high-tech clusters and SEMI’s global members deeply reliant on skilled workers for sustaining innovation and growth, Tsao and Mayor Lin agreed that inspiring students to pursue an education and careers in science, technology, engineering and mathematics (STEM) is vital to building a high-tech talent pool. One collaboration opportunity SEMI Taiwan is eyeing is to launch Taiwan’s first SEMI High Tech U (HTU) program in Hsinchu to spark the interest of school-age children through STEM educational activities at school camps or art and cultural centers. SEMI’s STEM discovery program offers hands-on activities and experiential learning led by industry volunteers. Since 2002, HTU has reached some 8,000 high-school students in 12 U.S. states and nine countries.Emmy Yi is a marketing specialist at SEMI Taiwan.

With all major global electronic equipment OEMs having now reported their third quarter financials, we estimate that combined equipment sales increased 0.4 percent in 3Q’19 versus 3Q’18 and 2 percent sequentially from the second versus the third quarter of this year.

Despite a tough year for critical subsystem suppliers, their overall expenditure on R&D has remained at near record levels– evidence that critical subsystems are indeed critical to the semiconductor manufacturing equipment industry and that high R&D spending on these products is essential.