semiconductors

New SEMI Taiwan Testing Committee to strengthen the last line of defense to ensure the reliability of advanced semiconductor applications.Mobile, high-performance computing (HPC), automotive, and IoT – the four future growth drivers of semiconductor industry, plus the additional boost from artificial intelligence (AI) and 5G – will spur exponential demand for multi-function and high-performance chips. Today, a 3D IC semiconductor structure is beginning to integrate multiple chips to extend functionality and performance, making heterogeneous integration an irreversible trend. As the number of chips integrated in a single package increases, the structural complexity also rises. Not only will this make identifying chip defects harder, but the compatibility and interconnection between components will also introduce uncertainties that can undermine the reliability of the final ICs. Add to these challenges the need for tight cost control and a faster time to market, and it’s clear that semiconductor testing requires disruptive, innovative change. Traditional final-product testing focusing on finished components is now giving way to wafer- and system-level testing.In addition, the traditional notion of design for testing, an approach that enhances testing controllability and observability, is now coupled with the imperative to test for design, which emphasizes drawing analytics insights from collected test data to help reduce design errors and shorten development cycles. Going forward, the relationship among design, manufacturing, packaging, and testing will no longer be un-directional. Instead, it will be a cycle of continuous improvement.This paradigm shift in semiconductor testing, however, will also create a need for new industry standards and regulations, elevate visibility and security levels for shared data, require the optimization of testing time and costs, and lead to a shortage of testing professionals. Solving all these issues will require a joint effort by the industry and academia. "With leading technologies and $4.7 billion in market value, Taiwan still holds the top spot in global semiconductor testing market," said Terry Tsao, President of SEMI Taiwan. "When testing extends beyond the manufacturing process, it can play a critical role in ensuring quality throughout the entire life cycle from design and manufacturing to system integration while maintaining effective controls on development costs and schedules. Taiwan's semiconductor industry is in dire need of a common testing platform to enable the cross-disciplinary collaboration necessary for technical breakthroughs."The SEMI Taiwan Testing Committee was formed to meet that need, gathering testing experts and academics from MediaTek, Intel, NXP Semiconductors, TSMC, UMC, ASE Technology, SPIL, KYEC, Teradyne, Advantest, FormFactor, MJC, Synopsys, Cadence, Mentor, and National Tsing Hua University to collaborate in building a complete testing ecosystem. The committee addresses common technical challenges faced by the industry and cultivates next-generation testing professionals to enable Taiwan to maintain its global leadership in semiconductor testing.The SEMI Taiwan Testing Platform spans communities, expositions, programs, events, networking, business matching, advocacy, and market and technology insights. For more information about the SEMI Taiwan Testing platform, please contact Elaine Lee ([email protected]) or Ana Li ([email protected]). Emmy Yi is a marketing specialist at SEMI Taiwan.

SEMI and imec are joining forces to drive innovation and deepen industry alignment on technology roadmaps and international standards while adding technology depth to SEMI’s five vertical application platforms including Smart Transportation, Smart MedTech and Smart Data.Under a Memorandum of Understanding announced today at ISS 2019, the two organizations have set their sights on bringing together key industry players to advance cutting-edge technologies including Internet of Things (IoT), artificial intelligence (AI) and machine learning that enable new capabilities across healthcare, automotive and semiconductor manufacturing. The partnership also aims to speed the time to better business results for SEMI and imec members and partners. SEMI brings to the partnership access to the $2 trillion global electronics manufacturing supply chain and imec its global research and development (R D) and innovation leadership in nanoelectronics and digital technologies.Under the MOU, the two organizations will co-produce SEMI Think Tanks, extend SEMI’s International Standards platform to non-CMOS technologies, identify and fill gaps in technology roadmaps, and tighten imec’s engagement with SEMI in European workforce development efforts.Bettina Weiss is Chief of Staff at SEMI.

Region’s Fab Capacity Expansion Picks up PaceUnwavering in its drive to build a strong, self-sufficient semiconductor supply chain, China plans more new fab projects than any other region in the world from 2017 to 2020, and its expansion of fab capacity recently picked up pace on the strength of new foundry and memory projects from both domestic and foreign companies, according to SEMI’s 2018 China Semiconductor Silicon Wafer Outlook report. China’s installed fab capacity is forecast to grow at a 12 percent CAGR from 2.3 million wafers per month (wpm) in 2015 to 4 million wpm in 2020, faster than all other regions.Well known for its semiconductor packaging prowess, China in recent years shifted its focus to front-end semiconductor fabs and a few key material markets. In 2018, the region’s surge in fab investment thrust it past Taiwan as the second largest capital equipment market in the world, behind only Korea. However, China’s semiconductor manufacturing growth faces strong headwinds. Chief among them is the tight supply of silicon wafers over the past two years due in large part to the sector oligopoly’s firm control of global production, with the top five wafer manufacturers accounting for over 90 percent of market revenue. In response, China’s central and local governments has made the development of its domestic silicon wafer supply chain a key initiative, funding multiple silicon wafer manufacturing projects.According to the 2018 China Semiconductor Silicon Wafer Outlook report, many of China’s domestic silicon suppliers capably provide wafers 150mm in size and smaller. And the while the region lags peers in 200m and 300mm processing technology and capacity, strong domestic demand and favorable policies have fueled progress in 200mm and 300mm silicon manufacturing with some Chinese suppliers having reached key large-diameter manufacturing milestones.However, it will take these new suppliers several years before they can meet capacity and yield requirements of the larger-diameter silicon wafer market. Company plans and announcements indicate that by the end of 2020, total silicon supply capacity in China will reach 1.3 million wpm for 200mm, possibly leading to a slight oversupply, and 750,000 wpm for 300mm.China’s equipment suppliers, particularly crystal furnace vendors, are also investing in the development of 300mm wafer manufacturing, and domestic tool suppliers have developed most of the necessary tools for wafer manufacturing, except for inspection.While China’s silicon wafer suppliers continue to lag international peers in manufacturing capabilities, the region’s silicon manufacturing ecosystem is maturing and becoming better integrated. The sector’s growth is driven and accelerated by significant domestic market demand and favorable policies.About the China Semiconductor Silicon Wafer OutlookSEMI’s 2018 China Semiconductor Silicon Wafer Outlook is a comprehensive research report with a Microsoft Excel® workbook containing in-depth analysis of China’s silicon wafer manufacturing ecosystem as it relates to the global semiconductor wafer industry. The report covers the latest developments in China’s silicon wafer supply chain, including details on the rise of China’s silicon manufacturing, polysilicon, and silicon wafer-related equipment companies. The report also examines policies, funding and their implications for China’s silicon wafer supply chain.Clark Tseng is director in Industry Research and Statistics at SEMI.

I really don’t know clouds at all. – Joni MitchellThe semiconductor industry is finally on the cusp of joining the cloud revolution. The cloud has offered the promise of greatly expanded resources for years, but adoption has been slow due to lingering concerns. The biggest contributing factor for the concern over moving from on-premise EDA servers to cloud-based servers is, surprisingly, the rise of third-party IP. In the old days, if you were developing 100 percent of your own IP, and if you put that IP on a public cloud, and it somehow leaked out, well shame on you. That would certainly be bad for business. It might hurt your reputation a bit. But these days, with so much third-party IP being embedded into chips, if that third-party IP leaks out, that’s a lawsuit-fest in the making.Consequently, semiconductor companies now have even more incentive to protect IP with advanced security. Surprisingly, cloud-based security is far, far better than on-premise security. Why? Because keeping customers’ data secure is the central mission of cloud service suppliers, so they’ve developed a rich set of security tools to protect the data that’s entrusted to them by their clients. In many ways, you can maintain much better security in the cloud than you can with on-premise tools. Image credit: Markus Spiske temporausch.com from Pexels Amazon Web Services: Exemplifying the benefits of cloud computingTake Amazon Web Services (AWS) as an example. (Note: AWS is not the only vendor in the cloud space, but it’s one I’m very familiar with.)AWS has developed the concept of security groups – firewalls that you throw up around any network interface to allow only specific traffic into that secured network. You can do that for just one server or for a fleet of servers, in just seconds. Most on-premise server networks won’t let you work that quickly, or as easily, or with such fine control because most such networks lack the security tools to do this.In addition, AWS allows you to encrypt every bit of data stored on and flowing through its cloud-based storage systems. You can encrypt data at rest in on-premise storage but it’s a lot harder to encrypt data flying through the on-premise network. Amazon’s Elastic File System (EFS), a managed NFS file service, offers the ability to easily encrypt NFS traffic on the wire, a difficult feat at best with an on-premise solution.AWS built-in encryption key-management service can rotate encryption keys automatically. The cloud also allows you to have key policies that are easy to implement and maintain.Internal corporate networks rely heavily on perimeter firewalls for security. Perimeter defense just cannot deliver sufficient security against determined hackers and everyone realizes this. We’ve built big, open, on-premise networks that are just not well-suited to implementing adequate security protocols. Trying to retrofit these network architectures with additional security is time-consuming and costly, and it hurts engineering productivity. Moving to the cloud gives you a greenfield opportunity to right some of the wrongs of the past.Continuing with AWS as an example, here are some additional advantages of EDA in the cloud: AWS provides physical security that’s far above and beyond on-premise security. It doesn’t publish the physical locations of its data centers. It also has professional security staff 24/7, keycard access, and additional security features that far exceed typical on-premise physical security. AWS automatically manages security patches and access controls for their managed services such as database services. AWS gives you plenty of security tools to automate security processes, audits, and so forth to protect your data. AWS gives you so much flexibility that you can get yourself in trouble in you are not careful. If you want, you can create the same sorts of security holes that already exist with on-premise networks. You shouldn’t of course, but you can if you’re not thoughtful about things. You just need to hire the right people to implement and maintain your cloud security.Here are five very big differences between AWS (cloud-based) and on-premise server networking: Elasticity: Cloud-based systems enable you to scale up in minutes. That ability has pluses and minuses depending on how disciplined you are. On the plus side, you can quickly grow your EDA infrastructure as big as you want and then shrink it back down when you no longer need the additional capacity. All you need to do is tell the cloud service that you need more capacity and it will bring that extra capacity online for you in minutes – and will charge you for it. (That’s the minus side.) When you’re done, you can turn off the extra capacity (and stop paying for it) with the same speed. If you want to provision more EDA capacity for your on-premise network, you’ll need to beg, borrow, or steal existing capacity from someone else on your network, or you can order more servers, get the vendor to build and ship them, install them in your server room, provision them, and bring them online. That will take months. Fault tolerance: On-premise networks rely on large, monolithic service architectures, which saddle EDA vendors with more than 30 years of technical debt. The cloud operates on a different model, one that’s based on containers and microservices. This is inherently a redundant, fault-tolerant computing model if you write your code correctly. The difference between redundancy in the cloud and in on-premise networks is night and day. There’s no comparison. No private networks can match the available and growing redundancy of cloud systems, which have redundant servers inside of a data center and redundant data centers in multiple, worldwide geographic locations, which protects your data from natural and man-made disasters. Network segmentation: Many semiconductor developers have several design centers distributed around the world and there may be IP in use on a project that cannot be shared with certain geographic locations either by law or by contract. Cloud networks are already set up with automated tools for network segmentation that can enforce geography-specific rules through VPCs (Virtual Private Clouds), which are easy to set up. VPCs allow you to set up subnets with restrictions based on routing tables so that IP management and control become highly automated. Removal of single points of failure: The typical EDA grid configuration has several built-in single points of failure. For example, a central job dispatcher generally runs on one single node. If that node dies, all EDA work halts. The same is true for EDA license servers and for configuration-management and version-control servers. Again, because cloud networks are based on the microservices concept, the cloud simply doesn’t need to have the same single-point-of-failure vulnerabilities that on-premise networks have. On-premise networksTo get these same advantages with on-premise networks, the grid architecture must fundamentally be changed, starting with the replacement of NFS. EDA systems need to replace huge, monolithic file systems specifically developed for EDA with object storage. That's a tall order – one that requires the rewriting of fundamental assumptions that serve as EDA software’s foundation.In the 1980s, 1990s, and early 2000s, small EDA startups appeared to fill gaps in the offerings of the large EDA players. If they succeeded and grew, they’d eventually be gobbled up by a larger EDA vendor. That flowering of EDA startups seems to have damped down. The market has really matured.Next wave of EDA startups to offer cloud-first toolsGoing forward, I expect the next wave of EDA startups will be offering cloud-first tools that are not burdened by three decades of technical debt. They’ll be able to architect their tools specifically for the cloud.We’re starting to see this happen. For example, Metrics, a Canadian EDA startup, offers a pay-by-the-minute, cloud-based simulator and verification manager. Although one job on one cloud server might run slower than a monolithic simulator running an on-premise server, Metrics has architected its tools so that you can throw more servers at the problem, allowing you to run all of your jobs at once. Here, multiple simulation jobs running concurrently on multiple servers will ultimately finish faster than running the jobs serially on one slightly faster on-premise simulator.That’s the kind of innovation that we’re going to see. That’s the future of EDA.Derek Magill is executive director and president at HPC Pros. Derek has 20 years of experience supporting semiconductor engineering functions. His main focus has been in system architecture and technical management, but over the years he has been involved with technologies such as EDA licensing, ClearCase, HPC architecture, IP management and engineering software support. Derek spent 15 years at Texas Instruments in various technical and managerial roles. He is currently a senior manager, IT at Qualcomm managing the Global License Infrastructure team as well as the lead technical architect for the company's engineering cloud activities. The Electronic System Design (ESD) Alliance, a SEMI Strategic Association Partner, is the central voice to communicate and promote the value of the semiconductor design ecosystem as a vital component of the global electronics industry. As an international association of companies providing goods and services throughout the semiconductor design ecosystem, it provides a forum to address technical, marketing, economic and legislative issues affecting the entire industry. The ESD Alliance also stages events that promote networking, learning and collaboration among member companies. To learn more about the ESD Alliance and how to join the group, visit www.esd-alliance.org or contact Bob Smith at [email protected].

We are living in a digital world where semiconductors are taken for granted, AI is bringing semiconductors back into the deserved spotlight, and now we are witnessing the dawn of the Cognitive Era enabled by semiconductors,” SEMI president and CEO Ajit Manocha said to an audience of more than 500 during his presentation – Rebirth of the Semiconductor Industry – at the First Global IC Entrepreneur Conference.Speaking at the Shanghai event in mid-December, Manocha recalled how, when he first entered the semiconductor industry in the 1980s, semiconductors revenue topped out at about $10 billion. Now, with sales having swelled to a staggering $450 billion, the industry is on a much faster growth track. Revenue could reach $500 billion by the end of 2020 and trillions of dollars by 2030. Over the past two decades, chips have given rise to social media and e-commerce powerhouses such as Google, Facebook, and Alibaba. All rely on heavily on chips, the engines of data centers across all industries. Wave after wave of technology innovation have been powered by semiconductors – from mainframe computers in the 1970s, personal computers in the 1980s, the Internet in the 1990s, and mobile and social networking in the early 20th century, to the current shining stars of technology such as IoT, big data, new memory, virtual reality, autonomous driving and artificial intelligence, Manocha said. New applications across areas such as smart manufacturing and digital healthcare are stoking the latest round of semiconductor growth.The rise of AI, like all the technologies before it, has renewed the semiconductor industry once again with its promise to drive growth of all industries worldwide, Manocha said. Five years ago, IoT was but a gleam in a technologist’s eye, more hype than reality with doubt about its viability running deep. Today, with about 60 percent of people in the world connected to the Internet, the enormous promise and potential of IoT is flowering. Industry growth will explode as the melding of AI and IoT birth countless applications and innovations in SMART transportation (0 emissions; 0 fatalities; 0 congestion), smart sensors (agriculture, infrastructure, healthcare) and SMART “Everything” (people, devices, homes, cities, industries, and the list goes on). Indeed, AI is now widely recognized as a chief growth driver of the semiconductor industry well into the future, with semiconductor technology at the core of AI innovation, he said. Semiconductors are thrusting the fifth industrial revolution into the fast lane. China’s much-anticipated rise as an industry powerhouse over the next few years will only accelerate industry growth, turning current disruptions into future opportunities as SEMI China continues to cultivate connection, collaboration and innovation in China’s fast-growing semiconductor sector.Cherry Sun is a marketing manager at SEMI China.

Five young dancers bathed in a striking rainbow of colors with their silhouettes cast in the background dazzled SEMICON Japan 2018 attendees at the opening ceremony in mid-December. Gone were the standard opening keynotes and ribbon cutting, replaced by live performance and media art set against a dramatic black backdrop. There was no mistaking the wide-eyed looks of wonder in the audience.In its sheer vibrance, the opening ceremony thrilled with an excitement that seemed to embody the extraordinary growth expectations for the global semiconductor supply chain over the next five years, with the industry poised to double sales from $2 trillion to a staggering $4 trillion – a phenomena SEMI president and CEO Ajit Manocha has called The Rebirth of the Semiconductor Industry. Driving this unprecedented growth will be SMART applications that are transforming industries and applications worldwide, powered by artificial intelligence (AI) and Internet of Things (IoT) technologies.The dramatic scene at SEMICON Japan 2018 was staged by Rhizomatiks, a media arts company that produced the Rio Olympic Games closing ceremony and is famous for its pop music spectacles. The company’s CTO, Motoi Ishibashi, the event’s first keynote speaker, described his team’s development of drones and vehicles guided by motion and precision-control technologies. It was some of these SMART vehicles that maneuvered the opening ceremony performers from the dance company Elevenplay onstage. Only Rhizomatiks, Ishibashi said, has this capability. In its mission to enrich people’s lives through new media arts, Rhizomatiks uses the latest virtual and mixed-reality technologies to orchestrate not only dance performances but music videos, commercials, fashion shows and festivals.Toru Nishikawa, the second keynote speaker and CEO at Preferred Networks, a leading Japan-based developer of deep learning software programs, surprised the SEMICON Japan audience with his discussion of his company’s work to develop a specialized chip for deep learning processing, joining technology giants Apple, Google, Alibaba and Microsoft in chip design. As more IT and software companies develop specialized, differentiated chips, the devices are quickly becoming the heartbeat of SMART technologies. The company’s approach has taken hold. Only four years old, Preferred Networks is enjoying rapid growth by working with global powerhouses including Toyota, NTT, Panasonic, Fanuc, NVIDIA, Intel and Microsoft. Ishibashi’s and Nishikawa’s fresh visions and the media arts extravaganza reflected the success of SEMICON Japan, held again at Tokyo Big Sight: The event’s 1,881 booths – filled by 727 exhibitors from 14 regions – was the highest count in six years. With Japan home to companies that supply about 40 percent of semiconductor equipment and materials worldwide, top suppliers historically have occupied the largest spaces on the SEMICON Japan show floor.According to IDC, personal computers and smartphones, long the largest revenue sources for the semiconductor industry, will remain top revenue drivers in the coming years. But revenue from new SMART technologies for applications such as automotive and factory automation is growing, a trend expected to continue with a 2018-2022 CAGR of 9.5 percent for automotive and 5.2 percent for manufacturing, compared to 1.1 percent for PCs and 2.9 percent for smartphones.SEMICON Japan’s new SMART Applications zone highlighted these and other new market opportunities for semiconductor growth with product and technology exhibits from companies including Bosch, IBM, Microsoft, NEC, Preferred Networks, Sony, SAS, Siemens, Tesla and Toyota. But the zone wasn’t all work and no play. The ROBOT SQUARE and SPORTS x IOT robot exhibits took visitors back to their school days, with robot anime – from Astro Boy to Gundam and Evangelion – that they could ride and control! As the World Gets Smarter, So Must SEMICON and the IndustryWe all agree the world is getting smarter at a fast pace. New cars are easier to drive – some models are almost fully autonomous on highways and streets. Your SMART speaker has gone well beyond an audio playback device and is more like a home AI platform. Almost all storefronts are equipped with video cameras. Your workplace, whether an office or a factory, is driven by automation. The reliance of these environments and devices on semiconductors is driving exponential chip and changing the world. Businesses need to adapt and so do SEMICON events. We’re doing just that as SEMICON Japan 2018 demonstrated – from an opening ceremony enabled by technology innovation to new faces of the industry to the SMART Application zone. As the SEMICON Japan presidents’ reception concluded the first day of the show, a robot from the ROBOT SQUARE suddenly appeared in the reception hall in front of about 250 executives from the global industry. Everyone at the reception was impressed and stepped forward to the stage, reflecting the overall excitement about SEMICON Japan, which for many years showcased only chip manufacturing equipment and materials. This year, to keep pace with the changing world, it was much more than that.SEMICON Japan 2019 will again take place in December at Tokyo Big Sight. However, organizers of the Tokyo Olympics will be using the East Exhibit Hall usually occupied by SEMICON Japan to prepare for the games. As a result, SEMICON Japan will be held in the West and South Halls instead. Look for more changes to the event. I hope to see you next year!Jim Hamajima is president of SEMI Japan.

4 Key Takeaways from SEMI Taiwan Member ForumThe rapid development of artificial intelligence (AI) has accelerated the digital transformation in various industries and has now fused with Internet of Things (IoT) to exploit the value of both technologies in reshaping the electronics industry value chain. As it emerges from the shadows of its parent technologies, AIoT is giving rise to new opportunities in manufacturing, healthcare, transportation, and even energy. AIoT is fast rising in prominence as an enabler of key electronics manufacturing process improvements and the creation of add-on value to existing products – both critical to the success of many businesses.SEMI and the SEMI MEMS Sensors Industry Group (SEMI-MSIG) held a technical forum on smart sensing and its applications in AI and AIoT, inviting renowned experts in sensors and edge computing to share in-depth insights into the latest AIoT technologies and applications with more than 100 industry professionals in research and development, marketing and sales. Here are four key takeaways from the SEMI Taiwan member forum.1. Steady Growth for Global Sensors MarketThe global sensors market’s steady growth is expected to expand at a CAGR of 6.6 percent from 2017 to 2023, with Asia driving the biggest gains and automotive leading the segments – including healthcare and education – with the strongest growth. Automotive alone is expected to reach US$34 billion in 2023.2. Integration Critical to MEMS Sensors DesignsWith AI booming, MEMS sensor designs need to drive toward greater integration —not only integrating data collection with sensors, but also streamlining data processing on the backend – making 3D models of today’s MEMS mechanical designs critical. The differences between 3D and entrenched 2D models are dramatic, elevating the importance of specifying manufacturing steps in MEMS designs. As new sensors and applications continue to emerge, companies that develop the most powerful integrated designs will win. 3. Growth of Smart Voice-Control Applications to ExplodeAIoT is also accelerating the development of smart voice-control applications and the rise of new related business opportunities. Just 50 million voice-controlled devices shipped worldwide in 2017, a number predicted to swell to 436 million in 2021 with smart home devices such as set-top boxes and smart TVs the major growth drivers.4. AIoT Eyed to Make Human-Robot Collaboration SafeSafety is an essential feature for human-robot collaboration. Tactile sensing technologies give robots a layer of “skin” with capabilities rivaling human touch. To ensure humans and robots work together safely in work environments, sensors on this layer of skin are concentrated – less than 8mm apart, equivalent to the width of a human finger, with a response time of less than 5ms on contact. More than 4 million robots worldwide are expected to be upgraded with these sensing technologies and are on track for deployment in pilot plants in the next three years.SEMI-MSIG is committed to strengthening connections across all sectors in the MEMS and sensors supply chain, working closely with the industry to accelerate the development of related technologies and applications in both mature and emerging markets. In addition, SEMI-MSIG hosts regular events to inspire business opportunities and technology exchange for innovative applications, while enhancing the visibility of members among global customers and partners to help them forge new partnerships. To join the group, contact SEMI Taiwan’s Helen Chen at [email protected] Yi is a marketing specialist at SEMI Taiwan.

From measurement equipment and components to medical devices, SEMI will showcase SMART technologies at its Smart Starts Here Pavilion, booth 40761, in the Smart Home section at CES, the world’s largest consumer electronics event. Do you want to discuss new technology directions and the latest developments in sensors, displays and electronics manufacturing? Hear about the new SEMI program that promotes “cool” careers in semiconductor manufacturing? Get the outlook for the manufacturing supply chain in 2019 and beyond?Stop by our booth or connect with any of our co-exhibitors in the Smart Starts Here Pavilion at booth 40731 in the Sands Expo Hall A. Co-exhibitors include:Advantest – A world-class technology company, Advantest is a premier manufacturer of measuring instruments used in the design and production of electronic instruments and systems. The company also focuses on research and development (R D) for emerging markets that benefit from advancements in nanotech and terahertz technologies and has introduced multi-vision metrology scanning electron microscopes essential to photomask manufacturing, as well as a groundbreaking 3D imaging and analysis tool.Altergy – Alertgy’s Glucose Monitor is a biosensor-based wristband device that provides non-invasive, real-time blood glucose monitoring for diabetics. The device gives both patients and healthcare professionals on-demand access to blood glucose levels via a smartphone application. C2MI – C2MI is the largest microelectronic innovation centre in Canada. Offering state-of-the-art equipment dedicated mainly to advanced packaging and microelectromechanical systems (MEMS), the centre hosts more than 250 R D scientists. Collaboration and synergy among our partners promote rapid commercialization of advanced prototypes.CHASM – CHASM Advanced Materials is a leading developer and manufacturer of printed electronics materials and battery materials based on proprietary carbon nanotube and ink/coating technologies.Kent Displays – Kent Displays is a global leader in unique eWriter display technology, with expertise in research, development, roll-to-roll manufacturing, and consumer packaged goods design and assembly using the eWriter technology. Kent displays also commercializes and sells the eWriter technology under its brand Boogie Board in a number of global retail markets. mCube – mCube makes the smallest motion sensors in the world. As a technology leader, mCube aspires to be the enabler for the Internet of Moving Things by putting a MEMS motion sensor on anything that moves. With over 500M units shipped, mCube continues to provide the world’s most advanced inertial sensors.Mitsui Chemical – Mitsui Chemical provides chemicals and gases for solutions in energy, agri-system, medical, IoT, and related fields. Mitsui specializes in advanced materials for automotive, ophthalmic lenses, dental, nonwovens, agrochemicals, and packaging. N5 Sensors – N5 Sensors manufactures chip-scale gas sensors that provides reliable gas detection in small-footprint packages. N5’s patented gas sensor technology represents a new era in low-power, microscale gas and chemical sensing that aims to replace conventional gas sensors. N5 is currently offering sensors and modules for integration. Its platform technology enables development of sensors for different gases ranging from toxics such as chlorine, nitrogen dioxide, to explosives such as hydrogen and methane, to environmental gases such as carbon dioxide.OMRON – OMRON Corporation is a global leader in the field of automation based on its core technology of "Sensing Control + Think." OMRON's business fields cover a broad spectrum, ranging from industrial automation and electronic components to automotive electronic components, social infrastructure systems, healthcare, and environmental solutions. Established in 1933, OMRON has over 36,000 employees worldwide providing products and services in 117 countries. In the field of industrial automation, OMRON supports manufacturing innovation by providing advanced automation technologies and products, as well as through extensive customer support, to help create a better society. PlayNitride – PlayNitride’s PixeLEDTM display can be used in addition to traditional displays. Focused on GaN-based MicroLEDs, PlayNitride, a fabless company, offers an innovative mass transfer process and SMAR.TechTM pixel repair technology. PlayNitride also provides a broad range of products and services including research and development in the field of compound semiconductors.Si-Ware - Si-Ware Systems' NeoSpectra specializes in the design and manufacturing of Microelectromechanical Systems (MEMS) powered miniature Fourier Transform InfraRed (FT-IR) spectrometers, or spectral sensors. Its sensors are affordable, robust, and easily adapted for a diverse range of industries.TEL - A leading global provider of semiconductor and flat panel display (FPD) production equipment, Tokyo Electron Limited (TEL) develops, manufactures and sales a wide range of products. All of TEL's semiconductor and FPD production equipment product lines maintain high market shares in their respective global segments. TEL provides outstanding products and services to customers through a global network of approximately 75 locations in 16 countries in the U.S., Europe, and Asia.ULVAC - ULVAC is a leading supplier of production equipment for the semiconductor, FPD and solar cell industries. Semiconductor products include MEMS release equipment, the ENTRON metallization system with PVD/CVD/ALD capability, etching systems for various applications including solutions for LED, power device and non-volatile memory. The systems and components are designed with innovative production technology for cost-effective device fabrication.Uneo - UneoTM offers high-quality sensor manufacturing services and product module design and consultation support to shorten product design cycles.Heidi Hoffman is senior director of Technology Communities Marketing at SEMI.

Environment, Health and Safety (EHS) has steadily evolved to become a key element within SEMI’s Advocacy and Standards activities. On November 29th, 2018, nearly 60 members representing equipment, materials and device manufacturers gathered at SEMI’s Milpitas headquarters for our first EHS Summit. The main agenda for the day was related to discussing the new “EHS 2.0” strategy – and priorities – to better align with the current landscape facing members in various parts of the world. “SEMI will not compromise our commitment to EHS,” said SEMI president and CEO Ajit Manocha in is kickoff speech at the Summit, calling on members to rise to the challenge. “We also understand the importance of EHS for our industry. SEMI EHS staff is here to facilitate a program that achieves the highest priorities of our members – but we need you, our members, to be clear on your priorities.” SEMI’s EHS program has had many successes globally, including a strong suite of safety standards, since it launched in the 1980’s. Since then, exponential growth of EHS regulatory requirements worldwide has intensified pressure on members to become more transparent on environmental and social issues. The pressure to disclose on EHS performances has become more visible and challenging for members to manage across the entire supply chain. During facilitated breakout sessions, members were invited to share their views on various industry issues. Some of the most pressing raised related to changes in the REACH European Regulations, or implications from the Stockholm Convention that will affect what products or hazardous chemicals can be used. Some of the topics identified throughout the day included: Circular economy/green/sustainability Global RoHS and REACH regulations Used equipment machine safety Current and future prohibited substances tracking such as Perfluorooctanoic acid (PFOA) After the summit’s success, SEMI is now planning three EHS summits in 2019 and other events to further address the various issues facing members. To receive invitations and stay abreast of SEMI’s EHS activities, please join our EHS interest list by clicking here. Olivier Corvez is senior manager of Environment, Health, Safety and Sustainability at SEMI.

Orders for critical subsystems evaporated in the second half of 2018 after a very strong start to the year. Subsystems suppliers have been left with depleted order books after OEMs accumulated large inventories as the market for wafer fab equipment cooled off. Although overall critical subsystems revenue growth for 2018 is forecast to come in at +5% YoY, this year has been a tale of two halves with a bumpy ride for the critical subsystems supply chain along the way.The year started very strongly with overstretched OEMs switching from a “just in time” ordering strategy to panic buying and over ordering critical subsystems “just in case” as they battled to keep up with equipment demand from chipmakers. However, falling memory prices and technology push outs from major chipmakers in Q2 saw a sharp reduction in capex and demand for equipment. The whiplash effect through the supply chain has been severe and critical subsystems suppliers running at full capacity were unable to stop fast enough.Comparing inventories of vacuum processing OEMs (major consumers of advanced critical subsystems) and critical subsystems suppliers, warning signs for subsystems suppliers were apparent after the Q2 quarterly earnings reports. After OEM inventories surged in Q2, critical subsystems supplier inventories spiked in Q3. The overproduction of subsystems leading to this spike suggests that the OEMs had been promising orders to subsystems suppliers but turned off the buying as they too struggled to shift their own products earlier in the year. Suppliers of highly customised subsystems such as vacuum valves and power supplies were particularly badly hit. Whereas other subsystems such as vacuum pumps, which can generally be repurposed on other tools or applications, have fared better as the oversupply can be consumed by a wider variety of applications.The bad news does not appear to be finished for subsystems suppliers as Q3 OEM inventories as a percentage of revenue remained at historically high levels, which is a concern in the short term. Nevertheless, the underlying drivers for the industry remain strong and there is light at the end of the tunnel as major fab building projects in Asia appear to be continuing without delay – a promising sign that chipmakers are still intending to increase capacity. There will be a lot of empty fab shells and upgraded clean rooms ready for equipment installations at short notice if required, ensuring that orders for equipment and subsystems will pick up again soon. Although 2018 will appear in the historical data as a flat, if not slightly positive year, it does not quite reflect the bumpy ride that has been experienced by the supply chain along the way.For more information about VLSI Research and Critical Subsystems, visit www.vlsiresearch.com/public/csubs/. Julian West is a technical and market analyst at VLSI Research Europe.