EV Group

Electric mobility, renewable energy and other technology innovations like IoT, 5G, smart manufacturing and robotics all require reliability, efficiency, and compact power systems, fueling the adoption of Silicon Carbide (SiC) and Gallium Nitride (GaN) to support lower voltages in significantly smaller devices. But chip designers must overcome the technological and economical challenges of integrating the two semiconductor materials into power systems.SEMI spoke with Elisabeth Brandl, Business Development Manager at EV Group about trends and new developments within the power electronics industry and the devices' application in smart mobility. Brandl shared her views ahead of her presentation at the SEMI SMART Mobility Forum, 18 February, as part of the SEMI Technology Unites Global Summit, 15-19 February 2021, online event. Join us to meet experts from EV Group and other key industry influencers. Registration is open. SEMI: What is driving new developments in power electronics?Brandl: Globally there are significant changes in infrastructure requirements for communication, automotive and power conversion. We need to look no further than the rising adoption of 5G, electric and hybrid vehicles, and renewable energy as examples of drivers of these changes. The device level, particularly in the field of power electronics, figures prominently in these shifts.The power electronics industry faces a growing number of scenarios where conventional silicon power devices are no longer suitable and are easily outperformed by new architectures mainly based on wide bandgap semiconductor materials like Silicon Carbide (SiC) and Gallium Nitride (GaN).SEMI: What industry challenges is power electronics innovation aiming to solve? Brandl: Power conversion efficiency is very important and needs further improvement as the related losses significantly contribute to the overall power consumption. For green power and a better environmental footprint, renewable energy is crucial, but so is overall power-consumption efficiency, yet the role of power devices is often underestimated. High-frequency and high-power applications, such as data center applications and inverters for renewable energy, where silicon power electronics are reaching their limits, are also important areas in power electronics.SEMI: How will the transition from silicon to compound semiconductor materials help?Brandl: The superior material properties of several compound semiconductors can tackle the need for lower losses in power conversion or better high-frequency behavior. Today, we mainly talk about GaN and SiC power devices as they are materials well-suited to address these needs. However, other materials like diamond and gallium oxide are in development for these applications. Material properties of SiC that enable thinner materials with lower power losses and better thermal behavior address power conversion efficiency as well as form factor challenges. GaN, especially in a high electron mobility transistor (HEMT), can be used for high-frequency applications.SEMI: What enables a better and more cost-effective manufacturability of SiC and GaN power devices?Brandl: For the end customer, a typical figure of merit regarding the cost effectiveness is $ per Ampere or Watt. While this seems simple, the reality is of course more complex. It is important to understand the main cost contributors within the manufacturing area. For SiC, this is clearly the substrate cost. In my presentation, I will show a way to reduce this cost via wafer bonding. For GaN, epitaxy – a method for growing or depositing mono crystalline films on a substrate – is the critical parameter. And of course, yield has a very big impact on cost effectiveness too, which means that good process control including metrology is very important.SEMI: Many semiconductor companies are already transitioning to silicon carbide and gallium nitride. Can you give us an example of a success story?Brandl: All the big power device manufacturers have either acquired or developed their SiC and/or GaN power device technology, so they also see a bright future for these wide bandgap semiconductors in the power device market. The most prominent success story is STMicroelectronics with its SiC MOSFET power devices, which have been implemented by Tesla in its Model 3 vehicles since 2018.SEMI: What is coming next?Brandl: New materials for power devices are being explored, such as diamond and gallium oxide. For SiC, the trend is moving toward 8-inch substrates, which is the focus of the funded EU project REACTION under the coordination of STMicroelectronics. Cost reduction and substrate availability also play a big role. All major power device manufacturers have contracts to secure the supply chain for SiC substrates because material availability is the main uncertainty at this time. Finally, collaborations along the supply chain are crucial and generally beneficial for all parties, as development requirements are better communicated and prioritized.Elisabeth Brandl is Business Development Manager at EV Group. She received her master in technical physics from the Johannes Kepler University Linz, Austria in Semiconductor and Solid State Physics. Since 2014, she has been responsible for Product Marketing Management for temporary bonding and compound semiconductors at EVG. The SMART Mobility Forum is the digital platform of SEMI Europe’s Global Automotive Advisory Council (GAAC) for industry stakeholders along the automotive and electronics value chains, from Design, Semiconductor Equipment and Materials Suppliers to Automotive OEMs.Smart Mobility is one of four SEMI initiatives focused on building communities, content, and activities around critical and emerging electronics markets. Read more about our Regional Chapters.Serena Brischetto is senior manager of Marketing and Communications at SEMI Europe.

According to market research and strategy consulting firm Yole Développement (Yole), the total market size of MEMS, sensors and actuators will double from $48 billion in 2018 to $93 billion in 2024.[i] The consumer market will continue to drive volume, with applications such as smartphones making up for in volume what they lack in average selling price (ASP). Stronger demand in automotive, biomedical/health, industrial, and voice-first applications (such as smart speakers) will support this upward trajectory. With so much growth ahead of us, how will the design and manufacture of MEMS keep pace with industry demand for higher levels of innovation and integration, lower cost and lower power, smaller footprints, and faster design cycles — all while meeting acceptable price points?We turned to a handful of MEMS manufacturing experts from SEMI-MSIG who will join us at SEMICON West 2019, July 9-11 at the Moscone Center in San Francisco, to explore the complexities of keeping pace with market demand for MEMS over the next decade.Address the Design GapMentor GM, ICDS Division Greg Lebsack and SoftMEMS President Mary Ann Maher see tremendous progress in the manufacturing supply chain for MEMS. At the same time, they acknowledge the significant gap that still exists in design capability for creating the billions of interconnected sensors required for future applications. Greg and Mary Ann will dive into the standards, ecosystem requirements and collaborative design solutions that will allow the micro-sensors industry to meet demand for next-generation wearables, Internet of Things (IoT) products and medical devices.Get Collaborative with Greg and Mary Ann: Addressing the Design Gap to Enable Next Generation Sensor-Based Products, SEMICON West, TechTALKS South, Thursday, July 11, 2019, 10:35-11:00 a.m. Register today.Get to a Really Big NumberFrom thousands of sensors and actuators in a single airplane to hundreds in a single car or a piece of factory equipment to the twenty-plus that ship in each of the hundreds of millions of the world’s smartphones, we aren’t even close to reaching the saturation point for these intelligent devices. SPTS Technologies EVP GM David Butler isn’t living on the Spaceship Enterprise (or the Millenium Falcon, come to think of it) when he says that we are going to get to a trillion sensors. It is going to happen. The questions are: how and when?Connect with David: Enabling the Age of a Trillion Sensors, SEMICON West, TechTALKS South, Thursday, July 11, 2019, 11:00-11:25 a.m. Register today.Shift to Automotive-GradeDemand for optical sensing technologies such as LIDAR is shifting sensor manufacturing requirements from consumer- to automotive-grade, with its enhanced lifetimes, temperature cycling and higher performance specifications. To meet demand, manufacturers are turning to wafer-level processing, since it complies with the hermetic sealing and dew-point control required for the more rigorous automotive-grade applications. EV Group Business Development Director Thomas Uhrmann, Ph.D., will provide an overview of the steps for manufacturing optical elements, including integration with CMOS circuitry, as he offers a window into the future of automotive packaging for sensors.Tune in with Thomas: Future Manufacturing Requirements for Automotive and Photonics Sensing, SEMICON West, TechTALKS South, Thursday, July 11, 2019, 11:25-11:50 a.m. Register today. Measure Twice, Cut OnceFaster time-to-market, improved device yield, and greater productivity in high-volume manufacturing are increasingly critical requirements for MEMS manufacturers. When a single manufacturing error can cost hundreds of thousands if not a million or more dollars — as well as months of development time — designers can save both time and cost by employing an integrated approach to MEMS design. Lam Research Sr. Director of Strategic Marketing David Haynes will explain how simulation, verification and process modeling can address MEMS-specific engineering challenges such as multi-physics interactions, process variations, MEMS + IC integration, and MEMS + package interaction. Using the right tools before committing to actual fabrication can make or break a project.Get Conceptual (and Practical) with David: Enabling Better MEMS from Concept to High-Volume Production, SEMICON West, TechTALKS South, Thursday, July 11, 2019, 11:50 a.m.-12:15 p.m. Register today.Navigate a Dynamic Foundry LandscapeWe’re still living in a one product-one process world when it comes to MEMS manufacturing. This makes bringing a new device to market both time-consuming and expensive. These challenges aside, the functional capabilities of MEMS, combined with small-footprint and low-power options, have made MEMS increasingly popular. How are market dynamics in MEMS manufacturing evolving to accommodate both demand for high-volume, lower-cost products such as MEMS microphones as well as high-value, lower-volume products such as biomedical devices, IoT products and industrial sensors? Rogue Valley Microdevices Founder CEO Jessica Gomez will explain how foundry consolidation through acquisition, collaboration with other ecosystem players, and specialization in vertical markets such as biomedical or optical are some of the approaches that are transforming the MEMS foundry landscape.Join the Evolution with Jessica: Consolidation, Collaboration, Specialization: How Will MEMS Fabs Manage Changing Dynamics, TechTALKS Stage South, Thursday, July 11, 2019, 12:15-12:40 p.m. Register today.i“Status of the MEMS Industry report,” Yole Développement (Yole), 2019 Edition.Maria Vetrano is a public relations consultant at SEMI.

SEMI-MEMS Sensors Industry Group (MSIG) welcomed a global group of industry executives to its 14th annual MEMS Sensors Executive Congress (MSEC), October 29-30, 2018 in Napa, Calif. MEMS and sensors represent a robust sector of the electronic industry. Analyst firm Yole Développement expects the global market for MEMS and sensors to double in the next five years, reaching $100B by 2023, spurred by growth of autonomous mobility products such as Internet of Things (IoT) devices, autonomous cars, fitness and healthcare wearables, and agricultural sensors.“From drones that navigate any terrain in all lighting conditions, robo-taxis that ‘smell’ cigarette smoke, and sensors that monitor animal welfare and food safety, MSEC speakers shared inventive use cases representing new opportunities for MEMS and sensors suppliers,” said Carmelo Sansone, director, MEMS Sensors Industry Group. “Our keynote speakers spurred attendees to collaborate for the greater good. MITRE Corp. cybersecurity expert Cynthia Wright exhorted attendees to proactively address cybersecurity. DARPA Microsystems Technology Office (MTO) program manager Ron Polcawich invited participation in a rapid innovation and production concept that could dramatically speed design cycles for new MEMS. They exemplify the cross-pollination among commercial industry, government and academia that will continue to advance MEMS and sensors.”Getting serious about cybersecurityMITRE cybersecurity expert Cynthia Wright opened MSEC 2018 with a keynote on cybersecurity, alerting attendees to a topic that few in the industry have explored in-depth — but to which they need to pay attention.“Billions of connected mobile devices democratize knowledge, diversity and boost economies, and accelerate innovation by connecting humans to one another and to our environments,” said Wright. “At the same time, they easily create huge networks that carry operationally and personally sensitive data.”Because MEMS and sensors are deeply embedded into this vast array of connected devices, industry needs to get involved now or risk potentially grave consequences, claimed Wright. “From the destruction of critical infrastructure, cyberattacks on life-critical medical devices such as insulin pumps and heart monitors, and intrusions on autonomous vehicle safety systems, MEMS and sensors suppliers have a responsibility to help improve cybersecurity of connected devices,” she added.Allaying the potential fears of a roomful of suppliers envisioning complete redesigns of their products, Wright said that not every device requires the same level of security, and suppliers can make a difference with even “minor tweaks.” Wright suggested encryption at the edge and process authentication. She also gave MSEC attendees a list of design precepts: Build it in. Don’t bolt it on — Design your device with security in mind instead of retrofitting it after-the-fact to realize the most elegant design. Beware of shadow IT — You can’t protect what you don’t know about. Consider physical asset security; software/sensor-guided decision-making; personal or operational data collection; and key process control. Realize your points of vulnerability — because MEMS and sensors are susceptible to spoofing. Learn from cyberattacks of the past — even if they have not been tied directly to MEMS/sensors. Understand IoT software — Realizing that IoT software acts on what the hardware tells it, pay attention to altered sensor data that can lead to altered system performance. When asked about the role of US government regulation on the security of connected devices, Wright acknowledged that Europe has more restrictive cybersecurity guidelines than the US.“At the same time, it does not make sense to have two different approaches to cybersecurity of devices. US suppliers who implement more security measures can sell to both markets and to other parts of the world.”If she could leave MSEC attendees with a closing thought, it might be that companies “don’t need to put a firewall on a toaster.”“Not every chip has to be secure-foundry secure, but it would be nice if even 10% could hit that mark,” added Wright.Rapid Innovation through CollaborationIC designers typically enjoy three to four design cycles in a calendar year, leading to swift advancement of electronics over subsequent years.Designers in the MEMS community, however, generally have access to one design cycle or less per year, and typical time-to-market is four years for a new product. That slow fabrication pace has hindered deployment of innovative MEMS designs — and it’s something that MSEC closing keynote speaker, Ron Polcawich, program manager, DARPA MTO, would like to change.Polcawich’s vision of government collaboration with industry and academia spawned the investigational Rapid Innovation through Production MEMS (RIPM) Workshop, which Polcawich and his team held in May 2018. During his keynote, Polcawich shared lessons learned from the workshop while inviting MSEC attendees to get involved.Before RIPM can become a program, Polcawich knows it will require definition. What would a program concept look like? What is the best way to articulate the potential benefits to the MEMS community, and what additional inputs would be needed?“This is a daunting challenge from a program planning perspective,” said Polcawich. “In developing RIPM, we realized that we needed representatives from the entire MEMS ecosystem – integrated device manufacturers, or IDMs, equipment suppliers, foundries, and materials’ providers — to literally come to the table to tackle a common goal. Given the potential for the MEMS industry at large to benefit from rapid innovation and production, we hoped that competitors would realize that leveraging established MEMS processes could deliver significant benefits over the historically entrenched approach: one product, one process.”Polcawich believes that MEMS suppliers might relinquish the one product, one process paradigm if they knew that their IP were secure.“While technical challenges to realizing RIPM abound, we knew that we could tap the MEMS industry’s vast knowledge base to address them,” he said. “IP protection is an equally complex issue, and one that may bear a range of approaches. One model could ensure that each IDM owns their IP while the foundry owns the process technology, which it licenses to other companies through process development kits. In addition to speeding innovation, it also provides new revenue sources for the industry.”Polcawich sees RIPM as a win-win for both commercial industry and for the DoD. Speeding design-to-deployment of new MEMS devices could open new and larger markets to MEMS suppliers. It could also support greater product-line diversification and new revenue streams for foundries and other ecosystem members. The DoD could tap new MEMS devices for strategically important applications like tactical radios, unmanned aircraft systems such as drones, and image autofocus for cameras. Polcawich encouraged SEMI-MSIG members to get involved by emailing his group: [email protected] Hall of Fame MembersThree new industry leaders joined the SEMI-MSIG Hall of Fame, first established in 2011 as a means of honoring those who have made a substantial contribution to SEMI-MSIG. Selected by members of the Governing Council, 2018 Hall of Fame inductees include: Michelle Bourke, strategic marketing director, Customer Support Business Group, Lam Research Eric Pabo, business development manager, MEMS, EV Group Yoshio Sekiguchi, senior strategic advisor, TDK InvenSense Technology Showcase WinnerMSEC recognizes the latest advancements in applications enabled by MEMS and sensors — including those demonstrated by entrepreneurs competing in the Technology Showcase. Selected by a committee of industry experts, five finalists did their best to impress attendees with their technical approach and go-to-market strategies. The 2018 Technology Showcase winner, Alertgy, presented a biosensor-based wristband device that provides non-invasive, real-time blood glucose monitoring for people with type 2 diabetes, which affects more than 20 million Americans and hundreds of millions more worldwide. MSEC 2018 Sponsors MSEC 2019 Location and DatesMSEC 2019 will take place October 22-24, 2019, at the Coronado Island Marriott Resort Spa in Coronado, Calif., just minutes from downtown San Diego.For more information on MSEC 2019 and other SEMI-MSIG events and programs, please follow @MEMSgroup on Twitter, visit MSIG at SEMI and subscribe to SEMI’s weekly newsletter, SEMI Global Update.Maria Vetrano is a public relations consultant at SEMI.