NextFlex

Focusing on applications that help assist movement in people with neuromotor disorders & aging muscle, Georgia Tech is developing a flexible system that uses sensory feedback through EMG to assess muscle and motor neuron health and augments strength through pneumatically actuated artificial muscle.

For the first time in its 20-year history, the FLEX Conference dedicated an entire session to the important and timely twin topics of environmental sustainability and power consumption of electronic devices. The event planning committee recognized the urgent need to increase the awareness of how technology and electronics devices can help reduce greenhouse gas emissions (GGE) overall and meet aggressive targets to curb the impacts of climate change. Dr. Christine Ho, CEO of Imprint Energy, delivered the keynote for the session, focusing on the need for powering billions of sensors that will be deployed annually, and their role in reducing fossil fuel emissions through becoming aware of issues, monitoring our resources over time, and intervening early and often to combat waste in multiple sectors and industry. Quoting extensively from the organization Exponential Roadmap Initiative (ERI), Ho noted that “the digital sector has the potential to directly reduce fossil fuel emissions 15% by 2030 and indirectly support a further reduction of 35% by influencing consumer and business decisions and systems transformation.” The initiative’s playbook for reaching net zero carbon emissions by 2050 and limiting global warming to 1.5° Celsius outlines how the digital sector can help remove 13 of the 27 gigatons (GT) of CO2 needed to reach this goal. Ho stated that the rapidly emerging Internet of Things (IoT), devices, software systems, and data insights are the backbone of this digital transformation. The IoT's vast network of sensors can transform multiple sectors, such as the logistics industry, which on an annual basis moves and ships more than 10 billion tons of products worldwide by ships, airplanes, long haul trucks, and train - contributing 17% of GGE and more than 4 gigatons of CO2 annually. Always-connected IoT sensors used by the logistics industry can reduce waste and damage in the supply chain, which is especially problematic for temperature-sensitive and damage prone pharmaceutical and food products, mitigating the need for producing high volumes of buffer inventory to replace damaged goods Noting that the attendees of 20 Years of FLEX Conferences were a big part of the current advancements of low-cost printed, active, shipping tags, Ho said that Imprint Energy’s flexible and thin, Zinc based batteries are ideal for IoT devices, since they boast a significantly smaller carbon footprint than Lithium-Ion (Li-ion) batteries. Imprint Energy is working with systems designers and integrators to design the battery as an integral part of the device package and use low-power strategies to extend device lifetimes. Imprint recommends co-locating battery printing alongside the device integration to further minimize shipping and logistics. When manufactured separately, Imprint’s small footprint, low-operating temperature process line (less than 80°C) provides significant carbon footprint advantages over other technologies. Ho challenged the attendees, saying “we all need to participate in protecting our earth. We need to eliminate waste and contribute to reducing half of our current greenhouse gas emissions by 2030, and we can do that by deploying a global digital skin with more than 100 billion IoT devices in 2030 and up to 1 trillion by 2050. We can minimize the device carbon footprint and maximize its longevity by considering the power capability, as well as design for re-use and re-cycling of the critical materials.” Following Dr. Ho’s presentation, FLEX kicked off a spirited panel discussion with experts from PowerRox, ITN Energy Systems, Birla Carbon, and Auburn University and chaired by Bob Praino and Eric Forsythe, from Chasm Advanced Materials and the Army Research Labs, respectively. The speakers summarized their on-demand presentations and looked at what is being done today to recycle Lithium-Ion batteries, how IoT devices are currently being powered, and drew comparisons between the early days of the Internet and development of the IoT. The speakers generally agreed that the power requirements of wireless cellular and Blue-tooth devices were still too high and run times too short. FLEX 2021 was a virtual event in the 2021 SEMI Technology Series. It was organized by SEMI FlexTech, SEMI NBMC, and NextFlex. Major sponsors included E Ink and Novacentrix. The event covered technical developments in flexible, printed and hybrid electronics, featuring more than 100 presentations and networking opportunities. Technical proceedings are available until March 26 at http://flex.semi.org. Heidi Hoffman is senior director in Corporate Marketing at SEMI.

If you bought a new car recently, you must have noticed that it warns you if one of its functions needs your attention. It even alerts the factory if repairs or major adjustments are needed. Wouldn’t it be nice to have similar capabilities for our bodies that will call for a “service” before we end up in an emergency room – or worse? The United States invests almost 18 percent of its Gross Domestic Product (GDP) in healthcare. Such a significant part of our economy deserves our industry’s attention – and it gets it. SEMI’s recent Smart MedTech webinar series tells not only patients and healthcare providers how electronic products can impact their lives, but also offers device makers plenty of ideas for developing new solutions.SEMI Gets SmartIn addition to working on many important topics with more than 2,200 member companies across the semiconductor supply chain, SEMI focuses on special areas: Smart Mobility (as covered here), Smart MedTech (covered below), Smart Manufacturing, and Smart Data. Smart MedTech was the topic of four recent webinars, organized by Melissa Grupen-Shemansky, executive director Nano-Bio Materials Consortium (NBMC), and Chief Technology Officer, SEMI. NBMC’s mission is to enable flexible, wearable human performance monitoring. In her introduction, she emphasized that healthcare will shift from today’s provider-centric approach to a personalized care model, with the following characteristics: Outcome-based Decentralized, not limited to geographies Specific to your personal health and medical needs With a team of providers, connected like never before To achieve all these characteristics, microelectronics will be an essential contributor. That is why SEMI and member companies are working on platforms to fund and commercialize R D as well as to educate potential users and beneficiaries. Grupen-Shemansky engaged a series of experts and organized four webinars to address this broad and complex field, and outline their contributions to meeting the above criteria. They have been recorded and are available to SEMI members. Call your SEMI contacts to find out where and how you can access slides and recordings of more than a dozen presentations.From Biomarkers to BioChemical Sensors Physiological RelevancyTo monitor a human body’s performance, researchers have to first understand which biomarkers indicate specific conditions of the body, then learn how to capture and process the data. Grupen-Shemansky moderated this August 5th session. Christina Davis from UC Davis, Jennifer Martin, and Sean Harshman from the Air Force Research Lab (AFRL), and Kenneth Ward from Pacific Diabetes Technologies presented their ongoing efforts in this field.Davis talked about the challenges of analyzing exhaled breath, which contains 99% water and 1% biomarkers. She showed a hand-held analyzer her team has developed (Figure 1). She also elaborated on how to interpret the captured data and, if needed, decide which follow-up treatments are advised.Figure 1: Palm-sized µCON exhaled breath micro-condenser used to analyze biomarkers. (Courtesy: UC Davis) AFRL’s Martin and Harshman outlined how ongoing and future minimally invasive techniques are being used to monitor airmen, and give them advice for self-treatment to maximize their performance. The Pacific Diabetes Technologies speaker, Ward, showed how to use minimally invasive, subcutaneous (=under the skin) oxygen sensors to detect hemorrhage (= blood loss) and control it.En Route Care (ERC) and Point of Care (POC) DiagnosticsTreating injuries right away and correctly shortens not only a patient’s suffering, but also improves his or her chances for a full recovery. AFRL’s Matthew Dalton moderated this August 12th session. Derek M. Sorensen from AFRL, Zheng Yan from the University of Missouri-Columbia, Melinda Eaton from the Virtual Health Program Management Office at the U.S. Department of Defense (DoD), and Azar Alizadeh from General Electric (GE) Research outlined their contributions to achieving instant and professional care.AFRL’s Sorensen described the many challenges a Critical Care Air Transport Team (CCATT) deals with when performing their work inside a noisy, dark, hot, or cold, shaking airplane, discussed their equipment and personnel constraints, and explained how difficult it is, even for experienced doctors, to perform emergency surgeries under these conditions.Professor Yan takes low cost very seriously and demonstrated how he and his students have developed on-skin wearable sensors that can be manufactured by using only pencil and paper.Eaton outlined the DoD’s strategy for assuring its medical force is ready to support soldiers. Then she discussed a broad range of the DoD’s traditional health management responsibilities and added that Covid-19 is now an important factor.Alizadeh addressed how GE microelectronic solutions improve the efficiency of care, reduce medical errors and length of hospital stays as well as improve workflows of caregivers. In addition to GE’s well-known, large/stationary medical equipment and communications infrastructure (Figure 2), Alizadeh showed that GE is also providing skin patches and other wearable sensors to capture data.Figure 2: The Future of Monitoring: In 2017, Mercy Hospital served 800,000 patients with telemedicine including those with chronic diseases. Patient:doctor ratio: US average 300:1. Mercy = 1100:1. (Courtesy: GE) Human Wearables Enabling Rapid Decision Making in the Integrated Care ContinuumAs Figure 2 above shows, microelectronic equipment can improve patient care and efficiency of medical personnel, but only if sufficient data can be captured timely and accurately – increasing the importance of wearables. AFRL’s Jeremy Ward moderated this August 17th session. Christopher Scully from the U.S. Food and Drug Administration (FDA), Ashleigh Coker from the AFRL’s Sensors Directorate, Ted Harmer from the AFRL’s Airman Systems Directorate, and AFRL’s Regina Shia presented for Oxana Pantchenko from NextFlex how they develop wearables jointly. Scully introduced the FDA’s organization and its responsibilities, described the high-value accurate data can provide, warned about the damage false alarms and equipment failures can cause, and explained the regulatory role the FDA plays in this context.AFRL’s Coker highlighted the essential role sensors play in modern warfare with several examples, described her directorate’s operations and showed their warfighter-centric design process (Figure 3).Figure 3: Warfighter-centric design process steps and the need to engage multiple heads/perspectives in this process. (Courtesy of AFRL) AFRL’s Harmer addressed the importance of good communications architecture and protocols to capture and compute data to assure efficient cooperation between land/air/sea/space-based forces.NextFlex’ Pantchenko prepared a presentation about standards-compliant wearable electroencephalography (EEG), electromyography (EMG), and electrooculography (EOG) devices, jointly developed with AFRL and several other companies. It was delivered by AFRL’s Regina Shia.Automation, Augmentation and AINatalie Wisniewski, Founder of Profusa, Inc. a and consultant in Wearables and Digital Health, moderated the fourth webinar, held on August 26. She emphasized SEMI’s role in this context, then introduced the speakers: Michael Kirby from Colorado State University, Kevin Zhao from Harmonize Health, Mary Clare McCorry from armi/biofab USA, and Andreas Caduff from ETH Zuerich.Professor Kirby outlined several mathematical principles that need to be applied to get meaningful results when analyzing data. He emphasized that genetic factors influence if an individual is susceptible, tolerant, or even resistant to certain pathogens and warned that bacteria can develop resistance to today’s antibiotics.Zhao from Harmonize talked about the importance of predictive analytics in remote care, how to filter out false alarms, and how to deliver the best available care cost-effectively. In closing, he emphasized that computers and algorithms are not replacing clinical staff.McCorry outlined how biofab USA, a program of armi, uses sensors and automation to grow replacement tissue and organs (Figure 4). She explained how they use engineering principles and life sciences to make guide cells grow into replacement tissue. The company’s plan is to expand the currently lab-based capabilities into an industrial scale tissue foundry.Figure 4: Growing ear cartilage in the lab. (Courtesy: armi/biolab USA) SummaryMcCorry summarized her presentation, and actually the entire webinar series, with these statements: The human body is a 3D, highly complex, dynamic, and multi-faceted biological construct Skin lends itself well as an interface between body and wearable sensors Connecting physiology (e.g. vital signs), behavior, and external factors is important for getting good results Verification, validation, and FDA involvement are important for making methods and devices successful Sensors, communication computing (AI/ML) are complementing, not replacing, medical personnel Today’s methods and devices will be outperformed by tomorrow’s solutions – stay up to date Personal CommentsSummarizing eight hours of presentations in a few pages requires a very high and lossy compression factor – please understand. I suggest you call on your SEMI contact to get access to these previous and following webinar recordings. Excellent contacts across the electronics supply chain enable SEMI to win experts in many areas to convey valuable information in these webinars.I am impressed that the USA military, specifically the AFRL, invests so much effort in medical support for airmen/women. They demonstrate that only healthy and fit personnel can take full advantage of the sophisticated weapon systems at their disposal if/when they are called upon to deploy them.This Smart MedTech webinar series confirms what many medical experts told me during exams and/or before and after surgeries: The human body is a masterpiece of bioengineering. These webinars also reminded me of what I learned at a brain-health class at Stanford University: Our brains only need about 20 Watts to perform computing and memory tasks that fairly quickly approximate the results of today’s computers – a benchmark for computer architects and AI/ML experts.Republished with permission from 3D InCites.

Since 2015, FlexTech has funded three projects with ITN Energy Systems, based in Littleton, Colorado. The projects all draw on a unique concept of using thin, flexible ceramic sheets as both a substrate for functional devices and as an integral part of the hermetic packaging to support paper-thin FHE products. Each program was increasingly sophisticated, enabling a larger variety of functions to be integrated into a common package. Independent functions such as energy storage, energy harvesting, or printed microelectronic circuits are deposited on their own ceramic substrate and the layers vertically stacked and interconnected into a monolithic structure that combines several functions in the smallest possible package volume.The ITN projects provide excellent examples of the power of collaborative research and development to help de-risk investments in next-generation electronics. All the projects were conducted with technical contributions from small and large businesses as well as university partners. The programs were funded by the U.S. Army Research Laboratories (ARL), directed by industry leaders and managed by SEMI FlexTech with the focus on utilizing the advantages of flexible hybrid and printed electronics (FHE) to create lighter-weight, lower-power, more conformable electronics than available commercially today. Markets ready to take advantage of FHE developments include healthcare, aerospace, mobility, consumer electronics, industrial electronics.ITN was founded in 1995 to focus on researching and developing technologies related to aerospace, energy and the environment for defense and commercial marketplaces. Its business model employs collaborative R D projects to explore, develop and validate promising next-generation clean energy technologies with an emphasis on tackling the manufacturing challenges that enable low-cost, high-volume production of thin-film devices on flexible substrates. Those technologies that meet the technical and business requirements of the market are commercialized via focused, spin-out companies with five such spin-outs formed so far. The work on ultra-thin batteries needed by the SEMI FlexTech community readily slid into their portfolio of projects.Project 1 – New Solid-State Lithium BatteryThe first project kicked off in 2016, with ENrG, and successfully supported the development and validation of novel Solid-State Lithium Battery (SSLB) products with total packaged thickness ranging from 50-250 microns. The SSLB proved to have substantial advantages in form factor and performance when compared with both commercial-off-the-shelf batteries and emerging technologies. For example, the SSLB provided more than double the operating time in a substantially smaller package in powering an audio device supplied by SEMI FlexTech partner companies.By avoiding the use of liquid electrolytes, the ITN SSLB also eliminates flammability issues while still allowing the benefits of lithium-based battery chemistry. The SSLB boasted many attributes attractive to the FlexTech community, including: Ultra-thin form factor, i.e. 250 microns thick, mAh class packaged batteries High volumetric energy density, i.e. baseline products with ~500 Wh/l and a roadmap to 1,000Wh/l The ability to support high current pulsing, i.e. current pulses at 4-10C rates, in support of demanding FHE duty cycles High temperature compatibility with solder reflow and other FHE integration schemes Rechargeability with high capacity retention at 1,000 cycles This new SSLB has formed the foundation of subsequent projects and commercialization efforts.Project 2 – Adding Energy Harvesting Based Recharging Capability The second SEMI FlexTech-funded project proposed a novel self-recharging battery with the addition of Lucintech’s cadmium telluride (CdTe) photovoltaics (PV), which was also deposited on thin yttria stabilized zirconia (YSZ) substrates. Because the CdTe supports a superstrate configuration, the SSLB can function as the back sheet for the PV package, thereby dramatically decreasing overall package thickness. The resulting flexible integrated power pack provided up to 0.25 Wh of energy storage and ~0.2 W of PV generating capacity in a total package less than 250 microns.As part of that effort, the ITN Team identified an effective power-management circuit that was ultimately compatible with die thinning and form factors very attractive to FHE. Consequently, the PV and SSLB were interconnected into a common power bus that enabled FHE to be operated with either the PV, SSLB or some combination of the two.ITN is seeing great interest in this product and both developing a version with substantially higher capacities than the project entertained for a UAV platform while ramping to low volume with support from NextFlex, a member of the Manufacturing USA network, and formed in 2015 through a cooperative agreement between the U.S. Department of Defense (DoD) and FlexTech Alliance.Monolithic integration of function layers atop of SSLB for high performance microelectronics device Project 3 – Integration with Processing and Sensor SystemsThe third FlexTech-funded project builds further on that foundation. In this project, the ITN Team is maturing the technologies to create a battery with an integrated processing and sensor system, nicknamed BiPASS. In addition to SSLB layers, the BiPASS package integrates printed circuits on YSZ employing high-performance, silicon- based bare die micro-electronics and/or thin film sensors into the common packaging. Mock-up of the charge control circuit on SSLB The initial demonstration integrates a commercial lithium battery charge control circuit within the SSLB packaging to create a monolithically integrated power module. There have also been promising developments of the University of Rhode Island’s metal oxide (MOx)-based thin film gas sensors that have dramatically increased sensitivity when deposited on thin YSZ. The resultant sensor achieves ppb detection of trace explosives gases that can be powered by SSLB. Along the way, ITN’s partners Molex and SunRay Scientific matured several aspects of FHE circuit printing and integration on both PET and YSZ, including new materials and processes for conductive traces, and bare die attachment with fine features. The project is in its final stages and the ITN Team now has a promising roadmap to integrate power, microelectronics, and thin film sensors/sensor systems into a single paper-thin package.Commercial Scale-Up StrategySince the initial demonstrations were completed, ITN has been actively maturing a commercial scale-up strategy based on significant market-pull and interest from several companies. A new venture to commercialize this next generation SSLB is in process. As part of those discussions, ITN is in active discussions with potential strategic partners to support the transition to high-volume production to access additional markets, many of which are cost-sensitive and need a higher degree of production maturity.In the meantime, ITN’s limited volume SSLB production line is already supporting medical device customers. In addition, a baseline SSLB (~2.5 mAh capacity) has been developed and tested in several new applications, including wearables, sensors and smart labels.“Based on the acceptance of these project in the market, I believe all three projects have provided significant value to the SEMI FlexTech community,” noted Brian Berland, Chief Technology Officer at ITN. “In addition, the connections and visibility we have gained within the industry by partnering with SEMI FlexTech have been invaluable. We are excited to continue this journey with new and additional projects. In the meantime, we are hopeful that our ongoing discussions with investment partners will support our commercializing of these components.”For more information visit www.flextech.org. SEMI FlexTech is currently (from 6/10/2020 – 7/17/2020) accepting white papers for new technology development projects. Read more at www.flextech.org.About the AuthorDr. Gity Samadi is the SEMI FlexTech Program Manager. Gity is responsible for the flexible hybrid electronics R D consortium activities including project awards and management, Technical Advisory Council management, and webinar/industry event planning for the building and fostering of this dynamic innovative community.

MEMS technology has changed human interaction with electronic devices. Introduced in the 1990s, the first mass-market MEMS devices were used for inkjet printheads and automotive airbag crash sensors. Today, MEMS are ubiquitous, with billions of the tiny devices adding intelligence and interactivity to smartphones, smart speakers, wearables, automobiles, biomedical devices, remote monitoring and event detection systems, and countless other applications. Integrating MEMS with Flexible Hybrid Electronics (FHE) is an important step in the evolution of this miniaturized intelligent sensing technology, paving the way for its use in new classes of flexible, conformal devices.The integration of the two technologies promises to breed new applications in small form factors but also presents challenges inherent to FHE design and fabrication processes. SEMI’s Nishita Rao caught up with Nathan Pretorius, prototyping and automation engineer, NextFlex, to discuss MEMS-FHE device integration challenges and opportunities ahead of his February 26 presentation, Integrating MEMS Devices in FHE, at FLEX|MEMS Sensors Technical Congress (MSTC) 2020, February 24-27, 2020, at the DoubleTree by Hilton in San Jose, California.Join us at FLEX|MSTC to meet Nathan and other industry influencers advancing innovation in FHE and MEMS sensors. Register now to connect with him at FLEX|MSTC or visit him on LinkedIn.SEMI: Why is integrating MEMS devices into FHE systems important? What new use cases might it enable?Pretorius: The main value proposition of integrating MEMS devices into FHE is that it allows MEMS devices to exist in a different form factor than was possible previously, giving us high-quality MEMS sensors on the flexible and conformable platform of FHE.Ease of application, flexibility, lower cost and rapid iteration on a design are just some of the benefits of FHE devices. And because there are few robust FHE sensors that overlap with MEMS’ capabilities, when you combine the two, you get a lot of compelling uses. That’s why NextFlex is working with agencies and companies to evaluate MEMS’ integration, including using bare MEMS die with microfluidics and promoting new ways of attaching and packaging MEMS die for use with FHE. SEMI: Why is FHE an ideal platform for integrating various types of sensors?Pretorius: MEMS integrated with FHE devices are ideal for rapid design and deployment of data-gathering sensor nodes — which we can iterate for specific applications. A few examples include on-body health monitoring devices for bio-fluids analysis, medical pressure sensors for monitoring blood pressure, and peel-and-stick sensors nodes for infrastructure monitoring. In terms of design and production, FHE devices support rapid prototyping, allowing for instantaneous design-iteration cycles. This speeds design-to-production over traditional rigid PCBs and copper flex because the feedback cycle time between design, manufacturing and testing is shorter, accelerating time to market. What’s exciting about FHE technology is that a variety of sensors or components, including MEMS, can be designed into the base system to easily customize it for a specific application. In addition, our experience shows that when compared to a traditional rigid PCB, an FHE board reduces manufacturing steps and device weight by two-thirds and, perhaps most importantly, converts the device to a thin, conformal shape that makes possible products in new form factors. SEMI: What are the primary challenges to integrating MEMS with FHE? What is NextFlex doing to help device manufacturers address these challenges? Pretorius: There are a few challenges, some of which are device-specific. Most recently, I’ve been focusing on inertial and timing devices, including accelerometers, gyroscopes and resonators. There are a few technical challenges involved in the process of getting the devices from the wafer to an FHE substrate. The wafer processing is very important, especially the dicing and thinning steps. After thinning and dicing, the die is placed onto the FHE substrate. The stresses caused by bonding to the substrate have to be understood and characterized. After placing the die, you then have a calibration step, which is normally performed after the device is packaged. With a MEMS die placed onto directly onto an FHE substrate, calibration then must be done.Finally, the device encapsulation is important, since on an FHE substrate the hard-to-soft material transition is very important to mitigate stresses to rigid component interfaces. We have also been looking at how to work with devices that have damping vents. Flexible encapsulants are inherently more permeable to gases and water vapor than hard encapsulants, so studying the encapsulation of MEMS devices on FHE is another area of interest. NextFlex has been working in a supporting role to evaluate best design practices and best attach and integration methods. In addition to our ongoing collaborative programs, NextFlex is developing the FHE manufacturing ecosystem to include system and component manufacturers and designers, product developers, and materials and equipment providers.SEMI: How do we facilitate closer collaboration between the FHE manufacturing ecosystem and MEMS suppliers such as MEMS device manufacturers, product developers, and materials and equipment providers?Pretorius: It’s important to include manufacturers early in the design process so we can identify challenges up front. That’s why NextFlex spearheads technology road-mapping efforts that include representatives from across the manufacturing ecosystem. We use the roadmaps to prioritize challenges that we can address effectively through collaboration, focusing the industry on solving problems through Project Calls that reveal integration challenges and results from real devices and that tell us how the materials and equipment actually perform with a real device.NextFlex keeps the information flowing, holding quarterly project update webinars to share results. As current devices are optimized for the process in which they will be used, we learn a lot from the project performers who make FHE system demonstrators — and we share that information with the member community. SEMI: Can you point to an example of a successful MEMS-FHE device integration?Pretorius: MEMS-FHE integration is still in the early stages, but we are working on several projects including a DARPA Seedling project for which we have integrated MEMS sensors into FHE systems for testing and evaluation. We plan to continue this work by integrating MEMS and FHE devices using methods that support mass production.SEMI: What would you like FLEX|MSTC attendees to take away from your presentation?Pretorius: We would like to see the FHE community work more closely with MEMS device manufacturers. For example, NextFlex often works with manufacturers to gain access to bare die, which is still a significant hurdle in making devices.The best way to speed things along is to get involved. We encourage FLEX|MSTC attendees to join NextFlex. As a prototyping and automation engineer at NextFlex, Nathan Pretorius explores new print methods for prototyping and automation using novel materials and processes. Pretorius currently focuses on how best to apply software scripting and machine learning to streamline FHE processes. Prior to joining NextFlex, he researched the strengths of roll to roll and screen printing on printed electronics designs, including capacitive touch interfaces, FHE passive component design, and antennas. Nathan holds a Bachelor of Science degree in Graphic Communications from Clemson University. FLEX|MSTC is organized MEMS Sensors Industry Group (MSIG) and FlexTech, SEMI technology communities focused on the growth of MEMS sensors and the flexible electronics supply chain, respectively.Nishita Rao is marketing manager for technology communities at SEMI.

Peel-and-stick simplicity isn’t just for adhesive bandages any more. IoT and flexible hybrid electronics (FHE) are bound to change hardware business models. And flexible displays will breathe life into any surface.These were among the insights foreshadowing the future of the FHE, electronic textiles, IoT, MEMS and sensors industries at the FLEX Japan and MEMS Sensors Forum Japan 2018. At the April event, organized by SEMI-FlexTech-MSIG, nearly 200 attendees shared their observations and lessons learned in the development of processes, products and applications. Presentations and discussions revealed these five takeaways.1. Expect the unexpected with FHE developmentFlexible Hybrid Electronics (FHE) continues to shrink the size and weight of products, enabling new markets and concepts. “FHE takes printed electronics and adds ICs for getting performance out of the PE structure,” said Wilfried Bair of NextFlex, adding that “peel- and-stick electronic products are one example of unexpected new markets enabled by FHE capabilities.” One potential application is large peel-and-stick safety sensors adhered to buildings to warn of structural dangers.Another surprising turn: With new insights into OLED technology originally developed for flexible displays, Cambridge Display Technology (CDT) has devised an innovative medical diagnostic tool for markets such as biomedical and agricultural monitoring. The tool features an atmosphere-processable OLED component with a simplified OLED structure encapsulated in aluminum foil.2. IoT and FHE devices should change hardware business modelsThis is the standard business model for many new FHE products: develop a product, manufacture it, find customers and sell. FHE and IOT device developers were encouraged by Jam Kahn of Gemalto to consider flipping the script: During FHE product development, explore building an after-market revenue stream by controlling and mining the data for trends it reveals. Because of its data harvesting potential, IoT is an excellent emerging technology for this strategy.The “Experience Economy” could create 200 connectable items per person, generating strong revenue streams from the collection and analysis of massive amounts of sensor-generated data. The key is for the data to be actionable. That means hardware suppliers must extend their focus to software development. “A recent study of California investors found that by 2025, 60 percent of global business profits will be from data,“ noted Harri Kopola of VTT, who advised hardware producers to examine business models that produce continuous value by leveraging software. “With FHE, we are creating the path to digitization for non-digital industries, and these industries need complete solutions,” he said.Hardware provider Xenoma, for example, sells an electronic shirt with sensors for measuring muscle movements, heart rate and other health-related data. Xenoma’s Ichiro Amimori said the company offers its open-source software development kit for free under one condition: The developer must share the collection data with Xenoma. The idea is that the more data collected, the greater Xenoma’s ability to improve human health over the long term and achieve its long-term vision of alleviating disease.3. Roll-to-roll and sheet-to-sheet manufacturing will meet in the middleOne of the big advantages of flexible and printed electronics was its promise to enable the manufacturing of electronics on a roll-to-roll (R2R) process in atmospheric (or close) conditions, like newspaper, rather than one sheet at a time, as with displays or wafers. But as development of inks and interconnects progressed, along with the placement of discrete and thinned-die components and basic flexible substrates on a moving web, most research and development (R D) and limited-production runs moved to sheet-fed systems to control material costs for experiments and low-volume production. R D on printing electronics processes split into two camps: the simple printed components camp on R2R, and the camp backing more flexible hybrid electronics development on a sheet-by-sheet basis. But progress didn’t stop.Harri Kopola of VTT highlighted new R2R inspection and test capabilities in the VTT pilot line in Finland. R2R processing advances incorporate ideas from biology, chemistry, optics, optoelectronics, advanced inspection and test capability, illustrating the multidisciplinary nature of FHE. While accurate, high-speed, pick and place of thinned, bare die remains the domain of sheet-to-sheet manufacturing, look for more improvements in accuracy and speed.Another new manufacturing concept that turns business models on their heads – “minimal fabs” – focuses on creating limited-run equipment and processes that use 3D printing and do not require cleanrooms. With a relatively low cost of entry, the approach enables electronics to be produced affordably anywhere.4. Powering the IoT is a grand challengeThe requirement for edge devices to function without intervention for long periods raises hard questions about how to power the devices. Using organic photovoltaics (OPV) in textiles to harvest energy from light could be one solution, according to Kasimaesttro Sugino of the Suminoe Textile Technical Center. ULVAC’s answer to the IoT power issue are requirements for edge device micro-batteries to be environmentally benign, safe, flexible and compatible with semiconductor processing less than .1 mm in height. The micro-batteries must also feature a long life and support continuous power output, high power density, low self-discharge (over 10 years) and mass production, said Shunsuke Sasaki of ULVAC. The batteries are being built on silicon, glass and stainless steel with dry, thin-film vacuum processing. 5. Flexible displays bring any surface to lifeWith their durability, flexibility, low-cost processing and programmability, flexible displays can transform any surface into a content-rich display with messages that make lives healthier, simpler and safer.One example is FlexEnable’s organic thin-film transistor (OTFT), a device made possible not only by recent advances such as the ability to build organic material transistors on plastic and the increasing clarity of new film materials but by continuous manufacturing process improvements. These advances are improving switching times and the color and video capabilities of thin-film transistors while retaining their flexibility, low power consumption and communication capabilities. Simon Jone of FlexEnable gave the examples of wrapping a display around the blind spots of automobiles or replacing side-view mirrors with interior monitors showing feeds from an external camera, approaches that would improve safety while reducing wind drag and increasing fuel efficiency.E Ink’s reflective technology and flexible products are coming to market with a wider color spectrum. The company’s Michael McCreary said its designers are specifying the panels for innovative projects such as the exterior walls of the San Diego International Airport parking garage. Used to communicate with airport visitors, the installation is weather-proof, programmable and self-powered.