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Recent semiconductor technologies such as MEMS and MMIC is capable to deliver sensing elements in a much smaller form factor and low power application. With these new technologies, our team is now manage to develop smart lighting interacting with people and beyond. Combining with Infineon latest digital power (.DP) platform, we have already create use cases in China for demonstration. With recent AI technologies and the availability of lighting infrastructure gives lighting industries a completely new area to explore. In this section, we will illustrate how Infineon can facilitate this area with showcase and example.
Discover the OPTIS virtual prototyping platform and some uses cases in this short journey and see how it will answer your challenges through the design process: from Design, Analyze & Validate, to Manufacture, until the Marketing promotion & Sell. Whether you are a Luminaires manufacturer or a light architect, OEM or Tier 1 or Tier 2. OPTIS is a reference in physics based simulation, dealing with the overall Light area namely physics based materials, human vision and sensor modeling. The key of your success is the physics based modeling enables your collaborators, engineers and customers to immersively see the design in real time before it actually produced.
Senior Engineer, Haixi Research Institute, Chinese Academy of Sciences, inventor of KCOB kilowatt-level packaging technology Mr. Ye serves as the executive deputy manager and technical director of Fujian CAS-Ceramic Optoelectronics Technology Co., Ltd. He is responsible for the transfer and large-scale production of advanced material technology from the Chinese Academy of Sciences Haixi Research Institute. He undertook the 500W COB light source for stadium lighting research and development project under the “Glory Program” of Chinese Academy of Sciences. Breaking the bottleneck of traditional fluorescent plastic packaging technology, he invented transparent fluorescent ceramic kilowatt COB light source low thermal resistance packaging technology. He has also received the world's first COB 600W light source LM-80 certification, enabling the world's first 10 kilowatt level 500 meters deep-sea lighting fixtures for fishing operations. He holds 36 LED-related patents and has applied for four international PCT patents. Mr. Ye serves as the general manager of Fujian CAS-Xinyao Lighting Techbology Co., Ltd. The company utilize KCOB kilowatt-level packaging technology combined with patented three-dimensional heat dissipation technology to provide customized ultra-high-power professional lighting solutions, focusing on the customatized professional lighting design for sports lighting, port lighting, fishery lighting, remote lighting, indoor large space lighting and industrial special lighting.
he core technology of LED lighting is LED lamp beads and LED power supply. The core technology of LED power supply is the specialized integrated circuit chip. The past decade has seen great advancement of LED lighting power drive chip technology, from the universal power drive chips in the beginning to the constant current chip developed specifically for LED lighting. With various series, specifications and variety, the chip is applicable to different settings and light sources. As LED light source lamp bead technology rapidly develops from LVLED to HVLEDs, the constant-current drive chip for LED primarily based on switching constant current and high voltage linear constant current is used massively. High-voltage linear constant current drive develops in two directions, i.e. constant power and linear constant current control plus external MOS. The power drive chip must intensively integrate many functions, and power drive application circuit must be simplified in order to meet the requirement of massive LED light sources and light fixture market. The design of the power drive chip must satisfy the practical needs of LED light sources and luminaire products. The must-have functions should be kept but the redundant functions must be removed. Reducing the die area can increase the number of power drive chip on a wafer unit and lower its cost and price. China must develop proprietary technology of power drive integrated circuit chips with its own IP right. China is fully capable of designing, taping, packaging and testing power drive integrated circuit chip, which enables us to provide reliable and continuous delivery at a stable price to the application side. The optoelectronic design of LED lighting products is an inevitable trend. The optoelectronic engine technology with HVLEDs and linear drive chips designed on the same module is already mature, massively produced and widely used in LED lighting manufacturing industry, resulting in the rapid development of linear power drive chips. We have also seen new products design in various categories of LED lighting power drive integrated circuit chip in response to the growing needs of emerging markets. These applications include non-isolated low PF, non-isolated high PF, isolated low PF linear constant current for general lighting, switching power supply SCR dimming and linear power supply SCR dimming, PWM dimming constant current drive chip for smart lighting, low power constant voltage power supply chip, level conversion chip, isolated high PF for high power luminaire equipment, strobe chip, switching dimming and color chip and many more. Power drive integrated circuit chip has evolved in the context of "thinking lighting and transformation" in response to diversified demands for LED lighting. As new generations of power chips are developed, we are striving for winning in the blue ocean of LED lighting industry.
Alec Yan is a senior engineer, part-time professor, technical advisor, independent director of the board and volunteer in lighting industry. He had worked as an electronic engineer and marketing manager in Chinese and foreign companies for over 50 years. After retirement, he has worked as a part-time professor at Shanghai Institute of Microelectronics of Peking University for eight years. In the past decade, based on the in-depth analysis of and insights into LED lighting market, he has made a number of technological innovations, such as "switch constant current power drive chip", "high voltage linear constant current drive chip" and related application technologies,a full set of design, production technology and automated production equipment of "optoelectronic engine" and "LED filament lamp". He has actively advocated and promoted the wide application of technologies related to design, application, and production. After years of development, these products have now become the mainstream of the LED lighting market, supporting the robust growth of start-ups and SMEs in LED industry. LED lighting industry is moving towards integrated, simple and automated production. The key to success is innovation in technology and creativity in product design!
The efficacy of LEDs has improved 10-fold and seen equivalent price erosion over the past decade. The increased efficacy has led to reduced power dissipation and hence reduced need for cooling. All leading to smaller luminaires with a higher design freedom and reduced cost. The LED drivers have however not seen the same great improvements and have hence become the Achilles heel of most LED lighting products. New innovations are needed for the LED driver to catch up and to meet the market requirements. The volume and cost of drivers are mainly governed by passive energy storing elements (inductors and capacitors). They scale with the switching frequency and a dramatic increase in switching frequency will hence lead to highly increased power density and reduced cost. For hard-switched drivers this will however result in severe switching losses, which will ruin the efficiency and cause system failure. By combining circuits from the RF industry with the design methodology of power electronics, new driver topologies have been designed, which ideally eliminates these switching losses. This enables increased switching frequencies and hence a huge increase in power density and comparable cost reduction. The reduced need for passive energy storing elements enables removal of heavy and bulky magnetics components and temperature sensitive electrolytic capacitors. Hence enables longer lifetime on the overall luminaire and deeper integration of LEDs, LED drivers, heatsink and luminaire. The first commercial LED drivers with this technology have just launched.
Mickey Madsen have a strong technical background with both a MSc.EE and PhD in power electronics and several scientific publications and patents. He has received several awards, among them Semikron Innovation Award from the European Center for Power Electronics and PhD of the year award from the Technical University of Denmark. Mr Madsen is the CEO and founder of Nordic Power Converters, which is based on his technical breakthrough in power converters offering highly miniaturized LED drivers with increased reliability and extended lifetime. As CEO he is involved in all aspects of the business, but with a high focus on pushing the technology further, strategic partnerships, product roadmap and intellectual property.
Pu min, male, graduated from Soochow University. Master of software engineering, senior engineer. Now he is the vice president and Director of Lumlux Corp, deputy director of the Institute of intelligence agricultural facilities of the Soochow University, the committee member of the outdoor lighting Committee of China Illuminating Engineering Society, the deputy director of the agricultural lighting special committee, the deputy director of the transportation lighting and the light signal special committee. He has obtained dozens of research and development achievements and applied more than 30 patents, including a number of invention patents,and they had been widely applied in the field of road lighting, landscape lighting, etc. He has undertaken and participated in a number of lighting control related research projects, participated in writing “Technical specification for urban lighting automatic control system” and “Atlas of City lighting installation”
Kai Ren is currently the Developer Relation Manager for the APAC region at the Bluetooth SIG. He has more than 9 years of experience in design and development of wireless sensor networks, specializing in short range, low power wireless technology. His goal at the Bluetooth SIG is to build out Bluetooth’s developer program in the APAC region, helping developers bring innovative applications and products to market. Prior to joining the SIG, he served as a senior engineer at Honeywell in research and development of wireless sensor networks for industrial products. For Honeywell, Kai focused on developing plant safety and industrial wireless networks for gas detection and protection systems. Kai enjoys badminton and swimming, and currently lives in Shanghai with his wife and child.
1. Ai Lab introduction 2. Next generation Human Computer interface 3.Tmall Genie introduction 4. Aligenie ecosystem 5.Bluetooth Mesh introduction 6. Bluetooth mesh applied on Appliance(Lighting)
Based on standardized Bluetoothmesh,a REAL smart lighting system can be built. The Bluetooth mesh supplies advanced control methods to let lightings get rid of a cumbersome control mode. Bluetooth Mesh also links the wireless sensors networks, and also is the solution of assets / location tracking in the buildings. The Bluetooth mesh links lights, sensors, and other devices all together as a stable mesh networks. In the mesh networks, every device can link to smartphone directly. Whit APPs and clouds help, it will be very easy and friendly for us to set up, learn to use and maintain mesh device and networks. The most important function of a smart lighting system based on standardized Bluetooth mesh, is the foundation of assets tracking, location service in the buildings. To analysis the distance between Bluetooth LE devices, between the Bluetooth LE devices and smartphones, we are able to locate persons or devices inside buildings.
Lighting will head to smart lighting, and smart lighting system evolution to beyond illumination of IoT based will be introduced, furthermore, discussion will be on how to connect a smart switch by Bluetooth LE in order to drive lighting evolution smart lighting.
Feng Huang lead lighting system standard program, help Philips lighting be a leading lighting company in IoT industry with valuable innovation and growth strategy. He also takes the leadership in several Chinese standard SDOs, he is associated director of smart building committee in building energy saving association, steering member of SAC/TC426, CSAS and CALIS.
Smart home has been realized by using Bluetooth Mesh Technology, which smart lighting can constructed as an important backbone. The Bluetooth mesh technology works fast, flexible and friendly running a mesh network and will be a milestone for IoT application.
Ray Shiu is in charge of IoT Bluetooth team of Askey R&D Group, who is specialized in Bluetooth mesh technology constructed with Heterogeneous network, has been working on the integration of Bluetooth LE and Bluetooth Mesh to develop the innovation products, including the architecture design of near field network as Bluetooth LE smart lighting smart home and smart positioning etc. He was graduated from National Taiwan University and Université Joseph Fourier as a mutual Ph.D. He worked at ITRI for the system integration over 6 year as a senior researcher and in ICT over 6 years.
Mesh has been an ideal network topology for usage requires range more than a single hop RF coverage. The interest in Mesh technology got even higher when Bluetooth SIG announced the first Mesh standard last year. We would like to discuss features defined today help making a Mesh technology even better for actual life.
Desmond Chan is a Senior Field Marketing Manager, Asia Pacific region, at Silicon Labs. An over 20-year semiconductor industry veteran, Desmond has focused on wireless IC products and wireless system design for the past 12 years and now focusing on IoT application. He graduated from Hong Kong University of Science and Technology in 1994 with an Electronic Engineering degree.
To keep up with the industry’s growing focus on a connected home, lighting manufacturing leaders have chosen to build their products on Zigbee. Through testing and Certification, Zigbee technology gives users and developers the confidence that products will work together not only with other lighting devices, but also devices form other market segments that implement the technology. By examining use cases, we will explore how Zigbee unlocks new markets, allows for new use cases, creates an easy user experience, and delivers on the promise of the IoT.
Victor Berrios is responsible for the day-to-day operations of all technology programs for the Alliance and for supporting Work Group efforts in the development and maintenance of wireless communication standards. He is a recognized expert in the short-range wireless industry as evidenced by his contributions to the RF4CE Network; Zigbee Remote Control, Zigbee Input Device, Zigbee Healthcare, and Zigbee Low Power End Device Specifications. He was recognized by the Continua Health Alliance as its Spring 2011 Key Contributor in recognition for his contributions to the success of the Test and Certification Work Group. He is the 1997 recipient of the Hispanic Engineer National Achievement Award for community service, has worked for over twenty years in the wireless communication industry. Mr. Berrios received his bachelor’s of science in computer engineering from Iowa State University, his master's in electrical engineering from Arizona State University (ASU), and his master's in business administration from ASU.
Mr. Huang is a seasoned business executive with 20 years of marketing experience in various roles from component level products to enterprise solutions to consumer products. He is currently serving as the Director of Wi-Fi Alliance Greater China Region based in Beijing. Jerry was the Founder and General Manager of the Great Pacific Marketing, Inc. in Silicon Valley, California, focusing on assisting companies with establishing a business presence in China and other regions in Asia. Mr. Huang has held various executive positions in worldwide enterprises such as Acer, Bell Microproducts, Everdream Corporation and several startups in his career. His expertise is building teams from the early phase and producing a successful track record of results through solid growth.
Mr. Philip Huang is the general manager of Zhejiang UMElink Intelligent Technology Co Ltd. Graduated from the Department of Automatic Control of Shanghai Jiaotong University, he founded and served as general manager of a number of companies after 1995 including Shanghai Longjun Electronics, Langjun Electronics, Langjun Electromechanical Technology, Langjun Machinery & Electronics Import and Export Company, and Langjun Intelligent Technology Company. He is the member of Shanghai Youth Federation and has won the award of Shanghai New Long March Spearhead. Langjun Intelligent Technology Company is now listed on the National Equities Exchange and Quotations System (NEEQ, stock code 837588). With over 20 years of experience, the company specializes in the R&D and manufacturing of outdoor and indoor light fixtures and lighting control devices. Its customers include major lighting companies in North America, lighting control brands, chain construction supermarkets, and outdoor lamp factories home and abroad. Holding patents and various IPs, the company is dedicated to providing lighting industry with cost-effective technologies and solutions of intelligent control. The affiliated companies include Zhejiang Langjun Electronics Technology—the wholly owned manufacturing base, Shanghai Langjun Machinery & Electronics Import and Export Company—the foreign trade company and Zhejiang UMElink Intelligent Technology Co Ltd.—the research center of intelligent lighting control system.
Due to the increasing demands for indoor location-based services, wireless indoor positioning system has attracted much research and development attention in recent years, and the market size for indoor positioning has been assessed to be tens of billions of dollars. Compared with other indoor positioning technologies such as radio frequency, infrared and ultra-sound, visible light positioning technology has the advantages of simpler infrastructure, more efficient energy use, and higher positioning accuracy. In this talk, we will first provide an overview of indoor positioning using visible light and its state of the art. While positioning with visible light communication (VLC) infrastructure can achieve centimeter-level accuracy, most existing VLC-positioning system prototypes have some practical limitations. To overcome these limitations, we propose a new VLC positioning technique called angle difference of arrival (ADOA), which allows for arbitrary tilting and pitching of the receivers. We demonstrate both numerically and experimentally that the proposed VLC positioning system based on ADOA can achieve accuracy of less than 1 centimeter. The proposed VLC positioning technology, which has both low cost and low complexity, can be used in a wide variety of indoor positioning applications. Finally, we will discuss about the business opportunities and challenges for indoor visible light positioning technologies.
Julian Cheng (S’96–M’04–SM’13) received the B.Eng. degree (Hons.) in electrical engineering from the University of Victoria, Victoria, BC, Canada, in 1995, the M.Sc.(Eng.) degree in mathematics and engineering from Queens University, Kingston, ON, Canada, in 1997, and the Ph.D. degree in electrical engineering from the University of Alberta, Edmonton, AB, Canada, in 2003. He is currently a Full Professor in the School of Engineering, Faculty of Applied Science, The University of British Columbia, Kelowna, BC, Canada. He was with Bell Northern Research and NORTEL Networks. His current research interests include digital communications over fading channels, statistical signal processing for wireless applications, optical wireless communications, and 5G wireless networks. He was the Co-Chair of the 12th Canadian Workshop on Information Theory in 2011, the 28th Biennial Symposium on Communications in 2016, and the 6th EAI International Conference on Game Theory for Networks (GameNets 216). He currently serves as an Area Editor for the IEEE TRANSACTIONS ON COMMUNICATIONS, and he was a past Associate Editor of the IEEE TRSACTIONS ON COMMUNICATIONS, the IEEE TRANSACTIONS ON WIRELESS COMMUNICATIONS, the IEEE COMMUNICATIONS LETTERS, and the IEEE ACCESS. Dr. Cheng served as a Guest Editor for a Special Issue of the IEEE JOURNAL ON SELECTED AREAS IN COMMUNICATIONS on Optical Wireless Communications. He is also a Registered Professional Engineer with the Province of British Columbia, Canada. Currently he serves as the President of the Canadian Society of Information Theory.
Visible light communication (VLC) is a technology that uses LEDs as data transmitters to carry information. Modulating inexpensive LEDs with data allows for the simultaneous use of lighting panels for wireless access and illumination. This dual-use approach can offer energy-efficient connectivity as well as high throughput due to the huge unregulated optical spectrum. Since light is easily contained, VLC systems are secure and can exploit spatial resource reuse to effectively form dense data networks. Future applications range from mobile Wi-Fi alternatives (popularly called Li-Fi) for large indoor spaces to vehicular communication networks. These systems are ideal for environments where RF systems are ineffective or prohibited because of the risk of electromagnetic interference or contamination. In this talk, we explore the potential of this new technology within the context of its practical limitations and present some visions on the commercialization path for VLC.
Dr. Maïté Brandt-Pearce is professor of Electrical and Computer Engineering and Executive Associate Dean for Academic Affairs of the School of Engineering and Applied Sciences at the University of Virginia. She joined UVa after receiving her Ph.D. in Electrical Engineering from Rice University in 1993. Her research interests include nonlinear effects in fiber-optics, free-space optical communications, visible light communications, cross-layer design of optical networks subject to physical layer degradations, body area networks, and radar signal processing. Dr. Brandt-Pearce is the recipient of an NSF CAREER Award and an NSF RIA. She is a co-recipient of Best Paper Awards at ICC 2006 and GLOBECOM 2012. She had served on the editorial board of IEEE Transaction of Communications, IEEE Communications Letters, IEEE/OSA Journal of Optical Communications and Networks and Springer Photonic Network Communications. She was Jubilee Professor at Chalmers University, Sweden, in 2014. After serving as General Chair of the Asilomar Conference on Signals, Systems & Computers in 2009, she served as Technical Vice-Chair of GLOBECOM 2016. She is a member of Tau Beta Pi, Eta Kappa Nu, and a Senior Member of the IEEE. In addition to co-editing a book entitled Cross-Layer Design in Optical Networks, Springer Optical Networks Series, 2013, Prof. Brandt-Pearce has over two hunderd technical publications.
Webster Chu is the Specifier Service & Application Support Manager of Xicato Inc. to provide lighting designers service & education roles as well as technical support for lighting manufactures around Asia Pacific. For the last 15 years, Webster has been application support and product development roles in LED and power electronics industries across Asia, where he leads the development of over 300 products of LED luminaries & relative control gears products and managed the technical support team for the company's global base of customers.
LED brings disruptive change to the industry. Over time, industry growth will be driven in three ways: - Energy saving (happening now, RoI-/Payback-driven) - Controllable light (starting to happen, adaptability and quality of light) - Connected light (early stage now, value beyond lighting) In the third stage, it will be about delivering value beyond lighting itself. Lighting fixtures will become an infrastructure backbone for anything 'SMART': Smart City, Smart Building, Smart Home. Four reasons for this: - Lights are everywhere - Lights have a fixed location - Lights are always powered - Lights will become data hubs. This will allow for functionalities well beyond lighting a space; specifically, Lights will allow data collection and diessemination. Examples include building management through heatmapping, indoor localization, asset tracking, traffic management, VLC/LiFi and many more. It will be key for the industry to understand the true value of such services in order to develop the right offer to the market and establish the right pricing strategies for such offers. I will share some real eaxmples.
Academics: - Lighting physicist - MBA Professional: - McKinsey - OSRAM: 19 years in various VP/SVP positions such as -- Global CEO Lighting Electronics (based in HK/China) -- Global CEO Consumer Lighting -- Global CEO Luminaires -- SVP Corporate Strategy & Marketing - Sylvania: since January 2014 -- President Havells Sylvania EMEA -- Global Group CEO Feilo Sylvania (after acquisition of Sylvania by Feilo in January 2016) Personal: - Broad international exposure – Europe, Asia, Latin America, US - Languages: German, French, English, Spanish
Joel Reiner is the head grower and a plant scientist at AeroFarms, the largest indoor vertical farm in the world, based in Newark, NJ. AeroFarms has been recognized as one of Fast Company’s Most Innovative Companies OF 2018, NJ Future’s SmartGrowth Award for 2018, Global Cleantech 100, Inc.com’s Top 25 Disruptive Companies, Winner of the World Technology Award for Most Impactful Environmental Company, and Finalist for The Circular Awards of The World Economic Forum. AeroFarms is a Certified B Corporation and part of the Ellen MacArthur Foundation Circular Economy 100. In his role, Joel focuses on yield, plant quality, sustainability and scalability of the AeroFarms growing system, working toward the ultimate goal of building and operating environmentally responsible farms throughout the world. Prior to joining AeroFarms, Joel worked for eight years as a grower at DuPont Pioneer in the controlled environment group, where he focused on soybean quality, yield and automation. Joel holds a Masters degree in Plant Science from the University of Delaware and a certificate in Hydroponic Lettuce Production from the University of Arizona.
We developed the world’s first Ultraviolet LED in 2000, and UV-LED is expected as not only a substitution market of mercury lamps but also a next generation light source and display panel in the near future. The UV mosquito catcher is now in common use. Recently we released reasonable price 275nm deep UV-LEDs in the market. We applied them for air purifier, sterilizer, etc.. These UV-LED applied functional products are called LEDPURE®. Furthermore UV excited micro LED panel can be a candidate of next generation display.
AlGaN deep ultraviolet light-emitting diodes (DUV-LEDs) are attracting a great deal of attention, since they have the potential to be used in a wide variety of applications, such as for sterilization, water purification, UV curing, and in the medical and biochemistry fields. As a result of recent developments in AlGaN DUV LEDs, high internal quantum efficiencies (IQE) of more than 60-80% have been achieved by reducing the threading dislocation density (TDD) of the AlN, and/or by the introduction of AlN single crystal wafers. However, the wall-plug efficiency (WPE) of AlGaN DUV-LEDs still remains below 2%. The target for the efficiency of AlGaN DUV-LEDs is to go beyond an efficiency of 20%, which would make them comparable to low-pressure mercury lamps. A significant problem is that the light-extraction efficiency (LEE) is still quite low because of heavy UV absorption through the p-GaN contact-layer. Usual LEE is still below 10%. Recently we succeeded in reducing an applying voltage and obtained the record WPE of 10.8% from the DUV LED with lens. We also demonstrated the increase of LEE by introducing highly-reflective photonic crystal fabricated on both of the p-AlGaN transparent contact layer and the p-GaN contact layer. Since highly-reflective photonic crystal on the p-contact layer is enable to reduce the heavy UV absorption and keep low applying voltage, WPE will be improved to be compared with typical deep-UV LEDs.
I am currently belong to Hirayama Quantum Optodevice Lab at RIKEN and contribute to improve the light extraction efficiency of deep-UV LEDs by introducing highly-reflective photonic crystal. The current subject is computer simulation to use both of ray-tracing and finite difference time domain method for photonic crystal and bonding semi-spherical lens. Published paper is "High external quantum efficiency(10%) AlGaN-based deep-ultraviolet light-emitting diodes achieved by using highly reflective photonic crystal on p-AlGaN contact layer", Applied Physics Express 11,012101(2019).
Expected to replace traditional ultraviolet mercury lamp light source, ultraviolet light-emitting diodes (UV-LED) based on AlGaN are widely used in such fields as solid-state lighting, purification and disinfection of water and air, as well as medical treatment and curing of skin and blood. However, as the emission wavelength becomes shorter, ie, the aluminum composition increases, the preparation of high-quality AlGaN materials becomes increasingly difficult. This is partly due to the large lattice mismatch between the AlGaN film and the substrate of the high aluminum composition, which increases the density of various defects on the film. It is also caused by the increase in the aluminum composition and the growing difficulty of AlGaN doping and activation, which leads to poorer ohmic contact and higher operating voltage. As a result, there is a huge gap between AlGaN-based UV-LEDs and GaN-based blue LEDs in terms of both internal quantum efficiency and luminous power (brightness). The valence band structure of AlGaN-based Ni-nitride materials favors the optical field direction parallel to the C direction, or the optical transition perpendicular to the M (10-10) surface and A (11-20) surface, both of which are non-polar surface unaffected by the quantum confinement Stark effect. Therefore, non-polar AlGaN-based materials naturally become the ideal material for UV-LEDs. However, compared with AlGaN-based materials grown on polar C-surface, those grown on non-polar M-surface or A-surface are still high in defect density. Therefore, if we can develop high-quality growth techniques for non-polar AlGaN-based epitaxial materials of M-surface or with A-surface orientation that is suitable to device fabrication and find methods to suppress defect generation, chances are we will eventually develop non-polar AlGaN-based UV-LEDs with high luminous efficiency to replace mercury lamps in water and air purification. This will have a great and far-reaching significance for environmental protection and people’s wellbeing. This presentation will start with an introduction of UV-LED research home and abroad. The speaker tries to offer a new solution to deep ultraviolet LED technology research in response to the issues mentioned above. Hopefully this new solution will pave the way for the mass application of AlGaN-based UV-LEDs in water and air purification.
Canadian nationality, Professor and Ph.D. Supervisor at the School of Electronic Science and Engineering, Southeast University; Doctor of Engineering, University of Tokyo, Japan; Lee Kuan Yew Postdoctoral Researcher at the National University of Singapore He served as a senior engineer and project manager for Olympus Corporation of Japan and a high-tech company in Silicon Valley for years. He was granted two U.S. patents, one Singapore patent, seven Japanese patents and sixteen Chinese patents. He published 79 SCI papers in English and two monographs in English. After returning to China in 2006, he served as the general manager and technical director of Wuxi Bluestar Electronics Co., Ltd., and led the research and development of high-brightness GaN-based LED. He received the Award of High-level Talents of Innovation and Entrepreneurship Introduced to Jiangsu Province and “Top Talents in Six Specialized Areas " Award due to his outstanding performance.
Recently, necessity of new technology LED has been increased due to rising of environmental consciousness. It is UVC-LED which has wavelength range of around 260nm to 290nm. Still conventional mercury lamp is exception of the Minamata convention on mercury, with recent technology development and evolution of practical technology , UVC-LED are approaching to be substitution technology. Nikkiso’s Nobel prized technology offers UVC-LED products in the wavelength 260nm to 290nm for many kinds of applications, e.g. water /air/surface disinfection, medical and industrial applications. As pioneer and leader of global technology ,Nikkiso and our group companies including AquiSense Technologies in US has made significant progress for efficiency improvement and will continue to expedite the product evolution further. Today, we will introduce the application examples which has possibility to use UVC-LED, We hope our new technology will contribute for better global environmental.
Major subject : Economics Final academic background : University in Japan Experience : 20years experience in LED industry (visible LED and UVC-LED)
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