Microsystems technologies have found their way into an impressive variety of applications, from mobile phones, computers, and displays to smart grids, electric cars, and space shuttles. This multidisciplinary field of research extends the current capabilities of standard integrated circuits in terms of materials and designs and complements them by creating innovative components and smaller systems that require lower power consumption and display better performance. Novel Advances in Microsystems Technologies and their Applications delves into the state of the art and the applications of microsystems and microelectronics-related technologies.
Featuring contributions by academic and industrial researchers from around the world, this book:
- Examines organic and flexible electronics, from polymer solar cell to flexible interconnects for the co-integration of micro-electromechanical systems (MEMS) with complementary metal oxide semiconductors (CMOS)
- Discusses imaging and display technologies, including MEMS technology in reflective displays, the fabrication of thin-film transistors on glass substrates, and new techniques to display and quickly transmit high-quality images
- Explores sensor technologies for sensing electrical currents and temperature, monitoring structural health and critical industrial processes, and more
- Covers biomedical microsystems, including biosensors, point-of-care devices, neural stimulation and recording, and ultra-low-power biomedical systems
Written for researchers, engineers, and graduate students in electrical and biomedical engineering, this book reviews groundbreaking technology, trends, and applications in microelectronics. Its coverage of the latest research serves as a source of inspiration for anyone interested in further developing microsystems technologies and creating new applications.
| Preface |
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xi | |
| Editors |
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xiii | |
| Contributors |
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xv | |
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PART I Organic and Flexible Electronics |
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Chapter 1 Device Modelling for SPICE Simulations in Organic Technologies |
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3 | (20) |
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Chapter 2 Nanoscale Phase Separation and Device Engineering in Polymer Solar Cells |
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23 | (22) |
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Chapter 3 Mechanically Flexible Interconnects and TSVs: Applications in CMOS/MEMS Integration |
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45 | (24) |
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Chapter 4 Wafer-Scale Rapid Electronic Systems Prototyping Platform: User Support Tools and Thermo-Mechanical Validation |
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69 | (36) |
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PART II Imaging and Display Technologies |
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Chapter 5 MIRASOL Displays: MEMS-Based Reflective Display Systems |
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105 | (24) |
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Chapter 6 Thin-Film Transistors Fabricated on Intentionally Agglomerated, Laser-Crystallized Silicon on Insulator |
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129 | (20) |
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Chapter 7 New Approaches for High-Speed, High-Resolution Imaging |
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149 | (20) |
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Chapter 8 Terahertz Communications for Terabit Wireless Imaging |
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169 | (18) |
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Chapter 9 Increasing Projector Contrast and Brightness through Light Redirection |
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187 | (18) |
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PART III Sensors and Microdevices |
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Chapter 10 Theoretical Electromagnetic Survey: Application to a CMOS-MEMS Planar Electrodynamic Microphone |
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205 | (42) |
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Chapter 11 Thin-Film Sensors |
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247 | (18) |
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Chapter 12 Technologies for Electric Current Sensors |
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265 | (28) |
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Chapter 13 Power Density Limits and Benchmarking of Resonant Piezoelectric Vibration Energy Harvesters |
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293 | (42) |
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Chapter 14 Microwave Sensors for Non-Invasive Monitoring of Industrial Processes |
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335 | (20) |
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Chapter 15 Microwave Reflectometry for Sensing Applications in the Agrofood Industry |
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355 | (22) |
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PART IV Point-of-Care and Biosensors |
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Chapter 16 Applications of Sensor Systems in Prognostics and Health Management |
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Chapter 17 Rigid Body Motion Capturing by Means of Wearable Inertial and Magnetic MEMS Sensor Assembly: Towards the Reconstitution of the Posture of Free-Ranging Animals in Bio-Logging |
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393 | (20) |
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Chapter 18 Point-of-Care Testing Platform with Nanogap-Embedded Field- Effect Transistors |
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413 | (24) |
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Chapter 19 Bionanotechnological Advances in Neural Recording and Stimulation |
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437 | (26) |
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PART V Ultra-Low-Power Biomedical Systems |
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Chapter 20 Advances in Ultra-Low-Power Miniaturized Applications for Health Care and Sports: The Sensium™ Platform |
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463 | (34) |
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Miguel Hernandez-Silveira |
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Chapter 21 Ultra-Low-Power Harvesting Body-Centred Electronics for Future Health Monitoring Devices |
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497 | (38) |
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Chapter 22 ADC Basics and Design Techniques for a Low-Power ADC for Biomedical Applications |
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535 | (36) |
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Chapter 23 Ultra-Low-Power Techniques in Small Autonomous Implants and Sensor Nodes |
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571 | (24) |
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| Index |
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Laurent A. Francis is an associate professor in the Electrical Engineering Department at the Université catholique de Louvain, Belgium. His main focus is on co-integrated, ultra-low-power CMOS MEMS sensors for biomedical applications and harsh environments. He was previously a researcher at IMEC in Leuven, Belgium, and a visiting professor at the Université de Sherbrooke, Canada. He has published more than 60 research papers in scientific journals, international conferences, and books, and he holds one patent. He is a board member of the Belgian National Committee on Biomedical Engineering and an editorial board member of the Journal of Sensors. He is also a regular member of the IEEE.
Krzysztof (Kris) Iniewski manages R&D at Redlen Technologies, Inc., a startup company in Vancouver, Canada. He is also a president of CMOS Emerging Technologies Research Inc., an organization of high-tech events covering communications, microsystems, optoelectronics, and sensors. Dr. Iniewski has held numerous faculty and management positions at the University of Toronto, University of Alberta, Simon Fraser University, and PMC-Sierra, Inc. He has published more than 100 research papers in international journals and conferences. He holds 18 international patents granted in the United States, Canada, France, Germany, and Japan. He is a frequent invited speaker, has consulted for multiple organizations internationally, and has written and edited several books.
