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Handbook of Mems for Wireless and Mobile Applications
Deepak Uttamchandani (Edited by)
9780857092717
Hardback, published 31 August 2013
640 pages
23.3 x 15.6 x 3.5 cm, 1.09 kg
"In my opinion this is an excellent book for MEMS in mobile communications" --Professor Hamed Al-Raweshidy, Director of the Wireless Networks and Communications Centre (WNCC), Brunel University, UK "An excellent introduction to the field for engineers and scientists; it identifies important capabilities and opportunities for MEMS in wireless sensing and communication." --Professor Yogesh B. Gianchandani, University of Michigan, USA "This comprehensive handbook will be a valuable resource to practitioners in the field, as well as to users and potential users of MEMS technology in wireless and mobile." --Professor Eric M. Yeatman, Imperial College London
The increasing demand for mobile and wireless sensing necessitates the use of highly integrated technology featuring small size, low weight, high performance and low cost: micro-electro-mechanical systems (MEMS) can meet this need. The Handbook of MEMS for wireless and mobile applications provides a comprehensive overview of radio frequency (RF) MEMS technologies and explores the use of these technologies over a wide range of application areas.
Part one provides an introduction to the use of RF MEMS as an enabling technology for wireless applications. Chapters review RF MEMS technology and applications as a whole before moving on to describe specific technologies for wireless applications including passive components, phase shifters and antennas. Packaging and reliability of RF MEMS is also discussed. Chapters in part two focus on wireless techniques and applications of wireless MEMS including biomedical applications, such as implantable MEMS, intraocular pressure sensors and wireless drug delivery. Further chapters highlight the use of RF MEMS for automotive radar, the monitoring of telecommunications reliability using wireless MEMS and the use of optical MEMS displays in portable electronics.
With its distinguished editor and international team of expert authors, the Handbook of MEMS for wireless and mobile applications is a technical resource for MEMS manufacturers, the electronics industry, and scientists, engineers and academics working on MEMS and wireless systems.
Contributor contact details Woodhead Publishing Series in Electronic and Optical Materials Dedication Preface Part I: RF MEMS as an enabling technology for wireless applications Chapter 1: Overview of RF MEMS technology and applications Abstract: 1.1 Introduction 1.2 Radio frequency microelectromechanical systems (RF MEMS) operation principle and common realizations 1.3 RF MEMS design challenges 1.4 RF MEMS applications 1.5 Conclusion 1.6 Sources of further information and advice 1.7 Acknowledgements Chapter 2: Overview of wireless techniques for use with MEMS Abstract: 2.1 Introduction 2.2 Transport layer issues 2.3 Network layer mobility issues 2.4 Data-link layer 2.5 Physical layer 2.6 The wireless link budget 2.7 Physical layer system design 2.8 Conclusion Chapter 3: RF MEMS fabrication technologies Abstract: 3.1 Introduction 3.2 MEMS-based technologies for RF circuits with enhanced quality factor and minimized losses 3.3 Technologies for smart RF MEMS 3.4 Highlights on specific key steps in RF MEMS fabrication 3.5 Towards integrated technology for microsystem implementation 3.6 Emerging technologies in wireless applications 3.7 Conclusion 3.8 Acknowledgements Chapter 4: RF MEMS passive components for wireless applications Abstract: 4.1 Introduction 4.2 RF MEMS passive components and their applications 4.3 High-performance passive components enabled by RF MEMS technology 4.4 Complex networks based on RF MEMS passive components 4.5 Conclusion Chapter 5: RF MEMS phase shifters for wireless applications Abstract: 5.1 Introduction 5.2 Switched-line phase shifter 5.3 Loaded-line phase shifter 5.4 Reflection-type phase shifter 5.5 Distributed-line phase shifter 5.6 Mixed-architectures and exotic phase shifters 5.7 Towards global manufacturing 5.8 Applications 5.9 Conclusion Chapter 6: RF MEMS antennas for wireless applications Abstract: 6.1 Introduction 6.2 RF MEMS antennas 6.3 Reconfigurable feeding networks 6.4 Reconfigurable antennas 6.5 Design considerations 6.6 Conclusion and future trends 6.7 Sources of further information and advice Chapter 7: RF MEMS-based wireless architectures and front-ends Abstract: 7.1 Introduction 7.2 Communication standards 7.3 Receivers, transmitters and transceivers: basic architectures 7.4 Conventional component technology 7.5 MEMS-based technology: filters, duplexers, switches, tunable devices and architecture 7.6 Diversity in receivers and transmitters 7.7 Multi-input multi-output (MIMO) systems 7.8 Systems-on-a-chip 7.9 Conclusion Chapter 8: RF MEMS technology for next-generation wireless communications Abstract: 8.1 Introduction 8.2 RF MEMS technology 8.3 RF MEMS technology for high-performance passive components 8.4 Technology platform for the fabrication of RF MEMS complex circuits 8.5 Some examples of high-performance devices enabled by the RF MEMS technology 8.6 Conclusion Chapter 9: Wafer-level packaging technology for RF MEMS Abstract: 9.1 Introduction 9.2 Wafer -level zero-level packaging for RF MEMSSS 9.3 Electrical effects of the packaging material on the packaged devices 9.4 Packaging with hard cap materials 9.5 Packaging with a polymer cap 9.6 Conclusion Chapter 10: Reliability of RF MEMS Abstract: 10.1 Introduction 10.2 Overview of failure mechanisms in RF MEMS 10.3 Charging in RF MEMS 10.4 Analytical modelling 10.5 Electrostatic discharge 10.6 Reliability issues of MEMS packages 10.7 Conclusion Part II: Wireless techniques and applications of wireless MEMS Chapter 11: Energy harvesters for powering wireless systems Abstract: 11.1 Introduction 11.2 Kinetic energy harvesters 11.3 Design of kinetic energy harvesters 11.4 Other typologies of energy harvesters 11.5 Conclusion 11.6 References 11.7 Appendix: list of symbols Chapter 12: MEMS wireless implantable systems: historical review and perspectives Abstract: 12.1 Introduction 12.2 Basic considerations and characteristics of wireless MEMS implantable systems 12.3 Significant research on radio frequency implantable systems from 1955 to 1975 12.4 Progress of implantable systems from 1980 to 2010 12.5 Challenges of implantable/attached electronics 12.6 Conclusion and future trends 12.7 Acknowledgements Chapter 13: Wireless considerations in ocular implants based on microsystems Abstract: 13.1 Introduction 13.2 Challenges of wireless ocular implants 13.3 Considerations of ocular microsystems 13.4 Applications of wireless microsystems in ocular implants 13.5 Necessary improvements in wireless ocular implants 13.6 Conclusion Chapter 14: MEMS-based wireless intraocular pressure sensors Abstract: 14.1 Introduction 14.2 Passive miniature implants for intraocular pressure (IOP) sensing 14.3 Introduction of active MEMS systems for IOP implants 14.4 Flexible parylene platforms for long-term MEMS implants 14.5 Design of custom ultra-low-power autonomous IOP sensors 14.6 Active and passive MEMS contact lenses for IOP monitoring 14.7 Conclusion Chapter 15: Drug delivery using wireless MEMS Abstract: 15.1 Introduction 15.2 Wireless power and data for drug delivery applications 15.3 A MEMS approach to drug delivery 15.4 Biological constraints and requirements 15.5 Security concerns for wireless implants 15.6 Wireless inductive powering and uni-directional data system for a MEMS drug pump 15.7 Suggested improvements and future generation device 15.8 Conclusion 15.9 Acknowledgment Chapter 16: RF MEMS for automotive radar Abstract: 16.1 Introduction 16.2 RF MEMS components for automotive radar 16.3 Examples of RF MEMS-based automotive radar front-end technology 16.4 Unconventional MEMS radar beam-steering technologies 16.5 Conclusion Chapter 17: Telecommunications reliability monitoring using wireless MEMS Abstract: 17.1 Introduction 17.2 Typical reliability issues in telecommunication systems 17.3 Reliability monitoring with wireless MEMS 17.4 Case study: multi-MEMS platform 17.5 Conclusion 17.6 Acknowledgements Chapter 18: Optical MEMS for displays in portable systems Abstract: 18.1 Introduction 18.2 MEMS-based direct-view displays 18.3 Handheld picoprojectors 18.4 Automobile head-up display 18.5 Eyewear displays 18.6 Conclusion Index
Subject Areas: WAP [wireless technology TJKW], Electrical engineering [THR]
