Wearable communication systems and antennas : design, efficiency, and miniaturization techniques /

The main objective of this book is to present efficient wearable systems, compact sensors and antennas for communication and healthcare systems.

Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Sabban, Albert (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Bristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) : IOP Publishing, [2022]
Edición:Second edition.
Colección:IOP (Series). Release 22.
IOP ebooks. 2022 collection.
Temas:
Wearable computers.
Wireless communication systems > Equipment and supplies.
Antennas (Electronics)
Human-computer interaction.
WAP (wireless) technology.
Engineering.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • 1. Theory of wireless wearable communication systems
  • 1.1. Wireless wearable communication systems : frequency range
  • 1.2. Free space propagation
  • 1.3. Electromagnetic transmission, Friis formula
  • 1.4. Wearable communication channel budget
  • 1.5. Noise
  • 1.6. Communication systems channel budget calculation
  • 1.7. Communication system path loss
  • 1.8. Receiver sensitivity
  • 1.9. Definitions and characteristics of receiving channel
  • 1.10. Basic features of radars
  • 1.11. Communication systems transmitters--definitions and features
  • 1.12. Introduction to wearable communication and IOT systems basics
  • 1.13. Internet of things IoT basics
  • 1.14. Satellite communication transceiver
  • 1.15. Conclusions
  • 2. Wearable communication technology for medical and sport applications
  • 2.1. Wearable technology
  • 2.2. Wearable medical systems
  • 2.3. Physiological parameters measured by wearable medical systems
  • 2.4. Wearable body-area networks (WBANs)
  • 2.5. Wearable wireless body-area network (WWBAN)
  • 2.6. Conclusions
  • 3. Electromagnetic waves and transmission lines for wearable communication systems
  • 3.1. Electromagnetic spectrum
  • 3.2. Basic electromagnetic wave definitions
  • 3.3. Electromagnetic waves theory
  • 3.4. Wave propagation through the human body
  • 3.5. Materials
  • 3.6. Transmission lines theory
  • 3.7. Matching techniques
  • 3.8. Coaxial transmission line
  • 3.9. Microstrip line
  • 3.10. Waveguides
  • 3.11. Circular waveguide
  • 4. Microwave technologies for wearable communication systems
  • 4.1. Introduction
  • 4.2. MIC--microwave integrated circuit
  • 4.3. Low noise K band compact receiving channel for a satellite communication ground terminal
  • 4.4. MMICs--monolithic microwave integrated circuits
  • 4.5. 18-40 GHz front end
  • 4.6. MEMS technology
  • 4.7. W band MEMS detection array
  • 4.8. MEMS bow-tie dipole with a bolometer
  • 4.9. LTCC and HTCC technology
  • 4.10. Conclusions
  • 5. RF components and module design for wearable communication systems
  • 5.1. Introduction
  • 5.2. Passive elements
  • 5.3. Power dividers and combiners
  • 5.4. RF amplifiers
  • 5.5. Linearity of RF amplifiers, active devices
  • 5.6. Wideband phased array direction finding system
  • 5.7. Conclusions
  • 6. System engineering of body-area networks, BAN communication systems
  • 6.1. Introduction
  • 6.2. Cloud storage and computing services for wearable body-area networks
  • 6.3. Wireless body area networks (WBANs) systems and applications
  • 6.4. Wearable wireless body area network (WWBAN) systems and applications
  • 6.5. Systems engineering methodology for wearable medical systems
  • 6.6. System engineering tools for the development of wearable medical systems
  • 6.7. ICDM--integrated, customer-driven, conceptual design method
  • 6.8. 434 MHz receiving channel for communication and medical systems
  • 6.9. Conclusions
  • 7. Wearable antennas for wireless communication systems
  • 7.1. Introduction to antennas
  • 7.2. Antenna definitions
  • 7.3. Dipole antenna
  • 7.4. Monopole antenna for wearable communication systems
  • 7.5. Loop antennas for wireless communication systems
  • 7.6. Wearable printed antennas
  • 7.7. Two-layer wearable stacked microstrip antennas
  • 7.8. Stacked mono-pulse Ku band patch antenna
  • 7.9. Wearable loop antennas
  • 7.10. Planar wearable inverted-F antenna (PIFA)
  • 7.11. Conclusions
  • 8. Wideband wearable antennas for communication and medical applications
  • 8.1. Introduction
  • 8.2. Printed wearable dual polarized dipole antennas
  • 8.3. Printed wearable loop antenna
  • 8.4. Compact dual polarized wearable antennas
  • 8.5. Conclusions
  • 9. Analysis and measurements of wearable antennas in the vicinity of the human body
  • 9.1. Introduction
  • 9.2. Analysis of wearable antennas
  • 9.3. Design of wearable antennas in the vicinity of the human body
  • 9.4. Wearable antenna arrays
  • 9.5. Small wide band dual polarized wearable printed antennas
  • 9.6. Wearable helix antenna's performance on the human body
  • 9.7. Wearable antenna measurements in the vicinity of the human body
  • 9.8. Phantom configuration
  • 9.9. Measurements of wearable antennas using a phantom
  • 9.10. Measurement results of wearable antennas
  • 9.11. Conclusions
  • 10. Wearable RFID technology and antennas
  • 10.1. Introduction
  • 10.2. RFID technology
  • 10.3. RFID standards
  • 10.4. Dual polarized 13.5 MHz compact printed antenna
  • 10.5. Varying the antenna feed network
  • 10.6. Wearable loop antennas for RFID applications
  • 10.7. Proposed antenna applications
  • 10.8. Conclusions
  • 11. Novel wearable printed antennas for wireless communication and medical systems
  • 11.1. Wideband wearable metamaterial antennas for wireless communication applications
  • 11.2. Stacked patch antenna loaded with SRR
  • 11.3. Patch antenna loaded with split ring resonators
  • 11.4. Metamaterial antenna characteristics in the vicinity of the human body
  • 11.5. Metamaterial wearable antennas
  • 11.6. Wideband stacked patch with SRR
  • 11.7. Fractal printed antennas
  • 11.8. Anti-radar fractals and/or multilevel chaff dispersers
  • 11.9. Definition of a multilevel fractal structure
  • 11.10. Advanced antenna system
  • 11.11. Applications of fractal printed antennas
  • 11.12. Conclusion
  • 12. Active wearable printed antennas for medical applications
  • 12.1. Tunable printed antennas
  • 12.2. Varactors : theory
  • 12.3. Dually polarized tunable printed antenna
  • 12.4. Wearable tunable antennas
  • 12.5. Varactors : electrical characteristics
  • 12.6. Measurements of wearable tunable antennas
  • 12.7. Folded wearable dual polarized tunable antenna
  • 12.8. Medical applications for wearable tunable antennas
  • 12.9. Active wearable antennas
  • 12.10. Active transmitting antenna
  • 12.11. Conclusions
  • 13. New wideband passive and active wearable slot and notch antennas for wireless and medical communication systems
  • 13.1. Slot antennas
  • 13.2. Slot radiation pattern
  • 13.3. Slot antenna impedance
  • 13.4. A wideband wearable printed slot antenna
  • 13.5. A wideband T shape wearable printed slot antenna
  • 13.6. Wideband wearable notch antenna for wireless communication systems
  • 13.7. Wearable tunable slot antennas for wireless communication systems
  • 13.8. A wideband T shape tunable wearable printed slot antenna
  • 13.9. Wearable active slot antennas for wireless communication systems
  • 13.10. Wearable active T shape slot antennas for wireless communication systems
  • 13.11. New fractal compact ultra-wideband, 1 GHz to 6 GHz, notch antenna
  • 13.12. New compact ultra-wideband notch antenna 1.3 GHz to 3.9 GHz
  • 13.13. New compact ultra-wideband notch antenna 5.8 GHz to 18 GHz
  • 13.14. New fractal active compact ultra-wideband, 0.5 GHz to 3 GHz, notch antenna
  • 13.15. New compact ultra-wideband active notch antenna 0.4 GHz to 3 GHz
  • 13.16. Conclusions
  • 14. Aperture antennas for wireless communication systems
  • 14.1. The parabolic reflector antenna's configuration
  • 14.2. Reflector directivity
  • 14.3. Cassegrain reflector
  • 14.4. Horn antennas
  • 14.5. Antenna arrays for wireless communication systems
  • 14.6. Integrated outdoor unit for mm wave communication systems
  • 14.7. Solid state power amplifier, SSPA
  • 14.8. Solid state high power amplifiers, SSPAs, for mm wave communication system
  • 14.9. Integrated Ku band automatic tracking system
  • 14.10. Conclusions
  • 15. Compact circular patch wearable metamaterials antennas for healthcare, IOT, and 5G systems
  • 15.1. Introduction
  • 15.2. Circular metamaterial patch with CSRR
  • 15.3. Active receiving compact circular patch antennas
  • 15.4. Active transmitting wearable circular patch
  • 15.5. Active receiving compact stacked circular patch antenna
  • 15.6. Metamaterial wearable stacked circular patch antennas
  • 15.7. Applications of wearable antennas for healthcare and IoT systems
  • 15.8. Conclusions
  • 16. Green electronic and communication technologies--going green
  • 16.1. Introduction to green electronic technologies
  • 16.2. Electronic and communication green technologies
  • 16.3. Renewable green energy for electronic and RF systems
  • 16.4. Recycling in the electronics and computing industry
  • 16.5. Innovations and challenges in green technologies
  • 17. Analysis and design of wearable communication, medical and IOT systems
  • 17.1. Introduction
  • 17.2. Commercial electromagnetic software
  • 17.3. Advance design system, ADS
  • 17.4. CST electromagnetic software
  • 17.5. Microwave office, AWR
  • 17.6. Evaluation of losses in wearable sensors and antennas
  • 17.7. Computation of radiation loss in wearable antennas feed network
  • 17.8. Conclusions
  • 18. Measurements of wearable systems and antennas
  • 18.1. Introduction
  • 18.2. Representation of wearable systems by N ports model
  • 18.3. Scattering matrix
  • 18.4. S parameter measurements for RF devices
  • 18.5. RF transmission measurements
  • 18.6. Output power and linearity measurements
  • 18.7. Power input protection measurements of RF devices
  • 18.8. Non-harmonic spurious measurements of RF devices
  • 18.9. Switching time measurements of RF devices
  • 18.10. IP2 measurements
  • 18.11. IP3 measurements
  • 18.12. Noise figure measurements
  • 18.13. Antennas' electrical performance measurements
  • 18.14. Antenna range setup
  • 18.15. Conclusions
  • 19. Ethics in wearable healthcare and communication systems
  • 19.1. Introduction to ethics theory and practice
  • 19.2. The basics of ethics theory
  • 19.3. Medical ethics
  • 19.4. Ethical problems
  • 19.5. Ethics in organizations and companies
  • 19.6. Ethical dilemmas in science research and development
  • 19.7. Ethical dilemmas for using computers and the internet
  • 19.8. How to prevent and minimize ethical crimes in the digital media
  • 19.9. Conclusions.

Ejemplares similares