Antenna and Sensor Technologies in Modern Medical Applications

Herausgegeben:Rahmat-Samii, Yahya

• Gebundenes Buch

Produktbeschreibung

A guide to the theory and recent development in the medical use of antenna technology

Antenna and Sensor Technologies in Modern Medical Applications offers a comprehensive review of the theoretical background, design, and the latest developments in the application of antenna technology. Written by two experts in the field, the book presents the most recent research in the burgeoning field of wireless medical telemetry and sensing that covers both wearable and implantable antenna and sensor technologies.

The authors review the integrated devices that include various types of sensors wired within a wearable garment that can be paired with external devices. The text covers important developments in sensor-integrated clothing that are synonymous with athletic apparel with built-in electronics. Information on implantable devices is also covered. The book explores technologies that utilize both inductive coupling and far field propagation. These include minimally invasive microwave ablation antennas, wireless targeted drug delivery, and much more. This important book:
_ Covers recent developments in wireless medical telemetry
_ Reviews the theory and design of in vitro/in vivo testing
_ Explores emerging technologies in 2D and 3D printing of antenna/sensor fabrication
_ Includes a chapter with an annotated list of the most comprehensive and important references in the field

Written for students of engineering and antenna and sensor engineers, Antenna and Sensor Technologies in Modern Medical Applications is an essential guide to understanding human body interaction with antennas and sensors.

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Produktdetails

• Wiley - IEEE
• Verlag: Wiley / Wiley & Sons
• Artikelnr. des Verlages: 1W119683300
• 1. Auflage
• Seitenzahl: 624
• Erscheinungstermin: 16. März 2021
• Englisch
• Abmessung: 230mm x 160mm x 32mm
• Gewicht: 1076g
• ISBN-13: 9781119683308
• ISBN-10: 1119683300
• Artikelnr.: 59258992

Autorenporträt

YAHYA RAHMAT-SAMII, PHD, is a Distinguished Professor, holder of the Northrop-Grumman Chair in Electromagnetics at the University of California, Los Angeles, member of the US National Academy of Engineering, Fellow of the IEEE, URSI, ACES, AMTA and EMA, recipient of the IEEE Electromagetnics Award and Third Millennium Medal, UCLA Distinguished Teaching Award, URSI Booker Gold Medal and Ellis Island Medal of Honor. ERDEM TOPSAKAL, PHD, is a tenured full Professor and Electrical and Computer Engineering Department Chair at Virginia Commonwealth University, Richmond, Virginia.

Inhaltsangabe

List of Contributors xvii

1 Introduction 1
Yahya Rahmat-Samii and Erdem Topsakal

2 Ultraflexible Electrotextile Magnetic Resonance Imaging (MRI) Radio-Frequency Coils 11
Daisong Zhang and Yahya Rahmat-Samii

2.1 Introduction to MRI and the Basic Antenna Considerations 11

2.2 Motivations, Challenges, and Strategies for MRI RF Coil Design 15

2.2.1 Design Motivations and Challenges for MRI RF Coils 15

2.2.2 Design Strategies and Roadmap of MRI RF Coils 18

2.3 Selection, Fabrication, and Characterization of Electrotextiles for RF Coils 20

2.3.1 Selection and Fabrication of Flexible Material Candidate 20

2.3.2 Characterization of Electrotextiles 22

2.4 Design of Single-Element Flexible RF Coil 26

2.4.1 RF Coil Element Design with a Rigid Material 26

2.4.2 RF Coil Element Design with Electrotextile Cloth 30

2.4.3 RF Coil Element Design with Tunable Circuitry 31

2.5 Design of Flexible RF Coil Array and System Integration with MRI Scanner 31

2.5.1 RF Coil Array Design and Characterization 32

2.5.2 RF Coil Array System Integration with MRI Scanner 33

2.6 Characterization of RF Coil Array 34

2.6.1 Characterization of RF Coil Array System with Phantom 35

2.6.2 Characterization of RF Coil Array System with Cadaver 38

2.7 Conclusion 38

References 38

3 Wearable Sensors for Motion Capture 43
Vigyanshu Mishra and Asimina Kiourti

3.1 Introduction 43

3.2 The Promise of Motion Capture 45

3.2.1 Healthcare 45

3.2.2 Sports 47

3.2.3 Human-Machine Interfaces 47

3.2.4 Animation/Movies 48

3.2.5 Biomedical Research 48

3.3 Motion Capture in Contrived Settings 49

3.3.1 Camera-Based Motion Capture Laboratory 49

3.3.2 Electromagnetics-Based Sensors 52

3.3.2.1 RADAR Based 52

3.3.2.2 Wi-Fi Based 55

3.3.2.3 RFID Based 57

3.3.3 Magnetic Motion Capture System 59

3.3.4 Imaging Methods 60

3.3.5 Additional Sensors/Tools 60

3.3.5.1 Goniometers 61

3.3.5.2 Force Plates 62

3.4 Wearable Motion Capture (Noncontrived Settings) 63

3.4.1 Inertial Measurement Units (IMUs) 63

3.4.2 Bending/Deformation Sensors 65

3.4.2.1 Strain Based 65

3.4.2.2 Fiber Optics Based 68

3.4.3 Time-of-Flight (TOF) Sensors 70

3.4.3.1 Acoustic Based 70

3.4.3.2 Radio Based 71

3.4.4 Received Signal Strength-based Sensors 73

3.4.4.1 Antenna Based 73

3.4.4.2 Magnetoinductive Sensors/Electrically Small Loop Antennas 74

3.5 Conclusion 78

References 82

4 Antennas and Wireless Power Transfer for Brain-Implantable Sensors 91
Leena Ukkonen, Lauri Sydänheimo, Toni Björninen and Shubin Ma

4.1 Introduction 91

4.2 Implantable Antennas for Wireless Biomedical Devices 92

4.3 Wireless Power Transfer Techniques for Implantable Devices 95

4.3.1 Inductive Power Transfer 95

4.3.2 Ultrasonic Power Transfer 97

4.3.3 Near-Field Capacitive Power Transfer 98

4.3.4 Far-Field Power Transfer 99

4.3.5 Computing the Fundamental Performance Indicators of Near-Field WPT Systems Using Two-Port Network Approach 100

4.4 Human Body Models for Implantable Antenna Development 107

4.4.1 Comparison of Human Head Phantoms with Different Complexities for Intracranial Implantable Antenna Development 110

4.5 Wirelessly Powered Intracranial Pressure Sensing System Integrating Near- and Far-Field Antennas 1