Handbook of biomedical telemetry /

"Handbook of Biomedical Telemetry describes the main components of a typical biomedical telemetry system as well as its technical challenges. Author K.S. Nikita addresses technologies for biomedical sensing and design of biomedical telemetry devices with special emphasis on powering/integration...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor Corporativo: Institute of Electrical and Electronics Engineers
Otros Autores: Nikita, Konstantina S. (Editor )
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Hoboken, New Jersey : John Wiley & Sons Inc., [2014]
Colección:IEEE Press series in biomedical engineering.
Temas:
Biotelemetry.
Radio telemetry.
Telemetry
Biosensing Techniques
Biotélémétrie.
Télémesure.
HEALTH & FITNESS > Holism.
HEALTH & FITNESS > Reference.
MEDICAL > Alternative Medicine.
MEDICAL > Atlases.
MEDICAL > Essays.
MEDICAL > Family & General Practice.
MEDICAL > Holistic Medicine.
MEDICAL > Osteopathy.
Radio telemetry
Biotelemetry
Internet Resources.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • PREFACE xxi
  • ACKNOWLEDGMENTS xxiii
  • CONTRIBUTORS xxv
  • 1 Introduction to Biomedical Telemetry 1 /Konstantina S. Nikita
  • 1.1 What is Biomedical Telemetry? 1
  • 1.2 Significance of Area, 3
  • 1.3 Typical Biomedical Telemetry System, 4
  • 1.4 Challenges in Biomedical Telemetry, 5
  • 1.5 Commercial Medical Telemetry Devices, 14
  • 1.6 Overview of Book, 19
  • References, 23
  • PART I BIOMEDICAL TELEMETRY DEVICES 27
  • 2 Design Considerations of Biomedical Telemetry Devices 29 /Dominik Cirmirakis and Andreas Demosthenous
  • 2.1 Introduction, 29
  • 2.2 Energy Transfer Types, 30
  • 2.3 Architecture of Inductively Coupled Biomedical Telemetry Devices, 31
  • 2.4 Data Transmission Methods, 39
  • 2.5 Safety Issues, 44
  • 2.6 Conclusion, 51
  • References, 51
  • 3 Sensing Principles for Biomedical Telemetry 56 /Athanasios Lioumpas, Georgia Ntouni, and Konstantina S. Nikita
  • 3.1 Introduction, 56
  • 3.2 Biosensor Structure, 57
  • 3.3 Electrochemical Biosensors, 59
  • 3.4 Optical Biosensors, 63
  • 3.5 Thermal/Calorimetric Biosensors, 67
  • 3.6 Piezoelectric Biosensors, 69
  • 3.7 Other Types of Biosensors, 71
  • 3.8 Conclusions, 72
  • References, 73
  • 4 Sensing Technologies for Biomedical Telemetry 76 /Toshiyo Tamura
  • 4.1 Introduction, 76
  • 4.2 Noninvasive Sensors and Interfaces, 77
  • 4.3 Invasive and Implantable Sensors, 92
  • 4.4 Conclusion, 101
  • References, 101
  • 5 Power Issues in Biomedical Telemetry 108 /Manos M. Tentzeris, Rushi Vyas, WeiWei, Yoshihiro Kawahara, Li Yang, Stavros Georgakopoulos, Vasileios Lakafosis, Sangkil Kim, Hoseon Lee, Taoran Le, Sagar Mukala, and Anya Traille
  • 5.1 Introduction and Powering Mechanisms, 108
  • 5.2 Motion-Powered Radio Frequency Identification (RFID) Wireless Sensors, 109
  • 5.3 Noninvasive Wireless Methods for Powering on Sensors, 112
  • 5.4 Conclusion, 129
  • References, 129
  • PART II PROPAGATION AND COMMUNICATION ISSUES FOR BIOMEDICAL TELEMETRY 131
  • 6 Numerical and Experimental Techniques for Body Area Electromagnetics 133 /Asimina Kiourti and Konstantina S. Nikita.
  • 6.1 Introduction, 133
  • 6.2 Electrical Properties of Human Body Tissues, 135
  • 6.3 Numerical Modeling, 139
  • 6.4 Physical Modeling, 154
  • 6.5 Safety Issues, 164
  • 6.6 Conclusion, 167
  • References, 168
  • 7 Inductive Coupling 174 /Maysam Ghovanloo and Mehdi Kiani
  • 7.1 Introduction, 174
  • 7.2 Induction Principles, 175
  • 7.3 Wireless Power Transmission, 178
  • 7.4 Inductive Coupling for Biomedical Telemetry, 186
  • 7.5 Inductive Data Transmission, 192
  • 7.6 Broader Applications, 201
  • 7.7 Future Research Directions, 202
  • 7.8 Conclusion, 202
  • References, 203
  • 8 Antennas and RF Communication 209 /Asimina Kiourti and Konstantina S. Nikita
  • 8.1 Introduction, 209
  • 8.2 Background Information, 211
  • 8.3 On-Body Antennas, 212
  • 8.4 Implantable Antennas, 223
  • 8.5 Ingestible Antennas, 235
  • 8.6 Conclusion and Future Research Directions, 245
  • References, 246
  • 9 Intrabody Communication 252 /Laura M. Roa, Javier Reina-Tosina, Amparo Callejon-Leblic, David Naranjo, and Miguel A. Estudillo-Valderrama
  • 9.1 Introduction, 252
  • 9.2 Intrabody Communication Transmission Methods, 256
  • 9.3 Dielectric Properties of Human Body, 259
  • 9.4 Experimental Characterization of IBC Channel, 265
  • 9.5 Introduction to IBC Models, 273
  • 9.6 IBC Propagation Channel, 282
  • 9.7 Conclusion, 292
  • Acknowledgments, 294
  • References, 294
  • 10 Optical Biotelemetry 301 /Koichi Shimizu
  • 10.1 Introduction, 301
  • 10.2 Optical Technology for Optical Biotelemetry, 303
  • 10.3 Communication Technology for Optical Telemetry, 306
  • 10.4 Propagation of Optical Signal, 309
  • 10.5 Multiplexing in Optical Telemetry, 313
  • 10.6 Applications of Optical Telemetry, 316
  • 10.7 Conclusion, 327
  • References, 328
  • 11 Biosensor Communication Technology and Standards 330 /Lars Schmitt, Javier Espina, Thomas Falck, and Dong Wang
  • 11.1 Introduction, 330
  • 11.2 Biosensor Application Scenarios, 332
  • 11.3 Biosensor Communication Technologies, 335
  • 11.4 Conclusion, 364
  • References, 365.
  • 12 Context-Aware Sensing and Multisensor Fusion 368 /Stefan Hey
  • 12.1 Introduction, 368
  • 12.2 Context-Aware Sensing, 368
  • 12.3 Multisensor Fusion, 373
  • 12.4 Example Application: Stress Measurement, 378
  • 12.5 Conclusion and Future Research Directions, 379
  • References, 379
  • 13 Security and Privacy in Biomedical Telemetry: Mobile Health Platform for Secure Information Exchange 382 /Nikolaos Bourbakis, Alexandros Pantelopoulos, and Raghudeep Kannavara
  • 13.1 Introduction, 382
  • 13.2 Digital Security, 383
  • 13.3 Wearable Health Monitoring Systems (WHMS) Platform, 390
  • 13.4 Processing of Physiological Data, 394
  • 13.5 Secure Information Exchange, 400
  • 13.6 Conclusion and Future Research Directions, 414
  • Acknowledgment, 415
  • References, 415
  • 14 Connection Between Biomedical Telemetry and Telemedicine 419 /Emmanouil G. Spanakis, Vangelis Sakkalis, Kostas Marias, and Manolis Tsiknakis
  • 14.1 Introduction, 419
  • 14.2 Biomedical Instrumentation, 420
  • 14.3 Biomedical Telemetry and Telemedicine: Related Work, 421
  • 14.4 Theory and Applications of Biomedical Telemetry, 423
  • 14.5 Integration of Biomedical Telemetry with Telemedicine, 423
  • 14.6 Wireless Communication Protocols and Standards, 425
  • 14.7 Cross-Layer Design of Wireless Biomedical Telemetry and Telemedicine Health Networks, 425
  • 14.8 Telecommunication Networks in Health Care for Biomedical Telemetry, 428
  • 14.9 Future Research Directions and Challenges, 437
  • 14.10 Conclusion, 440
  • References, 442
  • 15 Safety Issues in Biomedical Telemetry 445 /Konstantinos A. Psathas, Asimina Kiourti, and Konstantina S. Nikita
  • 15.1 Introduction, 445
  • 15.2 Operational Safety, 446
  • 15.3 Product and Device Hazards, 450
  • 15.4 Patient and Clinical Safety, 454
  • 15.5 Human Factor and Use Issues, 458
  • 15.6 Electromagnetic Compatibility and Interference Issues, 461
  • 15.7 Applicable Guidelines, 464
  • 15.8 Occupational Safety, 471
  • 15.9 Future Research Directions, 472
  • 15.10 Conclusion, 473.

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