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Doppler radar physiological sensing / (Record no. 74483)

000 -LEADER
fixed length control field 10696nam a2201093 i 4500
001 - CONTROL NUMBER
control field 7753057
005 - DATE AND TIME OF LATEST TRANSACTION
control field 20220712205941.0
008 - FIXED-LENGTH DATA ELEMENTS--GENERAL INFORMATION
fixed length control field 170118s2016 njua ob 001 eng d
020 ## - INTERNATIONAL STANDARD BOOK NUMBER
ISBN 9781119078418
-- electronic
020 ## - INTERNATIONAL STANDARD BOOK NUMBER
-- hardback
082 00 - CLASSIFICATION NUMBER
Call Number 612.1/71
245 00 - TITLE STATEMENT
Title Doppler radar physiological sensing /
300 ## - PHYSICAL DESCRIPTION
Number of Pages 1 PDF (xii, 288 pages) :
490 1# - SERIES STATEMENT
Series statement Wiley series in biomedical engineering and multi-disciplinary integrated systems
505 0# - FORMATTED CONTENTS NOTE
Remark 2 List of Contributors xi -- 1 Introduction 1 /Amy D. Droitcour, Olga Boric-Lubecke, Shuhei Yamada, and Victor M. Lubecke -- 1.1 Current Methods of Physiological Monitoring, 2 -- 1.2 Need for Noncontact Physiological Monitoring, 3 -- 1.2.1 Patients with Compromised Skin, 3 -- 1.2.2 Sleep Monitoring, 4 -- 1.2.3 Elderly Monitoring, 5 -- 1.3 Doppler Radar Potential for Physiological Monitoring, 5 -- 1.3.1 Principle of Operation and Power Budget, 6 -- 1.3.2 History of Doppler Radar in Physiological Monitoring, 8 -- References, 16 -- 2 Radar Principles 21 /Ehsan Yavari, Olga Boric-Lubecke, and Shuhei Yamada -- 2.1 Brief History of Radar, 21 -- 2.2 Radar Principle of Operation, 22 -- 2.2.1 Electromagnetic Wave Propagation and Reflection, 23 -- 2.2.2 Radar Cross Section, 24 -- 2.2.3 Radar Equation, 25 -- 2.3 Doppler Radar, 28 -- 2.3.1 Doppler Effect, 28 -- 2.3.2 Doppler Radar Waveforms: CW, FMCW, Pulsed, 29 -- 2.4 Monostatic and Bistatic Radar, 32 -- 2.5 Radar Applications, 35 -- References, 36 -- 3 Physiological Motion and Measurement 39 /Amy D. Droitcour and Olga Boric-Lubecke -- 3.1 Respiratory System Motion, 39 -- 3.1.1 Introduction to the Respiratory System, 39 -- 3.1.2 Respiratory Motion, 40 -- 3.1.3 Chest Wall Motion Associated with Breathing, 43 -- 3.1.4 Breathing Patterns in Disease and Disorder, 43 -- 3.2 Heart System Motion, 44 -- 3.2.1 Location and Gross Anatomy of the Heart, 45 -- 3.2.2 Electrical and Mechanical Events of the Heart, 46 -- 3.2.3 Chest Surface Motion Due to Heart Function, 48 -- 3.2.4 Quantitative Measurement of Chest Wall Motion Due to Heartbeat, 50 -- 3.3 Circulatory System Motion, 53 -- 3.3.1 Location and Structure of the Major Arteries and Veins, 54 -- 3.3.2 Blood Flow Through Arteries and Veins, 55 -- 3.3.3 Surface Motion from Blood Flow, 56 -- 3.3.4 Circulatory System Motion: Variation with Age, 57 -- 3.4 Interaction of Respiratory, Heart, and Circulatory Motion at the Skin Surface, 58 -- 3.5 Measurement of Heart and Respiratory Surface Motion, 58.
505 8# - FORMATTED CONTENTS NOTE
Remark 2 3.5.1 Radar Measurement of Physiological Motion, 59 -- 3.5.2 Surface Motion Measurement of Respiration Rate, 59 -- 3.5.3 Surface Motion Measurement of Heart/Pulse Rate, 61 -- References, 63 -- 4 Physiological Doppler Radar Overview 69 /Aditya Singh, Byung-Kwon Park, Olga Boric-Lubecke, Isar Mostafanezhad, and Victor M. Lubecke -- 4.1 RF Front End, 70 -- 4.1.1 Quadrature Receiver, 73 -- 4.1.2 Phase Coherence and Range Correlation, 77 -- 4.1.3 Frequency Choice, 79 -- 4.1.4 Antenna Considerations, 80 -- 4.1.5 Power Budget, 80 -- 4.2 Baseband Module, 83 -- 4.2.1 Analog Signal Conditioning and Coupling Methods, 83 -- 4.2.2 Data Acquisition, 85 -- 4.3 Signal Processing, 86 -- 4.3.1 Phase Demodulation, 86 -- 4.3.2 Demodulated Phase Processing, 87 -- 4.4 Noise Sources, 90 -- 4.4.1 Electrical Noise, 90 -- 4.4.2 Mechanical Noise, 92 -- 4.5 Conclusions, 92 -- References, 93 -- 5 CW Homodyne Transceiver Challenges 95 /Aditya Singh, Alex Vergara, Amy D. Droitcour, Byung-Kwon Park, Olga Boric-Lubecke, Shuhei Yamada, and Victor M. Lubecke -- 5.1 RF Front End, 95 -- 5.1.1 Single-Channel Limitations, 96 -- 5.1.2 LO Leakage Cancellation, 103 -- 5.1.3 IQ Imbalance Assessment, 109 -- 5.2 Baseband Module, 113 -- 5.2.1 AC and DC Coupling, 113 -- 5.2.2 DC Canceller, 114 -- 5.3 Signal Demodulation, 118 -- 5.3.1 DC Offset and DC Information, 118 -- 5.3.2 Center Tracking, 125 -- 5.3.3 DC Cancellation Results, 130 -- References, 134 -- 6 Sources of Noise and Signal-to-Noise Ratio 137 /Amy D. Droitcour, Olga Boric-Lubecke, and Shuhei Yamada -- 6.1 Signal Power, Radar Equation, and Radar Cross Section, 138 -- 6.1.1 Radar Equation, 138 -- 6.1.2 Radar Cross Section, 140 -- 6.1.3 Reflection and Absorption, 141 -- 6.1.4 Phase-to-Amplitude Conversion, 141 -- 6.2 Oscillator Phase Noise, Range Correlation and Residual Phase Noise, 143 -- 6.2.1 Oscillator Phase Noise, 143 -- 6.2.2 Range Correlation and Residual Phase Noise, 147 -- 6.3 Contributions of Various Noise Sources, 151 -- 6.3.1 Phase Noise, 151.
505 8# - FORMATTED CONTENTS NOTE
Remark 2 6.3.2 Baseband 1/f Noise, 154 -- 6.3.3 RF Additive White Gaussian Noise, 154 -- 6.4 Signal-to-Noise Ratio, 155 -- 6.5 Validation of Range Correlation, 157 -- 6.6 Human Testing Validation, 158 -- References, 168 -- 7 Doppler Radar Physiological Assessments 171 /John Kiriazi, Olga Boric-Lubecke, Shuhei Yamada, Victor M. Lubecke, and Wansuree Massagram -- 7.1 Actigraphy, 172 -- 7.2 Respiratory Rate, 176 -- 7.3 Tidal Volume, 179 -- 7.4 Heart Rates, 184 -- 7.5 Heart Rate Variability, 185 -- 7.6 Respiratory Sinus Arrhythmia, 190 -- 7.7 RCs and Subject Orientation, 196 -- References, 204 -- 8 Advanced Performance Architectures 207 /Aditya Singh, Aly Fathy, Isar Mostafanezhad, Jenshan Lin, Olga Boric-Lubecke, Shuhei Yamada, Victor M. Lubecke, and Yazhou Wang -- 8.1 DC Offset and Spectrum Folding, 208 -- 8.1.1 Single-Channel Homodyne System with Phase Tuning, 208 -- 8.1.2 Heterodyne System with Frequency Tuning, 213 -- 8.1.3 Low-IF Architecture, 220 -- 8.2 Motion Interference Suppression, 224 -- 8.2.1 Interference Cancellation, 226 -- 8.2.2 Bistatic Radar: Sensor Nodes, 231 -- 8.2.3 Passive RF Tags, 240 -- 8.3 Range Detection, 250 -- 8.3.1 Physiological Monitoring with FMCW Radar, 250 -- 8.3.2 Physiological Monitoring with UWB Radar, 251 -- References, 266 -- 9 Applications and Future Research 269 /Aditya Singh and Victor M. Lubecke -- 9.1 Commercial Development, 269 -- 9.1.1 Healthcare, 269 -- 9.1.2 Defense, 272 -- 9.2 Recent Research Areas, 272 -- 9.2.1 Sleep Study, 272 -- 9.2.2 Range, 275 -- 9.2.3 Multiple Subject Detection, 276 -- 9.2.4 Animal Monitoring, 279 -- 9.3 Conclusion, 282 -- References, 282 -- Index 285.
520 ## - SUMMARY, ETC.
Summary, etc Presents a comprehensive description of the theory and practical implementation of Doppler radar-based physiological monitoring This book includes an overview of current physiological monitoring techniques and explains the fundamental technology used in remote non-contact monitoring methods. Basic radio wave propagation and radar principles are introduced along with the fundamentals of physiological motion and measurement. Specific design and implementation considerations for physiological monitoring radar systems are then discussed in detail. The authors address current research and commercial development of Doppler radar based physiological monitoring for healthcare and other applications. . Explains pros and cons of different Doppler radar architectures, including CW, FMCW, and pulsed Doppler radar. Discusses nonlinear demodulation methods, explaining dc offset, dc information, center tracking, and demodulation enabled by dc cancellation. Reviews advanced system architectures that address issues of dc offset, spectrum folding, motion interference, and range resolution. Covers Doppler radar physiological measurements demonstrated to date, from basic cardiopulmonary rate extractions to more involved volume assessments Doppler Radar Physiological Sensing serves as a fundamental reference for radar, biomedical, and microwave engineers as well as healthcare professionals interested in remote physiological monitoring methods.
650 12 - SUBJECT ADDED ENTRY--SUBJECT 1
Subject Heart Rate.
650 12 - SUBJECT ADDED ENTRY--SUBJECT 1
Subject Monitoring, Physiologic
General subdivision methods.
650 22 - SUBJECT ADDED ENTRY--SUBJECT 1
Subject Respiratory Rate.
650 22 - SUBJECT ADDED ENTRY--SUBJECT 1
Subject Signal Processing, Computer-Assisted.
650 22 - SUBJECT ADDED ENTRY--SUBJECT 1
Subject Ultrasonography, Doppler
General subdivision methods.
700 1# - AUTHOR 2
Author 2 Boric-Lubecke, Olga,
700 1# - AUTHOR 2
Author 2 Lubecke, Victor M.,
700 1# - AUTHOR 2
Author 2 Droitcour, Amy D.,
700 1# - AUTHOR 2
Author 2 Park, Byung-Kwon,
700 1# - AUTHOR 2
Author 2 Singh, Aditya,
856 42 - ELECTRONIC LOCATION AND ACCESS
Uniform Resource Identifier https://ieeexplore.ieee.org/xpl/bkabstractplus.jsp?bkn=7753057
942 ## - ADDED ENTRY ELEMENTS (KOHA)
Koha item type eBooks
264 #1 -
-- Hoboken, New Jersey :
-- IEEE, Wiley,
-- [2016]
264 #2 -
-- [Piscataqay, New Jersey] :
-- IEEE Xplore,
-- [2016]
336 ## -
-- text
-- rdacontent
337 ## -
-- electronic
-- isbdmedia
338 ## -
-- online resource
-- rdacarrier
588 ## -
-- Description based on PDF viewed 01/18/2017.
695 ## -
-- Abdomen
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-- Antenna measurements
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-- Baseband
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-- Biomedical monitoring
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-- Clutter
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-- Communication system security
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-- Data acquisition
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-- Demodulation
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-- Diseases
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-- Doppler radar
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-- Electrodes
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-- Electromagnetic scattering
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-- Heart
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-- Instruments
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-- Lungs
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-- Mixers
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-- Monitoring
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-- Motion measurement
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-- Muscles
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-- Phase shifters
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-- Radar antennas
695 ## -
-- Radar cross-sections
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-- Radar detection
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-- Radar imaging
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-- Radio frequency
695 ## -
-- Receivers
695 ## -
-- Receiving antennas
695 ## -
-- Ribs
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-- Robot sensing systems
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-- Sensors
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-- Skin
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-- Sleep
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-- Sleep apnea
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-- Transceivers
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-- Transmitting antennas
695 ## -
-- Tuning
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-- Two dimensional displays
695 ## -
-- Wireless communication
695 ## -
-- Wireless sensor networks

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