Yong Song,received his Ph.D. degree from the Department of Opto-electronic,Beijing Institute of Technology, China, in 2004. In 2007, he was an associate professor with the School of Information Science and Technology, Beijing Institute of Technology. From 2009 to 2010, he was a visiting scientist with the Institute of Optics, University of Rochester, Rochester, NY, America. Recently, he is a professor and the director of the Institute of Opto-Electronic Instrument, Department of Opto-electronic,Beijing Institute of Technology. Dr. Song was selected into the Excellent Talents of Beijing in 2011, and awarded the Excellent Young Scholars Research Fund of Beijing Institute of Technology in 2012. Dr. Song''s research with respect to Intra-Body Communication began in 2006, which was supported by the National Natural Science Foundation of China,theExcellent Talent Cultivation Plan of Beijing, and the Basic Research Foundation of BeijingInstitute of Technology. He holds the first patent of Intra-Body Communication of China, andhas published over 40 technical articles in this field.Qun Hao,received her Ph. D. degree from the Department of PrecisionInstruments and Mechanology, Tsinghua University, China, in1997. In the same year, she joined the faculty of the Department ofOpto-electronic Engineering in Beijing Institute of Technology. Shebecame a full professor in 2003. She was a guest researcher atUniversity of Tokyo, Japan, during 1999 - 2001, and a visitingprofessor at the Department of Biomedical Engineering, Case Western Reserve University,USA in 2011. She is vice chairman of Key Laboratory of Ministry of Education of Bionic Robotand System, director of China Instrument and Control Society and director of Chinese Societyfor Measurement. She was selected into Trans-Century Training Programme for Talents by theState Education Commission in 2003. Her research interests include optics and precisionmeasurement and opto-electronic sensor technology.
目錄:
1.Introduction
1.1 Concept of Intra-Body Communication
1.2 Safety Issue
1.3 Advantages of IBC
1.4 Applications of IBC
1.4.1 Biomedical monitoring
1.4.2 Consumer electronics
1.4.3 Secure space
1.4.4 Application prospect
1.5 The Scope of This Book
1.5.1 The modeling and the simulation of IBC
1.5.2 The implementing methods of IBC
1.5.3 Book contents
References
2.Theory Foun$1ation
2.1 IBC Types
2.1.1 Electrostatic coupling type
2.1.2 Galvanic coupling IBC
2.2 Theoretical Analysis of Signal Transmission Within the Human Body
2.2.1 Signal represented as electromagnetic wave
2.2.2 Signal represented as current density
2.3 Theoretical Explanation of Galvanic Coupling IBC
2.4 Theoretical Explanation of Electrostatic Coupling IBC
2.4.1 Electric fields of electrostatic coupling IBC
2.4.2 Model of electrostatic coupling IBC
2.5 Conclusions
References
3.IBC Modeling Based on the Transfer Function Method
3.1 Current Researches
3.1.1 Galvanic coupling IBC
3.1.2 Electrostatic coupling IBC
3.2 IBC Modeling Based on the Transfer Function
3.2.1 Modeling of galvanic coupling IBC
3.2.2 Modeling of electrostatic coupling IBC
3.3 IBC Simulation Based on the Transfer Function
3.3.1 Method
3.3.2 Signal transmissions along arm
3.3.3 Signal transmissions along different paths
3.4 Discussions
References
4.IBC Modeling and Simulation Based on FEM
4.1 Finite-element Modeling Method
4.2 The Research Status
4.2.1 Research of ETH
4.2.2 Research of HKUST
4.3 Modeling of the Whole Human Body
4.3.1 The modeling of the head and the neck
4.3.2 The modeling of the torso
4.3.3 The modeling of the arm and the leg
4.3.4 The connection of the human body part models
4.4 IBC Simulation Based on FEM
4.4.1 Galvanic coupling IBC
4.4.2 Electrostatic coupling IBC
4.4.3 Electromagnetic parameters
4.5 Simulation Results and Analysis
4.5.1 Simulation results of galvanic coupling IBC
4.5.2 The measurement experiments
4.5.3 Simulation results of electrostatic coupling IBC
4.6 Conclusions
References
5.IBC Based on Electro-Optical Modulation
5.1 Current Studies
5.2 IBC Based on a Mach-Zehnder EO Modulator
5.2.1 Circuit model
5.2.2 Mathematical model
5.2.3 The complete mathematical model
5.3 Experiments
5.3.1 Sensitivity
5.3.2 Frequency response
5.3.3 Temperature characteristic
5.4 Conclusions
References
6.Signal Transmission System of IBC
6.1 Current Research
6.2 IBC System
6.2.1 System structure
6.2.2 DBPSK modulation and demodulation
6.3 Transmitter and Receiver Design
6.3.1 Transmitter circuit
6.3.2 Receiver circuit
6.3.3 Electrodes design
6.4 Experiments and Discussion
6.4.1 Experiment device
6.4.2 Influence of carrier frequency
6.4.3 Influence of baseband frequency
6.4.4 Influence of signal transmission path
6.5 Conclusions
References
7.Conclusions and Future Outlook
7.1 Summary of Intra-Body Communication
7.2 Future Research
7.3 Future Applications of IBC
References
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