Indoor Infrared Optical Wireless Communications Systems and Integration 1st edition by Ke Wang – Ebook PDF Instant Download/Delivery: 0367254247, 9780367254247
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ISBN 10: 0367254247
ISBN 13: 9780367254247
Author: Ke Wang
This book aims to give an overview of recent developments in indoor near-infrared optical wireless communication technologies and systems, including basic theories, operating fundamentals, system architectures, modelling, experimental demonstrations, advanced techniques, and most recently, the research efforts towards integrations. Both line-of-sight and diffusive-signals-based options will be reviewed, to provide readers a complete picture about this rapidly developing area, which targets the provision of high-speed wireless connectivity to end- users in indoor environments, such as offices, homes and shopping centres, to satisfy the growing high-speed communication requirement. Provides a systematic approach for the fundamentals of indoor optical wireless communications. Provides an overview of recent developments in indoor infrared optical wireless communications, including theoretical fundamentals. Examines system architectures, modelling, experimental demonstrations, and the research efforts towards integrations. Dr. Ke Wang is an Australian Research Council (ARC) DECRA Fellow and a senior lecturer in the School of Engineering, Royal Melbourne Institute of Technology (RMIT University), VIC, Australia. He worked with the University of Melbourne, Australia, and Stanford University, California, before joining RMIT University. He has published over 110 peer-reviewed papers in top journals and leading international conferences, including over 20 invited papers. He has been awarded several prestigious national and international awards as recognition of research contributions, such as the Victoria Fellowship, the AIPS Young Tall Poppy Science Award, and the Marconi Society Paul Baran Young Scholar Award. His major areas of interest include: silicon photonics integration, opto-electronics integrated devices and circuits, nanophotonics, optical wireless technology for short-range applications, quasi-passive reconfigurable devices and applications and optical interconnects in data -centres and high-performance computing.
Indoor Infrared Optical Wireless Communications Systems and Integration 1st Table of contents:
1. Introduction: Optical Wireless Communications
1.1 Optical Wireless Communication Technologies
1.2 Optical Wireless Communications – Brief History
1.3 Long-Range Outdoor OWC Systems
1.4 Short-Range OWC Systems
1.4.1 Personal and Local Area Networks
1.4.2 Wireless Body Area Networks and Indoor Localizations
1.4.3 Optical Interconnects
1.5 Book Structure
References
2. Near-Infrared Indoor Optical Wireless Communications: System Architecture, Principle and Modeling
2.1 Near-Infrared Indoor OWC System Architecture
2.1.1 Direct LOS Link-Based Indoor OWC Systems
2.1.2 Diffusive Link-Based Indoor OWC Systems
2.2 Near-Infrared Indoor OWC System Modeling
2.2.1 OWC Transmitter
2.2.2 OWC Receiver
2.2.3 OWC Free-Space Channel
2.3 High-Speed Near-Infrared Indoor OWC System Example
2.3.1 High-Speed Near-Infrared Indoor OWC System Structure
2.3.2 High-Speed Near-Infrared Indoor OWC System Operation Principle
2.3.3 High-Speed Near-Infrared Indoor OWC System Model
2.3.4 High-Speed Near-Infrared Indoor OWC System Simulation and Analysis
2.3.5 High-Speed Near-Infrared Indoor OWC System Demonstration
2.4 Background Light in Indoor OWC Systems
2.5 Conclusions
References
3. Spatial Diversity Techniques in Near-Infrared Indoor Optical Wireless Communication (OWC) Systems
3.1 Spatial Diversity Techniques in Indoor OWC Systems
3.2 High-Speed Indoor OWC System with Transmitter Diversity
3.2.1 Repetition Coded Indoor OWC System
3.2.2 Space-Time Coded Indoor OWC System
3.3 Comparison of STBC- and RC-Based High-Speed Indoor OWC System
3.4 Delay-Tolerant High-Speed Indoor OWC System with Transmitter Diversity
3.5 Conclusions
References
4. Wavelength Multiplexing and Multi-User Access in Near-Infrared Indoor Optical Wireless Communication Systems
4.1 Indoor OWC Systems with WDM
4.2 FDMA-, CDMA- and TDMA-Based Multi-User Access in Indoor OWC Systems
4.3 TSC-Based Multi-User Access in Indoor OWC Systems
4.3.1 Time-Slot-Coding-Based Multi-User Access in Indoor OWC Systems
4.3.2 Adaptive Loading-Based Time-Slot Coding for Multi-User Access
4.3.3 TSC Code Misalignment Tolerance
4.4 Conclusions
References
5. Photonic Integrations of Near-Infrared Indoor Optical Wireless Communications
5.1 Introduction of Photonic Integrations
5.2 Silicon Photonic Integrated Passive Devices
5.2.1 Silicon Waveguides
5.2.2 Silicon Integrated Polarization Splitter and Rotator
5.2.3 Silicon Integrated Optical Filters
5.2.4 Silicon Integrated Optical Power Splitters
5.3 Silicon Photonic Integrated Active Devices
5.3.1 Silicon Integrated Optical Modulators
5.3.2 Silicon Integrated Photodetectors
5.4 Silicon Photonic Integrations for Indoor OWC Systems
5.4.1 Beam Steering Devices in Indoor OWC Systems
5.4.2 Optical Phased Arrays for Beam Steering
5.4.3 Silicon Integrated Optical Phased Arrays
5.5 Demonstration of Indoor OWC System with Silicon Photonic Integrated Circuit
5.6 Conclusions
References
6. Indoor Optical Wireless Localization Technology
6.1 Indoor Localization Systems
6.2 Indoor Localization Based on the Optical Wireless Technology – “Search and Scan”
6.3 Indoor Optical Wireless Localization Principles with High Accuracy
6.4 Three-Dimensional Indoor Optical Wireless Localization
6.5 Conclusions
References
7. Conclusions and Future Directions
7.1 Conclusions
7.2 Optical Interconnect Application of Near-Infrared Optical Wireless Technology
7.3 Future Research Needs and Directions
References
Index
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Tags: Ke Wang, Indoor Infrared, Wireless Communications