Wireless communications : signal processing perspectives

62034-4 Signal processing algorithms and architectures have an increasingly important role to play in meeting the central challenges faced in the design of advanced wireless communication systems. In Wireless Communications: Signal Processing Perspectives, leaders in the field describe state-of-the-art research in applying signal processing methodologies in the context of tomorrow's most important wireless applications, ranging from next-generation cellular telephony and personal communication services, to nomadic computing and wireless multimedia. Wireless Communications: Signal Processing Perspectives is a valuable reference both for signal processing specialists seeking to apply their expertise in the rapidly growing wireless communications field, and for communications specialists eager to exploit signal processing techniques and implementations in developing efficient wireless systems of the future. Wireless Communications: Signal Processing Perspectives includes both physical and network layer topics: * diversity strategies * interference suppression algorithms * equalization structures * array processing techniques * capacity measures and power control * network architecture * data compression and coding * underwater acoustic systems The book also contains a thought-provoking essay by Andrew J. Viterbi on the laws of nature and society that ultimately govern wireless networks.

Each chapter concludes with 'References' and 'Acknowledgments.' List of Contributors. 1. Linear Diversity Techniques for Fading Channels, Gregory W. Wornell. 1.1 System and Fading Channel Models. 1.2 Transmission without Diversity. 1.3 Spectral Diversity. 1.4 Temporal Diversity. 1.5 Diversity Methods for Multiuser Systems. 1.6 Spatial Diversity. 1.7 Concluding Remarks. 2. Adaptive Interference Suppression, Michael L. Honig and H. Vincent Poor. 2.1 Multiple-Access Signal Model. 2.2 Elements of Multiuser Detection. 2.3 Linear Interference Suppression. 2.4 Application to DS-CDMA. 2.5 Adaptive Algorithms. 2.6 Further Issues and Refinements. 2.7 Concluding Remarks. 3. Equalization of Multiuser Channels, Haralabos C. Papadopoulos. 3.1 Characterization of Wireless Channels. 3.2 Equalization of Known Multipath Fading Channels. 3.3 Blind Equalization in Multipath, Slowly Time-Varying Channels. 3.4 Concluding Remarks. 4. Blind Space-Time Signal Processing, Arogyaswami J. Paulraj, Constantinos B. Papadias, Vellenki U. Reddy, and Alle-Jan van der Veen. 4.1 The Wireless Propagation Environment. 4.2 Signal Model and Structure. 4.3 Channel Identification and Equalization. 4.4 Blind Techniques. 4.5 Concluding Remarks. 5. Network Capacity, Power Control, and Effective Bandwidth, David N. C. Tse and Stephen V. Hanly. 5.1 Basic Spread-Spectrum Model and the MMSE Receiver 5.2 Performance under Random Spreading Sequences 5.3 Capacity and Performance under Power Control 5.4 Multiple Classes, Maximum Power Constraints, and Effective Bandwidths. 5.5 The Decorrelator. 5.6 Antenna Diversity. 5.7 Concluding Remarks. 6. Architectural Principles for Multimedia Networks, Paul Haskell, David G. Messerschmitt, and Louis Yun. 6.1 Basic Considerations. 6.2 Modularity of Services and Bitway Layers. 6.3 Edge vs. Link Architecture for Service Layer. 6.4 Design Examples. 6.5 Concluding Remarks. 7. Multiresolution Joint Source-Channel Coding, Kannan Ramchandran and Martin Vetterli. 7.1 Multiresolution Source Coding for Images and Video. 7.2 Multiresolution Channel Coding. 7.3 Multiresolution Joint Source-Channel Coding. 7.4 Concluding Remarks. 8. Underwater Acoustic Communications, David Brady and James C. Preisig. 8.1 The Underwater Acoustic Channel. 8.2 Platform Constraints in Underwater Acoustic Communications. 8.3 A Brief History of Underwater Acoustic Communications. 8.4 Signal Processing in Digital Underwater Communications. 8.5 Concluding Remarks. Epilogue: Four Laws of Nature and Society: The Governing Principles of Digital Wireless Communication Networks, Andrew J. Viterbi. E.1 Overview. E.2 Wireless Propagation and Its Anomalies. E.3 Shannon Theory: Limitations on Signal Processing. E.4 Half a Century of Wireless Spread Spectrum: From Military to Commercial Applications. E.5 Moore's Law: The Socio-Economic Basis for Digital Wireless. E.6 Metcalfe's Law: Implications for Wireless Networks. List of Acronyms. Index.