The high level of technical detail included in standards specifications can make it difficult to find the correlation between the standard specifications and the theoretical results. This book aims to cover both of these elements to give accessible information and support to readers. It explains the current and future trends on communication theory and shows how these developments are implemented in contemporary wireless communication standards.
Examining modulation, coding and multiple access techniques, the book is divided into two major sections to cover these functions. The two-stage approach first treats the basics of modulation and coding theory before highlighting how these concepts are defined and implemented in modern wireless communication systems. Part 1 is devoted to the presentation of main L1 procedures and methods including modulation, coding, channel equalization and multiple access techniques. In Part 2, the uses of these procedures and methods in the wide range of wireless communication standards including WLAN, WiMax, WCDMA, HSPA, LTE and cdma2000 are considered.
- An essential study of the implementation of modulation and coding techniques in modern standards of wireless communication
- Bridges the gap between the modulation coding theory and the wireless communications standards material
- Divided into two parts to systematically tackle the topic - the first part develops techniques which are then applied and tailored to real world systems in the second part
- Covers special aspects of coding theory and how these can be effectively applied to improve the performance of wireless communications systems
Arvustused
This is a timely book on wireless communications, with twelve chapters covering theoretical results and material of Standards The effort dedicated by the authors to bridge technology with standards for sure will be very well appreciated by the readers. (IEEE Communications Magazine, 1 June 2012)
About the Editors. List of Contributors. Acknowledgements.
Introduction.
1. Channel Models and Reliable Communications (Evgenii Krouk,
Andrei Ovchinnikov, and Jussi Poikonen) 1.1 Principles of Reliable
Communication. 1.2 AWGN. 1.3 Fading Processes in Wireless Communication
Channels. 1.4 Modelling Frequency-Nonselective Fading. 1.5 WSSUS Models for
Frequency-Selective Fading. References.
2. Modulation (Sergei Semenov).
2.1 Basic Principles of Bandpass Modulation. 2.2 PSK. 2.3 MSK. 2.4 QAM.
2.5 OFDM. References.
3. Block Codes (Grigorii Kabatiansky, Evgenii Krouk,
Andrei Ovchinnikov, and Sergei Semenov). 3.1 Main Definitions. 3.2
Algebraic Structures. 3.3 Linear Block Codes. 3.4 Cyclic Codes. 3.5 Bounds
on Minimum Distance. 3.6 Minimum Distance Decoding. 3.7 Information Set
Decoding. 3.8 Hamming Codes. 3.9 Reed-Solomon Codes. 3.10 BCH Codes. 3.11
Decoding of BCH Codes. 3.12 Sudan Algorithm and Its Extensions. 3.13 LDPC
Codes. References.
4. Convolutional Codes and Turbo-Codes (Sergei Semenov
and Andrey Trofimov). 4.1 Convolutional Codes Representation and Encoding.
4.2 Viterbi Decoding Algorithm. 4.3 List Decoding. 4.4 Upper Bound on Bit
Error Probability for Viterbi Decoding. 4.5 Sequential Decoding. 4.6
Parallel-Concatenated Convolutional Codes and Soft Input Soft Output
Decoding. 4.7 SISO Decoding Algorithms. References. 4.A Modified Chernoff
Bound and Some Applications (Andrey Trofimov). References.
5. Equalization
(Sergei Semenov). 5.1 Equalization with Filtering. 5.2 Equalization Based
on Sequence Estimation. 5.3 RAKE Receiver. 5.4 Turbo Equalization. 5.5
Performance Comparison. References.
6. ARQ (Evgenii Krouk). 6.1 Basic ARQ
Schemes. 6.2 Hybrid ARQ. References.
7. Coded Modulation (Andrey
Trofimov). 7.1 Principle of Coded Modulation. 7.2 Modulation Mapping by
Signal Set Partitioning. 7.3 Ungerboeck Codes. 7.4 Performance Estimation
of TCM System. References.
8. MIMO (Andrei Ovchinnikov and Sergei Semenov).
8.1 MIMO Channel Model. 8.2 Space-Time Coding. 8.3 Orthogonal Designs.
8.4 Space-Time Trellis Codes. 8.5 Differential Space-Time Codes. 8.6
Spatial Multiplexing. 8.7 Beamforming. References.
9. Multiple Access
Methods (Dimitry Osipov, Jarkko Paavola, and Jussi Poikonen). 9.1 Frequency
Division Multiple Access. 9.2 Time Division Multiple Access. 9.3 Code
Division Multiple Access. 9.4 Advanced MA Methods. 9.5 Random Access
Multiple Access Methods. 9.6 Conclusions. References.
10. Standardization
in IEEE 802,11, 802.16 (Tuomas Laine, Zexian Li, Andrei Malkov, and Prabodh
Varshney). 10.1 IEEE Overview. 10.2 Standard Development Process. 10.3
IEEE 802.11 Working Group. 10.4 IEEE 802.16 Working Group. 10.5 IEEE
802.11. 10.6 IEEE 802.16x. References.
11. Standardization in 3GPP
(Asbjorn Grovlen, Kari Hooli, Matti Jokimies, Kari Pajukoski, Sergei Semenov,
and Esa Tiirola). 11.1 Standardization Process and Organization. 11.2 3G
WCDMA. 11.3 3.5G HSDPA/HSUPA. 11.4 4G LTE. References.
12. CDMA 2000 and
Its Evolution (Andrei Ovchinnikov). 12.1 Development of 3G CDM 2000
Standard. 12.2 Reverse Channel of Physical Layer in CDMA 2000 Standard.
12.3 Forward Channel of Physical Layer in CDMA 2000 Standard. 12.4
Architecture Model of CDMA 2000 1xEV-DO Standard. 12.5 Access Terminal of
the CDMA 2000 1xEV-DO Standard. 12.6 Access Network of the CDMA 2000 1xEV-DO
Standard. References. Index.
Professor E. Krouk has worked in the field of communication theory and techniques for more than 30 years. His areas of interests are coding theory, the mathematical theory of communications and cryptography. He is now the Dean of the Information Systems and Data Protection Faculty of the Saint-Petersburg State University of Aerospace Instrumentation. He is author of 3 books, more than 100 scientific articles and 30 international and Russian patents. Sergei Semenov received his Ph.D. degree from St.-Petersburg State University for Airspace Instrumentation (SUAI), Russia in 1993. Dr. Semenov joined Nokia Corporation in 1999 and is currently a Specialist in Modem Algorithm Design/Wireless Modem. His research interests include coding and communication theory and their application to communication systems.
