Description |
1 online resource (xxvii, 302 pages) : illustrations |
Contents |
Performance Limits of Multiple-Input Multiple-Output Wireless Communication Systems -- MIMO System Model -- MIMO System Capacity Derivation -- MIMO Channel Capacity Derivation for Adaptive Transmit Power Allocation -- MIMO Capacity Examples for Channels with Fixed Coefficients -- Capacity of MIMO Systems with Random Channel Coefficients -- Capacity of MIMO Fast and Block Rayleigh Fading Channels -- Capacity of MIMO Slow Rayleigh Fading Channels -- Capacity Examples for MIMO Slow Rayleigh Fading Channels -- Effect of System Parameters and Antenna Correlation on the Capacity of MIMO Channels -- Correlation Model for LOS MIMO Channels -- Correlation Model for a Rayleigh MIMO Fading Channel -- Correlation Model for a Rician MIMO Channel -- Keyhole Effect -- MIMO Correlation Fading Channel Model with Transmit and Receive Scatterers -- The Effect of System Parameters on the Keyhole Propagation -- Space-Time Coding Performance Analysis and Code Design -- Fading Channel Models -- Multipath Propagation -- Doppler Shift -- Statistical Models for Fading Channels -- Diversity -- Diversity Techniques -- Diversity Combining Methods -- Transmit Diversity -- Space-Time Coded Systems -- Performance Analysis of Space-Time Codes -- Error Probability on Slow Fading Channels -- Error Probability on Fast Fading Channels -- Space-Time Code Design Criteria -- Code Design Criteria for Slow Rayleigh Fading Channels -- Code Design Criteria for Fast Rayleigh Fading Channels -- Code Performance at Low to Medium SNR Ranges -- Exact Evaluation of Code Performance |
Summary |
The capacity of wireless data communications is lagging behind demands due to unsatisfactory performance of the existing wireless networks, such as low data rates, low spectral efficiency and low quality of service. Space-time coding is an effective transmit diversity technique to combat fading in wireless communications. Space-time codes are a highly bandwidth-efficient approach to signalling within wireless communication that takes advantage of the spatial dimension by transmitting a number of data streams using multiple co-located antennas. There are various approaches to the coding structures, including space-time trellis coded modulation, space-time turbo codes and also layered architectures. The central issue in all these various coding structures is the exploitation of multipath effects in order to achieve very high spectral efficiencies. The spectral efficiencies of traditional wireless systems range between 1-5bps/sec/Hz but by using space-time techniques spectral efficiencies of 20-40bps/sec/Hz have been possible. Hence, space-time coding enables an increase in capacity by an order of magnitude.; This is the main reason why space-time codes have been included in the standards for the third generation wireless communication systems and ultimately why Space-time Coding will be in great demand by individuals within industry and academia. The comprehensive understanding of space-time coding is essential in the implementation of 3G, and as the only title currently available, Space-Time Coding will be the standard text for Researchers, telecommunication engineers and network planners, academics and undergraduate/postgraduate students, telecommunications managers and consultants |
Analysis |
Communication Technology |
Bibliography |
Includes bibliographical references and index |
Notes |
Print version record |
Subject |
Coding theory.
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Iterative methods (Mathematics)
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Signal processing -- Mathematics.
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Wireless communication systems.
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Form |
Electronic book
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Author |
Yuan, Jinhong, 1969-
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ISBN |
047001413X (electronic bk.) |
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0470847573 (alk. paper) |
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0470864796 (electronic bk.) |
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1280554150 |
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9780470014134 (electronic bk.) |
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9780470847572 (alk. paper) |
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9780470864791 (electronic bk.) |
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9781280554155 |
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