LEADER 05840nam  22007334a 450 
001 9910830743803321
005 20230617023719.0
010   $a1-280-26887-5
010   $a9786610268870
010   $a0-470-02480-1
010   $a0-470-01408-3
035   $a(CKB)1000000000018863
035   $a(EBL)191368
035   $a(OCoLC)181840096
035   $a(SSID)ssj0000206328
035   $a(PQKBManifestationID)11174708
035   $a(PQKBTitleCode)TC0000206328
035   $a(PQKBWorkID)10212887
035   $a(PQKB)11345338
035   $a(MiAaPQ)EBC191368
035   $a(EXLCZ)991000000000018863
100   $a20021024d2003      uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aMulti-antenna transceiver techniques for 3G and beyond$b[electronic resource] /$fAri Hottinen, Olav Tirkkonen, Risto Wichman
210   $aWest Sussex, England ;$aHoboken, NJ $cJ. Wiley$dc2003
215   $a1 online resource (344 p.)
300   $aDescription based upon print version of record.
311   $a0-470-84542-2 
320   $aIncludes bibliographical references (p. [305]-322) and index.
327   $aContents; Preface; Acronyms; Part I: Introduction; 1 Background; 1.1 Modular System Design; 1.2 Diversity Techniques in 3G Systems; 1.3 GSM/EDGE; 1.4 Multi-antenna Modems for 3G and Beyond; 1.5 Summary; 2 Diversity Gain, SNR Gain and Rate Increase; 2.1 Channel Models; 2.2 Performance Limits of Transmit Diversity; 2.3 Theoretical MIMO Channel Capacity; 2.4 MIMO Capacity in Correlated Channels; 2.5 Performance Measures for Closed-loop Transmit Diversity; 2.6 Summary; Part II: Open-loop Methods; 3 Open-loop Concepts: Background; 3.1 Delay Diversity; 3.2 Implicit Diversity via Phase Modulation
327   $a3.3 Code and Time Division Transmit Diversity3.4 Diversity Transform; 3.5 Space-Time Coding; 3.6 Space-Time Block Codes; 3.7 Non-linear Matrix Modulation; 3.8 Summary; 4 Matrix Modulation: Low SNR Aspects; 4.1 Linear Matrix Modulation; 4.2 Examples; 4.3 Heuristic Design Rules at Low SNR; 4.4 Matched Filtering and Maximum Likelihood Metric; 4.5 Mutual Information; 4.6 Expansion around Diagonal Dominance; 4.7 Performance of Examples; 4.8 Summary; 5 Increasing Symbol Rate: Quasi-orthogonal Layers; 5.1 Orthogonal Designs; 5.2 Complexity Issues: Choosing Symbol Rate and Target Tx Diversity
327   $a5.3 Multimodulation Schemes5.4 Matrix Modulation with Quasi-orthogonal Layers; 5.5 Summary; 6 Receiver Algorithms; 6.1 Channel Estimation Issues; 6.2 Maximum Likelihood Detection; 6.3 Quasi-orthogonality Assisted Maximum Likelihood Detection; 6.4 Linear Receivers; 6.5 Iterative Receivers; 6.6 Joint Decoding and Detection; 6.7 Example: Linear Detection for ABBA; 6.8 Performance; 6.9 Summary; 7 Matrix Modulation: High SNR Aspects; 7.1 Symmetries of Information and Performance; 7.2 Optimizing Performance with Orthogonal Symbol Rotations; 7.3 Explicit Performance Optima for ABBA
327   $a7.4 Improved Performance by Extending Block7.5 Comparison of Layered Schemes for Four Tx Antennas; 7.6 Weighted and Multimodulation Non-orthogonal Matrix Modulation; 7.7 Summary; 8 Robust and Practical Open-loop Designs; 8.1 Randomized Matrix Modulations; 8.2 Space-Time Block Code with Rotated Constellations; 8.3 Performance Evaluation; 8.4 Summary; 9 High-rate Designs for MIMO Systems; 9.1 Sets of Frobenius Orthogonal Unitary Matrices; 9.2 Optimizing Rate 2 MIMO-Modulation for N[sub(t)] = T = 2; 9.3 Four Transmit Antennas, Rate 2; 9.4 Four Transmit Antennas, Rate 3
327   $a9.5 Four Transmit Antennas, Rate 49.6 The Information Provided by the Schemes; 9.7 Summary; Part III: Closed-loop Methods; 10 Closed-loop Methods: Selected Multi-antenna Extensions; 10.1 Closed-loop Transmit Diversity in WCDMA; 10.2 More than Two Transmit Antennas; 10.3 Performance; 10.4 Summary; 11 Analysis of Closed-loop Concepts; 11.1 Generalized Feedback Signalling Design; 11.2 Analysis of SNR Gain of the Co-phase Algorithm; 11.3 Analysis of SNR Gain of the Order and Co-phase Algorithm; 11.4 SNR Gain in Multipath Rayleigh Fading Channels; 11.5 Errors in Feedback Signalling
327   $a11.6 Feedback Latency
330   $aMulti-antenna techniques are widely considered to be the most promising avenue for significantly increasing the bandwidth efficiency of wireless data transmission systems. In so called MIMO (multiple input multiple output) systems, multiple antennas are deployed both at the transmitter and the receiver. In MISO (multiple input single output) systems, the receiver has only one antenna, and the multiple transmit antennas are used for transmit diversity.The key aspects of multiple antenna transceiver techniques for evolving 3G systems and beyond are presented. MIMO and MISO (transmit dive
606   $aRadio$xTransmitter-receivers$xDesign and construction
606   $aRadio circuits
606   $aModulation (Electronics)
606   $aAntennas (Electronics)
606   $aSignal processing
606   $aWireless communication systems$xEquipment and supplies$xDesign and construction
615  0$aRadio$xTransmitter-receivers$xDesign and construction.
615  0$aRadio circuits.
615  0$aModulation (Electronics)
615  0$aAntennas (Electronics)
615  0$aSignal processing.
615  0$aWireless communication systems$xEquipment and supplies$xDesign and construction.
676   $a621.3845
676   $a621.3845/6
700   $aHottinen$b Ari$01658857
701   $aTirkkonen$b Olav$01658858
701   $aWichman$b Risto$01658859
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910830743803321
996   $aMulti-antenna transceiver techniques for 3G and beyond$94013144
997   $aUNINA