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<b>Preface xi</b> <p><b>List of Abbreviations xiii</b></p> <p><b>List of Symbols xvii</b></p> <p><b>1 Introduction 1</b></p> <p>1.1 From SISO to MISO/ SIMO to MIMO 2</p> <p><i>1.1.1 Single Input Single Output SISO</i> 2</p> <p><i>1.1.2 Single Input Multiple Output, SIMO, and Multiple Input Single Output, MISO</i> 3</p> <p><i>1.1.3 Multiple Input Multiple Output, MIMO</i> 6</p> <p>1.2 What Do We Need MIMO For? 7</p> <p><i>1.2.1 The Single User Perspective</i> 8</p> <p><i>1.2.2 The Multiple User Perspective</i> 8</p> <p>1.3 How Does MIMO Work? Two Analogies 10</p> <p><i>1.3.1 The Single User Perspective</i> 10</p> <p><i>1.3.2 The Multiple User Perspective</i> 12</p> <p>1.4 Conditions for MIMO to Work 13</p> <p>1.5 How Long Has MIMO Been Around? 14</p> <p>1.6 Where is MIMO Being Used? 15</p> <p>1.7 Purpose of the Book 16</p> <p><b>2 Capacity of MIMO Channels 17</b></p> <p>2.1 Some Background on Digital Communication Systems 18</p> <p><i>2.1.1 Generation of Digital Signals</i> 18</p> <p><i>2.1.2 Conversion/Formatting for Transmission</i> 19</p> <p><i>2.1.3 Complex Baseband Representation</i> 19</p> <p><i>2.1.4 Decoder</i> 19</p> <p>2.2 Notion of Capacity 20</p> <p><i>2.2.1 Abstract Communication System</i> 20</p> <p><i>2.2.2 Definition of Capacity</i> 22</p> <p><i>2.2.3 Capacity Achieving Transceivers</i> 23</p> <p>2.3 Channel State Information and Fading 24</p> <p><i>2.3.1 Fast and Slow Fading</i> 24</p> <p><i>2.3.2 Channel State Information</i> 26</p> <p>2.4 Narrowband MIMO Model 27</p> <p>2.5 Capacity of the Time-Invariant Channel 28</p> <p><i>2.5.1 Capacity of the Time-Invariant SISO Channel</i> 29</p> <p><i>2.5.2 Time-Invariant SIMO Channel</i> 30</p> <p><i>2.5.3 Time-Invariant MISO Channel</i> 32</p> <p><i>2.5.4 Time-Invariant MIMO Channel: A Set of Parallel Independent AWGN Channels</i> 34</p> <p><i>2.5.5 Maximal Achievable Rate for Fixed Input Covariance Matrix</i> 43</p> <p>2.6 Fast Fading Channels with CSIT Distribution: Ergodic Capacity 46</p> <p><i>2.6.1 Ergodic Capacity: Basic Principles</i> 47</p> <p><i>2.6.2 Fast Fading SISO Channel with CSIT Distribution</i> 47</p> <p><i>2.6.3 Fast Fading SIMO Channel with CSIT Distribution</i> 48</p> <p><i>2.6.4 Fast Fading MISO Channel with CSIT Distribution</i> 49</p> <p><i>2.6.5 Fast Fading MIMO Channels with CSIT Distribution</i> 49</p> <p>2.7 Slow Fading Channel with CSIT Distribution: Outage Probability and Capacity with Outage 54</p> <p><i>2.7.1 Outage: Basic Principles</i> 55</p> <p><i>2.7.2 Diversity to Improve Communication Reliability</i> 57</p> <p><i>2.7.3 Slow Fading SISO Channels with CSIT Distribution</i> 58</p> <p><i>2.7.4 Slow Fading SIMO Channel with CSIT Distribution: Receive Diversity</i> 60</p> <p><i>2.7.5 Slow Fading MISO Channel with CSIT Distribution: Transmit Diversity</i> 60</p> <p><i>2.7.6 Slow Fading MIMO Channel with CSIT Distribution</i> 62</p> <p>2.8 Chapter Summary Tables 67</p> <p>2.9 Further Reading 73</p> <p><b>3 MIMO Transceivers 75</b></p> <p>3.1 MIMO Receivers 76</p> <p><i>3.1.1 General MIMO Architecture</i> 76</p> <p><i>3.1.2 Maximum Likelihood Receiver</i> 78</p> <p><i>3.1.3 Classes of Receivers Considered in the Chapter</i> 78</p> <p><i>3.1.4 Spatial Matched Filtering</i> 80</p> <p><i>3.1.5 Zero Forcing Receiver</i> 86</p> <p><i>3.1.6 MMSE Receiver</i> 92</p> <p><i>3.1.7 SIC Receiver and V-Blast</i> 97</p> <p><i>3.1.8 Performance</i> 103</p> <p>3.2 Transceivers with CSI at Transmitter and Receiver: Transmit and Receive Beamforming 108</p> <p><i>3.2.1 Principle of Beamforming</i> 108</p> <p><i>3.2.2 Multiple Transmit and Receive Beams</i> 109</p> <p><i>3.2.3 Transmit Beamforming (MISO System)</i> 111</p> <p><i>3.2.4 Receive Beamforming (SIMO)</i> 112</p> <p><i>3.2.5 Single Beam MIMO: Maximal Eigenmode Beamforming</i> 113</p> <p><i>3.2.6 Eigenmode Transmission</i> 114</p> <p><i>3.2.7 Performance of Beamforming Schemes</i> 118</p> <p>3.3 Space–Time Block Codes 122</p> <p><i>3.3.1 Orthogonal Design for a 2</i> × <i>1 MISO System: Alamouti STBC</i> 123</p> <p><i>3.3.2 STBC for More than Two Transmit Antennas</i> 128</p> <p>3.4 D-Blast 133</p> <p><i>3.4.1 Diagonal Encoding</i> 133</p> <p><i>3.4.2 Diagonal Decoding</i> 134</p> <p><i>3.4.3 D-Blast: Outage Optimal</i> 135</p> <p><i>3.4.4 Performance Gains</i> 135</p> <p><i>3.4.5 Error Propagation</i> 136</p> <p><i>3.4.6 Numerical Evaluations: Comparison of D-Blast with STBC</i> 136</p> <p>3.5 Chapter Summary Tables 138</p> <p>3.6 Further Reading 143</p> <p><b>4 MIMO Channel Models 145</b></p> <p>4.1 SISO Models and Channel Fundamentals 146</p> <p><i>4.1.1 Models for the Prediction of the Power</i> 146</p> <p><i>4.1.2 Models for the Prediction of the Temporal Variation of the Channel</i> 152</p> <p><i>4.1.3 Narrowband and Wideband Channels</i> 160</p> <p><i>4.1.4 Polarisation</i> 166</p> <p><i>4.1.5 Summary of Parameters Required for SISO Channel Modelling</i> 167</p> <p>4.2 Challenges in MIMO Channel Modelling 167</p> <p><i>4.2.1 Deterministic Models</i> 169</p> <p><i>4.2.2 Stochastic Models</i> 171</p> <p>4.3 Summary 190</p> <p><b>5 MIMO Antenna Design 193</b></p> <p>5.1 Antenna Element Fundamentals 194</p> <p><i>5.1.1 Isotropic Radiator</i> 194</p> <p><i>5.1.2 Directivity and Gain</i> 195</p> <p><i>5.1.3 Far Field and Rayleigh Distance</i> 196</p> <p><i>5.1.4 Three Dimensional Antenna Patterns</i> 197</p> <p><i>5.1.5 Impedance and Return Loss</i> 198</p> <p><i>5.1.6 Reciprocity</i> 199</p> <p><i>5.1.7 Antenna Polarisation</i> 199</p> <p><i>5.1.8 Mean Effective Gain</i> 202</p> <p>5.2 Single Antenna Design 205</p> <p>5.3 Designing Array Antennas for MIMO 207</p> <p><i>5.3.1 Spatial Correlation</i> 207</p> <p><i>5.3.2 Angular and Polarised Correlation</i> 209</p> <p><i>5.3.3 Impact of Nonuniform Angles of Arrival</i> 211</p> <p>5.4 Impact of Antenna Design on the MIMO Radio Channel 212</p> <p>5.5 Evaluating Antenna Impact on the MIMO Channel 217</p> <p><i>5.5.1 A Crude Evaluation of the Impact of Antennas on MIMO Channel Capacity</i> 217</p> <p><i>5.5.2 Advanced Techniques to Evaluate MIMO Antenna Performance</i> 219</p> <p>5.6 Challenges in Compact MIMO Antenna Design and Examples 221</p> <p>5.7 Summary 223</p> <p><i>5.7.1 Antenna Fundamentals</i> 223</p> <p><i>5.7.2 Designing Antenna Arrays</i> 223</p> <p><i>5.7.3 Practical Antennas for MIMO</i> 223</p> <p><b>6 MIMO in Current and Future Standards 225</b></p> <p>6.1 Wireless Channel Modelling in Standards 225</p> <p>6.2 Current Wireless Standards Employing MIMO and the Corresponding Channel Models 228</p> <p><i>6.2.1 IEEE 802.11n</i> 228</p> <p><i>6.2.2 IEEE 802.16–WiMAX</i> 231</p> <p><i>6.2.3 3GPP-LTE</i> 235</p> <p><i>6.2.4 Comparison of the IEEE 802.11n, WiMAX and 3GPP Models</i> 238</p> <p>6.3 MIMO in Other Areas 240</p> <p><i>6.3.1 MIMO for DVB-T2</i> 240</p> <p><i>6.3.2 MIMO in the HF Band</i> 241</p> <p><i>6.3.3 MIMO for Satellite Communications</i> 242</p> <p><i>6.3.4 Ultrawideband MIMO</i> 242</p> <p><i>6.3.5 MIMO for On-body Communications</i> 243</p> <p><i>6.3.6 MIMO for Vehicular Communications</i> 244</p> <p><i>6.3.7 MIMO in Small Cellular Environments</i> 244</p> <p>6.4 Concluding Remarks and Future Wireless Systems 245</p> <p><b>Appendix: Some Useful Definitions 247</b></p> <p><b>Bibliography 251</b></p> <p><b>Index 257</b></p>

<b>Dr Tim Brown, University of Surrey, Guildford, UK</b> is a lecturer in mobile communications at the University of Surrey, UK, where he is conducting research in MIMO as well as teaching courses and seminars that include introducing MIMO as well as other aspects of mobile communications. <p><b>Dr Persefoni Kyritsi, Aalborg University, Denmark</b> has worked in wireless communications for Lucent Technologies Bell Labs, in wireline communications for Deutsche Telekom, Frankfurt, and in circuit design for Intel Corporation and the Nokia Research Center, Helsinki- Finland. In 2001 she joined Aalborg University as an assistant research professor. From September 2003 until August 2005, she was a visiting researcher at the Department of Mathematics, Stanford University. Since September 2005, she holds the position of Assistant Professor at the Antennas, Propagation and Radio Networking Section at Aalborg University</p> <p><b>Dr Elisabeth De Carvalho, Aalborg University</b> was a post-doc at Stanford University, USA in 1999-2001. In 2001-2005, she worked in 2 start-ups in the USA and France. She also held short-term positions at Deutsche Telekom, and Lucent Technologies, Bell Labs, USA. She has worked on several aspects of wireless communications (GSM, CDMA, OFDM, wireless LANs, IEEE 802.16) and wireline communications (xDSL). In 2005, she joined Aalborg University as an Associate Professor. She has managed a project in collaboration with Samsung Electronics, Korea including 20 researchers and focusing mainly on MIMO and relay communications.</p>

<b>This book provides an excellent reference to the MIMO radio channel</b> <p>In this book, the authors introduce the concept of the Multiple Input Multiple Output (MIMO) radio channel, which is an intelligent communication method based upon using multiple antennas. Moreover, the authors provide a summary of the current channel modelling approaches used by industry, academia, and standardisation bodies. Furthermore, the book is structured to allow the reader to easily progress through the chapters in order to gain an understanding of the fundamental and mathematical principles behind MIMO. It also provides examples (i.e. Kroenecker model, Weicheselberger model, geometric and deterministic models, and ray tracing), system scenarios, trade-offs, and visual explanations. The authors explain and demonstrate the use and application of these models at system level.</p> <p><b>Key Features:</b></p> <ul> <li>Provides a summary of the current channel modelling approaches used by industry, academia and standardisation bodies</li> <li>Contains experimental and measurement based results</li> <li>Provides a comprehensive approach with concise and visual explanations of MIMO Radio Channel</li> <li>Covers a variety of system scenarios and explains the trade-offs involved in each</li> <li>Accompanying website containing MATLAB code and solutions to related problems<br /> <b>(<a href="http://www.tim.brown76.name/MIMObook">http://www.tim.brown76.name/MIMObook</a>)</b></li> </ul> <p><i>Practical Guide to the MIMO Radio Channel with MATLAB Examples</i> is an invaluable reference for R&D engineers and professionals in industry requiring familiarisation with the concept, and engineers entering the field or working in related fields seeking an introduction to the topic. Postgraduate and graduate students will also find this book of interest.</p>

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