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Baseband receiver design for wireless MIMO-OFDM communications / / Tzi-Dar Chiueh, Pei-Yun Tsai, I-Wei Lai
| Baseband receiver design for wireless MIMO-OFDM communications / / Tzi-Dar Chiueh, Pei-Yun Tsai, I-Wei Lai |
| Autore | Chiueh Tzi-Dar <1960-> |
| Edizione | [2nd ed.] |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : Wiley, , 2012 |
| Descrizione fisica | 1 online resource (374 p.) |
| Disciplina | 621.384/18 |
| Altri autori (Persone) |
TsaiPei-Yun
Lai. I-Wei ChiuehTzi-Dar <1960-> |
| Soggetto topico |
Radio - Transmitter-receivers
Wireless communication systems - Equipment and supplies Orthogonal frequency division multiplexing MIMO systems |
| ISBN |
1-280-69941-8
9786613676399 1-118-18819-5 1-118-18820-9 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Preface xiii -- About the Authors xvii -- Acknowledgements xix -- List of Abbreviations and Acronyms xxi -- PART ONE: FUNDAMENTALS OF WIRELESS COMMUNICATION -- 1. Introduction 3 -- 1.1 Digital Broadcasting Systems 3 -- 1.1.1 Digital Audio Broadcasting (DAB) 4 -- 1.1.2 Digital Video Broadcasting (DVB) 4 -- 1.2 Mobile Cellular Systems 6 -- 1.2.1 Carrier Aggregation 8 -- 1.2.2 Multiple-Antenna Configuration 8 -- 1.2.3 Relay Transmission 9 -- 1.2.4 Coordinated Multipoint Transmission and Reception (CoMP) 9 -- 1.3 Wireless Network Systems 10 -- 1.3.1 Personal Area Network (PAN) 10 -- 1.3.2 Local Area Network (LAN) 12 -- 1.3.3 Metropolitan Area Network (MAN) 13 -- 1.3.4 Wide Area Network (WAN) 14 -- Summary 14 -- References 15 -- 2. Digital Modulation 17 -- 2.1 Single-Carrier Modulation 17 -- 2.1.1 Power Spectral Densities of Modulation Signals 18 -- 2.1.2 PSK, QAM, and ASK 19 -- 2.1.3 CPFSK and MSK 22 -- 2.1.4 Pulse Shaping and Windowing 23 -- 2.2 Multi-Carrier Modulation 24 -- 2.2.1 Orthogonal Frequency-Division Multiplexing 27 -- 2.2.2 OFDM Related Issues 27 -- 2.2.3 OFDM Transceiver Architecture 31 -- 2.3 Adaptive OFDM 33 -- Summary 37 -- References 37 -- 3. AdvancedWireless Technology 39 -- 3.1 Multiple-Input Multiple-Output (MIMO) 39 -- 3.1.1 Introduction 39 -- 3.1.2 MIMO Basics 41 -- 3.1.3 MIMO Techniques 43 -- 3.1.4 MIMO-OFDM System Example 50 -- 3.2 Multiple Access 53 -- 3.2.1 Frequency-Division Multiple Access (FDMA) 54 -- 3.2.2 Time-Division Multiple Access (TDMA) 54 -- 3.2.3 Code-Division Multiple Access (CDMA) 55 -- 3.2.4 Carrier Sense Multiple Access (CSMA) 57 -- 3.2.5 Orthogonal Frequency-Division Multiple Access (OFDMA) 57 -- 3.2.6 Space-Division Multiple Access (SDMA) 58 -- 3.3 Spread Spectrum and CDMA 59 -- 3.3.1 PN Codes 60 -- 3.3.2 Direct-Sequence Spread Spectrum 63 -- 3.3.3 Frequency-Hopping Spread Spectrum 65 -- Summary 66 -- References 67 -- 4. Error-Correcting Codes 69 -- 4.1 Introduction 69 -- 4.2 Block Codes 70 -- 4.2.1 Linear Codes 70 -- 4.2.2 Cyclic Codes 72.
4.3 Reed-Solomon Codes 73 -- 4.3.1 Finite Fields 74 -- 4.3.2 Encoding 75 -- 4.3.3 Decoding 76 -- 4.3.4 Shortened Reed-Solomon Codes 76 -- 4.4 Convolutional Codes 77 -- 4.4.1 Encoding 77 -- 4.4.2 Viterbi Decoder 79 -- 4.4.3 Punctured Convolutional Codes 80 -- 4.5 Soft-Input Soft-Output Decoding Algorithms 81 -- 4.5.1 MAP Decoder 82 -- 4.5.2 Log-MAP Decoder 85 -- 4.5.3 Max-Log-MAP Decoder 86 -- 4.6 Turbo Codes 87 -- 4.6.1 Encoding 87 -- 4.6.2 Decoding 88 -- 4.7 Low-Density Parity-Check Codes 89 -- 4.7.1 Encoding 89 -- 4.7.2 Decoding 91 -- Summary 93 -- References 94 -- 5. Signal Propagation and Channel Model 95 -- 5.1 Introduction 95 -- 5.2 Wireless Channel Propagation 96 -- 5.2.1 Path Loss and Shadowing 96 -- 5.2.2 Multipath Fading 97 -- 5.2.3 Multipath Channel Parameters 98 -- 5.2.4 MIMO Channel 104 -- 5.3 Front-End Electronics Effects 105 -- 5.3.1 Carrier Frequency Offset 105 -- 5.3.2 Sampling Clock Offset 106 -- 5.3.3 Phase Noise 106 -- 5.3.4 IQ Imbalance and DC Offset 107 -- 5.3.5 Power Amplifier Nonlinearity 110 -- 5.4 Channel Model 111 -- 5.4.1 Model for Front-End Impairments 112 -- 5.4.2 Multipath Rayleigh Fader Model 113 -- 5.4.3 Channel Models Used in Standards 116 -- Summary 122 -- References 123 -- PART TWO: MIMO-OFDM RECEIVER PROCESSING -- 6. Synchronization 127 -- 6.1 Introduction 127 -- 6.2 Synchronization Issues 128 -- 6.2.1 Synchronization Errors 128 -- 6.2.2 Effects of Synchronization Errors 128 -- 6.2.3 Consideration for Estimation and Compensation 133 -- 6.3 Detection and Estimation of Synchronization Errors 134 -- 6.3.1 Symbol Timing Detection 134 -- 6.3.2 Carrier Frequency Offset Estimation 143 -- 6.3.3 Residual CFO and SCO Estimation 147 -- 6.3.4 Carrier Phase Estimation 149 -- 6.3.5 IQ Imbalance Estimation 150 -- 6.4 Detection and Estimation of Synchronization Errors in MIMO-OFDM Systems 153 -- 6.4.1 Symbol Timing Detection in MIMO-OFDM Systems 153 -- 6.4.2 Carrier Frequency Offset Estimation in MIMO-OFDM Systems 155 -- 6.4.3 Residual CFO and SCO Estimation in MIMO-OFDM Systems 156. 6.4.4 Carrier Phase Estimation in MIMO-OFDM Systems 157 -- 6.4.5 IQ Imbalance Estimation in MIMO-OFDM Systems 157 -- 6.5 Recovery of Synchronization Errors 158 -- 6.5.1 Carrier Frequency Offset Compensation 158 -- 6.5.2 Sampling Clock Offset and Common Phase Error Compensation 160 -- 6.5.3 IQ Imbalance Compensation 163 -- Summary 163 -- References 164 -- 7. Channel Estimation and Equalization 167 -- 7.1 Introduction 167 -- 7.2 Pilot Pattern 168 -- 7.2.1 Pilot Pattern in SISO-OFDM Systems 168 -- 7.2.2 Pilot Pattern in MIMO-OFDM Systems 171 -- 7.3 SISO-OFDM Channel Estimation 174 -- 7.3.1 Channel Estimation by Block-Type Pilot Symbols 177 -- 7.3.2 Channel Estimation by Comb-Type Pilot Symbols 179 -- 7.3.3 Channel Estimation by Grid-Type Pilot Symbols 186 -- 7.4 MIMO-OFDM Channel Estimation 191 -- 7.4.1 Space-Time Pilot 191 -- 7.5 Adaptive Channel Estimation 194 -- 7.6 Equalization 195 -- 7.6.1 One-Tap Equalizer 195 -- 7.6.2 Multi-Tap Equalizer 198 -- 7.7 Iterative Receiver 204 -- 7.7.1 Iterative Synchronization and Channel Estimation 205 -- 7.7.2 Bit-Interleaved Coded Modulation with Iterative -- Decoding (BICM-ID) 205 -- Summary 206 -- References 207 -- 8. MIMO Detection 209 -- 8.1 Introduction 209 -- 8.2 Linear Detection 210 -- 8.2.1 Zero Forcing (ZF) 210 -- 8.2.2 Minimum Mean Squared Error (MMSE) 211 -- 8.3 MIMO Detection with Channel Preprocessing 212 -- 8.3.1 Sorting 212 -- 8.3.2 QR Decomposition 213 -- 8.3.3 MMSE-SQRD 215 -- 8.3.4 Ordered Successive Interference Cancelation (OSIC) 216 -- 8.3.5 Lattice Reduction (LR) 218 -- 8.4 Sphere Decoder 220 -- 8.4.1 Depth-First Tree Search 221 -- 8.4.2 Breadth-First Tree Search 223 -- 8.4.3 Best-First Tree Search 224 -- 8.4.4 Complexity Measurement 227 -- 8.4.5 Design Space Exploration of Sphere Decoder 227 -- 8.5 Soft-Output Sphere Decoder 230 -- 8.5.1 Repeated Tree Search 231 -- 8.5.2 Single Tree Search 232 -- 8.5.3 LLR Clipping 232 -- 8.6 Iterative MIMO Detection 234 -- 8.6.1 List Sphere Decoder 234 -- 8.6.2 Soft-Input Soft-Output Sphere Decoder 235. 8.6.3 Iterative SIC-MMSE Detection 237 -- 8.7 Precoding 239 -- 8.7.1 Beam Steering 239 -- 8.7.2 Spatial Decorrelation 241 -- 8.7.3 Limited Feedback 244 -- 8.8 Space Block Code 246 -- Summary 247 -- References 248 -- PART THREE: HARDWARE DESIGN FOR MIMO-OFDM RECEIVERS -- 9. Circuit Techniques 253 -- 9.1 Introduction 253 -- 9.2 Fast Fourier Transform Modules 253 -- 9.2.1 FFT Algorithms 254 -- 9.2.2 Architecture 259 -- 9.2.3 Comparison 264 -- 9.3 Delay Buffer 267 -- 9.3.1 SRAM/Register File-Based Delay Buffer 267 -- 9.3.2 Pointer-Based Delay Buffer 268 -- 9.3.3 Gated Clock Strategy 269 -- 9.3.4 Comparison 272 -- 9.4 Circuits for Rectangular-to-Polar Conversion 274 -- 9.4.1 Arctangent Function 274 -- 9.4.2 Magnitude Function 279 -- 9.4.3 Comparison 286 -- 9.5 Circuits for Polar-to-Rectangular Conversion 286 -- 9.5.1 Trigonometric Approximation 287 -- 9.5.2 Polynomial Approximation 288 -- 9.5.3 Comparison 290 -- Summary 290 -- References 291 -- 10. MIMO IC Design Examples 293 -- 10.1 Introduction 293 -- 10.2 QR Decomposition IC 294 -- 10.2.1 System Description 294 -- 10.2.2 Algorithm Design 295 -- 10.2.3 Architecture Design 300 -- 10.2.4 Experimental Results 303 -- 10.3 8 x 8 Soft-Output Sphere Decoder 306 -- 10.3.1 Block Description 306 -- 10.3.2 Algorithm Design 306 -- 10.3.3 Architecture Design 307 -- 10.3.4 Experimental Results 316 -- Summary 318 -- References 319 -- 11. Mobile MIMO WiMAX System-on-Chip Design 321 -- 11.1 Introduction of WiMAX Standard 321 -- 11.2 Mobile WiMAX OFDMA and Frame Structure 322 -- 11.3 WiMAX Baseband Receiver Design 325 -- 11.3.1 Automatic Gain Control (AGC) 325 -- 11.3.2 Packet Detection (PKD) 326 -- 11.3.3 Symbol Timing Recovery (STR) 328 -- 11.3.4 Carrier Frequency Offset (CFO) Compensation 328 -- 11.3.5 Channel Estimation 330 -- 11.3.6 MIMO Detection 330 -- 11.3.7 Outer Receiver 333 -- 11.4 WiMAX Media Access Control (MAC) Design 333 -- 11.5 Implementation and Field Trial of the WiMAX SoC 336 -- 11.5.1 Laboratory Testing and Performance Evaluation 338. 11.5.2 Taiwan High Speed Rail Field Trial 340 -- Summary 341 -- References 341 -- Index 343. |
| Record Nr. | UNINA-9910141419303321 |
Chiueh Tzi-Dar <1960->
|
||
| Hoboken, New Jersey : , : Wiley, , 2012 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Baseband receiver design for wireless MIMO-OFDM communications / / Tzi-Dar Chiueh, Pei-Yun Tsai, I-Wei Lai
| Baseband receiver design for wireless MIMO-OFDM communications / / Tzi-Dar Chiueh, Pei-Yun Tsai, I-Wei Lai |
| Autore | Chiueh Tzi-Dar <1960-> |
| Edizione | [2nd ed.] |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : Wiley, , 2012 |
| Descrizione fisica | 1 online resource (374 p.) |
| Disciplina | 621.384/18 |
| Altri autori (Persone) |
TsaiPei-Yun
Lai. I-Wei ChiuehTzi-Dar <1960-> |
| Soggetto topico |
Radio - Transmitter-receivers
Wireless communication systems - Equipment and supplies Orthogonal frequency division multiplexing MIMO systems |
| ISBN |
1-280-69941-8
9786613676399 1-118-18819-5 1-118-18820-9 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Preface xiii -- About the Authors xvii -- Acknowledgements xix -- List of Abbreviations and Acronyms xxi -- PART ONE: FUNDAMENTALS OF WIRELESS COMMUNICATION -- 1. Introduction 3 -- 1.1 Digital Broadcasting Systems 3 -- 1.1.1 Digital Audio Broadcasting (DAB) 4 -- 1.1.2 Digital Video Broadcasting (DVB) 4 -- 1.2 Mobile Cellular Systems 6 -- 1.2.1 Carrier Aggregation 8 -- 1.2.2 Multiple-Antenna Configuration 8 -- 1.2.3 Relay Transmission 9 -- 1.2.4 Coordinated Multipoint Transmission and Reception (CoMP) 9 -- 1.3 Wireless Network Systems 10 -- 1.3.1 Personal Area Network (PAN) 10 -- 1.3.2 Local Area Network (LAN) 12 -- 1.3.3 Metropolitan Area Network (MAN) 13 -- 1.3.4 Wide Area Network (WAN) 14 -- Summary 14 -- References 15 -- 2. Digital Modulation 17 -- 2.1 Single-Carrier Modulation 17 -- 2.1.1 Power Spectral Densities of Modulation Signals 18 -- 2.1.2 PSK, QAM, and ASK 19 -- 2.1.3 CPFSK and MSK 22 -- 2.1.4 Pulse Shaping and Windowing 23 -- 2.2 Multi-Carrier Modulation 24 -- 2.2.1 Orthogonal Frequency-Division Multiplexing 27 -- 2.2.2 OFDM Related Issues 27 -- 2.2.3 OFDM Transceiver Architecture 31 -- 2.3 Adaptive OFDM 33 -- Summary 37 -- References 37 -- 3. AdvancedWireless Technology 39 -- 3.1 Multiple-Input Multiple-Output (MIMO) 39 -- 3.1.1 Introduction 39 -- 3.1.2 MIMO Basics 41 -- 3.1.3 MIMO Techniques 43 -- 3.1.4 MIMO-OFDM System Example 50 -- 3.2 Multiple Access 53 -- 3.2.1 Frequency-Division Multiple Access (FDMA) 54 -- 3.2.2 Time-Division Multiple Access (TDMA) 54 -- 3.2.3 Code-Division Multiple Access (CDMA) 55 -- 3.2.4 Carrier Sense Multiple Access (CSMA) 57 -- 3.2.5 Orthogonal Frequency-Division Multiple Access (OFDMA) 57 -- 3.2.6 Space-Division Multiple Access (SDMA) 58 -- 3.3 Spread Spectrum and CDMA 59 -- 3.3.1 PN Codes 60 -- 3.3.2 Direct-Sequence Spread Spectrum 63 -- 3.3.3 Frequency-Hopping Spread Spectrum 65 -- Summary 66 -- References 67 -- 4. Error-Correcting Codes 69 -- 4.1 Introduction 69 -- 4.2 Block Codes 70 -- 4.2.1 Linear Codes 70 -- 4.2.2 Cyclic Codes 72.
4.3 Reed-Solomon Codes 73 -- 4.3.1 Finite Fields 74 -- 4.3.2 Encoding 75 -- 4.3.3 Decoding 76 -- 4.3.4 Shortened Reed-Solomon Codes 76 -- 4.4 Convolutional Codes 77 -- 4.4.1 Encoding 77 -- 4.4.2 Viterbi Decoder 79 -- 4.4.3 Punctured Convolutional Codes 80 -- 4.5 Soft-Input Soft-Output Decoding Algorithms 81 -- 4.5.1 MAP Decoder 82 -- 4.5.2 Log-MAP Decoder 85 -- 4.5.3 Max-Log-MAP Decoder 86 -- 4.6 Turbo Codes 87 -- 4.6.1 Encoding 87 -- 4.6.2 Decoding 88 -- 4.7 Low-Density Parity-Check Codes 89 -- 4.7.1 Encoding 89 -- 4.7.2 Decoding 91 -- Summary 93 -- References 94 -- 5. Signal Propagation and Channel Model 95 -- 5.1 Introduction 95 -- 5.2 Wireless Channel Propagation 96 -- 5.2.1 Path Loss and Shadowing 96 -- 5.2.2 Multipath Fading 97 -- 5.2.3 Multipath Channel Parameters 98 -- 5.2.4 MIMO Channel 104 -- 5.3 Front-End Electronics Effects 105 -- 5.3.1 Carrier Frequency Offset 105 -- 5.3.2 Sampling Clock Offset 106 -- 5.3.3 Phase Noise 106 -- 5.3.4 IQ Imbalance and DC Offset 107 -- 5.3.5 Power Amplifier Nonlinearity 110 -- 5.4 Channel Model 111 -- 5.4.1 Model for Front-End Impairments 112 -- 5.4.2 Multipath Rayleigh Fader Model 113 -- 5.4.3 Channel Models Used in Standards 116 -- Summary 122 -- References 123 -- PART TWO: MIMO-OFDM RECEIVER PROCESSING -- 6. Synchronization 127 -- 6.1 Introduction 127 -- 6.2 Synchronization Issues 128 -- 6.2.1 Synchronization Errors 128 -- 6.2.2 Effects of Synchronization Errors 128 -- 6.2.3 Consideration for Estimation and Compensation 133 -- 6.3 Detection and Estimation of Synchronization Errors 134 -- 6.3.1 Symbol Timing Detection 134 -- 6.3.2 Carrier Frequency Offset Estimation 143 -- 6.3.3 Residual CFO and SCO Estimation 147 -- 6.3.4 Carrier Phase Estimation 149 -- 6.3.5 IQ Imbalance Estimation 150 -- 6.4 Detection and Estimation of Synchronization Errors in MIMO-OFDM Systems 153 -- 6.4.1 Symbol Timing Detection in MIMO-OFDM Systems 153 -- 6.4.2 Carrier Frequency Offset Estimation in MIMO-OFDM Systems 155 -- 6.4.3 Residual CFO and SCO Estimation in MIMO-OFDM Systems 156. 6.4.4 Carrier Phase Estimation in MIMO-OFDM Systems 157 -- 6.4.5 IQ Imbalance Estimation in MIMO-OFDM Systems 157 -- 6.5 Recovery of Synchronization Errors 158 -- 6.5.1 Carrier Frequency Offset Compensation 158 -- 6.5.2 Sampling Clock Offset and Common Phase Error Compensation 160 -- 6.5.3 IQ Imbalance Compensation 163 -- Summary 163 -- References 164 -- 7. Channel Estimation and Equalization 167 -- 7.1 Introduction 167 -- 7.2 Pilot Pattern 168 -- 7.2.1 Pilot Pattern in SISO-OFDM Systems 168 -- 7.2.2 Pilot Pattern in MIMO-OFDM Systems 171 -- 7.3 SISO-OFDM Channel Estimation 174 -- 7.3.1 Channel Estimation by Block-Type Pilot Symbols 177 -- 7.3.2 Channel Estimation by Comb-Type Pilot Symbols 179 -- 7.3.3 Channel Estimation by Grid-Type Pilot Symbols 186 -- 7.4 MIMO-OFDM Channel Estimation 191 -- 7.4.1 Space-Time Pilot 191 -- 7.5 Adaptive Channel Estimation 194 -- 7.6 Equalization 195 -- 7.6.1 One-Tap Equalizer 195 -- 7.6.2 Multi-Tap Equalizer 198 -- 7.7 Iterative Receiver 204 -- 7.7.1 Iterative Synchronization and Channel Estimation 205 -- 7.7.2 Bit-Interleaved Coded Modulation with Iterative -- Decoding (BICM-ID) 205 -- Summary 206 -- References 207 -- 8. MIMO Detection 209 -- 8.1 Introduction 209 -- 8.2 Linear Detection 210 -- 8.2.1 Zero Forcing (ZF) 210 -- 8.2.2 Minimum Mean Squared Error (MMSE) 211 -- 8.3 MIMO Detection with Channel Preprocessing 212 -- 8.3.1 Sorting 212 -- 8.3.2 QR Decomposition 213 -- 8.3.3 MMSE-SQRD 215 -- 8.3.4 Ordered Successive Interference Cancelation (OSIC) 216 -- 8.3.5 Lattice Reduction (LR) 218 -- 8.4 Sphere Decoder 220 -- 8.4.1 Depth-First Tree Search 221 -- 8.4.2 Breadth-First Tree Search 223 -- 8.4.3 Best-First Tree Search 224 -- 8.4.4 Complexity Measurement 227 -- 8.4.5 Design Space Exploration of Sphere Decoder 227 -- 8.5 Soft-Output Sphere Decoder 230 -- 8.5.1 Repeated Tree Search 231 -- 8.5.2 Single Tree Search 232 -- 8.5.3 LLR Clipping 232 -- 8.6 Iterative MIMO Detection 234 -- 8.6.1 List Sphere Decoder 234 -- 8.6.2 Soft-Input Soft-Output Sphere Decoder 235. 8.6.3 Iterative SIC-MMSE Detection 237 -- 8.7 Precoding 239 -- 8.7.1 Beam Steering 239 -- 8.7.2 Spatial Decorrelation 241 -- 8.7.3 Limited Feedback 244 -- 8.8 Space Block Code 246 -- Summary 247 -- References 248 -- PART THREE: HARDWARE DESIGN FOR MIMO-OFDM RECEIVERS -- 9. Circuit Techniques 253 -- 9.1 Introduction 253 -- 9.2 Fast Fourier Transform Modules 253 -- 9.2.1 FFT Algorithms 254 -- 9.2.2 Architecture 259 -- 9.2.3 Comparison 264 -- 9.3 Delay Buffer 267 -- 9.3.1 SRAM/Register File-Based Delay Buffer 267 -- 9.3.2 Pointer-Based Delay Buffer 268 -- 9.3.3 Gated Clock Strategy 269 -- 9.3.4 Comparison 272 -- 9.4 Circuits for Rectangular-to-Polar Conversion 274 -- 9.4.1 Arctangent Function 274 -- 9.4.2 Magnitude Function 279 -- 9.4.3 Comparison 286 -- 9.5 Circuits for Polar-to-Rectangular Conversion 286 -- 9.5.1 Trigonometric Approximation 287 -- 9.5.2 Polynomial Approximation 288 -- 9.5.3 Comparison 290 -- Summary 290 -- References 291 -- 10. MIMO IC Design Examples 293 -- 10.1 Introduction 293 -- 10.2 QR Decomposition IC 294 -- 10.2.1 System Description 294 -- 10.2.2 Algorithm Design 295 -- 10.2.3 Architecture Design 300 -- 10.2.4 Experimental Results 303 -- 10.3 8 x 8 Soft-Output Sphere Decoder 306 -- 10.3.1 Block Description 306 -- 10.3.2 Algorithm Design 306 -- 10.3.3 Architecture Design 307 -- 10.3.4 Experimental Results 316 -- Summary 318 -- References 319 -- 11. Mobile MIMO WiMAX System-on-Chip Design 321 -- 11.1 Introduction of WiMAX Standard 321 -- 11.2 Mobile WiMAX OFDMA and Frame Structure 322 -- 11.3 WiMAX Baseband Receiver Design 325 -- 11.3.1 Automatic Gain Control (AGC) 325 -- 11.3.2 Packet Detection (PKD) 326 -- 11.3.3 Symbol Timing Recovery (STR) 328 -- 11.3.4 Carrier Frequency Offset (CFO) Compensation 328 -- 11.3.5 Channel Estimation 330 -- 11.3.6 MIMO Detection 330 -- 11.3.7 Outer Receiver 333 -- 11.4 WiMAX Media Access Control (MAC) Design 333 -- 11.5 Implementation and Field Trial of the WiMAX SoC 336 -- 11.5.1 Laboratory Testing and Performance Evaluation 338. 11.5.2 Taiwan High Speed Rail Field Trial 340 -- Summary 341 -- References 341 -- Index 343. |
| Record Nr. | UNINA-9910820478003321 |
|
Chiueh Tzi-Dar <1960->
|
||
| Hoboken, New Jersey : , : Wiley, , 2012 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Coding for MIMO communication systems / / Tolga M. Duman, Ali Ghrayeb
| Coding for MIMO communication systems / / Tolga M. Duman, Ali Ghrayeb |
| Autore | Duman Tolga M. |
| Pubbl/distr/stampa | Chichester, England ; , : J. Wiley & Sons, , c2007 |
| Descrizione fisica | 1 online resource (368 p.) |
| Disciplina | 621.3840285/572 |
| Altri autori (Persone) | GhrayebAli |
| Soggetto topico |
Space time codes
MIMO systems Wireless communication systems |
| ISBN |
1-282-12310-6
9786612123108 0-470-72434-X 0-470-72433-1 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
About the Authors. -- Preface -- List of Figures -- List of Tables -- Notation -- Abbreviations -- 1 Overview -- 1.1 Need for MIMO Systems -- 1.2 MIMO Communications in Wireless Standards -- 1.3 Organization of the Book -- 1.4 Other Topics in MIMO Systems -- 2 Fading Channels and Diversity Techniques -- 2.1 Wireless Channels -- 2.1.1 Path Loss, Shadowing and Small Scale Fading -- 2.1.2 Fading Channel Models -- 2.2 Error/Outage Probabilities over Fading Channels -- 2.2.1 Outage Probability for Rayleigh Fading Channels -- 2.2.2 Average Error Probabilities over Rayleigh Fading Channels -- 2.2.3 Extensions to Other Fading Channels -- 2.2.4 Performance over Frequency Selective Fading Channels -- 2.3 Diversity Techniques -- 2.3.1 Types of Diversity -- 2.3.2 System Model for Lth Order Diversity -- 2.3.3 Maximal Ratio Combining (MRC) -- 2.3.4 Suboptimal Combining Algorithms -- 2.3.5 Selection Combining -- 2.3.6 Examples -- 2.4 Channel Coding as a Means of Time Diversity -- 2.4.1 Block Coding over a Fully Interleaved Channel -- 2.4.2 Convolutional Coding -- 2.5 Multiple Antennas in Wireless Communications -- 2.5.1 Receive Diversity -- 2.5.2 Smart Antennas and Beamforming -- 2.6 Chapter Summary and Further Reading -- 3 Capacity and Information Rates of MIMO Channels -- 3.1 Capacity and Information Rates of Noisy Channels -- 3.2 Capacity and Information Rates of AWGN and Fading Channels -- 3.2.1 AWGN Channels -- 3.2.2 Fading Channels -- 3.3 Capacity of MIMO Channels -- 3.3.1 Deterministic MIMO Channels -- 3.3.2 Ergodic MIMO Channels -- 3.3.3 Non-Ergodic MIMO Channels and Outage Capacity -- 3.3.4 Transmit CSI for MIMO Fading Channels -- 3.4 Constrained Signaling for MIMO Communications -- 3.5 Discussion: Why Use MIMO Systems? -- 3.6 Chapter Summary and Further Reading. -- 4 Space-Time Block Codes -- 4.1 Transmit Diversity with Two Antennas: The Alamouti Scheme -- 4.1.1 Transmission Scheme -- 4.1.2 Optimal Receiver for the Alamouti Scheme -- 4.1.3 Performance Analysis of the Alamouti Scheme.
4.1.4 Examples -- 4.2 Orthogonal Space-Time Block Codes -- 4.2.1 Linear Orthogonal Designs -- 4.2.2 Decoding of General Space-Time Block Codes -- 4.2.3 Performance Analysis of Space-Time Block Codes. -- 4.2.4 Examples -- 4.3 Quasi-Orthogonal Space-Time Block Codes -- 4.4 Linear Dispersion Codes -- 4.5 Chapter Summary and Further Reading. -- 5 Space-Time Trellis Codes -- 5.1 A Simple Space-Time Trellis Code -- 5.2 General Space-Time Trellis Codes -- 5.2.1 Notation and Preliminaries -- 5.2.2 Decoding of Space-Time Trellis Codes -- 5.3 Basic Space-Time Code Design Principles -- 5.3.1 Pairwise Error Probability -- 5.3.2 Space-Time Code Design Principles -- 5.3.3 Examples of Good Space-Time Codes -- 5.3.4 Space-Time Trellis Codes for Fast Fading Channels -- 5.4 Representation for Space-Time Trellis Codes for PSK Constellations -- 5.4.1 Generator Matrix Representation -- 5.4.2 Improved Space-Time Code Design -- 5.5 Performance Analysis for Space-Time Trellis Codes -- 5.5.1 Union Bound for Space-Time Trellis Codes -- 5.5.2 Useful Performance Bounds for Space-Time Trellis Codes -- 5.5.3 Examples -- 5.6 Comparison of Space-Time Block and Trellis Codes -- 5.7 Chapter Summary and Further Reading -- 6 Layered Space-Time Codes. -- 6.1 Basic Bell Labs Layered Space-Time (BLAST) Architectures -- 6.1.1 VBLAST/HBLAST/SCBLAST -- 6.1.2 Detection Algorithms for Basic BLAST Architectures -- 6.1.3 Examples -- 6.2 Diagonal BLAST (DBLAST) -- 6.2.1 Detection Algorithms for DBLAST -- 6.2.2 Examples -- 6.3 Multilayered Space-Time Coding -- 6.3.1 Encoder Structure -- 6.3.2 Group Interference Cancellation Detection -- 6.3.3 Example -- 6.4 Threaded Space-Time Codes -- 6.4.1 Layering Approach -- 6.4.2 Threaded Space-Time Code Design -- 6.4.3 Example -- 6.4.4 Detection of Threaded Space-Time Codes -- 6.5 Other Detection Algorithms for Spatial Multiplexing Systems -- 6.5.1 Greedy Detection -- 6.5.2 Belief Propagation Detection -- 6.5.3 Turbo-BLAST Detection -- 6.5.4 Reduced Complexity ZF/MMSE Detection. 6.5.5 Sphere Decoding -- 6.6 Diversity/Multiplexing Gain Trade-off -- 6.7 Chapter Summary and Further Reading -- 7 Concatenated Codes and Iterative Decoding -- 7.1 Development of Concatenated Codes -- 7.2 Concatenated Codes for AWGN Channels -- 7.2.1 Encoder Structures -- 7.2.2 Iterative Decoder Structures -- 7.2.3 The SOVA Decoder -- 7.2.4 Performance with Maximum Likelihood Decoding -- 7.2.5 Examples -- 7.3 Concatenated Codes for MIMO Channels -- 7.3.1 Concatenated Space-Time Turbo Coding Scheme -- 7.3.2 Turbo Space-Time Trellis Coding Scheme -- 7.3.3 Turbo Space-Time Coding Scheme -- 7.4 Turbo Coded Modulation for MIMO Channels -- 7.4.1 Encoder Structure -- 7.4.2 Decoder Structure -- 7.4.3 Examples -- 7.5 Concatenated Space-Time Block Coding -- 7.5.1 Encoder Structure -- 7.5.2 Decoder Structure -- 7.5.3 Performance Analysis -- 7.5.4 Examples -- 7.6 Chapter Summary and Further Reading. -- 8 Unitary and Differential Space-Time Codes -- 8.1 Capacity of Noncoherent MIMO Channels -- 8.1.1 Channel Capacity -- 8.1.2 Capacity Achieving Signals -- 8.2 Unitary Space-Time Codes -- 8.2.1 USTC Encoder -- 8.2.2 ML Detection of USTCs -- 8.2.3 Performance Analysis -- 8.2.4 Construction of Unitary Space-Time Signals -- 8.2.5 Examples -- 8.3 Differential Space-Time Codes -- 8.3.1 Differential Space-Time Coding for Single Antenna Systems -- 8.3.2 Differential Space-Time Coding for MIMO Systems -- 8.4 Turbo Coded Unitary Space-Time Codes -- 8.4.1 Encoder Structure -- 8.4.2 Noncoherent Iterative Decoder -- 8.4.3 Example. -- 8.5 Trellis Coded Unitary Space-Time Codes -- 8.6 Turbo Coded Differential Space-Time Codes -- 8.6.1 Encoder Structure -- 8.6.2 Iterative Detectors -- 8.7 Chapter Summary and Further Reading -- 9 Space-Time Coding for Frequency Selective Fading Channels -- 9.1 MIMO Frequency Selective Channels -- 9.2 Capacity and Information Rates of MIMO Frequency Selective Fading Channels -- 9.2.1 Information Rates with Gaussian Inputs -- 9.2.2 Achievable Information Rates with Practical Constellations. 9.2.3 Examples -- 9.3 Space-Time Coding for MIMO FS Channels -- 9.3.1 Interpretation of MIMO FS Channels Using Virtual Antennas -- 9.3.2 A Simple Full Diversity Code for MIMO FS Channels -- 9.3.3 Space-Time Trellis Codes for MIMO FS Channels -- 9.3.4 Concatenated Coding for MIMO FS Channels -- 9.3.5 Spatial Multiplexing for MIMO FS Channels -- 9.4 Channel Detection for MIMO FS Channels -- 9.4.1 Linear Equalization for MIMO FS Channels -- 9.4.2 Decision Feedback Equalization for MIMO FS Channels -- 9.4.3 Soft Input Soft Output Channel Detection -- 9.4.4 Other Reduced Complexity Approaches -- 9.5 MIMO OFDM Systems -- 9.5.1 MIMO-OFDM Channel Model -- 9.5.2 Space-Frequency Coding -- 9.5.3 Challenges in MIMO-OFDM -- 9.6 Chapter Summary and Further Reading -- 10 Practical Issues in MIMO Communications -- 10.1 Channel State Information Estimation -- 10.1.1 CSI Estimation Using Pilot Tones -- 10.1.2 What to Do with CSI? -- 10.1.3 Space-Time Coding Examples with Estimated CSI -- 10.2 Spatial Channel Correlation for MIMO Systems -- 10.2.1 Measurements and Modeling of Spatial Correlation -- 10.2.2 Spatial Channel Correlation Models -- 10.2.3 Channel Capacity with Spatial Correlation -- 10.2.4 Space-Time Code Performance with Spatial Correlation -- 10.3 Temporal Channel Correlation -- 10.4 MIMO Communication System Design Issues -- 10.5 Chapter Summary and Further Reading -- 11 Antenna Selection for MIMO Systems -- 11.1 Capacity-based Antenna Selection -- 11.1.1 System Model -- 11.1.2 Optimal Selection -- 11.1.3 Simplified (Suboptimal) Selection -- 11.1.4 Examples -- 11.2 Energy-based Antenna Selection -- 11.3 Antenna Selection for Space-Time Trellis Codes -- 11.3.1 Quasi-Static Fading Channels -- 11.3.2 Block Fading Channels -- 11.3.3 Fast Fading Channels -- 11.3.4 Examples -- 11.4 Antenna Selection for Space-Time Block Codes -- 11.4.1 Receive Antenna Selection -- 11.4.2 Transmit Antenna Selection -- 11.4.3 Examples -- 11.5 Antenna Selection for Combined Channel Coding and Orthogonal STBCs. 11.5.1 Performance Analysis -- 11.5.2 Examples -- 11.6 Antenna Selection for Frequency Selective Channels -- 11.7 Antenna Selection with Nonidealities -- 11.7.1 Impact of Spatial Correlation -- 11.7.2 Example -- 11.7.3 Impact of Channel Estimation Error -- 11.8 Chapter Summary and Further Reading -- Bibliography -- Index. |
| Record Nr. | UNINA-9910144580503321 |
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Duman Tolga M.
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| Chichester, England ; , : J. Wiley & Sons, , c2007 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Coding for MIMO communication systems / / Tolga M. Duman, Ali Ghrayeb
| Coding for MIMO communication systems / / Tolga M. Duman, Ali Ghrayeb |
| Autore | Duman Tolga M. |
| Pubbl/distr/stampa | Chichester, England ; , : J. Wiley & Sons, , c2007 |
| Descrizione fisica | 1 online resource (368 p.) |
| Disciplina | 621.3840285/572 |
| Altri autori (Persone) | GhrayebAli |
| Soggetto topico |
Space time codes
MIMO systems Wireless communication systems |
| ISBN |
1-282-12310-6
9786612123108 0-470-72434-X 0-470-72433-1 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
About the Authors. -- Preface -- List of Figures -- List of Tables -- Notation -- Abbreviations -- 1 Overview -- 1.1 Need for MIMO Systems -- 1.2 MIMO Communications in Wireless Standards -- 1.3 Organization of the Book -- 1.4 Other Topics in MIMO Systems -- 2 Fading Channels and Diversity Techniques -- 2.1 Wireless Channels -- 2.1.1 Path Loss, Shadowing and Small Scale Fading -- 2.1.2 Fading Channel Models -- 2.2 Error/Outage Probabilities over Fading Channels -- 2.2.1 Outage Probability for Rayleigh Fading Channels -- 2.2.2 Average Error Probabilities over Rayleigh Fading Channels -- 2.2.3 Extensions to Other Fading Channels -- 2.2.4 Performance over Frequency Selective Fading Channels -- 2.3 Diversity Techniques -- 2.3.1 Types of Diversity -- 2.3.2 System Model for Lth Order Diversity -- 2.3.3 Maximal Ratio Combining (MRC) -- 2.3.4 Suboptimal Combining Algorithms -- 2.3.5 Selection Combining -- 2.3.6 Examples -- 2.4 Channel Coding as a Means of Time Diversity -- 2.4.1 Block Coding over a Fully Interleaved Channel -- 2.4.2 Convolutional Coding -- 2.5 Multiple Antennas in Wireless Communications -- 2.5.1 Receive Diversity -- 2.5.2 Smart Antennas and Beamforming -- 2.6 Chapter Summary and Further Reading -- 3 Capacity and Information Rates of MIMO Channels -- 3.1 Capacity and Information Rates of Noisy Channels -- 3.2 Capacity and Information Rates of AWGN and Fading Channels -- 3.2.1 AWGN Channels -- 3.2.2 Fading Channels -- 3.3 Capacity of MIMO Channels -- 3.3.1 Deterministic MIMO Channels -- 3.3.2 Ergodic MIMO Channels -- 3.3.3 Non-Ergodic MIMO Channels and Outage Capacity -- 3.3.4 Transmit CSI for MIMO Fading Channels -- 3.4 Constrained Signaling for MIMO Communications -- 3.5 Discussion: Why Use MIMO Systems? -- 3.6 Chapter Summary and Further Reading. -- 4 Space-Time Block Codes -- 4.1 Transmit Diversity with Two Antennas: The Alamouti Scheme -- 4.1.1 Transmission Scheme -- 4.1.2 Optimal Receiver for the Alamouti Scheme -- 4.1.3 Performance Analysis of the Alamouti Scheme.
4.1.4 Examples -- 4.2 Orthogonal Space-Time Block Codes -- 4.2.1 Linear Orthogonal Designs -- 4.2.2 Decoding of General Space-Time Block Codes -- 4.2.3 Performance Analysis of Space-Time Block Codes. -- 4.2.4 Examples -- 4.3 Quasi-Orthogonal Space-Time Block Codes -- 4.4 Linear Dispersion Codes -- 4.5 Chapter Summary and Further Reading. -- 5 Space-Time Trellis Codes -- 5.1 A Simple Space-Time Trellis Code -- 5.2 General Space-Time Trellis Codes -- 5.2.1 Notation and Preliminaries -- 5.2.2 Decoding of Space-Time Trellis Codes -- 5.3 Basic Space-Time Code Design Principles -- 5.3.1 Pairwise Error Probability -- 5.3.2 Space-Time Code Design Principles -- 5.3.3 Examples of Good Space-Time Codes -- 5.3.4 Space-Time Trellis Codes for Fast Fading Channels -- 5.4 Representation for Space-Time Trellis Codes for PSK Constellations -- 5.4.1 Generator Matrix Representation -- 5.4.2 Improved Space-Time Code Design -- 5.5 Performance Analysis for Space-Time Trellis Codes -- 5.5.1 Union Bound for Space-Time Trellis Codes -- 5.5.2 Useful Performance Bounds for Space-Time Trellis Codes -- 5.5.3 Examples -- 5.6 Comparison of Space-Time Block and Trellis Codes -- 5.7 Chapter Summary and Further Reading -- 6 Layered Space-Time Codes. -- 6.1 Basic Bell Labs Layered Space-Time (BLAST) Architectures -- 6.1.1 VBLAST/HBLAST/SCBLAST -- 6.1.2 Detection Algorithms for Basic BLAST Architectures -- 6.1.3 Examples -- 6.2 Diagonal BLAST (DBLAST) -- 6.2.1 Detection Algorithms for DBLAST -- 6.2.2 Examples -- 6.3 Multilayered Space-Time Coding -- 6.3.1 Encoder Structure -- 6.3.2 Group Interference Cancellation Detection -- 6.3.3 Example -- 6.4 Threaded Space-Time Codes -- 6.4.1 Layering Approach -- 6.4.2 Threaded Space-Time Code Design -- 6.4.3 Example -- 6.4.4 Detection of Threaded Space-Time Codes -- 6.5 Other Detection Algorithms for Spatial Multiplexing Systems -- 6.5.1 Greedy Detection -- 6.5.2 Belief Propagation Detection -- 6.5.3 Turbo-BLAST Detection -- 6.5.4 Reduced Complexity ZF/MMSE Detection. 6.5.5 Sphere Decoding -- 6.6 Diversity/Multiplexing Gain Trade-off -- 6.7 Chapter Summary and Further Reading -- 7 Concatenated Codes and Iterative Decoding -- 7.1 Development of Concatenated Codes -- 7.2 Concatenated Codes for AWGN Channels -- 7.2.1 Encoder Structures -- 7.2.2 Iterative Decoder Structures -- 7.2.3 The SOVA Decoder -- 7.2.4 Performance with Maximum Likelihood Decoding -- 7.2.5 Examples -- 7.3 Concatenated Codes for MIMO Channels -- 7.3.1 Concatenated Space-Time Turbo Coding Scheme -- 7.3.2 Turbo Space-Time Trellis Coding Scheme -- 7.3.3 Turbo Space-Time Coding Scheme -- 7.4 Turbo Coded Modulation for MIMO Channels -- 7.4.1 Encoder Structure -- 7.4.2 Decoder Structure -- 7.4.3 Examples -- 7.5 Concatenated Space-Time Block Coding -- 7.5.1 Encoder Structure -- 7.5.2 Decoder Structure -- 7.5.3 Performance Analysis -- 7.5.4 Examples -- 7.6 Chapter Summary and Further Reading. -- 8 Unitary and Differential Space-Time Codes -- 8.1 Capacity of Noncoherent MIMO Channels -- 8.1.1 Channel Capacity -- 8.1.2 Capacity Achieving Signals -- 8.2 Unitary Space-Time Codes -- 8.2.1 USTC Encoder -- 8.2.2 ML Detection of USTCs -- 8.2.3 Performance Analysis -- 8.2.4 Construction of Unitary Space-Time Signals -- 8.2.5 Examples -- 8.3 Differential Space-Time Codes -- 8.3.1 Differential Space-Time Coding for Single Antenna Systems -- 8.3.2 Differential Space-Time Coding for MIMO Systems -- 8.4 Turbo Coded Unitary Space-Time Codes -- 8.4.1 Encoder Structure -- 8.4.2 Noncoherent Iterative Decoder -- 8.4.3 Example. -- 8.5 Trellis Coded Unitary Space-Time Codes -- 8.6 Turbo Coded Differential Space-Time Codes -- 8.6.1 Encoder Structure -- 8.6.2 Iterative Detectors -- 8.7 Chapter Summary and Further Reading -- 9 Space-Time Coding for Frequency Selective Fading Channels -- 9.1 MIMO Frequency Selective Channels -- 9.2 Capacity and Information Rates of MIMO Frequency Selective Fading Channels -- 9.2.1 Information Rates with Gaussian Inputs -- 9.2.2 Achievable Information Rates with Practical Constellations. 9.2.3 Examples -- 9.3 Space-Time Coding for MIMO FS Channels -- 9.3.1 Interpretation of MIMO FS Channels Using Virtual Antennas -- 9.3.2 A Simple Full Diversity Code for MIMO FS Channels -- 9.3.3 Space-Time Trellis Codes for MIMO FS Channels -- 9.3.4 Concatenated Coding for MIMO FS Channels -- 9.3.5 Spatial Multiplexing for MIMO FS Channels -- 9.4 Channel Detection for MIMO FS Channels -- 9.4.1 Linear Equalization for MIMO FS Channels -- 9.4.2 Decision Feedback Equalization for MIMO FS Channels -- 9.4.3 Soft Input Soft Output Channel Detection -- 9.4.4 Other Reduced Complexity Approaches -- 9.5 MIMO OFDM Systems -- 9.5.1 MIMO-OFDM Channel Model -- 9.5.2 Space-Frequency Coding -- 9.5.3 Challenges in MIMO-OFDM -- 9.6 Chapter Summary and Further Reading -- 10 Practical Issues in MIMO Communications -- 10.1 Channel State Information Estimation -- 10.1.1 CSI Estimation Using Pilot Tones -- 10.1.2 What to Do with CSI? -- 10.1.3 Space-Time Coding Examples with Estimated CSI -- 10.2 Spatial Channel Correlation for MIMO Systems -- 10.2.1 Measurements and Modeling of Spatial Correlation -- 10.2.2 Spatial Channel Correlation Models -- 10.2.3 Channel Capacity with Spatial Correlation -- 10.2.4 Space-Time Code Performance with Spatial Correlation -- 10.3 Temporal Channel Correlation -- 10.4 MIMO Communication System Design Issues -- 10.5 Chapter Summary and Further Reading -- 11 Antenna Selection for MIMO Systems -- 11.1 Capacity-based Antenna Selection -- 11.1.1 System Model -- 11.1.2 Optimal Selection -- 11.1.3 Simplified (Suboptimal) Selection -- 11.1.4 Examples -- 11.2 Energy-based Antenna Selection -- 11.3 Antenna Selection for Space-Time Trellis Codes -- 11.3.1 Quasi-Static Fading Channels -- 11.3.2 Block Fading Channels -- 11.3.3 Fast Fading Channels -- 11.3.4 Examples -- 11.4 Antenna Selection for Space-Time Block Codes -- 11.4.1 Receive Antenna Selection -- 11.4.2 Transmit Antenna Selection -- 11.4.3 Examples -- 11.5 Antenna Selection for Combined Channel Coding and Orthogonal STBCs. 11.5.1 Performance Analysis -- 11.5.2 Examples -- 11.6 Antenna Selection for Frequency Selective Channels -- 11.7 Antenna Selection with Nonidealities -- 11.7.1 Impact of Spatial Correlation -- 11.7.2 Example -- 11.7.3 Impact of Channel Estimation Error -- 11.8 Chapter Summary and Further Reading -- Bibliography -- Index. |
| Record Nr. | UNINA-9910819169203321 |
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Duman Tolga M.
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| Chichester, England ; , : J. Wiley & Sons, , c2007 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Comparing state-space multivariable controls to multi-SISO controls for load reduction of drivetrain-coupled modes on wind turbines through field-testing [[electronic resource] ] : preprint / / P.A. Fleming and A.D. Wright, J.W. van Wingerden
| Comparing state-space multivariable controls to multi-SISO controls for load reduction of drivetrain-coupled modes on wind turbines through field-testing [[electronic resource] ] : preprint / / P.A. Fleming and A.D. Wright, J.W. van Wingerden |
| Autore | Fleming Paul <1964-> |
| Pubbl/distr/stampa | [Golden, Colo.] : , : National Renewable Energy Laboratory, [National Wind Technology Center], , [2011] |
| Descrizione fisica | 1 online resource (13 pages) : color illustrations |
| Altri autori (Persone) |
Van WingerdenJan-Willem
WrightAlan D |
| Collana | NREL/CP |
| Soggetto topico |
Wind turbines - Research
MIMO systems |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Altri titoli varianti | Comparing State-Space Multivariable Controls to Multi-SISO Controls for Load Reduction of Drivetrain-Coupled Modes on Wind Turbines through Field-Testing |
| Record Nr. | UNINA-9910703207203321 |
|
Fleming Paul <1964->
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||
| [Golden, Colo.] : , : National Renewable Energy Laboratory, [National Wind Technology Center], , [2011] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Cooperative communications : hardware, channel & PHY / / Mischa Dohler, Yonghui Li
| Cooperative communications : hardware, channel & PHY / / Mischa Dohler, Yonghui Li |
| Autore | Dohler Mischa |
| Edizione | [1st edition] |
| Pubbl/distr/stampa | Chichester, West Sussex, U.K. ; , : Wiley, , 2010 |
| Descrizione fisica | 1 online resource (465 p.) |
| Disciplina | 621.384 |
| Altri autori (Persone) | LiYonghui <1975-> |
| Soggetto topico |
Cognitive radio networks
Internetworking (Telecommunication) MIMO systems Multiuser detection (Telecommunication) Ad hoc networks (Computer networks) |
| ISBN |
1-282-48226-2
9786612482267 0-470-74007-8 0-470-74006-X |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | Preface. -- Abbreviations. -- Functions. -- Symbols. -- 1 Introduction. -- 1.1 Book Structure. -- 1.2 Quick Introduction. -- 1.3 Application Scenarios. -- 1.4 Pros and Cons of Cooperation. -- 1.5 Cooperative Performance Bounds. -- 1.6 Definitions and Terminology. -- 1.7 Background and Milestones. -- 1.8 Concluding Remarks. -- 2 Wireless Relay Channel. -- 2.1 Introductory Note. -- 2.2 General Characteristics and Trends. -- 2.3 Regenerative Relaying Channel. -- 2.4 Transparent Relaying Channel. -- 2.5 Distributed MIMO Channel. -- 2.6 Concluding Remarks. -- 3 Transparent Relaying Techniques. -- 3.1 Introductory Note. -- 3.2 Transparent Relaying Protocols. -- 3.3 Transparent Space / Time Processing. -- 3.4 Distributed System Optimization. -- 3.5 Concluding Remarks. -- 4 Regenerative Relaying Techniques. -- 4.1 Introductory Note. -- 4.2 Regenerative Relay Protocols. -- 4.3 Distributed Space / Time Coding. -- 4.4 Distributed Network Coding. -- 4.5 Concluding Remarks. -- 5 Hardware Issues. -- 5.1 Introductory Note. -- 5.2 Analog Hardware Transceivers. -- 5.3 Digital Hardware Transceivers. -- 5.4 Architectural Comparisons. -- 5.5 Complexity of 3G UMTS Voice/HSDPA Relay. -- 5.6 Complexity of LTE/WiMAX Relay. -- 5.7 Hardware Demonstrators. -- 5.8 Concluding Remarks. -- 6 Conclusions and Outlook. -- 6.1 Contributions. -- 6.2 Real-World Impairments. -- 6.3 Open Research Problems. -- 6.4 Business Challenges. -- References. -- Index. |
| Record Nr. | UNINA-9910139507103321 |
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Dohler Mischa
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| Chichester, West Sussex, U.K. ; , : Wiley, , 2010 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Cooperative communications : hardware, channel & PHY / / Mischa Dohler, Yonghui Li
| Cooperative communications : hardware, channel & PHY / / Mischa Dohler, Yonghui Li |
| Autore | Dohler Mischa |
| Edizione | [1st edition] |
| Pubbl/distr/stampa | Chichester, West Sussex, U.K. ; , : Wiley, , 2010 |
| Descrizione fisica | 1 online resource (465 p.) |
| Disciplina | 621.384 |
| Altri autori (Persone) | LiYonghui <1975-> |
| Soggetto topico |
Cognitive radio networks
Internetworking (Telecommunication) MIMO systems Multiuser detection (Telecommunication) Ad hoc networks (Computer networks) |
| ISBN |
1-282-48226-2
9786612482267 0-470-74007-8 0-470-74006-X |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | Preface. -- Abbreviations. -- Functions. -- Symbols. -- 1 Introduction. -- 1.1 Book Structure. -- 1.2 Quick Introduction. -- 1.3 Application Scenarios. -- 1.4 Pros and Cons of Cooperation. -- 1.5 Cooperative Performance Bounds. -- 1.6 Definitions and Terminology. -- 1.7 Background and Milestones. -- 1.8 Concluding Remarks. -- 2 Wireless Relay Channel. -- 2.1 Introductory Note. -- 2.2 General Characteristics and Trends. -- 2.3 Regenerative Relaying Channel. -- 2.4 Transparent Relaying Channel. -- 2.5 Distributed MIMO Channel. -- 2.6 Concluding Remarks. -- 3 Transparent Relaying Techniques. -- 3.1 Introductory Note. -- 3.2 Transparent Relaying Protocols. -- 3.3 Transparent Space / Time Processing. -- 3.4 Distributed System Optimization. -- 3.5 Concluding Remarks. -- 4 Regenerative Relaying Techniques. -- 4.1 Introductory Note. -- 4.2 Regenerative Relay Protocols. -- 4.3 Distributed Space / Time Coding. -- 4.4 Distributed Network Coding. -- 4.5 Concluding Remarks. -- 5 Hardware Issues. -- 5.1 Introductory Note. -- 5.2 Analog Hardware Transceivers. -- 5.3 Digital Hardware Transceivers. -- 5.4 Architectural Comparisons. -- 5.5 Complexity of 3G UMTS Voice/HSDPA Relay. -- 5.6 Complexity of LTE/WiMAX Relay. -- 5.7 Hardware Demonstrators. -- 5.8 Concluding Remarks. -- 6 Conclusions and Outlook. -- 6.1 Contributions. -- 6.2 Real-World Impairments. -- 6.3 Open Research Problems. -- 6.4 Business Challenges. -- References. -- Index. |
| Record Nr. | UNINA-9910811953003321 |
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Dohler Mischa
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| Chichester, West Sussex, U.K. ; , : Wiley, , 2010 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Cooperative networking / / [edited by] Mohammad Obaidat, Sudip Misra
| Cooperative networking / / [edited by] Mohammad Obaidat, Sudip Misra |
| Autore | Obaidat Mohammad S |
| Pubbl/distr/stampa | Chichester, West Sussex, U.K. ; , : Wiley, , 2011 |
| Descrizione fisica | 1 online resource (354 p.) |
| Disciplina |
004.6
621.384 |
| Altri autori (Persone) |
ObaidatMohammad S <1952-> (Mohammad Salameh)
MisraSudip |
| Soggetto topico |
Ad hoc networks (Computer networks)
Internetworking (Telecommunication) MIMO systems Peer-to-peer architecture (Computer networks) Radio relay systems Wireless communication systems Electrical & Computer Engineering Engineering & Applied Sciences Telecommunications |
| ISBN |
1-283-20442-8
9786613204424 1-119-97358-9 1-61344-505-9 1-119-97359-7 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
About the Editors xiii -- List of Contributors xvii -- 1 Introduction 1 / Mohammad S. Obaidat and Sudip Misra -- 1.1 Major Features of the Book 4 -- 1.2 Target Audience 4 -- 1.3 Supplementary Resources 5 -- 1.4 Acknowledgements 5 -- 2 Fundamentals and Issues with Cooperation in Networking 7 / Mohammad S. Obaidat and Tarik Guelzim -- 2.1 Introduction 7 -- 2.2 Fundamentals of Cooperating Networks 7 -- 2.2.1 Cooperative Adhoc Network Services 8 -- 2.2.2 Cooperative Relaying Network Service 13 -- 2.3 Issues and Security Flaws with Cooperating Networks: -- Wireless Sensor Networks Case Study 15 -- 2.3.1 Limitations in Mobile Ad hoc Networks 16 -- 2.4 Conclusions 19 -- References 19 -- 3 To Cooperate or Not to Cooperate? That is the Question! 21 / Mohamed H. Ahmed and Salama S. Ikki -- 3.1 Introduction 21 -- 3.2 Overview of Cooperative-Diversity Systems 22 -- 3.2.1 Relaying Techniques 22 -- 3.2.2 Combining Techniques 23 -- 3.2.3 Other Cooperating Techniques 24 -- 3.3 Benefits of Cooperative-Diversity Systems 25 -- 3.3.1 Signal-Quality Improvement 25 -- 3.3.2 Reduced Power 28 -- 3.3.3 Better Coverage 28 -- 3.3.4 Capacity Gain 28 -- 3.4 Major Challenges of Cooperative-Diversity Systems 28 -- 3.4.1 Resources Over-Utilization 28 -- 3.4.2 Additional Delay 29 -- 3.4.3 Complexity 30 -- 3.4.4 Unavailability of Cooperating Nodes 32 -- 3.4.5 Security Threats 32 -- 3.5 Discussion and Conclusion 32 -- References 33 -- 4 Cooperation in Wireless Ad Hoc and Sensor Networks 35 / J. Barbancho, D. Cascado, J. L. Sevillano, C. Leƒon, A. Linares and F. J. Molina -- 4.1 Introduction 35 -- 4.2 Why Could Cooperation in WAdSN be Useful? 36 -- 4.2.1 Time Synchronization, Localization and Calibration 36 -- 4.2.2 Routing 41 -- 4.2.3 Data Aggregation and Fusion 43 -- 4.3 Research Directions for Cooperation in WAdSN 45 -- 4.3.1 Middleware for WAdSN 46 -- 4.3.2 Multi-Agent Systems in WAdSN 48 -- 4.3.3 Artificial Neural Networks in WAdSN 50 -- 4.4 Final Remarks 53 -- 4.5 Acknowledgements 53 -- References 53.
5 Cooperation in Autonomous Vehicular Networks 57 / Sidi Mohammed Senouci, Abderrahim Benslimane and Hassnaa Moustafa -- 5.1 Introduction 57 -- 5.2 Overview on Vehicular Networks 58 -- 5.3 Cooperation at Different OSI Layers 59 -- 5.3.1 Cooperation at Lower Layers 59 -- 5.3.2 Cooperation at Network Layer 60 -- 5.3.3 Security and Authentication versus Cooperation 67 -- 5.3.4 Cooperation at Upper Layers 69 -- 5.4 Conclusion 73 -- References 73 -- 6 Cooperative Overlay Networking for Streaming Media Content 77 / F. Wang, J. Liu and K. Wu -- 6.1 Introduction 77 -- 6.2 Architectural Choices for Streaming Media Content over the Internet 78 -- 6.2.1 Router-Based Architectures: IP Multicast 79 -- 6.2.2 Architectures with Proxy Caching 80 -- 6.2.3 Peer-to-Peer Architectures 81 -- 6.3 Peer-to-Peer Media Streaming 82 -- 6.3.1 Comparisons with Other Peer-to-Peer Applications 82 -- 6.3.2 Design Issues 83 -- 6.3.3 Approaches for Overlay Construction 83 -- 6.4 Overview of mTreebone 85 -- 6.4.1 Treebone: A Stable Tree-Based Backbone 85 -- 6.4.2 Mesh: An Adaptive Auxiliary Overlay 86 -- 6.5 Treebone Construction and Optimization 87 -- 6.5.1 Optimal Stable Node Identification 87 -- 6.5.2 Treebone Bootstrapping and Evolution 88 -- 6.5.3 Treebone Optimization 89 -- 6.6 Collaborative Mesh-Tree Data Delivery 91 -- 6.6.1 Seamless Push/Pull Switching 91 -- 6.6.2 Handling Host Dynamics 91 -- 6.7 Performance Evaluation 92 -- 6.7.1 Large-Scale Simulations 92 -- 6.7.2 PlanetLab-Based Experiments 94 -- 6.8 Conclusion and Future Work 98 -- References 98 -- 7 Cooperation in DTN-Based Network Architectures 101 / Vasco N. G. J. Soares and Joel J. P. C. Rodrigues -- 7.1 Introduction 101 -- 7.2 Delay-Tolerant Networks 102 -- 7.2.1 DTN Application Domains 103 -- 7.2.2 Cooperation in Delay-Tolerant Networks 103 -- 7.3 Vehicular Delay-Tolerant Networks 106 -- 7.3.1 Cooperation in Vehicular-Delay Tolerant Networks 106 -- 7.3.2 Performance Assessment of Node Cooperation 108 -- 7.4 Conclusions 112 -- 7.5 Acknowledgements 113. References 113 -- 8 Access Selection and Cooperation in Ambient Networks 117 / Ram'on Agüero -- 8.1 Leveraging the Cooperation in Heterogeneous Wireless Networks 117 -- 8.2 The Ambient Networks Philosophy 118 -- 8.2.1 Generic Link Layer 120 -- 8.2.2 Management of Heterogeneous Wireless Resources 120 -- 8.2.3 Additional Functional Entities 121 -- 8.2.4 Multi-Access Functions and Procedures 122 -- 8.3 Related Work 125 -- 8.4 Outlook 125 -- 8.4.1 Cognition 125 -- 8.4.2 Mesh Topologies 127 -- 8.5 Conclusions 127 -- References 128 -- 9 Cooperation in Intrusion Detection Networks 133 / Carol Fung and Raouf Boutaba -- 9.1 Overview of Network Intrusions 133 -- 9.1.1 Single-Host Intrusion and Malware 133 -- 9.1.2 Distributed Attacks and Botnets 134 -- 9.1.3 Cooperative Attacks and Phishing 134 -- 9.2 Intrusion Detection Systems 135 -- 9.2.1 Signature-Based and Anomaly-Based IDSs 135 -- 9.2.2 Host-Based and Network-Based IDSs 135 -- 9.3 Cooperation in Intrusion Detection Networks 136 -- 9.3.1 Cooperation Topology 136 -- 9.3.2 Cooperation Scope 137 -- 9.3.3 Specialization 137 -- 9.3.4 Cooperation Technologies and Algorithms 137 -- 9.3.5 Taxonomy 138 -- 9.4 Selected Intrusion Detection Networks 139 -- 9.4.1 Indra 139 -- 9.4.2 DOMINO 139 -- 9.4.3 DShield 140 -- 9.4.4 NetShield 140 -- 9.4.5 Gossip 141 -- 9.4.6 Worminator 142 -- 9.4.7 ABDIAS 142 -- 9.4.8 CRIM 142 -- 9.4.9 HBCIDS 143 -- 9.4.10 ALPACAS 143 -- 9.4.11 CDDHT 143 -- 9.4.12 SmartScreen Filter 143 -- 9.4.13 FFCIDN 144 -- 9.5 Open Challenges and Future Directions 144 -- 9.6 Conclusion 144 -- References 144 -- 10 Cooperation Link Level Retransmission in Wireless Networks 147 / Mehrdad Dianati, Xuemin (Sherman) Shen and Kshirasagar Naik -- 10.1 Introduction 147 -- 10.2 Background 149 -- 10.2.1 Modeling of Fading Channels 149 -- 10.2.2 Automatic Repeat Request 152 -- 10.3 System Model 154 -- 10.4 Protocol Model 155 -- 10.5 Node Cooperative SW Scheme 156 -- 10.6 Performance Analysis 157 -- 10.7 Delay Analysis 164 -- 10.8 Verification of Analytical Models 168. 10.8.1 Throughput 169 -- 10.8.2 Average Delay and Delay Jitter 171 -- 10.9 Discussion of the Related Works 172 -- 10.10 Summary 174 -- 10.11 Acknowledgement 174 -- References 175 -- 11 Cooperative Inter-Node and Inter-Layer Optimization of Network Protocols 177 / D. Kliazovich, F. Granelli and N. L. S. da Fonseca -- 11.1 Introduction 177 -- 11.2 A Framework for Cooperative Configuration and Optimization 178 -- 11.2.1 Tuning TCP/IP Parameters 178 -- 11.2.2 Cooperative Optimization Architecture 179 -- 11.3 Cooperative Optimization Design 181 -- 11.3.1 Inter-Layer Cooperative Optimization 181 -- 11.3.2 Inter-Node Cooperative Optimization 183 -- 11.4 A Test Case: TCP Optimization Using a Cooperative Framework 184 -- 11.4.1 Implementation 184 -- 11.4.2 Inter-Layer Cognitive Optimization 186 -- 11.4.3 Inter-Node Cognitive Optimization 187 -- 11.5 Conclusions 189 -- References 189 -- 12 Cooperative Network Coding 191 / H. Rashvand, C. Khirallah, V. Stankovic and L. Stankovic -- 12.1 Introduction 191 -- 12.2 Network Coding Concept 192 -- 12.2.1 Example 192 -- 12.3 Cooperative Relay 195 -- 12.4 Cooperation Strategies 196 -- 12.4.1 Performance Measures 197 -- 12.5 Cooperative Network Coding 206 -- 12.6 Conclusions 214 -- References 214 -- 13 Cooperative Caching for Chip Multiprocessors 217 / J. Chang, E. Herrero, R. Canal and G. Sohi -- 13.1 Caching and Chip Multiprocessors 217 -- 13.1.1 Caching Background 217 -- 13.1.2 CMP (Chip Multiprocessor) 218 -- 13.1.3 CMP Caching Challenges 218 -- 13.2 Cooperative Caching and CMP Caching 220 -- 13.2.1 Motivation for Cooperative Caching 220 -- 13.2.2 The Unique Aspects of Cooperative Caching 220 -- 13.2.3 CMP Cache Partitioning Schemes 225 -- 13.2.4 A Taxonomy of CMP Caching Techniques 226 -- 13.3 CMP Cooperative Caching Framework 226 -- 13.3.1 CMP Cooperative Caching Framework 227 -- 13.3.2 CC Mechanisms 229 -- 13.3.3 CC Implementations 234 -- 13.3.4 CC for Large Scale CMPs 241 -- 13.3.5 Distributed Cooperative Caching 243 -- 13.3.6 Summary 249. 13.4 CMP Cooperative Caching Applications 251 -- 13.4.1 CMP Cooperative Caching for Latency Reduction 252 -- 13.4.2 CMP Cooperative Caching for Adaptive Repartitioning 259 -- 13.4.3 CMP Cooperative Caching for Performance Isolation 262 -- 13.5 Summary 269 -- References 270 -- 14 Market-Oriented Resource Management and Scheduling: A Taxonomy and Survey 277 / Saurabh Kumar Garg and Rajkumar Buyya -- 14.1 Introduction 277 -- 14.2 Overview of Utility Grids and Preliminaries 277 -- 14.3 Requirements 279 -- 14.3.1 Consumer Side Requirements 279 -- 14.3.2 Resource Provider Side Requirements 280 -- 14.3.3 Market Exchange Requirements 280 -- 14.4 Utility Grid Infrastructural Components 282 -- 14.5 Taxonomy of Market-Oriented Scheduling 283 -- 14.5.1 Market Model 284 -- 14.5.2 Allocation Decision 288 -- 14.5.3 Participant Focus 288 -- 14.5.4 Application Type 288 -- 14.5.5 Allocation Objective 289 -- 14.6 Survey of Grid Resource Management Systems 289 -- 14.6.1 Survey of Market-Oriented Systems 289 -- 14.6.2 System-Oriented Schedulers 296 -- 14.7 Discussion and Gap Analysis 300 -- 14.7.1 Scheduling Mechanisms 300 -- 14.7.2 Market Based Systems 301 -- 14.8 Summary 302 -- References 303 -- Glossary 307 -- Index 319. |
| Record Nr. | UNINA-9910139621003321 |
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Obaidat Mohammad S
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| Chichester, West Sussex, U.K. ; , : Wiley, , 2011 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Cooperative networking / / [edited by] Mohammad Obaidat, Sudip Misra
| Cooperative networking / / [edited by] Mohammad Obaidat, Sudip Misra |
| Autore | Obaidat Mohammad S |
| Pubbl/distr/stampa | Chichester, West Sussex, U.K. ; , : Wiley, , 2011 |
| Descrizione fisica | 1 online resource (354 p.) |
| Disciplina |
004.6
621.384 |
| Altri autori (Persone) |
ObaidatMohammad S <1952-> (Mohammad Salameh)
MisraSudip |
| Soggetto topico |
Ad hoc networks (Computer networks)
Internetworking (Telecommunication) MIMO systems Peer-to-peer architecture (Computer networks) Radio relay systems Wireless communication systems Electrical & Computer Engineering Engineering & Applied Sciences Telecommunications |
| ISBN |
1-283-20442-8
9786613204424 1-119-97358-9 1-61344-505-9 1-119-97359-7 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
About the Editors xiii -- List of Contributors xvii -- 1 Introduction 1 / Mohammad S. Obaidat and Sudip Misra -- 1.1 Major Features of the Book 4 -- 1.2 Target Audience 4 -- 1.3 Supplementary Resources 5 -- 1.4 Acknowledgements 5 -- 2 Fundamentals and Issues with Cooperation in Networking 7 / Mohammad S. Obaidat and Tarik Guelzim -- 2.1 Introduction 7 -- 2.2 Fundamentals of Cooperating Networks 7 -- 2.2.1 Cooperative Adhoc Network Services 8 -- 2.2.2 Cooperative Relaying Network Service 13 -- 2.3 Issues and Security Flaws with Cooperating Networks: -- Wireless Sensor Networks Case Study 15 -- 2.3.1 Limitations in Mobile Ad hoc Networks 16 -- 2.4 Conclusions 19 -- References 19 -- 3 To Cooperate or Not to Cooperate? That is the Question! 21 / Mohamed H. Ahmed and Salama S. Ikki -- 3.1 Introduction 21 -- 3.2 Overview of Cooperative-Diversity Systems 22 -- 3.2.1 Relaying Techniques 22 -- 3.2.2 Combining Techniques 23 -- 3.2.3 Other Cooperating Techniques 24 -- 3.3 Benefits of Cooperative-Diversity Systems 25 -- 3.3.1 Signal-Quality Improvement 25 -- 3.3.2 Reduced Power 28 -- 3.3.3 Better Coverage 28 -- 3.3.4 Capacity Gain 28 -- 3.4 Major Challenges of Cooperative-Diversity Systems 28 -- 3.4.1 Resources Over-Utilization 28 -- 3.4.2 Additional Delay 29 -- 3.4.3 Complexity 30 -- 3.4.4 Unavailability of Cooperating Nodes 32 -- 3.4.5 Security Threats 32 -- 3.5 Discussion and Conclusion 32 -- References 33 -- 4 Cooperation in Wireless Ad Hoc and Sensor Networks 35 / J. Barbancho, D. Cascado, J. L. Sevillano, C. Leƒon, A. Linares and F. J. Molina -- 4.1 Introduction 35 -- 4.2 Why Could Cooperation in WAdSN be Useful? 36 -- 4.2.1 Time Synchronization, Localization and Calibration 36 -- 4.2.2 Routing 41 -- 4.2.3 Data Aggregation and Fusion 43 -- 4.3 Research Directions for Cooperation in WAdSN 45 -- 4.3.1 Middleware for WAdSN 46 -- 4.3.2 Multi-Agent Systems in WAdSN 48 -- 4.3.3 Artificial Neural Networks in WAdSN 50 -- 4.4 Final Remarks 53 -- 4.5 Acknowledgements 53 -- References 53.
5 Cooperation in Autonomous Vehicular Networks 57 / Sidi Mohammed Senouci, Abderrahim Benslimane and Hassnaa Moustafa -- 5.1 Introduction 57 -- 5.2 Overview on Vehicular Networks 58 -- 5.3 Cooperation at Different OSI Layers 59 -- 5.3.1 Cooperation at Lower Layers 59 -- 5.3.2 Cooperation at Network Layer 60 -- 5.3.3 Security and Authentication versus Cooperation 67 -- 5.3.4 Cooperation at Upper Layers 69 -- 5.4 Conclusion 73 -- References 73 -- 6 Cooperative Overlay Networking for Streaming Media Content 77 / F. Wang, J. Liu and K. Wu -- 6.1 Introduction 77 -- 6.2 Architectural Choices for Streaming Media Content over the Internet 78 -- 6.2.1 Router-Based Architectures: IP Multicast 79 -- 6.2.2 Architectures with Proxy Caching 80 -- 6.2.3 Peer-to-Peer Architectures 81 -- 6.3 Peer-to-Peer Media Streaming 82 -- 6.3.1 Comparisons with Other Peer-to-Peer Applications 82 -- 6.3.2 Design Issues 83 -- 6.3.3 Approaches for Overlay Construction 83 -- 6.4 Overview of mTreebone 85 -- 6.4.1 Treebone: A Stable Tree-Based Backbone 85 -- 6.4.2 Mesh: An Adaptive Auxiliary Overlay 86 -- 6.5 Treebone Construction and Optimization 87 -- 6.5.1 Optimal Stable Node Identification 87 -- 6.5.2 Treebone Bootstrapping and Evolution 88 -- 6.5.3 Treebone Optimization 89 -- 6.6 Collaborative Mesh-Tree Data Delivery 91 -- 6.6.1 Seamless Push/Pull Switching 91 -- 6.6.2 Handling Host Dynamics 91 -- 6.7 Performance Evaluation 92 -- 6.7.1 Large-Scale Simulations 92 -- 6.7.2 PlanetLab-Based Experiments 94 -- 6.8 Conclusion and Future Work 98 -- References 98 -- 7 Cooperation in DTN-Based Network Architectures 101 / Vasco N. G. J. Soares and Joel J. P. C. Rodrigues -- 7.1 Introduction 101 -- 7.2 Delay-Tolerant Networks 102 -- 7.2.1 DTN Application Domains 103 -- 7.2.2 Cooperation in Delay-Tolerant Networks 103 -- 7.3 Vehicular Delay-Tolerant Networks 106 -- 7.3.1 Cooperation in Vehicular-Delay Tolerant Networks 106 -- 7.3.2 Performance Assessment of Node Cooperation 108 -- 7.4 Conclusions 112 -- 7.5 Acknowledgements 113. References 113 -- 8 Access Selection and Cooperation in Ambient Networks 117 / Ram'on Agüero -- 8.1 Leveraging the Cooperation in Heterogeneous Wireless Networks 117 -- 8.2 The Ambient Networks Philosophy 118 -- 8.2.1 Generic Link Layer 120 -- 8.2.2 Management of Heterogeneous Wireless Resources 120 -- 8.2.3 Additional Functional Entities 121 -- 8.2.4 Multi-Access Functions and Procedures 122 -- 8.3 Related Work 125 -- 8.4 Outlook 125 -- 8.4.1 Cognition 125 -- 8.4.2 Mesh Topologies 127 -- 8.5 Conclusions 127 -- References 128 -- 9 Cooperation in Intrusion Detection Networks 133 / Carol Fung and Raouf Boutaba -- 9.1 Overview of Network Intrusions 133 -- 9.1.1 Single-Host Intrusion and Malware 133 -- 9.1.2 Distributed Attacks and Botnets 134 -- 9.1.3 Cooperative Attacks and Phishing 134 -- 9.2 Intrusion Detection Systems 135 -- 9.2.1 Signature-Based and Anomaly-Based IDSs 135 -- 9.2.2 Host-Based and Network-Based IDSs 135 -- 9.3 Cooperation in Intrusion Detection Networks 136 -- 9.3.1 Cooperation Topology 136 -- 9.3.2 Cooperation Scope 137 -- 9.3.3 Specialization 137 -- 9.3.4 Cooperation Technologies and Algorithms 137 -- 9.3.5 Taxonomy 138 -- 9.4 Selected Intrusion Detection Networks 139 -- 9.4.1 Indra 139 -- 9.4.2 DOMINO 139 -- 9.4.3 DShield 140 -- 9.4.4 NetShield 140 -- 9.4.5 Gossip 141 -- 9.4.6 Worminator 142 -- 9.4.7 ABDIAS 142 -- 9.4.8 CRIM 142 -- 9.4.9 HBCIDS 143 -- 9.4.10 ALPACAS 143 -- 9.4.11 CDDHT 143 -- 9.4.12 SmartScreen Filter 143 -- 9.4.13 FFCIDN 144 -- 9.5 Open Challenges and Future Directions 144 -- 9.6 Conclusion 144 -- References 144 -- 10 Cooperation Link Level Retransmission in Wireless Networks 147 / Mehrdad Dianati, Xuemin (Sherman) Shen and Kshirasagar Naik -- 10.1 Introduction 147 -- 10.2 Background 149 -- 10.2.1 Modeling of Fading Channels 149 -- 10.2.2 Automatic Repeat Request 152 -- 10.3 System Model 154 -- 10.4 Protocol Model 155 -- 10.5 Node Cooperative SW Scheme 156 -- 10.6 Performance Analysis 157 -- 10.7 Delay Analysis 164 -- 10.8 Verification of Analytical Models 168. 10.8.1 Throughput 169 -- 10.8.2 Average Delay and Delay Jitter 171 -- 10.9 Discussion of the Related Works 172 -- 10.10 Summary 174 -- 10.11 Acknowledgement 174 -- References 175 -- 11 Cooperative Inter-Node and Inter-Layer Optimization of Network Protocols 177 / D. Kliazovich, F. Granelli and N. L. S. da Fonseca -- 11.1 Introduction 177 -- 11.2 A Framework for Cooperative Configuration and Optimization 178 -- 11.2.1 Tuning TCP/IP Parameters 178 -- 11.2.2 Cooperative Optimization Architecture 179 -- 11.3 Cooperative Optimization Design 181 -- 11.3.1 Inter-Layer Cooperative Optimization 181 -- 11.3.2 Inter-Node Cooperative Optimization 183 -- 11.4 A Test Case: TCP Optimization Using a Cooperative Framework 184 -- 11.4.1 Implementation 184 -- 11.4.2 Inter-Layer Cognitive Optimization 186 -- 11.4.3 Inter-Node Cognitive Optimization 187 -- 11.5 Conclusions 189 -- References 189 -- 12 Cooperative Network Coding 191 / H. Rashvand, C. Khirallah, V. Stankovic and L. Stankovic -- 12.1 Introduction 191 -- 12.2 Network Coding Concept 192 -- 12.2.1 Example 192 -- 12.3 Cooperative Relay 195 -- 12.4 Cooperation Strategies 196 -- 12.4.1 Performance Measures 197 -- 12.5 Cooperative Network Coding 206 -- 12.6 Conclusions 214 -- References 214 -- 13 Cooperative Caching for Chip Multiprocessors 217 / J. Chang, E. Herrero, R. Canal and G. Sohi -- 13.1 Caching and Chip Multiprocessors 217 -- 13.1.1 Caching Background 217 -- 13.1.2 CMP (Chip Multiprocessor) 218 -- 13.1.3 CMP Caching Challenges 218 -- 13.2 Cooperative Caching and CMP Caching 220 -- 13.2.1 Motivation for Cooperative Caching 220 -- 13.2.2 The Unique Aspects of Cooperative Caching 220 -- 13.2.3 CMP Cache Partitioning Schemes 225 -- 13.2.4 A Taxonomy of CMP Caching Techniques 226 -- 13.3 CMP Cooperative Caching Framework 226 -- 13.3.1 CMP Cooperative Caching Framework 227 -- 13.3.2 CC Mechanisms 229 -- 13.3.3 CC Implementations 234 -- 13.3.4 CC for Large Scale CMPs 241 -- 13.3.5 Distributed Cooperative Caching 243 -- 13.3.6 Summary 249. 13.4 CMP Cooperative Caching Applications 251 -- 13.4.1 CMP Cooperative Caching for Latency Reduction 252 -- 13.4.2 CMP Cooperative Caching for Adaptive Repartitioning 259 -- 13.4.3 CMP Cooperative Caching for Performance Isolation 262 -- 13.5 Summary 269 -- References 270 -- 14 Market-Oriented Resource Management and Scheduling: A Taxonomy and Survey 277 / Saurabh Kumar Garg and Rajkumar Buyya -- 14.1 Introduction 277 -- 14.2 Overview of Utility Grids and Preliminaries 277 -- 14.3 Requirements 279 -- 14.3.1 Consumer Side Requirements 279 -- 14.3.2 Resource Provider Side Requirements 280 -- 14.3.3 Market Exchange Requirements 280 -- 14.4 Utility Grid Infrastructural Components 282 -- 14.5 Taxonomy of Market-Oriented Scheduling 283 -- 14.5.1 Market Model 284 -- 14.5.2 Allocation Decision 288 -- 14.5.3 Participant Focus 288 -- 14.5.4 Application Type 288 -- 14.5.5 Allocation Objective 289 -- 14.6 Survey of Grid Resource Management Systems 289 -- 14.6.1 Survey of Market-Oriented Systems 289 -- 14.6.2 System-Oriented Schedulers 296 -- 14.7 Discussion and Gap Analysis 300 -- 14.7.1 Scheduling Mechanisms 300 -- 14.7.2 Market Based Systems 301 -- 14.8 Summary 302 -- References 303 -- Glossary 307 -- Index 319. |
| Record Nr. | UNINA-9910811956403321 |
|
Obaidat Mohammad S
|
||
| Chichester, West Sussex, U.K. ; , : Wiley, , 2011 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
ICOF 2016 : 19th International Conference on OFDM and Frequency Domain Techniques : 25-26 August 2016
| ICOF 2016 : 19th International Conference on OFDM and Frequency Domain Techniques : 25-26 August 2016 |
| Pubbl/distr/stampa | Frankfurt am Main, Germany : , : VDE, , 2016 |
| Descrizione fisica | 1 online resource (214 pages) |
| Disciplina | 539.2 |
| Soggetto topico |
Orthogonal frequency division multiplexing
Electromagnetic waves MIMO systems |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNISA-996279831303316 |
| Frankfurt am Main, Germany : , : VDE, , 2016 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. di Salerno | ||
| ||
