| Description |
1 online resource (1 volume) : illustrations |
| Bibliography |
Includes bibliographical references and index. |
| Summary |
"An introduction to the technical details related to physical layer modeling of the LTE standard with MATLAB"-- Provided by publisher |
| Contents |
Preface xiii -- List of Abbreviations xvii -- 1 Introduction 1 -- 1.1 Quick Overview of Wireless Standards 1 -- 1.2 Historical Profile of Data Rates 4 -- 1.3 IMT-Advanced Requirements 4 -- 1.4 3GPP and LTE Standardization 5 -- 1.5 LTE Requirements 5 -- 1.6 Theoretical Strategies 6 -- 1.7 LTE-Enabling Technologies 7 -- 1.8 LTE Physical Layer (PHY) Modeling 9 -- 1.9 LTE (Releases 8 and 9) 11 -- 1.10 LTE-Advanced (Release 10) 11 -- 1.11 MATLAB(R) and Wireless System Design 11 -- 1.12 Organization of This Book 11 -- References 12 -- 2 Overview of the LTE Physical Layer 13 -- 2.1 Air Interface 13 -- 2.2 Frequency Bands 14 -- 2.3 Unicast and Multicast Services 14 -- 2.4 Allocation of Bandwidth 16 -- 2.5 Time Framing 17 -- 2.6 Time / Frequency Representation 17 -- 2.7 OFDM Multicarrier Transmission 20 -- 2.8 Single-Carrier Frequency Division Multiplexing 23 -- 2.9 Resource Grid Content 24 -- 2.10 Physical Channels 25 -- 2.11 Physical Signals 31 -- 2.12 Downlink Frame Structures 34 -- 2.13 Uplink Frame Structures 35 -- 2.14 MIMO 35 -- 2.15 MIMO Modes 40 -- 2.16 PHY Processing 41 -- 2.17 Downlink Processing 41 -- 2.18 Uplink Processing 43 -- 2.19 Chapter Summary 45 -- References 46 -- 3 MATLAB(R) for Communications System Design 47 -- 3.1 System Development Workflow 47 -- 3.2 Challenges and Capabilities 48 -- 3.3 Focus 49 -- 3.4 Approach 49 -- 3.5 PHY Models in MATLAB 49 -- 3.6 MATLAB 49 -- 3.7 MATLAB Toolboxes 50 -- 3.8 Simulink 51 -- 3.9 Modeling and Simulation 52 -- 3.10 Prototyping and Implementation 53 -- 3.11 Introduction to System Objects 54 -- 3.12 MATLAB Channel Coding Examples 60 -- 3.13 Chapter Summary 68 -- References 69 -- 4 Modulation and Coding 71 -- 4.1 Modulation Schemes of LTE 72 -- 4.2 Bit-Level Scrambling 79 -- 4.3 Channel Coding 85 -- 4.4 Turbo Coding 85 -- 4.5 Early-Termination Mechanism 93 -- 4.6 Rate Matching 99 -- 4.7 Codeblock Segmentation 105 -- 4.8 LTE Transport-Channel Processing 107 -- 4.9 Chapter Summary 112 -- References 113 -- 5 OFDM 115 -- 5.1 Channel Modeling 115. |
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Examples 117 -- 5.2 Scope 121 -- 5.3 Workflow 121 -- 5.4 OFDM and Multipath Fading 122 -- 5.5 OFDM and Channel-Response Estimation 123 -- 5.6 Frequency-Domain Equalization 124 -- 5.7 LTE Resource Grid 124 -- 5.8 Configuring the Resource Grid 125 -- 5.9 Generating Reference Signals 130 -- 5.10 Resource Element Mapping 132 -- 5.11 OFDM Signal Generation 136 -- 5.12 Channel Modeling 137 -- 5.13 OFDM Receiver 140 -- 5.14 Resource Element Demapping 141 -- 5.15 Channel Estimation 143 -- 5.16 Equalizer Gain Computation 145 -- 5.17 Visualizing the Channel 146 -- 5.18 Downlink Transmission Mode 1 147 -- 5.19 Chapter Summary 164 -- References 165 -- 6 MIMO 167 -- 6.1 Definition of MIMO 167 -- 6.2 Motivation for MIMO 168 -- 6.3 Types of MIMO 168 -- 6.4 Scope of MIMO Coverage 170 -- 6.5 MIMO Channels 170 -- Implementation 171 -- 6.6 Common MIMO Features 178 -- 6.7 Specific MIMO Features 197 -- 6.8 Chapter Summary 260 -- References 262 -- 7 Link Adaptation 263 -- 7.1 System Model 264 -- 7.2 Link Adaptation in LTE 265 -- 7.3 MATLAB(R) Examples 266 -- 7.4 Link Adaptations between Subframes 275 -- 7.5 Adaptive Modulation 277 -- 7.6 Adaptive Modulation and Coding Rate 283 -- 7.7 Adaptive Precoding 287 -- 7.8 Adaptive MIMO 291 -- 7.9 Downlink Control Information 294 -- 7.10 Chapter Summary 302 -- References 303 -- 8 System-Level Specification 305 -- 8.1 System Model 306 -- 8.2 System Model in MATLAB 315 -- 8.3 Quantitative Assessments 316 -- 8.4 Throughput Analysis 325 -- 8.5 System Model in Simulink 326 -- 8.6 Qualitative Assessment 349 -- 8.7 Chapter Summary 351 -- References 352 -- 9 Simulation 353 -- 9.1 Speeding Up Simulations in MATLAB 353 -- 9.2 Workflow 354 -- 9.3 Case Study: LTE PDCCH Processing 355 -- 9.4 Baseline Algorithm 356 -- 9.5 MATLAB Code Profiling 358 -- 9.6 MATLAB Code Optimizations 360 -- 9.7 Using Acceleration Features 383 -- 9.8 Using a Simulink Model 387 -- 9.9 GPU Processing 399 -- 9.10 Case Study: Turbo Coders on GPU 406 -- 9.11 Chapter Summary 419 -- 10 Prototyping as C/C++ Code 421. |
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10.1 Use Cases 422 -- 10.2 Motivations 422 -- 10.3 Requirements 422 -- 10.4 MATLAB Code Considerations 423 -- 10.5 How to Generate Code 423 -- 10.6 Structure of the Generated C Code 429 -- 10.7 Supported MATLAB Subset 432 -- 10.8 Complex Numbers and Native C Types 436 -- 10.9 Support for System Toolboxes 438 -- 10.10 Support for Fixed-Point Data 444 -- 10.11 Support for Variable-Sized Data 447 -- 10.12 Integration with Existing C/C++ Code 458 -- 10.13 Chapter Summary 471 -- References 471 -- 11 Summary 473 -- 11.1 Modeling 473 -- 11.2 Simulation 476 -- 11.3 Directions for Future Work 477 -- 11.4 Concluding Remarks 480 -- Index 483. |
| Subject |
MATLAB.
|
|
MATLAB |
|
Long-Term Evolution (Telecommunications) -- Computer simulation.
|
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Technologie d'évolution à long terme (Norme) -- Simulation par ordinateur. |
| Added Title |
Understanding Long-Term Evolution with MATLAB |
| Other Form: |
Print version: Zarrinkoub, Houman. Understanding LTE with MATLAB. Chichester, West Sussex, United Kingdom : Wiley, [2014] 9781118443415 (DLC) 2013034138 (OCoLC)856902914 |
| ISBN |
9781118443453 |
|
1118443454 |
|
1118443411 |
|
9781118443415 |
|
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