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Connected Vehicular Systems. Communication, Control, and Optimization. Edition No. 1

  • Book

  • 336 Pages
  • October 2023
  • John Wiley and Sons Ltd
  • ID: 5878907
CONNECTED VEHICULAR SYSTEMS

A framework for the analysis and design of connected vehicle systems, featuring numerous simulations, experimental studies, and problem-solving approaches

Connected Vehicular Systems synthesizes the research advances of the past decade to provide readers with practical tools to analyze and design all aspects of connected autonomous vehicle systems, addressing a series of major issues and challenges in autonomous connected vehicles and transportation systems, such as sensing, communication, control design, and command actuating. The text provides direct methodologies for solving important problems such as speed planning, cooperative adaptive cruise control, platooning, and string traffic flow stability, with numerous simulations and experimental studies for implementing algorithms and parameter settings.

To help the reader better understand and implement the concepts discussed, the text includes a variety of worked examples, including those related to car following, vehicular platooning problem, string stability, cooperative adaptive cruise control, and vehicular communications.

Written by two highly qualified academics with significant experience in the field, Connected Vehicular Systems includes information on: - Varying communication ranges, interruptions, and topologies, along with controls for event-triggered communication - Fault-tolerant and adaptive fault-tolerant controls with actuator saturation, input quantization, and dead-zone nonlinearity - Prescribed performance concurrent controls, adaptive sliding mode controls, and speed planning for various scenarios, such as to reduce inter-vehicle spacing - Control paradigms aimed at relaxing communications constraints and optimizing system performance - Detailed algorithms and parameter settings that readers can implement in their own work to drive progress in the field

Connected Vehicular Systems is an essential resource on the subject for mechanical and automotive engineers and researchers involved with the design and development of self-driving cars and intelligent transportation systems, along with graduate students in courses that cover vehicle controls within the context of control systems or vehicular systems engineering.

Table of Contents

Preface ix

Acknowledgments xiii

Part I Vehicular Platoon Communication and Control 1

1 Control with Varying Communication Range 3

1.1 Introduction 3

1.2 Problem Formulation 5

1.3 Switching Control of Connected Vehicles 9

1.4 Simulations and Experiments 16

1.5 Conclusions and Future Work 23

References 24

2 Control Subject to Communication Interruptions 26

2.1 Introduction 26

2.2 Problem Formulation 27

2.3 Mixed CACC-ACC Control 28

2.4 Finite-Time Sliding-Mode Control 32

2.5 Numerical Simulations 34

2.6 Conclusions and Future Work 39

References 41

3 Control and Communication Topology Assignment 42

3.1 Introduction 42

3.2 Problem Statement 44

3.3 Communication Topology and Control Co-Design 48

3.4 Simulation Studies 57

3.5 Conclusions and Future Work 70

References 70

4 Control with Communication Delay and Switching Topologies 72

4.1 Introduction 72

4.2 Problem Formulation 73

4.3 Stability Analysis 77

4.4 Controller Synthesis 82

4.5 Simulation Studies 86

4.6 Conclusions and Future Work 95

References 96

5 Control with Event-Triggered Communication 97

5.1 Introduction 97

5.2 Problem Formulation 99

5.3 Event-Triggered Communication and Platoon Control 104

5.4 Simulation Study 107

5.5 Conclusions and Future Work 119

References 120

Part II Performance Guarantee Under Actuator Limitation 121

6 Adaptive Fault-Tolerant Control with Actuator Saturation 123

6.1 Introduction 123

6.2 System Modeling and Problem Formulation 124

6.3 Quadratic Spacing Policy and Adaptive PID-Type Sliding Surface 127

6.4 Controller Design and Stability and Analysis 128

6.5 Simulation Results 135

6.6 Conclusions and Future Work 139

References 142

7 Fault-Tolerant Control with Input Quantization and Dead Zone 143

7.1 Introduction 143

7.2 System Modeling and Problem Formulation 144

7.3 Improved Quadratic Spacing Policy and Adaptive PID-Type Sliding Surface 148

7.4 Controller Design and Stability Analysis 149

7.5 Simulation Results 155

7.6 Conclusions and Future Work 157

References 163

8 Prescribed Performance Concurrent Control 165

8.1 Introduction 165

8.2 Problem Formulation 166

8.3 Controller Design Guaranteed Prescribed Performance 168

8.4 Simulation Studies 175

8.5 Conclusions and Future Work 179

References 179

9 Adaptive Sliding Mode Control with Prescribed Performance 181

9.1 Introduction 181

9.2 Problem Formulation 181

9.3 Model Transformation 184

9.4 Vehicles Tracking Controller Design 185

9.5 Simulation Studies 190

9.6 Conclusions and Future Work 197

References 198

Part III Speed Trajectory Planning and Control 199

10 Speed Planning and Tracking Control of Vehicles 201

10.1 Introduction 201

10.2 Problem Formulations 202

10.3 Speed Planning 205

10.4 Speed Tracking Controller Design 207

10.5 Simulation and Experiments 213

10.6 Conclusions and Future Work 221

References 224

11 Analytical Solution for Speed Planning and Tracking Control 225

11.1 Introduction 225

11.2 System Modeling and Problem Formulation 226

11.3 Speed Optimization Based on PMP 228

11.4 Speed Tracking Control and String Stability 232

11.5 Simulation Studies 237

11.6 Conclusions and Future Work 240

References 241

12 Speed Planning and Sliding-Mode Control to Reduce Intervehicle Spacing 242

12.1 Introduction 242

12.2 Problem Statement 243

12.3 Intervehicle Spacing Optimization 246

12.4 Sliding-Mode Controller Design 250

12.5 Simulation Studies 253

12.6 Conclusions and Future Work 265

References 266

13 Trajectory Planning and PID-Type Sliding-Mode Control to Reduce Intervehicle Spacing 268

13.1 Introduction 268

13.2 Problem Description 269

13.3 Distributed Trajectory Optimization 271

13.4 PID-Type Sliding-Mode Controller Design 275

13.5 Simulation Results 278

13.6 Conclusions and Future Work 288

References 288

14 Trajectory Planning and Fixed-Time Terminal Sliding-Mode Control 290

14.1 Introduction 290

14.2 Problem Formulation 291

14.3 Vehicles Trajectory Optimization 293

14.4 Fixed-Time Tracking Control Design 297

14.5 Numerical Simulations 301

14.6 Conclusions and Future Work 307

References 307

Index 309

Authors

Ge Guo Northeastern University, China. Shixi Wen Dalian University, China.