Advanced Wireless Technologies for Industrial Network Systems

Preface
Acknowledgments
Contents
Acronyms
List of Figures
List of Tables
1 Introduction
1.1 An Overview of Industrial Network Systems
1.1.1 Concept of Industrial Network System
1.1.2 Architecture of Industrial Network System
1.1.3 Applications of Industrial Network System
1.2 Sensing and Control in Industrial Network System
1.2.1 Sensing over Wireless Network
1.2.2 Control over Wireless Network
1.2.3 Sensing and Control Challenges
1.3 Organization of the Monograph
References
2 Advanced Wireless Technologies for Industrial Automation
2.1 High-throughput Data Transmission Technology
2.1.1 Massive Multiple Input Multiple Output
2.1.2 mm-Wave and 60GHz
2.1.3 THz Radio Communication
2.2 Spectrum Constrained Efficient Transmission
2.2.1 Diversity Gain Enabled Transmission
2.2.2 Non-orthogonal Multiple Access Based Transmission
2.2.3 Cognitive Radio Assisted Transmission
2.3 Energy Balanced Efficient Transmission
2.3.1 Power Control Based Transmission
2.3.2 Sleeping Control Based Transmission
2.3.3 Energy Harvesting Assisted Transmission
References
3 Sensing and Control Oriented Transmission for Industrial Network Systems
3.1 Introduction
3.2 Related Work
3.2.1 Sensing and Control Strategy Design over Wireless Networks
3.2.2 Efficient Transmission Technique
3.3 Problem Statement
3.3.1 Control System Model
3.3.2 Wireless Communication Model
3.3.3 Challenges and Design Goals
3.4 Cooperative Transmission Scheme for Industrial Network Systems
3.4.1 Overview of Cooperative Transmission
3.4.1.1 The Transmission Process of Sensing Information
3.4.1.2 The Transmission Process of Control Information
3.4.2 Spatial Diversity Based Cooperative Transmission
3.4.3 Beamforming Based Multi-point Cooperative Transmission
3.5 Performance Evaluation
3.5.1 Performance Evaluation for Spatial Diversity Based Cooperative Transmission
3.5.2 Performance Evaluation for Beamforming Based Multi-point Cooperative Transmission
3.5.3 Performance Comparison
3.6 Summary
References
4 Edge-assisted Transmission for 5G Enabled Industrial Network Systems
4.1 Introduction
4.2 Related Work
4.2.1 State Estimation over Wireless Networks
4.2.2 Control over Wireless Networks
4.3 Problem Statement
4.3.1 Control System Model
4.3.2 Wireless Communication Model
4.3.3 Challenges and Design Goals
4.4 Edge-assisted Transmission Scheme for Industrial Network
4.4.1 Overview of Hierarchical Sensing and Decentralized Control
4.4.1.1 Hierarchical Sensing
4.4.1.2 Decentralized Control
4.4.2 Edge-assisted Transmission for Hierarchical Sensing
4.4.3 Edge-assisted Transmission for Decentralized Control
4.5 Performance Evaluation
4.5.1 Performance Evaluation for the Edge-assisted Transmission for Hierarchical Sensing
4.5.2 Performance Evaluation for the Edge-assisted Transmission for Decentralized Control
4.6 Summary
References
5 Spectrum Constrained Efficient Transmission for Industrial Network Systems
5.1 Introduction
5.2 Related Work
5.3 Problem Statement
5.3.1 Control System Model
5.3.2 Wireless Communication Model
5.3.3 Challenges and Design Goals
5.4 Spectrum Efficient Transmission Scheme for Heterogeneous Sensing Tasks
5.4.1 Overview of Spectrum Efficient Transmission
5.4.2 Non-orthogonal Multiple Access Based Efficient Transmission
5.4.3 Spectrum Harvesting Based Transmission for Multi-priority Sensing Tasks
5.5 Performance Evaluation
5.5.1 Performance Evaluation for NOMA Based Effective Transmission
5.5.2 Performance Evaluation for Spectrum Harvesting Based Effective Transmission
5.6 Summary
References
6 Conclusions and Future Works
6.1 Conclusions
6.2 Open Issues for Further Research
6.2.1 Joint Design and Optimization of Sensing, Transmission, and Control
6.2.2 Delay-Constrained Transmission Design for Sensing and Control
6.2.3 Secure Transmission for Industrial Network Systems with Eavesdroppers
References
Index