- ホーム
- > 洋書
- > 英文書
- > Science / Mathematics
Full Description
Optimal Operation and Resilience Enhancement of Integrated Power and Transport Systems is a practical guidebook that builds your skills from fundamental principles to advanced applications, using actionable tools. This book supports a solid foundation in the principles of integrated power and transport, breaking down basic system structures, the fundamentals of key techniques such as game theory and variational inequality, and their function in optimization and resilience. Part II ensures the reader has a clear understanding of the design of such systems and key considerations from essential needs to the challenges of expansion, while parts III and IV outline the opportunities offered by cooperative and non-cooperative game theory. Special challenges are covered in part V, focusing on the major disruptions of adverse weather events and unpredictable demand. Providing a broad range of replicable and amendable methods, Optimal Operation and Resilience Enhancement of Integrated Power and Transport Systems supports readers in taking practical steps to improve resilience, sustainability, and responsive in integrated transport and energy systems.
Contents
Part I: Fundamentals
1. Introduction to Integrated Power and Transport Systems
2. Game Theory
3. Variational Inequality
4. Resilience of Integrated Power and Transport Systems
Part II: Design and Planning
5. Design and Planning of Integrated Power and Transport Systems
6. Robust Expansion Planning Model for Integrated Power and Transport Systems Considering Multiple Uncertainties
Part III: Optimal Operation under Non-Cooperative Game Theory
7. On Static Network Equilibrium of Integrated Power and Transport Systems: A Variational Inequality Approach
8. On Dynamic Network Equilibrium of Integrated Power and Transport Systems: A Differential Variational Inequality Approach
9. Nested Game Model for Integrated Power and Transport Systems Considering Demand Elasticity: A Quasi-Variational Inequality Approach
Part IV: Optimal Operation under Cooperative Game Theory
10. Collaborative Pricing in Integrated Power and Transport Systems: From Network Equilibrium to System Optimum
11. Decentralized Optimization of Multi-Area Integrated Power and Transport Systems Based on Variational Inequality
12. Robust Optimal Operation of Integrated Power and Transport Systems Considering Mixed Demand Uncertainties
Part V: Resilience Enhancement
13. Resilience Enhancement Strategies of Integrated Power and Transport Systems against Extreme Weather Events
14. Dynamic Load Restoration for Integrated Power and Transport Systems with Uncertain Travel Demands
