دانلود کتاب Adaptive Switching Control of Large-Scale Complex Power Systems: Theory and Applications

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Preface
Contents
Acronyms
Part I Switching Control Based on Bang-Bang Funnel Controller and Stability Analysis Methods
1 Switching Control of Impulsively Disturbed Nonlinear Systems Based on Bang-Bang Constant Funnel Controller
1.1 Impulsively Disturbed Nonlinear System and Feasibility Assumptions of the Switching Controller
1.1.1 Bang-Bang Constant Funnel Controller
1.1.2 Feasibility Assumptions of the Switching Controller
1.1.3 Description of Impulsive Disturbance
1.2 IDRA of the Nonlinear System Controlled by SC
1.2.1 Main Results on IDRA of Impulsively Disturbed Nonlinear Systems
1.2.2 State-Dependent Switching Strategy mathscrT of SC
1.2.3 Control Law of BCFC
1.2.4 Solution Framework of the Closed-Loop System Consisting of the Nonlinear System and Its SC
1.3 Proof of Main Results
1.3.1 Boundary Values of e(i)(t) (i=0, 1, …, r-1) and Their Recovery Time of the Impulsively Disturbed Nonlinear System Controlled by BCFC
1.3.2 Preliminaries for the Proof of Main Results
1.3.3 Proof of Theorem 1.1
1.3.4 Proof of Theorem 1.2
1.4 Simulation Studies: Application of BCFC and SC for Frequency Control of a SMIB Power System
1.4.1 Excitation Controller Designed Based on BBFC
1.4.2 Excitation Controller Designed Based on SC
1.5 Summary
References
2 Observer-Based Robust Bang-Bang Funnel Controller and Its Stability in Closed-Loop Systems
2.1 Introduction to Bang-Bang Funnel Control and Main Results on Closed-Loop Stability
2.1.1 System Description
2.1.2 Bang-Bang Funnel Control
2.1.3 High-Gain State Observer
2.1.4 Assumptions of RBC
2.1.5 Main Results on Convergence of Estimation Error and Closed-Loop Stability
2.2 Proof of Convergence of Estimation Errors of High-Gain Observer
2.3 Proof of Stability of Closed-Loop System
2.3.1 Dynamics of RBC Outside Error Funnels
2.4 Simulation Studies: Application of RBC for Frequency Control of a SMIB Test System
2.5 Summary
References
Part II Transient Stability Control of Large-Scale Complex Power Systems Based On Adaptive Switching Controllers
3 Switching Control of Synchronous Generators for Transient Stability Enhancement
3.1 Design of Switching Power System Stabilizer
3.1.1 Power System Model Used for Designing SPSS
3.1.2 Design of SPSS
3.1.3 Closed-Loop Stability
3.2 Design of Switching Excitation Controller and Switching Governor
3.2.1 Power System Model Used for Designing SEC and SG
3.2.2 Design of SEC and SG
3.3 Simulation Studies
3.3.1 Test Results of SPSS
3.3.2 Test Results of SEC and SG
3.4 Summary
References
4 Switching Control of Modular Multi-level Converters in High-Voltage-Direct-Current Transmission Systems Via BBFC-Based SCU
4.1 Model of a MMC-HVDC Transmission System
4.1.1 Model of a MMC
4.1.2 Outer-Loop Controllers of a VC for Rectifier-Side MMC
4.1.3 Outer-Loop Controllers of a VC for Inverter-Side MMC
4.1.4 Inner-Loop Current Controllers of a VC
4.2 Bang-Bang Funnel Controller and Its Applications in Control of MMCs
4.2.1 Bang-Bang Funnel Controller with Neutral Output
4.2.2 BBFCs of SCUs for Rectifier-Side MMC and Inverter-Side MMC
4.3 Switching Laws for Switching Control Units of FRTHCs
4.4 Simulation Studies
4.4.1 Fault Ride-Through Performance of a Two-Machine Test System in the Case of a Three-Phase-to-Ground Fault on the Rectifier-Side AC Grid
4.4.2 Fault Ride-Through Performance in a Two-Machine Test System in the Case that a Line-to-Line Fault Occurred on Inverter-Side AC Grid
4.4.3 Fault Ride-Through Performance in the Case of a Four-Machine Test Power System
4.4.4 Modal Analysis of the Four-Machine Thirteen Bus Test System Controlled by VC
4.5 Summary
References
5 Switching Control of Doubly-Fed Induction Generator-Based Wind Turbines for Transient Stability Enhancement of Wind Power Penetrated Power Systems
5.1 Multi-loop Switching Control of DFIG-Based Wind Turbine Systems
5.1.1 Model Linearization of DFIG-Based Wind Turbine System
5.1.2 Four-Loop Switching Controller Designed for DFIG-Based Wind Turbine System
5.2 Switching Angle Controller and AGC for Frequency Control of DFIG Based WPPS
5.2.1 Internal Voltage and Virtual Rotor Angle of DFIGs
5.2.2 Design of SAC and AGC
5.2.3 Modal Analysis of DFIGs with SAC and AGC
5.3 Simulation Studies
5.3.1 Test Results of the Four-Loop Switching Controller
5.3.2 Test Results of the Switching Angle Controller and AGC
5.4 Summary
References
6 Adaptive Switching Control of Power Electronic Converters
6.1 Switching Fault Ride-Through of GSCs via …
6.1.1 Design of SFRTC
6.2 Bang-Bang Funnel Control of Three-phase …
6.2.1 Introduction to Dual-Buck Scheme
6.2.2 Bang-Bang Funnel Control of the Inverter
6.3 Experiment and Simulation Results
6.3.1 Test Results of the Switching Fault Ride-Through Controller for GSCs
6.3.2 Test Results of the Bang-Bang Funnel Controller of the Three-Phase Full-Bridge Inverter
6.4 Summary
References