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Table of Contents
Preface; Contents; About the Authors; Acronyms; 1 Introduction; 1.1 Constant Power Loads: Sources, Behaviour and Effects; 1.2 Stability of a Simple dc Power System with CPL; 1.3 Small-Signal Stability of Basic DC/DC Converters with CPL; 1.3.1 Buck Converter; 1.3.2 Boost Converter; 1.3.3 Buck-Boost Converter; 1.3.4 Bidirectional Buck-Boost Converter; 1.4 Stability of a DC Microgrid with CPL; 1.5 Review of Literature; 1.5.1 Passive Damping; 1.5.2 Active Damping; 1.5.3 Feedback Linearization; 1.5.4 Pulse Adjustment; 1.5.5 Digital Charge Control; 1.5.6 Sliding Mode Control.
1.5.7 Synergetic Control1.5.8 Passivity Based Control; 1.5.9 Power Shaping Stabilization; 1.5.10 Coupling Based Techniques; 1.5.11 State-Space Pole Placement; 1.5.12 New Converter Topologies; 1.6 Motivation; 1.7 Organization of the Book; References; 2 Stabilization of a Buck Converter Feeding a Mixed Load Using SMC; 2.1 Mathematical Modeling of Buck Converter with Mixed Load; 2.2 Sliding Mode Control Design; 2.2.1 Discontinuous SMC; 2.2.2 PWM Based SMC; 2.2.3 Simulation Studies; 2.2.4 Experimental Validation; 2.3 Summary; References.
3 Mitigation of Destabilizing Effects of CPL in a Boost Converter Feeding Total CPL3.1 Mitigation of CPL Effects in Boost Converter Using SMC; 3.1.1 System Modeling of Boost Converter with CPL; 3.1.2 Design of PWM Based SMC; 3.1.3 Existence of Sliding Mode and Stability of Surface; 3.1.4 Validation of the Proposed Controller; 3.2 Mitigation of CPL Effects Using SMC Designed #x83;; 3.2.1 Modified Switching Function; 3.2.2 Discontinuous SMC Using Modified Switching Function; 3.2.3 Existence of Sliding Mode with Discontinuous SMC; 3.2.4 Stability of Modified Switching Surface.
3.2.5 Real-Time Simulation Studies3.2.6 Experimental Validation of the Proposed SMC; 3.3 Summary; References; 4 Compensation of CPL Effects in a Bidirectional Buck-Boost Converter; 4.1 Compensation of CPL in a Bidirectional DC/DC Converter; 4.1.1 Modeling of Bidirectional DC/DC Converter; 4.1.2 Sliding Mode Control Design; 4.1.3 Real-Time Simulation Studies; 4.2 Summary; References; 5 Robust Control of an Islanded DC Microgrid in Presence of CPL; 5.1 Robust Control of a PV Based DC Microgrid; 5.1.1 Test System and Its Operating Modes; 5.1.2 Mathematical Modeling of Island DC Microgrid.
5.1.3 Sliding Mode Control Design5.1.4 Stability on Switching Surface; 5.1.5 Simulation Studies and Experimental Results; 5.2 Summary; References; Index.
1.5.7 Synergetic Control1.5.8 Passivity Based Control; 1.5.9 Power Shaping Stabilization; 1.5.10 Coupling Based Techniques; 1.5.11 State-Space Pole Placement; 1.5.12 New Converter Topologies; 1.6 Motivation; 1.7 Organization of the Book; References; 2 Stabilization of a Buck Converter Feeding a Mixed Load Using SMC; 2.1 Mathematical Modeling of Buck Converter with Mixed Load; 2.2 Sliding Mode Control Design; 2.2.1 Discontinuous SMC; 2.2.2 PWM Based SMC; 2.2.3 Simulation Studies; 2.2.4 Experimental Validation; 2.3 Summary; References.
3 Mitigation of Destabilizing Effects of CPL in a Boost Converter Feeding Total CPL3.1 Mitigation of CPL Effects in Boost Converter Using SMC; 3.1.1 System Modeling of Boost Converter with CPL; 3.1.2 Design of PWM Based SMC; 3.1.3 Existence of Sliding Mode and Stability of Surface; 3.1.4 Validation of the Proposed Controller; 3.2 Mitigation of CPL Effects Using SMC Designed #x83;; 3.2.1 Modified Switching Function; 3.2.2 Discontinuous SMC Using Modified Switching Function; 3.2.3 Existence of Sliding Mode with Discontinuous SMC; 3.2.4 Stability of Modified Switching Surface.
3.2.5 Real-Time Simulation Studies3.2.6 Experimental Validation of the Proposed SMC; 3.3 Summary; References; 4 Compensation of CPL Effects in a Bidirectional Buck-Boost Converter; 4.1 Compensation of CPL in a Bidirectional DC/DC Converter; 4.1.1 Modeling of Bidirectional DC/DC Converter; 4.1.2 Sliding Mode Control Design; 4.1.3 Real-Time Simulation Studies; 4.2 Summary; References; 5 Robust Control of an Islanded DC Microgrid in Presence of CPL; 5.1 Robust Control of a PV Based DC Microgrid; 5.1.1 Test System and Its Operating Modes; 5.1.2 Mathematical Modeling of Island DC Microgrid.
5.1.3 Sliding Mode Control Design5.1.4 Stability on Switching Surface; 5.1.5 Simulation Studies and Experimental Results; 5.2 Summary; References; Index.