Zhong, Wenxing.
Wireless Power Transfer Between Distance and Efficiency / [electronic resource] : by Wenxing Zhong, Dehong Xu, Ron Shu Yuen Hui. - 1st ed. 2020. - X, 135 p. 109 illus., 70 illus. in color. online resource. - CPSS Power Electronics Series, 2520-8861 . - CPSS Power Electronics Series, .
Introduction of WPT -- Application of WPT -- Basic Theories -- General Modeling of Multi-Resonator WPT Systems -- Straight Domino-Resonator WPT -- Circular Domino-Resonator WPT -- Optimization of Dual-Receiver System -- Designing a Three-Coil System -- Designing a Dual-Frequency Dual-Receiver System -- Introduction on Maximizing WPT Efficiency -- Maximum Efficiency Point Tracking -- Using On-Off Keying Modulation for Impedance Transformation -- Designing a Reconfigurable WPT System -- Designing a Charging Time Control WPT System. .
Focusing on inductive wireless power transfer (WPT), which relies on coil resonators and power converters, this book begins by providing the background and basic theories of WPT, which are essential for newcomers to the field. Then two major challenges of WPT – power transfer distance and efficiency – are subsequently addressed, and multi-resonator WPT systems, which not only offer a way to extend power transfer distance but also provide more flexibility, are investigated. Recent findings on techniques to maximize the power transfer efficiency of WPT systems, e.g. maximum efficiency point tracking, are also introduced. Without the constraint of cables, wireless power transfer (WPT) is an elegant technique for charging or powering a range of electrical devices, e.g. electric vehicles, mobile phones, artificial hearts, etc. Given its depth of coverage, the book can serve as a technical guideline or reference guide for engineers and researchers working on WPT.
9789811524417
10.1007/978-981-15-2441-7 doi
Electric power production.
Electronic circuits.
Electronics.
Electrical Power Engineering.
Electronic Circuits and Systems.
Electronics and Microelectronics, Instrumentation.
Mechanical Power Engineering.
TK1001-1841
621.31
Wireless Power Transfer Between Distance and Efficiency / [electronic resource] : by Wenxing Zhong, Dehong Xu, Ron Shu Yuen Hui. - 1st ed. 2020. - X, 135 p. 109 illus., 70 illus. in color. online resource. - CPSS Power Electronics Series, 2520-8861 . - CPSS Power Electronics Series, .
Introduction of WPT -- Application of WPT -- Basic Theories -- General Modeling of Multi-Resonator WPT Systems -- Straight Domino-Resonator WPT -- Circular Domino-Resonator WPT -- Optimization of Dual-Receiver System -- Designing a Three-Coil System -- Designing a Dual-Frequency Dual-Receiver System -- Introduction on Maximizing WPT Efficiency -- Maximum Efficiency Point Tracking -- Using On-Off Keying Modulation for Impedance Transformation -- Designing a Reconfigurable WPT System -- Designing a Charging Time Control WPT System. .
Focusing on inductive wireless power transfer (WPT), which relies on coil resonators and power converters, this book begins by providing the background and basic theories of WPT, which are essential for newcomers to the field. Then two major challenges of WPT – power transfer distance and efficiency – are subsequently addressed, and multi-resonator WPT systems, which not only offer a way to extend power transfer distance but also provide more flexibility, are investigated. Recent findings on techniques to maximize the power transfer efficiency of WPT systems, e.g. maximum efficiency point tracking, are also introduced. Without the constraint of cables, wireless power transfer (WPT) is an elegant technique for charging or powering a range of electrical devices, e.g. electric vehicles, mobile phones, artificial hearts, etc. Given its depth of coverage, the book can serve as a technical guideline or reference guide for engineers and researchers working on WPT.
9789811524417
10.1007/978-981-15-2441-7 doi
Electric power production.
Electronic circuits.
Electronics.
Electrical Power Engineering.
Electronic Circuits and Systems.
Electronics and Microelectronics, Instrumentation.
Mechanical Power Engineering.
TK1001-1841
621.31