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The objective of this book is to publish the most recent technological advancements, and theoretical and practical research outcomes, alongside high-quality literature reviews on wireless power transfer to charge electric vehicles. More substantial research is proposed due to the fast-growing market for electric vehicles, and recent advances in wireless power transfer techniques have the potential to make this technology available for all consumers by overcoming its drawbacks. For instance, one of the major downsides to EVs is the requirement for an automobile to be idle during charging times. This problem can be solved by implementing dynamic wireless power transfer (WPT) with a higher power transfer efficiency (PTE). So, this book endeavors to create a major forum for investigating recent advances and the envisioned future in wireless power transfer for electric vehicles in terms of modeling, design, performance, operation, control, implementation, storage, electric machines, power electronics converters, optimization, cost, charging techniques, and applications. This book provides valuable contributions to the field of electric vehicles: inductive power transfer concepts; airport inductive charging infrastructures; the design of a wireless charging system for an e-bike with grid connection; control of renewables; social, economic, political, and technical factors for dynamic wireless charging; the influence of posture and coil position on the safety of a WPT; double-coil dynamic shielding technology for WPT; reduction in cogging torque in a PM brushless DC motor; and optimal dynamic scheduling of EVs in a parking lot.

Technology: general issues --- History of engineering & technology --- charging cost --- dynamic charging --- economics --- electric vehicles --- optimization --- parking lots --- static charging --- PMBLDC motor --- cogging torque --- finite element analysis --- virtual work method --- shifting angle --- electromagnetic field --- wireless power transfer --- shielding --- electric vehicle --- EMF safety --- numerical dosimetry --- wireless charging --- dynamic wireless power transfer --- EV charging infrastructure --- stakeholder engagement --- electric road systems --- system demand --- APF --- power quality --- SRF --- UPC --- VAR --- brushless doubly fed reluctance generator (BDFRG) --- crowbar --- symmetrical fault --- unsymmetrical fault --- wind turbine (WT) --- inductive power transfer --- e-bikes --- forward converter --- dynamic wireless charging --- airport apron --- airport infrastructure planning --- electric busses --- charging automation --- electric vehicles (EVs) --- wireless power transfer (WPT) --- production --- automation --- inductive power transfer (IPT) --- manufacturing

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Wireless power transfer allows the transfer of energy from a transmitter to a receiver across an air gap, without any electrical connections. Technically, any device that needs power can become an application for wireless power transmission. The current list of applications is therefore very diverse, from low-power portable electronics and household devices to high-power industrial automation and electric vehicles. With the rise of IoT sensor networks and Industry 4.0, the presence of wireless energy transfer will only increase. In order to improve the current state of the art, models are being developed and tested experimentally. Such models allow simulating, quantifying, predicting, or visualizing certain aspects of the power transfer from transmitter(s) to receiver(s). Moreover, they often result in a better understanding of the fundamentals of the wireless link. This book presents a wonderful collection of peer-reviewed papers that focus on the modelling of wireless power transmission. It covers both inductive and capacitive wireless coupling and includes work on multiple transmitters and/or receivers.

resonance-based wireless power transfer (R-WPT) --- resonance frequency --- power transfer efficiency (PTE) --- 3-coil system --- steady-state matrix analysis --- Class-E power amplifier --- wireless power transfer (WPT) system --- output characteristics --- strength --- coupling coefficient --- impedance matrix --- multiple coils --- mutual inductance --- scattering matrix --- transfer impedance --- wireless power transfer --- design optimization --- finite element analysis --- gallium nitride --- gradient methods --- inductive power transmission --- power measurement --- transformer cores --- wireless charging --- circuit modeling --- numerical analysis --- capacitive wireless power transfer --- resonance --- power-transfer efficiency --- multiports --- multiple-input single-output --- wireless power transmission --- electric field --- shielded-capacitive power transfer --- design guidelines --- resonant --- inductive coupling --- optimal load --- single-input multiple-output --- power gain

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This book focuses on emerging wireless power/data and energy harvesting technologies, and highlights their fundamental requirements, followed by recent advancements. It provides a various technical overview and analysis of key techniques for wireless power/data and energy harvesting system design. The state-of-the-art system introduced in this book will benefit designers looking to develop wireless power transfer and energy harvesting technologies in a variety of fields, such as wearable, implantable devices, home appliances, and electric vehicles.

Technology: general issues --- Energy industries & utilities --- wireless power transfer --- capacitive power transfer --- parallel-plate contactless power --- MIMO --- NOMA --- precoding --- power allocation --- user-clustering --- power splitter --- mobile sensor --- hopping sensor --- relocation protocol --- energy efficient protocol --- internet of things (IoTs) --- wireless sensor networks (WSNs) --- simulation --- inductive power --- dual impedance --- dual band --- reflected resistance --- frequency splitting --- multiple coils --- mutual inductance --- parasitic effect --- practical mutual inductance --- transfer impedance --- wearable heater --- inductive-power transmission --- textile coil --- impedance matching network --- parasitic resistance --- power loss --- reflection coefficient --- Smith chart --- cylindrical joint --- electromagnetic fields --- rotation-free structure --- soil sensing --- decision agriculture --- smart farming --- Wireless Power Transfer (WPT) --- compensation topology --- optimal load --- output power level --- electric vehicle (EV) --- capacitive power transfer (CPT) systems --- wireless power transfer (WPT) systems --- e-class inverter --- wireless resonance energy link system --- cognitive radio --- energy harvesting --- full-duplex relay --- simultaneous wireless information and power transfer (SWIPT) --- zero-forcing precoding --- shielded loop coil --- SAR --- coupled resonance --- coil resistance --- substrate size --- implantable biomedical microsystems --- data telemetry --- low power --- high data rate --- binary phase-shift keying demodulation --- electric vehicle --- center alignment point --- ferrite antenna --- laser wireless power transmission --- PV module --- maximum power point --- battery charging --- wirelessly-powered cage --- inductive power transmission --- implantable medical device --- animal experiment --- reference circuit --- inductive link --- implantable device --- line regulation --- wireless power telemetry --- supply independence --- balanced coil --- foreign object detection --- Maxwell bridge --- metal object detection --- wireless power transmission (WPT) --- power conversion efficiency (PCE) --- mm-sized implant --- duty cycle --- pulsed power transmission --- power transfer efficiency (PTE) --- rectifier

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This book focuses on emerging wireless power/data and energy harvesting technologies, and highlights their fundamental requirements, followed by recent advancements. It provides a various technical overview and analysis of key techniques for wireless power/data and energy harvesting system design. The state-of-the-art system introduced in this book will benefit designers looking to develop wireless power transfer and energy harvesting technologies in a variety of fields, such as wearable, implantable devices, home appliances, and electric vehicles.

Technology: general issues --- Energy industries & utilities --- wireless power transfer --- capacitive power transfer --- parallel-plate contactless power --- MIMO --- NOMA --- precoding --- power allocation --- user-clustering --- power splitter --- mobile sensor --- hopping sensor --- relocation protocol --- energy efficient protocol --- internet of things (IoTs) --- wireless sensor networks (WSNs) --- simulation --- inductive power --- dual impedance --- dual band --- reflected resistance --- frequency splitting --- multiple coils --- mutual inductance --- parasitic effect --- practical mutual inductance --- transfer impedance --- wearable heater --- inductive-power transmission --- textile coil --- impedance matching network --- parasitic resistance --- power loss --- reflection coefficient --- Smith chart --- cylindrical joint --- electromagnetic fields --- rotation-free structure --- soil sensing --- decision agriculture --- smart farming --- Wireless Power Transfer (WPT) --- compensation topology --- optimal load --- output power level --- electric vehicle (EV) --- capacitive power transfer (CPT) systems --- wireless power transfer (WPT) systems --- e-class inverter --- wireless resonance energy link system --- cognitive radio --- energy harvesting --- full-duplex relay --- simultaneous wireless information and power transfer (SWIPT) --- zero-forcing precoding --- shielded loop coil --- SAR --- coupled resonance --- coil resistance --- substrate size --- implantable biomedical microsystems --- data telemetry --- low power --- high data rate --- binary phase-shift keying demodulation --- electric vehicle --- center alignment point --- ferrite antenna --- laser wireless power transmission --- PV module --- maximum power point --- battery charging --- wirelessly-powered cage --- inductive power transmission --- implantable medical device --- animal experiment --- reference circuit --- inductive link --- implantable device --- line regulation --- wireless power telemetry --- supply independence --- balanced coil --- foreign object detection --- Maxwell bridge --- metal object detection --- wireless power transmission (WPT) --- power conversion efficiency (PCE) --- mm-sized implant --- duty cycle --- pulsed power transmission --- power transfer efficiency (PTE) --- rectifier

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Power electronics technology is still an emerging technology, and it has found its way into many applications, from renewable energy generation (i.e., wind power and solar power) to electrical vehicles (EVs), biomedical devices, and small appliances, such as laptop chargers. In the near future, electrical energy will be provided and handled by power electronics and consumed through power electronics; this not only will intensify the role of power electronics technology in power conversion processes, but also implies that power systems are undergoing a paradigm shift, from centralized distribution to distributed generation. Today, more than 1000 GW of renewable energy generation sources (photovoltaic (PV) and wind) have been installed, all of which are handled by power electronics technology. The main aim of this book is to highlight and address recent breakthroughs in the range of emerging applications in power electronics and in harmonic and electromagnetic interference (EMI) issues at device and system levels as discussed in ‎robust and reliable power electronics technologies, including fault prognosis and diagnosis technique stability of grid-connected converters and ‎smart control of power electronics in devices, microgrids, and at system levels.

Q-factor --- lithium-ion power battery pack --- electromagnetic field (EMF) --- expert systems --- total harmonic distortion (THD) --- current-fed inverter --- rotor design --- class-D amplifier --- LCL-S topology --- current switching ripple --- system in package --- energy storage modelling --- smart micro-grid --- embedded systems --- equivalent inductance --- SHIL --- permanent magnet --- static var generator (SVG) --- permanent magnet synchronous motor (PMSM) --- control strategy and algorithm --- digital control --- zero-voltage switching (ZVS) --- SOC estimator --- electric power --- optimal design --- electromagnetic field interference (EMI) --- line frequency instability --- analog phase control --- five-phase permanent magnet synchronous machine --- distribution generation --- leakage inductance --- adjacent two-phase open circuit fault (A2-Ph) --- chaotic PWM --- electric vehicles --- CMOS chaotic circuit --- series active filter --- cascaded topology --- total demand distortion --- efficiency motor --- triangular ramp generator --- 4T analog MOS control --- inductive coupling --- induction machines --- nanocrystalline core --- semi-active bridge --- multi-level control --- simulation models --- voltage source inverters (VSI) --- battery management system BMS --- voltage source converter --- current control loops --- droop control --- particle swarm optimization --- variable control gain --- state of charge SoC --- extended Kalman filter --- transient control --- multi-objective optimization --- composite equalizer --- converter --- DHIL --- five-leg voltage source inverter --- axial flux machines --- bifurcation --- active receivers --- field programmable gate array --- Nyquist stability analysis --- electric vehicle --- static compensator --- stability --- common-mode inductor --- DC–DC converters --- support vector machines --- electromagnetic compatibility --- real-time simulation --- passive equalization --- matrix converters --- wireless power transfer --- digital phase control --- compensation topology --- volt-per-hertz control (scalar control) --- switching losses --- voltage control --- hybrid converter --- bidirectional converter --- coupling factor --- selective harmonic elimination method --- power electronics --- soft switching --- optimization design --- multilevel inverter --- five-phase machine --- phase-shift control --- lithium-ion battery --- voltage boost --- VPI active damping control --- parameter identification --- electrical engineering communications --- current control --- DC–DC conversion --- battery management system --- GaN cascode --- single-switch --- high-frequency modeling --- synchronous motor --- power quality --- water purification --- power factor correction (PFC) --- composite active vectors modulation (CVM) --- digital signal controller --- line start --- power density --- hardware in loop --- n/a --- fault diagnosis --- multi-level converter (MLC) --- induction motor --- dual three-phase (DTP) permanent magnet synchronous motors (PMSMs) --- neural networks --- electromagnetic interference filter --- battery chargers --- power converter --- harmonics --- multiphase space vector modulation --- torque ripple --- power factor correction --- electrical drives --- modular multilevel converter (MMC) --- active power filter --- double layer capacitor (DLC) models --- PMSG --- response time --- resonator structure --- floating-point --- effect factors --- DC-link voltage control --- sliding mode control --- phasor model technique --- wireless power transfer (WPT) --- slim DC-link drive --- fault-tolerant control --- lithium-ion batteries --- DC-AC power converters --- conducting angle determination (CAD) techniques --- variable speed pumped storage system --- impedance-based model --- one cycle control --- renewable energy sources --- series-series compensation --- cogging torque --- active rectifiers --- three-level boost converter (TLBC) --- DC-link cascade H-bridge (DCLCHB) inverter --- battery energy storage systems --- filter --- power management system --- improved extended Kalman filter --- dead-time compensation --- disturbance observer --- reference phase calibration --- frequency locking --- space vector pulse width modulation (SVPWM) --- predictive controllers --- nine switch converter --- transmission line --- spread-spectrum technique --- energy storage --- electromagnetic interference --- renewable energy resources control --- harmonic linearization --- misalignment --- plug-in hybrid electric vehicles --- high level programing --- nearest level modulation (NLM) --- magnetic equivalent circuit --- EMI filter --- permanent-magnet machines --- real-time emulation --- switched capacitor --- back EMF --- fixed-point --- HF-link MPPT converter --- condition monitoring --- WPT standards --- switching frequency --- switching frequency modelling --- high frequency switching power supply --- field-programmable gate array --- three-phase bridgeless rectifier --- ice melting --- AC–DC power converters --- hybrid power filter --- PSpice --- microgrid control --- total harmonic distortion --- grid-connected inverter --- dynamic PV model --- fuzzy --- boost converter --- SiC PV Supply --- voltage doubling --- nonlinear control --- distributed control --- power system operation and control --- one phase open circuit fault (1-Ph) --- direct torque control (DTC) --- battery modeling --- non-linear phenomena --- frequency-domain analysis --- advanced controllers --- vector control --- fixed-frequency double integral sliding-mode (FFDISM) --- power converters --- modulation index --- DC-DC buck converter --- small signal stability analysis --- active equalization --- voltage source inverter --- hardware-in-the-loop --- current source --- synchronization --- grid-connected VSI --- synchronous generator --- fault tolerant control --- DC-DC converters --- DC-DC conversion --- AC-DC power converters