Wireless Power Transfer 2nd Edition
Wireless Power Transfer is the second edition of a well received first book, which published in 2012. It represents the state-of-the-art at the time of writing, and addresses a unique subject of great international interest in terms of research. Most of the chapters are contributed by the main autho...
Saved in:
| Main Author | |
|---|---|
| Format | eBook |
| Language | English |
| Published |
River Publishers
2020
|
| Edition | 2nd edition |
| Series | River Publishers Series in Communications |
| Subjects | |
| Online Access | Get full text |
| ISBN | 9788793237629 8793237626 |
Cover
| Abstract | Wireless Power Transfer is the second edition of a well received first book, which published in 2012. It represents the state-of-the-art at the time of writing, and addresses a unique subject of great international interest in terms of research. Most of the chapters are contributed by the main author, though as in the first edition several chapters are contributed by other authors. The authors of the various chapters are experts in their own right on the specific topics within wireless energy transfer. Compared to the first edition, this new edition is more comprehensive in terms of the concepts discussed, and the range of current industrial applications which are presented, such as those of magnetic induction. From the eleven chapters of the first edtion, this second edition has expanded to twenty chapters. More chapters on the theoretical foundations and applications have been included. This new edition also contains chapters which deal with techniques for reducing power losses in wireless power transfer systems. In this regard, specific chapters discuss impedance matching methods, frequency splitting and how to deploy systems based on frequency splitting. A new chapter on multi-dimensional wireless power transfer has also been added. The design of wireless power transfer systems based on bandpass filtering approach has been included, in addition to the two techniques using couple mode theory and electronic circuits. The book has retained chapters on how to increase efficiency of power conversion and induction, and also how to control the power systems. Furthermore, detailed techniques for power relay, including applications, which were also discussed in the first edition, have been updated and kept. The book is written in a progressive manner, with a knowledge of the first chapters making it easier to understand the later chapters. Most of the underlying theories covered in the book are clearly relevant to inductive near field communications, robotic control, robotic propulsion techniques, induction heating and cooking and a range of mechatronic systems. |
|---|---|
| AbstractList | Wireless Power Transfer is the second edition of a well received first book, which published in 2012. It represents the state-of-the-art at the time of writing, and addresses a unique subject of great international interest in terms of research. Most of the chapters are contributed by the main author, though as in the first edition several chapters are contributed by other authors. The authors of the various chapters are experts in their own right on the specific topics within wireless energy transfer. Compared to the first edition, this new edition is more comprehensive in terms of the concepts discussed, and the range of current industrial applications which are presented, such as those of magnetic induction. From the eleven chapters of the first edtion, this second edition has expanded to twenty chapters. More chapters on the theoretical foundations and applications have been included. This new edition also contains chapters which deal with techniques for reducing power losses in wireless power transfer systems. In this regard, specific chapters discuss impedance matching methods, frequency splitting and how to deploy systems based on frequency splitting. A new chapter on multi-dimensional wireless power transfer has also been added. The design of wireless power transfer systems based on bandpass filtering approach has been included, in addition to the two techniques using couple mode theory and electronic circuits.The book has retained chapters on how to increase efficiency of power conversion and induction, and also how to control the power systems. Furthermore, detailed techniques for power relay, including applications, which were also discussed in the first edition, have been updated and kept. The book is written in a progressive manner, with a knowledge of the first chapters making it easier to understand the later chapters. Most of the underlying theories covered in the book are clearly relevant to inductive near field communications, robotic control, robotic propulsion techniques, induction heating and cooking and a range of mechatronic systems. |
| Author | Agbinya, Johnson I |
| Author_xml | – sequence: 1 givenname: Johnson I surname: Agbinya fullname: Agbinya, Johnson I |
| BookMark | eNqFj09Lw0AUxFdUUGs-gLeAJw-B_fs27yilWqGgh5Yew2bzFmPDLmSD_foG2ktPnmYGfswwD-wmpkhXrEBb1xaVVBYUXF9kiXesyPmHcy6FQtDqnj3v-5EGyrn8Skcay-3oYg6zkbErV10_9Sk-stvghkzFWRds97baLtfV5vP9Y_m6qZxWeqps6Cx5CR1YKTwhOg8ERhkTJFgCZ7wWiLUWWnDufOuAUwgytFpbjVwt2Mup1-UDHfN3Gqbc_A7UpnTIzcWx_9l5gluEWWb26cT2RNScCSnqWhn1B2xdVkk |
| ContentType | eBook |
| Copyright | 2016 River Publishers |
| Copyright_xml | – notice: 2016 River Publishers |
| DatabaseTitleList | |
| DeliveryMethod | fulltext_linktorsrc |
| Discipline | Engineering |
| EISBN | 9788793237636 8793237634 9781000796100 1000796108 |
| Edition | 2nd edition 2nd edition. |
| ExternalDocumentID | 9788793237636 9781000796100 9218835 |
| GroupedDBID | -VX 38. AABBV ABARN ABCRS ABEQL ABMRC ABQPQ ACLGV ADTEY ADVEM ADYHE AERYV AEUHU AFOJC AHWGJ AIXXW AJFER AKSCQ ALMA_UNASSIGNED_HOLDINGS ALYTH AMYDA AXTGW AZZ BBABE BMO CULCI CZVVX CZZ DUGUG EBATF EBSCA ECOWB GEO GEOUK INALI JTX NEQ PQQKQ XI1 ABYSD |
| ID | FETCH-LOGICAL-a434t-7fd7ec26d6721ce99ac6e65355f267e6a5c41998414100acba60eff2fb4474903 |
| ISBN | 9788793237629 8793237626 |
| IngestDate | Fri Nov 08 05:35:02 EST 2024 Thu Aug 07 07:00:10 EDT 2025 Sun Jun 29 07:30:53 EDT 2025 |
| IsPeerReviewed | false |
| IsScholarly | false |
| Language | English |
| LinkModel | OpenURL |
| MergedId | FETCHMERGED-LOGICAL-a434t-7fd7ec26d6721ce99ac6e65355f267e6a5c41998414100acba60eff2fb4474903 |
| PageCount | 0 |
| ParticipantIDs | askewsholts_vlebooks_9788793237636 askewsholts_vlebooks_9781000796100 ieee_books_9218835 |
| PublicationCentury | 2000 |
| PublicationDate | 2020 2022-09-01 2016-02-01 |
| PublicationDateYYYYMMDD | 2020-01-01 2022-09-01 2016-02-01 |
| PublicationDate_xml | – year: 2020 text: 2020 |
| PublicationDecade | 2020 2010 |
| PublicationSeriesTitle | River Publishers Series in Communications |
| PublicationYear | 2020 2022 2016 |
| Publisher | River Publishers |
| Publisher_xml | – name: River Publishers |
| SSID | ssj0002139643 ssib057697072 |
| Score | 2.3158462 |
| Snippet | Wireless Power Transfer is the second edition of a well received first book, which published in 2012. It represents the state-of-the-art at the time of... |
| SourceID | askewsholts ieee |
| SourceType | Aggregation Database Publisher |
| SubjectTerms | Communication, Networking and Broadcast Technologies |
| TableOfContents | Preface xix Acknowledgment xxvii List of Contributors xxix List of Figures xxxi List of Tables lv List of Abbreviations lvii 1 Power Transfer by Magnetic Induction Using Coupled-Mode Theory 1 Mihai Iordache, Lucia Dumitriu and Dragos Niculae 1.1 Introduction 1 1.2 Series–Series Resonators Inductively Coupled 3 1.2.1 Analysis by the Circuit Theory 3 1.2.2 Analysis by the Coupled-Mode Theory 7 1.2.3 Transfer Power Computation 10 1.2.4 Remark 11 1.3 Mutual Inductance Computation 14 1.4 Efficiency of the Active Power Transffer 26 1.4.1 Scattering Parameters S 26 1.4.2 Efficiency Computation 29 1.5 Some Procedures for Optimal Wireless Energy Transfer Systems 35 1.5.1 Indroduction 35 1.5.2 Optimal Parameter Computing Performance Optimization of Magnetic Coupled Resonators 37 1.5.3 Remarks 47 1.6 Conclusions 47 1.7 Problems 50 1.8 Solutions to Problems 62 References 68 2 Efficient Wireless Power Transfer based on Strongly Coupled Magnetic Resonance 73 Fei Zhang and Mingui Sun 2.1 Introduction 73 2.2 Interaction in Lossless Physical System 74 2.3 Interaction in Real Two-Resonator Physical System 77 2.3.1 Fully Resonant Case 77 2.3.1.1 Strong coupling 78 2.3.1.2 Weak coupling 80 2.3.2 General Non-Resonant Case 80 2.4 Relay Effect of Wireless Power Transfer 80 2.4.1 Relay Effect 81 2.4.2 Time-Domain Comparison between Relayed and Original Witricity Systems 82 2.5 Wireless Power Transfer with Multiple Resonators 83 2.5.1 General Solution for Multiple Relays 83 2.5.2 Inline Relay(s) 84 2.5.2.1 One relay 84 2.5.2.2 Two relays 85 2.5.2.3 Spectral analysis of energy exchanges 85 2.5.3 Optimization of 2D WPTN Scheme 87 2.5.3.1 Case 1 with two relays 87 2.5.3.2 Case 2 with two relays 87 2.5.3.3 Spectral analysis of energy exchanges 87 2.6 Prototype of Wireless Power Transfer 90 2.6.1 Cylindrical Resonator Design 90 2.6.2 Implementation of Cylindrical Resonator 91 2.6.3 Evaluation of Cylindrical Resonator 93 2.6.4 Application of Cylindrical Resonator 95 2.7 Discussion 100 2.8 Conclusions 101 References 101 3 Low Power Rectenna Systems for Wireless Energy Transfer 105 Vlad Marian, Christian Vollaire, Jacques Verdier and Bruno Allard 3.1 Introduction 105 3.1.1 History of Wireless Power Transfer 106 3.1.2 Wireless Power Transfer Techniques 108 3.1.2.1 DC-RF conversion 110 3.1.2.2 Electromagnetic wave propagation 110 3.1.2.3 RF-DC conversion 112 3.2 Low Power Rectenna Topologies 113 3.2.1 Circuit Topologies 115 3.2.1.1 Series-mounted diode 116 3.2.1.2 Shunt-mounted diode 116 3.2.1.3 Voltage-doubler topology 117 3.2.1.4 Diode bridge topology 117 3.2.1.5 Transistor-based rectennas 118 3.2.2 Rectenna Associations 120 3.2.3 Modeling a Rectenna 122 3.2.4 A Designer’s Dilemma 124 3.2.4.1 Output characteristics 124 3.2.4.2 Antenna impedance influence 125 3.3 Reconfigurable Electromagnetic Energy Receiver 130 3.3.1 Typical Application 130 3.3.2 Rectenna Circuit Configuration 131 3.3.3 Reconfigurable Architecture 135 3.3.3.1 Antenna switch 135 3.3.3.2 Global performance 136 3.3.3.3 Output load matching 141 3.4 Conclusions 144 References 144 4 Wireless Power Transfer: Generation, Transmission, and Distribution Circuit Theory of Wireless Power Transfer 151 4.1 Introduction 151 4.2 Criteria for Efficient Resonant Wireless Power Transfer 152 4.2.1 High Power Factor (cos θ=1) 153 4.2.2 High Coupling Coefficient (k ≈ 1) 153 4.2.3 High Quality (Q >> 1) Factors 153 4.2.4 Matching Circuits 154 4.2.5 Focusing of Magnetic Field 154 4.3 Resonant Wireless Power Transfer 154 4.3.1 Higher-Order WPT Systems 157 4.4 Loosely Coupled Wireless Power Transfer System 159 4.4.1 Low Q1 and Q2 161 4.4.2 High Q1 and Q2 161 4.5 Efficiency 161 4.6 Summary 163 5 Inductive Wireless Power Transfer Using Circuit Theory 165 Kyriaki Fotopoulou and Brian Flynn 5.1 Introduction 165 5.2 Advantages of Inductive Coupling for Energy Transfer 167 5.3 Applications of Inductive Power Transfer 168 5.4 Fundamentals of Inductive Coupling 172 5.4.1 Inductive Coupling and Transformer Action 174 5.4.2 Resonant Circuit Topologies 177 5.4.3 Power Transfer across a Poorly Coupled Link 179 5.4.4 Near- and Far-Field Regions 184 5.4.5 The Importance of the Loop Antenna 186 5.4.6 Small Loop of Constant Current 188 5.4.7 The Loop in Transmitting Mode 189 5.4.8 The Loop in the Receiving Mode 192 5.5 Mutual Inductance of Coupled Coils 194 5.6 The Loosely Coupled Approximation 205 5.7 Summary 207 References 207 6 Recent Advances on Magnetic Resonant Wireless Power Transfer 217 Marco Dionigi, Alessandra Costanzo, Franco Mastri, Mauro Mongiardo and Giuseppina Monti 6.1 Introduction 217 6.2 Coupled Inductors 220 6.2.1 Coupled Inductors 220 6.2.2 The Series Resonant Circuit 225 6.2.3 Adding Resonators to the Coupled Inductors 227 6.2.4 Maximum Efficiency, Maximum Power on the load, and Conjugate Matching: Two-Port Case 230 6.2.5 Maximum Efficiency: N-port Case 233 6.2.6 Scattering Matrix Representation of a Wireless Power Transfer Network 235 6.3 Four Coupled Resonators 236 6.4 Travelling Waves, Power Waves and Conjugate Image Impedances 241 6.4.1 Travelling Waves and Power Waves 242 6.4.2 Conjugate Image Impedances 245 6.5 Measurement of the Resonator Quality Factor 248 6.6 Examples of Coupled Resonators for WPT 252 6.7 Design of the Oscillator Powering the Resonant Link 255 6.8 Conclusions 264 6.9 Exercises 264 6.9.1 MATLAB function for single-loop inductance computation 265 6.9.2 MATLAB function for two coaxial conducting loops mutual inductance computation 265 References 266 7 Techniques for Optimal Wireless Power Transfer Systems 271 7.1 Introduction 272 7.2 Flux Conentrators 273 7.2.1 Splitting of Coupling Coefficients 273 7.2.2 Doubling of Coil Radius 275 7.3 Separators 276 7.3.1 Simulations 279 7.3.2 Effect of Concentrator Quality Factor 282 7.3.3 Effect of Concentrator Radius 284 7.4 Approximate Magneto-Inductive Array Coupling Functions 285 7.4.1 System Specifications 286 7.4.2 Power Relations in Inductive Systems 287 7.4.3 Algorithm for Approximate Transfer Function 288 7.4.4 Interpretation of Algorithm 294 7.4.5 Correction Terms 295 7.5 Wireless Feedback Modelling 295 7.5.1 Wireless Feedback 299 7.5.2 Q-Based Explanation of Wireless Closed-Loop Transfer Function 301 7.6 Conclusions 303 References 303 8 Directional Tuning/Detuning Control of Wireless Power Pickups 307 8.1 Introduction 307 8.1.1 Shorting Control 308 8.1.2 Dynamic Tuning/Detuning Control 311 8.2 Directional Tuning/Detuning Control (DTDC) 313 8.2.1 Fundamentals of DTDC 313 8.2.2 Coarse-Tuning Stage 315 8.2.2.1 Coarse tuning in region A 315 8.2.2.2 Coarse tuning in region B 315 8.2.2.3 Coarse tuning in region C 315 8.2.2.4 Coarse tuning in region D 316 8.2.3 Fine-Tuning Stage 316 8.2.3.1 Fine-tuning between regions A and B 316 8.2.3.2 Fine-tuning between regions C and D 318 8.2.4 Design and Performance Considerations of DTDC 320 8.2.4.1 Category I 323 8.2.4.2 Category II 324 8.2.4.3 Category III 324 8.2.5 Standard Procedure of DTDC 325 8.3 DTDC-Controlled Parallel-Tuned LC Power Pickup 327 8.3.1 Fundamentals of Parallel-Tuned LC Power Pickup 327 8.3.2 Controllable Power Transfer Capacity of Parallel-Tuned LC Power Pickup 328 8.3.3 Effects of Parameter Variations on Output Voltage of Parallel-Tuned LC Power Pickup 329 8.3.4 Operating Frequency Variation 330 8.3.5 Magnetic Coupling Variation 331 8.3.6 Load Variation 333 8.3.7 Operating Range of Variable CS 333 8.3.7.1 Maximum required ratio (r adj_pv_max) 335 8.3.7.2 Minimum required ratio (r adj_pv_min) 335 8.3.8 Implementation of DTDC Controlled Parallel-Tuned LC Power Pickup 335 8.3.8.1 Selection of CS1 and CS2 336 8.3.8.2 Equivalent Capacitance of CS2 337 8.3.8.3 Integration of Control and ZVS Signals for Q1 and Q2 340 8.4 Conclusions 343 8.5 Problems 343 References 344 9 Technology Overview and Concept of Wireless Charging Systems 347 Pratik Raval, Dariusz Kacprzak and Aiguo Patrick Hu 9.1 Introduction 347 9.2 System Technology 348 9.2.1 Power Converter 349 9.2.2 Compensation Networks 351 9.2.3 Electromagnetic Structures 356 9.2.4 Power Conditioner 360 9.3 Applications 361 9.4 Development of Wireless Low-Power Transfer System 363 9.4.1 Methodology 363 9.4.1.1 Finite element formulation 364 9.4.2 D Planar Wireless Power Transfer System 366 9.4.2.1 Primary track loop 366 9.4.2.2 Pickup 368 9.4.3 Wireless Power Transfer System 372 9.4.3.1 Continuous mode of operation 372 9.4.3.2 Discontinuous mode of operation 374 9.4.3.3 Development 376 9.5 Conclusions 380 9.6 Problems 380 References 381 10 Wireless Power Transfer in On-Line Electric Vehicle 385 10.1 Introduction 385 10.1.1 Wireless Power Transfer Technology 385 10.1.2 Wireless Power Transfer System in the Market 387 10.1.2.1 Application to automobiles 388 10.2 Mechanism of Wireless Power Transfer 391 10.2.1 Electric Field and Magnetic Field 391 10.2.2 Inductive Coupling and Resonant Magnetic Coupling 393 10.2.3 Topology Selection and Coil Design 395 10.3 Design of On-Line Electric Vehicle 397 10.3.1 Necessity of On-Line Electric Vehicle 397 10.3.2 Challenges 400 10.3.3 Topology Analysis 401 10.3.4 Coil Design for Electric Vehicle 402 10.3.5 Electromagnetic Field Reduction Technology 403 10.3.6 Design Procedure and Optimization 411 10.4 Conclusions 417 10.5 Problems 418 References 418 11 Wireless Powering and Propagation of Radio Frequencies through Tissue 421 Eric Y. Chow, Chin-Lung Yang and Pedro P. Irazoqui 11.1 Introduction 421 11.2 Comparison of Transcutaneous Powering Techniques 422 11.3 Analysis 423 11.3.1 Reflections at an Interface 425 11.3.2 Attenuation Due to Tissue Absorption 427 11.3.3 Energy Spreading (Free-Space Path Loss) 430 11.3.4 Expanding to Multiple Layers and Interfaces 430 11.4 Simulation Modeling 433 11.5 Empirical Studies 434 11.6 Antenna Design and Frequency Band Selection 437 11.7 Power Conversion Circuitry 440 11.8 Benefiting Applications and Devices 445 11.9 Conclusions 448 11.10 Problems 449 References 449 12 Microwave Propagation and Inductive Energy Coupling in Biological Human Body Tissue Channe |
| Title | Wireless Power Transfer 2nd Edition |
| URI | https://ieeexplore.ieee.org/servlet/opac?bknumber=9218835 https://www.vlebooks.com/vleweb/product/openreader?id=none&isbn=9781000796100 https://www.vlebooks.com/vleweb/product/openreader?id=none&isbn=9788793237636&uid=none |
| hasFullText | 1 |
| inHoldings | 1 |
| isFullTextHit | |
| isPrint | |
| link | http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwnV3dS8MwED_38eKenB84vyjqa6Wk6XV9FJlMYSKywd5G0iYylApbJ-hf793Wbt0Ygr6ENAmB_o5cfpdc7gCuSePpJPSV62tpXOm3pauJ2bsYSx3ZhKxcwwf6vSfsDuTjMBhWdkzJa2mW6Zv4e-u7kv9IldpIrvxK9g-SXU5KDVQn-VJJEqZyg_wuP_OA22POdUI66pmTnC0ilFuqiJRDFI_Ll-u3r2T7fqnC7ZYTDj6UTX3hbZj6L-ypUXKXXzMF27TQ2MMlPz9YjyEd0UZOVKsK1RBp6ddpy-v0lkdRglggERPOXlhMgovYRKtJG9BQ0zfSu6STs-laKpr5Ttzfg7rh5xlNqJh0HxqlcIoHcFXA4sxhcQpYHILFyWE5hMF9p3_XdfMkEK6Svszc0CahiQUmSLZqbKJIxWgwIJpkBYYGVRBLfico2WHVU7FW6BlrhdVShjLy_COopR-pOQYn0NSDiRDK8mAbCQ9NQPrdoLRW-y24LP3j6PN9fl89HXFYMOZSEVFN75dBBVo-tqDJ-IzyrgX6J9saT2F3JekzqGWTmTknmpPpi1xMP7YC-g4 |
| linkProvider | ProQuest Ebooks |
| openUrl | ctx_ver=Z39.88-2004&ctx_enc=info%3Aofi%2Fenc%3AUTF-8&rfr_id=info%3Asid%2Fsummon.serialssolutions.com&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Abook&rft.genre=book&rft.title=Wireless+Power+Transfer+2nd+Edition&rft.au=Agbinya%2C+Johnson+I&rft.date=2020-01-01&rft.pub=River+Publishers&rft.isbn=9788793237629&rft.externalDocID=9218835 |
| thumbnail_m | http://utb.summon.serialssolutions.com/2.0.0/image/custom?url=https%3A%2F%2Fvle.dmmserver.com%2Fmedia%2F640%2F97810007%2F9781000796100.jpg http://utb.summon.serialssolutions.com/2.0.0/image/custom?url=https%3A%2F%2Fvle.dmmserver.com%2Fmedia%2F640%2F97887932%2F9788793237636.jpg |