| Autore: |
Lee Byunghun
|
| Titolo: |
Wireless Power/Data Transfer, Energy Harvesting System Design
|
| Pubblicazione: |
Basel, Switzerland, : MDPI - Multidisciplinary Digital Publishing Institute, 2021 |
| Descrizione fisica: |
1 online resource (344 p.) |
| Soggetto topico: |
Energy industries & utilities |
| |
Technology: general issues |
| Soggetto non controllato: |
animal experiment |
| |
balanced coil |
| |
battery charging |
| |
binary phase-shift keying demodulation |
| |
capacitive power transfer |
| |
capacitive power transfer (CPT) systems |
| |
center alignment point |
| |
cognitive radio |
| |
coil resistance |
| |
compensation topology |
| |
coupled resonance |
| |
cylindrical joint |
| |
data telemetry |
| |
decision agriculture |
| |
dual band |
| |
dual impedance |
| |
duty cycle |
| |
e-class inverter |
| |
electric vehicle |
| |
electric vehicle (EV) |
| |
electromagnetic fields |
| |
energy efficient protocol |
| |
energy harvesting |
| |
ferrite antenna |
| |
foreign object detection |
| |
frequency splitting |
| |
full-duplex relay |
| |
high data rate |
| |
hopping sensor |
| |
impedance matching network |
| |
implantable biomedical microsystems |
| |
implantable device |
| |
implantable medical device |
| |
inductive link |
| |
inductive power |
| |
inductive power transmission |
| |
inductive-power transmission |
| |
internet of things (IoTs) |
| |
laser wireless power transmission |
| |
line regulation |
| |
low power |
| |
maximum power point |
| |
Maxwell bridge |
| |
metal object detection |
| |
MIMO |
| |
mm-sized implant |
| |
mobile sensor |
| |
multiple coils |
| |
mutual inductance |
| |
NOMA |
| |
optimal load |
| |
output power level |
| |
parallel-plate contactless power |
| |
parasitic effect |
| |
parasitic resistance |
| |
power allocation |
| |
power conversion efficiency (PCE) |
| |
power loss |
| |
power splitter |
| |
power transfer efficiency (PTE) |
| |
practical mutual inductance |
| |
precoding |
| |
pulsed power transmission |
| |
PV module |
| |
rectifier |
| |
reference circuit |
| |
reflected resistance |
| |
reflection coefficient |
| |
relocation protocol |
| |
rotation-free structure |
| |
SAR |
| |
shielded loop coil |
| |
simulation |
| |
simultaneous wireless information and power transfer (SWIPT) |
| |
smart farming |
| |
Smith chart |
| |
soil sensing |
| |
substrate size |
| |
supply independence |
| |
textile coil |
| |
transfer impedance |
| |
user-clustering |
| |
wearable heater |
| |
wireless power telemetry |
| |
wireless power transfer |
| |
Wireless Power Transfer (WPT) |
| |
wireless power transfer (WPT) systems |
| |
wireless power transmission (WPT) |
| |
wireless resonance energy link system |
| |
wireless sensor networks (WSNs) |
| |
wirelessly-powered cage |
| |
zero-forcing precoding |
| Persona (resp. second.): |
LeeByunghun |
| Sommario/riassunto: |
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. |
| Titolo autorizzato: |
Wireless Power |
|
| Formato: |
Materiale a stampa  |
| Livello bibliografico |
Monografia |
| Lingua di pubblicazione: |
Inglese |
| Record Nr.: | 9910557759903321 |
|
| Lo trovi qui: | Univ. Federico II |
| Opac: |
Controlla la disponibilità qui |
