This article classifies, describes, and critically compares different compensation schemes,
converter topologies, control methods, and coil structures of wireless power transfer systems …

Inductive power transfer (IPT) for electric vehicles (EVs) is an emerging technology that can
transfer power wirelessly over certain distances, thus offering some remarkable …

This article proposes a review map for comparative designs of wireless high-power transfer
(WHPT) systems using single-and double-resonance blocks. In-depth analyses and key …

In this article, a self-tuning LCC/LCC wireless power transfer system based on switch-
controlled capacitors is proposed to maintain a high power factor on the primary inverter …

In this article, a triple-phase-shift (TPS) control strategy combining a switch-controlled
capacitor (SCC) is proposed for LCC–LCC compensated wireless power transfer (WPT) …

A typical battery charging process consists of a constant-current (CC) charging phase which
is followed and completed by a constant-voltage charging phase. Moreover, replacing the …

The double-sided inductor capacitor capacitor topology has been proposed in some
national standards for wireless charging systems. However, misalignment between the …

The inverter is crucial for a wireless power transfer (WPT) system, wherein its losses cannot
be overlooked. For wide output voltage regulation in the WPT system, the phase-shifting …

Wireless charging must be highly efficient throughout the entire battery charging profile to
compete in the electric vehicle (EV) industry. Thus, optimum load matching is commonly …

Although the wireless charging system (WCS) achieves flexible power transmission, high
system operating performance needs strong anti-misalignment capability and excellent …