A 92.3%-Efficiency Switching-Mode Dual-Output Regulating Rectifier With Improved Link Adaptability for Wireless Power Transfer

Abstract

This article presents a 6.78-MHz switching-mode wireless power transfer (WPT) receiver (RX) with single-stage dual-output regulation and improved adaptability to link variations for biomedical applications. Based on a modified voltage doubler topology, it optimally transitions between voltage mode (VM) and resonant current mode (RCM) to extend the WPT range without compromising efficiency or delivered power. Seamless mode transition is achieved with no dead zones or output undershoots, thanks to the proposed quasi-open-circuit mode detection leveraging existing operational states without power-carrier interferences. The essential advantages of switching mode are consolidated via transient modeling. To meet dual-voltage-domain supply requirement in bio-implants, the RX uses stacked dc nodes in the voltage doubler to generate two regulated outputs with only three power switches. Designed and fabricated in a 180-nm CMOS technology, the proposed RX regulates two dc outputs at 1.8 and 3.3 V, respectively, with unobservable load-transient over/undershoots and cross-regulations. Using a 3.3-V-supplied class-D transmitter (TX), a 13.5-mm-radius TX coil, and an 11.5-mm-radius RX coil, the RX achieves a maximum WPT range of 7.5 cm under both 50-k $\Omega $ load conditions, demonstrating a 42% extension compared with VM-only operation. Real-time mode transition is validated through coil separation distance transients between 3 and 5.5 cm. In addition, with adaptive delay compensation in both VM and RCM operations, the RX achieves a peak power conversion efficiency (PCE) of 92.3% at a maximum output power of 171 mW.