A Low-Profile High-Efficiency Fast Battery Charger With Unifiable Constant-Current and Constant-Voltage Regulation
Yong Qu, Wei Shu, Lei Qiu, Yen‐Cheng Kuan, Shiuh-Hua Wood Chiang, Joseph S. Chang
Abstract
Present universal serial bus (USB) battery chargers often suffer from limitations to meet the increasing demand for quick charging due to compromised power efficiency and complicated hardware implementation. In this paper, we propose a charge unifiable (QU) control scheme that enables a battery charger to improve power efficiency in a low-profile hardware manner. This scheme features fully soft-switching (vis-à-vis hard switching) and single control scheme (vis-à-vis multiple) for distinct constant current (CC) and constant voltage (CV) charging modes. To the best of authors' knowledge, the proposed QU control scheme is the first to simultaneously offer fully softs-witching, innate CC-and-CV regulation, and seamless CC-toCV transition. To verify the proposed design, we monolithically realize a low-profile high-efficiency fast battery charger based on this scheme. The prototype embodying a tiny 470-nil output inductor supports a maximum input voltage of 16V, output voltage of 2.2-4.2 V, output current of 0.1-2 A, and peak power efficiency of 96.2%. When benchmarked against state-of-the-art counterparts, the proposed charger features at least 2.1× smaller inductor and 7.2% higher power efficiency at both the maximum and the minimum output power charging scenarios. Further, this charger is the only design that features ≥91% power efficiency in the whole load range.