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引用次数: 4
摘要
本文提出了一种适用于高降压比、大电流点负载应用的4相串联电容降压变换器(SCB)。提出了一种嵌入自适应实时控制器的电流平衡策略,有效地解决了电感器不同相位间的电流失配问题。这大大减少了所需的外部电感的尺寸,从而减少了转换器的体积。与传统的4相交错降压转换器相比,所提出的电流平衡方案还节省了2个电流传感器。采用0.35µm CMOS技术实现的4相SCB e-mode GaN fet转换器支持10A的全负载,在12v -1.2 v转换和2.5MHz/相位工作下实现92.5%的峰值功率效率。验证了负载电流在稳态和暂态条件下均均匀分布于4相。与工业和文献中最先进的变换器相比,所提出的4相SCB变换器同时实现了最高的功率效率和最大的电流密度。
A Current-Density-Enhanced 12V-to-1.2V/10A, AOT-Controlled, 4-Phase Series-Capacitor Buck Converter with Embedded Current Balancing
This paper presents a 4-phase series-capacitor buck converter (SCB) for high step-down-ratio, high-current point-of-load applications. A current-balancing strategy embedded in the adaptive-on-time controller is proposed to effectively address the inductor current mismatch between different phases. This significantly reduces the required size of the external inductor and thus the converter volume. The proposed current balancing scheme also saves 2 current sensors compared to that of the traditional 4-phase interleaved buck converters. Implemented in a 0.35µm CMOS technology, the proposed 4-phase SCB converter with e-mode GaN FETs supports the full load of 10A and achieves the peak power efficiency of 92.5% under 12V-to-1.2V conversion and 2.5MHz/phase operation. The load current is verified to be equally distributed among 4 phases in both steady-state and transient conditions. Compared to state-of-the-art converters from industry and literature, the proposed 4-phase SCB converter simultaneously achieves the highest power efficiency and the largest current density.
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