Abstract

This article presents a family of resonant switched-capacitor (SC) converters with multiple operating phases, herein named &#x201C;Multi-Resonant SC Converter&#x201D;. These converters can be synthesized from the basic two-phase SC topologies, such as the Doubler and the Series-Parallel, and are capable of achieving the same conversion ratio with fewer capacitors and switches. The augmenting inductor can resonantly charge/discharge all flying capacitors at different resonances, thereby facilitating soft-charging and soft-switching operation. Based upon this concept, an 8-to-1 Multi-Resonant-Doubler (MRD) converter and a 6-to-1 Cascaded Series-Parallel (CaSP) converter are proposed and analyzed. Both theoretical analysis and experimental results from a practical implementation are provided to demonstrate the benefits of the multi-resonant approach. The designed hardware prototype is configurable and can achieve one of the best overall in-class performances for the intermediate bus conversion in data centers. At 48-to-6&#x00A0;V conversion, the prototype achieves 98.6&#x0025; peak efficiency (98.0&#x0025; including gate drive loss) and 1675&#x00A0;W/in<inline-formula><tex-math notation="LaTeX">$^{3}$</tex-math></inline-formula> power density. At 48-to-8&#x00A0;V conversion, the prototype achieves 99.0&#x0025; peak efficiency (98.5&#x0025; including gate drive loss) and 2230&#x00A0;W/in<inline-formula><tex-math notation="LaTeX">$^{3}$</tex-math></inline-formula> power density.

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