Split Duty Cycle Coupled Multiphase Boost-Buck Converter

The classic cascaded boost-buck converter has inductors at the input and output ports of the converters, which makes it an ideal interface for bidirectional battery charging applications, where accurate current control and low ripple currents are required. This article proposes a split duty cycle coupled multiphase variant applied to the cascaded boost-buck converter and utilizes coupled inductor features to achieve very lower current ripples at the output, lower power losses, and reduction in magnetic component volume. Moreover, current sharing between each phase is inherently implemented, making it suitable for a high-conversion-ratio bidirectional operation in systematic energy storage applications, where the low-voltage port has very high current. This article covers a split duty cycle converter operation principle using coupled inductors between the input and the multiphase output. Magnetic component design and selection guidelines are presented. The proposed control method and the coupled inductor structure are validated by simulation and experimental results.

Automated summary

This article introduces a split duty cycle coupled multiphase variant for cascaded boost-buck converter, utilizing coupled inductor features to achieve lower current ripples at the output, reduce power losses, and decrease magnetic component volume. Current sharing between phases is inherently implemented, suitable for high-conversion-ratio bidirectional operation in energy storage applications.