Current-Ripple Compensation Control Technique for Switching Power Converters

As for ripple-current mode control, it cannot achieve average current tracking, resulting in poor current accuracy and even current waveform distortion. Meanwhile, fast-scale instability may occur in some operating conditions. To solve these problems effectively, a current-ripple compensation (CRC) control technique is proposed in this paper. The error between the average of the controlled current and the reference current is compensated by certain compensation signal, achieving average current tracking while suppressing fast-scale instability. On this basis, the compensator in the outer-voltage loop is further simplified to a proportional part by introducing a rebuilt average reference current. The idea and design procedure of the proposed CRC control technique are discussed in detail. Accordingly, two available implementation schemes for the proposed CRC are presented, including slope compensated and parabolic compensated schemes. Finally, two application cases, respectively, to dc–dc Buck converter and Boost PFC converter, are presented to verify the proposed CRC control technique.

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