Benoît Labbé, David Chesneau, B. Allard, X. Lin-Shi
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Modeling and design of an integrated sliding-mode buck converter with regulated switching frequency suitable for mobile devices
Mobile applications necessitate nowadays huge digital resources. Power management of digital circuits is based on dynamic strategies to preserve energy. DC/DC converters used to supply the digital core face stringent constraints with respect to load transients. Sliding-mode control is well suited to control buck converters that are subject to high dynamic load and line transients. Fixed frequency sliding-mode control has been experimented. Transient performances or silicon area are negatively affected. A new analog implementation of the sliding-mode control with switching frequency control is presented here. The proposed synchronization scheme does not degrade the intrinsic asynchronous transient performances and is not affected by a significant silicon area penalty. The proposed DC/DC converter is implemented in CMOS 130 nm. The switching frequency is kept constant thanks to the frequency regulation loop. The demonstrator achieves more than 80% efficiency from 3mW to 840mW.
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