Analysis and optimization of CMOS switched-capacitor converters

Energy-efficiency continues to limit peak computational performance in digital systems. To drive continued energy-improvements, designers of modern digital systems are relying on multiple, smaller voltage domains for enhanced voltage-scaling. Switched-capacitor (SC) voltage converters are a promising alternative to traditional switched-inductor regulators due to their suitability for efficient, fully-integrated regulation of finer voltage domains. However, several important problems regarding the analysis and optimization of SC converter design remain unaddressed. This paper develops a comprehensive analysis of SC converter output resistance to establish the optimal switching frequency and switch resistance for maximum converter efficiency. The proposed analysis is validated through simulation experiments conducted using an industrial 65nm CMOS technology.

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