A Fully Integrated 0.4 mm² Soft-Charging Switched-Capacitor DC-DC Step-Down Converter with 85% Peak Efficiency Minimizing the Circuit Footprint for Sub-mA-Load E-Textile Applications
Mim, Nugaira Gahan, Electrical Engineering - School of Engineering and Applied Science, University of Virginia
Calhoun, Benton, EN-Elec & Comp Engr Dept, University of Virginia
This work proposes a design approach for a fixed/narrowed-voltage-conversion-ratio (VCR)
in a soft-charging switched-capacitor (SC) DC-DC step-down converter, utilizing a continuous scalable-
conversion-ratio (CSCR) architecture, specifically designed for sub-mA-load smart e-textile
applications where minimizing size is critical. By narrowing the VCR range, the proposed
approach reduces area consumption by constraining design parameters such as capacitor size and
operating frequency, sacrificing wide VCR flexibility to enhance power density (PD). This makes
it particularly suitable for fixed-VCR mA-load smart e-textile applications, where seamless system
integration and compact size are essential. Designed for a 1.8V to 1.2V conversion, the system
achieves peak efficiencies of 85.4% and 87.8 % in compact footprints of 0.4mm² and 0.6mm²,
using 65nm CMOS technology. It operates efficiently across a load range of 0.15mA to 2 mA.
These simulation-validated results demonstrate the efficiency and PD advantages of the proposed
design method over wide-VCR designs in sub-mA-load scenarios. The approach optimizes capacitor
sizing and operating frequency, balancing efficiency and area, making it well-suited for
space-constrained fixed-VCR-sub-mA smart e-textile applications where maximizing PD in small
form factors is crucial.
MS (Master of Science)
English
2024/12/10