Title :
A fully integrated switched-capacitor based PMU with adaptive energy harvesting technique for ultra-low power sensing applications
Author :
Suyoung Bang ; Yoonmyung Lee ; Inhee Lee ; Yejoong Kim ; Gyouho Kim ; Blaauw, D. ; Sylvester, Dennis
Author_Institution :
Univ. of Michigan, Ann Arbor, MI, USA
Abstract :
We present a self-adapting power management unit (PMU) for ultra-low power wireless sensor nodes. The PMU uses 1.03nF of on-chip MIM capacitance in a reconfigurable switched-capacitor network (SCN) that automatically adapts to different battery voltages for down-conversion and different harvesting sources/harvesting conditions for up-conversion. The PMU achieves 63.8% / 60.7% down-conversion efficiency at 17.9μW active mode / 12.8nW sleep mode power loading. With the adaptive down-conversion ratio, load power range is improved by 3.76× and 5.48× in sleep and active mode, respectively. We show how the proposed adaptation method enables harvesting with solar, microbial fuel cell, and thermal energy sources, increases harvesting efficiency by 1.92× and achieves the peak extraction efficiency of 99.8% for solar cell.
Keywords :
energy harvesting; microbial fuel cells; solar cells; switched capacitor networks; telecommunication power supplies; wireless sensor networks; adaptive energy harvesting; capacitance 1.03 nF; efficiency 60.7 percent; efficiency 63.8 percent; efficiency 99.8 percent; integrated switched-capacitor; microbial fuel cell; on-chip MIM capacitance; power 12.8 nW; power 17.9 muW; self-adapting power management unit; solar cell; switched-capacitor network; thermal energy sources; ultralow power sensing; ultralow power wireless sensor nodes; Batteries; Clocks; Current measurement; Low-power electronics; Monitoring; Phasor measurement units; Photovoltaic cells;
Conference_Titel :
Circuits and Systems (ISCAS), 2013 IEEE International Symposium on
Conference_Location :
Beijing
Print_ISBN :
978-1-4673-5760-9
DOI :
10.1109/ISCAS.2013.6571945
