Title :
Dynamic Integrated MPP Tracker in 0.35 μm CMOS
Author :
Enne, R. ; Nikolic, M. ; Zimmermann, H.
Author_Institution :
Inst. of Electrodynamics, Vienna Univ. of Technol., Vienna, Austria
Abstract :
An integrated CMOS controller with fast maximum power point regulation for module-integrated automotive solar converters with nine solar cells per string is reported. It provides the 530-kHz switching signals for the module-integrated converter whereby the mean output current of the module is maximized. The on-chip “perturb and observe” algorithm bases on a quasi-analog principle and performs more than 1000 tracking cycles/s at a power consumption around 560 μW. In order to maximize the precision, the duration of the measurement intervals is automatically adjusted to the output current. Due to the use of a very small shunt resistance of 1 mΩ for the current measurement, the insertion loss is small and the circuit complexity is kept low. Between 0.25- and 5-A photocurrent, the tracker achieves a tracking efficiency better than 99.5%.
Keywords :
CMOS integrated circuits; automotive electrics; electric current measurement; maximum power point trackers; photovoltaic power systems; power consumption; solar cells; switching convertors; circuit complexity; current measurement; dynamic integrated MPPT; frequency 530 kHz; insertion loss; integrated CMOS controller; maximum power point regulation; module integrated automotive solar converter; on-chip perturb and observe algorithm; power consumption; quasianalog principle; resistance 1 mohm; size 0.35 mum; solar cell; switching signal; Capacitors; Clocks; Current measurement; Load flow; Photovoltaic cells; Pulse width modulation; Voltage control; Analog integrated circuits; CMOS analog integrated circuits; analog processing circuit; dc–dc power conversion; impedance matching; mixed analog–digital integrated circuits; photovoltaic power systems; solar power generation;
Journal_Title :
Power Electronics, IEEE Transactions on
DOI :
10.1109/TPEL.2012.2213615
