Title :
Study of the fuzzy PID controlled super-capacitor auxiliary power system of the electrical vehicle
Author :
Chen Xiang ; Li Guo-fang ; Liu Shuang ; Zhang Hai-yan
Author_Institution :
Inst. of Mech. Detection & Fault Diagnosis, Lanzhou City Univ., Lanzhou, China
Abstract :
A way to use super-capacitor as energy storage element to achieve regenerative braking energy recovery is presented, and the average model for the control circuit of the super-capacitor regenerative braking system is established based on fully analysis of the dynamic model of DC/DC full-bridge converter. The self-tuning fuzzy PID controller with the super-capacitor in charging/discharging states is designed according to the non-linear characteristics of the DC/DC converter. The simulation test shows that the self-tuning fuzzy PID controlled super-capacitor regenerative braking system is more effective than the gain PID control in increasing the driving current of the electric vehicle, improving its starting and accelerating performance, extending its driving range, particularly in improving its performance in responsive time and robustness.
Keywords :
DC-DC power convertors; capacitor motors; electric vehicles; fuzzy control; regenerative braking; three-term control; DC/DC full-bridge converter; capacitor charging state; capacitor discharging state; electric vehicle; energy storage element; fuzzy PID control; regenerative braking energy recovery; super-capacitor auxiliary power system; Control systems; Electric vehicles; Fuzzy control; Fuzzy systems; Power system analysis computing; Power system control; Power system dynamics; Power system modeling; Power systems; Three-term control; DC/DC converter; electrical vehicle; fuzzy PID control; regenerative braking; self-tuning;
Conference_Titel :
Computer Design and Applications (ICCDA), 2010 International Conference on
Conference_Location :
Qinhuangdao
Print_ISBN :
978-1-4244-7164-5
Electronic_ISBN :
978-1-4244-7164-5
DOI :
10.1109/ICCDA.2010.5540968
