Title :
Dynamic fuzzy Q-learning control of uncertain systems with applications to humanoids
Author :
Zhou, Yi ; Er, Meng Joo
Author_Institution :
Sch. of Electr. & Electron. Eng., Nanyang Technol. Univ.
Abstract :
In this paper, a design methodology for enhancing the stability of humanoid robots is presented. Fuzzy Q-learning (FQL) is applied to improve the zero moment point (ZMP) performance by intelligent control of the trunk of a humanoid robot. With the fuzzy evaluation signal and the neural networks of FQL, biped robots are dynamically balanced in situations of time-varying terrains. Compared with scale reward, fuzzy evaluation gives more informative feedback for training. Different types of membership functions (MF) for fuzzy systems have been compared. Simulation studies show that the FQL controllers based on both triangular and Gaussian MFs are able to improve the stability as the actual ZMP trajectories become very close to the ideal case, and Gaussian function is superior as the actions generated are smoother and the learning speed is faster
Keywords :
Gaussian processes; control system synthesis; fuzzy control; humanoid robots; intelligent control; learning systems; legged locomotion; neurocontrollers; stability; time-varying systems; uncertain systems; FQL controller; Gaussian MF; Gaussian function; ZMP trajectory; biped robot; fuzzy Q-learning control; fuzzy evaluation signal; fuzzy system; humanoid robot stability; intelligent control; membership function; neural network; time-varying terrain; uncertain system; zero moment point; Control systems; Design methodology; Fuzzy control; Fuzzy neural networks; Fuzzy systems; Humanoid robots; Intelligent control; Neural networks; Stability; Uncertain systems;
Conference_Titel :
Control Applications, 2005. CCA 2005. Proceedings of 2005 IEEE Conference on
Conference_Location :
Toronto, Ont.
Print_ISBN :
0-7803-9354-6
DOI :
10.1109/CCA.2005.1507168
