Title :
Unified walking control for a biped robot using neural networks
Author :
Kun, Andrew L. ; Miller, W. Thomas, III
Author_Institution :
Falmouth Sci. Inc., Cataumet, MA, USA
Abstract :
A control scheme for handling variable speed gaits was implemented on an experimental biped. The control scheme used adaptation of pre-planned motion sequences in combination with closed loop reactive control. CMAC neural networks were responsible for the adaptive control of motion sequences. The biped was able to walk with variable speed gaits, and to change gait speeds on the fly. The slower gait speeds required statically balanced walking, while the faster speeds required dynamically balanced walking. It was not necessary to distinguish between the two balance modes within the controller. Following training, the biped was able to walk on flat, nonslippery surfaces at forward velocities in the range of 21 cm/min to 72 cm/min, with an average stride length of 6.5 cm
Keywords :
adaptive control; cerebellar model arithmetic computers; closed loop systems; legged locomotion; neurocontrollers; 0.35 to 1.2 cm/s; 6.5 cm; CMAC neural networks; adaptive control; biped robot; closed loop reactive control; dynamically balanced walking; flat nonslippery surfaces; motion sequences; neural networks; pre-planned motion sequences; statically balanced walking; unified walking control; variable speed gaits; Adaptive control; Foot; Gravity; Intelligent networks; Laboratories; Legged locomotion; Motion control; Neural networks; Robots; Stability;
Conference_Titel :
Intelligent Control (ISIC), 1998. Held jointly with IEEE International Symposium on Computational Intelligence in Robotics and Automation (CIRA), Intelligent Systems and Semiotics (ISAS), Proceedings
Conference_Location :
Gaithersburg, MD
Print_ISBN :
0-7803-4423-5
DOI :
10.1109/ISIC.1998.713675
