DocumentCode
237727
Title
Guidance and obstacle avoidance of passive robot walking helper based on receding horizon control
Author
Chun-Hsu Ko ; Yi-Hung Hsieh ; Yao-Tse Chang ; Agrawal, Sunil K. ; Kuu-Young Young
Author_Institution
Dept. of Electr. Eng., I-Shou Univ., Kaohsiung, Taiwan
fYear
2014
fDate
18-22 Aug. 2014
Firstpage
1032
Lastpage
1037
Abstract
Along with the coming of the aging society, the passive robot walking helper is introduced for providing safe mobility for the elderly, which features continuous energy dissipation from the system with brakes for steering. When this passive walking helper is applied for guidance and obstacle avoidance, it is crucial to determine proper braking torques in accordance with user-applied force for avoiding the obstacles and reaching the desired location. Motivated by it, in this paper, we propose such an approach based on receding horizon control. The proposed approach is efficient in braking torque derivation and allows the walking helper to stop at the goal with parking control. With the desired location to reach, the proposed scheme first plans a smooth path for the walking helper to follow based on Dubins curve [13]. The process of torque derivation is then formulated into solving an optimization problem with constraints that guarantee system passivity. When the walking helper detects the obstacles, the obstacle avoiding strategy is activated to bring it to deviate from them, which is achieved by including the constraints for obstacle avoidance into the optimization process. Simulations and experiments are performed to demonstrate the effectiveness of the proposed approach.
Keywords
brakes; braking; collision avoidance; force; mobile robots; motion control; optimisation; steering systems; torque; traffic control; Dubins curve; brakes; braking torque derivation; energy dissipation; guarantee system; obstacle avoidance; optimization; parking control; passive robot walking helper; receding horizon control; steering; torque derivation; Acceleration; Collision avoidance; Equations; Legged locomotion; Robot kinematics; Obstacle avoidance; Passive guidance; Receding horizon control; Robot walking helper;
fLanguage
English
Publisher
ieee
Conference_Titel
Automation Science and Engineering (CASE), 2014 IEEE International Conference on
Conference_Location
Taipei
Type
conf
DOI
10.1109/CoASE.2014.6899453
Filename
6899453
Link To Document