TY - GEN
T1 - Obstacle Avoidance Trajectory Correction Control Method for Hopping Movement on Small Celestial Bodies
AU - Yang, Zhe
AU - Gao, Xizhen
AU - Zhu, Shengying
N1 - Publisher Copyright:
© 2024 Technical Committee on Control Theory, Chinese Association of Automation.
PY - 2024
Y1 - 2024
N2 - The surface of small celestial bodies is characterized by complex morphology and irregular gravitational fields. The rover faces the risk of colliding with obstacles during the hopping movement, and environmental disturbances and initial errors can lead to trajectory deviations. In response to the issue, this paper proposes an obstacle avoidance trajectory correction control method during hopping movement of the rover. Initially, the obstacle avoidance correction potential function is established. The maneuver moment is determined by setting limits on trajectory errors, obstacle warning boundaries, and potential function gradients. Using the minimization of the potential field value at the final landing point as the performance metric, the analytical solution for the maneuver velocity during obstacle avoidance correction is derived by solving the linearized dynamic equations. Finally, simulation results for hopping movement on simulated surface and a small celestial body model are presented, demonstrating the effectiveness of the method in steering the rover avoiding obstacles, correcting trajectory errors, and improving hopping accuracy.
AB - The surface of small celestial bodies is characterized by complex morphology and irregular gravitational fields. The rover faces the risk of colliding with obstacles during the hopping movement, and environmental disturbances and initial errors can lead to trajectory deviations. In response to the issue, this paper proposes an obstacle avoidance trajectory correction control method during hopping movement of the rover. Initially, the obstacle avoidance correction potential function is established. The maneuver moment is determined by setting limits on trajectory errors, obstacle warning boundaries, and potential function gradients. Using the minimization of the potential field value at the final landing point as the performance metric, the analytical solution for the maneuver velocity during obstacle avoidance correction is derived by solving the linearized dynamic equations. Finally, simulation results for hopping movement on simulated surface and a small celestial body model are presented, demonstrating the effectiveness of the method in steering the rover avoiding obstacles, correcting trajectory errors, and improving hopping accuracy.
KW - Hopping movement
KW - Obstacle avoidance
KW - Potential function
KW - Trajectory correction
UR - http://www.scopus.com/inward/record.url?scp=85205471798&partnerID=8YFLogxK
U2 - 10.23919/CCC63176.2024.10662075
DO - 10.23919/CCC63176.2024.10662075
M3 - Conference contribution
AN - SCOPUS:85205471798
T3 - Chinese Control Conference, CCC
SP - 3845
EP - 3850
BT - Proceedings of the 43rd Chinese Control Conference, CCC 2024
A2 - Na, Jing
A2 - Sun, Jian
PB - IEEE Computer Society
T2 - 43rd Chinese Control Conference, CCC 2024
Y2 - 28 July 2024 through 31 July 2024
ER -