English

Adaptive Gaussian Process based Stochastic Trajectory Optimization for Motion Planning

Robotics 2022-01-03 v1 Optimization and Control

Abstract

We propose a new formulation of optimal motion planning (OMP) algorithm for robots operating in a hazardous environment, called adaptive Gaussian-process based stochastic trajectory optimization (AGP-STO). It first restarts the accelerated gradient descent with the reestimated Lipschitz constant (L-reAGD) to improve the computation efficiency, only requiring 1st-order momentum. However, it still cannot infer a global optimum of the nonconvex problem, informed by the prior information of Gaussian-process (GP) and obstacles. So it then integrates the adaptive stochastic trajectory optimization (ASTO) in the L-reestimation process to learn the GP-prior rewarded by the important samples via accelerated moving averaging (AMA). Moreover, we introduce the incremental optimal motion planning (iOMP) to upgrade AGP-STO to iAGP-STO. It interpolates the trajectory incrementally among the previously optimized waypoints to ensure time-continuous safety. Finally, we benchmark iAGP-STO against the numerical (CHOMP, TrajOpt, GPMP) and sampling (STOMP, RRT-Connect) methods and conduct the tuning experiment of key parameters to show how the integration of L-reAGD, ASTO, and iOMP elevates computation efficiency and reliability. Moreover, the implementation of iAGP- STO on LBR-iiwa, multi-AGV, and rethink-Baxter demonstrates its application in manipulation, collaboration, and assistance.

Keywords

Cite

@article{arxiv.2112.14953,
  title  = {Adaptive Gaussian Process based Stochastic Trajectory Optimization for Motion Planning},
  author = {Feng Yichang and Zhang Haiyun and Wang Jin and Lu Guodong},
  journal= {arXiv preprint arXiv:2112.14953},
  year   = {2022}
}
R2 v1 2026-06-24T08:35:37.394Z