English

Online Dynamic Trajectory Optimization and Control for a Quadruped Robot

Robotics 2021-03-24 v3

Abstract

Legged robot locomotion requires the planning of stable reference trajectories, especially while traversing uneven terrain. The proposed trajectory optimization framework is capable of generating dynamically stable base and footstep trajectories for multiple steps. The locomotion task can be defined with contact locations, base motion or both, making the algorithm suitable for multiple scenarios (e.g., presence of moving obstacles). The planner uses a simplified momentum-based task space model for the robot dynamics, allowing computation times that are fast enough for online replanning.This fast planning capabilitiy also enables the quadruped to accommodate for drift and environmental changes. The algorithm is tested on simulation and a real robot across multiple scenarios, which includes uneven terrain, stairs and moving obstacles. The results show that the planner is capable of generating stable trajectories in the real robot even when a box of 15 cm height is placed in front of its path at the last moment.

Keywords

Cite

@article{arxiv.2008.12687,
  title  = {Online Dynamic Trajectory Optimization and Control for a Quadruped Robot},
  author = {Oguzhan Cebe and Carlo Tiseo and Guiyang Xin and Hsiu-chin Lin and Joshua Smith and Michael Mistry},
  journal= {arXiv preprint arXiv:2008.12687},
  year   = {2021}
}

Comments

7 pages, 10 figures, for video see https://bit.ly/3gyccU6

R2 v1 2026-06-23T18:10:03.215Z