Trajectory Optimization for High-Dimensional Nonlinear Systems under STL Specifications
Abstract
Signal Temporal Logic (STL) has gained popularity in recent years as a specification language for cyber-physical systems, especially in robotics. Beyond being expressive and easy to understand, STL is appealing because the synthesis problem---generating a trajectory that satisfies a given specification---can be formulated as a trajectory optimization problem. Unfortunately, the associated cost function is nonsmooth and non-convex. As a result, existing synthesis methods scale poorly to high-dimensional nonlinear systems. In this letter, we present a new trajectory optimization approach for STL synthesis based on Differential Dynamic Programming (DDP). It is well known that DDP scales well to extremely high-dimensional nonlinear systems like robotic quadrupeds and humanoids: we show that these advantages can be harnessed for STL synthesis. We prove the soundness of our proposed approach, demonstrate order-of-magnitude speed improvements over the state-of-the-art on several benchmark problems, and demonstrate the scalability of our approach to the full nonlinear dynamics of a 7 degree-of-freedom robot arm.
Cite
@article{arxiv.2011.07104,
title = {Trajectory Optimization for High-Dimensional Nonlinear Systems under STL Specifications},
author = {Vince Kurtz and Hai Lin},
journal= {arXiv preprint arXiv:2011.07104},
year = {2020}
}
Comments
Accepted to L-CSS