Contact-Implicit Trajectory Optimization Using Variational Integrators
Abstract
Contact constraints arise naturally in many robot planning problems. In recent years, a variety of contact-implicit trajectory optimization algorithms have been developed that avoid the pitfalls of mode pre-specification by simultaneously optimizing state, input, and contact force trajectories. However, their reliance on first-order integrators leads to a linear tradeoff between optimization problem size and plan accuracy. To address this limitation, we propose a new family of trajectory optimization algorithms that leverage ideas from discrete variational mechanics to derive higher-order generalizations of the classic time-stepping method of Stewart and Trinkle. By using these dynamics formulations as constraints in direct trajectory optimization algorithms, it is possible to perform contact-implicit trajectory optimization with significantly higher accuracy. For concreteness, we derive a second-order method and evaluate it using several simulated rigid-body systems, including an underactuated biped and a quadruped. In addition, we use this second-order method to plan locomotion trajectories for a complex quadrupedal microrobot. The planned trajectories are evaluated on the physical platform and result in a number of performance improvements.
BibTeX
@article{Manchester-2019-122101,author = {Zac Manchester and Neel Doshi and Robert J. Wood and Scott Kuindersma},
title = {Contact-Implicit Trajectory Optimization Using Variational Integrators},
journal = {International Journal of Robotics Research: Special Issue on ISRR '17},
year = {2019},
month = {October},
volume = {38},
number = {12},
pages = {1463 - 1476},
}