Sampling-based methods for factored task and motion planning

Author(s)

Garrett, Caelan Reed; Lozano-Pérez, Tomás; Kaelbling, Leslie P

Abstract

This paper presents a general-purpose formulation of a large class of discrete-time planning problems, with hybrid state and control-spaces, as factored transition systems. Factoring allows state transitions to be described as the intersection of several constraints each affecting a subset of the state and control variables. Robotic manipulation problems with many movable objects involve constraints that only affect several variables at a time and therefore exhibit large amounts of factoring. We develop a theoretical framework for solving factored transition systems with sampling-based algorithms. The framework characterizes conditions on the submanifold in which solutions lie, leading to a characterization of robust feasibility that incorporates dimensionality-reducing constraints. It then connects those conditions to corresponding conditional samplers that can be composed to produce values on this submanifold. We present two domain-independent, probabilistically complete planning algorithms that take, as input, a set of conditional samplers. We demonstrate the empirical efficiency of these algorithms on a set of challenging task and motion planning problems involving picking, placing, and pushing. Keywords: task and motion planning; manipulation planning; AI reasoning

Date issued

2018-10-10

URI

https://hdl.handle.net/1721.1/124490

Department

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory

Journal

International Journal of Robotics Research

Publisher

SAGE Publications

Citation

Garrett, Caelan Reed, Lozano-Pérez, Tomás and Kaelbling, Leslie Pack. "Sampling-based methods for factored task and motion planning." International Journal of Robotics Research 37, 13/14 (December 2018): 1796-1825 © The Author(s) 2018.

Version: Author's final manuscript

ISSN

0278-3649

1741-3176