Predicting Object Interactions with Behavior Primitives: An Application in Stowing Tasks
Abstract
Stowing, the task of placing objects in cluttered shelves or bins, is a common task in warehouse and manufacturing operations. However, this task is still predominantly carried out by human workers as stowing is challenging to automate due to the complex multi-object interactions and long-horizon nature of the task. Previous works typically involve extensive data collection and costly human labeling of semantic priors across diverse object categories. This paper presents a method to learn a generalizable robot stowing policy from predictive model of object interactions and a single demonstration with behavior primitives. We propose a novel framework that utilizes Graph Neural Networks to predict object interactions within the parameter space of behavioral primitives. We further employ primitive-augmented trajectory optimization to search the parameters of a predefined library of heterogeneous behavioral primitives to instantiate the control action. Our framework enables robots to proficiently execute long-horizon stowing tasks with a few keyframes (3-4) from a single demonstration. Despite being solely trained in a simulation, our framework demonstrates remarkable generalization capabilities. It efficiently adapts to a broad spectrum of real-world conditions, including various shelf widths, fluctuating quantities of objects, and objects with diverse attributes such as sizes and shapes.
Cite
@article{arxiv.2309.16873,
title = {Predicting Object Interactions with Behavior Primitives: An Application in Stowing Tasks},
author = {Haonan Chen and Yilong Niu and Kaiwen Hong and Shuijing Liu and Yixuan Wang and Yunzhu Li and Katherine Driggs-Campbell},
journal= {arXiv preprint arXiv:2309.16873},
year = {2023}
}
Comments
Project Page: https://haonan16.github.io/stow_page/ 16 pages, 9 figures, Accepted for an oral presentation at CoRL 2023