Automating Planar Object Singulation by Linear Pushing with Single-point and Multi-point Contacts

Singulation is useful for manufacturing, logistics, and service applications; we consider the problem in a planar setting. We propose a novel O(n(n + v)) linear push policy (n denotes the number of objects, v denotes the maximum number of vertices per object), ClusterPush, that can be efficiently co...

Full description

Saved in:
Bibliographic Details
Main Authors: Dong, Zisu, Krishnan, Sanjay, Dolasia, Sona, Balakrishna, Ashwin, Danielczuk, Michael, Goldberg, Ken
Format: Conference Proceeding
Language:English
Subjects:
Computational modeling
Friction
Grippers
Manufacturing
Robots
Trajectory
Two dimensional displays
Online Access:Request full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Singulation is useful for manufacturing, logistics, and service applications; we consider the problem in a planar setting. We propose a novel O(n(n + v)) linear push policy (n denotes the number of objects, v denotes the maximum number of vertices per object), ClusterPush, that can be efficiently computed using clustering. To evaluate the policy, we define singulation distance as the average pairwise distance of polygon centroids given random arrangements of 2D polygonal objects on a surface, and seek pushing policies that can maximize singulation distance. When compared with a brute force evaluation of all candidate pushes in Box2D simulator using 50,000 pushing scenarios, ClusterPush achieves 70% of the singulation distance achieved using brute force and is 2000x faster. ClusterPush also improves on previous pushing policies and can be used for multi-point pushes with two-point and edge (infinite-point) contacts. Compared with pushes with single-point contacts using ClusterPush, pushes with two-point and edge contacts improve singulation by 7% and 13% respectively. In physical experiments conducted with an ABB YuMi robot on 40 sets of 3-7 blocks, ClusterPush increases singulation distance by 15-30%, outperforming the next best policy by 24% on average. Data and code are available at https://github.com/Jekyll1021/MultiPointPushing.
ISSN:2161-8089
DOI:10.1109/COASE.2019.8843111