A constraint programming model for the scheduling and workspace layout design of a dual-arm multi-tool assembly robot-Reference-Cited by-同舟云学术

A constraint programming model for the scheduling and workspace layout design of a dual-arm multi-tool assembly robot

Published:2023-06 Issue:2 Volume:28 Page:71-104
ISSN:1383-7133
Container-title:Constraints
language:en
Short-container-title:Constraints

Author:

Wessén Johan^ORCID,Carlsson Mats^ORCID,Schulte Christian^ORCID,Flener Pierre^ORCID,Pecora Federico^ORCID,Matskin Mihhail^ORCID

Abstract

AbstractThe generation of a robot program can be seen as a collection of sub-problems, where many combinations of some of these sub-problems are well studied. The performance of a robot program is strongly conditioned by the location of the tasks. However, the scope of previous methods does not include workspace layout design, likely missing high-quality solutions. In industrial applications, designing robot workspace layout is part of the commissioning. We broaden the scope and show how to model a dual-arm multi-tool robot assembly problem. Our model includes more robot programming sub-problems than previous methods, as well as workspace layout design. We propose a constraint programming formulation in MiniZinc that includes elements from scheduling and routing, extended with variable task locations. We evaluate the model on realistic assembly problems and workspaces, utilizing the dual-arm YuMi robot from ABB Ltd. We also evaluate redundant constraints and various formulations for avoiding arm-to-arm collisions. The best model variant quickly finds high-quality solutions for all problem instances. This demonstrates the potential of our approach as a valuable tool for a robot programmer.

Funder

Royal Institute of Technology

Publisher

Springer Science and Business Media LLC

Subject

Artificial Intelligence,Computational Theory and Mathematics,Discrete Mathematics and Combinatorics,Software

Link

https://link.springer.com/content/pdf/10.1007/s10601-023-09345-4.pdf

Reference50 articles.

1. ABB AB. (2022) The ABB YuMi industrial robot. https://new.abb.com/products/robotics/collaborative-robots/irb-14000-yumi

2. Behrens, J.K., Lange, R., Mansouri, M. (2019) A constraint programming approach to simultaneous task allocation and motion scheduling for industrial dual-arm manipulation tasks. In: International Conference on Robotics and Automation (ICRA) . https://doi.org/10.1109/ICRA.2019.8794022

3. Brain, M.N., Davenport, J.H., Griggio, A. (2022) Benchmarking solvers, sat-style. http://www.sc-square.org/CSA/workshop2-papers/RP3-FinalVersion.pdf

4. Brauner, N. (2008). Identical part production in cyclic robotic cells: concepts, overview and open questions. Discrete Applied Mathematics, 156(13), 2480–2492. https://doi.org/10.1016/j.dam.2008.03.021

5. Burgard, W., Cremers, A.B., Fox, D., Hähnel, D., Lakemeyer, G., Schulz, D., Steiner, W., Thrun, S. (1998) The interactive museum tour-guide robot. In: National Conference on Artificial Intelligence (AAAI). pp. 11–18. American Association for Artificial Intelligence, USA. https://www.aaai.org/Library/AAAI/1998/aaai98-002.php