Safety-Critical Manipulation for Collision-Free Food Preparation
Abstract
Recent advances allow for the automation of food preparation in high-throughput environments, yet the successful deployment of these robots requires the planning and execution of quick, robust, and ultimately collision-free behaviors. In this work, we showcase a novel framework for modifying previously generated trajectories of robotic manipulators in highly detailed and dynamic collision environments using Control Barrier Functions (CBFs). This method dynamically re-plans previously validated behaviors in the presence of changing environments—and does so in a computationally efficient manner. Moreover, the approach provides rigorous safety guarantees of the resulting trajectories, factoring in the true underlying dynamics of the manipulator. This methodology is extensively validated on a full-scale robotic manipulator in a real-world cooking environment, and has resulted in substantial improvements in computation time and robustness over re-planning.
Additional Information
© 2022 IEEE. Manuscript received: February, 24, 2022; Revised June, 2, 2022; Accepted June, 27, 2022. This paper was recommended for publication by Editor Clement Gosselin upon evaluation of the Associate Editor and Reviewers' comments. This work is supported by Miso Robotics and NSF CPS award #1932091.Attached Files
Accepted Version - Safety-Critical_Manipulation_for_Collision-Free_Food_Preparation.pdf
Submitted - 2205.01026.pdf
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Additional details
- Eprint ID
- 115564
- Resolver ID
- CaltechAUTHORS:20220714-194307878
- Miso Robotics
- NSF
- CNS-1932091
- Created
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2022-07-15Created from EPrint's datestamp field
- Updated
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2022-09-02Created from EPrint's last_modified field