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A Learning-Based Framework for Safe Human-Robot Collaboration with Multiple Backup Control Barrier Functions

Robotics 2024-03-08 v3 Systems and Control Systems and Control

Abstract

Ensuring robot safety in complex environments is a difficult task due to actuation limits, such as torque bounds. This paper presents a safety-critical control framework that leverages learning-based switching between multiple backup controllers to formally guarantee safety under bounded control inputs while satisfying driver intention. By leveraging backup controllers designed to uphold safety and input constraints, backup control barrier functions (BCBFs) construct implicitly defined control invariance sets via a feasible quadratic program (QP). However, BCBF performance largely depends on the design and conservativeness of the chosen backup controller, especially in our setting of human-driven vehicles in complex, e.g, off-road, conditions. While conservativeness can be reduced by using multiple backup controllers, determining when to switch is an open problem. Consequently, we develop a broadcast scheme that estimates driver intention and integrates BCBFs with multiple backup strategies for human-robot interaction. An LSTM classifier uses data inputs from the robot, human, and safety algorithms to continually choose a backup controller in real-time. We demonstrate our method's efficacy on a dual-track robot in obstacle avoidance scenarios. Our framework guarantees robot safety while adhering to driver intention.

Keywords

Cite

@article{arxiv.2310.05865,
  title  = {A Learning-Based Framework for Safe Human-Robot Collaboration with Multiple Backup Control Barrier Functions},
  author = {Neil C. Janwani and Ersin Daş and Thomas Touma and Skylar X. Wei and Tamas G. Molnar and Joel W. Burdick},
  journal= {arXiv preprint arXiv:2310.05865},
  year   = {2024}
}

Comments

Accepted to the International Conference on Robotics and Automation 2024

R2 v1 2026-06-28T12:44:52.583Z