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Main Authors: Abbas, Ammar N., Mehak, Shakra, Chasparis, Georgios C., Kelleher, John D., Guilfoyle, Michael, Leva, Maria Chiara, Ramasubramanian, Aswin K
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2407.02231
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author Abbas, Ammar N.
Mehak, Shakra
Chasparis, Georgios C.
Kelleher, John D.
Guilfoyle, Michael
Leva, Maria Chiara
Ramasubramanian, Aswin K
author_facet Abbas, Ammar N.
Mehak, Shakra
Chasparis, Georgios C.
Kelleher, John D.
Guilfoyle, Michael
Leva, Maria Chiara
Ramasubramanian, Aswin K
contents This study presents a novel methodology incorporating safety constraints into a robotic simulation during the training of deep reinforcement learning (DRL). The framework integrates specific parts of the safety requirements, such as velocity constraints, as specified by ISO 10218, directly within the DRL model that becomes a part of the robot's learning algorithm. The study then evaluated the efficiency of these safety constraints by subjecting the DRL model to various scenarios, including grasping tasks with and without obstacle avoidance. The validation process involved comprehensive simulation-based testing of the DRL model's responses to potential hazards and its compliance. Also, the performance of the system is carried out by the functional safety standards IEC 61508 to determine the safety integrity level. The study indicated a significant improvement in the safety performance of the robotic system. The proposed DRL model anticipates and mitigates hazards while maintaining operational efficiency. This study was validated in a testbed with a collaborative robotic arm with safety sensors and assessed with metrics such as the average number of safety violations, obstacle avoidance, and the number of successful grasps. The proposed approach outperforms the conventional method by a 16.5% average success rate on the tested scenarios in the simulations and 2.5% in the testbed without safety violations. The project repository is available at https://github.com/ammar-n-abbas/sim2real-ur-gym-gazebo.
format Preprint
id arxiv_https___arxiv_org_abs_2407_02231
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Safety-Driven Deep Reinforcement Learning Framework for Cobots: A Sim2Real Approach
Abbas, Ammar N.
Mehak, Shakra
Chasparis, Georgios C.
Kelleher, John D.
Guilfoyle, Michael
Leva, Maria Chiara
Ramasubramanian, Aswin K
Robotics
Machine Learning
This study presents a novel methodology incorporating safety constraints into a robotic simulation during the training of deep reinforcement learning (DRL). The framework integrates specific parts of the safety requirements, such as velocity constraints, as specified by ISO 10218, directly within the DRL model that becomes a part of the robot's learning algorithm. The study then evaluated the efficiency of these safety constraints by subjecting the DRL model to various scenarios, including grasping tasks with and without obstacle avoidance. The validation process involved comprehensive simulation-based testing of the DRL model's responses to potential hazards and its compliance. Also, the performance of the system is carried out by the functional safety standards IEC 61508 to determine the safety integrity level. The study indicated a significant improvement in the safety performance of the robotic system. The proposed DRL model anticipates and mitigates hazards while maintaining operational efficiency. This study was validated in a testbed with a collaborative robotic arm with safety sensors and assessed with metrics such as the average number of safety violations, obstacle avoidance, and the number of successful grasps. The proposed approach outperforms the conventional method by a 16.5% average success rate on the tested scenarios in the simulations and 2.5% in the testbed without safety violations. The project repository is available at https://github.com/ammar-n-abbas/sim2real-ur-gym-gazebo.
title Safety-Driven Deep Reinforcement Learning Framework for Cobots: A Sim2Real Approach
topic Robotics
Machine Learning
url https://arxiv.org/abs/2407.02231