Safe-Control-Gym: A Unified Benchmark Suite for Safe Learning-Based Control and Reinforcement Learning in Robotics

In recent years, both reinforcement learning and learning-based control-as well as the study of their safety , which is crucial for deployment in real-world robots-have gained significant traction. However, to adequately gauge the progress and applicability of new results, we need the tools to equit...

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Bibliographic Details
Published inIEEE robotics and automation letters Vol. 7; no. 4; pp. 11142 - 11149
Main Authors Yuan, Zhaocong, Hall, Adam W., Zhou, Siqi, Brunke, Lukas, Greeff, Melissa, Panerati, Jacopo, Schoellig, Angela P.
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 01.10.2022
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Benchmark testing
Benchmarks
Constraint modelling
Control tasks
Learning
Machine learning for robot control
Open source software
Reinforcement learning
Reproducibility
Robot control
robot safety
Robotics
Robots
Safety
software tools for benchmarking and reproducibility
Task analysis
Trajectory control
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Summary:In recent years, both reinforcement learning and learning-based control-as well as the study of their safety , which is crucial for deployment in real-world robots-have gained significant traction. However, to adequately gauge the progress and applicability of new results, we need the tools to equitably compare the approaches proposed by the controls and reinforcement learning communities. Here, we propose a new open-source benchmark suite, called safe-control-gym , supporting both model-based and data-based control techniques. We provide implementations for three dynamic systems-the cart-pole, the 1D, and 2D quadrotor-and two control tasks-stabilization and trajectory tracking. We propose to extend OpenAI's Gym API-the de facto standard in reinforcement learning research-with (i) the ability to specify (and query) symbolic dynamics and (ii) constraints, and (iii) (repeatably) inject simulated disturbances in the control inputs, state measurements, and inertial properties. To demonstrate our proposal and in an attempt to bring research communities closer together, we show how to use safe-control-gym to quantitatively compare the control performance, data efficiency, and safety of multiple approaches from the fields of traditional control, learning-based control, and reinforcement learning.
ISSN:2377-3766
2377-3766
DOI:10.1109/LRA.2022.3196132