Is Linear Feedback on Smoothed Dynamics Sufficient for Stabilizing Contact-Rich Plans?
Designing planners and controllers for contact-rich manipulation is extremely challenging as contact violates the smoothness conditions that many gradient-based controller synthesis tools assume. Contact smoothing approximates a non-smooth system with a smooth one, allowing one to use these synthesi...
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| creator | Shirai, Yuki Zhao, Tong Suh, H. J. Terry Zhu, Huaijiang Ni, Xinpei Wang, Jiuguang Simchowitz, Max Pang, Tao |
| description | Designing planners and controllers for contact-rich manipulation is extremely
challenging as contact violates the smoothness conditions that many
gradient-based controller synthesis tools assume. Contact smoothing
approximates a non-smooth system with a smooth one, allowing one to use these
synthesis tools more effectively. However, applying classical control synthesis
methods to smoothed contact dynamics remains relatively under-explored. This
paper analyzes the efficacy of linear controller synthesis using differential
simulators based on contact smoothing. We introduce natural baselines for
leveraging contact smoothing to compute (a) open-loop plans robust to uncertain
conditions and/or dynamics, and (b) feedback gains to stabilize around
open-loop plans. Using robotic bimanual whole-body manipulation as a testbed,
we perform extensive empirical experiments on over 300 trajectories and analyze
why LQR seems insufficient for stabilizing contact-rich plans. The video
summarizing this paper and hardware experiments is found here:
https://youtu.be/HLaKi6qbwQg?si=_zCAmBBD6rGSitm9. |
| doi_str_mv | 10.48550/arxiv.2411.06542 |
| format | Article |
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challenging as contact violates the smoothness conditions that many
gradient-based controller synthesis tools assume. Contact smoothing
approximates a non-smooth system with a smooth one, allowing one to use these
synthesis tools more effectively. However, applying classical control synthesis
methods to smoothed contact dynamics remains relatively under-explored. This
paper analyzes the efficacy of linear controller synthesis using differential
simulators based on contact smoothing. We introduce natural baselines for
leveraging contact smoothing to compute (a) open-loop plans robust to uncertain
conditions and/or dynamics, and (b) feedback gains to stabilize around
open-loop plans. Using robotic bimanual whole-body manipulation as a testbed,
we perform extensive empirical experiments on over 300 trajectories and analyze
why LQR seems insufficient for stabilizing contact-rich plans. The video
summarizing this paper and hardware experiments is found here:
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challenging as contact violates the smoothness conditions that many
gradient-based controller synthesis tools assume. Contact smoothing
approximates a non-smooth system with a smooth one, allowing one to use these
synthesis tools more effectively. However, applying classical control synthesis
methods to smoothed contact dynamics remains relatively under-explored. This
paper analyzes the efficacy of linear controller synthesis using differential
simulators based on contact smoothing. We introduce natural baselines for
leveraging contact smoothing to compute (a) open-loop plans robust to uncertain
conditions and/or dynamics, and (b) feedback gains to stabilize around
open-loop plans. Using robotic bimanual whole-body manipulation as a testbed,
we perform extensive empirical experiments on over 300 trajectories and analyze
why LQR seems insufficient for stabilizing contact-rich plans. The video
summarizing this paper and hardware experiments is found here:
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challenging as contact violates the smoothness conditions that many
gradient-based controller synthesis tools assume. Contact smoothing
approximates a non-smooth system with a smooth one, allowing one to use these
synthesis tools more effectively. However, applying classical control synthesis
methods to smoothed contact dynamics remains relatively under-explored. This
paper analyzes the efficacy of linear controller synthesis using differential
simulators based on contact smoothing. We introduce natural baselines for
leveraging contact smoothing to compute (a) open-loop plans robust to uncertain
conditions and/or dynamics, and (b) feedback gains to stabilize around
open-loop plans. Using robotic bimanual whole-body manipulation as a testbed,
we perform extensive empirical experiments on over 300 trajectories and analyze
why LQR seems insufficient for stabilizing contact-rich plans. The video
summarizing this paper and hardware experiments is found here:
https://youtu.be/HLaKi6qbwQg?si=_zCAmBBD6rGSitm9.</abstract><doi>10.48550/arxiv.2411.06542</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Computer Science - Artificial Intelligence Computer Science - Robotics Computer Science - Systems and Control |
| title | Is Linear Feedback on Smoothed Dynamics Sufficient for Stabilizing Contact-Rich Plans? |
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