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Main Authors: Jayasinghe, Nethmi, Gontero, Diana, Migliarba, Francesco, Brown, Spencer T., Sangwan, Vinod K., Hersam, Mark C., Trivedi, Amit Ranjan
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.07775
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author Jayasinghe, Nethmi
Gontero, Diana
Migliarba, Francesco
Brown, Spencer T.
Sangwan, Vinod K.
Hersam, Mark C.
Trivedi, Amit Ranjan
author_facet Jayasinghe, Nethmi
Gontero, Diana
Migliarba, Francesco
Brown, Spencer T.
Sangwan, Vinod K.
Hersam, Mark C.
Trivedi, Amit Ranjan
contents Robotic systems operating in real-world environments inevitably encounter unobserved dynamics shifts during continuous execution, including changes in actuation, mass distribution, or contact conditions. When such shifts occur mid-episode, even locally stabilizing learned policies can experience substantial transient performance degradation. While input-to-state stability guarantees bounded state deviation, it does not ensure rapid restoration of task-level performance. We address inference-time recovery under frozen policy parameters by casting adaptation as constrained disturbance shaping around a nominal stabilizing controller. We propose a stability-aligned residual control architecture in which a reinforcement learning policy trained under nominal dynamics remains fixed at deployment, and adaptation occurs exclusively through a bounded additive residual channel. A Stability Alignment Gate (SAG) regulates corrective authority through magnitude constraints, directional coherence with the nominal action, performance-conditioned activation, and adaptive gain modulation. These mechanisms preserve the nominal closed-loop structure while enabling rapid compensation for unobserved dynamics shifts without retraining or privileged disturbance information. Across mid-episode perturbations including actuator degradation, mass variation, and contact changes, the proposed method consistently reduces recovery time relative to frozen and online-adaptation baselines while maintaining near-nominal steady-state performance. Recovery time is reduced by \textbf{87\%} on the Go1 quadruped, \textbf{48\%} on the Cassie biped, \textbf{30\%} on the H1 humanoid, and \textbf{20\%} on the Scout wheeled platform on average across evaluated conditions relative to a frozen SAC policy.
format Preprint
id arxiv_https___arxiv_org_abs_2603_07775
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Residual Control for Fast Recovery from Dynamics Shifts
Jayasinghe, Nethmi
Gontero, Diana
Migliarba, Francesco
Brown, Spencer T.
Sangwan, Vinod K.
Hersam, Mark C.
Trivedi, Amit Ranjan
Robotics
Robotic systems operating in real-world environments inevitably encounter unobserved dynamics shifts during continuous execution, including changes in actuation, mass distribution, or contact conditions. When such shifts occur mid-episode, even locally stabilizing learned policies can experience substantial transient performance degradation. While input-to-state stability guarantees bounded state deviation, it does not ensure rapid restoration of task-level performance. We address inference-time recovery under frozen policy parameters by casting adaptation as constrained disturbance shaping around a nominal stabilizing controller. We propose a stability-aligned residual control architecture in which a reinforcement learning policy trained under nominal dynamics remains fixed at deployment, and adaptation occurs exclusively through a bounded additive residual channel. A Stability Alignment Gate (SAG) regulates corrective authority through magnitude constraints, directional coherence with the nominal action, performance-conditioned activation, and adaptive gain modulation. These mechanisms preserve the nominal closed-loop structure while enabling rapid compensation for unobserved dynamics shifts without retraining or privileged disturbance information. Across mid-episode perturbations including actuator degradation, mass variation, and contact changes, the proposed method consistently reduces recovery time relative to frozen and online-adaptation baselines while maintaining near-nominal steady-state performance. Recovery time is reduced by \textbf{87\%} on the Go1 quadruped, \textbf{48\%} on the Cassie biped, \textbf{30\%} on the H1 humanoid, and \textbf{20\%} on the Scout wheeled platform on average across evaluated conditions relative to a frozen SAC policy.
title Residual Control for Fast Recovery from Dynamics Shifts
topic Robotics
url https://arxiv.org/abs/2603.07775