English

Quantifying and Visualizing Sim-to-Real Gaps: Physics-Guided Regularization for Reproducibility

Robotics 2025-08-01 v1 Systems and Control Systems and Control

Abstract

Simulation-to-real transfer using domain randomization for robot control often relies on low-gear-ratio, backdrivable actuators, but these approaches break down when the sim-to-real gap widens. Inspired by the traditional PID controller, we reinterpret its gains as surrogates for complex, unmodeled plant dynamics. We then introduce a physics-guided gain regularization scheme that measures a robot's effective proportional gains via simple real-world experiments. Then, we penalize any deviation of a neural controller's local input-output sensitivities from these values during training. To avoid the overly conservative bias of naive domain randomization, we also condition the controller on the current plant parameters. On an off-the-shelf two-wheeled balancing robot with a 110:1 gearbox, our gain-regularized, parameter-conditioned RNN achieves angular settling times in hardware that closely match simulation. At the same time, a purely domain-randomized policy exhibits persistent oscillations and a substantial sim-to-real gap. These results demonstrate a lightweight, reproducible framework for closing sim-to-real gaps on affordable robotic hardware.

Keywords

Cite

@article{arxiv.2507.23445,
  title  = {Quantifying and Visualizing Sim-to-Real Gaps: Physics-Guided Regularization for Reproducibility},
  author = {Yuta Kawachi},
  journal= {arXiv preprint arXiv:2507.23445},
  year   = {2025}
}
R2 v1 2026-07-01T04:27:37.938Z