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Fast Model Identification via Physics Engines for Data-Efficient Policy Search

Robotics 2018-06-14 v3 Artificial Intelligence Machine Learning

Abstract

This paper presents a method for identifying mechanical parameters of robots or objects, such as their mass and friction coefficients. Key features are the use of off-the-shelf physics engines and the adaptation of a Bayesian optimization technique towards minimizing the number of real-world experiments needed for model-based reinforcement learning. The proposed framework reproduces in a physics engine experiments performed on a real robot and optimizes the model's mechanical parameters so as to match real-world trajectories. The optimized model is then used for learning a policy in simulation, before real-world deployment. It is well understood, however, that it is hard to exactly reproduce real trajectories in simulation. Moreover, a near-optimal policy can be frequently found with an imperfect model. Therefore, this work proposes a strategy for identifying a model that is just good enough to approximate the value of a locally optimal policy with a certain confidence, instead of wasting effort on identifying the most accurate model. Evaluations, performed both in simulation and on a real robotic manipulation task, indicate that the proposed strategy results in an overall time-efficient, integrated model identification and learning solution, which significantly improves the data-efficiency of existing policy search algorithms.

Keywords

Cite

@article{arxiv.1710.08893,
  title  = {Fast Model Identification via Physics Engines for Data-Efficient Policy Search},
  author = {Shaojun Zhu and Andrew Kimmel and Kostas E. Bekris and Abdeslam Boularias},
  journal= {arXiv preprint arXiv:1710.08893},
  year   = {2018}
}

Comments

IJCAI 18

R2 v1 2026-06-22T22:24:24.784Z