English

A data-efficient geometrically inspired polynomial kernel for robot inverse dynamics

Robotics 2020-01-28 v4 Machine Learning Systems and Control

Abstract

In this paper, we introduce a novel data-driven inverse dynamics estimator based on Gaussian Process Regression. Driven by the fact that the inverse dynamics can be described as a polynomial function on a suitable input space, we propose the use of a novel kernel, called Geometrically Inspired Polynomial Kernel (GIP). The resulting estimator behaves similarly to model-based approaches as concerns data efficiency. Indeed, we proved that the GIP kernel defines a finite-dimensional Reproducing Kernel Hilbert Space that contains the inverse dynamics function computed through the Rigid Body Dynamics. The proposed kernel is based on the recently introduced Multiplicative Polynomial Kernel, a redefinition of the classical polynomial kernel equipped with a set of parameters that allows for a higher regularization. We tested the proposed approach in a simulated environment, and also in real experiments with a UR10 robot. The obtained results confirm that, compared to other data-driven estimators, the proposed approach is more data-efficient and exhibits better generalization properties. Instead, with respect to model-based estimators, our approach requires less prior information and is not affected by model bias.

Keywords

Cite

@article{arxiv.1904.13317,
  title  = {A data-efficient geometrically inspired polynomial kernel for robot inverse dynamics},
  author = {Alberto Dalla Libera and Ruggero Carli},
  journal= {arXiv preprint arXiv:1904.13317},
  year   = {2020}
}
R2 v1 2026-06-23T08:53:31.556Z