English

Directionality-Aware Mixture Model Parallel Sampling for Efficient Linear Parameter Varying Dynamical System Learning

Robotics 2024-03-26 v3 Systems and Control Systems and Control

Abstract

The Linear Parameter Varying Dynamical System (LPV-DS) is an effective approach that learns stable, time-invariant motion policies using statistical modeling and semi-definite optimization to encode complex motions for reactive robot control. Despite its strengths, the LPV-DS learning approach faces challenges in achieving a high model accuracy without compromising the computational efficiency. To address this, we introduce the Directionality-Aware Mixture Model (DAMM), a novel statistical model that applies the Riemannian metric on the n-sphere Sn\mathbb{S}^n to efficiently blend non-Euclidean directional data with Rm\mathbb{R}^m Euclidean states. Additionally, we develop a hybrid Markov chain Monte Carlo technique that combines Gibbs Sampling with Split/Merge Proposal, allowing for parallel computation to drastically speed up inference. Our extensive empirical tests demonstrate that LPV-DS integrated with DAMM achieves higher reproduction accuracy, better model efficiency, and near real-time/online learning compared to standard estimation methods on various datasets. Lastly, we demonstrate its suitability for incrementally learning multi-behavior policies in real-world robot experiments.

Keywords

Cite

@article{arxiv.2309.02609,
  title  = {Directionality-Aware Mixture Model Parallel Sampling for Efficient Linear Parameter Varying Dynamical System Learning},
  author = {Sunan Sun and Haihui Gao and Tianyu Li and Nadia Figueroa},
  journal= {arXiv preprint arXiv:2309.02609},
  year   = {2024}
}
R2 v1 2026-06-28T12:13:41.903Z