English

Learning Neural Observer-Predictor Models for Limb-level Sampling-based Locomotion Planning

Robotics 2025-10-28 v1

Abstract

Accurate full-body motion prediction is essential for the safe, autonomous navigation of legged robots, enabling critical capabilities like limb-level collision checking in cluttered environments. Simplified kinematic models often fail to capture the complex, closed-loop dynamics of the robot and its low-level controller, limiting their predictions to simple planar motion. To address this, we present a learning-based observer-predictor framework that accurately predicts this motion. Our method features a neural observer with provable UUB guarantees that provides a reliable latent state estimate from a history of proprioceptive measurements. This stable estimate initializes a computationally efficient predictor, designed for the rapid, parallel evaluation of thousands of potential trajectories required by modern sampling-based planners. We validated the system by integrating our neural predictor into an MPPI-based planner on a Vision 60 quadruped. Hardware experiments successfully demonstrated effective, limb-aware motion planning in a challenging, narrow passage and over small objects, highlighting our system's ability to provide a robust foundation for high-performance, collision-aware planning on dynamic robotic platforms.

Keywords

Cite

@article{arxiv.2510.22789,
  title  = {Learning Neural Observer-Predictor Models for Limb-level Sampling-based Locomotion Planning},
  author = {Abhijeet M. Kulkarni and Ioannis Poulakakis and Guoquan Huang},
  journal= {arXiv preprint arXiv:2510.22789},
  year   = {2025}
}
R2 v1 2026-07-01T07:06:43.949Z