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Generalizable Motion Planning via Operator Learning

Robotics 2025-05-28 v3

Abstract

In this work, we introduce a planning neural operator (PNO) for predicting the value function of a motion planning problem. We recast value function approximation as learning a single operator from the cost function space to the value function space, which is defined by an Eikonal partial differential equation (PDE). Therefore, our PNO model, despite being trained with a finite number of samples at coarse resolution, inherits the zero-shot super-resolution property of neural operators. We demonstrate accurate value function approximation at 16×16\times the training resolution on the MovingAI lab's 2D city dataset, compare with state-of-the-art neural value function predictors on 3D scenes from the iGibson building dataset and showcase optimal planning with 4-DOF robotic manipulators. Lastly, we investigate employing the value function output of PNO as a heuristic function to accelerate motion planning. We show theoretically that the PNO heuristic is ϵ\epsilon-consistent by introducing an inductive bias layer that guarantees our value functions satisfy the triangle inequality. With our heuristic, we achieve a 30%30\% decrease in nodes visited while obtaining near optimal path lengths on the MovingAI lab 2D city dataset, compared to classical planning methods (AA^\ast, RRTRRT^\ast).

Keywords

Cite

@article{arxiv.2410.17547,
  title  = {Generalizable Motion Planning via Operator Learning},
  author = {Sharath Matada and Luke Bhan and Yuanyuan Shi and Nikolay Atanasov},
  journal= {arXiv preprint arXiv:2410.17547},
  year   = {2025}
}
R2 v1 2026-06-28T19:32:23.502Z