Euclidean Equivariant Models for Generative Graphical Inverse Kinematics

TL;DR

This paper introduces a Euclidean equivariant graph neural network-based inverse kinematics solver that efficiently generates multiple diverse solutions for various robots, leveraging symmetry and a novel geometric representation.

Contribution

It proposes a novel graph-based, Euclidean equivariant model for inverse kinematics that generalizes across robots, enabling fast, diverse solutions without retraining for each robot.

Findings

The model produces diverse IK solutions efficiently.

It generalizes across different robot configurations.

The approach leverages symmetry for improved performance.

Abstract

Quickly and reliably finding accurate inverse kinematics (IK) solutions remains a challenging problem for robotic manipulation. Existing numerical solvers typically produce a single solution only and rely on local search techniques to minimize a highly nonconvex objective function. Recently, learning-based approaches that approximate the entire feasible set of solutions have shown promise as a means to generate multiple fast and accurate IK results in parallel. However, existing learning-based techniques have a significant drawback: each robot of interest requires a specialized model that must be trained from scratch. To address this shortcoming, we investigate a novel distance-geometric robot representation coupled with a graph structure that allows us to leverage the flexibility of graph neural networks (GNNs). We use this approach to train a generative graphical inverse kinematics solver (GGIK) that is able to produce a large number of diverse solutions in parallel while also generalizing well -- a single learned model can be used to produce IK solutions for a variety of different robots. The graphical formulation elegantly exposes the symmetry and Euclidean equivariance of the IK problem that stems from the spatial nature of robot manipulators. We exploit this symmetry by encoding it into the architecture of our learned model, yielding a flexible solver that is able to produce sets of IK solutions for multiple robots.