Hybrid Diffusion Policies with Projective Geometric Algebra for Efficient Robot Manipulation Learning

Diffusion policies have become increasingly popular in robot learning due to their reliable convergence in motion generation tasks. At a high level, these policies learn to transform noisy action trajectories into effective ones, conditioned on observations. However, each time such a model is trained in a robotics context, the network must relearn fundamental spatial representations and operations, such as translations and rotations, from scratch in order to ground itself and operate effectively in a 3D environment. Incorporating geometric inductive biases directly into the network can alleviate this redundancy and substantially improve training efficiency. In this paper, we introduce hPGA-DP, a diffusion policy approach that integrates a mathematical framework called Projective Geometric Algebra (PGA) to embed strong geometric inductive biases. PGA is particularly well-suited for this purpose as it provides a unified algebraic framework that naturally encodes geometric primitives, such as points, directions, and rotations, enabling neural networks to reason about spatial structure through interpretable and composable operations. Specifically, we propose a novel diffusion policy architecture that incorporates the Projective Geometric Algebra Transformer (P-GATr), leveraging its E(3)-equivariant properties established in prior work. Our approach adopts a hybrid architecture strategy, using P-GATr as both a state encoder and action decoder, while employing U-Net or Transformer-based modules for the denoising process. Several experiments and ablation studies in both simulated and real-world environments demonstrate that hPGA-DP not only improves task performance and training efficiency through the geometric bias of P-GATr, but also achieves substantially faster convergence through its hybrid model compared to architectures that rely solely on P-GATr.