STRIDE: Structured Lagrangian and Stochastic Residual Dynamics via Flow Matching

TL;DR

STRIDE is a dynamics learning framework that combines physics-based models with stochastic residuals to improve prediction accuracy and reliability in uncertain robotic environments.

Contribution

It introduces a joint training approach that separates conservative rigid-body dynamics from stochastic interaction effects using Lagrangian Neural Networks and flow matching.

Findings

20% reduction in long-horizon prediction error

30% reduction in contact force prediction error

Effective modeling of complex stochastic interactions

Abstract

Robotic systems operating in unstructured environments must operate under significant uncertainty arising from intermittent contacts, frictional variability, and unmodeled compliance. While recent model-free approaches have demonstrated impressive performance, many deployment settings still require predictive models that support planning, constraint handling, and online adaptation. Analytical rigid-body models provide strong physical structure but often fail to capture complex interaction effects, whereas purely data-driven models may violate physical consistency, exhibit data bias, and accumulate long-horizon drift. In this work, we propose STRIDE, a dynamics learning framework that explicitly separates conservative rigid-body mechanics from uncertain, effectively stochastic non-conservative interaction effects. The structured component is modeled using a Lagrangian Neural Network (LNN) to preserve energy-consistent inertial dynamics, while residual interaction forces are represented using Conditional Flow Matching (CFM) to capture multi-modal interaction phenomena. The two components are trained jointly end-to-end, enabling the model to retain physical structure while representing complex stochastic behavior. We evaluate STRIDE on systems of increasing complexity, including a pendulum, the Unitree Go1 quadruped, and the Unitree G1 humanoid. Results show 20% reduction in long-horizon prediction error and 30% reduction in contact force prediction error compared to deterministic residual baselines, supporting more reliable model-based control in uncertain robotic environments.