Lie-algebra Adaptive Tracking Control for Rigid Body Dynamics

TL;DR

This paper introduces a Lie-algebra-based adaptive control method for rigid body dynamics that respects the manifold structure, enabling more accurate and efficient control in robotics.

Contribution

It proposes a novel geometric adaptive control approach leveraging Lie algebra, transforming the state space to derive linear error dynamics and improve control accuracy.

Findings

Demonstrates effectiveness through extensive simulations

Achieves computational efficiency and geometric consistency

Provides publicly available source code for further research

Abstract

Adaptive tracking control for rigid body dynamics is of critical importance in control and robotics, particularly for addressing uncertainties or variations in system model parameters. However, most existing adaptive control methods are designed for systems with states in vector spaces, often neglecting the manifold constraints inherent to robotic systems. In this work, we propose a novel Lie-algebra-based adaptive control method that leverages the intrinsic relationship between the special Euclidean group and its associated Lie algebra. By transforming the state space from the group manifold to a vector space, we derive a linear error dynamics model that decouples model parameters from the system state. This formulation enables the development of an adaptive optimal control method that is both geometrically consistent and computationally efficient. Extensive simulations demonstrate the effectiveness and efficiency of the proposed method. We have made our source code publicly available to the community to support further research and collaboration.