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Port-Hamiltonian Neural ODE Networks on Lie Groups for Robot Dynamics Learning and Control

Thai Duong, Abdullah Altawaitan, Jason Stanley, Nikolay Atanasov

2024IEEE Transactions on Robotics23 citationsDOI

Abstract

Accurate models of robot dynamics are critical for safe and stable control and generalization to novel operational conditions. Hand-designed models, however, may be insufficiently accurate, even after careful parameter tuning. This motivates the use of machine learning techniques to approximate the robot dynamics over a training set of state-control trajectories. The dynamics of many robots are described in terms of their generalized coordinates on a matrix Lie group, e.g., on <inline-formula xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink"><tex-math notation="LaTeX">$\text{SE}(3)$</tex-math></inline-formula> for ground, aerial, and underwater vehicles, and generalized velocity, and satisfy conservation of energy principles. This article proposes a port-Hamiltonian formulation over a Lie group of the structure of a neural ordinary differential equation (ODE) network to approximate the robot dynamics. In contrast to a black-box ODE network, our formulation embeds energy conservation principle and Lie group's constraints in the dynamics model and explicitly accounts for energy-dissipation effect such as friction and drag forces in the dynamics model. We develop energy shaping and damping injection control for the learned, potentially under-actuated Hamiltonian dynamics to enable a unified approach for stabilization and trajectory tracking with various robot platforms.

Topics & Concepts

OdeMobile robotArtificial neural networkRobotComputer scienceHamiltonian mechanicsRobot controlPort (circuit theory)Artificial intelligenceControl engineeringControl (management)Control theory (sociology)MathematicsEngineeringPhysicsApplied mathematicsPhase spaceMechanical engineeringThermodynamicsControl and Stability of Dynamical SystemsModel Reduction and Neural NetworksModeling and Simulation Systems
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