A Geometric Task-Space Port-Hamiltonian Formulation for Redundant Manipulators
By: Federico Califano , Camilla Rota , Riccardo Zanella and more
We present a novel geometric port-Hamiltonian formulation of redundant manipulators performing a differential kinematic task $η=J(q)\dot{q}$, where $q$ is a point on the configuration manifold, $η$ is a velocity-like task space variable, and $J(q)$ is a linear map representing the task, for example the classical analytic or geometric manipulator Jacobian matrix. The proposed model emerges from a change of coordinates from canonical Hamiltonian dynamics, and splits the standard Hamiltonian momentum variable into a task-space momentum variable and a null-space momentum variable. Properties of this model and relation to Lagrangian formulations present in the literature are highlighted. Finally, we apply the proposed model in an \textit{Interconnection and Damping Assignment Passivity-Based Control} (IDA-PBC) design to stabilize and shape the impedance of a 7-DOF Emika Panda robot in simulation.
Similar Papers
Multimodal Control of Manipulators: Coupling Kinematics and Vision for Self-Driving Laboratory Operations
Robotics
Helps robots move their arms smoothly and precisely.
Optimal Control and Structurally-Informed Gradient Optimization of a Custom 4-DOF Rigid-Body Manipulator
Robotics
Makes robot arms move precisely and quickly.
Leveraging Port-Hamiltonian Theory for Impedance Control Benchmarking
Robotics
Makes robots move more smoothly and safely.