A Geometric Task-Space Port-Hamiltonian Formulation for Redundant Manipulators

Federico Califano; Camilla Rota; Riccardo Zanella; Antonio Franchi

doi:10.48550/arXiv.2512.14349

A Geometric Task-Space Port-Hamiltonian Formulation for Redundant Manipulators

Federico Califano
, Camilla Rota
, Riccardo Zanella
, Antonio Franchi

Research output: Working paper › Preprint › Academic

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Abstract

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.

Original language	English
Publisher	ArXiv.org
DOIs	https://doi.org/10.48550/arXiv.2512.14349
Publication status	Published - 16 Dec 2025

Keywords

eess.SY
cs.RO

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10.48550/arXiv.2512.14349Licence: CC BY

2512.14349v1Final published version, 1.34 MBLicence: CC BY

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title = "A Geometric Task-Space Port-Hamiltonian Formulation for Redundant Manipulators",

abstract = "We present a novel geometric port-Hamiltonian formulation of redundant manipulators performing a differential kinematic task \$η=J(q)\textbackslash{}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 \textbackslash{}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.",

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AU - Califano, Federico

AU - Rota, Camilla

AU - Zanella, Riccardo

AU - Franchi, Antonio

PY - 2025/12/16

Y1 - 2025/12/16

N2 - 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.

AB - 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.

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BT - A Geometric Task-Space Port-Hamiltonian Formulation for Redundant Manipulators

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A Geometric Task-Space Port-Hamiltonian Formulation for Redundant Manipulators

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