%0 Journal Article %1 holicki2023energy %A Holicki, Tobias %A Nicodemus, Jonas %A Schwerdtner, Paul %A Unger, Benjamin %D 2023 %K %T Energy matching in reduced passive and port-Hamiltonian systems %X It is well known that any port-Hamiltonian (pH) system is passive, and conversely, any minimal and stable passive system has a pH representation. Nevertheless, this equivalence is only concerned with the input-output mapping but not with the Hamiltonian itself. Thus, we propose to view a pH system either as an enlarged dynamical system with the Hamiltonian as additional output or as two dynamical systems with the input-output and the Hamiltonian dynamic. Our first main result is a structure-preserving Kalman-like decomposition of the enlarged pH system that separates the controllable and zero-state observable parts. Moreover, for further approximations in the context of structure-preserving model-order reduction (MOR), we propose to search for a Hamiltonian in the reduced pH system that minimizes the 2-distance to the full-order Hamiltonian without altering the input-output dynamic, thus discussing a particular aspect of the corresponding multi-objective minimization problem corresponding to $H_2$-optimal MOR for pH systems. We show that this optimization problem is uniquely solvable, can be recast as a standard semidefinite program, and present two numerical approaches for solving it. The results are illustrated with three academic examples.

@article{holicki2023energy, abstract = {It is well known that any port-Hamiltonian (pH) system is passive, and conversely, any minimal and stable passive system has a pH representation. Nevertheless, this equivalence is only concerned with the input-output mapping but not with the Hamiltonian itself. Thus, we propose to view a pH system either as an enlarged dynamical system with the Hamiltonian as additional output or as two dynamical systems with the input-output and the Hamiltonian dynamic. Our first main result is a structure-preserving Kalman-like decomposition of the enlarged pH system that separates the controllable and zero-state observable parts. Moreover, for further approximations in the context of structure-preserving model-order reduction (MOR), we propose to search for a Hamiltonian in the reduced pH system that minimizes the 2-distance to the full-order Hamiltonian without altering the input-output dynamic, thus discussing a particular aspect of the corresponding multi-objective minimization problem corresponding to $\mathcal{H}_2$-optimal MOR for pH systems. We show that this optimization problem is uniquely solvable, can be recast as a standard semidefinite program, and present two numerical approaches for solving it. The results are illustrated with three academic examples.}, added-at = {2023-09-26T20:56:45.000+0200}, archiveprefix = {arXiv}, author = {Holicki, Tobias and Nicodemus, Jonas and Schwerdtner, Paul and Unger, Benjamin}, biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2a4ab02f43b234754df6ecd3dfc02de4a/benjaminunger}, eprint = {2309.05778}, interhash = {fef9d3e8aaf8abe4be1f249a0e8e10bc}, intrahash = {a4ab02f43b234754df6ecd3dfc02de4a}, keywords = {}, primaryclass = {math.OC}, timestamp = {2023-09-26T18:56:45.000+0200}, title = {Energy matching in reduced passive and port-Hamiltonian systems}, year = 2023 }