A class of damping models preserving eigenspaces for linear conservative port-Hamiltonian systems

For conservative mechanical systems, the so-called Caughey series are known to define the class of damping matrices that preserve eigenspaces. In particular, for finite-dimensional systems, these matrices prove to be a polynomial of one reduced matrix, which depends on the mass and stiffness matrices. Damping is ensured whatever the eigenvalues of the conservative problem if and only if the polynomial is positive for positive scalar values. This paper first recasts this result in the port-Hamiltonian framework by introducing a port variable corresponding to internal energy dissipation (resistive element). Moreover, this formalism naturally allows to cope with systems including gyroscopic effects (gyrators). Second, generalizations to the infinite-dimensional case are considered. They consist of extending the previous polynomial class to rational functions and more general functions of operators (instead of matrices), once the appropriate functional framework has been defined. In this case, the resistive element is modelled by a given static operator, such as an elliptic PDE. These results are illustrated on several PDE examples: the Webster horn equation, the Bernoulli beam equation; the damping models under consideration are fluid, structural, rational and generalized fractional Laplacian or bi-Laplacian.

[1]  Stefano Stramigioli,et al.  Modeling and Control of Complex Physical Systems - The Port-Hamiltonian Approach , 2014 .

[2]  Hans Zwart,et al.  Linear Port-Hamiltonian Systems on Infinite-dimensional Spaces , 2012 .

[3]  J. Graham-Pole,et al.  Physical , 1998, The Lancet.

[4]  Denis Matignon Diffusive representations for fractional Laplacian: systems theory framework and numerical issues , 2009 .

[5]  L. Trefethen,et al.  Spectra and Pseudospectra , 2020 .

[6]  Denis Matignon,et al.  Resonance modes in a one-dimensional medium with two purely resistive boundaries: Calculation methods, orthogonality, and completeness , 2004, physics/0411238.

[7]  Denis Matignon,et al.  On damping models preserving the eigenfunctions of conservative systems: a port-Hamiltonian perspective , 2012 .

[8]  I. Petrovsky,et al.  Lectures On Partial Differential Equations , 1962 .

[9]  M. Géradin,et al.  Mechanical Vibrations: Theory and Application to Structural Dynamics , 1994 .

[10]  Scott W. Hansen Optimal regularity results in boundary control of elastic systems with fractional order damping , 2000 .

[11]  Alberto Dou,et al.  Lectures on partial differential equations of first order , 1972 .

[12]  Sondipon Adhikari,et al.  Damping modelling using generalized proportional damping , 2006 .

[13]  René Causse,et al.  Modalys, a physical modeling synthesizer: More than twenty years of researches, developments, and musical uses , 2011 .

[14]  L. Rayleigh,et al.  The theory of sound , 1894 .

[15]  Bernhard Maschke,et al.  Boundary control for a class of dissipative differential operators including diffusion systems , 2006 .

[16]  Thomas Hélie,et al.  On the 1D wave propagation in wind instruments with a smooth profile , 2011 .

[17]  Hans Zwart,et al.  Dirac structures and Boundary Control Systems associated with Skew-Symmetric Differential Operators , 2005, SIAM J. Control. Optim..

[18]  Kerem Ege La table d'harmonie du piano - Études modales en basses et moyennes fréquences , 2009 .

[19]  Thomas Hélie,et al.  Unidimensional models of acoustic propagation in axisymmetric waveguides. , 2003, The Journal of the Acoustical Society of America.

[20]  S. Chen,et al.  Proof of two conjectures by G. Chen and D. L. Russel on structural damping for elastic systems , 1989 .

[21]  Carsten Trunk,et al.  Analyticity and Riesz basis property of semigroups associated to damped vibrations , 2008 .

[22]  T. Caughey,et al.  Classical Normal Modes in Damped Linear Dynamic Systems , 1960 .

[23]  A. Schaft Port-Hamiltonian Systems: Network Modeling and Control of Nonlinear Physical Systems , 2004 .

[24]  Arch W. Naylor,et al.  Linear Operator Theory in Engineering and Science , 1971 .

[25]  A. Schaft,et al.  Fluid dynamical systems as Hamiltonian boundary control systems , 2001, Proceedings of the 40th IEEE Conference on Decision and Control (Cat. No.01CH37228).

[26]  A G Webster,et al.  Acoustical Impedance and the Theory of Horns and of the Phonograph. , 1919, Proceedings of the National Academy of Sciences of the United States of America.

[27]  Roberto Triggiani,et al.  PROOF OF EXTENSIONS OF TWO CONJECTURES ON STRUCTURAL DAMPING FOR ELASTIC SYSTEMS , 1989 .