In this paper we present a unifying geometric and compositional framework for
modeling complex physical network dynamics as port-Hamiltonian systems on open
graphs. Basic idea is to associate with the incidence matrix of the graph a
Dirac structure relating the flow and effort variables associated to the edges,
internal vertices, as well as boundary vertices of the graph, and to formulate
energy-storing or energy-dissipating relations between the flow and effort
variables of the edges and internal vertices. This allows for state variables
associated to the edges, and formalizes the interconnection of networks.
Examples from different origins such as consensus algorithms are shown to share
the same structure. It is shown how the identified Hamiltonian structure offers
systematic tools for the analysis of the resulting dynamics.Comment: 45 pages, 2 figure