Virtually every phenomenon in nature, whether biological, geological, or mechanical, can be described with the aid of the laws of physics, in terms of algebraic, differential, or integral equations relating various quantities of interest. The objectives of the thesis were to show how distributed parameter systems can be modeled using a bond graph model, which is by its nature itself a lumped parameter model. Two ways are possible :- using an approximation technique to discretize the model in the space domain, assuming that physical distributed phenomena can be considered as homogenous in some parts of space, and thus lumped. Different bond graph models can be obtained depending on the technique used.- determining a solution of the PDE depending on space and time, and thus to approximate this solution by means of different kinds of tools.In chapter 1, some classical methods used for approximation of partial differential equations are recalled and the corresponding bond graph model is designed. For each of them advantages and drawbacks are presented.In the second chapter, the port-Hamiltonian approach for distributed parameter system is presented, and a new result is proposed for telegrapher’s equation solving.In the third chapter, the main models used for traffic flow representation are presented and some of them are implemented in simulation. A comparison is done on one hand on different numerical methods applied on the first class of models (1-eq. model) and on the other hand between 1-equation and 2- equation models.In chapter 4, we have proposed an original approach extending Computational Fluid Dynamics bond graph representation to traffic flow, using Jiang’s model