Title :
Geometric modeling of nonlinear RLC circuits
Author :
Blankenstein, Guido
Author_Institution :
Dept. of Mech. Eng., Katholieke Univ. Leuven, Belgium
Abstract :
In this paper, the dynamics of nonlinear RLC circuits including independent and controlled voltage or current sources is described using the Brayton-Moser equations. The underlying geometric structure is highlighted and it is shown that the Brayton-Moser equations can be written as a dynamical system with respect to a noncanonical Dirac structure. The state variables are inductor currents and capacitor voltages. The formalism can be extended to include circuits with elements in excess, as well as general noncomplete circuits. Relations with the Hamiltonian formulation of nonlinear electrical circuits are clearly pointed out.
Keywords :
RLC circuits; nonlinear network analysis; Brayton-Moser equations; Hamiltonian formulation; capacitor voltages; dissipative circuits; dynamical system; general noncomplete circuits; geometric modelling; inductor currents; noncanonical Dirac structure; nonlinear RLC circuits; nonlinear electrical circuits; state variables; Capacitors; Electromagnetic induction; Inductors; Lagrangian functions; Nonlinear dynamical systems; Nonlinear equations; RLC circuits; Solid modeling; Tensile stress; Voltage; Brayton–Moser equations; circuit theory; dissipative circuits; excess elements; modeling; noncanonical Dirac structures; noncomplete networks; nonlinear circuits;
Journal_Title :
Circuits and Systems I: Regular Papers, IEEE Transactions on
DOI :
10.1109/TCSI.2004.840481
