Frequency and time domain analysis of linear systems with frequency dependent parameters

Linear lossy two-conductor transmission line can be modelled as dynamic two ports in the time domain, via the describing input and transfer impulse responses. This convolution technique is very e!ective when dealing with networks composed of transmission lines with frequency-dependent parameters and

A mixed method of model-order reduction is introduced, which is based on the linear state-space representation of the original system. The derivation of' its transfer function matrix expression uses the Leverrier algorithm and the application of well known partialfraction expansion techniques togeth

The primary objective of the present study is to develop a new analytical method for estimating the frequency response characteristics of a linear time-variant, discrete vibratory system when the mass, stiffness and damping parameters are uncertain. The excitation amplitude is also considered to be

This paper presents a new frequency-domain method to analyze physically non-linear structural systems having non-proportional damping. Single-and multi-degree-of-freedom (d.o.f.) systems subjected to time-dependent excitations are considered. A procedure to consider initial conditions, required by t

An efficient frequency-dependent finite-element time-domain method for the analysis of dispersive media is presented. The formulation, based on the 2 nd -order wave equation, includes a slowly-varying envelope approximation (SVEA) and perfectly matched layers (PMLs), and the dispersion effects of th