Identification of time-varying bilinear systems using legendre series

A finite series expansion method using discrete Legendre orthogonal polynomials (DLOPs) is applied to analyze linear time-varying discrete systems. An effective algorithm is derived to establish a representation which relates the DLOP coeficient vector of a product function to those of its two-comp

## A method of using orthogonal shifted Legendre polynomials for identifying the parameters of a process whose behaviour can be modelled by a linear di$erential equation with time-varying coeficients in the form ofjinite-order polynomials is presented. It is based on the repeated integration of the

This paper considers the problem of identifying the parameters and initial conditions of systems described by linear dtjierential equations with time-varying coefficients. A new approach is proposed which is based on the idea of using orthogonal functions to represent the input-output data, as well

This paper is concerned with the identification of linear time-varying systems. The discrete-time state space model of freely vibrating systems is used as an identification model. The focus is placed on identifying successive discrete transition matrices that have the same eigenvalues as the origina

## This paper analyses the linear time-varying system by the shifted Legendre polynomials expansion. Using the operational matrix for integrating the shgted Legendre polynomials, the dynamic equation of a linear time-varying system is reduced to a set of simultaneous linear algebraic equations. Th

A bilinear model is introduced to study the effects of anti-tumor drugs on the kinetics of the cell cycle. Optimal control theory is applied in the estimation of these timevarying effects based on a least squares fit of laboratory data. This methodology enables the authors to quantify the effects of