Title :
Approximation of infinite-dimensional systems
Author :
Gu, Guaxiang ; Khargonekar, Pramod P. ; Lee, E. Bruce
Author_Institution :
Dept. of Electr. Syst. Eng., Wright State Univ., Dayton, OH, USA
fDate :
6/1/1989 12:00:00 AM
Abstract :
A Fourier series-based method for approximation of stable infinite-dimensional linear time-invariant system models is discussed. The basic idea is to compute the Fourier series coefficients of the associated transfer function Td(Z) and then take a high-order partial sum. Two results on H∞ convergence and associated error bounds of the partial sum approximation are established. It is shown that the Fourier coefficients can be replaced by the discrete Fourier transform coefficients while maintaining H∞ convergence. Thus, a fast Fourier transform algorithm can be used to compute the high-order approximation. This high-order finite-dimensional approximation can then be reduced using balanced truncation or optimal Hankel approximation leading to the final finite-dimensional approximation to the original infinite-dimensional model. This model has been tested on several transfer functions of the time-delay type with promising results
Keywords :
convergence; fast Fourier transforms; linear systems; multidimensional systems; series (mathematics); Fourier series-based method; H∞ convergence; discrete Fourier transform coefficients; error bounds; high-order finite-dimensional approximation; infinite-dimensional systems; linear time-invariant system; multidimensional systems; transfer function; transfer functions; Approximation algorithms; Approximation methods; Convergence; Fourier transforms; Frequency domain analysis; Frequency response; Hilbert space; Image analysis; Reduced order systems; Transfer functions;
Journal_Title :
Automatic Control, IEEE Transactions on
