Title :
A new canonical expansion of z-transfer function for reduced-order modeling of discrete-time systems
Author :
Hwang, Chyi ; Hsieh, Ching-Shieh
Author_Institution :
Dept. of Chem. Eng., Nat. Cheng Kung Univ., Tainan, Taiwan
fDate :
12/1/1989 12:00:00 AM
Abstract :
On the basis of the unique decomposition of a polynomial into a mirror image polynomial (MIP) and an antimirror image polynomial (AMIP) and the expansion of A.M. Davis´ discrete reactance function (ibid., vol.CAS-29, no.10, p.658-62, 1982) into a continued fraction which proceeds in terms of z/(z-1) and 1/(z-1) alternately, a new canonical expansion of the z-transfer function is presented. Although it has the same structure as the Routh canonical expansion of the s-transfer function, the new canonical expansion is suitable for deriving reduced-order models of discrete-time systems by direct truncation. Using this canonical expansion, frequency- and time-domain reduced-order modeling procedures are derived. The necessary and sufficient conditions imposed on the continued-fraction expansion of Davis´ discrete reactance function for reduced-order models to be stable are also derived. It is shown that the reduced model has the partial Pade approximation property
Keywords :
control system analysis; discrete time systems; polynomials; stability; transfer functions; antimirror image polynomial; canonical expansion; continued-fraction expansion; decomposition; direct truncation; discrete reactance function; discrete-time systems; frequency-domain modelling; mirror image polynomial; partial Pade approximation property; reduced-order modeling; stability; time-domain modelling; z-transfer function; Councils; Digital filters; Frequency; Mirrors; Polynomials; Reduced order systems; Stability; Sufficient conditions; System testing; Time domain analysis;
Journal_Title :
Circuits and Systems, IEEE Transactions on
