Title :
FIR (q) filter design without the linear phase constraint
Author :
Kootsookos, Peter J. ; Bitmead, Robert R. ; Green, Michael
Author_Institution :
Dept. of Syst. Eng., Australian Nat. Univ., Canberra, ACT, Australia
Abstract :
The authors present a novel approach to the problem of designing a finite impulse response (FIR) filter of specified length q, which approximates in uniform frequency (L∞) norm a given desired (possibly infinite impulse response) filter transfer function. They derive an algorithm-independent lower bound on the achievable approximation error and then present an approximation method which involves the solution of a fixed number of all-pass (Nehari) extension problems and so is called the Nehari shuffle. An upper bound on the approximation error for the algorithm is derived. As this bound is calculable a priori, the length of filter required to satisfy a given maximum error can be found before designing the filter. Examples indicate that the method closely approaches the derived global lower bound. The method is compared with the Parks-McClellan (Remez exchange) algorithm in some examples
Keywords :
digital filters; signal processing; FIR (q) filter design; FIR filter; IIR filter approximation; Nehari shuffle; Parks-McClellan algorithm; Remez exchange; achievable approximation error; algorithm-independent lower bound; filter transfer function; finite impulse response; infinite impulse response; signal processing; upper bound; Algorithm design and analysis; Approximation algorithms; Approximation error; Finite impulse response filter; Frequency; IIR filters; Nonlinear filters; Systems engineering and theory; Transfer functions; Upper bound;
Conference_Titel :
Acoustics, Speech, and Signal Processing, 1991. ICASSP-91., 1991 International Conference on
Conference_Location :
Toronto, Ont.
Print_ISBN :
0-7803-0003-3
DOI :
10.1109/ICASSP.1991.150789
