Title :
Design of stable, causal 2-D digital filters using real coefficient 2-D all-pass building blocks
Author :
Safiri, H. ; Ahmadi, M. ; Ramachandran, V.
Author_Institution :
Dept. of Electr. Eng., Windsor Univ., Ont., Canada
fDate :
5/1/1997 12:00:00 AM
Abstract :
Presented here is a method for the design of 2-D causal quarter-plane recursive digital filters with real coefficients and arbitrary magnitude with/without linear phase characteristics, by using all-pass building blocks. It is shown that in general, cascades of sum or difference of two 2-D all-pass filters with appropriate delay elements are required to guarantee the arbitrary shape of the cutoff boundary of the desired filters. To design a 2-D filter satisfying given specifications the binary parameters of the cascaded all-pass structure are adapted from the given table, and the coefficients of the 2-D all-pass filters are obtained via an iterative technique by using a nonlinear optimization method. Design examples are given to illustrate the usefulness of the proposed technique
Keywords :
IIR filters; all-pass filters; cascade networks; circuit optimisation; circuit stability; delay circuits; iterative methods; low-pass filters; network parameters; physics fundamentals; two-dimensional digital filters; 2-D causal quarter-plane recursive digital filters; 2-variable very strictly Hurwitz polynomial; IIR filters; arbitrary magnitude; arbitrary shape cutoff boundary; binary parameters; cascaded all-pass structure; causal 2-D digital filter design; delay elements; filter stability; iterative technique; linear phase characteristics; linear phase circular symmetric low-pass filter; nonlinear optimization method; real coefficient 2-D all-pass building blocks; Delay; Design methodology; Digital filters; Iterative methods; Low pass filters; Optimization methods; Shape; Signal design; Stability; Transfer functions;
Journal_Title :
Circuits and Systems II: Analog and Digital Signal Processing, IEEE Transactions on
