Title :
Predictive FIR filters with low computational complexity
Author :
Campbell, T. George ; Neuvo, Yrjö
Author_Institution :
Signal Process. Lab., Swiss Federal Inst. of Technol., Lausanne, Switzerland
fDate :
9/1/1991 12:00:00 AM
Abstract :
New families of finite-impulse-response (FIR) digital filters with low computational complexity are presented. The filters are extensions of the recursive running sum. Each family of filters predicts points along a characteristic polynomial. Closed-form equations are given in both time- and frequency-domain for filters corresponding to first- and second-order polynomial models. Block diagrams for efficient implementation structures are given. The first-order predictive filters require three multipliers and five adders, and the second-order predictive filters require five multipliers and twelve adders, irrespective of the filter length. The filters exhibit low-pass characteristics with the passband shape controllable by a single parameter. The frequency and phase responses are discussed. A design example is given showing how the filters can be used as building blocks to obtain effective linear-phase low-pass filters
Keywords :
computational complexity; digital filters; filtering and prediction theory; frequency response; low-pass filters; polynomials; FIR filters; adders; characteristic polynomial; computational complexity; digital filters; finite-impulse-response; first-order predictive filters; frequency response; frequency-domain; linear-phase low-pass filters; low-pass characteristics; multipliers; phase responses; polynomial models; recursive running sum; second-order predictive filters; time domain; Closed-form solution; Computational complexity; Design methodology; Digital filters; Finite impulse response filter; Frequency; Low pass filters; Passband; Polynomials; Shape control;
Journal_Title :
Circuits and Systems, IEEE Transactions on
