Title :
Finite-precision Goertzel filters used for signal tone detection
Author :
Beck, Robert ; Dempster, Andrew G. ; Kale, Izzet
Author_Institution :
Dept. of Electron. Syst., Univ. of Westminster, London, UK
fDate :
7/1/2001 12:00:00 AM
Abstract :
The effect of coefficient quantization on the output of a second-order Goertzel filter tone-detector is analyzed in order that the Goertzel filter may be systematically designed for minimum complexity. Three alternative configurations are identified for the Goertzel filter´s component second-order digital resonator, which are especially suited to VLSI implementation, and which complement each other on the zero-to-Nyquist frequency interval. The Goertzel filter´s tone response is formulated using the Fourier summation transform (and shown to depend on both the frequency and phase of the incident tone). Hence analytic expressions are derived for the tone response of a fully finite-precision Goertzel filter when used with either a rectangular or half-end-point, input data window. These formulas are amenable to optimization, and are applied to improve a DTMF receiver design which is subject to the use of low-complexity second-order resonators
Keywords :
VLSI; discrete Fourier transforms; filtering theory; quantisation (signal); recursive filters; signal detection; DTMF receiver design; Fourier summation transform; VLSI implementation; coefficient quantization; digital resonator; finite-precision Goertzel filters; half-end-point input data window; minimum complexity; rectangular input data window; second-order Goertzel filter tone-detector; signal tone detection; tone response; zero-to-Nyquist frequency interval; Digital filters; Digital signal processing; Discrete Fourier transforms; Fourier transforms; Frequency; Nonlinear filters; Quantization; Resonator filters; Signal detection; Very large scale integration;
Journal_Title :
Circuits and Systems II: Analog and Digital Signal Processing, IEEE Transactions on
