Nonlinear-phase maximally-flat lowpass FIR filter design

Ivan Selesnick, C. Sidney Burrus

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Abstract

This paper reports a new analytic technique for the design of nonlinear-phase maximally-flat lowpass FIR filters. By subjecting the response magnitude and the group delay (individually) to differing numbers of flatness constraints, a new family of filters is obtained. With these filters, the delay can be reduced while maintaining relatively constant group delay in the passband, without significantly altering the response magnitude.

Original languageEnglish (US)
Title of host publicationIEEE Digital Signal Processing Workshop
Pages374-377
Number of pages4
StatePublished - 1996
EventProceedings of the 1996 7th IEEE Digital Signal Processing Workshop - Loen, Norway
Duration: Sep 1 1996Sep 4 1996

Other

OtherProceedings of the 1996 7th IEEE Digital Signal Processing Workshop
CityLoen, Norway
Period9/1/969/4/96

Fingerprint

Group delay
FIR filters

ASJC Scopus subject areas

  • Signal Processing
  • Electrical and Electronic Engineering

Cite this

Selesnick, I., & Burrus, C. S. (1996). Nonlinear-phase maximally-flat lowpass FIR filter design. In IEEE Digital Signal Processing Workshop (pp. 374-377)

Nonlinear-phase maximally-flat lowpass FIR filter design. / Selesnick, Ivan; Burrus, C. Sidney.

IEEE Digital Signal Processing Workshop. 1996. p. 374-377.

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Selesnick, I & Burrus, CS 1996, Nonlinear-phase maximally-flat lowpass FIR filter design. in IEEE Digital Signal Processing Workshop. pp. 374-377, Proceedings of the 1996 7th IEEE Digital Signal Processing Workshop, Loen, Norway, 9/1/96.
Selesnick I, Burrus CS. Nonlinear-phase maximally-flat lowpass FIR filter design. In IEEE Digital Signal Processing Workshop. 1996. p. 374-377
Selesnick, Ivan ; Burrus, C. Sidney. / Nonlinear-phase maximally-flat lowpass FIR filter design. IEEE Digital Signal Processing Workshop. 1996. pp. 374-377
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