You are here

Finite impulse response filter design using cosine series functions

Download pdf | Full Screen View

Date Issued:
1988
Abstract/Description:
Window functions have been extensively used for the design of SAW filters. The classical truncated cosine series functions, such as the Hamming and Blackmann functions, are only a few of an infinite set of such functions. The derivation of this set of functions from orthonormal basis sets and the criteria for obtaining the constant coefficients of the functions are presented. These functions are very useful because of the closed-form expressions and their easily recognizable Fourier transform. Another approach to the design of Gaussian shaped filters having a desired sidelobe level using a 40 term cosine series will be presented as well. This approach is again non-iterative and a near equi-ripple sidelobe level filter could be achieved. A deconvolution technique will also be presented. this has the advantage of being non-iterative, simple and fast. This design method produces results comparable to the Dolph-Chebyshev technique.
Title: Finite impulse response filter design using cosine series functions.
52 views
13 downloads
Name(s): Bishop, Carlton Delos, Author
Malocha, Donald C., Committee Chair
Engineering, Degree Grantor
Type of Resource: text
Date Issued: 1988
Publisher: University of Central Florida
Language(s): English
Abstract/Description: Window functions have been extensively used for the design of SAW filters. The classical truncated cosine series functions, such as the Hamming and Blackmann functions, are only a few of an infinite set of such functions. The derivation of this set of functions from orthonormal basis sets and the criteria for obtaining the constant coefficients of the functions are presented. These functions are very useful because of the closed-form expressions and their easily recognizable Fourier transform. Another approach to the design of Gaussian shaped filters having a desired sidelobe level using a 40 term cosine series will be presented as well. This approach is again non-iterative and a near equi-ripple sidelobe level filter could be achieved. A deconvolution technique will also be presented. this has the advantage of being non-iterative, simple and fast. This design method produces results comparable to the Dolph-Chebyshev technique.
Identifier: CFR0013088 (IID), ucf:53133 (fedora)
Note(s): 1988-12-01
Ph.D.
Electrical Engineering and Communication
Doctorate
This record was generated from author submitted information.
Electronically reproduced by the University of Central Florida from a book held in the John C. Hitt Library at the University of Central Florida, Orlando.
Subject(s): Dissertations
Academic -- Engineering -- FOFT
Engineering -- Dissertations
Academic -- FOFT
Persistent Link to This Record: http://purl.flvc.org/ucf/fd/CFR0013088
Restrictions on Access: public
Host Institution: UCF

In Collections