An L1-method for the design of linear-phase FIR digital filters

Liron D. Grossmann; Yonina C. Eldar

doi:10.1109/tsp.2007.896088

An L₁-method for the design of linear-phase FIR digital filters

Liron D. Grossmann
, Yonina C. Eldar

Technion-Israel Institute of Technology

Research output: Contribution to journal › Article › peer-review

40 Scopus citations

Abstract

This paper considers the design of linear-phase finite impulse response digital filters using an L₁ optimality criterion. The motivation for using such filters as well as a mathematical framework for their design is introduced. It is shown that L₁ filters possess flat passbands and stopbands while keeping the transition band comparable to that of least-squares filters. The uniqueness of L₁-based filters is explored, and an alternation type theorem for the optimal frequency response is derived. An efficient algorithm for calculating the optimal filter coefficients is proposed, which may be viewed as the analogue of the celebrated Remez exchange method. A comparison with other design techniques is made, demonstrating that the L₁ approach may be a good alternative in several applications.

Original language	English
Pages (from-to)	5253-5266
Number of pages	14
Journal	IEEE Transactions on Signal Processing
Volume	55
Issue number	11
DOIs	https://doi.org/10.1109/tsp.2007.896088
State	Published - Nov 2007
Externally published	Yes

Keywords

Differentiability
Digital filtering
L norm
Newton method
Uniqueness

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10.1109/tsp.2007.896088

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abstract = "This paper considers the design of linear-phase finite impulse response digital filters using an L1 optimality criterion. The motivation for using such filters as well as a mathematical framework for their design is introduced. It is shown that L1 filters possess flat passbands and stopbands while keeping the transition band comparable to that of least-squares filters. The uniqueness of L1-based filters is explored, and an alternation type theorem for the optimal frequency response is derived. An efficient algorithm for calculating the optimal filter coefficients is proposed, which may be viewed as the analogue of the celebrated Remez exchange method. A comparison with other design techniques is made, demonstrating that the L1 approach may be a good alternative in several applications.",

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AB - This paper considers the design of linear-phase finite impulse response digital filters using an L1 optimality criterion. The motivation for using such filters as well as a mathematical framework for their design is introduced. It is shown that L1 filters possess flat passbands and stopbands while keeping the transition band comparable to that of least-squares filters. The uniqueness of L1-based filters is explored, and an alternation type theorem for the optimal frequency response is derived. An efficient algorithm for calculating the optimal filter coefficients is proposed, which may be viewed as the analogue of the celebrated Remez exchange method. A comparison with other design techniques is made, demonstrating that the L1 approach may be a good alternative in several applications.

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KW - Digital filtering

KW - L norm

KW - Newton method

KW - Uniqueness

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JO - IEEE Transactions on Signal Processing

JF - IEEE Transactions on Signal Processing

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An L₁-method for the design of linear-phase FIR digital filters

Abstract

Keywords

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