Add to ORKGIn this paper two methods of designing efficiently a digital linear-phase differentiator of an arbitrary degree of differentiation are proposed. The first one utilizes a symbolic expression for the coefficients of a generic fractional delay filter and is based on a fundamental relationship between the coefficients of a digital differentiator and the coefficients of the generic FD filter. The second profits from one of the crucial attributes of the structure invented by Farrow for FD filters. It lies in an alternate symmetry and anti-symmetry of sub-filters which are linear-phase differentiators. The proposed design methods are illustrated by examples. Some practical remarks concerning the usage of the Farrow structure are also included. 1
Abstract—In this letter, the design of a fractional order FIR differentiator is investigated. First,...
Interrelationships between seven types of digital FIR filters, viz. the differentiators (DD), Hilber...
This paper describes a new method for designing low-pass differentiators that could be widely suitab...
[[abstract]]In this paper, the design of digital differentiator is investigated. First, the relation...
[[abstract]]The design of digital differentiators is investigated. First, the backward difference fo...
[[abstract]]In this paper, a new approach to the design of digital FIR differentiators is presented....
[[abstract]]In this paper, a digital fractional-order differentiator (FOD) is designed by using frac...
In this paper, design of linear phase FIR digital differentiators is investigated using convex optim...
In this paper, the least-squares design of variable fractional-delay (VFD) finite impulse response (...
Optimal, maximally accurate digital differentiators (DDS) are derived for the low-frequency range. E...
Abstract—In this letter, the Taylor series expansion is used to transform the design problem of a fr...
[[abstract]]In this paper, the Taylor series expansion is used to transform the design problem of a ...
[[abstract]]In this paper, the design of a fractional order FIR differentiator is investigated. Firs...
Digital differentiators (DDs) which are maximally linear at the spot frequency ω=p/p, p ...
Digital differentiators of orders greater than unity are often required in processing various types ...
Abstract—In this letter, the design of a fractional order FIR differentiator is investigated. First,...
Interrelationships between seven types of digital FIR filters, viz. the differentiators (DD), Hilber...
This paper describes a new method for designing low-pass differentiators that could be widely suitab...
[[abstract]]In this paper, the design of digital differentiator is investigated. First, the relation...
[[abstract]]The design of digital differentiators is investigated. First, the backward difference fo...
[[abstract]]In this paper, a new approach to the design of digital FIR differentiators is presented....
[[abstract]]In this paper, a digital fractional-order differentiator (FOD) is designed by using frac...
In this paper, design of linear phase FIR digital differentiators is investigated using convex optim...
In this paper, the least-squares design of variable fractional-delay (VFD) finite impulse response (...
Optimal, maximally accurate digital differentiators (DDS) are derived for the low-frequency range. E...
Abstract—In this letter, the Taylor series expansion is used to transform the design problem of a fr...
[[abstract]]In this paper, the Taylor series expansion is used to transform the design problem of a ...
[[abstract]]In this paper, the design of a fractional order FIR differentiator is investigated. Firs...
Digital differentiators (DDs) which are maximally linear at the spot frequency ω=p/p, p ...
Digital differentiators of orders greater than unity are often required in processing various types ...
Abstract—In this letter, the design of a fractional order FIR differentiator is investigated. First,...
Interrelationships between seven types of digital FIR filters, viz. the differentiators (DD), Hilber...
This paper describes a new method for designing low-pass differentiators that could be widely suitab...