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Title: On the Impulse Response of Singular Discrete LTI Systems and Three Fourier Transform Pairs
A basic tenet of linear invariant systems is that they are sufficiently described by either the impulse response function or the frequency transfer function. This implies that we can always obtain one from the other. However, when the transfer function contains uncanceled poles, the impulse function cannot be obtained by the standard inverse Fourier transform method. Specifically, when the input consists of a uniform train of pulses and the output sequence has a finite duration, the transfer function contains multiple poles on the unit cycle. We show how the impulse function can be obtained from the frequency transfer function for such marginally stable systems. We discuss three interesting discrete Fourier transform pairs that are used in demonstrating the equivalence of the impulse response and transfer functions for such systems. The Fourier transform pairs can be used to yield various trigonometric sums involving sin⁡πk/Nsin⁡πLk/N, where k is the integer summing variable and N is a multiple of integer L.  more » « less
Award ID(s):
2152109
PAR ID:
10560805
Author(s) / Creator(s):
Publisher / Repository:
MDPI
Date Published:
Journal Name:
Signals
Volume:
5
Issue:
3
ISSN:
2624-6120
Page Range / eLocation ID:
460 to 473
Format(s):
Medium: X
Sponsoring Org:
National Science Foundation
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