Guided Tour Of Generalized Functions In Signal Processing
- Conference
- Location
-
Portland, Oregon
- Publication Date
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June 12, 2005
- Start Date
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June 12, 2005
- End Date
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June 15, 2005
- ISSN
-
2153-5965
- Conference Session
- Page Count
-
9
- Page Numbers
-
10.679.1 - 10.679.9
- DOI
-
10.18260/1-2--15478
- Permanent URL
-
https://peer.asee.org/15478
- Download Count
-
476
Paper Authors
John Schmeelk Virginia Commonwealth University Qatar Branch
Abstract
NOTE: The first page of text has been automatically extracted and included below in lieu of an abstract
Session ####
Guided Tour of Generalized Functions in Signal Processing 1
John Schmeelk
Department of Mathematical Sciences Virginia Commonwealth University Doha, Qatar
Abstract
The paper considers generalized functions as a necessary ingredient in various signal- processing techniques. Oftentimes generalized functions are implemented in a casual way and not reflecting the need to establish results on a mathematical platform. A few of the important connections between the applications and mathematical foundations are included together with several illustrations.
I. Introduction
The rapid descent test functions with the inclusion of a few very needed principals are given in section 2. It also gives a brief introduction of tempered distributions including some very important theorems. The paper then moves into section 3 giving the fundamentals of a discrete Fourier transform pair. This is then embedded into a tempered distribution setting. Section 4 gives an introduction to windowing signal data and again embeds it into the tempered distribution setting. The paper concludes with a very brief overview on filtering frequency techniques.
II. The Test Space S
We adopt the following notation conventions. For positive integers, qi, (1 ≤ i ≤ n ) , the n length of q=(q1, q2,…, qn) is defined as q = ∑ q i . The absolute values in the paper also i =1 use the same notation. The context of the notation will indicate the appropriate meaning. n The Euclidean distance for x ∈ R will be denoted as a norm, x = n ∑x i =1 2 i , and for
differentiable functions, φ(x), the differential operator will be denoted as ∂ ( q1 ,..., qn ) D qφ ( x) = q1 φ ( x1 ,..., x n ) . ∂x1 ...∂x n n q
The test space S of rapid descent test functions are all infinitely differentiable and together with all of their partial derivatives decrease to zero faster than every power of
1 Funded by the Qatar Foundation, Doha, Qatar
“Proceedings of the 2005 American Society for engineering Education Annual Conferences & Exposition Copyright © 2005, American Society for Engineering Education”
Schmeelk, J. (2005, June), Guided Tour Of Generalized Functions In Signal Processing Paper presented at 2005 Annual Conference, Portland, Oregon. 10.18260/1-2--15478
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