Approximating a Function with a Jump Discontinuity—The High-Noise Case

Qusay Muzaffar; David Levin; Michael Werman

doi:10.3390/appliedmath4020030

Approximating a Function with a Jump Discontinuity—The High-Noise Case

Qusay Muzaffar, David Levin, Michael Werman

The Hebrew University of Jerusalem, Tel Aviv University

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

Abstract

This paper presents a novel deep-learning network designed to detect intervals of jump discontinuities in single-variable piecewise smooth functions from their noisy samples. Enhancing the accuracy of jump discontinuity estimations can be used to find a more precise overall approximation of the function, as traditional approximation methods often produce significant errors near discontinuities. Detecting intervals of discontinuities is relatively straightforward when working with exact function data, as finite differences in the data can serve as indicators of smoothness. However, these smoothness indicators become unreliable when dealing with highly noisy data. In this paper, we propose a deep-learning network to pinpoint the location of a jump discontinuity even in the presence of substantial noise.

Original language	English
Pages (from-to)	561-569
Number of pages	9
Journal	AppliedMath
Volume	4
Issue number	2
DOIs	https://doi.org/10.3390/appliedmath4020030
State	Published - Jun 2024

Keywords

approximation theory
deep learning
highly noisy data
piecewise smooth function approximation

All Science Journal Classification (ASJC) codes

Mathematics (miscellaneous)
Applied Mathematics

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10.3390/appliedmath4020030

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title = "Approximating a Function with a Jump Discontinuity—The High-Noise Case",

abstract = "This paper presents a novel deep-learning network designed to detect intervals of jump discontinuities in single-variable piecewise smooth functions from their noisy samples. Enhancing the accuracy of jump discontinuity estimations can be used to find a more precise overall approximation of the function, as traditional approximation methods often produce significant errors near discontinuities. Detecting intervals of discontinuities is relatively straightforward when working with exact function data, as finite differences in the data can serve as indicators of smoothness. However, these smoothness indicators become unreliable when dealing with highly noisy data. In this paper, we propose a deep-learning network to pinpoint the location of a jump discontinuity even in the presence of substantial noise.",

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AU - Levin, David

AU - Werman, Michael

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N2 - This paper presents a novel deep-learning network designed to detect intervals of jump discontinuities in single-variable piecewise smooth functions from their noisy samples. Enhancing the accuracy of jump discontinuity estimations can be used to find a more precise overall approximation of the function, as traditional approximation methods often produce significant errors near discontinuities. Detecting intervals of discontinuities is relatively straightforward when working with exact function data, as finite differences in the data can serve as indicators of smoothness. However, these smoothness indicators become unreliable when dealing with highly noisy data. In this paper, we propose a deep-learning network to pinpoint the location of a jump discontinuity even in the presence of substantial noise.

AB - This paper presents a novel deep-learning network designed to detect intervals of jump discontinuities in single-variable piecewise smooth functions from their noisy samples. Enhancing the accuracy of jump discontinuity estimations can be used to find a more precise overall approximation of the function, as traditional approximation methods often produce significant errors near discontinuities. Detecting intervals of discontinuities is relatively straightforward when working with exact function data, as finite differences in the data can serve as indicators of smoothness. However, these smoothness indicators become unreliable when dealing with highly noisy data. In this paper, we propose a deep-learning network to pinpoint the location of a jump discontinuity even in the presence of substantial noise.

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KW - deep learning

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KW - piecewise smooth function approximation

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JO - AppliedMath

JF - AppliedMath

IS - 2

ER -

Approximating a Function with a Jump Discontinuity—The High-Noise Case

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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