Probabilistic Approach to Characterize Quantitative Uncertainty in Numerical Approximations

Joel Chaskalovic; Franck Assous

doi:10.3846/13926292.2017.1272499

Probabilistic Approach to Characterize Quantitative Uncertainty in Numerical Approximations

Joel Chaskalovic, Franck Assous

Department of Mathematics

Ariel University

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

Abstract

This paper proposes a statistical and probabilistic approach to compare and analyze the errors of two different approximation methods. We introduce the principle of numerical uncertainty in such a process, and we illustrate it by considering the discretization difference between two different approximation orders, e.g., first and second order Lagrangian finite element. Then, we derive a probabilistic approach to define and to qualify equivalent results. We illustrate our approach on a model problem on which we built the two above mentioned finite element approximations. We consider some variables as physical “predictors”, and we characterize how they influence the odds of the approximation methods to be locally “same order accurate”.

Original language	English
Pages (from-to)	106-120
Number of pages	15
Journal	Mathematical Modelling and Analysis
Volume	22
Issue number	1
DOIs	https://doi.org/10.3846/13926292.2017.1272499
State	Published - 2 Jan 2017

Keywords

Big Data
data mining
finite elements
probabilistic models
quantitative uncertainty

All Science Journal Classification (ASJC) codes

Analysis
Modelling and Simulation

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10.3846/13926292.2017.1272499

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title = "Probabilistic Approach to Characterize Quantitative Uncertainty in Numerical Approximations",

abstract = "This paper proposes a statistical and probabilistic approach to compare and analyze the errors of two different approximation methods. We introduce the principle of numerical uncertainty in such a process, and we illustrate it by considering the discretization difference between two different approximation orders, e.g., first and second order Lagrangian finite element. Then, we derive a probabilistic approach to define and to qualify equivalent results. We illustrate our approach on a model problem on which we built the two above mentioned finite element approximations. We consider some variables as physical “predictors”, and we characterize how they influence the odds of the approximation methods to be locally “same order accurate”.",

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AB - This paper proposes a statistical and probabilistic approach to compare and analyze the errors of two different approximation methods. We introduce the principle of numerical uncertainty in such a process, and we illustrate it by considering the discretization difference between two different approximation orders, e.g., first and second order Lagrangian finite element. Then, we derive a probabilistic approach to define and to qualify equivalent results. We illustrate our approach on a model problem on which we built the two above mentioned finite element approximations. We consider some variables as physical “predictors”, and we characterize how they influence the odds of the approximation methods to be locally “same order accurate”.

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KW - data mining

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KW - probabilistic models

KW - quantitative uncertainty

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IS - 1

ER -

Probabilistic Approach to Characterize Quantitative Uncertainty in Numerical Approximations

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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