A global sensitivity index based on Fréchet derivative and its efficient numerical analysis

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  • The University of Liverpool
  • Tongji University
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OriginalspracheEnglisch
Aufsatznummer103096
FachzeitschriftProbabilistic Engineering Mechanics
Jahrgang62
Frühes Online-Datum3 Sept. 2020
PublikationsstatusVeröffentlicht - Okt. 2020

Abstract

Sensitivity analysis plays an important role in reliability evaluation, structural optimization and structural design, etc. The local sensitivity, i.e., the partial derivative of the quantity of interest in terms of parameters or basic variables, is inadequate when the basic variables are random in nature. Therefore, global sensitivity such as the Sobol’ indices based on the decomposition of variance and the moment-independent importance measure, among others, have been extensively studied. However, these indices are usually computationally expensive, and the information provided by them has some limitations for decision making. Specifically, all these indices are positive, and therefore they cannot reveal whether the effects of a basic variable on the quantity of interest are positive or adverse. In the present paper, a novel global sensitivity index is proposed when randomness is involved in structural parameters. Specifically, a functional perspective is firstly advocated, where the probability density function (PDF) of the output quantity of interest is regarded as the output of an operator on the PDF of the source basic random variables. The Fréchet derivative is then naturally taken as a measure for the global sensitivity. In some sense such functional perspective provides a unified perspective on the concepts of global sensitivity and local sensitivity. In the case the change of the PDF of a basic random variable is due to the change of parameters of the PDF of the basic random variable, the computation of the Fréchet-derivative-based global sensitivity index can be implemented with high efficiency by incorporating the probability density evolution method (PDEM) and change of probability measure (COM). The numerical algorithms are elaborated. Several examples are illustrated, demonstrating the effectiveness of the proposed method.

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A global sensitivity index based on Fréchet derivative and its efficient numerical analysis. / Chen, Jianbing; Wan, Zhiqiang; Beer, Michael.
in: Probabilistic Engineering Mechanics, Jahrgang 62, 103096, 10.2020.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Chen J, Wan Z, Beer M. A global sensitivity index based on Fréchet derivative and its efficient numerical analysis. Probabilistic Engineering Mechanics. 2020 Okt;62:103096. Epub 2020 Sep 3. doi: 10.1016/j.probengmech.2020.103096
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title = "A global sensitivity index based on Fr{\'e}chet derivative and its efficient numerical analysis",
abstract = "Sensitivity analysis plays an important role in reliability evaluation, structural optimization and structural design, etc. The local sensitivity, i.e., the partial derivative of the quantity of interest in terms of parameters or basic variables, is inadequate when the basic variables are random in nature. Therefore, global sensitivity such as the Sobol{\textquoteright} indices based on the decomposition of variance and the moment-independent importance measure, among others, have been extensively studied. However, these indices are usually computationally expensive, and the information provided by them has some limitations for decision making. Specifically, all these indices are positive, and therefore they cannot reveal whether the effects of a basic variable on the quantity of interest are positive or adverse. In the present paper, a novel global sensitivity index is proposed when randomness is involved in structural parameters. Specifically, a functional perspective is firstly advocated, where the probability density function (PDF) of the output quantity of interest is regarded as the output of an operator on the PDF of the source basic random variables. The Fr{\'e}chet derivative is then naturally taken as a measure for the global sensitivity. In some sense such functional perspective provides a unified perspective on the concepts of global sensitivity and local sensitivity. In the case the change of the PDF of a basic random variable is due to the change of parameters of the PDF of the basic random variable, the computation of the Fr{\'e}chet-derivative-based global sensitivity index can be implemented with high efficiency by incorporating the probability density evolution method (PDEM) and change of probability measure (COM). The numerical algorithms are elaborated. Several examples are illustrated, demonstrating the effectiveness of the proposed method.",
keywords = "Change of probability measure, Fr{\'e}chet derivative, Global sensitivity index, Probability density evolution method, Uncertainty quantification",
author = "Jianbing Chen and Zhiqiang Wan and Michael Beer",
note = "Funding information: Financial supports from the National Natural Science Foundation of China (NSFC Grant Nos. 51725804 , 51538010 and 11761131014 ), the DFG, Germany Grant No. 392113882 , the NSFC-Guangdong Province Joint Project, China (Grant No. U1711264 ) are highly appreciated. The China Scholarship Council (CSC) is gratefully appreciated by the second author.",
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AU - Chen, Jianbing

AU - Wan, Zhiqiang

AU - Beer, Michael

N1 - Funding information: Financial supports from the National Natural Science Foundation of China (NSFC Grant Nos. 51725804 , 51538010 and 11761131014 ), the DFG, Germany Grant No. 392113882 , the NSFC-Guangdong Province Joint Project, China (Grant No. U1711264 ) are highly appreciated. The China Scholarship Council (CSC) is gratefully appreciated by the second author.

PY - 2020/10

Y1 - 2020/10

N2 - Sensitivity analysis plays an important role in reliability evaluation, structural optimization and structural design, etc. The local sensitivity, i.e., the partial derivative of the quantity of interest in terms of parameters or basic variables, is inadequate when the basic variables are random in nature. Therefore, global sensitivity such as the Sobol’ indices based on the decomposition of variance and the moment-independent importance measure, among others, have been extensively studied. However, these indices are usually computationally expensive, and the information provided by them has some limitations for decision making. Specifically, all these indices are positive, and therefore they cannot reveal whether the effects of a basic variable on the quantity of interest are positive or adverse. In the present paper, a novel global sensitivity index is proposed when randomness is involved in structural parameters. Specifically, a functional perspective is firstly advocated, where the probability density function (PDF) of the output quantity of interest is regarded as the output of an operator on the PDF of the source basic random variables. The Fréchet derivative is then naturally taken as a measure for the global sensitivity. In some sense such functional perspective provides a unified perspective on the concepts of global sensitivity and local sensitivity. In the case the change of the PDF of a basic random variable is due to the change of parameters of the PDF of the basic random variable, the computation of the Fréchet-derivative-based global sensitivity index can be implemented with high efficiency by incorporating the probability density evolution method (PDEM) and change of probability measure (COM). The numerical algorithms are elaborated. Several examples are illustrated, demonstrating the effectiveness of the proposed method.

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JO - Probabilistic Engineering Mechanics

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ER -

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