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Machine learning based stochastic dynamic analysis of functionally graded shells

Machine learning based stochastic dynamic analysis of functionally graded shells
Machine learning based stochastic dynamic analysis of functionally graded shells

This paper presents stochastic dynamic characterization of functionally graded shells based on an efficient Support Vector Machine assisted finite element (FE) approach. Different shell geometries such as cylindrical, spherical, elliptical paraboloid and hyperbolic paraboloid are investigated for the stochastic dynamic analysis. Monte Carlo Simulation is carried out in conjunction with the machine learning based FE computational framework for obtaining the complete probabilistic description of the natural frequencies. Here the coupled machine learning based FE model is found to reduce the computational time and cost significantly without compromising the accuracy of results. In the stochastic approach, both individual and compound effect of depth-wise source-uncertainty in material properties of FGM shells are considered taking into account the influences of different critical parameters such as the power-law exponent, temperature, thickness and variation of shell geometries. A moment-independent sensitivity analysis is carried out to enumerate the relative significance of different random input parameters considering depth-wise variation and collectively. The presented numerical results clearly indicate that it is imperative to take into account the relative stochastic deviations (including their probabilistic characterization) of the global dynamic characteristics for different shell geometries to ensure adequate safety and serviceability of the system while having an economical structural design.

Depth-wise sensitivity analysis, FGM shells, Free vibration, Machine learning based analysis of FGM, Monte Carlo simulation, Support vector machine
0263-8223
Vaishali,
f129101a-6555-4e0e-9912-65b2a7145586
Mukhopadhyay, T.
2ae18ab0-7477-40ac-ae22-76face7be475
Karsh, P. K.
b039f77d-f480-4493-b2a9-325b04e3cbaf
Basu, B.
409b22b1-be33-4f94-9e98-85dddb8ae53b
Dey, S.
ad19fb29-0675-43ef-85a6-69aedc394525
Vaishali,
f129101a-6555-4e0e-9912-65b2a7145586
Mukhopadhyay, T.
2ae18ab0-7477-40ac-ae22-76face7be475
Karsh, P. K.
b039f77d-f480-4493-b2a9-325b04e3cbaf
Basu, B.
409b22b1-be33-4f94-9e98-85dddb8ae53b
Dey, S.
ad19fb29-0675-43ef-85a6-69aedc394525

Vaishali, , Mukhopadhyay, T., Karsh, P. K., Basu, B. and Dey, S. (2020) Machine learning based stochastic dynamic analysis of functionally graded shells. Composite Structures, 237, [111870]. (doi:10.1016/j.compstruct.2020.111870).

Record type: Article

Abstract

This paper presents stochastic dynamic characterization of functionally graded shells based on an efficient Support Vector Machine assisted finite element (FE) approach. Different shell geometries such as cylindrical, spherical, elliptical paraboloid and hyperbolic paraboloid are investigated for the stochastic dynamic analysis. Monte Carlo Simulation is carried out in conjunction with the machine learning based FE computational framework for obtaining the complete probabilistic description of the natural frequencies. Here the coupled machine learning based FE model is found to reduce the computational time and cost significantly without compromising the accuracy of results. In the stochastic approach, both individual and compound effect of depth-wise source-uncertainty in material properties of FGM shells are considered taking into account the influences of different critical parameters such as the power-law exponent, temperature, thickness and variation of shell geometries. A moment-independent sensitivity analysis is carried out to enumerate the relative significance of different random input parameters considering depth-wise variation and collectively. The presented numerical results clearly indicate that it is imperative to take into account the relative stochastic deviations (including their probabilistic characterization) of the global dynamic characteristics for different shell geometries to ensure adequate safety and serviceability of the system while having an economical structural design.

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More information

Published date: 1 April 2020
Additional Information: Funding Information: The first author acknowledges MHRD, Government of India, for providing the necessary supports to perform this research work. Publisher Copyright: © 2020 Elsevier Ltd
Keywords: Depth-wise sensitivity analysis, FGM shells, Free vibration, Machine learning based analysis of FGM, Monte Carlo simulation, Support vector machine

Identifiers

Local EPrints ID: 483576
URI: http://eprints.soton.ac.uk/id/eprint/483576
DOI: doi:10.1016/j.compstruct.2020.111870
ISSN: 0263-8223
PURE UUID: a14a0581-3efb-4b9b-9c58-5fa937abbdba
ORCID for T. Mukhopadhyay: ORCID iD orcid.org/0000-0002-0778-6515

Catalogue record

Date deposited: 01 Nov 2023 18:02
Last modified: 18 Mar 2024 04:10

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Contributors

Author: Vaishali
Author: T. Mukhopadhyay ORCID iD
Author: P. K. Karsh
Author: B. Basu
Author: S. Dey

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