New validation metric for solid mechanics models

Numerical simulation is essential in mechanical engineering as it predicts the mechanical behaviour of a component when subjected to external forces, helping to improve performance and optimise design. Before utilizing the numerical model's valuable information, its reliability must be verified...

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Autores: Sáez Landete, José Bienvenido|||0000-0002-9384-9745, Vargas Vargas, Horlando, Siegmann, Philip|||0000-0002-0231-0446, Camacho Bello, César
Formato: artículo
Fecha de publicación:2024
País:España
Recursos:Universidad de Alcalá (UAH)
Repositorio:e_Buah Biblioteca Digital Universidad de Alcalá
Idioma:inglés
OAI Identifier:oai:ebuah.uah.es:10017/62830
Acesso em linha:http://hdl.handle.net/10017/62830
https://dx.doi.org/10.1016/j.optlaseng.2024.108306
Access Level:acceso abierto
Palavra-chave:Validation methods
Finite element analysis
Digital image correlation
Zernike moments
Strain analysis
Telecomunicaciones
Telecommunication
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spelling New validation metric for solid mechanics modelsSáez Landete, José Bienvenido|||0000-0002-9384-9745Vargas Vargas, HorlandoSiegmann, Philip|||0000-0002-0231-0446Camacho Bello, CésarValidation methodsFinite element analysisDigital image correlationZernike momentsStrain analysisTelecomunicacionesTelecommunicationNumerical simulation is essential in mechanical engineering as it predicts the mechanical behaviour of a component when subjected to external forces, helping to improve performance and optimise design. Before utilizing the numerical model's valuable information, its reliability must be verified through a validation process. Validation is usually carried out by comparison with full field experimental measurements of the displacement or strain maps that undergoes the probe sample when subjected to the external forces, mainly with the technique of digital image correlation. The numerical simulation and its predictions are validated if there is an agreement between the model's prediction and the corresponding experimental measurements. In this procedure, comparing the simulated and experimental data requires an image compression process, typically using descriptors based on Zernike moments or any polynomial decomposition. In more recent work, agreement or validation is quantified with a “probabilistic validation metric” (PVM), which is obtained by measuring the normalised differences of these moments. For the PVM, these differences must be below a predetermined and constant threshold obtained from the experimental uncertainty and the reconstruction error of the moments. The threshold effectively captures the behaviour of lower-order moments, but is insensitive to changes in higher-order moments. In this work, a new validation method called “Moment Validation Metric” (MVM) is proposed. It introduces an adaptive threshold that is specific to each moment, considering the impact of the propagation of the uncertainty and the errors in the experimental and simulated measurements of the associated maps. The uncertainty of the maps is propagated to the moments through an accurate calculation procedure of the moments shown in [1]. As a result, moments containing most of the information (with the highest impact) have a smaller threshold, while moments with lower impact tend to have a larger threshold. The proposed validation method detects and quantifies differences in the experimental and simulated maps which are not detected by previous techniques. The MVM, being more accurate, is able to identify these differences more effectively.Elsevier20242024-09-01journal articlehttp://purl.org/coar/resource_type/c_6501NAhttp://purl.org/coar/version/c_be7fb7dd8ff6fe43info:eu-repo/semantics/articleapplication/pdfhttp://hdl.handle.net/10017/62830https://dx.doi.org/10.1016/j.optlaseng.2024.108306reponame:e_Buah Biblioteca Digital Universidad de Alcaláinstname:Universidad de Alcalá (UAH)Inglésengopen accesshttp://purl.org/coar/access_right/c_abf2Attribution-NonCommercial-NoDerivatives 4.0 Internationalhttp://creativecommons.org/licenses/by-nc-nd/4.0/info:eu-repo/semantics/openAccessoai:ebuah.uah.es:10017/628302026-06-18T11:13:07Z
dc.title.none.fl_str_mv New validation metric for solid mechanics models
title New validation metric for solid mechanics models
spellingShingle New validation metric for solid mechanics models
Sáez Landete, José Bienvenido|||0000-0002-9384-9745
Validation methods
Finite element analysis
Digital image correlation
Zernike moments
Strain analysis
Telecomunicaciones
Telecommunication
title_short New validation metric for solid mechanics models
title_full New validation metric for solid mechanics models
title_fullStr New validation metric for solid mechanics models
title_full_unstemmed New validation metric for solid mechanics models
title_sort New validation metric for solid mechanics models
dc.creator.none.fl_str_mv Sáez Landete, José Bienvenido|||0000-0002-9384-9745
Vargas Vargas, Horlando
Siegmann, Philip|||0000-0002-0231-0446
Camacho Bello, César
author Sáez Landete, José Bienvenido|||0000-0002-9384-9745
author_facet Sáez Landete, José Bienvenido|||0000-0002-9384-9745
Vargas Vargas, Horlando
Siegmann, Philip|||0000-0002-0231-0446
Camacho Bello, César
author_role author
author2 Vargas Vargas, Horlando
Siegmann, Philip|||0000-0002-0231-0446
Camacho Bello, César
author2_role author
author
author
dc.subject.none.fl_str_mv Validation methods
Finite element analysis
Digital image correlation
Zernike moments
Strain analysis
Telecomunicaciones
Telecommunication
topic Validation methods
Finite element analysis
Digital image correlation
Zernike moments
Strain analysis
Telecomunicaciones
Telecommunication
description Numerical simulation is essential in mechanical engineering as it predicts the mechanical behaviour of a component when subjected to external forces, helping to improve performance and optimise design. Before utilizing the numerical model's valuable information, its reliability must be verified through a validation process. Validation is usually carried out by comparison with full field experimental measurements of the displacement or strain maps that undergoes the probe sample when subjected to the external forces, mainly with the technique of digital image correlation. The numerical simulation and its predictions are validated if there is an agreement between the model's prediction and the corresponding experimental measurements. In this procedure, comparing the simulated and experimental data requires an image compression process, typically using descriptors based on Zernike moments or any polynomial decomposition. In more recent work, agreement or validation is quantified with a “probabilistic validation metric” (PVM), which is obtained by measuring the normalised differences of these moments. For the PVM, these differences must be below a predetermined and constant threshold obtained from the experimental uncertainty and the reconstruction error of the moments. The threshold effectively captures the behaviour of lower-order moments, but is insensitive to changes in higher-order moments. In this work, a new validation method called “Moment Validation Metric” (MVM) is proposed. It introduces an adaptive threshold that is specific to each moment, considering the impact of the propagation of the uncertainty and the errors in the experimental and simulated measurements of the associated maps. The uncertainty of the maps is propagated to the moments through an accurate calculation procedure of the moments shown in [1]. As a result, moments containing most of the information (with the highest impact) have a smaller threshold, while moments with lower impact tend to have a larger threshold. The proposed validation method detects and quantifies differences in the experimental and simulated maps which are not detected by previous techniques. The MVM, being more accurate, is able to identify these differences more effectively.
publishDate 2024
dc.date.none.fl_str_mv 2024
2024-09-01
dc.type.none.fl_str_mv journal article
http://purl.org/coar/resource_type/c_6501
NA
http://purl.org/coar/version/c_be7fb7dd8ff6fe43
dc.type.openaire.fl_str_mv info:eu-repo/semantics/article
format article
dc.identifier.none.fl_str_mv http://hdl.handle.net/10017/62830
https://dx.doi.org/10.1016/j.optlaseng.2024.108306
url http://hdl.handle.net/10017/62830
https://dx.doi.org/10.1016/j.optlaseng.2024.108306
dc.language.none.fl_str_mv Inglés
eng
language_invalid_str_mv Inglés
language eng
dc.rights.none.fl_str_mv open access
http://purl.org/coar/access_right/c_abf2
Attribution-NonCommercial-NoDerivatives 4.0 International
http://creativecommons.org/licenses/by-nc-nd/4.0/
dc.rights.openaire.fl_str_mv info:eu-repo/semantics/openAccess
rights_invalid_str_mv open access
http://purl.org/coar/access_right/c_abf2
Attribution-NonCommercial-NoDerivatives 4.0 International
http://creativecommons.org/licenses/by-nc-nd/4.0/
eu_rights_str_mv openAccess
dc.format.none.fl_str_mv application/pdf
dc.publisher.none.fl_str_mv Elsevier
publisher.none.fl_str_mv Elsevier
dc.source.none.fl_str_mv reponame:e_Buah Biblioteca Digital Universidad de Alcalá
instname:Universidad de Alcalá (UAH)
instname_str Universidad de Alcalá (UAH)
reponame_str e_Buah Biblioteca Digital Universidad de Alcalá
collection e_Buah Biblioteca Digital Universidad de Alcalá
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