Uncertainty quantification in a two-dimensional river hydraulic model

Siham El Garroussi; Matthias De Lozzo; Sophie Ricci; Didier Lucor; Nicole Goutal; Cedric Goeury; Sebastien Boyaval

doi:10.7712/120219.6339.18380

Uncertainty quantification in a two-dimensional river hydraulic model

Siham El Garroussi
, Matthias De Lozzo
, Sophie Ricci
, Didier Lucor
, Nicole Goutal
, Cedric Goeury
, Sebastien Boyaval

CERFACS
CS34436
INRIA Saclay, Laboratoire de Recherche en Informatique (LRI), Université Paris Sud
Lamsid/EDF/R and D
Saint-Venant Laboratory

Résultats de recherche: Le chapitre dans un livre, un rapport, une anthologie ou une collection › Contribution à une conférence › Revue par des pairs

Résumé

River hydraulic models are used to assess the environmental risk associated to flooding and consequently inform decision support systems for civil security needs. These numerical models are generally based on a deterministic approach based on resolving the partial differential equations. However, these models are subject to various types of uncertainties in their input. Knowledge of the type and magnitude of these uncertainties is crucial for a meaningful interpretation of the model results. Uncertainty quantification (UQ) framework aims to probabilize the uncertainties in the input, propagate them through the numerical model and quantify their impact on the simulated quantity of interest, here, water level field discretized over an unstructured finite element mesh over the Garonne River (South-West France) between Tonneins and La Reole simulated with a numerical solver, TELEMAC-2D. The computational cost of the sensitivity analysis with the classical Monte Carlo approach is reduced using a surrogate model instead of the numerical solver. The present study investigates one of the machine learning algorithms: A surrogate model based on Gaussian process. This latter was used to represent the spatially distributed water level with respect to uncertain stationary flow to the model and friction coefficients. The quality of the surrogate was assessed on a validation set, with small root mean square error and a predictive coefficient equal to 1. Sobol' sensitivity indices are computed and enhance the high impact of the input discharge on the water level variation.

langue originale	Anglais
titre	Proceedings of the 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019
rédacteurs en chef	M. Papadrakakis, V. Papadopoulos, G. Stefanou
Editeur	National Technical University of Athens
Pages	243-262
Nombre de pages	20
ISBN (imprimé)	9786188284494
Les DOIs	https://doi.org/10.7712/120219.6339.18380
état	Publié - 1 janv. 2019
Modification externe	Oui
Evénement	3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019 - Crete, Grcce Durée: 24 juin 2019 → 26 juin 2019

Série de publications

Nom	Proceedings of the 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019

Une conférence

Une conférence	3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019
Pays/Territoire	Grcce
La ville	Crete
période	24/06/19 → 26/06/19

Accès au document

10.7712/120219.6339.18380

Autres fichiers et liens

Lien vers la publication dans Scopus

Contient cette citation

El Garroussi, S., De Lozzo, M., Ricci, S., Lucor, D., Goutal, N., Goeury, C., & Boyaval, S. (2019). Uncertainty quantification in a two-dimensional river hydraulic model. Dans M. Papadrakakis, V. Papadopoulos, & G. Stefanou (eds.), Proceedings of the 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019 (p. 243-262). (Proceedings of the 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019). National Technical University of Athens. https://doi.org/10.7712/120219.6339.18380

El Garroussi, Siham ; De Lozzo, Matthias ; Ricci, Sophie et al. / Uncertainty quantification in a two-dimensional river hydraulic model. Proceedings of the 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019. Editeur / M. Papadrakakis ; V. Papadopoulos ; G. Stefanou. National Technical University of Athens, 2019. p. 243-262 (Proceedings of the 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019).

@inproceedings{6febd6564a2f421a8e94664f6a6cef1e,

title = "Uncertainty quantification in a two-dimensional river hydraulic model",

abstract = "River hydraulic models are used to assess the environmental risk associated to flooding and consequently inform decision support systems for civil security needs. These numerical models are generally based on a deterministic approach based on resolving the partial differential equations. However, these models are subject to various types of uncertainties in their input. Knowledge of the type and magnitude of these uncertainties is crucial for a meaningful interpretation of the model results. Uncertainty quantification (UQ) framework aims to probabilize the uncertainties in the input, propagate them through the numerical model and quantify their impact on the simulated quantity of interest, here, water level field discretized over an unstructured finite element mesh over the Garonne River (South-West France) between Tonneins and La Reole simulated with a numerical solver, TELEMAC-2D. The computational cost of the sensitivity analysis with the classical Monte Carlo approach is reduced using a surrogate model instead of the numerical solver. The present study investigates one of the machine learning algorithms: A surrogate model based on Gaussian process. This latter was used to represent the spatially distributed water level with respect to uncertain stationary flow to the model and friction coefficients. The quality of the surrogate was assessed on a validation set, with small root mean square error and a predictive coefficient equal to 1. Sobol' sensitivity indices are computed and enhance the high impact of the input discharge on the water level variation.",

keywords = "Gaussian process, Monte Carlo method, Open-channel flow, Sensitivity analysis, Surrogate model",

author = "\{El Garroussi\}, Siham and \{De Lozzo\}, Matthias and Sophie Ricci and Didier Lucor and Nicole Goutal and Cedric Goeury and Sebastien Boyaval",

note = "Publisher Copyright: {\textcopyright} 2019 Proceedings of the 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019. All rights reserved.; 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019 ; Conference date: 24-06-2019 Through 26-06-2019",

year = "2019",

month = jan,

day = "1",

doi = "10.7712/120219.6339.18380",

language = "English",

isbn = "9786188284494",

series = "Proceedings of the 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019",

publisher = "National Technical University of Athens",

pages = "243--262",

editor = "M. Papadrakakis and V. Papadopoulos and G. Stefanou",

booktitle = "Proceedings of the 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019",

}

El Garroussi, S, De Lozzo, M, Ricci, S, Lucor, D, Goutal, N, Goeury, C & Boyaval, S 2019, Uncertainty quantification in a two-dimensional river hydraulic model. Dans M Papadrakakis, V Papadopoulos & G Stefanou (eds), Proceedings of the 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019. Proceedings of the 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019, National Technical University of Athens, p. 243-262, 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019, Crete, Grcce, 24/06/19. https://doi.org/10.7712/120219.6339.18380

Uncertainty quantification in a two-dimensional river hydraulic model. / El Garroussi, Siham; De Lozzo, Matthias; Ricci, Sophie et al.
Proceedings of the 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019. Ed. / M. Papadrakakis; V. Papadopoulos; G. Stefanou. National Technical University of Athens, 2019. p. 243-262 (Proceedings of the 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019).

Résultats de recherche: Le chapitre dans un livre, un rapport, une anthologie ou une collection › Contribution à une conférence › Revue par des pairs

TY - GEN

T1 - Uncertainty quantification in a two-dimensional river hydraulic model

AU - El Garroussi, Siham

AU - De Lozzo, Matthias

AU - Ricci, Sophie

AU - Lucor, Didier

AU - Goutal, Nicole

AU - Goeury, Cedric

AU - Boyaval, Sebastien

PY - 2019/1/1

Y1 - 2019/1/1

N2 - River hydraulic models are used to assess the environmental risk associated to flooding and consequently inform decision support systems for civil security needs. These numerical models are generally based on a deterministic approach based on resolving the partial differential equations. However, these models are subject to various types of uncertainties in their input. Knowledge of the type and magnitude of these uncertainties is crucial for a meaningful interpretation of the model results. Uncertainty quantification (UQ) framework aims to probabilize the uncertainties in the input, propagate them through the numerical model and quantify their impact on the simulated quantity of interest, here, water level field discretized over an unstructured finite element mesh over the Garonne River (South-West France) between Tonneins and La Reole simulated with a numerical solver, TELEMAC-2D. The computational cost of the sensitivity analysis with the classical Monte Carlo approach is reduced using a surrogate model instead of the numerical solver. The present study investigates one of the machine learning algorithms: A surrogate model based on Gaussian process. This latter was used to represent the spatially distributed water level with respect to uncertain stationary flow to the model and friction coefficients. The quality of the surrogate was assessed on a validation set, with small root mean square error and a predictive coefficient equal to 1. Sobol' sensitivity indices are computed and enhance the high impact of the input discharge on the water level variation.

AB - River hydraulic models are used to assess the environmental risk associated to flooding and consequently inform decision support systems for civil security needs. These numerical models are generally based on a deterministic approach based on resolving the partial differential equations. However, these models are subject to various types of uncertainties in their input. Knowledge of the type and magnitude of these uncertainties is crucial for a meaningful interpretation of the model results. Uncertainty quantification (UQ) framework aims to probabilize the uncertainties in the input, propagate them through the numerical model and quantify their impact on the simulated quantity of interest, here, water level field discretized over an unstructured finite element mesh over the Garonne River (South-West France) between Tonneins and La Reole simulated with a numerical solver, TELEMAC-2D. The computational cost of the sensitivity analysis with the classical Monte Carlo approach is reduced using a surrogate model instead of the numerical solver. The present study investigates one of the machine learning algorithms: A surrogate model based on Gaussian process. This latter was used to represent the spatially distributed water level with respect to uncertain stationary flow to the model and friction coefficients. The quality of the surrogate was assessed on a validation set, with small root mean square error and a predictive coefficient equal to 1. Sobol' sensitivity indices are computed and enhance the high impact of the input discharge on the water level variation.

KW - Gaussian process

KW - Monte Carlo method

KW - Open-channel flow

KW - Sensitivity analysis

KW - Surrogate model

UR - https://www.scopus.com/pages/publications/85079324418

U2 - 10.7712/120219.6339.18380

DO - 10.7712/120219.6339.18380

M3 - Conference contribution

AN - SCOPUS:85079324418

SN - 9786188284494

T3 - Proceedings of the 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019

SP - 243

EP - 262

BT - Proceedings of the 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019

A2 - Papadrakakis, M.

A2 - Papadopoulos, V.

A2 - Stefanou, G.

PB - National Technical University of Athens

T2 - 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019

Y2 - 24 June 2019 through 26 June 2019

ER -

El Garroussi S, De Lozzo M, Ricci S, Lucor D, Goutal N, Goeury C et al. Uncertainty quantification in a two-dimensional river hydraulic model. Dans Papadrakakis M, Papadopoulos V, Stefanou G, rédacteurs en chef, Proceedings of the 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019. National Technical University of Athens. 2019. p. 243-262. (Proceedings of the 3rd International Conference on Uncertainty Quantification in Computational Sciences and Engineering, UNCECOMP 2019). doi: 10.7712/120219.6339.18380

Uncertainty quantification in a two-dimensional river hydraulic model

Résumé

Série de publications

Une conférence

Accès au document

Autres fichiers et liens

Empreinte digitale

Contient cette citation