Metamodeling techniques for CPU-intensive simulation-based design optimization: a survey

Khatouri, Hanane; Benamara, Tariq; Breitkopf, Piotr; Demange, J

doi:10.1186/s40323-022-00214-y

Cited by 13 publications

(6 citation statements)

References 196 publications

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“…These responses may be obtained through numerical simulations or experimental measurements. The surrogate is subsequently trained employing Machine Learning and Model Order Reduction techniques [26][27][28][29][30][31]. It is important to emphasize that during the surrogate training process, we assume precise knowledge of the values of each feature in p. This assumption enables the collection of the corresponding quantity of interest for the parameters' samples within the DoE.…”

Section: Uncertainty Propagation Through Parametric Surrogatementioning

confidence: 99%

Parametric Metamodeling Based on Optimal Transport Applied to Uncertainty Evaluation

Torregrosa,

Muñoz,

Herbert

et al. 2024

Technologies

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When training a parametric surrogate to represent a real-world complex system in real time, there is a common assumption that the values of the parameters defining the system are known with absolute confidence. Consequently, during the training process, our focus is directed exclusively towards optimizing the accuracy of the surrogate’s output. However, real physics is characterized by increased complexity and unpredictability. Notably, a certain degree of uncertainty may exist in determining the system’s parameters. Therefore, in this paper, we account for the propagation of these uncertainties through the surrogate using a standard Monte Carlo methodology. Subsequently, we propose a novel regression technique based on optimal transport to infer the impact of the uncertainty of the surrogate’s input on its output precision in real time. The OT-based regression allows for the inference of fields emulating physical reality more accurately than classical regression techniques, including advanced ones.

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Section: Uncertainty Propagation Through Parametric Surrogatementioning

confidence: 99%

Parametric Metamodeling Based on Optimal Transport Applied to Uncertainty Evaluation

Torregrosa,

Muñoz,

Herbert

et al. 2024

Technologies

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“…In [7] drew from two different but related concepts of modeling and simulation. The [8] describe modeling and simulation as providing inputs to a model of a system and watching the resulting outputs, whereas [9] defines modeling and simulation as "the act of developing a model of a conceptual system and utilizing it to conduct experiments with the aim of understanding the performance of the system and/or assessing different management strategies and decision-making processes using simulation result as inputs and outputs" Modeling and simulation may be used for a wide variety of purposes, such as testing hypotheses, making predictions, learning new information, teaching, and even providing amusement. Research into computer systems, industrial processes, social systems, political structures, corporate structures, ecological environments, and other complex processes and systems all make use of simulation.…”

Section: Introductionmentioning

confidence: 99%

Different Numerical Techniques, Modeling and Simulation in Solving Complex Problems

Hong

2023

JMC

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This study investigates the performance of different numerical techniques, modeling, and simulation in solving complex problems. The study found that the Finite Element Method was found to be the most precise numerical approach for simulating the behavior of structures under loading conditions, the Finite Difference Method was found to be the most efficient numerical technique for simulating fluid flow and heat transfer problems, and the Boundary Element Method was found to be the most effective numerical technique for solving problems involving singularities, such as those found in acoustics and electromagnetics. The mathematical model established in this research was able to effectively forecast the behaviors of the system under different conditions, with an error of less than 5%. The physical model established in this research was able to replicate the behavior of the system under different conditions, with an error of less than 2%. The employment of multi-physics or multi-scale modeling was found to be effective in overcoming the limitations of traditional numerical techniques. The results of this research have significant effects for the field of numerical techniques, modeling and simulation, and can be used to guide engineers and researchers in choosing the most appropriate numerical technique for their specific problem or application.

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“…The uncertainty propagation in such models is also fundamental to operate efficiently in diagnosis and prognosis. In a non-intrusive framework, given an engineering problem, a Design of Experiments-DoE-based on the problem parameters is established and the corresponding responses of the system are collected into databases, which are used as training data to build the surrogate model via Machine Learning-ML-and Model Order Reduction-MOR-algorithms (Wang and Shan, 2007;Benner et al, 2015;Hesthaven and Ubbiali, 2018;Rajaram et al, 2020;Franchini et al, 2022;Khatouri et al, 2022). Such responses are usually the ensemble of several Quantities of Interest-QoI-observed, for instance, over time (i.e., time series) and can come both from experiments and numerical simulations.…”

Section: Introductionmentioning

confidence: 99%

Parametric Curves Metamodelling Based on Data Clustering, Data Alignment, POD-Based Modes Extraction and PGD-Based Nonlinear Regressions

et al. 2022

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In the context of parametric surrogates, several nontrivial issues arise when a whole curve shall be predicted from given input features. For instance, different sampling or ending points lead to non-aligned curves. This also happens when the curves exhibit a common pattern characterized by critical points at shifted locations (e.g., in mechanics, the elastic-plastic transition or the rupture point for a material). In such cases, classical interpolation methods fail in giving physics-consistent results and appropriate pre-processing steps are required. Moreover, when bifurcations occur into the parametric space, to enhance the accuracy of the surrogate, a coupling with clustering and classification algorithms is needed. In this work we present several methodologies to overcome these issues. We also exploit such surrogates to quantify and propagate uncertainty, furnishing parametric stastistical bounds for the predicted curves. The procedures are exemplified over two problems in Computational Mechanics.

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Metamodeling techniques for CPU-intensive simulation-based design optimization: a survey

Cited by 13 publications

References 196 publications

Parametric Metamodeling Based on Optimal Transport Applied to Uncertainty Evaluation

Parametric Metamodeling Based on Optimal Transport Applied to Uncertainty Evaluation

Different Numerical Techniques, Modeling and Simulation in Solving Complex Problems

Parametric Curves Metamodelling Based on Data Clustering, Data Alignment, POD-Based Modes Extraction and PGD-Based Nonlinear Regressions

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