State-Based Adjoint Method for Reduced Order Modeling

Bang, Youngsuk; Wang, Congjian; Abdel-Khalik, Hany S.

doi:10.1080/00411450.2012.672359

Cited by 5 publications

(7 citation statements)

References 24 publications

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“…In this work, an "Adjoint Proper Orthogonal Decomposition" method is proposed which is aimed at combining the feature of the Proper Orthogonal Decomposition for the spatial basis functions and the adjoint function as test functions. This approach can be intended to some extent as the counterpart of what presented in (Bang et al, 2012b) but applied to the projection-based framework (instead of the interpolation-based one). In order to assess the capability of the APOD method, a comparison with other couples of spatial basis functions and test functions is performed.…”

Section: Spatial Basis Calculation and The Adjoint Proper Orthogonal ...mentioning

confidence: 99%

An Adjoint Proper Orthogonal Decomposition method for a neutronics reduced order model

Lorenzi

2018

Annals of Nuclear Energy

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Section: Spatial Basis Calculation and The Adjoint Proper Orthogonal ...mentioning

confidence: 99%

An Adjoint Proper Orthogonal Decomposition method for a neutronics reduced order model

Lorenzi

2018

Annals of Nuclear Energy

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“…They are usually divided into two steps, an offline step carried out once and an online step for each new calculation. In reactor physics, Proper Orthogonal Decomposition [5,6] or Principal Component Analysis in statistics [7] are commonly used for the creation of the basis. The basis can be constructed using a range-finding algorithm which captures the active subspace of our problem and provides an a posteriori estimator for the precision [8].…”

Section: Introductionmentioning

confidence: 99%

“…For example, Galerkin projection allows solving a reduced order system instead of the full one [10]. Differently, adjoint based reduced order model uses the adjoint equation to calculate the projection coefficients [6]. Hence, one does not solve a reduced order system but simply calculates the projection of the solution on the reduced basis.…”

Section: Introductionmentioning

confidence: 99%

A Novel Adjoint Based Reduced Order Model for Depletion Calculations in Nuclear Reactor Physics

Sauzedde,

Archier,

Nguyen

2024

Preprint

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The licensing of new reactors implies the use of verified and validated neutronics codes. Numerical validation can rely on sensitivity and uncertainty studies but they require repeated execution of time-consuming neutron flux and depletion calculations. The computational costs can be shortened by using perturbation theories. However, Depletion Perturbation Theory is restricted to single integral values such as a nuclide density. Relying on reduced basis approaches, which reconstruct the whole nuclide densities at once, is one way to get around this restriction. Furthermore, the adjoint-based reduced-order model uses the direct and adjoint equations for the projection. For diffusion or transport calculations, Exact-to-Precision Generalized Perturbation Theory has been developed. Still, no models for depletion calculations are readily available. Therefore, this paper describes a novel adjoint-based reduced order model for the Bateman equation. It uses a range-finding algorithm to create the basis and the Depletion Perturbation Theory for the reconstruction of the nuclide densities at first order. Our paper shows that for several perturbed cases, the depletion reduced-order model successfully reconstructs the nuclide densities. As a result, this serves as a proof of concept for our adjoint-based reduced order model which can perform sensitivity and uncertainty burn-up analysis in a shorter time.

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“…In nuclear engineering, efficient basis construction algorithms based on randomized subspace methodologies have been proposed and their feasibility to reactor physics applications has been demonstrated. For example, the state-level reduction technique was incorporated into initial condition perturbation theory to reduce the number of adjoint mode runs [2]. The parameter-level reduction technique was applied to second order sensitivity analysis and uncertainty propagation [3].…”

Section: Introductionmentioning

confidence: 99%

“…Assembly Model (PB-2 BWR) PWR Assembly Model (WB-2 PWR) SCALE Assembly ModelSuppose that the models can be expressed as: is the variations in system configurations, i.e. fuel/moderator temperatures or nuclide number densities, -0      is the effective macroscopic cross section changes, values of system configurations, effective macroscopic cross sections and k-eigenvalue, respectively, f represents a resonance calculation (BONAMI) g represents a transport calculation (NEWT)2 the nuclides in different mixtures are counted as different nuclides though there are the same isotopes because they are depleted differently.…”

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confidence: 99%

Hybrid reduced order modeling for assembly calculations

Bang¹,

Abdel-Khalik

Jessee

et al. 2015

Nuclear Engineering and Design

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While the accuracy of assembly calculations has considerably improved due to the increase in computer power enabling more refined description of the phase space and use of more sophisticated numerical algorithms, the computational cost continues to increase which limits the full utilization of their effectiveness for routine engineering analysis. Reduced order modeling is a mathematical vehicle that scales down the dimensionality of large-scale numerical problems to enable their repeated executions on small computing environment, often available to end users. This is done by capturing the most dominant underlying relationships between the model's inputs and outputs. Previous works demonstrated the use of the reduced order modeling for a single physics code, such as a radiation transport calculation. This manuscript extends those works to coupled code systems as currently employed in assembly calculations. Numerical tests are conducted using realistic SCALE assembly models with resonance self-shielding, neutron transport, and nuclides transmutation/depletion models representing the components of the coupled code system.

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State-Based Adjoint Method for Reduced Order Modeling

Cited by 5 publications

References 24 publications

An Adjoint Proper Orthogonal Decomposition method for a neutronics reduced order model

An Adjoint Proper Orthogonal Decomposition method for a neutronics reduced order model

A Novel Adjoint Based Reduced Order Model for Depletion Calculations in Nuclear Reactor Physics

Hybrid reduced order modeling for assembly calculations

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