Solving Inverse Parametrized Problems via Finite Elements and Extreme Learning Networks
- URL: http://arxiv.org/abs/2602.14757v1
- Date: Mon, 16 Feb 2026 14:01:50 GMT
- Title: Solving Inverse Parametrized Problems via Finite Elements and Extreme Learning Networks
- Authors: Erik Burman, Mats G. Larson, Karl Larsson, Jonatan Vallin,
- Abstract summary: We develop a parametric-based reduced-order modeling framework for parameter-dependent partial differential equations.<n>We derive rigorous error estimates that explicitly quantify the interplay between spatial discretization and parameter approximation.<n>The proposed framework is applied to inverse problems in quantitative photoacoustic tomography, where we derive potential and parameter reconstruction error estimates.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: We develop an interpolation-based reduced-order modeling framework for parameter-dependent partial differential equations arising in control, inverse problems, and uncertainty quantification. The solution is discretized in the physical domain using finite element methods, while the dependence on a finite-dimensional parameter is approximated separately. We establish existence, uniqueness, and regularity of the parametric solution and derive rigorous error estimates that explicitly quantify the interplay between spatial discretization and parameter approximation. In low-dimensional parameter spaces, classical interpolation schemes yield algebraic convergence rates based on Sobolev regularity in the parameter variable. In higher-dimensional parameter spaces, we replace classical interpolation by extreme learning machine (ELM) surrogates and obtain error bounds under explicit approximation and stability assumptions. The proposed framework is applied to inverse problems in quantitative photoacoustic tomography, where we derive potential and parameter reconstruction error estimates and demonstrate substantial computational savings compared to standard approaches, without sacrificing accuracy.
Related papers
- Wasserstein Regression as a Variational Approximation of Probabilistic Trajectories through the Bernstein Basis [41.99844472131922]
Existing approaches often ignore the geometry of the probability space or are computationally expensive.<n>A new method is proposed that combines the parameterization of probability trajectories using a Bernstein basis and the minimization of the Wasserstein distance between distributions.<n>The developed approach combines geometric accuracy, computational practicality, and interpretability.
arXiv Detail & Related papers (2025-10-30T15:36:39Z) - Parameter Identification for Partial Differential Equation with Jump Discontinuities in Coefficients by Markov Switching Model and Physics-Informed Machine Learning [13.124899777324602]
In this work, we propose a novel framework that integrates physics-informed deep learning with Bayesian inference for accurate parameter identification in PDEs with jump discontinuities in coefficients.<n>To identify mixture structures in discontinuous parameter spaces, we employ Markovian dynamics methods to capture hidden state transitions of complextemporal systems.<n>This study provides a generalizable computational approach of parameter identification for PDEs with discontinuous parameter structures, particularly in non-stationary or heterogeneous systems.
arXiv Detail & Related papers (2025-10-16T13:12:26Z) - Deep Learning for Subspace Regression [42.94349364701736]
A practical way to apply such a scheme is to compute subspaces for a selected set of parameters in the computationally demanding offline stage.<n>For realistic problems the space of parameters is high dimensional, which renders classical strategies infeasible or unreliable.<n>We propose to relax the problem to regression, introduce several loss functions suitable for subspace data, and use a neural network as an approximation to high-dimensional target function.
arXiv Detail & Related papers (2025-09-27T10:56:03Z) - Gaussian process surrogate with physical law-corrected prior for multi-coupled PDEs defined on irregular geometry [3.3798563347021093]
Parametric partial differential equations (PDEs) are fundamental mathematical tools for modeling complex physical systems.<n>We propose a novel physical law-corrected prior Gaussian process (LC-prior GP) surrogate modeling framework.
arXiv Detail & Related papers (2025-09-01T02:40:32Z) - Total Uncertainty Quantification in Inverse PDE Solutions Obtained with Reduced-Order Deep Learning Surrogate Models [50.90868087591973]
We propose an approximate Bayesian method for quantifying the total uncertainty in inverse PDE solutions obtained with machine learning surrogate models.
We test the proposed framework by comparing it with the iterative ensemble smoother and deep ensembling methods for a non-linear diffusion equation.
arXiv Detail & Related papers (2024-08-20T19:06:02Z) - Multivariate root-n-consistent smoothing parameter free matching estimators and estimators of inverse density weighted expectations [51.000851088730684]
We develop novel modifications of nearest-neighbor and matching estimators which converge at the parametric $sqrt n $-rate.<n>We stress that our estimators do not involve nonparametric function estimators and in particular do not rely on sample-size dependent parameters smoothing.
arXiv Detail & Related papers (2024-07-11T13:28:34Z) - Diffusion Tempering Improves Parameter Estimation with Probabilistic Integrators for Ordinary Differential Equations [34.500484733973536]
Ordinary differential equations (ODEs) are widely used to describe dynamical systems in science, but identifying parameters that explain experimental measurements is challenging.
We propose diffusion tempering, a novel regularization technique for probabilistic numerical methods which improves convergence of gradient-based parameter optimization in ODEs.
We demonstrate that our method is effective for dynamical systems of different complexity and show that it obtains reliable parameter estimates for a Hodgkin-Huxley model with a practically relevant number of parameters.
arXiv Detail & Related papers (2024-02-19T15:36:36Z) - Counting Phases and Faces Using Bayesian Thermodynamic Integration [77.34726150561087]
We introduce a new approach to reconstruction of the thermodynamic functions and phase boundaries in two-parametric statistical mechanics systems.
We use the proposed approach to accurately reconstruct the partition functions and phase diagrams of the Ising model and the exactly solvable non-equilibrium TASEP.
arXiv Detail & Related papers (2022-05-18T17:11:23Z) - A Variational Inference Approach to Inverse Problems with Gamma
Hyperpriors [60.489902135153415]
This paper introduces a variational iterative alternating scheme for hierarchical inverse problems with gamma hyperpriors.
The proposed variational inference approach yields accurate reconstruction, provides meaningful uncertainty quantification, and is easy to implement.
arXiv Detail & Related papers (2021-11-26T06:33:29Z) - Optimal oracle inequalities for solving projected fixed-point equations [53.31620399640334]
We study methods that use a collection of random observations to compute approximate solutions by searching over a known low-dimensional subspace of the Hilbert space.
We show how our results precisely characterize the error of a class of temporal difference learning methods for the policy evaluation problem with linear function approximation.
arXiv Detail & Related papers (2020-12-09T20:19:32Z) - Understanding Implicit Regularization in Over-Parameterized Single Index
Model [55.41685740015095]
We design regularization-free algorithms for the high-dimensional single index model.
We provide theoretical guarantees for the induced implicit regularization phenomenon.
arXiv Detail & Related papers (2020-07-16T13:27:47Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.