Data-Driven Surrogate Models for Agromaritime Applications: Finite Element-Neural Network Integration

TL;DR

This paper presents a hybrid finite element-neural network approach for rapid, accurate prediction of nutrient transport and salinity in agromaritime systems, significantly speeding up computations while maintaining acceptable accuracy.

Contribution

It introduces a novel integration of FEM, POD, and neural networks to create efficient surrogates for complex PDE models in agromaritime applications.

Findings

NN surrogate achieves 956x speed-up over FEM solver.

Mean relative L2-error of 15% across test scenarios.

Method enables rapid scenario screening and parametric studies.

Abstract

Predicting nutrient transport and salinity distribution is crucial for mitigating climate-related threats to agromaritime systems. Traditional PDE-based models can capture the physics of nutrient dispersion, salinity and water quality. However, they face challenges in scalability and adaptability to real-time problems. In this article, we develop a hybrid approach that combines finite element discretisations with neural network integration to enable efficient and adaptive data-informed predictions. We use a finite element solver for the steady-state diffusion-reaction equation to generate a dataset across varying diffusivity, reaction and inflow conditions. We then build a proper orthogonal decomposition (POD), which reduces dimensionality, and a neural network (NN) that maps parameters to reduced coefficients. A numerical study presented on a simplified model demonstrates the proof-of-concept for predicting nutrient transport and salinity distribution. Numerical experiments show that the NN surrogate achieve a speed-up of approximately 956x compared to a regular FEM solver while maintaining an accuracy of mean relative L2-errors of 15% across the test set, with occasional higher deviations, which is sufficient for rapid scenario screening and parametric studies. These results highlight the method's potential as a fast and accurate surrogate for nutrient and salinity prediction, offering a balance between FEM reliability and NN adaptability for sustainable agromaritime management.