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Bibliographic Details
Main Authors: Uzma, Cholet, Fabien, Quinn, Domenic, Smith, Cindy, You, Siming, Sloan, William
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2504.18595
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author Uzma
Cholet, Fabien
Quinn, Domenic
Smith, Cindy
You, Siming
Sloan, William
author_facet Uzma
Cholet, Fabien
Quinn, Domenic
Smith, Cindy
You, Siming
Sloan, William
contents Environmental biotechnologies, such as drinking water biofilters, rely on complex interactions between microbial communities and their surrounding physical-chemical environments. Predicting the performance of these systems is challenging due to high-dimensional, sparse datasets that lack diversity and fail to fully capture system behaviour. Accurate predictive models require innovative, science-guided approaches. In this study, we present the first application of Buckingham Pi theory to modelling biofilter performance. This dimensionality reduction technique identifies meaningful, dimensionless variables that enhance predictive accuracy and improve model interpretability. Using these variables, we developed the Environmental Buckingham Pi Neural Network (EnviroPiNet), a physics-guided model benchmarked against traditional data-driven methods, including Principal Component Analysis (PCA) and autoencoder neural networks. Our findings demonstrate that the EnviroPiNet model achieves an R^2 value of 0.9236 on the testing dataset, significantly outperforming PCA and autoencoder methods. The Buckingham Pi variables also provide insights into the physical and chemical relationships governing biofilter behaviour, with implications for system design and optimization. This study highlights the potential of combining physical principles with AI approaches to model complex environmental systems characterized by sparse, high-dimensional datasets.
format Preprint
id arxiv_https___arxiv_org_abs_2504_18595
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle EnviroPiNet: A Physics-Guided AI Model for Predicting Biofilter Performance
Uzma
Cholet, Fabien
Quinn, Domenic
Smith, Cindy
You, Siming
Sloan, William
Machine Learning
Artificial Intelligence
Environmental biotechnologies, such as drinking water biofilters, rely on complex interactions between microbial communities and their surrounding physical-chemical environments. Predicting the performance of these systems is challenging due to high-dimensional, sparse datasets that lack diversity and fail to fully capture system behaviour. Accurate predictive models require innovative, science-guided approaches. In this study, we present the first application of Buckingham Pi theory to modelling biofilter performance. This dimensionality reduction technique identifies meaningful, dimensionless variables that enhance predictive accuracy and improve model interpretability. Using these variables, we developed the Environmental Buckingham Pi Neural Network (EnviroPiNet), a physics-guided model benchmarked against traditional data-driven methods, including Principal Component Analysis (PCA) and autoencoder neural networks. Our findings demonstrate that the EnviroPiNet model achieves an R^2 value of 0.9236 on the testing dataset, significantly outperforming PCA and autoencoder methods. The Buckingham Pi variables also provide insights into the physical and chemical relationships governing biofilter behaviour, with implications for system design and optimization. This study highlights the potential of combining physical principles with AI approaches to model complex environmental systems characterized by sparse, high-dimensional datasets.
title EnviroPiNet: A Physics-Guided AI Model for Predicting Biofilter Performance
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2504.18595