- Published
- 06 June 2025
- Journal article
A data augmentation strategy for deep neural networks with application to epidemic modelling
- Authors
- Source
- Bollettino dell'Unione Matematica Italiana
Abstract
In this work, we integrate the predictive capabilities of compartmental disease dynamics models with machine learning’s ability to analyze complex, high-dimensional data and uncover patterns that conventional models may overlook. Specifically, we present a proof of concept demonstrating the application of data-driven methods and deep neural networks to a recently introduced Susceptible-Infected-Recovered type model with social features, including a saturated incidence rate, to improve epidemic prediction and forecasting. Our results show that a robust data augmentation strategy trough suitable data-driven models can improve the reliability of Feed-Forward Neural Networks and Nonlinear Autoregressive Networks, providing a complementary strategy to Physics-Informed Neural Networks, particularly in settings where data augmentation from mechanistic models can enhance learning. This approach enhances the ability to handle nonlinear dynamics and offers scalable, data-driven solutions for epidemic forecasting, prioritizing predictive accuracy over the constraints of physics-based models. Numerical simulations of the lockdown and post-lockdown phase of the COVID-19 epidemic in Italy and Spain validate our methodology.
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Cite as
Awais, M., Ali, A., Dimarco, G., Ferrarese, F. & Pareschi, L. 2025, 'A data augmentation strategy for deep neural networks with application to epidemic modelling', Bollettino dell'Unione Matematica Italiana. https://doi.org/10.1007/s40574-025-00486-3