A model learning framework for inferring the dynamics of transmission rate depending on exogenous variables for epidemic forecasts
In this work, we aim to formalize a novel scientific machine learning framework to reconstruct the hidden dynamics of the transmission rate, whose inaccurate extrapolation can significantly impair the quality of the epidemic forecasts, by incorporating the influence of exogenous variables (such as e...
Gespeichert in:
Hauptverfasser: | , , , , |
---|---|
Format: | Artikel |
Sprache: | eng |
Schlagworte: | |
Online-Zugang: | Volltext bestellen |
Tags: |
Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
|
Zusammenfassung: | In this work, we aim to formalize a novel scientific machine learning
framework to reconstruct the hidden dynamics of the transmission rate, whose
inaccurate extrapolation can significantly impair the quality of the epidemic
forecasts, by incorporating the influence of exogenous variables (such as
environmental conditions and strain-specific characteristics). We propose an
hybrid model that blends a data-driven layer with a physics-based one. The
data-driven layer is based on a neural ordinary differential equation that
learns the dynamics of the transmission rate, conditioned on the meteorological
data and wave-specific latent parameters. The physics-based layer, instead,
consists of a standard SEIR compartmental model, wherein the transmission rate
represents an input. The learning strategy follows an end-to-end approach: the
loss function quantifies the mismatch between the actual numbers of infections
and its numerical prediction obtained from the SEIR model incorporating as an
input the transmission rate predicted by the neural ordinary differential
equation. We validate this original approach using both a synthetic test case
and a realistic test case based on meteorological data (temperature and
humidity) and influenza data from Italy between 2010 and 2020. In both
scenarios, we achieve low generalization error on the test set and observe
strong alignment between the reconstructed model and established findings on
the influence of meteorological factors on epidemic spread. Finally, we
implement a data assimilation strategy to adapt the neural equation to the
specific characteristics of an epidemic wave under investigation, and we
conduct sensitivity tests on the network hyperparameters. |
---|---|
DOI: | 10.48550/arxiv.2410.11545 |