Deep learning framework for epidemiological forecasting: A study on COVID-19 cases and deaths in the Amazon state of Pará, Brazil

Modeling time series has been a particularly challenging aspect due to the need for constant adjustments in a rapidly changing environment, data uncertainty, dependencies between variables, volatile fluctuations, and the need to identify ideal hyperparameters. The present study presents a Framework...

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Published in:PloS one Vol. 18; no. 11; p. e0291138
Main Authors: Souza, Gilberto Nerino de, Mendes, Alícia Graziella Balbino, Costa, Joaquim dos Santos, Oliveira, Mikeias dos Santos, Lima, Paulo Victor Cunha, de Moraes, Vitor Nunes, Silva, David Costa Correia, Rocha, Jonas Elias Castro da, Botelho, Marcel do Nascimento, Araujo, Fabricio Almeida, Fernandes, Rafael da Silva, Souza, Daniel Leal, Braga, Marcus de Barros
Format: Journal Article
Language:English
Published: San Francisco Public Library of Science 17-11-2023
Public Library of Science (PLoS)
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Summary:Modeling time series has been a particularly challenging aspect due to the need for constant adjustments in a rapidly changing environment, data uncertainty, dependencies between variables, volatile fluctuations, and the need to identify ideal hyperparameters. The present study presents a Framework capable of making projections from time series related to cases and deaths by COVID-19 in the Amazonian state of Pará, in Brazil. For the first time, deep learning models such as TCN, TRANSFORMER, TFT, N-BEATS, and N-HiTS were assessed for this purpose. The ARIMA statistical model was also used in post-processing for residual adjustment and short-term smoothing of the generated forecasts. The Framework generates probabilistic forecasts, with multivariate support, considering the following variables: daily cases per day of the first symptom, cases published daily, the occurrence of deaths, deaths published daily, and percentage of daily vaccination. The generated predictions are statistically evaluated by determining the best model for 7-day moving average projections using evaluating metrics such as MSE, RMSE, MAPE, sMAPE, r.sup.2, Coefficient of Variation, and residual analysis. As a result, the generated projections showed an average error of 5.4% for Cases Publication, 8.0% for Cases Symptoms, 11.12% for Deaths Publication, and 4.6% for Deaths Occurrence, with the N-HiTS and N-BEATS models obtaining better results. In general terms, the use of deep learning models to predict cases and deaths from COVID-19 has proven to be a valuable practice for analyzing the spread of the virus, which allows health managers to better understand and respond to this kind of pandemic outbreak.
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ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0291138