Abstract
A novel phenomenological epidemic model is proposed to characterize the state of infectious diseases and predict their behaviors. This model is given by a new stochastic partial differential equation that is derived from foundations of statistical physics. The analytical solution of this equation describes the spatio-temporal evolution of a Gaussian probability density function. Our proposal can be applied to several epidemic variables such as infected, deaths, or admitted-to-the-Intensive Care Unit (ICU). To measure model performance, we quantify the error of the model fit to real time-series datasets and generate forecasts for all the phases of the COVID-19, Ebola, and Zika epidemics. All parameters and model uncertainties are numerically quantified. The new model is compared with other phenomenological models such as Logistic Grow, Original, and Generalized Richards Growth models. When the models are used to describe epidemic trajectories that register infected individuals, this comparison shows that the median RMSE error and standard deviation of the residuals of the new model fit to the data are lower than the best of these growing models by, on average, 19.6% and 35.7%, respectively. Using three forecasting experiments for the COVID-19 outbreak, the median RMSE error and standard deviation of residuals are improved by the performance of our model, on average by 31.0% and 27.9%, respectively, concerning the best performance of the growth models.
Highlights
During the period of an epidemic when the human-to-human transmission is established, and the number of reported cases and deaths are relevant or watched with alarm, nowcasting and forecasting are of crucial importance for public health planning [1,2]
One of the main features of this model is the introduction of a new stochastic partial differential equation that is derived from foundations of statistical physics
We have presented results of the Gaussian model fit to data that represent the following epidemic variables: infected, deaths, admitted-to-the-Intensive Care Unit (ICU), and hospital-discharge
Summary
During the period of an epidemic when the human-to-human transmission is established, and the number of reported cases and deaths are relevant or watched with alarm, nowcasting and forecasting are of crucial importance for public health planning [1,2] In this situation, mathematical epidemiological models play a key role in policy decisions about the prevention and control of infectious diseases. Our model is based on a partial differential equation (PDE) that is derived from assuming that the spread of infectious diseases is a stationary Markov random process in the statistical-physics sense. This new model is compared to three phenomenological models that are used in fitting real epidemic datasets. This paper includes an appendix that provides the derivation of the stochastic partial differential equation
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