Abstract
Different types of mathematical models have been used to predict the dynamic behavior of the novel coronavirus (COVID-19). Many of them involve the formulation and solution of inverse problems. This kind of problem is generally carried out by considering the model, the vector of design variables, and system parameters as deterministic values. In this contribution, a methodology based on a double loop iteration process and devoted to evaluate the influence of uncertainties on inverse problem is evaluated. The inner optimization loop is used to find the solution associated with the highest probability value, and the outer loop is the regular optimization loop used to determine the vector of design variables. For this task, we use an inverse reliability approach and Differential Evolution algorithm. For illustration purposes, the proposed methodology is applied to estimate the parameters of SIRD (Susceptible-Infectious-Recovery-Dead) model associated with dynamic behavior of COVID-19 pandemic considering real data from China's epidemic and uncertainties in the basic reproduction number (R0). The obtained results demonstrate, as expected, that the increase of reliability implies the increase of the objective function value.
Highlights
Since November 2019, the world has observed the spread of a new disease, the COVID-19 (Coronavirus disease 2019)
We present the results for the inverse deterministic problem, considering a deterministic constraint regarding the value of R0, in order to illustrate the deterioration of the unconstrained solution with respect to the constrained problems
The inverse problems are solved by the Differential Evolution Algorithm (DE) algorithm, with the following parameters: NP = 25, CR = 0.8, F = 0.8, G = 500 and strategy rand/1 (see Eq (4.1))
Summary
Since November 2019, the world has observed the spread of a new disease, the COVID-19 (Coronavirus disease 2019). To evaluate the individual behavioral response, governmental actions, zoonotic transmission and emigration of a large proportion of the population in a short period of time and vaccine administration related with the COVID-19, various mathematical model-based predictions have been proposed and studied [10]. These models are obtained through the formulation and solution of an inverse problem and aim to describe a state of infection (susceptible and infected) and a process of infection (the transition between these states) by using compartmental relations. The population is divided into compartments by taking assumptions about the nature and time rate of transfer from one compartment to another [2, 20]
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