On the Implementation of the Artificial Neural Network Approach for Forecasting Different Healthcare Events

Overview

Journal Diagnostics (Basel)

Specialty Radiology

Date 2023 Apr 13

PMID 37046528

Authors

Huda M Alshanbari

Hasnain Iftikhar

Faridoon Khan

Moeeba Rind

Zubair Ahmad

Abd Al-Aziz Hosni El-Bagoury

Affiliations

Soon will be listed here.

Abstract

The rising number of confirmed cases and deaths in Pakistan caused by the coronavirus have caused problems in all areas of the country, not just healthcare. For accurate policy making, it is very important to have accurate and efficient predictions of confirmed cases and death counts. In this article, we use a coronavirus dataset that includes the number of deaths, confirmed cases, and recovered cases to test an artificial neural network model and compare it to different univariate time series models. In contrast to the artificial neural network model, we consider five univariate time series models to predict confirmed cases, deaths count, and recovered cases. The considered models are applied to Pakistan's daily records of confirmed cases, deaths, and recovered cases from 10 March 2020 to 3 July 2020. Two statistical measures are considered to assess the performances of the models. In addition, a statistical test, namely, the Diebold and Mariano test, is implemented to check the accuracy of the mean errors. The results (mean error and statistical test) show that the artificial neural network model is better suited to predict death and recovered coronavirus cases. In addition, the moving average model outperforms all other confirmed case models, while the autoregressive moving average is the second-best model.

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