A fractional-order model for the novel coronavirus (COVID-19) outbreak

被引:0
作者
Karthikeyan Rajagopal
Navid Hasanzadeh
Fatemeh Parastesh
Ibrahim Ismael Hamarash
Sajad Jafari
Iqtadar Hussain
机构
[1] Amirkabir University of Technology,Department of Biomedical Engineering
[2] Ton Duc Thang University,Nonlinear Systems and Applications, Faculty of Electrical and Electronics Engineering
[3] University of Tehran,School of Electrical and Computer Engineering, College of Engineering
[4] University of Kurdistan-Hewler,Department of Computer Science and Engineering
[5] Salahaddin University,Department of Electrical Engineering
[6] Amirkabir University of Technology,Health Technology Research Institute
[7] Qatar University,Department of Mathematics, Statistics and Physics
来源
Nonlinear Dynamics | 2020年 / 101卷
关键词
Fractional-order derivative; COVID-19; SEIRD model;
D O I
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中图分类号
学科分类号
摘要
The outbreak of the novel coronavirus (COVID-19), which was firstly reported in China, has affected many countries worldwide. To understand and predict the transmission dynamics of this disease, mathematical models can be very effective. It has been shown that the fractional order is related to the memory effects, which seems to be more effective for modeling the epidemic diseases. Motivated by this, in this paper, we propose fractional-order susceptible individuals, asymptomatic infected, symptomatic infected, recovered, and deceased (SEIRD) model for the spread of COVID-19. We consider both classical and fractional-order models and estimate the parameters by using the real data of Italy, reported by the World Health Organization. The results show that the fractional-order model has less root-mean-square error than the classical one. Finally, the prediction ability of both of the integer- and fractional-order models is evaluated by using a test data set. The results show that the fractional model provides a closer forecast to the real data.
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页码:711 / 718
页数:7
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