Fractional‐order backstepping strategy for fractional‐order model of COVID‐19 outbreak

Veisi, Amir; Delavari, Hadi

doi:10.1002/mma.7994

Cited by 9 publications

(2 citation statements)

References 40 publications

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“…The dynamics of this type of transmission are described using a fractional order derivative by [27][28][29][30][31][32][33], fractional-order backstepping strategy by Veisi and Delavari [34], generalized fractional-order by Xu et al [35], hybrid stochastic fractional order by Sweilam et al [36], El-Borai and El-Nadi [37], Caputo-Fabrizio (CF) and Atangana-Baleanu models non-singular fractional derivatives by Panwar et al [38], Mohammad and Trounev [39], Peter et al [40], Verma and Kumar [41], Sintunavarat and Turab [42], Kolebaje et al [43], optimized fractional order by Alshomrani et al [44], Caputo-Fabrizio derivative by Baleanu et al [45], fractional Chebyshev polynomials by Hadid et al [46], fractal-fractional order by Algehyne and Ibrahim [47], fractional order with fuzzy theory by Verma and Kumar [48], fractional order derivative with Krasnoselskiiʼs fixed point theorem by Verma et al [49], the multifractional characteristics with time-dependent memory indexes by Jahanshahi et al [50], fractional derivative with Riesz wavelets simulation by Mohammad et al [51]. Padmapriya and Kaliyappan [52], Dong et al [53] discussed the model of fuzzy fractional differential systems for the epidemic.…”

Section: Introductionmentioning

confidence: 99%

Stability analysis of fractional epidemic model for two infected classes incorporating hospitalization impact

Santra,

Mahapatra,

Basu

2024

Phys. Scr.

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This article presents an epidemic disease propagation mathematical model in fractional order. The epidemiological characteristics are presented based on the susceptible, exposed, unknown infected, known infected, hospitalized population and the population in the secure zone. Both the disease endemic equilibrium and the disease-free equilibrium's stability characteristics have been examined using the basic reproduction number. Variation of basic reproduction number based on the different sensitive parameters has been discussed. It has been disputed whether the fractional model provides a uniform, reliable solution. An analysis of the time history of unknown and known infected populations, hospitalized populations and recovered populations at different values of various sensitive parameters has been carried out. To support the key theoretical conclusions, some numerical simulations are completed using MATLAB. The impact of various populations on the propagation of the illness has also been investigated, as well as how specific state variables change over time for various fractional order values.

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Section: Introductionmentioning

confidence: 99%

Stability analysis of fractional epidemic model for two infected classes incorporating hospitalization impact

Santra,

Mahapatra,

Basu

2024

Phys. Scr.

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“…But this consideration may not be practical, as the individual behavior of the population cannot be directly controlled, but realistically its the responsibility of governments to design suitable policies in order the mitigate and control the pandemic. In other works on Lypanuov functions [40] , backstepping control [41] and sliding mode control [42] have considered strategies like pharmacological, isolation, and social distancing based strategies, but these works are largely limited to simulations. In this regard, we believe that the designing of optimal strategies for governmental intervention to be real-world data-driven.…”

Section: Introductionmentioning

confidence: 99%

Attention based parameter estimation and states forecasting of COVID-19 pandemic using modified SIQRD Model

Khan¹,

Ullah²,

Lee³

2022

Chaos, Solitons & Fractals

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Numerical solutions and simulations of the fractional COVID‐19 model via Pell–Lucas collocation algorithm

Yıldırım,

Yüzbaşı

2024

Math Methods in App Sciences

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The aim of this study is to present the evolution of COVID‐19 pandemic in Turkey. For this, the SIR (Susceptible, Infected, Removed) model with the fractional order derivative is employed. By applying the collocation method via the Pell–Lucas polynomials (PLPs) to this model, the approximate solutions of model with fractional order derivative are obtained. Hence, the comments are made about the susceptible population, the infected population, and the recovered population. For the method, firstly, PLPs are expressed in matrix form for a selected number of . With the help of this matrix relationship, the matrix forms of each term in the SIR model with the fractional order derivative are constituted. For implementation and visualization, we utilize MATLAB. Moreover, the outcomes for the Runge–Kutta method (RKM) are obtained using MATLAB, and these results are compared with the results obtained with the Pell–Lucas collocation method (PLCM). From all simulations, it is concluded that the presented method is effective and reliable.

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Fractional‐order backstepping strategy for fractional‐order model of COVID‐19 outbreak

Cited by 9 publications

References 40 publications

Stability analysis of fractional epidemic model for two infected classes incorporating hospitalization impact

Stability analysis of fractional epidemic model for two infected classes incorporating hospitalization impact

Attention based parameter estimation and states forecasting of COVID-19 pandemic using modified SIQRD Model

Numerical solutions and simulations of the fractional COVID‐19 model via Pell–Lucas collocation algorithm

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