Abstract
Just in a week a rapidly spreading corona virus which was originated in Wuhan, city of China, infected more than 20,000 people and also killed at least 427 people in that week worldwide. Corona virus is transmissible and spreading from person to person, while the Chinese commanded authorities are scrambling to treat a flood of new patients in Chines successfully. The said Corona virus has been spread from an initial outbreak in Wuhan, city of China, and invade 25 other worldwide countries. In this article, we considered the mathematical model (Chen et al. Infect Dis Poverty, https://doi.org/10.1186/s40249-020-00640-3) in which Bats-Hosts-Reservoir-People and their transmission was taken, while we introduced the population of susceptible Bats and visitors to Wuhan city or any country in same mathematical model. Now we studying two types of populations first Bats-Hosts-Reservoir-People (Chen et al. Infect Dis Poverty, https://doi.org/10.1186/s40249-020-00640-3, also introducing susceptible Bats and second visitors to Wuhan city, china or any country in the same model. We used Caputo-Fabrizio derivative with provided result that the addition of susceptible Bats and visitors are not responsible in spread of infection. The numerical result also supported our model.
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1 Background
The people of the entire world seen a very new epidemic thread in end of 2019 and 2020. After the middle East Respiratory Syndrome(MERS), in middle east, a new virus Corona attacked the “Wuhan city, China”. The Corona virus was first emerged in late December and has killed more than 2500 people there, this means “Wuhan”, China alone accounted for nearly 80 percent of the country’s with total deaths occur 3299 or more. Before this, the World Health Organization (WHO) China Country Office informed in 31, December 2019 about pneumonia(unknown cause) detected in “Wuhan” city, Hubei China and WHO announced novel Corona virus (2019-nCoV). The International Committee of Taxonomy assigned it severe acute respiratory syndrome Corona virus-2(SARS-CoV-2) on 11 February, 2020 [12, 31, 34]. Similarly some of the best approaches was studied and presented in [4, 15, 18, 35]. All the country then infected, and an perception was drawn that visitors involve in this transmission of new virus mostly.
Scientists of all the world then felt an urgent mathematical model to estimate the transmission of this disease in China. Several researches focusing and developed mathematical models for MERS [21, 30, 32]. In these mathematical model the scientists trying the reproductive number which responsible for whole model [10, 23, 32]. The people are awarded from different methods, and control strategies to make possible precautions against Corona virus. Here the main aim is to estimate positivity, equilibrium, and Boundedness of these models [11, 13, 16, 27]. The recent and new ideas was also discussed in [1,2,3, 5, 14, 19, 25, 26]. While one of the best approach towards mathematical models is optimal control [17, 20, 22, 29]. Many different methods are adopted for optimal purpose. One best attempt was done in [31].
In our work we try to vanish and prove the wrong perception that susceptible Bats and visitors are the spreading agent of Corona virus in “wuhan” or any other country. Here we focus on the study done in [9] which was Bats-Hosts-Reservoir-People(BHRP) and its different transmission ways of Corona virus in any population. We just interesting in human-to-human transmission, so for that issue we introduced Bats population and visitors population who visit Wuhan China or any other country. We developed a mathematical model for the transmission of Corona virus Reservoir-People-Visitors(RPV) with introducing susceptible bats and estimate the value of \(R_0\). We apply Caputo-Fabrizio derivative approach towards this issue, and a numerical simulation in the last.
2 Data source
The named Corona virus which was COVID-19 which was SARS-CoV-2 in the first and the model was taken from the published literature [21]. The epidemic and its sharp curve was considered from 7 December, 2019 to 31 March, 2020 is collected for this study, while simulation step size is 1 week.
3 Simulation methods and statistical analysis
For simulation and curve fitting we have used Runge-Kutta-fourth-order method. The reproductive number for first model was considered 0.5 and also we considered \(R_0\) is equal to 1 for Bats and visitors model.
4 Mathematical model and transmission of Bats-Hosts-Reservoir-People(BHRP)
In 19 January, 2020 [8] published BHRP mathematical transmission model in bioRxiv, with the following certain assumptions:
Bats population: 1:) Divided into four section, susceptible, exposed, infected, and removed are \((S_B),(E_B),(I_B)\) and \((R_B)\) respectively. But in our model we considered susceptible Bats \((S_B)\) only, and ignored the remaining because of no concern in human population. While \(n_B\) and \(m_B\) are taken the birth and death rate. \( _B\) is the rate of infection from \(S_B\) when contact with \(I_B\).
Host Population: 2:) Population of host is also divided in four compartments: \((S_H), (E_H), (I_H)\) and \((R_H)\) denoted susceptible, exposed, infected, and removed hosts. Here we leave all the compartments of the Hosts population, due to no role in human population infection.
Reservoir Population: Here W denoted SARS-CoV-2 in reservoir (the seafood market). In our study the rate of asymptomatic infected people and symptomatic infected people export virus with \(\mu _p\) and \(\hat{\mu }_p\) respectively from markets or any other source.
People Population: This population is divided in to five classes, there five compartments are: \((S_p), (E_p), (I_p), (A_p)\) and \((R_p)\) denoted susceptible, exposed, symptomatic infected, asymptomatic infected, and removed peoples compartments. Here \(m_p\) represent death rate. \(\delta _p\) was defined for the proportion of asymptomatic infection, also the \(S_p\) infected from W and \(I_p\) with the transmission rate \(\beta _W\) and \(\beta _p\).
5 The new bats and visitors model
Here we drawn some more assumptions for our model:
Assumption 1
In our study we considered the Bats population only.
Assumption 2
We ignored the transmission of Bats-Host population due to unknown spreading source.
Assumption 3
Hosts population of Bats is totally ignored in this study because of its unknown relation and infection.
Assumption 4
We leave other related terms and contact in reservoir population in this article.
Assumption 5
We taken the class of susceptible Bats to check weather this class spread any infection in the concern model.
Assumption 6
In this study we introduced visitors population compartment separately.
During in any outbreak the death rate is normally high, therefore, the model BHRP converted into BRP and then in BRV(Bats-reservoir-visitors) model by the following,
In outbreak the visitors and hosts interaction was very slow in “Wuhan” or other country. Now introducing dynamic population of the visitors to any city or country is as in separate for estimation of infection,
6 Transmissibility of Corona Virus or SARS-CoV-2 based on the BRP And Bats-visitors model
In article, \(R_0\) is assessed for transmissibility of Corona virus(SARS-CoV-2). While the, \(R_0\) we defined as, the expected number of secondary infections with introducing any single infected individual to susceptible population [7, 29, 36]. The value of \(R_0\) having two faces that is, \(R_0 > 1\), or \(R_0 < 1\), showing different characteristics of the model in any outbreak to control or for no out control. In this study, \(R_0\) was deduced from the BRP model and Bats-visitors population by next generation matrix approach [12].
7 Some results
Here in this subsection of study, we given some basic definition of the fractional calculus, which we used later,
Definition A
Let \(H\varepsilon G^1(c,d)\) and d is greater then c, also \(\tau \varepsilon [0,1]\) then CFF derivative [6] is given as,
Here \(M(\tau )\), which implies normality with \(M(0)=M(1)=1\) [6]. But if H is not contain in \( G^1(c,d)\) then we get,
Definition B
When \(\upsilon =\frac{(1-\tau )}{\tau }\varepsilon [0,\infty )\) and \(\tau =\frac{1}{1+\upsilon }\varepsilon [0,1]\) we have the following result,
With
Applying \(\lim \upsilon \rightarrow 0\) we get,
This integral definition was provided by Losada and J. Nieto [24].
Definition C
Suppose that \(``0<\tau <1\)” then CFFD integral of given function h is as,
The above equation will also be written in the following as,
This gives us that \(M(\tau )=\frac{2}{(2-\tau )}\), with \(0<\tau <1\). From Eq. (3) a new form of the above \(``Caputo\) \(-\) \(Fabrizio\) fractinal derivative of order \(0<\tau <1\) which was further investigated by Losada and J. Nieto [24].
We use the above form in mathematical model of HBV and diabetes model [28, 33].
8 Formulation of Model BVP from BRPV
Now we are going to replace system (1) by the new CF fractional derivative, as,
Similarly we also replace Eq. (2) by CF fractional derivative by below,
9 Basic reproductive number
The calculate the basic reproductive number for system (1) is as,
10 Methodology for our model
For existence for the model we use Fixed point theory. Now Caputo-Fabrizio fractional derivative for system (1), is,
Similarly using Caputo-Fabrizio fractional derivative for Eq. (4), is in below,
Now we applying the idea which used in [24] on Eqs. (6), and (7), while we get Eqs. (8) and (9), from Eqs. (6), and (7),
Here we applying the new idea of Losada and J.Nieto [24] on the system given in above, and we get,
Now the simplified form of the Eqs. (10) and (11), after Eqs. (8) and (9), is below,
Theorem 10.1
The Kernals of \(\Phi _1,\Phi _2,\Phi _3,\Phi _4,\Phi _5, \Phi _6\) and \(\Phi _7\) fulfill the Lipschitz condition and contraction if the following inequality hold. \(0\le (m_B+\beta _m\psi )e+I_B<1\), where \(\psi =1\) and \(e=\frac{1}{2}\).
Proof
We prove the theorem for \(\Phi _1,\Phi _2,\Phi _3,\Phi _4,\Phi _5, \Phi _6\) and \(\Phi _7\) respectively. First suppose that S and \(S_1\) are two function for \(\Phi _1\), then,
For Eq. (12) we apply triangle in-equality, we get,
Here while we use \(\varphi = (m_B+\beta _m)\) with \(\psi =1\) and \(e=\frac{1}{2}\).
This implies the given function is a bounded function, so we have,
Hence, we see that the Lipschitz condition for Eq. (12) is satisfied, also \(0\le (m_B+\beta _m\psi )e+I_B<1\), where \(\psi =1\) and \(e=\frac{1}{2}\), which also emphasized that the said Eq. (12) is contraction. The Lipschitz condition for other equations by the similar way are given below,
Theorem 10.2
The Kernals of Eq. (10) \(\prod _1, \prod _2\) and \(\prod _3\) fulfill the Lipschitz condition and contraction if the following inequality hold. \(0\le (\sigma (t)+\alpha \psi )e+I<1\), where \(\psi =1\) and \(I=e=\frac{1}{2}\).
Proof
To prove the concern condition suppose that D and \(D_1\) are any two function then, from \(\prod _1\) we write as,
By triangle inequality Eq. (15) becomes,
Where \(\Omega =\sigma (t)+\alpha \), while again we see that \(\psi =1\) and \(I=e=\frac{1}{2}\) showing the same effect of disease spread rate through visitors to “Wahan” city or the people living there in “Wahan”.
Hence, Lipschitz condition for Eq. (16) is satisfied, and by similar way we find the remaining Eq. (10) are below, as,
Conclusion : 1 In this subsection we conclude that both the population showing the same effect on the new disease “Corona Virus” spread in China “Wahan” city. The Eqs. (13), (14), (16), and (17) providing the same values i.e, \(\psi =1\) and \(e=\frac{1}{2}\), indicated that if the visitors visit the particular city or no visitors there in the concern city the spreading ratio of the disease remain same from the fixed values taken both population. These fixed values of both the population \(\psi \) and e create a perception that visitors have not a key role in this epidemic disease which spread in particular region of the “Wahan” city.
Taking Eqs. (8) and (9) with kernal notation becomes,
Using technique in Eq. (19), we obtain Eqs. (17) and (18) as Eqs.(20) and (21),
Using recurrence formula for Eqs. (19) and (20) we get,
And we get also
With the initial conditions for Eqs. (21) and (22) are,
Now to calculate the successive terms, we use the following difference formula,
Now applying the recurrence formula for visitors population dynamic in Eq. (22) is given by,
Here we have the following Eq. (25) with \(i=1,2,3,4,5,6,7\) and Eq. (26) with \(j=1,2,3\) are given,
Here we use the same strategy and assume the following,
Now for above equation we using triangle inequality, we get,
But we have proved that the kernal satisfied the Lipschits criteria then the above becomes,
From simplifying form Eq. (27) implies,
By the same way we get the following result,
Similarly from Eq. (24) we have below result,
Now considered the theorem given below,
Theorem 10.3
The model defined in system (1) has exact coupled solution if the condition below hold that is we find that
Proof
We shown that all the Eqs. in (28) and (29) are bounded and the functions \(S_B, S_p, E_p, I_p, A_p,R_p, W\) fulfill the Lipschitz condition, so Eqs. (28) and (29) by recursive method its succeeding relation are given below,
which shows that the existence and as well as the continuity of the concern solutions is valid and proved. Furthermore, to ensure that the above function is a solution of Eq. (3), we proceed as follows:
Where the terms \(T_1(t), T_2(t), T_3(t), T_4(t),T_5(t),T_6(t)\) and \(T_7(t)\) are classified as below,
In recurrence manner we write as
Now using limit \(n\rightarrow \infty \) on Eq. (34)
The same procedure using for Eq. (32) we get,
To show system (3) having unique solution, we suppose that there exists another solution of system (3) are \(S_{1B}(t), S_{1p}(t), E_{1p}(t), I_{1p}(t), A_{1p}(t), R_{1P}(t)\) and \(W_{1}(t)\), such that,
Now for Eq(34) using \(\parallel .\parallel \), and applying Lipschitz condition of kernelwe,
Conclusion: 2 The model defined in system (4) by using the strategies of Eqs. (28) and (29), we see that the succeeding relation with continivity like in Eq. (32) the terms \(\hat{T}_1\), \(\hat{T}_2\), \(\hat{T}_3\), showing same behavior of Eq. (34) with assigning new supposition of solution \(\hat{S}_1\), \(\hat{S}_2\), \(\hat{S}_3\), provides us Eq. (36) of the form of Eq. (35) revealed that the spreading of Corona virus in “Wahan city” do not effected by visitors (Table 1).
Theorem 10.4
The model (3) solution will unique if
Proof
If condition defined in above theorem hold then Eq. (36) written as,
We easily get that,
Provided that the following solution of all concern,
Similarly apply the same theorem (above) and procedure we also find the visitors population as below, provided that the following solution of all concern,
11 Conclusion
considering the published data with calculating all parameters, we concluded that the models “BHRP”, and “RP” showed that the spread of Corona virus is very high then MERS in any population. But the addition of our model to published data model showed that the susceptible Bats and visitors to Wuhan or any country having same estimation as that population, more specially visitors of any country are not responsible in the spread of more infection in that area. In simulation from Fig. 1 show that the spread is randomly occurred in your model which shows that, in spread of Corona virus no external agent is involved (visitors). Fig 2 also indicate that the virus may be started from any point where there will be no visitors and susceptible Bats exist. From Fig. 3 we see that the spread of this virus is very fast and then it change in any region of the country. But here our objective of this mathematical model is to estimate the role of susceptible Bats and visitors in spread of “Corona \(virus''\) in any population. Finally we say that the spread of virus is free from any type of visitors and susceptible Bats.
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MT: The corresponding author of this research article, with area of specialization are Mathematical Biology, and fluid dynamics. He is an Lecturer in Northern university, Wattar, Nowshera, Pakistan.
GZ: currently working as a Vice Chancellor at University of Malakand, lower Dir, 18800, Chakdara, Pakistan. His Ph.D from, Pusan National University, South Korea in 2008.
SIAS: currently working a professor and dean in mathematics at Islamia College Peshawar, 25000. His Ph.D degree from Saga University Japan in 2002.
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Tahir, M., Zaman, G. & Shah, S.I.A. Using caputo-fabrizio derivative for the transmission of mathematical model epidemic Corona Virus. SeMA 78, 119–136 (2021). https://doi.org/10.1007/s40324-020-00230-1
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DOI: https://doi.org/10.1007/s40324-020-00230-1