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1. Introduction

The fight against cholera is far from over; it, therefore, becomes very reasonable to try and tackle the cholera infection also from theoretical and numerical points of view. It must be emphasized that looking at the high death rates of cholera, any research that aims at improving the success rates becomes crucial.

Cholera is an acute intestinal infection caused by the Vibrio cholerae bacterium being ingested in contaminated water or food which is characterized by extreme diarrhea and vomiting. Cholera has a brief incubation period, ranging from one to five days. The bacteria Vibrio cholerae produces a toxin known as enterotoxin that dehydrates and prevents the human body from absorbing liquids which can lead to death if treatment is delayed within two to three hours of infection [1]. According to Crooks and Atesmachew [2], getting portable drinking water and basic environmental hygiene is a major problem in Africa and Asia where cholera cases are on a continuous rise.

Cholera is one of the oldest diseases that continue to harm people of all ages, generating epidemics and pandemic outbreaks notwithstanding continued efforts to control its transmission. There exist a number of environmental factors that contribute to the spread of cholera infections. Because Vibrio cholerae can travel around in the water, any change in the hydrological cycle has the potential to modify the concentration of the pathogens in the water. Droughts and floods can boost or decrease the transmission process depending on the amount of rain and its seasonal nature [3].

The symptoms of cholera include painless watery stools, extreme vomiting, irregular heartbeat, and low blood pressure [4]. Most people do not fall sick with infection of cholera when exposed to Vibrio cholerae, but they can still infect other susceptible individuals through polluted water, as they shed the pathogen in their stool for 7 to 14 days. According to Akor [5], most people who are sometimes exposed have mild or asymptomatic symptoms, and at other times, symptoms are very severe. About one in every 20 infected individuals develops severe diarrhea with vomiting which could lead to dehydration.

The transmission of cholera can be direct or indirect [6]. The direct (human-to-human) transmission of cholera occurs when the infected person contact, engages in sexual activity with, or bites other infected individuals, whereas indirect (environment-to-human) transmission of cholera occurs when infected individuals consume Vibrio cholerae bacteria through contaminated waters and food [7].

As cholera epidemics become a global health burden in recent decades, researchers have paid more attention to cholera epidemiology. The interactions of Vibrio cholerae bacteria with its host and other pathogens in the environment have revealed that the dynamics of cholera are far more complicated than imagined previously [3]. Several mathematical models have been presented in the past by different authors to study the complicated epidemic and endemic nature of cholera. The study done by Capasso and Paveri-Fontana [8] in the Mediterranean formulated a deterministic mathematical model to investigate the outbreak of cholera that occurred in $1973$. Codeco extended and explicitly included the role of the aquatic environment in the dynamics of cholera in 2001, based on the work of Capasso and Paveri-Fontana [8]. The study done by Hntsa and Kahsay [9] focused on a mathematical model of the dynamical behavior of a fractional order model of cholera. Opoku and Afriyie [10] proposed and developed a dynamic mathematical model to analyze the role of the environment and control measures on cholera transmission dynamics involving the human population and the population of bacteria. Wang and Modnak [7] developed and analyzed an epidemiological model of cholera incorporating control measures, which is an extension of the formulated model by Mukandavire et al. [11] to better gain an understanding of the complex dynamics of cholera which included medicinal treatment, vaccination, and water sanitation effects. Hntsa and Kahsay [9] formulated a deterministic mathematical epidemic model to examine the influence of adequate cholera prevention strategies on the disease’s dynamics. According to Mark et al. [12], lytic bacteriophage specific for Vibrio cholerae may decrease the severity of epidemics of cholera by killing bacteria both in the infected persons and in the reservoir, based on environmental and epidemiological studies of cholera epidemics in Dhaka. Ochoche [13] proposed and formulated a mathematical model for transmission dynamics of cholera control with a water treatment control strategy. Fatima et al. [4] formulated and analyzed a mathematical epidemic model for cholera control in Nigeria that differed from earlier cholera models. In order to control cholera epidemics, this research model integrates treatment, water hygiene, and environmental cleanliness. Togbenon and Moyo [14] proposed and analyzed a mathematical model for cholera transfer as a control strategy with a quarantine class and vaccination parameter. Posny and Wang [15] proposed in a periodic environment, a deterministic compartmental model for the dynamics of cholera. Seasonal variation is incorporated into a broad formulation for the pathogen concentration and the incidence in their model. According to Fakai et al. [6], epidemics of cholera have been on the rise and more than 250,000 cholera cases are recorded worldwide annually. Flood, drought, and river height are all factors that influence the outbreak of cholera. Draught and flood, according to Codeco [3], are likely to have a complex impact on the dynamics of cholera. Flooding can wash infected feces and sewage into rivers, disrupting water delivery and worsening hygiene conditions. Nyabadza et al. [16] developed a deterministic mathematical model to investigate the mechanisms of cholera transmission in the face of scarce resources which includes nonlinear recovery rates. Lemos-paião et al. [17] researched an epidemic cholera model optimum treatment with control in Portugal. They proposed in the study a quarantine-treated cholera mathematics model which employs an ideal control problem and controls a fraction of infected individuals who will be treated in quarantine until their recovery will be completed, with a reduced number of infected persons. Peter et al. [18] developed a deterministic mathematical model to examine the degree of sensitivity of certain factors that aid in cholera transmission and management. Nyaberi and Malonza [19] researched the trends of transmission dynamics of cholera through health education and quarantine treatment as an epidemic control measure, modeling disease transmission using ordinary differential equations with an appropriate simple reproductive number, $R_0$, measured with the use of next-generation matrices. Abdulai [20] conducted research on the dynamics of the fractional order cholera transmission behavior model in Ghana with the Atanackovic and Stankovic numerical methods. Mwasa and Tchuenche [21] worked on a SIR model combining programs for public health awareness, vaccination, quarantine, and treatment as preventive measures to curb the illness.

Other researchers on cholera transmission dynamics include Crooks and Atesmachew and Lemaitre et al. [2, 22], to mention but a few.

According to Liang et al. [23], mathematical models as a tool in analyzing and predicting dynamical behavior in biological systems have been successfully used in the past decay. Therefore, in this study, a stochastic differential equation model would be used which provides an effective and efficient tool to unravel the role of the aquatic environment in the transmission dynamics and a better understanding of the spread of cholera infection even under uncertainties. In this study, we extend the deterministic model developed in [3] by converting it to a stochastic model. To understand the flow and prevent cholera infection in a better way, we first study the deterministic model by deriving the $R_0$, qualitative features such as positivity and invariant region of the solution, and stabilities of both the disease-free and endemic equilibriums to ensure the biological meaningfulness of the model. Next, we pass to the stochastic differential equation model and show the existence and uniqueness of the model. Finally, numerical simulations are carried out using the Euler-Maruyama scheme and analyzed with the aid of MATLAB, and the findings showed that the sample path of the stochastic differential equation for the number of infectious individuals is continuous but not differentiable.

The rest of the study is organized as follows: in Section 2, the Codeco [3] cholera model is described and reformulated. A qualitative analysis of the model is also discussed. In Section 3, a stochastic differential equation (SDEs) is formulated from transition probabilities. The existence and uniqueness of the stochastic differential equation model are also discussed. In Section 4, we use MATLAB software to investigate the numerical simulation results. Finally, in Section 5, we present our discussions and conclusions.

2. Model Formulation

The cholera model formulated by [3] is a system that includes both the environment and human population, with the environment-to-human transmission route represented by a logistic function. This model incorporated explicitly the environmental component, namely, the concentration of Vibrio cholerae bacteria in water $B$, into a regular SIR system to create an epidemiological model of a combined human-to-environment SI-B. In this study, we extend this model to a stochastic model by adding a “noise” to the deterministic model developed by [3]. Thus, we add a Brownian motion (Wiener’s process) and the intensity or impact of the stochastic environmental factors on the deterministic model.

2.1. The Deterministic Model Equations

In this model, we consider a deterministic compartmental human population and a Vibrio cholera bacteria population. The total human population is divided into three subclasses which are the susceptible population $S$, the cholera infectious population $I$, and a Vibrio cholerae bacteria population $B$. Susceptibles are recruited with the rate of $n$ through birth, susceptible can get cholera with the rate of $aB/K+B$, where $a$ is the contact rate with untreated water and $B/K+B$ is the probability of an individual to catch cholera. Infected individuals also contribute to the enhancement of the Vibrio cholera bacteria population through excretion at the rate of $e$. The infected individual may recover at the rate of $r$. In the aquatic environment, the bacteria population also grows at a rate determined by environmental factors, and b is the size of bacteria in the aquatic reservoir. A susceptible individual dies naturally at a rate of $\mu$. The above description of the model is plotted in Figure 1, while the variables and parameters are defined in Tables 1 and 2, respectively.

[figure(s) omitted; refer to PDF]

Table 1

Definition of variables in Codeco’s model.

Table 2

Description of parameters in Codeco’s model.

To extend the deterministic model in [3] to a stochastic one, we reformulate the basic model as follows.

The above assumptions of the model lead to the system of ordinary differential equations shown below as in [3]. $$\begin{array}{}\text{(1)}& \begin{array}{c}\frac{dS}{\text{dt}}=nH-S-\frac{a\text{BS}}{K+B}\hfill \\ \frac{dI}{\text{dt}}=\frac{a\text{BS}}{K+B}-rI\hfill \\ \frac{dB}{\text{dt}}=B\text{nb}-\text{mb}+eI\hfill \end{array},\end{array}$$with initial conditions $S0=S_0,I0=I_0,B0=B_0$.

2.2. Basic Properties of the Deterministic Model

For our model to make sense, it is necessary to show at least that this $\text{SI}-B$ model has a solution, and also the solution will remain within $0,H$ whenever it starts from there.

2.2.1. Positivity of the Solutions

In order for our model to be realistic, solutions will have to be nonnegative at all times for all $t\ge 0.$ We show that every state variable in the system equations will remain nonnegative.

So, by integrating Equation (3), we have $$\begin{array}{}\text{(4)}& \frac{d}{\text{dt}}St{e}^{\text{nt}+\int \lambda \tau d\tau }=nH{e}^{\text{nt}+\int \lambda \tau d\tau }.\end{array}$$

Thus, $$\begin{array}{}\text{(5)}& S{t}_{\ast }{e}^{\text{n}{\text{t}}_{\ast }+{\int }_0^{t_{\ast }}\lambda \tau d\tau }-S0={\int }_0^{t_{\ast }}{e}^{\int n+\lambda t\text{dt}}.nH\text{dt}.\end{array}$$

This implies $$\begin{array}{c}\text{(6)}& S{t}_{\ast }=S0e^{-\text{n}{\text{t}}_{\ast }+{\int }_0^{t_{\ast }}\lambda \tau d\tau }+e^{-\text{n}{\text{t}}_{\ast }+{\int }_0^{t_{\ast }}\lambda \tau d\tau }\times {\int }_0^{t_{\ast }}{e}^{\int n+\lambda t\text{dt}}.nH\text{dt},S{t}_{\ast }=T_1\text{S}0+T_1{\int }_0^{t_{\ast }}{e}^{\int n+\lambda t\text{dt}}.nH\text{dt}>0,\end{array}$$where $T_1=e^{-\text{n}{\text{t}}_{\ast }+{\int }_0^{t_{\ast }}\lambda \tau d\tau }>0,$$S0>0,$ and from the definition of $t_{\ast }$ above, we have $Bt>0$. Therefore, the solution $S{t}_{\ast }>0$ and, hence, $S{t}_{\ast }\ne 0.$

Consider the second equation of model (1), $$\begin{array}{}\text{(7)}& \frac{dIt}{\text{dt}}=\frac{aBtSt}{K+Bt}-rIt,\end{array}$$which can be written as $$\begin{array}{}\text{(8)}& \frac{dIt}{\text{dt}}+rIt=\lambda tSt,\end{array}$$where $\lambda t=\alpha Bt/K+Bt$.

Also, by integrating Equation (8), we have $$\begin{array}{}\text{(9)}& \frac{d}{\text{dt}}It{e}^{\int \text{rdt}}=\lambda tSt{e}^{\int \text{rdt}}.\end{array}$$

Thus, $$\begin{array}{}\text{(10)}& I{t}_{\ast }{e}^{{\text{rt}}_{\ast }}-I0={\int }_0^{t_{\ast }}{e}^{\int \text{rdt}}.\lambda tSt\text{dt}.\end{array}$$

This implies, $$\begin{array}{c}\text{(11)}& I{t}_{\ast }=I0e^{-\text{r}{\text{t}}_{\ast }}+e^{-\text{r}{\text{t}}_{\ast }}{\int }_0^{t_{\ast }}{e}^{\int \text{rdt}}.\lambda tSt\text{dt},I{t}_{\ast }=T_{1}I0+T_1{\int }_0^{t_{\ast }}{e}^{\int \text{rdt}}.\lambda tSt\text{dt}>0,\end{array}$$where $T_1=e^{-\text{r}{\text{t}}_{\ast }}>0,I0>0,$ and from the above, $St>0:$ then, the solution $I{t}_{\ast }>0$ and, hence, $I{t}_{\ast }\ne 0.$

Consider the third equation of model (1), $$\begin{array}{c}\text{(12)}& \frac{dBt}{\text{dt}}=eIt-\text{mb}-\text{nb}Bt,\frac{dBt}{\text{dt}}+\text{mb}-\text{nb}Bt=eIt,\\ \frac{d}{\text{dt}}Bt{e}^{\int \text{mb}-\text{nb}dt}=e^{\int \text{mb}-\text{nb}dt}.eIt.\end{array}$$

Thus, $$\begin{array}{}\text{(13)}& B{t}_{\ast }{e}^{\text{mb}-\text{nb}{t}_{\ast }}-B0={\int }_0^{t_{\ast }}{e}^{\int \text{mb}-\text{nb}dt}.eIt\text{dt}.\end{array}$$

This implies, $$\begin{array}{c}\text{(14)}& B{t}_{\ast }=B0e^{-\text{mb}-\text{nb}{t}_{\ast }}+e^{-\text{mb}-\text{nb}{t}_{\ast }}{\int }_0^{t_{\ast }}{e}^{\int \text{mb}-\text{nb}\text{dt}}.eIt\text{dt},B{t}_{\ast }=k_{1}B0+k_1{\int }_0^{t_{\ast }}{e}^{\int \text{mb}-\text{nb}\text{dt}}.eIt\text{dt}>0,\end{array}$$where $k_1=e^{-\text{mb}-\text{nb}{t}_{\ast }}>0$ for $\text{mb}-\text{nb}>0$, $B0>0$ and from the above, $It>0;$ then the solution $B{t}_{\ast }>0,$ and, hence, $B{t}_{\ast }\ne 0.$

Based on the definition, $t_{\ast }$ is not finite which means $t_{\ast }=+\infty$; therefore, the solutions of the Codeco model system (1) are always positive.

2.2.2. Invariant Region for the Deterministic Model

In this subsection, we obtain the invariant region of the model Equation (1).

2.3. Existence and Stability of the Disease-Free Equilibrium

Here, the existence of the equilibrium state of the model is discussed.

We set $dS/\text{dt}=dI/\text{dt}=dB/\text{dt}=0$ at the equilibrium state.

Therefore, by setting the model equations of the system (1) to zero, we have $$\begin{array}{}\text{(23)}& nH-S-\frac{a\text{BS}}{K+B}=0,\text{(24)}& \frac{a\text{BS}}{K+B}-rI=0,\text{(25)}& \text{nb}-\text{mb}B+eI=0.\end{array}$$

There are no infections at the disease-free state; thus, $I=0$. Substituting this into Equation (25), we have $\text{nb}-\text{mb}B=0⟹B=0$ provided $\text{nb}-\text{mb}\ne 0.$ Therefore, putting $B=0$ into Equation (23), we have $nH-S=0⟹n=0$ and $S=H.$

Therefore, a disease-free equilibrium state exists and is given by $E_{0}H,0,0.$

Now, we analyze the disease-free equilibrium’s stability. Let us consider taking the Jacobian of the model Equations (23)–(25) to prove that they are locally asymptotically stable around the equilibrium point as in [19].

When it comes to disease spread, local asymptotic stability means that if there is a small change or perturbation on the system, the system will still return to the disease-free equilibrium.

2.4. Basic Reproductive Number for the Deterministic Model

The basic reproductive number $R_0$ is calculated from the disease compartments as follows:

$\mathcal{F}:$ rate of appearance of new infection$=aBS/K+B/0$

$V_i^{-}:$ transfer rate of disease out of the disease compartment $=\begin{array}{c}rI\\ 0\end{array}$

$V_i^{+}:$ transfer rate of infection into the disease compartment by other means $$\begin{array}{c}\text{(26)}& =\begin{array}{c}0\\ \text{nb}-\text{mb}B+eI\end{array},V_i=V_i^{-}-V_i^{+}=\begin{array}{c}rI\\ \text{mb}-\text{nb}B-eI\end{array}.\end{array}$$

$F=\partial F{E}_0/\partial x_j:$ the Jacobian of $\mathcal{F}$ with respect to disease compartments $x_j$ evaluated at disease-free equilibrium. The model’s disease-free equilibrium point is obtained by setting $$\begin{array}{c}\text{(27)}& \frac{dSt}{\text{dt}}=\frac{dIt}{\text{dt}}=\frac{dBt}{\text{dt}}=0,nHt-\frac{aBtSt}{K+Bt}-nSt=0,\\ \text{(28)}& \frac{aBtSt}{K+Bt}-rIt=0,\text{nb}-\text{mb}Bt+eIt=0.\end{array}$$

Now, from system above, we have, $$\begin{array}{c}\text{(29)}& S^{\ast }=\frac{nH}{a{B}^{\ast }/K+B^{\ast }+n},I^{\ast }=\frac{a{B}^{\ast }{S}^{\ast }}{rK+B^{\ast }},\\ B^{\ast }=\frac{e{I}^{\ast }}{\text{nb}-\text{mb}}.\end{array}$$

From the equations above,

$I^{\ast }=0$ and $\text{nb}-\text{mb}{B}^{\ast }=0⟹B^{\ast }=0$ provided $\text{nb}-\text{mb}\ne 0.$ Therefore, putting $B^{\ast }=0$ into $S^{\ast }=nH/a{B}^{\ast }/K+B^{\ast }+n$, we have $S^{\ast }=H$.

Therefore, $E_0=St,It,Bt=H,0,0$. $$\begin{array}{}\text{(30)}& F=\begin{array}{cc}\frac{\partial m_1}{\partial I}& \frac{\partial m_1}{\partial B}\\ \frac{\partial m_2}{\partial I}& \frac{\partial m_2}{\partial B}\end{array},\end{array}$$where $$\begin{array}{c}\text{(31)}& m_1=\frac{aBtSt}{K+Bt}-rIt.m_2=nb-mbBt+eIt\end{array}$$

Then, the Jacobian matrix is given by the following equation: $$\begin{array}{}\text{(32)}& F=\begin{array}{cc}0& \frac{aSK}{{K+B}^2}\\ 0& 0\end{array}.\end{array}$$

At disease-free equilibrium, $$\begin{array}{c}\text{(33)}& S=H,B=0,\\ F=\begin{array}{cc}0& \frac{aH}{K}\\ 0& 0\end{array}.\end{array}$$

$V=\partial V_i{E}_0/\partial x_j:$ the Jacobian of $V_i$ with respect to disease compartments $x_j$ evaluated at DFE, $$\begin{array}{c}\text{(34)}& V=\begin{array}{cc}r& 0\\ -e& \text{mb}-\text{nb}\end{array},V^{-1}=\frac{1}{r\text{mb}-\text{nb}}\begin{array}{cc}\text{mb}-\text{nb}& 0\\ e& r\end{array},\\ V^{-1}=\begin{array}{cc}\frac{1}{r}& 0\\ \frac{e}{r\text{mb}-\text{nb}}& \frac{1}{\text{mb}-\text{nb}}\end{array}.\end{array}$$

Therefore, $$\begin{array}{c}\text{(35)}& \text{F}{\text{V}}^{-1}=\begin{array}{cc}0& \frac{aH}{K}\\ 0& 0\end{array}\begin{array}{cc}\frac{1}{r}& 0\\ \frac{e}{r\text{mb}-\text{nb}}& \frac{1}{\text{mb}-\text{nb}}\end{array},\text{F}{\text{V}}^{-1}=\begin{array}{cc}\frac{eaH}{Kr\text{mb}-\text{nb}}& \frac{aH}{K\text{mb}-\text{nb}}\\ 0& 0\end{array}.\end{array}$$

Now, we calculate the eigenvalues of the matrix $\begin{array}{cc}eaH/Kr\text{mb}-\text{nb}& aH/K\text{mb}-\text{nb}\\ 0& 0\end{array}$ to determine the basic reproduction number, $R_0$ which is defined as the spectral radius or the dominant eigenvalue of the matrix as in [7]. We compute this by $\begin{array}{cc}eaH/Kr\text{mb}-\text{nb}& aH/K\text{mb}-\text{nb}\\ 0& 0\end{array}-\text{I}\lambda =0$, where $I$ is a $2\times 2$ identity matrix. Hence, $$\begin{array}{c}\text{(36)}& \begin{array}{cc}\frac{eaH}{Kr\text{mb}-\text{nb}}& \frac{aH}{K\text{mb}-\text{nb}}\\ 0& 0\end{array}-\begin{array}{cc}\lambda & 0\\ 0& \lambda \end{array}=0,\begin{array}{cc}\frac{eaH}{Kr\text{mb}-\text{nb}}-\lambda & \frac{aH}{K\text{mb}-\text{nb}}\\ 0& -\lambda \end{array}=0,\\ \frac{eaH}{Kr\text{mb}-\text{nb}}-\lambda \lambda =0.\end{array}$$

Either $eaH/Kr\text{mb}-\text{nb}-\lambda =0$ or $\lambda =0\Rightarrow {\lambda }_1=eaH/Kr\text{mb}-\text{nb}$ and ${\lambda }_2=0$

The eigenvalues of ${\text{FV}}^{-1}$ are $eaH/Kr\text{mb}-\text{nb},0.$ Clearly, ${\lambda }_1$ is the dominant eigenvalue and becomes the basic reproduction number $R_0$ of the model as in [7]. $$\begin{array}{}\text{(37)}& R_0=\frac{eaH}{Kr\text{mb}-\text{nb}}.\end{array}$$

With respect to the cholera disease, the basic reproduction number ($R_0$) describes the expected number of cholera infections generated by one cholera case in a susceptible population [7].

We can rewrite the characteristic Equation (40) as $P\lambda ={\lambda }^3+A{\lambda }^2+B\lambda +C=0$, where $$\begin{array}{c}\text{(42)}& A=r+n+\text{mb}-\text{nb},B=\text{nr}+r+n\text{mb}-\text{nb}-\frac{\text{ae}H}{K}=n\text{mb}-\text{nb}+r+r\text{mb}-\text{nb}1-R_0,\\ C=\text{nr}\text{mb}-\text{nb}-\frac{\text{nae}H}{K}=\text{nr}\text{mb}-\text{nb}1-R_0,\\ \text{AB}-C=\text{mb}-\text{nb}+n+rn\text{mb}-\text{nb}+r+r\text{mb}-\text{nb}1-R_0.\end{array}$$

Therefore, the eigenvalues that correspond to the equilibrium $E_0$ are $$\begin{array}{c}\text{(43)}& {\lambda }_1=-n,{\lambda }_{2,3}=\frac{-\text{mb}-\text{nb}+r\pm \sqrt{{\text{mb}-\text{nb}+r}^2-4r\text{mb}-\text{nb}1-R_0}}{2}.\end{array}$$

We have $A>0$, $B>0$, $C>0$ and $AB-C>0$ and according to the Routh-Hurwitz criterion, all the characteristic equation’s roots have negative real part when $R_0<1$ and $\text{mb}-\text{nb}>0$. Hence, the disease-free equilibrium (DFE) point is stable given that $R_0<1$ [19].

2.5. Existence and Stability of the Endemic Equilibrium

$I\ne 0$ will be used to find the endemic state of the system of Equation (1). We now investigate if the endemic equilibrium condition of the system is stable. $$\begin{array}{}\text{(44)}& nH-S-\frac{a\text{BS}}{K+B}=0,\text{(45)}& \frac{a\text{BS}}{K+B}-rI=0,\text{(46)}& \text{nb}-\text{mb}B+eI=0,\end{array}$$

From Equation (46), $$\begin{array}{}\text{(47)}& B=\frac{eI}{\text{mb}-\text{nb}}.\end{array}$$

From Equation (45), $$\begin{array}{}\text{(48)}& S=\frac{K+BrI}{aB}.\end{array}$$

From Equation (44), $$\begin{array}{}\text{(49)}& nH-Sn+\frac{aB}{K+B}=0.\end{array}$$

Substitute Equation (48) into Equation (49). $$\begin{array}{c}\text{(50)}& nH-\frac{B+KrI}{aB}n+\frac{aB}{B+K}=0,nH-rI\frac{nB+K}{aB}+1=0.\end{array}$$

Substitute Equation (47) into Equation (50). $$\begin{array}{c}\text{(51)}& nH-rI\frac{K+eI/\text{mb}-\text{nb}}{aeI/\text{mb}-\text{nb}}n+1=0,\text{nae}H-\text{nr}K\text{mb}-\text{nb}-\text{er}In+a=0,\\ I=\frac{\text{nae}H-\text{nr}Kmb-nb}{\text{er}n+a}.\end{array}$$

Supposedly, for $I>0,$$$\begin{array}{c}\text{(52)}& \frac{\text{nae}H-\text{nr}K\text{mb}-\text{nb}}{\text{er}n+a}>0,\frac{\text{ae}H}{rK\text{mb}-\text{nb}}>1.\end{array}$$

Therefore, $R_0>1$, where $R_0$ is the reproduction number and is written as $R_0=\text{ae}H/rK\text{mb}-\text{nb}.$

We observed from the analysis that if $R_0>1$ and $\text{mb}-\text{nb}>0$, there exists a positive endemic equilibrium.

Now, it remains to show that $a_1{a}_2-a_0{a}_3>0.$ Thus, $$\begin{array}{}\text{(57)}& n+r+W+V\text{nr}+nV+rW+\text{WV}-eU-\text{nr}V+r\text{WV}-\text{ne}U=n^{2}r+n^{2}V+nrW+n\text{WV}+\text{n}{\text{r}}^2+r^{2}W+nrW+n\text{WV}+r{W}^2+W^{2}V+\text{nr}V+n{V}^2+r\text{WV}+\text{W}{\text{V}}^2-\text{re}U-eWU-eVU>0.\end{array}$$

Therefore, when $R_0>1$, the model system (1) has a unique endemic equilibrium $E^{\ast }$, and it is stable if $n^{2}r+n^{2}V+nrW+n\text{WV}+n{r}^2+r^{2}W+\text{nr}W+n\text{WV}+r{W}^2+W^{2}V+\text{nr}V+n{V}^2+r\text{WV}+\text{W}{\text{V}}^2>reU+e\text{WU}+e\text{VU}$, and $\text{mb}-\text{nb}>0$.

3. Transition Probabilities

Allen [24] developed the Ito stochastic differential equations from transition probabilities approach, which is based on the diffusion process. The stochastic differential equation to be formed is in the form, $$\begin{array}{}\text{(58)}& dXt=fXt,tdt+gXt,tdWt,\end{array}$$where $fXt,t$ is the drift (deterministic part of the model), $gXt,t$ is the diffusion part given as $gXt,t=V^{1/2}$, $V$ is the covariance to order $\Delta t$, $V\Delta t$ is the approximate covariance matrix, and $Wt$ is the vector of independent Wiener’s process.

From the deterministic equations above, we formulate the stochastic differential equation as $$\begin{array}{}\text{(59)}& dXt=fXt,tdt+gXt,tdWt,\end{array}$$where $fXt,t={\rm E}\Delta X/\Delta t$, and $gXt,t=\sqrt{V}=\sqrt{{\rm E}\Delta X{\Delta X}^T/\Delta t}$ [24].

Throughout this study, we assume that time is a continuous variable and the state variables $St$ and $It$ are continuous random variables. Now, let $\Delta S=St+\Delta t-St$ and $\Delta I=It+\Delta t-It.$ In addition, we also assume that the change (transition) of random variables $St$ and $It$ is approximately normally distributed, $\Delta St~N\mu s\Delta t,{\sigma }^{2}s\Delta t$ and $\Delta It~N\mu I\Delta t,{\sigma }^{2}I\Delta t$ for small time intervals $\Delta t$.

Let $Xt={X_1,X_2}^T$, where $X_1$ and $X_2$ correspond to the number of individuals $St,It\in 0,H$, respectively, and $Bt$ is the concentration of Vibrio cholerae bacteria in the aquatic environment. But $Bt$ was not considered as it is not compartment occupancy as the susceptible and the infected; as a result, its transition is not taken into consideration in formulating the transitions.

The following are needed in forming a stochastic differential equation model: the expectation ${\rm E}\Delta X$ and the covariance ${\rm E}\Delta X{\Delta X}^T$ which is a matrix. To compute the expectation and the covariance matrix, the possible changes or the transitions along with their associated probabilities are first computed as shown in Table 3 below. The transition probabilities are formulated from the deterministic model.

Table 3

Transition probabilities.

In Table 3, the expectation is computed as follows: $$\begin{array}{}\text{(60)}& {\rm E}\Delta X=\sum _{i=1}^4{P}_i\Delta X_i=P_1\Delta X_1+P_2\Delta X_2+P_3\Delta X_3+P_4\Delta X_4,\end{array}$$substituting the values of $P_i,\Delta X_i$ and ${X_1,X_2}^T={St,It}^T$ into Equation (60), $$\begin{array}{}\text{(61)}& {\rm E}\Delta X=P_1\begin{array}{c}1\\ 0\end{array}+P_2\begin{array}{c}-1\\ 1\end{array}+P_3\begin{array}{c}-1\\ 0\end{array}+P_4\begin{array}{c}0\\ -1\end{array}=\begin{array}{c}{P}_1\\ 0\end{array}+\begin{array}{c}-P_2\\ P_2\end{array}+\begin{array}{c}-P_3\\ 0\end{array}+\begin{array}{c}0\\ -P_4\end{array}=\begin{array}{c}{P}_1-P_2-P_3\\ P_2-P_4\end{array}=\begin{array}{c}nH\Delta t-\frac{aBS}{K+B}\Delta t-nS\Delta t\\ \frac{aBS}{K+B}\Delta t-rI\Delta t\end{array}\therefore {\rm E}\Delta X=\begin{array}{c}nH-S-\frac{aBS}{K+B}\\ \frac{aBS}{K+B}-rI\end{array}\Delta t.\end{array}$$

And the covariance matrix is also computed as follows: $$\begin{array}{}\text{(62)}& {\rm E}\Delta X{\Delta X}^T=\sum _{i=1}^4{P}_i\Delta X_i{{\Delta X}_i}^T=P_1\Delta X_1{\Delta X_1}^T+P_2\Delta X_2{\Delta X_2}^T+P_3\Delta X_3{\Delta X_3}^T+P_4\Delta X_4{\Delta X_4}^T,\end{array}$$substituting the values of $P_i,\Delta X_i$ and ${X_1,X_2}^T={St,It}^T$ into Equation (62), $$\begin{array}{}\text{(63)}& {\rm E}\Delta X{\Delta X}^T=P_1\begin{array}{c}1\\ 0\end{array}1\hspace{1em}0+P_2\begin{array}{c}-1\\ 1\end{array}-1\hspace{1em}1+P_3\begin{array}{c}-1\\ 0\end{array}-1\hspace{1em}0+P_4\begin{array}{c}0\\ -1\end{array}0\hspace{1em}-1=P_1\begin{array}{cc}1& 0\\ 0& 0\end{array}+P_2\begin{array}{cc}1& -1\\ -1& 1\end{array}+P_3\begin{array}{cc}1& 0\\ 0& 0\end{array}+P_4\begin{array}{cc}0& 0\\ 0& 1\end{array}=\begin{array}{cc}{P}_1+P_2+P_3& -P_2\\ -P_2& P_2+P_4\end{array}=\begin{array}{cc}nH\Delta t+\frac{a\text{BS}}{K+B}\Delta t+nS\Delta t& -\frac{a\text{BS}}{K+B}\Delta t\\ -\frac{a\text{BS}}{K+B}\Delta t& \frac{a\text{BS}}{K+B}\Delta t+rI\Delta t\end{array}\therefore {\rm E}\Delta X{\Delta X}^T=\begin{array}{cc}nH+S+\frac{a\text{BS}}{K+B}& -\frac{a\text{BS}}{K+B}\\ -\frac{a\text{BS}}{K+B}& \frac{a\text{BS}}{K+B}+rI\end{array}\Delta t.\end{array}$$

In Equation (61), $$\begin{array}{}\text{(64)}& \frac{E\Delta X}{\Delta \text{t}}=\begin{array}{c}nH-S-\frac{a\text{BS}}{K+B}\\ \frac{a\text{BS}}{K+B}-rI\end{array}=fXt,t,\end{array}$$

and in Equation (63), $$\begin{array}{}\text{(65)}& \frac{E\Delta X{\Delta X}^T}{\Delta t}=\begin{array}{cc}nH+S+\frac{aBS}{K+B}& -\frac{a\text{BS}}{K+B}\\ -\frac{a\text{BS}}{K+B}& \frac{a\text{BS}}{K+B}+rI\end{array}=VXt,t.\end{array}$$

Now, we compute $V^{1/2}$.

According to Allen [24], in a 2-dimensional system $g=V^{1/2}$ can be computed exactly, and it is computed as follows: $$\begin{array}{}\text{(66)}& g=V^{1/2}=\frac{1}{\beta }\begin{array}{cc}\delta +\theta & \rho \\ \rho & \omega +\theta \end{array},\end{array}$$where $\theta =\sqrt{\delta \omega -{\rho }^2}$ and $\beta =\sqrt{\delta +\omega +2\theta }$ with $$\begin{array}{c}\text{(67)}& \delta =nH+S+\frac{a\text{BS}}{K+B},\rho =-\frac{\text{aBS}}{\text{K}+\text{B}},\\ \omega =\frac{a\text{BS}}{K+B}+rI.\end{array}$$

Therefore, $\theta =\sqrt{nH+S+a\text{BS}/K+Ba\text{BS}/K+B+rI-{a\text{BS}/K+B}^2}.$$$\begin{array}{}\text{(68)}& \theta =\sqrt{nH+S\frac{a\text{BS}}{K+B}+rI\frac{a\text{BS}}{K+B}+nH+SrI},\end{array}$$and $\beta =\sqrt{nH+S+2a\text{BS}/K+B+rI+2\theta }$.

Therefore, the stochastic differential equation for the dynamics of the cholera infection is given as follows: $dXt=fXt,tdt+gXt,tdWt$ with the initial condition $X0=X_0$ and $Wt={W_{1}t,W_{2}t}^T,W_{1}t,\text{and}{W}_{2}t$ represent independent Wiener’s process. For each compartment, the following differential equations are obtained: $$\begin{array}{}\text{(69)}& \begin{array}{c}dSt=nH-S-\frac{a\text{BS}}{K+B}dt+\frac{\delta +\theta }{\beta }d{W}_{1}t+\frac{\rho }{\beta }d{W}_{2}t\hfill \\ dIt=\frac{a\text{BS}}{K+B}-rIdt+\frac{\rho }{\beta }d{W}_{1}t+\frac{\omega +\theta }{\beta }d{W}_{2}t\hfill \end{array}.\end{array}$$

The stochastic differential equations above are known as stochastic differential equations SI-B model.

Now, we model the populations each in system (69) to a single dimension Brownian motion (Wiener’s process). Thus, we write equations of system (69) in their simplified form.

Let us integrate the first equation of system (69), $$\begin{array}{c}\text{(70)}& {\int }_0^{t}dSs={\int }_0^{t}nH-S-\frac{a\text{BS}}{K+B}\text{ds}+{\int }_0^t\frac{\delta s+\theta s}{\beta s}d{W}_{1}s+{\int }_0^t\frac{\rho s}{\beta s}d{W}_{2}s,St={\int }_0^{t}nH-S-\frac{a\text{BS}}{K+B}\text{ds}+{\int }_0^t\frac{\delta s+\theta s}{\beta s}d{W}_{1}s+{\int }_0^t\frac{\rho s}{\beta s}d{W}_{2}s.\end{array}$$

Now, we define $$\begin{array}{}\text{(71)}& Mt={\int }_0^t\frac{\delta s+\theta s}{\beta s}d{W}_{1}s+{\int }_0^t\frac{\rho s}{\beta s}d{W}_{2}s.\end{array}$$

According to Greenhalgh et al. [25], the above is a martingale in terms of filtration and can be written in its quadratic variation as follows: $$\begin{array}{}\text{(72)}& Mt={\int }_0^t\frac{{\delta s+\theta s}^2}{\beta s^2}\text{ds}+{\int }_0^t\frac{\rho s^2}{\beta s^2}ds={\int }_0^t\frac{\rho s^2+\delta s^2+2\delta s\theta s+\theta s^2}{\beta s^2}\text{ds}={\int }_0^t\frac{\begin{array}{c}{-a\text{BS}/K+B}^2+{nH+S+a\text{BS}/K+B}^2+2nH+S+a\text{BS}/K+B\theta +\\ {\sqrt{nH+Sa\text{BS}/K+B+rIa\text{BS}/K+B+nH+SrI}}^2\end{array}}{{\sqrt{nH+S+2a\text{BS}/K+B+rI+2\theta }}^2}\text{ds}={\int }_0^t\frac{nH+S+a\text{BS}/K+BnH+S+2a\text{BS}/K+B+rI+2\theta }{nH+S+2a\text{BS}/K+B+rI+2\theta }\text{ds}={\int }_0^{t}nH+S+\frac{a\text{BS}}{K+B}\text{ds}.\end{array}$$