Discrete-time COVID-19 epidemic model with bifurcation and control

A. Q. Khan; M. Tasneem; M. B. Almatrafi; A. Q. Khan; M. Tasneem; M. B. Almatrafi

doi:10.3934/mbe.2022092

Mathematical Biosciences and Engineering

2022, Volume 19, Issue 2: 1944-1969. doi: 10.3934/mbe.2022092

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Discrete-time COVID-19 epidemic model with bifurcation and control

1.
Department of Mathematics, University of Azad Jammu and Kashmir, Muzaffarabad 13100, Pakistan
2.
Department of Mathematics, College of Science, Taibah University, Al-Madinah Al-Munawarah, Saudi Arabia

Received: 22 September 2021 Accepted: 15 December 2021 Published: 22 December 2021

The local dynamics with different topological classifications, bifurcation analysis and chaos control in a discrete-time COVID-19 epidemic model are investigated in the interior of $\mathbb{R}_+^3$ . It is proved that discrete-time COVID-19 epidemic model has boundary equilibrium solution for all involved parameters, but it has an interior equilibrium solution under definite parametric condition. Then by linear stability theory, local dynamics with different topological classifications are investigated about boundary and interior equilibrium solutions of the discrete-time COVID-19 epidemic model. Further for the discrete-time COVID-19 epidemic model, existence of periodic points and convergence rate are also investigated. It is also investigated the existence of possible bifurcations about boundary and interior equilibrium solutions, and proved that there exists no flip bifurcation about boundary equilibrium solution. Moreover, it is proved that about interior equilibrium solution there exists hopf and flip bifurcations, and we have studied these bifurcations by utilizing explicit criterion. Next by feedback control strategy, chaos in the discrete COVID-19 epidemic model is also explored. Finally numerically verified theoretical results.

Keywords:

Citation: A. Q. Khan, M. Tasneem, M. B. Almatrafi. Discrete-time COVID-19 epidemic model with bifurcation and control[J]. Mathematical Biosciences and Engineering, 2022, 19(2): 1944-1969. doi: 10.3934/mbe.2022092

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Abstract

1. Introduction

1.1. Motivation and literature review

In December 2019, Wuhan city in China—home to 11 million people—first came to the global spotlight with the reports of a pneumonia-like disease. Initially it was suspected that certain animals such as bats were its origin. Later on, however, with an unexpected surge of the corona cases all over the world, it was declared as a serious infectious pandemic which spread from one infected person to another through direct or indirect contact. This severe acute respiratory syndrome, later called COVID-19, is actually caused by a novel Coronavirus SARS-CoV-2.

Besides, SARS-CoV-2, there have also been identified at least six other kinds of coronavirus that originate from animals. Most of them cause common cold which, in certain cases, can prove a potential threat to human health. Each infected person is estimated to pass the phenomenon on to three other people. It lasts approximately between 1–14 days. The common symptoms include: sore throat, fever, general weakness, shortness of breath, cough, pain etc. There are particular groups of people among whom the risk factor becomes too higher. They include old men and women, obese guys, chain smokers, those fighting hypertension and cancer patients. Prevention seems to be the only sure cure out there.

When it initiated in China nearly two years ago, the COVID-19 was limited only to the city of Wuhan. With the progress of time, however, it first spread in the whole country and then within months reached almost every corner of the world. It happened largely due to the careless of the masses. As a result, most government were forced to impose such strict regulations as lockdown. Maintaining social distancing too could be a very viral step to curb the spread of the virus which is generally reliant upon other people to reach the healthy segment of the society.

The second wave of this contagious coronavirus was another reminder that it's over. As we learn through media, the death rate was once again on the rise. In Pakistan and Azad Kashmir (just like the rest of the world), all educational institutions were closed for two or more months. The reason was simple. People didn't take the threat seriously and, as a result, its spread couldn't be stopped. Nations globally need to learn their lessons quickly. Without taking all the precautionary measures, we won't be able to fight COVID-19. On the other hand, as compared to second wave, the third and forth waves of coronavirus were not so serious and rate of new cases controlled.

Various vaccines are continuously being tested throughout the world. Most of them have reportedly proven successful too. This, however, seems to be time consuming task. It isn't simple to first agree on a single vaccine and then make it simultaneously available across all the continents. Therefore, we, the people, are left with no other option than taking care of ourselves and near and dear ones. Kids, being less immune, are particularly prone to catch most ailments. If there's a strict parental control, it will not just keep their own families safe, but the whole society at large will also be in a better position to defy this looming health danger.

In the meanwhile, many chemists, biologists, doctors and mathematicians are trying to study the behavior of coronavirus. On the mathematical side, there are few models already discovered, to study it's behavior. Some of them are: SIR (Susceptible, Infected and Recovered) model, SIQR (Susceptible, Infectious, Quarantined and Recovered) model, SEIR (Susceptible, Exposed, Infected and Recovered) model, and SIRS (Susceptible, Infected and Recovered, Susceptible) model. For instance, Zou et al. ^[1] suggested the following epidemic model (SuEIR), which is alternative to the SEIR model by considering the unreported COVID-19 cases and instructed by machine learning algorithms based on the reported historical data, for forecasting the propagation of COVID-19 comprising a lot of authentic and casualty cases at national levels in the United States:

$\begin{equation} \frac{d S}{dt} = -\frac{\beta(I+E)S}{N}, \ \ \frac{d E}{dt} = \frac{\beta (I+E)S}{N}-\sigma E, \ \ \frac{d I}{dt} = \mu \sigma E-\gamma I, \ \ \frac{d R}{d t} = \gamma I, \end{equation}$

(1.1)

where $\beta$ is the exposure rate between the susceptible and infected people, $\sigma$ expresses the ratio of cases in the revealed sections that are either confirmed as infectious or dead/recovered without authentication, $\mu$ is the rate of realization of the infected cases, and $\gamma$ represents the alteration rate between the sections $I$ and $R$ . Ray et al. ^[2] estimated the real-time application of an open, collective ensemble to predict deaths attributable to COVID-19 in the United States. Shea et al. ^[3] explored multiple COVID-19 mathematical models to comprehend the sources of widespread COVID-19 disease. Nadim et al. ^[4] studied the stability analysis of the following compartmental epidemic model of COVID-19 to forecast and control the upsurge:

$\begin{equation} \begin{split} \frac{dS}{dt}& = \Pi-\frac{S (\beta I+r_Q\beta Q+r_A\beta A+r_J\beta J)}{N}-\mu S, \\ \frac{dE}{dt}& = \frac{S (\beta I+r_Q\beta Q+r_A\beta A+r_J\beta J)}{N}-(\gamma_1+k_1+\mu)E, \\ \frac{dQ}{dt}& = \gamma_1E-(k_2+\sigma_1+\mu)J, \\ \frac{dA}{dt}& = p K_1E-(\sigma_2+\mu)A, \\ \frac{dI}{dt}& = (1-p)k_1E-(\gamma_2+\sigma_3+\mu)I, \\ \frac{dJ}{dt}& = k_2Q+\gamma_2I-(\delta+\sigma_4+\mu)J, \\ \frac{dR}{dt}& = \sigma_1Q+\sigma_2A+\sigma_3I+\sigma_4J-\mu R, \end{split} \end{equation}$

(1.2)

where $\Pi$ is recuitment rate, $\beta$ is transmission rate. $r_Q$ , $r_A$ and $r_J$ are modification factors for quarantined, asymptomatic and isolated respectively. $\gamma_1$ is the rate at which the exposed individuals are diminished by quarantine, and $\gamma_2$ is the rate at which the symptomatic individuals are diminished by isolation. $k_1$ and $k_2$ are rates at which exposed become infected, quarantined individuals are isolated, respectively. $p$ is the proportion of asymptomatic individuals. $\sigma_1$ , $\sigma_2$ , $\sigma_3$ , $\sigma_4$ are respectively the recovery rates from quarantined, asymptomatic, symptomatic and isolated individuals. $\delta$ and $\mu$ are the diseases induced mortality rate and natural death rate, respectively. Li et al. ^[5] developed a SEIQR COVID-19 model, described by the system of difference equation:

$\begin{equation} \begin{split} S_{t+1}& = S_t-\frac{\beta S_tE_t +\beta_1 S_tI_t}{N_t}, \\ E_{t+1}& = E_t+\frac{\beta S_tE_t +\beta_1 S_tI_t}{N_t}-\delta E_t, \\ I_{t+1}& = I_t+\delta E_t-m I_t, \\ Q_{t+1}& = Q_t+m I_t-\gamma Q_t, \\ R_{t+1}& = R_t+\gamma Q_t, \\ N_t& = S_t+E_t+I_t+Q_t+R_t, \end{split} \end{equation}$

(1.3)

where human host incubation period is $\frac{1}{\delta}$ days. Infectious cases at the rate $m$ revert to confirmed cases, and recovered rate is $\gamma$ . Susceptible humans acquire COVID-19 through direct contact with exposed cases and infected cases at rates $\frac{\beta S_tE_t}{N_t}$ and $\frac{\beta_1S_tI_t}{N_t}$ , respectively. Tian et al. ^[6] investigated the spread and control of COVID-19 using a data set that included case reports, human movement, and public health interventions. Sun et al. ^[7] presented the following model to show the propagation of COVID-19 in Wuhan:

$\begin{equation} \frac{dS}{dt} = -\frac{\beta_1^{'} S E+\beta_2^{'}S I}{N}, \ \frac{dE}{dt} = \frac{\beta_1^{'} S E+\beta_2^{'}S I}{N}-\delta E, \ \frac{dI}{dt} = \delta E-m_1I, \ \frac{dQ}{dt} = m_1I-\gamma Q, \ \frac{dR}{dt} = \gamma Q, \end{equation}$

(1.4)

where $N$ , $S$ , $E$ , $I$ , $Q$ , $R$ are total, susceptible, exposed, infected, confirmed and removed populations, respectively. $\beta_1^{'}$ and $\beta_2^{'}$ are infection coefficients under lockdown, and $m_1$ is confirmation rate depends on the rickness of medical resources. $\delta$ is transform rate from the exposed population to infected population, and $\gamma$ is transform rate from the confirmed population to the removed population. In 2021, Tesfaya et al. ^[8] suggested the following continuous-time stochastic COVID-19 epidemic model with jump-diffusion derived by both Gaussian and non-Gaussian noises:

$\begin{eqnarray} \begin{split} \frac{dS}{dt}& = \Lambda-\beta S I-\nu S+\sigma R, \ \frac{dI}{dt} = \beta S I-(\nu+\gamma) I, \ \frac{dR}{dt} = \gamma I-(\nu+\sigma) R, \end{split} \end{eqnarray}$

(1.5)

where $S, \ I$ and $R$ respectively denote susceptible, infected and recovered populations, whereas joining rate of people to susceptible class through migration or birth is $\Lambda$ , $\beta$ is the rate at which susceptible class tends to infected one, $\nu$ is due to coronavirus death, recovery rate is $\gamma$ , and $\sigma$ is the rate of deteriorate in health.

1.2. Statement of the problem

Motivated from the aforementioned studies, the purpose of this study is to investigate the dynamical characteristics of COVID-19 epidemic model, which is discrete analogue of continuous-time stochastic COVID-19 epidemic model (1.5), by Euler-forward formula. It is noted here that by applying Euler-forward formula the continuous-time stochastic COVID-19 epidemic model (1.5) takes the following form:

$\begin{eqnarray} \begin{split} \frac{S_{t+1}-S_t}{h}& = \Lambda-\beta S_t I_t-\nu S_t+\sigma R_t, \ \frac{I_{t+1}-I_t}{h} = \beta S_t I_t-(\nu+\gamma) I_t, \ \frac{R_{t+1}-R_t}{h} = \gamma I_t-(\nu+\sigma) R_t. \end{split} \end{eqnarray}$

(1.6)

After simplification, model (1.6) takes the following form:

$\begin{eqnarray} \begin{split} S_{n+1}& = h \Lambda+(1-\nu h)S_n-\beta h S_n I_n+h \sigma R_n, \ I_{n+1} = (1-\nu h-\gamma h) I_n+h \beta S_n I_n, \\ R_{n+1}& = (1-h \nu-h \sigma) R_n+h \gamma I_n, \end{split} \end{eqnarray}$

(1.7)

with $h$ is step size and $t$ is denoted by $n$ . It is also important to note that in the proposed work we study dynamical characteristics of discrete-time COVID-19 epidemic model (1.7), which is counter part of epidemic model (1.5), because discrete model gives more efficient computational results as compared to continuous once.

1.3. Structure of the paper

In the subsequent Section existence of equilibrium solutions of discrete COVID-19 epidemic model (1.7) is explored. In Section 3 we have constructed linearized form of discrete COVID-19 epidemic model (1.7) whereas Section 4 is about the exploration of local behavior of COVID-19 epidemic model (1.7) at equilibrium solutions. In Section 5 periodic points with period- $n$ of COVID-19 epidemic model (1.7) is investigated. The convergence rate for COVID-19 epidemic model (1.7) is studied in Section 6. In detailed bifurcation analysis about equilibrium solutions of discrete COVID-19 epidemic model (1.7) is given in Section 7. Section 8 is about the study of chaos control of COVID-19 epidemic model (1.7). Numerical verifications of theoretical results are given in Section 9. The concluding remarks are given in Section 10.

2. Existence of equilibrium solutions of discrete COVID-19 epidemic model (1.7)

In $\mathbb{R}_+^3$ , existence of equilibrium solutions of COVID-19 epidemic model (1.7) is studied in this Section, as follows:

Lemma 2.1. For existence results regarding equilibrium solutions of discrete COVID-19 epidemic model (1.7), following statements hold:

${\rm{(i)}}$ $\forall \ h, \ \beta, \ \Lambda, \ \nu, \ \sigma, \ \gamma > 0$ , discrete COVID-19 epidemic model (1.7) has boundary equilibrium solution: $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ ;

$({\rm{ii}})$ If $\beta > \frac{\nu \left(\nu+\gamma\right)}{\Lambda}$ then discrete COVID-19 epidemic model (1.7) has interior equilibrium solution:

$E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right).$

Proof. If equilibrium solution of COVID-19 epidemic model (1.7) is $E_{SIR}(S, I, R)$ then

$\begin{equation} S = h \Lambda+(1-\nu h) S-\beta h S I+h \sigma R, \ I = (1-\nu h -\gamma h ) I+h \beta S I, \ R = (1-h \nu-h \sigma) R+h \gamma I. \end{equation}$

(2.1)

It is noted that for $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ algebraic system (2.1) satisfied identically. Thus one can obtain that the boundary solution of discrete COVID-19 epidemic model (1.7) is $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ . For the interior equilibrium solution of discrete COVID-19 epidemic model (1.7), one need to solve following algebraic system simultaneously:

$\begin{equation} (\beta I+\nu) S = \Lambda+\sigma R, \ \nu+ \gamma = \beta S, \ (\nu+\sigma) R = \gamma I. \end{equation}$

(2.2)

$2^{nd}$ equation of (2.2) yields

$\begin{equation} S = \frac{\nu+\gamma}{\beta}. \end{equation}$

(2.3)

Using Eq (2.3) in $1^{st}$ equation of (2.2) one has

$\begin{equation} (\beta I+\nu)\frac{\nu+\gamma}{\beta} = \Lambda+\sigma R. \end{equation}$

(2.4)

From $3^{rd}$ equation of (2.2) one has

$\begin{equation} R = \frac{\gamma I}{\nu+\sigma}. \end{equation}$

(2.5)

From Eqs (2.4) and (2.5) one has

$\begin{equation} I = \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}. \end{equation}$

(2.6)

Using Eq (2.6) in Eq (2.5) one has

$\begin{equation} R = \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}. \end{equation}$

(2.7)

Finally, from Eqs (2.3), (2.6) and (2.7) it can be concluded that if $\beta > \frac{\nu (\nu+\gamma)}{\Lambda}$ then interior equilibrium solution of discrete COVID-19 epidemic model (1.7) is $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ . Moreover it is important here to mention that if $\beta > \frac{\nu (\nu+\gamma)}{\Lambda}$ , i.e., $\frac{\beta \Lambda}{\nu (\nu+\gamma)} > 1$ then discrete COVID-19 epidemic model (1.7) has interior equilibrium solution, and hence basic reproductive number is $R_0 = \frac{\beta \Lambda}{\nu (\nu+\gamma)}$ .

3. Linearized form of model (1.7)

In the present Section, linearized form of discrete COVID-19 epidemic model (1.7) about equilibrium solution $E_{SIR}(S, I, R)$ is explored. The linearized form of discrete COVID-19 epidemic model (1.7) about equilibrium solution $E_{SIR}(S, I, R)$ under the map

$\begin{equation} (f, g, h)\mapsto (S_{n+1}, I_{n+1}, R_{n+1}), \end{equation}$

(3.1)

$\begin{equation} \Psi_{n+1} = J|_{E_{SIR}(S, I, R)} \Psi_{n}, \end{equation}$

(3.2)

where

$\begin{equation} J|_{E_{SIR}(S, I, R)} = \left( \begin{array}{ccc} 1-\nu h-\beta h I& -\beta h S& \sigma h\\ \beta h I& 1-\nu h-\gamma h+\beta h S& 0\\ 0& \gamma h& 1-\nu h-\sigma h \end{array} \right), \end{equation}$

(3.3)

and

$\begin{equation} f = h \Lambda+(1-\nu h)S-\beta h S I+h \sigma R, \ g = (1-\nu h-\gamma h) I+h \beta S I, \ h = (1-h \nu-h \sigma) R+h \gamma I. \end{equation}$

(3.4)

4. Local behavior of discrete COVID-19 epidemic model (1.7) about equilibrium solutions

Local dynamic behavior of COVID-19 epidemic model (1.7) about equilibrium solutions: $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ and $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ is explored in this section.

4.1. Local dynamic behavior of COVID-19 epidemic model (1.7) about $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$

About $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ , Eq (3.3) becomes

$\begin{equation} J|_{E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)} = \left( \begin{array}{ccc} 1-\nu h& -\frac{\beta \Lambda h}{\nu}& \sigma h\\ 0& 1-h \nu-h \gamma+\frac{\beta \Lambda h}{\nu}& 0\\ 0& h \gamma& 1-h \nu-h \sigma \end{array} \right), \end{equation}$

(4.1)

with characteristic roots are

$\begin{equation} \lambda_1 = 1-\nu h, \ \lambda_2 = 1-\nu h-\gamma h+\frac{\beta \Lambda h}{\nu}, \ \lambda_3 = 1-\nu h-\sigma h. \end{equation}$

(4.2)

From Eq (4.2) and by stability theory ^[9,10,11,12], one can conclude local dynamic behavior of discrete COVID-19 epidemic model (1.7) about $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ as follows.

Lemma 4.1. For local dynamic behavior of COVID-19 epidemic model (1.7) about $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ , following statements hold:

$({\rm{i}})$ $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ of discrete COVID-19 model (1.7) is a sink if

$\begin{equation} 0 < \nu < \min\left\{\frac{2}{h}, \frac{2}{h}-\sigma\right\} \ \ \mathrm{and} \ \ \frac{\nu (\nu h+\gamma h-2)}{h \Lambda} < \beta < \frac{\nu (\nu+\gamma)}{\Lambda}, \end{equation}$

(4.3)

with

$\begin{equation} \sigma < \frac{2}{h}\ \ \mathrm{and}\ \ \nu > \frac{2}{h}-\gamma; \end{equation}$

(4.4)

$({\rm{ii}})$ $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ of discrete COVID-19 model (1.7) is a source if (4.4) holds and additionally

$\begin{equation} \nu > \max\left\{\frac{2}{h}, \frac{2}{h}-\sigma\right\} \ \ \mathrm{and} \ \ \beta < \frac{\nu (\nu h+\gamma h-2)}{h \Lambda}; \end{equation}$

(4.5)

$({\rm{iii}})$ $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ of discrete COVID-19 model (1.7) is a saddle if (4.4) hold and additionally

$\begin{equation} \nu > \max\left\{\frac{2}{h}, \frac{2}{h}-\sigma\right\} \ \ \mathrm{and} \ \ \frac{\nu (\nu h+\gamma h-2)}{h \Lambda} < \beta < \frac{\nu (\nu+\gamma)}{\Lambda}, \end{equation}$

(4.6)

$\begin{equation} \frac{2}{h}-\sigma < \nu < \frac{2}{h}\ \ \mathrm{and} \ \ \frac{\nu (\nu h+\gamma h-2)}{h \Lambda} < \beta < \frac{\nu (\nu+\gamma)}{\Lambda}, \end{equation}$

(4.7)

$\begin{equation} 0 < \nu < \min\left\{\frac{2}{h}, \frac{2}{h}-\sigma\right\}\ \ \mathrm{and} \ \ \beta < \frac{\nu (\nu h+\gamma h-2)}{h \Lambda}, \end{equation}$

(4.8)

$\begin{equation} \frac{2}{h}-\sigma < \nu < \frac{2}{h}\ \ \mathrm{and} \ \ \beta < \frac{\nu (\nu h+\gamma h-2)}{h \Lambda}; \end{equation}$

(4.9)

$({\rm{iv}})$ $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ of discrete COVID-19 model (1.7) is non-hyperbolic if

$\begin{equation} \nu = \frac{2}{h}, \end{equation}$

(4.10)

$\begin{equation} \beta = \frac{\nu (\nu h+\gamma h-2)}{h \Lambda}, \end{equation}$

(4.11)

$\begin{equation} \nu = \frac{2}{h}-\sigma. \end{equation}$

(4.12)

Proof. $(i)$ By stability theory $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ of discrete COVID-19 model (1.7) is a sink if eigenvalues of $J|_{E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)}$ which are depicted in (4.2) satisfying $|\lambda_{1, 2, 3}| < 1$ . So if $|\lambda_1| = \left|1-\nu h\right| < 1$ , $|\lambda_2| = \left|1-\nu h-\gamma h+\frac{\beta \Lambda h}{\nu}\right| < 1$ and $|\lambda_3| = \left|1-\nu h-\sigma h\right| < 1$ then straightforward manipulation implies that $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ of discrete COVID-19 model (1.7) is a sink if $0 < \nu < \min\left\{\frac{2}{h}, \frac{2}{h}-\sigma\right\}$ , $\frac{\nu (\nu h+\gamma h-2)}{h \Lambda} < \beta < \frac{\nu (\nu+\gamma)}{\Lambda}$ with $\sigma < \frac{2}{h}$ and $\nu > \frac{2}{h}-\gamma$ . In similarly way one can prove conclusions $(ii)$ - $(iv)$ .

4.2. Local dynamic behavior of discrete COVID-19 epidemic model (1.7) about interior equilibrium solution: $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$

In order to find local dynamic behavior of discrete COVID-19 epidemic model (1.7) about interior equilibrium solution: $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ following theorem is utilized which shows the fact that all roots of the characteristic equation of $J|_{E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)}$ whose absolute value less than one (^[13], Theorem 1.2.3).

Theorem 4.2. The necessary and sufficient conditions for roots of following third-degree polynomial

$\begin{equation} P(\lambda) = \lambda^3+\mathcal{H}_1\lambda^2+\mathcal{H}_2\lambda+\mathcal{H}_3, \end{equation}$

(4.13)

satisfying $\left|\lambda_{1, 2, 3}\right| < 1$ are

$\begin{equation} \left|\mathcal{H}_1 + \mathcal{H}_3\right| < 1+\mathcal{H}_2, \ \ \left|\mathcal{H}_1-3\mathcal{H}_3\right| < 3 -\mathcal{H}_2, \ \ \mathcal{H}_3^2 + \mathcal{H}_2 - \mathcal{H}_3\mathcal{H}_1 < 1. \end{equation}$

(4.14)

Lemma 4.3. $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ of discrete COVID-19 epidemic model (1.7) is a stable if

$\begin{equation} \left|\mathcal{H}_1 + \mathcal{H}_3\right| < 1+\mathcal{H}_2, \ \ \left|\mathcal{H}_1-3\mathcal{H}_3\right| < 3 - \mathcal{H}_2, \ \ \mathcal{H}_3^2 + \mathcal{H}_2 - \mathcal{H}_3\mathcal{H}_1 < 1, \end{equation}$

(4.15)

where

$\begin{eqnarray} \begin{split} \mathcal{H}_1 = &-3+h \nu+h \sigma+\frac{\beta \Lambda h \nu+\beta \Lambda h \sigma-\nu \gamma \sigma h}{\gamma \nu+{\nu}^2+\sigma \nu}, \\ \mathcal{H}_2 = &\frac{1} {{\nu}^2+\sigma \nu+\gamma \nu} [3 \gamma \nu-2 \beta \Lambda h (\nu+\sigma)+3 {\nu}^2+\beta \Lambda {\nu}^2 h^2+\beta \Lambda \sigma \nu h^2-\gamma {\nu}^2 h-{\nu}^3 h\\&+2 \nu \gamma \sigma h-{\nu}^2 \gamma \sigma h^2-h^2 (\gamma+\nu) (-\beta \Lambda+{\nu}^2+\nu \gamma) (\nu+\sigma)+\beta \Lambda \nu \sigma h^2+\beta \Lambda {\sigma}^2 h^2\\&-\gamma \nu \sigma h-{\nu}^2 \sigma h-\nu \gamma {\sigma}^2 h^2+3 \sigma \nu-{\nu}^2 h \sigma-{\sigma}^2 h \nu-h (\sigma+\nu) (\gamma \nu+{\nu}^2+\sigma \nu)], \\ \mathcal{H}_3 = &\frac{1}{{\nu}^2+\sigma \nu+\gamma \nu} [\beta \Lambda \nu h+\beta \Lambda \sigma h-\gamma \nu-{\nu}^2 (1+\beta \Lambda h^2)-\beta \Lambda \sigma \nu h^2+\gamma {\nu}^2 h-\nu \gamma \sigma h\\&+{\nu}^3 h+{\nu}^2 h^2 \gamma \sigma-h^2 (\gamma+\sigma) (\nu+\sigma) (-\beta \Lambda +{\nu}^2+\nu \gamma) (-1+h \nu+\sigma h)-\beta \Lambda \sigma h^2 (\nu+\sigma)\\&+\gamma \nu \sigma h+{\nu}^2 \sigma h+\nu \gamma {\sigma}^2 h^2-h^3 \sigma \gamma (\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)-\sigma \nu (1-\nu h-\sigma h)]. \end{split} \end{eqnarray}$

(4.16)

Proof. About $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ , Eq (3.3) becomes

$\begin{eqnarray} \begin{split} J|_{E^+_{SIR}} = \left( \begin{array}{ccc} \frac{{\nu}^2+\sigma \nu+\gamma \nu-\beta \Lambda \nu h-\beta \Lambda \sigma h+\nu \gamma \sigma h}{{\nu}^2+\sigma \nu+\gamma \nu}& -h (\nu+\gamma)& \sigma h\\ \frac{h (\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{{\nu}^2+\sigma \nu+\gamma \nu}& 1& 0\\ 0& \gamma h& 1-h \nu-h \sigma \end{array} \right). \end{split} \end{eqnarray}$

(4.17)

The characteristic polynomial of $J|_{E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)}$ about interior equilibrium solution $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ of discrete COVID-19 epidemic model (1.7) is

$\begin{equation} P(\lambda) = \lambda^3+\mathcal{H}_1\lambda^2+\mathcal{H}_2\lambda+\mathcal{H}_3, \end{equation}$

(4.18)

where $\mathcal{H}_1, \mathcal{H}_2$ and $\mathcal{H}_3$ are depicted in Eq (4.16). Now Theorem 4.2 implies that interior equilibrium solution $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ of discrete COVID-19 epidemic model (1.7) is a sink if $\left|\mathcal{H}_1 + \mathcal{H}_3\right| < 1+\mathcal{H}_2, \ \left|\mathcal{H}_1-3\mathcal{H}_3\right| < 3-\mathcal{H}_2$ and $\mathcal{H}_3^2 + \mathcal{H}_2 - \mathcal{H}_3\mathcal{H}_1 < 1$ .

5. Periodic points with period- $n$ of discrete COVID-19 epidemic model (1.7)

Motivated from existing study ^[14], in this section it is explored that equilibrium solutions: $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ and $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ of discrete COVID-19 epidemic model (1.7) are periodic points with period- $n$ .

Theorem 5.1. $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ and $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ of discrete COVID-19 epidemic model (1.7) are periodic points of prime period- $1$ .

Proof. From model (1.7) one denotes

$\begin{equation} \mathcal{P}\left(S, I, R\right): = \left(f(S, I, R), g(S, I, R), h(S, I, R)\right), \end{equation}$

(5.1)

where $f(S, I, R), \ g(S, I, R)$ and $h(S, I, R)$ are depicted in Eq (3.4). From Eq (5.1) the computation yields

$\begin{eqnarray} \begin{split} \mathcal{P}|_{E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)}& = E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right), \\ \mathcal{P}|_{E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)}& = E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right). \end{split} \end{eqnarray}$

(5.2)

Therefore Eq (5.2) implies that $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ and $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ of discrete COVID-19 epidemic model (1.7) are periodic points of prime period- $1$ .

Theorem 5.2. Equilibrium solution: $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ of discrete COVID-19 epidemic model (1.7) is a periodic point of period- $n$ .

Proof. From Eq (5.1) we have

$\begin{eqnarray} \begin{split} \mathcal{P}^2& = \left(\left(1-\nu h\right)f(S, I, R)+h \Lambda-\right.\\ &\qquad \left. {}\ \beta h f(S, I, R) g(S, I, R)+h \sigma h(S, I, R), \right.\\ &\qquad \left. {}\ (1-\nu h-\gamma h) g(S, I, R)+\right.\\ &\qquad \left. {}\ \beta h f(S, I, R) g(S, I, R), \right.\\ &\qquad \left. {}\ (1-h \nu-h \sigma) h(S, I, R)+h \gamma g(S, I, R)\right) \Rightarrow \mathcal{P}^2|_{E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)} = E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right), \\ \mathcal{P}^3& = \left(\left(1-\nu h\right)f^{2}(S, I, R)+h \Lambda-\right.\\ &\qquad \left. {}\ \beta h f^{2}(S, I, R) g^{2}(S, I, R)\right.\\ &\qquad \left. {}\ +h \sigma h^{2}(S, I, R), \right.\\ &\qquad \left. {}\ (1-\nu h-\gamma h) g^{2}(S, I, R)+\right.\\ &\qquad \left. {}\ \beta h f^{2}(S, I, R) g^{2}(S, I, R), \right.\\ &\qquad \left. {}\ (1-h \nu-h \sigma) h^{2}(S, I, R)+h \gamma g^{2}(S, I, R)\right) \Rightarrow \mathcal{P}^3|_{E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)} = E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right), \\ \vdots \\ \mathcal{P}^{n}& = \left(\left(1-\nu h\right)f^{n-1}(S, I, R)+\right.\\ &\qquad \left. {}\ h \Lambda-\beta h f^{n-1}(S, I, R) g^{n-1}(S, I, R)\right.\\ &\qquad \left. {}\ +h \sigma h^{n-1}(S, I, R), \right.\\ &\qquad \left. {}\ (1-\nu h-\gamma h) g^{n-1}(S, I, R)+\right.\\ &\qquad \left. {}\ \beta h f^{n-1}(S, I, R) g^{n-1}(S, I, R), \right.\\ &\qquad \left. {}\ (1-h \nu-h \sigma) h^{n-1}(S, I, R)+h \gamma g^{n-1}(S, I, R)\right) \Rightarrow \mathcal{P}^n|_{E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)} = E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right). \end{split} \end{eqnarray}$

(5.3)

Equation (5.3) implies that equilibrium solution: $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ of discrete COVID-19 epidemic model (1.7) is a periodic point of period- $n$ .

Theorem 5.3. Equilibrium solution: $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)$ of discrete COVID-19 epidemic model (1.7) is a periodic point of period- $n$ .

Proof. From Eq (5.3) the following computation yields the required statement:

$\begin{eqnarray*} \label{b13} \begin{split} \mathcal{P}^2|_{E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)}& = &E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right), \\ \mathcal{P}^3|_{E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)}& = &E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right), \\ \vdots&\\ \mathcal{P}^n|_{E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)}& = &E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right). \end{split} \end{eqnarray*}$

6. Convergence rate of discrete COVID-19 epidemic model (1.7)

Convergence rate of discrete COVID-19 epidemic model (1.7) is studied for the completeness of this Section.

Theorem 6.1. If $\{(S_n, I_n, R_n)\}$ is a positive solution of discrete COVID-19 epidemic model (1.7) such that $\lim\limits_{n\to\infty}\{(S_n, I_n, R_n)\} = E_{SIR}(S, I, R)$ then

$\begin{equation} \varphi_n = \left( \begin{array}{ccc} \varphi_{n}^1\\ \varphi_{n}^2\\ \varphi_{n}^3 \end{array} \right), \end{equation}$

(6.1)

satisfying the following mathematical relation:

$\begin{eqnarray} \begin{split} \lim\limits_{n\to\infty}\sqrt[n]{||\varphi_n||}& = &\left|\lambda_{1, 2, 3} J|_{E_{SIR}(S, I, R)}\right|, \\ \lim\limits_{n\to\infty}\frac{||\varphi_{n+1}||}{||\varphi_n||}& = &\left|\lambda_{1, 2, 3} J|_{E_{SIR}(S, I, R)}\right|. \end{split} \end{eqnarray}$

(6.2)

Proof. It is recalled that if $\{(S_n, I_n, R_n)\}$ is a positive solution of COVID-19 epidemic model (1.7) such that $\lim\limits_{n\to\infty}\{(S_n, I_n, R_n)\} = E_{SIR}(S, I, R)$ , then in order for error terms one has

$\begin{eqnarray} \begin{split} S_{n+1}-S& = \left(1-\nu h-\beta h I\right)\left(S_n-S\right)-\beta h S_n \left(I_n-I\right)+h \sigma \left(R_n-R\right), \\ I_{n+1}-I& = h \beta I \left(S_n-S\right)+\left(1-\nu h-\gamma h+h \beta S_n\right) \left(I_n-I\right), \\ R_{n+1}-R& = h \gamma \left(I_n-I\right)+\left(1-h \nu-h \sigma\right)\left(R_n-R\right). \end{split} \end{eqnarray}$

(6.3)

Set

$\begin{equation} \varphi_{n}^1 = S_n-S, \ \ \varphi_{n}^2 = I_n-I, \ \ \varphi_{n}^3 = R_n-R. \end{equation}$

(6.4)

In view of Eq (6.4), Eq (6.3) becomes:

$\begin{eqnarray} \begin{split} \varphi_{n+1}^1& = \alpha_{11} \varphi_n^1+\alpha_{12} \varphi_n^2+\alpha_{13} \varphi_n^3, \\ \varphi_{n+1}^2& = \alpha_{21} \varphi_n^1+\alpha_{22} \varphi_n^2, \\ \varphi_{n+1}^3& = \alpha_{32} \varphi_n^2+\alpha_{33} \varphi_n^3, \end{split} \end{eqnarray}$

(6.5)

where

$\begin{eqnarray} \begin{split} \alpha_{11}& = 1-\nu h-\beta h I, \\ \alpha_{12}& = -\beta h S_n, \\ \alpha_{13}& = h \sigma , \\ \alpha_{21}& = h \beta I, \\ \alpha_{22}& = 1-\nu h-\gamma h+h \beta S_n, \\ \alpha_{32}& = h \gamma, \\ \alpha_{33}& = 1-h \nu-h \sigma. \end{split} \end{eqnarray}$

(6.6)

From Eq (6.6), one has

$\begin{eqnarray} \begin{split} \lim\limits_{n\to\infty}\alpha_{11}& = 1-\nu h-\beta h I, \\ \lim\limits_{n\to\infty}\alpha_{12}& = -\beta h S, \\ \lim\limits_{n\to\infty}\alpha_{13}& = h \sigma, \\ \lim\limits_{n\to\infty}\alpha_{21}& = h \beta I, \\ \lim\limits_{n\to\infty}\alpha_{22}& = 1-\nu h-\gamma h+h \beta S, \\ \lim\limits_{n\to\infty}\alpha_{32}& = h \gamma , \\ \lim\limits_{n\to\infty}\alpha_{33}& = 1-h \nu-h \sigma, \end{split} \end{eqnarray}$

(6.7)

that is

$\begin{eqnarray} \begin{split} \alpha_{11}& = 1-\nu h-\beta h I+\sigma_{11}, \\ \alpha_{12}& = -\beta h S+\sigma_{12}, \\ \alpha_{13}& = h \sigma+\sigma_{13}, \\ \alpha_{21}& = h \beta I+\sigma_{21}, \\ \alpha_{22}& = 1-\nu h-\gamma h+h \beta S+\sigma_{22}, \\ \alpha_{32}& = h \gamma+\sigma_{32}, \\ \alpha_{33}& = 1-h \nu-h \sigma+\sigma_{33}, \end{split} \end{eqnarray}$

(6.8)

where $\sigma_{11}, \sigma_{12}, \sigma_{13}, \sigma_{21}, \sigma_{22}, \sigma_{32}, \sigma_{33}\rightarrow0$ as $n\rightarrow \infty$ . In view of existing literature ^[15], one has the following error system:

$\begin{equation} \varphi_{n+1} = (A+B_n) \varphi_n, \end{equation}$

(6.9)

where $A = J|_{E_{SIR}(S, I, R)}$ and $B_n = \left(\begin{array}{ccc} \sigma_{11} & \sigma_{12} & \sigma_{13}\\ \sigma_{21} & \sigma_{22} & 0\\ 0 & \sigma_{32} & \sigma_{33} \end{array} \right)$ . Therefore one has the following limiting system of error terms

$\begin{equation} \left( \begin{array}{ccc} \varphi_{n+1}^1\\ \varphi_{n+1}^2\\ \varphi_{n+1}^3 \end{array} \right) = \left( \begin{array}{ccc} 1-\nu h-\beta h I& -\beta h S& h \sigma\\ h \beta I& 1-\nu h-h \gamma+h \beta S& 0\\ 0& h \gamma& 1-h \nu-h \sigma \end{array} \right) \left( \begin{array}{ccc} \varphi_{n}^1\\ \varphi_{n}^2\\ \varphi_{n}^3 \end{array} \right), \end{equation}$

(6.10)

which is same as linearized system of discrete COVID-19 epidemic model (1.7) about $E_{SIR}(S, I, R)$ . Particularly Eq (6.10) implies that

$\begin{equation} \left( \begin{array}{ccc} \varphi_{n+1}^1\\ \varphi_{n+1}^2\\ \varphi_{n+1}^3 \end{array} \right) = \left( \begin{array}{ccc} 1-\nu h& -\frac{\beta \Lambda h}{\nu}& \sigma h\\ 0& 1-h \nu-h \gamma+\frac{\beta \Lambda h}{\nu}& 0\\ 0& h \gamma& 1-h \nu-h \sigma \end{array} \right) \left( \begin{array}{ccc} \varphi_{n}^1\\ \varphi_{n}^2\\ \varphi_{n}^3 \end{array} \right), \end{equation}$

(6.11)

and

$\begin{equation} \left( \begin{array}{ccc} \varphi_{n+1}^1\\ \varphi_{n+1}^2\\ \varphi_{n+1}^3 \end{array} \right) = \left( \begin{array}{ccc} \frac{{\nu}^2+\sigma \nu+\gamma \nu-\beta \Lambda \nu h-\beta \Lambda \sigma h+\nu \gamma \sigma h}{{\nu}^2+\sigma \nu+\gamma \nu}& -h (\nu+\gamma)& \sigma h\\ \frac{h (\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{{\nu}^2+\sigma \nu+\gamma \nu}& 1& 0\\ 0& \gamma h& 1-h \nu-h \sigma \end{array} \right) \left( \begin{array}{ccc} \varphi_{n}^1\\ \varphi_{n}^2\\ \varphi_{n}^3 \end{array} \right), \end{equation}$

(6.12)

which are same as respective linearized system obtained at equilibrium solution $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ and $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)$ of the discrete COVID-19 epidemic model (1.7).

7. Bifurcations of discrete COVID-19 epidemic model (1.7)

The bifurcation analysis about $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ and $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)$ of the discrete COVID-19 epidemic model (1.7) are explored deeply in the section by bifurcation theory ^[16,17].

7.1. Bifurcation analysis about $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$

From (4.2) the computation yields $\lambda_1|_{(4.10)} = -1$ but $\lambda_{2, 3} = -1-\gamma h+\frac{\beta \Lambda h^2}{2}, -1-\sigma h\ne 1$ or $-1$ , which implies that discrete COVID-19 epidemic model (1.7) may undergo flip bifurcation if $(\Lambda, \beta, \gamma, \nu, \sigma, h)$ located in the set:

$\begin{equation} \mathcal{F}|_{E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)} = \left\{(\Lambda, \beta, \gamma, \nu, \sigma, h):\nu = \frac{2}{h}\right\}. \end{equation}$

(7.1)

The following Theorem guarantees the fact that if $(\Lambda, \beta, \gamma, \nu, \sigma, h)\in \mathcal{F}|_{E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)}$ then discrete COVID-19 epidemic model (1.7) does not undergo flip bifurcation.

Theorem 7.1. If $(\Lambda, \beta, \gamma, \nu, \sigma, h)\in \mathcal{F}|_{E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)}$ then discrete COVID-19 epidemic model (1.7) does not undergo flip bifurcation.

Proof. Since discrete COVID-19 epidemic model (1.7) is invariant with respect to $I = R = 0$ . Therefore in order to determine bifurcation, discrete COVID-19 epidemic model (1.7) is restricted on $I = R = 0$ , where it becomes

$\begin{equation} S_{n+1} = (1-\nu h) S_n+h\Lambda. \end{equation}$

(7.2)

From Eq (7.2) one denotes the map

$\begin{equation} f(S): = (1-\nu h) S+h\Lambda. \end{equation}$

(7.3)

Now if $\nu = \nu^{\ast} = \frac{2}{h}$ and $S = S^\ast = \frac{\Lambda}{\nu}$ then from Eq (7.3) one gets

$\begin{equation} \frac{\partial f}{\partial {S}}\biggr|_{\nu = \nu^\ast = \frac{2}{h}, \ S = S^\ast = \frac{\Lambda}{\nu}} = -1, \end{equation}$

(7.4)

$\begin{equation} \frac{\partial f}{\partial {\nu}}\biggr|_{\nu = \nu^\ast = \frac{2}{h}, \ S = S^\ast = \frac{\Lambda}{\nu}} = -\frac{h \Lambda}{\nu}\ne0, \end{equation}$

(7.5)

and

$\begin{equation} \frac{\partial^2f}{\partial {S^2}}\biggr|_{\nu = \nu^\ast = \frac{2}{h}, \ S = S^\ast = \frac{\Lambda}{\nu}} = 0. \end{equation}$

(7.6)

It is noted that the condition obtained in Eq (7.6) violates the non-degenerate condition for the existence of flip bifurcation and hence one can say that discrete COVID-19 epidemic model (1.7) does not undergo flip bifurcation if $(\Lambda, \beta, \gamma, \nu, \sigma, h)\in \mathcal{F}|_{E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)}$ .

7.2. Bifurcation analysis about $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)$

By utilizing explicit criterion (without finding eigenvalues), we will explore hopf and flip bifurcations by choosing $h$ as a bifurcation parameter about $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)$ of discrete COVID-19 epidemic model (1.7) in this section.

7.2.1. Hopf bifurcation about $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)$

By using following explicit criterion^[18], hopf bifurcation for the discrete COVID-19 epidemic model (1.7) about $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)$ is explored.

Lemma 7.2. Consider the following $n$ -dimensional discrete dynamical system:

$\begin{equation} X_{n+1} = f_h(X_n), \end{equation}$

(7.7)

where $h\in \mathbb{R}$ is considered as a bifurcation parameter. Moreover characteristic polynomial of $J|_X$ about $X$ of $n$ -dimensional discrete dynamical system, which is depicted in system (7.7), is

$\begin{equation} P(\lambda) = \lambda^n+\mathcal{H}_1\lambda^{n-1}+\mathcal{H}_2\lambda^{n-2}+ \cdots +\mathcal{H}_n. \end{equation}$

(7.8)

Now considering the determinants: $\Delta_0^\pm(h) = 1$ , $\Delta_1^\pm(h), \cdots, \Delta_n^\pm(h)$ , which can be expressed as

$\begin{eqnarray} \begin{split} \Delta_j^\pm(h) = \begin{vmatrix} \left( \begin{array}{ccccc} 1& \mathcal{H}_1& \mathcal{H}_2& \cdots& \mathcal{H}_{j-1}\\ 0& 1& \mathcal{H}_1& \cdots& \mathcal{H}_{j-2}\\ 0& 0& 1& \cdots& \mathcal{H}_{j-3}\\ \cdots& \cdots& \cdots& \cdots& \cdots\\ 0& 0& 0& \cdots& 1 \end{array} \right)\pm \left( \begin{array}{ccccc} \mathcal{H}_{n-j+1}& \mathcal{H}_{n-j+2}& \cdots& \mathcal{H}_{n-1}& \mathcal{H}_n\\ \mathcal{H}_{n-j+2}& \mathcal{H}_{n-j+3}& \cdots& \mathcal{H}_n& 0\\ \cdots& \cdots& \cdots& \cdots& \cdots\\ \mathcal{H}_{n-1}& \mathcal{H}_n& \cdots& 0& 0\\ \mathcal{H}_n& 0& \cdots& 0& 0 \end{array} \right) \end{vmatrix} \end{split}, \end{eqnarray}$

(7.9)

where $j = 1, \cdots, n$ . Furthermore, hopf bifurcation occurs at critical value $h = h_0$ if following parametric conditions hold:

$\Gamma_1:$ Eigenvalue assignment: $P_{h_0}(1) > 0, \ (-1)^nP_{h_0}(-1) > 0, \ \Delta_{n-1}^-(h_0) = 0, \ \Delta_{n-1}^+(h_0) > 0, \ \Delta_j^\pm(h_0) > 0$ where $j = n-3, n-5, \cdots, 1$ (or 2), when $n$ is even (or odd, respectively).

$\Gamma_2:$ Transversality condition: $\frac{d}{dh}\Delta_{n-1}^-(h_0)\neq0$ .

$\Gamma_3:$ Nonresonance condition: $\cos(\frac{2\pi}{l})\neq1-0.5P_h(1)\frac{\Delta_{n-3}^-(h_0)}{\Delta_{n-2}^+(h_0)}$ or resonance condition $\cos\left(\frac{2\pi}{l}\right) = 1-0.5P_h(1)\frac{\Delta_{n-3}^-(h_0)}{\Delta_{n-2}^+(h_0)}$ , where $l = 3, 4, \cdots$ .

Theorem 7.3. If

$\begin{eqnarray} \begin{split} 1 -\mathcal{H}_2 +\mathcal{H}_3(\mathcal{H}_1 -\mathcal{H}_3) = 0, \\ 1 + \mathcal{H}_2 - \mathcal{H}_3(\mathcal{H}_1 + \mathcal{H}_3) > 0, \\ 1 + \mathcal{H}_1 + \mathcal{H}_2 + \mathcal{H}_3 > 0, \\ 1 - \mathcal{H}_1 + \mathcal{H}_2 - \mathcal{H}_3 > 0, \\ \frac{d}{dh}\left(1 - \mathcal{H}_2 + \mathcal{H}_3(\mathcal{H}_1 - \mathcal{H}_3)\right)|_{h = h_0}\neq 0, \\ \cos\frac{2\pi}{l}\neq 1- \frac{1 + \mathcal{H}_1 + \mathcal{H}_2 + \mathcal{H}_3}{2(1+\mathcal{H}_3)}, \ l = 3, 4, \cdots, \end{split} \end{eqnarray}$

(7.10)

then about $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)$ discrete COVID-19 epidemic model (1.7) undergoes a hopf bifurcation at a critical value $h_0$ where $\mathcal{H}_1, \mathcal{H}_2, \mathcal{H}_3$ are depicted in Eq (4.16) and $h_0$ is the real root of $1 -\mathcal{H}_2(h) +\mathcal{H}_3(h)(\mathcal{H}_1(h) -\mathcal{H}_3(h)) = 0$ .

Proof. By utilizing Lemma 7.2 for $n = 3$ , one gets:

$\begin{eqnarray} \begin{split} \Delta_2^-(h) = 1 - \mathcal{H}_2 + \mathcal{H}_3(\mathcal{H}_1-\mathcal{H}_3) = 0, \\ \Delta_2^+(h) = 1 + \mathcal{H}_2 - \mathcal{H}_3(\mathcal{H}_1 + \mathcal{H}_3) > 0, \\ P_h(1) = 1 + \mathcal{H}_1 + \mathcal{H}_2 + \mathcal{H}_3 > 0, \\ (-1)^3P_h(-1) = 1 - \mathcal{H}_1 + \mathcal{H}_2 - \mathcal{H}_3 > 0, \\ \frac{d}{d h}\left(\Delta_2^-(h)\right)|_{h = h_0} = \frac{d}{d h}\left(1 - \mathcal{H}_2 + \mathcal{H}_3(\mathcal{H}_1-\mathcal{H}_3)\right)|_{h = h_0}\neq 0. \end{split} \end{eqnarray}$

(7.11)

Finally

$\begin{eqnarray} \begin{split} 1-0.5P_h(1)\frac{\Delta_0^-(h)}{\Delta_1^+(h)} = 1- \frac{1 + \mathcal{H}_1 + \mathcal{H}_2 + \mathcal{H}_3}{2(1+\mathcal{H}_3)} \end{split}. \end{eqnarray}$

7.2.2. Flip bifurcation about $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)$

By using following explicit criterion ^[18,19], flip bifurcation for the discrete COVID-19 epidemic model (1.7) about $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)$ by choosing $h$ as a bifurcation parameter is explored.

Lemma 7.4. Consider the system (7.7) with $h\in \mathbb{R}$ is a bifurcation parameter. Moreover, characteristic polynomial of $J|_X$ about $X$ of system (7.7) is of the form, which is depicted in Eq (7.8). Now considering the determinants: $\Delta_0^\pm(h) = 1$ , $\Delta_1^\pm(h), \cdots, \Delta_n^\pm(h)$ , which are depicted in Eq (7.9) and $j = 1, \cdots, n$ . Furthermore flip bifurcation occurs at critical value $h = h_0$ if following parametric conditions hold:

$\Gamma_1:$ Eigenvalue assignment: $P_{h_0}(-1) = 0, \ P_{h_0}(1) > 0, \ \Delta_{n-1}^{\pm}(h_0) > 0, \ \Delta_j^\pm(h_0) > 0$ where $j = n-3, n-5, \cdots, 1$ (or 2), when $n$ is even (or odd, respectively).

$\Gamma_2:$ Transversality condition: $\frac{\sum\limits_{i = 1}^{n}(-1)^{n-i}\mathcal{H}_i^{'}}{\sum\limits_{i = 1}^{n}(-1)^{n-i}(n-i+1)\mathcal{H}_{i-1}}\neq 0$ where $\mathcal{H}_i^{'}$ represents the derivative w.r.t $h$ at $h = h_0$ .

Theorem 7.5. If

$\begin{eqnarray} \begin{split} 1 -\mathcal{H}_2 +\mathcal{H}_3(\mathcal{H}_1 -\mathcal{H}_3) > 0, \\ 1 + \mathcal{H}_2 - \mathcal{H}_3(\mathcal{H}_1 + \mathcal{H}_3) > 0, \\ 1 + \mathcal{H}_1 + \mathcal{H}_2 + \mathcal{H}_3 > 0, \\ 1 - \mathcal{H}_1 + \mathcal{H}_2 - \mathcal{H}_3 = 0, \\ 1\pm\mathcal{H}_3 > 0, \\ \frac{\mathcal{H}_1^{'} - \mathcal{H}_2^{'} + \mathcal{H}_3^{'}}{3-2\mathcal{H}_1+\mathcal{H}_2}\neq0, \end{split} \end{eqnarray}$

(7.12)

then about $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)$ discrete COVID-19 epidemic model (1.7) undergoes a flip bifurcation at a critical value $h_0$ , where $h_0$ is the real root of $1 - \mathcal{H}_1(h) + \mathcal{H}_2 (h)- \mathcal{H}_3(h) = 0$ .

Proof. By utilizing Lemma 7.4 for $n = 3$ , one gets:

$\begin{eqnarray} \begin{split} \Delta_2^-(h)& = 1 - \mathcal{H}_2 + \mathcal{H}_3(\mathcal{H}_1-\mathcal{H}_3) > 0, \\ \Delta_2^+(h)& = 1 + \mathcal{H}_2 - \mathcal{H}_3(\mathcal{H}_1 + \mathcal{H}_3) > 0, \\ P_{h_0}(1)& = 1 + \mathcal{H}_1 + \mathcal{H}_2 + \mathcal{H}_3 > 0, \\ P_{h_0}(-1)& = 1 - \mathcal{H}_1 + \mathcal{H}_2 - \mathcal{H}_3 = 0, \\ \Delta_j^{\pm}& = 1\pm\mathcal{H}_3 > 0, \\ \frac{\sum\limits_{i = 1}^{3}(-1)^{3-i}\mathcal{H}_i^{'}}{\sum\limits_{i = 1}^{3}(-1)^{3-i}(3-i+1)\mathcal{H}_{i-1}} & = \frac{\mathcal{H}_1^{'}-\mathcal{H}_2^{'}+\mathcal{H}_3^{'}}{3-2\mathcal{H}_1+\mathcal{H}_2}\neq0. \end{split} \end{eqnarray}$

(7.13)

8. Chaos control

In this Section, feedback control strategy is utilized in order to study chaos in discrete COVID-19 epidemic model (1.7) about interior equilibrium solution: $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ . By utilizing feedback control strategy, discrete COVID-19 epidemic model (1.7) takes the form

$\begin{eqnarray} \begin{split} S_{n+1}& = h \Lambda+(1-\nu h)S_n-\beta h S_n I_n+h \sigma R_n+\delta(S_n-S), \\ I_{n+1}& = (1-\nu h-\gamma h) I_n+h \beta S_n I_n+\delta(I_n-I), \\ R_{n+1}& = (1-h \nu-h \sigma) R_n+h \gamma I_n+\delta(R_n-R), \end{split} \end{eqnarray}$

(8.1)

with $\delta$ is chosen as the control parameter. The $J^C|_{E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)}$ about interior equilibrium solution $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ of controlled discrete COVID-19 epidemic model (8.1) is

$\begin{eqnarray} \begin{split} J|_{E^+_{SIR}} = \left( \begin{array}{ccc} 1+\frac{\nu\gamma\sigma h-\beta\Lambda h (\nu+\sigma)}{\nu^2+\sigma\nu+\gamma\nu}+\delta& -h (\nu+\gamma)& \sigma h\\ \frac{h(\nu+\sigma)(\beta\Lambda-\nu^2-\nu\gamma)}{\nu^2+\sigma\nu+\gamma\nu}& 1+\delta& 0\\ 0& \gamma h& 1-h \nu-h \sigma+\delta \end{array} \right), \end{split} \end{eqnarray}$

(8.2)

the characteristic polynomial of $J^C|_{E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)}$ about interior equilibrium solution $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ is

$\begin{equation} P(\lambda) = \lambda^3+\mathcal{H}_1^{*}\lambda^2+\mathcal{H}_2^{*}\lambda+\mathcal{H}_3^{*}, \end{equation}$

(8.3)

where

$\begin{eqnarray} \begin{split} \mathcal{H}_1^{*} = &\frac{\beta h\Lambda(\sigma+\nu)+\nu \{\gamma(-3-3\delta+h\nu)+(\sigma+\nu)(-3-3\delta+h(\sigma+\nu))\}}{\nu(\gamma+\sigma+\nu)}, \\ \mathcal{H}_2^{*} = &1+4\delta+3\delta^2-2h\delta\sigma-h\nu-2h\delta\nu-\frac{h^2(\gamma+\nu)(\sigma+\nu)(-\beta\Lambda+\nu(\gamma+\nu))}{\nu(\gamma+\sigma+\nu)}\\& +\frac{\{2+2\delta-h(\sigma+\nu)\}\{-\beta h\Lambda(\sigma+\nu)+\nu(\gamma+\sigma+h\gamma\sigma+\nu)\}}{\nu(\gamma+\sigma+\nu)}, \\ \mathcal{H}_3^{*} = &-\frac{1+\delta-h\nu}{\nu(\gamma+\sigma+\nu)}[\beta h\Lambda(\sigma+\nu)\{-1-\delta+h(\gamma+\sigma+\nu)\}+\nu\{-h^2\gamma^2(\sigma+\nu)\\&-(\sigma+\nu)(1+\delta+h\sigma)(-1-\delta+h(\sigma+\nu)) +\gamma(1+\delta(2+\delta)-h^2(\sigma+\nu)(\sigma+2\nu))\}]. \end{split} \end{eqnarray}$

(8.4)

Based on linear stability theory the local dynamics of controlled discrete COVID-19 epidemic model (8.1) about $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)$ can be stated as following Lemma:

Lemma 8.1. $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)$ of controlled discrete COVID-19 epidemic model (8.1) is a sink if

$\begin{equation} |\mathcal{H}_1^{*}+\mathcal{H}_3^{*}| < 1+\mathcal{H}_2^{*}, \ |\mathcal{H}_1^{*}-3\mathcal{H}_3^{*}| < 3-\mathcal{H}_2^{*}, \ {\mathcal{H}_3^{*}}^2+\mathcal{H}_2^{*}-\mathcal{H}_3^{*}\mathcal{H}_1^{*} < 1, \end{equation}$

(8.5)

where $\mathcal{H}_1^{*}, \mathcal{H}_2^{*}$ and $\mathcal{H}_3^{*}$ are depicted in Eq (8.4).

Proof. Since $J^C|_{E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)}$ about interior equilibrium solution $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ of controlled discrete COVID-19 epidemic model (8.1) has characteristics polynomial which is depicted in model (8.3). By Theorem 4.2 $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ of controlled discrete COVID-19 epidemic model (8.1) is a sink if $|\mathcal{H}_1^{*}+\mathcal{H}_3^{*}| < 1+\mathcal{H}_2^{*}$ , $|\mathcal{H}_1^{*}-3\mathcal{H}_3^{*}| < 3-\mathcal{H}_2^{*}$ and ${\mathcal{H}_3^{*}}^2+\mathcal{H}_2^{*}-\mathcal{H}_3^{*}\mathcal{H}_1^{*} < 1$ where $\mathcal{H}_1^{*}$ , $\mathcal{H}_2^{*}$ and $\mathcal{H}_3^{*}$ are depicted in Eq (8.4).

9. Numerical simulations

Theoretical results are illustrated numerically in this section. In this regard, following cases are presented to discuss the correctness of obtained theoretical results about equilibrium solutions for discrete COVID-19 epidemic model (1.7) :

Case Ⅰ: If $h = 0.565, \ \beta = 3, \ \Lambda = 0.4, \ \nu = 0.2, \ \sigma = 2, \ \gamma = 0.4$ then from Eq (4.13) computation yields $\left|\mathcal{H}_1 + \mathcal{H}_3\right| = 0.0791966397692303 < 1+\mathcal{H}_2 = 0.3493437692307695$ , $\left|\mathcal{H}_1-3\mathcal{H}_3\right| = 3.512871619153845 < 3-\mathcal{H}_2 = 3.6506562307692305$ and $\mathcal{H}_3^2 + \mathcal{H}_2 - \mathcal{H}_3\mathcal{H}_1 = 0.8910931323439 < 1$ , which implies that equilibrium solution $E^+_{SIR}\left(0.2, 1.5230769230769232, 0.27692307692307694\right)$ of discrete COVID-19 epidemic model (1.7) is a sink. In this case plots for discrete COVID-19 epidemic model (1.7) with initial values $(S_0, I_0, R_0) = (0.84, 0.84, 0.0082)$ are drawn in which show that interior equilibrium solution $E^+_{SIR}\left(0.2, 1.5230769230769232, 0.27692307692307694\right)$ is a sink.

Figure 1. Local dynamics of discrete COVID-19 epidemic model (1.7).

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Case Ⅱ: Now in this case it is proved that at $h = 0.9645432692307686$ , discrete COVID-19 epidemic model (1.7) undergoes a hopf bifurcation if $\beta = 3, \ \Lambda = 0.4, \ \nu = 0.2, \ \sigma = 0.42, \ \gamma = 4.5$ and $h\in[0.1, 1.9]$ with initial values $(S_0, I_0, R_0) = (0.94, 0.00084, 0.000782)$ . If $\beta = 3, \ \Lambda = 0.4, \ \nu = 0.2, \ \sigma = 0.42, \ \gamma = 4.5$ and $h = 0.9645432692307686$ then from Eq (4.18) one gets:

$\begin{equation} \lambda^3-2.057234309269832\lambda^2 +2.008979566986039\lambda-0.807091346153846 = 0, \end{equation}$

(9.1)

whose roots are $\lambda_{1, 2} = 0.625071481557993\pm0.7805675133791408\iota, \lambda_3 = 0.8070913461538463$ where $|\lambda_{1, 2}| = |0.625071481557993\pm0.7805675133791408\iota| = 1$ . This implies that for said parametric values the eigenvalues criterion for the existence of hopf bifurcation holds, and hence discrete COVID-19 epidemic model (1.7) may undergo hopf bifurcation. In the rest of simulation, it is proved that discrete COVID-19 epidemic model (1.7) must undergo hopf bifurcation. For instance, if $\beta = 3, \ \Lambda = 0.4, \ \nu = 0.2, \ \sigma = 0.42, \ \gamma = 4.5$ and $h = 0.9645432692307686$ then from Eq (7.10) the computation yields

$\begin{eqnarray} \begin{split} 1 -\mathcal{H}_2 +\mathcal{H}_3(\mathcal{H}_1 -\mathcal{H}_3)& = 0, \\ 1 + \mathcal{H}_2 - \mathcal{H}_3(\mathcal{H}_1 + \mathcal{H}_3)& = 0.6972071179271455 > 0, \\ 1 + \mathcal{H}_1 + \mathcal{H}_2 + \mathcal{H}_3& = 0.14465391156236085 > 0, \\ 1 - \mathcal{H}_1 + \mathcal{H}_2 - \mathcal{H}_3& = 5.8733052224097175 > 0, \\ \frac{d}{dh}\left(1 - \mathcal{H}_2 + \mathcal{H}_3(\mathcal{H}_1 - \mathcal{H}_3)\right)|_{h = 0.9645432692307686}& = 0.499543845441214\neq 0, \\ 1- \frac{1 + \mathcal{H}_1 + \mathcal{H}_2 + \mathcal{H}_3}{2(1+\mathcal{H}_3)}& = 0.6250714815579933. \end{split} \end{eqnarray}$

(9.2)

Moreover $\cos\frac{2\pi}{l} = 0.6250714815579933$ implies $l = \pm7.0158253519640486$ . Thus from Eq (9.2) all conditions of Theorem 7.3 hold and hence it can be concluded that discrete COVID-19 epidemic model (1.7) undergoes hopf bifurcation. So hopf bifurcation diagram and maximum lypunov exponents are drawn in . Finally some phase portraits for discrete COVID-19 epidemic model (1.7) are also plotted for certain values of $h$ with initial values $(S_0, I_0, R_0) = (0.94, 0.00084, 0.000782)$ in Figure 3.

Figure 2. Bifurcation diagrams and maximum lyapunov exponents for discrete COVID-19 epidemic model (1.7) if

$\beta = 3, \ \Lambda = 0.4, \ \nu = 0.2, \ \sigma = 0.42, \ \gamma = 4.5$ and

$h\in[0.1, 1.9]$ with initial values

$(S_0, I_0, R_0) = (0.94, 0.00084, 0.000782)$ .

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Figure 3. Phase portraits for discrete COVID-19 epidemic model (1.7) if

$\beta = 3, \ \Lambda = 0.4, \ \nu = 0.2, \ \sigma = 0.42, \ \gamma = 4.5$ and

$h = 0.19, 0.34, 0.5, 0.51345$ with initial values

$(S_0, I_0, R_0) = (0.94, 0.00084, 0.000782)$ .

DownLoad: Full-Size Img PowerPoint

Case Ⅲ: Now in this case it is proved that at $h = 0.3882629532979648$ , discrete COVID-19 epidemic model (1.7) undergoes a flip bifurcation if $\beta = 3, \ \Lambda = 0.4, \ \nu = 0.2, \ \sigma = 0.2, \ \gamma = 0.043$ and $h\in[0.01, 1.5]$ with initial values $(S_0, I_0, R_0) = (0.4, 0.6, 0.7)$ . If $\beta = 3, \ \Lambda = 0.4, \ \nu = 0.2, \ \sigma = 0.2, \ \gamma = 0.043$ and $h = 0.3882629532979648$ , then from Eq (4.18) one gets:

$\begin{equation} \lambda^3-0.7487760229319358\lambda^2 -0.9865217321810046\lambda+0.7622542907509305 = 0, \end{equation}$

(9.3)

whose roots are $\lambda_{1} = -1$ but $\lambda_{2, 3} = 0.8264286135915285, 0.922347409340407\not = 1\ \mathrm{or} \ -1$ . This implies that for said parametric values the eigenvalues criterion for the existence of flip bifurcation holds, and hence discrete COVID-19 epidemic model (1.7) may undergo flip bifurcation. In the rest of simulation it is proved that discrete COVID-19 epidemic model (1.7) must undergo flip bifurcation. For instance if $\beta = 3, \ \Lambda = 0.4, \ \nu = 0.2, \ \sigma = 0.2, \ \gamma = 0.043$ and $h = 0.3882629532979648$ , then from Eq (7.12) the computation yields

$\begin{eqnarray} \begin{split} 1 -\mathcal{H}_2 +\mathcal{H}_3(\mathcal{H}_1 -\mathcal{H}_3)& = 0.8347323921215153 > 0, \\ 1 + \mathcal{H}_2 - \mathcal{H}_3(\mathcal{H}_1 + \mathcal{H}_3)& = 0.0032044003420764813 > 0, \\ 1 + \mathcal{H}_1 + \mathcal{H}_2 + \mathcal{H}_3& = 0.026956535637990164 > 0, \\ 1 - \mathcal{H}_1 + \mathcal{H}_2 - \mathcal{H}_3& = 0, \\ 1+\mathcal{H}_3& = 1.7622542907509304 > 0, \\ 1-\mathcal{H}_3& = 0.23774570924906946 > 0, \\ \frac{\mathcal{H}_1^{'} - \mathcal{H}_2^{'} + \mathcal{H}_3^{'}}{3-2\mathcal{H}_1+\mathcal{H}_2}& = -1.0314039405572908\neq0. \end{split} \end{eqnarray}$

(9.4)

Thus from Eq (9.4) all conditions of Theorem 7.5 hold and hence it can be concluded that discrete COVID-19 epidemic model (1.7) undergoes flip bifurcation. So flip bifurcation diagrams and maximum lypunov exponents are drawn in . Finally, phase portraits for discrete COVID-19 epidemic model (1.7) are also plotted for $h = 0.38, 0.383$ with initial values $(S_0, I_0, R_0) = (0.4, 0.6, 0.7)$ in Figure 5.

Figure 4. Flip bifurcation diagrams and Maximum Lyapunov Exponents for discrete COVID-19 epidemic model (1.7) if

$\beta = 3, \ \Lambda = 0.4, \ \nu = 0.2, \ \sigma = 0.2, \ \gamma = 0.043$ and

$h\in[0.01, 1.5]$ with initial values

$(S_0, I_0, R_0) = (0.4, 0.6, 0.7)$ .

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Figure 5. Phase portraits for discrete COVID-19 epidemic model (1.7) if

$\beta = 3, \ \Lambda = 0.4, \ \nu = 0.2, \ \sigma = 0.2, \ \gamma = 0.043$ and

$h = 0.38, 0.383$ with initial values

$(S_0, I_0, R_0) = (0.4, 0.6, 0.7)$ .

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Case Ⅳ: The numerical simulation will be provided in order to verify result of Lemma 8.1 for controlled discrete COVID-19 epidemic model (8.1). If $h = 0.5643, \ \beta = 3, \ \Lambda = 0.22, \ \nu = 0.2, \ \sigma = 2, \ \gamma = 0.43, \delta = 0.22$ then from Eq (8.5) computation yields $|\mathcal{H}_1^{*}+\mathcal{H}_3^{*}| = 1.9887516175217854 < 1+\mathcal{H}_2^{*} = 2.062885326736867, |\mathcal{H}_1^{*}-3\mathcal{H}_3^{*}| = 1.4779003281575345 < 3-\mathcal{H}_2^{*} = 1.937114673263$ and ${\mathcal{H}_3^{*}}^2+\mathcal{H}_2^{*}-\mathcal{H}_3^{*}\mathcal{H}_1^{*} = 0.8415173747084458 < 1$ which implies that interior equilibrium solution of controlled discrete COVID-19 epidemic model (8.1) is a sink. In this case plots for discrete COVID-19 epidemic model (1.7) with initial values $(S_0, I_0, R_0) = (0.84, 0.84, 0.0082)$ are drawn in Figure 6, which show that interior equilibrium solution is a sink.

Figure 6. Local dynamics for controlled discrete COVID-19 epidemic model (8.1).

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Case Ⅴ: Finally, we will fit real data, obtained from published materials for three different countries France, Italy and United Kingdom, to our under consideration discrete epidemic model (1.7) in order for the effectiveness of our mathematical analysis regarding stability. The collected real data is depicted in Table 1 whereas corresponding dynamical analysis of discrete epidemic model (1.7) of France, Italy and the United Kingdom are respectively given in Figures 7–9. In Figure 7(a) the plot of susceptible population show a curve that represent the number of susceptible individuals increase rapidly with the passage of time. After peak, the number of susceptible individuals decrease and attain a steady state whereas Figure 7(b) shows a curve that represent the infection rate is sharply increase with the passage of time and reach to its maximum level. Finally, Figure 7(c) represent that curve goes upward slowly which means that the number of recovered individuals were small initially due to less medical care and facilities but with the passage of time the recovery rate increases due to proper medication and vaccination. Similar results can be interpreted for real data plotted in Figures 8 and 9 for Italy and United Kingdom, respectively.

Table 1. Real data for three different countries France, Italy and United Kingdom.

Parameter	Interpretation	France	Italy	United Kingdom	Source
$\Lambda$	Rate in $S$ through migration	0.21	0.21	0.21	Estimated
$\beta$	Rate to join $S$ to $I$	0.926	0.571	0.999	^[20,21]
$\nu$	Death rate due to virus	$3.3616\times 10^{-5}$	$3.2612\times 10^{-5}$	$3.2929\times 10^{-5}$	^[23]
$\gamma$	Recovery rate	0.0735	0.076	0.0714	^[21,22]
$\sigma$	Rate of deteriorate in health	0.0249	0.0338	0.0294	^[23]
$h$	Step size	0.2	0.2	0.2	Estimated

| Show Table

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Figure 7. Plots for fitting results of discrete COVID-19 epidemic model (1.7) of France.

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Figure 8. Plots for fitting results of discrete COVID-19 epidemic model (1.7) of Italy.

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Figure 9. Plots for fitting results of discrete COVID-19 epidemic model (1.7) of United Kingdom.

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10. Conclusions

Beginning from the COVID-19, different mathematicians have proposed mathematical models to predict the cause of COVID-19 pandemic starting from Wuhan city of China in December 2019. For instance, few newly proposed mathematical models regarding COVID-19 pandemic are quoted in references ^{[1,2,3,4,5,6,7]}. In the references ^{[1,2,3,4,5,6,7]} and more study indicates that different authors predict the case of this disease by mathematical models representing systems of differential or difference equations, and moreover based on date analysis and mathematical analysis authors have explored the effect of lockdown and medical resources on the COVID-19 transformation in Wuhan city of China. So motivation from aforementioned studies, in this paper we have explored local dynamical properties, bifurcation and control in a discrete-time COVID-19 epidemic model in $\mathbb{R}_+^3$ . Algebraically, it is proved that discrete COVID-19 epidemic model (1.7) has boundary equilibrium solution: $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right) \ \forall \ h, \ \beta, \ \Lambda, \ \nu, \ \sigma, \ \gamma > 0$ but it has has interior equilibrium solution: $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ if $\beta > \frac{\nu \left(\nu+\gamma\right)}{\Lambda}$ . Further local dynamical characteristics with topological classifications about equilibrium solutions $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ and $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ of discrete COVID-19 epidemic model (1.7) are explored. It is investigated that $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ of discrete COVID-19 epidemic model (1.7) is a sink if $0 < \nu < \min\left\{\frac{2}{h}, \frac{2}{h}-\sigma\right\} \ \ \mathrm{and} \ \ \frac{\nu (\nu h+\gamma h-2)}{h \Lambda} < \beta < \frac{\nu (\nu+\gamma)}{\Lambda}$ with $\sigma < \frac{2}{h}\ \ \mathrm{and}\ \ \nu > \frac{2}{h}-\gamma$ ; source if (4.4) holds and additionally $\nu > \max\left\{\frac{2}{h}, \frac{2}{h}-\sigma\right\} \ \ \mathrm{and} \ \beta < \frac{\nu (\nu h+\gamma h-2)}{h \Lambda}$ ; saddle if (4.4) holds and additionally $\nu > \max\left\{\frac{2}{h}, \frac{2}{h}-\sigma\right\} \ \ \mathrm{and} \ \frac{\nu (\nu h+\gamma h-2)}{h \Lambda} < \beta < \frac{\nu (\nu+\gamma)}{\Lambda},$ or $\frac{2}{h}-\sigma < \nu < \frac{2}{h}\ \mathrm{and} \ \ \frac{\nu (\nu h+\gamma h-2)}{h \Lambda} < \beta < \frac{\nu (\nu+\gamma)}{\Lambda},$ or $0 < \nu < \min\left\{\frac{2}{h}, \frac{2}{h}-\sigma\right\}\ \ \mathrm{and} \ \beta < \frac{\nu (\nu h+\gamma h-2)}{h \Lambda},$ or $\frac{2}{h}-\sigma < \nu < \frac{2}{h}\ \mathrm{and} \ \ \beta < \frac{\nu (\nu h+\gamma h-2)}{h \Lambda}$ ; non-hyperbolic if $\nu = \frac{2}{h},$ or $\beta = \frac{\nu (\nu h+\gamma h-2)}{h \Lambda},$ or $\nu = \frac{2}{h}-\sigma$ , and moreover interior equilibrium solution $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ of discrete COVID-19 epidemic model (1.7) is a sink if $\left|\mathcal{H}_1 + \mathcal{H}_3\right| < 1+\mathcal{H}_2, \ \ \left|\mathcal{H}_1-3\mathcal{H}_3\right| < 3-\mathcal{H}_2, \ \ \mathcal{H}_3^2 + \mathcal{H}_2 - \mathcal{H}_3\mathcal{H}_1 < 1$ where $\mathcal{H}_1, \mathcal{H}_2$ and $\mathcal{H}_3$ are depicted in Eq (4.16). It is shown that $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ and $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ of discrete COVID-19 epidemic model (1.7) are periodic points of period- $n$ . We have also studied convergence rate for discrete COVID-19 epidemic model (1.7). Further, in order to understand dynamics of discrete COVID-19 epidemic model (1.7) deeply, we have studied the possible bifurcation scenarios. It is proved that about $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$ there exist no flip bifurcation if $(\Lambda, \beta, \gamma, \nu, \sigma, h)\in \mathcal{F}|_{E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)} = \left\{(\Lambda, \beta, \gamma, \nu, \sigma, h):\nu = \frac{2}{h}\right\}$ , but discrete COVID-19 epidemic model (1.7) undergoes both hopf and flip bifurcations about $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ by choosing $h$ as bifurcation parameter. We have studied hopf and flip bifurcations about $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ of discrete COVID-19 epidemic model (1.7) by utilizing explicit criterion. By feedback control strategy, chaos in discrete COVID-19 epidemic model (1.7) about $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{\left(\nu+\sigma\right) \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}, \frac{\gamma \left(\beta \Lambda-{\nu}^2-\nu \gamma\right)}{\beta \left({\nu}^2+\left(\sigma+\gamma\right) \nu\right)}\right)$ is also explored. For controlled system (8.1) it is proved that $E^+_{SIR}\left(\frac{\nu+\gamma}{\beta}, \frac{(\nu+\sigma) (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}, \frac{\gamma (\beta \Lambda-{\nu}^2-\nu \gamma)}{\beta ({\nu}^2+(\sigma+\gamma) \nu)}\right)$ is a sink if $|\mathcal{H}_1^{*}+\mathcal{H}_3^{*}| < 1+\mathcal{H}_2^{*}, \ |\mathcal{H}_1^{*}-3\mathcal{H}_3^{*}| < 3-\mathcal{H}_2^{*}$ and ${\mathcal{H}_3^{*}}^2+\mathcal{H}_2^{*}-\mathcal{H}_3^{*}\mathcal{H}_1^{*} < 1$ , where $\mathcal{H}_1^{*}, \mathcal{H}_2^{*}$ and $\mathcal{H}_3^{*}$ are depicted in Eq (8.4). Finally numerically verified theoretical results.

Acknowledgments

This research is partially supported by the Higher Education Commission of Pakistan.

Conflict of interest

The authors declare that they have no conflicts of interest regarding the publication of this paper.

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Mathematical Biosciences and Engineering

Discrete-time COVID-19 epidemic model with bifurcation and control

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Abstract

1. Introduction

1.1. Motivation and literature review

1.2. Statement of the problem

1.3. Structure of the paper

2. Existence of equilibrium solutions of discrete COVID-19 epidemic model (1.7)

3. Linearized form of model (1.7)

4. Local behavior of discrete COVID-19 epidemic model (1.7) about equilibrium solutions

4.1. Local dynamic behavior of COVID-19 epidemic model (1.7) about ES00(Λν,0,0) E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)

5. Periodic points with period-n n of discrete COVID-19 epidemic model (1.7)

6. Convergence rate of discrete COVID-19 epidemic model (1.7)

7. Bifurcations of discrete COVID-19 epidemic model (1.7)

7.1. Bifurcation analysis about ES00(Λν,0,0) E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)

8. Chaos control

9. Numerical simulations

10. Conclusions

Acknowledgments

Conflict of interest

References

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Abstract

1. Introduction

1.1. Motivation and literature review

1.2. Statement of the problem

1.3. Structure of the paper

2. Existence of equilibrium solutions of discrete COVID-19 epidemic model (1.7)

3. Linearized form of model (1.7)

4. Local behavior of discrete COVID-19 epidemic model (1.7) about equilibrium solutions

4.1. Local dynamic behavior of COVID-19 epidemic model (1.7) about ES00(Λν,0,0) E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)

5. Periodic points with period-n n of discrete COVID-19 epidemic model (1.7)

6. Convergence rate of discrete COVID-19 epidemic model (1.7)

7. Bifurcations of discrete COVID-19 epidemic model (1.7)

7.1. Bifurcation analysis about ES00(Λν,0,0) E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)

8. Chaos control

9. Numerical simulations

10. Conclusions

Acknowledgments

Conflict of interest

References

4.1. Local dynamic behavior of COVID-19 epidemic model (1.7) about $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$

5. Periodic points with period- $n$ of discrete COVID-19 epidemic model (1.7)

7.1. Bifurcation analysis about $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$

4.1. Local dynamic behavior of COVID-19 epidemic model (1.7) about $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$

5. Periodic points with period- $n$ of discrete COVID-19 epidemic model (1.7)

7.1. Bifurcation analysis about $E_{S00}\left(\frac{\Lambda}{\nu}, 0, 0\right)$