Abstract

Food security has become a significant issue due to the growing human population. In this case, a significant role is played by agriculture. The essential foods are obtained mainly from plants. Plant diseases can, however, decrease both food production and its quality. Therefore, it is substantial to comprehend the dynamics of plant diseases as they can provide insightful information about the dispersal of plant diseases. In order to investigate the dynamics of plant disease and analyze the effects of strategies of disease control, a mathematical model can be applied. We show that this model provides the non-negative solutions that population dynamics requires. The model was investigated by using the Atangana-Baleanu in Caputo sense (ABC) operator which is symmetrical to the Caputo-Fabrizio (CF) operator with a different function. Whereas the ABC operator uses the generalized Mittag-Leffler function while the CF operator employs the exponential kernel. For the proposed model, we have displayed the local and global stability of a nonendemic and an endemic equilibrium, existence and uniqueness theorems. By applying the fractional Adams-Bashforth-Moulton method, we have implemented numerical solutions to illustrate the theoretical analysis.

Keywords: Adams-Bashforth-Moulton method, local and global asymptotic equilibrium stability, sensitivity analysis, existence theorems, uniqueness theorems, plant diseases model, numerical simulations

1. Introduction

Plants are an incredibly valuable component of our world. The earth, due to the presence of plants, is known as a green planet. They are perhaps the most important component of the life of all the earth's living beings. Some of the plant's essential functions are food, reducing the level of pollution, supplying fresh oxygen, medications, furniture and refuge. Plant disease, however, triggers a decline in food production and efficiency, which can lead to numerous health and social issues. Moreover, it can cause considerable economic ramifications.

Plant disease epidemiology studies the evolution of populations of plant diseases in time and space. Usually, the execution of the techniques is accomplished by roguing and then replanting, which offers two possible advantages. Initially, infected plants could be removed and could inoculum sources could be reduced, possibly slowing the dispersal of pathogens. Then, the infected plant may die or suffer a reduction in yield. Consequently, substituting diseased plants with healthful plants can indemnity crop casualties. The exposed plant can also be able to spread disease in some cases [1-3]. Since the exposed plant is capable of spreading disease, the propagation of plant disease can be more rapid. It is therefore important to realize the impact of plants uncovered on the dynamics of plant disease contamination. Their simulation revealed that the application of fungicides is efficient in minimizing population infection [4-6].

Mathematical modeling is useful in explaining how diseases dispersal and different factors involved in the dispersal of the disease have been specified [7-11]. The defensive and curative fungicide model was introduced in Anggriani et al. [12], where it has been split into three ingredients: Infectious, protected and susceptible. Their simulation revealed that the implementation of fungicides is active in minimizing population infection. Model plant diseases with replanting, roguing and preventive care have been introduced in Anggriani et al. [13] without consideration to curative therapy. In 2017, Anggriani et al. [14] created a plant disease mathematical model that includes five ingredients: Susceptible, Protected, Infectious, Exposed and Post-Infectious with protective curative therapies. They observed that by using curative and preventative care, the transmission of plant disease can be minimized. However, where only one therapy is offered, preventive therapy is favored over curative therapy.

In actuality, there are various meanings of fractional derivatives which in general do not necessarily correspond. One of these definitions which is often utilized in different implementations of fractional differential equations is Caputo fractional derivative [15-18]. There is also a novel fractional derivative definition, named the Caputo-Fabrizio fractional operator, which centered on the exponential function [19-21]. And in the same context, there is a novel fractional derivative definition, named the Atangana-Baleanu fractional operator, which centered on the Mittag-Leffler function [22-27]. Many authors have successfully attempted to model actual processes utilizing this fractional derivative operator [28-29].

We consider a plant disease spread model within fractional calculus, where a susceptible person crosses an exposed stage prior to becoming an infectious person and diseases may also be passed on by exposed plants. The major purpose for this protraction is that the plant diseases of the classical case [12-14] do not load any acquaintance about the memory and learning techniques that impact the propagation of a disease [25]. Now, we regard the plant diseases model with fractional order as follows:

${\displaystyle {\begin{aligned}^{ABC}D_{*}^{\upsilon }S_{1}\left(t\right)&=r(M-N)-\gamma S_{1}\left(t\right)-{\frac {a_{1}}{M}}S_{1}\left(t\right)I_{1}\left(t\right)-\alpha S_{1}\left(t\right)+\beta P_{1}\left(t\right),\\^{ABC}D_{*}^{\upsilon }P_{1}\left(t\right)&=\alpha S_{1}\left(t\right)+\beta P_{1}\left(t\right)-\gamma P_{1}\left(t\right),\\^{ABC}D_{*}^{\upsilon }E_{1}\left(t\right)&={\frac {a_{1}}{M}}S_{1}\left(t\right)I_{1}\left(t\right)-\left(\gamma +a_{2}+b_{1}\right)E_{1}\left(t\right),\\^{ABC}D_{*}^{\upsilon }I_{1}\left(t\right)&=a_{2}E_{1}\left(t\right)-\left(\gamma {+}a_{3}+b_{2}+\eta \right)I_{1}\left(t\right),\\^{ABC}D_{*}^{\upsilon }R_{1}\left(t\right)&=a_{3}I_{1}\left(t\right)-\left(\gamma {+}b_{3}\right)R_{1}\left(t\right).\end{aligned}}}$

(1)

With initial conditions ${\displaystyle \left(S_{1}\right)_{0}\left(0\right)>0}$, ${\displaystyle \left(P_{1}\right)_{0}\left(0\right)\geq {0}}$, ${\displaystyle \left(E_{1}\right)_{0}\left(0\right)\geq {0}}$, ${\displaystyle \left(I_{1}\right)_{0}\left(0\right)\geq {0}}$ and ${\displaystyle \left(R_{1}\right)_{0}\left(0\right)\geq {0}}$, where ${\displaystyle N}$ indicate to the overall population of the actual plant, ${\displaystyle S_{1}\left(t\right)}$ is representing the Susceptible population, ${\displaystyle P_{1}\left(t\right)}$ is representing the Protected population, ${\displaystyle E_{1}\left(t\right)}$ is representing the Exposed population, ${\displaystyle I_{1}\left(t\right)}$ is representing the Infectious/Removed population, ${\displaystyle R_{1}\left(t\right)}$ is representing the Recovered population, and ${\displaystyle N=S_{1}\left(t\right)+P_{1}\left(t\right)+E_{1}\left(t\right)+I_{1}\left(t\right)+R_{1}\left(t\right)}$, this suggests that the size of population is not steady. (i.e. size of the population is variable). The actual meaning of each of the model's parameters, all of which have positive values, is as follows:

• ${\textstyle r}$: rate of replanting.
• ${\textstyle a_{1}}$: disease progression diversion rate for latent compartment.
• ${\textstyle a_{2}}$: disease progression diversion rate for infected compartment.
• ${\textstyle a_{3}}$: disease progression diversion rate for removed compartment.
• ${\textstyle M}$: overall maximum plant population (agronomy).
• ${\textstyle b_{1}}$: influence accumulative death rate for latent compartment.
• ${\textstyle b_{2}}$: influence accumulative death rate for infected compartment.
• ${\textstyle b_{3}}$: influence accumulative death rate for latent removed compartment.
• ${\textstyle \alpha }$: efficacy preventive therapy.
• ${\textstyle \beta }$: preventive therapy rate.
• ${\textstyle \gamma }$: rate of natural death.
• ${\textstyle \eta }$: rate of roguing.

Some assumptions have been made to facilitate understanding this model [american14]:

• There is no closure of the plant population due to replanting and natural death.
• The infected plant compartment comprises of two compartments, called, latent ${\textstyle E(t)}$ and infected ${\textstyle I(t)}$.
• The infected plant is lifted if it shows comprehensive symptoms.
• The insect vector and environment factor are neglected.
• The Preventive therapy (insecticide) be presented to susceptible compartments.
• The Protected compartment ${\textstyle P_{1}(t)}$ contains the Susceptible plants ${\textstyle S_{1}(t)}$ that have received protective therapy.
• Protected plants have defensive or prevention impact, but are not immune to disease, therefore it is permitting re-entry into the susceptible compartment.

This article is structured to have some significant preliminaries in Section 2. Section 3 transacts with studying the local and global asymptotic equilibrium stability (the disease-free case and the endemic case) and the sensibility analysis of reproduction number (${\textstyle \mathrm {\mathcal {R}} _{0}}$) without control of our model (Eq.(1)). Section 4 transacts with studying the existence and uniqueness theorems of our model (Eq.(1)). Then, computational technique (Adams-Bashforth-Moulton method) are graphically represented and covered in Sections 5 and 6. Finally, conclusions are drawn.

2. Preliminaries

Recently, many fractional calculus concepts and definitions have been developed [31-32].

Definition 1

The fractional derivative of the Atangana-Baleanu in Caputo sense (ABC) is denoted as

${\displaystyle _{0}^{ABC}D_{\varrho }^{\upsilon }\varphi \left(\varrho \right)={\frac {\chi \left(\upsilon \right)}{1-\upsilon }}{\stackrel {=}{0}}\varphi ^{\prime }\left(\tau \right)E_{\upsilon }\left[{\frac {-\upsilon }{1-\upsilon }}\left(\varrho {-\tau }\right)^{\upsilon }\right]d\tau ,}$

(2)

where ${\textstyle \chi \left(\upsilon \right)}$ is a normalized function with ${\textstyle \chi (0)=\chi (1)=1}$ which are symmetrical to the Caputo-Fabrizio (CF) case, ${\textstyle \varphi \left(\varrho \right)\in {\mathcal {H}}^{1}(a,b)}$, ${\textstyle b>a}$, ${\textstyle \upsilon \in (0,1]}$, where ${\textstyle {\mathcal {H}}^{1}(a,b)}$ is the Sobolev space ${\textstyle ({\mathcal {H}})}$ of order 1 in ${\textstyle (a,b)}$ and ${\textstyle E_{\upsilon }}$ indicate to a Mittag-Leffler function expressed as

${\displaystyle E_{\upsilon }\left(-\varrho ^{\upsilon }\right)={\stackrel {=}{\scriptscriptstyle i=0}}{\frac {\left(-\varrho \right)^{i\upsilon }}{\Gamma \left(i\upsilon {+1}\right)}}.}$

(3)

Definition 2

The related fractional integral to the AB Caputo operator is denoted as

${\displaystyle {\begin{aligned}_{0}^{AB}J_{\varrho }^{\upsilon }\varphi \left(\varrho \right)&={\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\varphi \left(\varrho \right)+{\frac {\upsilon }{\chi \left(\upsilon \right)\Gamma \left(\upsilon \right)}}{\stackrel {=}{0}}\varphi \left(\tau \right)\left(\varrho {-\tau }\right)^{\upsilon {-1}}d\tau ,\\&={\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\varphi \left(\varrho \right)+{\frac {\upsilon }{\chi \left(\upsilon \right)\Gamma \left(\upsilon \right)}}\left(I^{\upsilon }\varphi \left(\varrho \right)\right).\end{aligned}}}$

(4)

3. Analysis of plant disease model

3.1 The local asymptotic equilibrium stability

Since ${\textstyle ^{ABC}D^{\upsilon }S_{1}\left(t\right)=0}$, ${\textstyle ^{ABC}D^{\upsilon }P_{1}\left(t\right)=0}$, ${\textstyle ^{ABC}D^{\upsilon }E_{1}\left(t\right)=0}$, ${\textstyle ^{ABC}D^{\upsilon }I_{1}\left(t\right)=0}$ and ${\textstyle ^{ABC}D^{\upsilon }R_{1}\left(t\right)=0}$ when ${\textstyle t\rightarrow \infty }$, we can use them to find two equilibrium points of the fractional system (Eq.(1)), by solving the above equations we get

3.1.1 Non endemic equilibrium (NEE) point

The NEE solution of the system (Eq.(1)) is

${\displaystyle {\begin{aligned}{\mathcal {E}}_{0}&=\left(\left(S_{1}\right)_{eq},\left(P_{1}\right)_{eq},\left(E_{1}\right)_{eq},\left(I_{1}\right)_{eq},\left(R_{1}\right)_{eq}\right)\\&=\left({\frac {\gamma A_{3}Mr}{(\gamma {+}r)(\alpha \beta {+}A_{3}(\alpha {+\gamma }))}},-{\frac {\alpha \gamma Mr}{(\gamma {+}r)(\alpha \beta {+}A_{3}(\alpha {+\gamma }))}},0,0,0\right),\end{aligned}}}$

(5)

with ${\textstyle N_{E_{1}q}={\frac {rM}{\gamma {+}r}}}$ where ${\textstyle A_{1}=a_{2}+b_{1}+\gamma }$, ${\textstyle A_{2}=\gamma {+}a_{3}+b_{2}+\eta }$, ${\textstyle A_{3}=\beta {-\gamma }}$. The basic reproduction number ${\textstyle \mathrm {\mathcal {R}} _{0}}$ that is calculated utilizing the generation operator method [28,29] can be found in [14] as follows:

${\displaystyle \mathrm {\mathcal {R}} _{0}={\frac {ra_{1}a_{2}(\beta {+\gamma })}{A_{1}A_{2}(\gamma {+}r)\left(\alpha {+\beta }+\gamma \right)}}.}$

(6)

It is known as the number of secondary contagions induced by a single primary contagion in a completely susceptible population [35] and is generally expressed using model (Eq.(1)). The rate of the basic reproduction number counts on the replanting rate value. This is the justification that we should replant the plant if we want to control plant disease.

3.1.2 Endemic equilibrium (EE) point

The endemic equilibrium solution of the system (Eq.(1)) is

${\displaystyle {\mathcal {E}}^{*}=\left(S_{1}^{*},P_{1}^{*},E_{1}^{*},I_{1}^{*},R_{1}^{*}\right),}$

where

${\displaystyle {\begin{cases}S_{1}^{*}=&\displaystyle {\frac {A_{1}A_{2}M}{a_{1}a_{2}}},\\P_{1}^{*}=&-\displaystyle {\frac {\alpha A_{1}A_{2}M}{a_{1}a_{2}A_{3}}},\\E_{1}^{*}=&\displaystyle {\frac {A_{2}M\left(b_{3}+\gamma \right)\left(A_{1}A_{2}(\gamma {+}r)(\alpha \beta {+}A_{3}(\alpha {+\gamma }))-a_{1}a_{2}\gamma A_{3}r\right)}{a_{1}a_{2}A_{3}\left(a_{2}r\left(b_{3}\left(a_{3}+b_{2}+\eta \right)+\gamma \left(b_{2}+\eta \right)\right)-A_{2}\left(b_{3}+\gamma \right)\left(A_{1}(\gamma {+}r)-b_{1}r\right)\right)}},\\I_{1}^{*}=&-\displaystyle {\frac {M\left(b_{3}+\gamma \right)\left(A_{1}A_{2}(\gamma {+}r)(\alpha \beta {+}A_{3}(\alpha {+\gamma }))-a_{1}a_{2}\gamma A_{3}r\right)}{a_{1}A_{3}\left(A_{2}\left(b_{3}+\gamma \right)\left(A_{1}(\gamma {+}r)-b_{1}r\right)-a_{2}r\left(b_{3}\left(a_{3}+b_{2}+\eta \right)+\gamma \left(b_{2}+\eta \right)\right)\right)}},\\R_{1}^{*}=&-\displaystyle {\frac {a_{3}M\left(A_{1}A_{2}(\gamma {+}r)(\alpha \beta {+}A_{3}(\alpha {+\gamma }))-a_{1}a_{2}\gamma A_{3}r\right)}{a_{1}A_{3}\left(A_{2}\left(b_{3}+\gamma \right)\left(A_{1}(\gamma {+}r)-b_{1}r\right)-a_{2}r\left(b_{3}\left(a_{3}+b_{2}+\eta \right)+\gamma \left(b_{2}+\eta \right)\right)\right)}}.\end{cases}}}$

(7)

with ${\textstyle N^{*}=\displaystyle {\frac {rM-b_{1}E_{1}^{*}-\left(b_{2}+\eta \right)I_{1}^{*}-b_{3}R_{1}^{*}}{\gamma {+}r}}}$. Conclusion of the outcomes of the system's equilibrium points (Eq.(1)) with prepared to research analytically the stability of the equilibrium points.

Theorem 3.1.2.1. The NEE point ${\textstyle {\mathcal {E}}_{0}}$ of model (Eq.(1)) is locally asymptotically stable if ${\textstyle \mathrm {\mathcal {R}} _{0}<1}$ and unstable if ${\textstyle \mathrm {\mathcal {R}} _{0}>1}$.

Proof. The system's Jacobian matrix (Eq.(1)) at ${\displaystyle {\mathcal {E}}_{0}}$ is

${\displaystyle J_{{\mathcal {E}}_{0}}=\left({\begin{array}{ccccc}-\left(\alpha {+\gamma }\right)&\beta &0&\displaystyle {\frac {ra_{1}\left(\beta {+\gamma }\right)}{\left(\gamma {+}r\right)\left(\alpha {+\beta }+\gamma \right)}}&0\\\alpha &-\left(\beta {+\gamma }\right)&0&0&0\\0&0&-A_{1}&\displaystyle {\frac {ra_{1}\left(\beta {+\gamma }\right)}{\left(\gamma {+}r\right)\left(\alpha {+\beta }+\gamma \right)}}&0\\0&0&a_{2}&-A_{2}&0\\0&0&0&a_{3}&-\left(\gamma {+}b_{3}\right)\end{array}}\right).}$

(8)

The eigenvalues of ${\textstyle J_{{\mathcal {E}}_{0}}}$are given as ${\textstyle \lambda _{1}=-\gamma {<0},\quad \lambda _{2}=-\alpha {-\beta }-\gamma {<0},\quad \lambda _{3}=-b_{3}-\gamma {<0}}$ and the following quadratic equation gives ${\textstyle \lambda _{4}}$ and ${\textstyle \lambda _{5}}$ as

${\displaystyle \psi ^{2}+\left(A_{1}+A_{2}\right)\psi {+}A_{1}A_{2}\left(1-\mathrm {\mathcal {R}} _{0}\right)=0.}$

(9)

From Eq.(9), we can notice that if ${\textstyle \mathrm {\mathcal {R}} _{0}\leq {1}}$, then ${\textstyle {\mathcal {E}}_{0}}$ is locally asymptotically stable. This suggests that all polynomial coefficients (9) have the same signal, then the eigenvalues (roots) have negative real part. But if ${\textstyle \mathrm {\mathcal {R}} _{0}>1}$, the NEE is unstable and this would lead to a stable endemic equilibrium being present of ${\textstyle {\mathcal {E}}^{*}}$. Now by proving the theorem of local stability of ${\textstyle {\mathcal {E}}^{*}}$ , we conclude this section.

Theorem 3.1.2.2. If ${\textstyle \mathrm {\mathcal {R}} _{0}>1}$, the endemic equilibrium ${\displaystyle {\mathcal {E}}^{*}}$ of model (Eq.(1)) is locally asymptotically stable.

Proof. The system's Jacobian matrix (Eq.(1)) at ${\textstyle {\mathcal {E}}^{*}}$ is

${\displaystyle J_{{\mathcal {E}}^{*}}=\left({\begin{array}{ccccc}-\left(\beta {+\gamma }\right)-\displaystyle {\frac {\gamma \left(\mathrm {\mathcal {R}} _{0}-1\right)\left(\alpha {+\beta }+\gamma \right)}{\left(\beta {+\gamma }\right)}}&\beta &0&\displaystyle {\frac {ra_{1}\left(\beta {+\gamma }\right)}{\mathrm {\mathcal {R}} _{0}\left(\gamma {+}r\right)\left(\alpha {+\beta }+\gamma \right)}}&0\\\alpha &-\left(\beta {+\gamma }\right)&0&0&0\\\displaystyle {\frac {\gamma \left(\mathrm {\mathcal {R}} _{0}-1\right)\left(\alpha {+\beta }+\gamma \right)}{\left(\beta {+\gamma }\right)}}&0&-A_{1}&\displaystyle {\frac {ra_{1}\left(\beta {+\gamma }\right)}{\mathrm {\mathcal {R}} _{0}\left(\gamma {+}r\right)\left(\alpha {+\beta }+\gamma \right)}}&0\\0&0&a_{2}&-A_{2}&0\\0&0&0&a_{3}&-\left(\gamma {+}b_{3}\right)\end{array}}\right),}$

(10)

and its polynomial characteristic written as

${\displaystyle C_{J_{{\mathcal {E}}^{*}}}={\frac {\varphi {+\gamma }+b_{3}}{\mathrm {\mathcal {R}} _{0}\left(\gamma {+}r\right)\left(\alpha {+\beta }+\gamma \right)\left(\beta {+\gamma }\right)}}\left(c_{0}\varphi ^{4}+c_{1}\varphi ^{3}+c_{2}\varphi ^{2}+c_{3}\varphi {+}c_{4}\right).}$

(11)

The eigenvalues of ${\textstyle C_{J_{{\mathcal {E}}^{*}}}}$ are ${\textstyle -\left(\gamma {+}b_{3}\right)}$ and the roots of the polynomial ${\textstyle c_{0}\varphi ^{4}+c_{1}\varphi ^{3}+c_{2}\varphi ^{2}+c_{3}\varphi {+}c_{4}}$. By applying the Routh-Hortwitz criterian [31] we find that ${\textstyle c_{4},c_{3},c_{2},c_{1},c_{0}>0}$, ${\textstyle c_{2}c_{3}-c_{1}c_{4}>0}$ and ${\textstyle c_{1}c_{2}c_{3}-c_{1}^{2}c_{4}-c_{0}c_{3}^{2}>0}$. Therefore every the polynomial roots ${\textstyle C_{J_{{\mathcal {E}}^{*}}}}$ have a negative real part when ${\textstyle \mathrm {\mathcal {R}} _{0}>1}$ [32,33]. This implies that ${\textstyle {\mathcal {E}}^{*}=\left(S_{1}^{*},P_{1}^{*},E_{1}^{*},I_{1}^{*},R_{1}^{*}\right)}$ is locally asymptotically stable when ${\textstyle \mathrm {\mathcal {R}} _{0}>1}$ [30].

3.2 The global asymptotic equilibrium stability

Theorem 3.2.1. The disease-free equilibrium of the plant disease model is globally asymptotically stable in the suitable range if ${\textstyle \mathrm {\mathcal {R}} _{0}<1}$ and unstable if ${\textstyle \mathrm {\mathcal {R}} _{0}>1}$ .

Proof. We are applying the Lyapunov function [33], which is defined by

${\displaystyle {\mathcal {L}}={\frac {1}{\ell _{1}}}S_{1}+{\frac {1}{\ell _{2}}}P_{1}+{\frac {1}{\ell _{3}}}E_{1}+{\frac {1}{\ell _{4}}}I_{1}+{\frac {1}{\ell _{5}}}R_{1},}$

(12)

where

${\displaystyle \ell _{1}=\alpha {+\gamma },\quad \ell _{2}=\gamma {-\beta },\quad \ell _{3}=\gamma {+}a_{2}+b_{1},\quad \ell _{4}=\gamma {+}a_{3}+b_{2}+\eta ,\quad \ell _{5}=\gamma {+}b_{3}.}$

(13)

englishConsequently, its derivative along the plant disease model's solutions

${\displaystyle ^{ABC}D_{*}^{\upsilon }{\mathcal {L}}={\frac {1}{\ell _{1}}}{}^{ABC}D_{*}^{\upsilon }S_{1}+{\frac {1}{\ell _{2}}}{}^{ABC}D_{*}^{\upsilon }P_{1}+{\frac {1}{\ell _{3}}}{}^{ABC}D_{*}^{\upsilon }E_{1}}$ ${\displaystyle +{\frac {1}{\ell _{4}}}{}^{ABC}D_{*}^{\upsilon }I_{1}+{\frac {1}{\ell _{5}}}{}^{ABC}D_{*}^{\upsilon }R_{1}.}$

(14)

${\displaystyle {\begin{aligned}^{ABC}D_{*}^{\upsilon }{\mathcal {L}}&={\frac {1}{\ell _{1}}}\left[r(M-N)-{\frac {a_{1}}{M}}S_{1}I_{1}+\beta P_{1}-\left(\alpha {+\gamma }\right)S_{1}\right]\\&\quad +{\frac {1}{\ell _{2}}}\left[\alpha S_{1}-\left(\gamma {-\beta }\right)P_{1}\right]\\&\quad +{\frac {1}{\ell _{3}}}\left[{\frac {a_{1}}{M}}S_{1}I_{1}-\left(\gamma {+}a_{2}+b_{1}\right)E_{1}\right]\\&\quad +{\frac {1}{\ell _{4}}}\left[a_{2}E_{1}-\left(\gamma {+}a_{3}+b_{2}+\eta \right)I_{1}\right]\\&\quad +{\frac {1}{\ell _{5}}}\left[a_{3}I_{1}-\left(\gamma {+}b_{3}\right)R_{1}\right],\end{aligned}}}$

(15)

${\displaystyle {\begin{aligned}^{ABC}D_{*}^{\upsilon }{\mathcal {L}}&=\,{\frac {1}{\ell _{1}}}\left[r(M-N)-{\frac {a_{1}}{M}}S_{1}I_{1}+\beta P_{1}-\ell _{1}S_{1}\right]+{\frac {1}{\ell _{2}}}\left[\alpha S_{1}-\ell _{2}P_{1}\right]+{\frac {1}{\ell _{3}}}\left[{\frac {a_{1}}{M}}S_{1}I_{1}-\ell _{3}E_{1}\right]\\&\quad +{\frac {1}{\ell _{4}}}\left[a_{2}E_{1}-\ell _{4}I_{1}\right]+{\frac {1}{\ell _{5}}}\left[a_{3}I_{1}-\ell _{5}R_{1}\right]\\&=\,\left\{{\frac {1}{\ell _{1}}}\left(r(M-N)-{\frac {a_{1}}{M}}S_{1}I_{1}+\beta P_{1}\right)+{\frac {\alpha }{\ell _{2}}}S_{1}+{\frac {1}{\ell _{3}}}{\frac {a_{1}}{M}}S_{1}I_{1}+{\frac {a_{2}}{\ell _{4}}}E_{1}+{\frac {a_{3}}{\ell _{5}}}I_{1}\right\}\\&\quad -\left(S_{1}+P_{1}+E_{1}+I_{1}+R_{1}\right)\\&=\,{\Bigg [}\left\{{\frac {1}{\ell _{1}}}\left(r(M-N)-{\frac {a_{1}}{M}}S_{1}I_{1}+\beta P_{1}\right)+{\frac {\alpha }{\ell _{2}}}S_{1}+{\frac {1}{\ell _{3}}}{\frac {a_{1}}{M}}S_{1}I_{1}+{\frac {a_{2}}{\ell _{4}}}E_{1}+{\frac {a_{3}}{\ell _{5}}}I_{1}\right\}\\&\quad {\frac {1}{\left(S_{1}+P_{1}+E_{1}+I_{1}+R_{1}\right)}}-1{\Bigg ]}\left(S_{1}+P_{1}+E_{1}+I_{1}+R_{1}\right).\end{aligned}}}$

(16)

Now we divide by S to get

${\displaystyle ^{ABC}D_{*}^{\upsilon }{\mathcal {L}}={\Bigg [}\left\{{\frac {1}{\ell _{1}}}\left({\frac {r(M-N)}{S_{1}}}-{\frac {a_{1}}{M}}I_{1}+\beta {\frac {P_{1}}{S_{1}}}\right)+{\frac {\alpha }{\ell _{2}}}+{\frac {1}{\ell _{3}}}{\frac {a_{1}}{M}}I_{1}+{\frac {a_{2}}{\ell _{4}}}{\frac {E_{1}}{S_{1}}}+{\frac {a_{3}}{\ell _{5}}}{\frac {I_{1}}{S_{1}}}\right\}}$ ${\displaystyle {\frac {1}{\left(S_{1}+P_{1}+E_{1}+I_{1}+R_{1}\right)}}-1{\Bigg ]}\left(S_{1}+P_{1}+E_{1}+I_{1}+R_{1}\right).}$

(17)

Since ${\displaystyle S}$ is major than ${\displaystyle P,\,E,\,I}$ and ${\displaystyle R}$ categories, so

${\displaystyle {\begin{aligned}^{ABC}D_{*}^{\upsilon }{\mathcal {L}}&\leq \left[{\frac {ra_{1}a_{2}(\beta {+\gamma })}{\left(a_{2}+b_{1}+\gamma \right)\left(\gamma {+}a_{3}+b_{2}+\eta \right)(\gamma {+}r)\left(\alpha {+\beta }+\gamma \right)}}-1\right]\left(S_{1}+P_{1}+E_{1}+I_{1}+R_{1}\right)\\&\leq \left[\mathrm {\mathcal {R}} _{0}-1\right]\left(S_{1}+P_{1}+E_{1}+I_{1}+R_{1}\right)\leq {0.}\end{aligned}}}$

(18)

Since ${\textstyle S_{1}+P_{1}+E_{1}+I_{1}+R_{1}>0,\forall t}$. According to the proposed model, plant disease model would therefore be eliminated if and only if ${\textstyle \mathrm {\mathcal {R}} _{0}<1}$. In general, because all parameters are positive in the plant disease model, Lyapunov function ${\textstyle \left(^{ABC}D_{*}^{\upsilon }{\mathcal {L}}\right)}$ therefore decreases if ${\textstyle \mathrm {\mathcal {R}} _{0}<1}$ and increases if ${\textstyle \mathrm {\mathcal {R}} _{0}>1}$, eventually ${\textstyle {\mathcal {L}}=0}$ if ${\textstyle S_{1}=P_{1}=E_{1}=I_{1}=R_{1}=0}$. ${\textstyle {\mathcal {L}}}$ is therefore the function of Lyapunov within the practicable biological interval and the greater compact invariant set in ${\textstyle \left\{S_{1},P_{1},E_{1},I_{1},R_{1}\in \Theta :{}^{ABC}D_{*}^{\upsilon }{\mathcal {L}}\leq {0}\right\}}$ is the point ${\textstyle {\mathcal {E_{1}}}_{0}}$. Every solution of the plant disease model proposed in this study with an initial term in ${\textstyle \Theta }$ tends to ${\textstyle {\mathcal {E_{1}}}_{0}}$ when ${\textstyle t\rightarrow \infty }$ if and only if ${\textstyle \mathrm {\mathcal {R}} _{0}\leq {1}}$ through the well-known Lasalles invariance principle [38]. In conclusion, the plant disease model's disease-free equilibrium ${\textstyle {\mathcal {E_{1}}}_{0}}$ presented here is globally asymptotically stable.

Theorem 3.2.2. The endemic equilibrium point ${\textstyle {\mathcal {E_{1}}}^{*}}$ of the plant disease system is globally asymptotically stable if ${\displaystyle \mathrm {\mathcal {R}} _{0}\leq {1}}$.

Proof. We use the Lyapunov function [38] to prove this

${\displaystyle {\begin{aligned}{\mathcal {L}}\left(S_{1}^{*},P_{1}^{*},E_{1}^{*},I_{1}^{*},R_{1}^{*}\right)&=\,\left(S_{1}-S_{1}^{*}-S_{1}^{*}\log {\frac {S_{1}^{*}}{S_{1}}}\right)+\left(P_{1}-P_{1}^{*}-P_{1}^{*}\log {\frac {P_{1}^{*}}{P_{1}}}\right)+\left(E_{1}-E_{1}^{*}-E_{1}^{*}\log {\frac {E_{1}^{*}}{E_{1}}}\right)\\&\quad +\left(I_{1}-I_{1}^{*}-I_{1}^{*}\log {\frac {I_{1}^{*}}{I_{1}}}\right)+\left(R_{1}-R_{1}^{*}-R_{1}^{*}\log {\frac {R_{1}^{*}}{R_{1}}}\right).\end{aligned}}}$

(19)

Consequently, applying the derivative to both sides gives

${\displaystyle {\begin{aligned}^{ABC}D_{*}^{\upsilon }{\mathcal {L}}&=\left({\frac {S_{1}-S_{1}^{*}}{S_{1}}}\right){}^{ABC}D_{*}^{\upsilon }S_{1}+\left({\frac {P_{1}-P_{1}^{*}}{P_{1}}}\right){}^{ABC}D_{*}^{\upsilon }P_{1}+\left({\frac {E_{1}-E_{1}^{*}}{E_{1}}}\right){}^{ABC}D_{*}^{\upsilon }E_{1}\\&\quad +\left({\frac {I_{1}-I_{1}^{*}}{I_{1}}}\right){}^{ABC}D_{*}^{\upsilon }I_{1}+\left({\frac {R_{1}-R_{1}^{*}}{R_{1}}}\right){}^{ABC}D_{*}^{\upsilon }R_{1},\end{aligned}}}$

(20)

replacing ${\textstyle ^{ABC}D_{*}^{\upsilon }S_{1}}$, ${\textstyle ^{ABC}D_{*}^{\upsilon }P_{1}}$, ${\textstyle ^{ABC}D_{*}^{\upsilon }E_{1}}$, ${\textstyle ^{ABC}D_{*}^{\upsilon }I_{1}}$ and ${\textstyle ^{ABC}D_{*}^{\upsilon }R_{1}}$ by their values, we obtain

${\displaystyle {\begin{aligned}^{ABC}D_{*}^{\upsilon }{\mathcal {L}}&=\left({\frac {S_{1}-S_{1}^{*}}{S_{1}}}\right)\left(r(M-N)-{\frac {a_{1}}{M}}S_{1}I_{1}+\beta P_{1}-\ell _{1}S_{1}\right)\\&\quad +\left({\frac {P_{1}-P_{1}^{*}}{P_{1}}}\right)\left(\alpha S_{1}-\ell _{2}P_{1}\right)+\left({\frac {E_{1}-E_{1}^{*}}{E_{1}}}\right)\left({\frac {a_{1}}{M}}S_{1}I_{1}-\ell _{3}E_{1}\right)\\&\quad +\left({\frac {I_{1}-I_{1}^{*}}{I_{1}}}\right)\left(a_{2}E_{1}-\ell _{4}I_{1}\right)+\left({\frac {R_{1}-R_{1}^{*}}{R_{1}}}\right)\left(a_{3}I_{1}-\ell _{5}R_{1}\right).\end{aligned}}}$

(21)

Then we have

${\displaystyle {\begin{aligned}^{ABC}D_{*}^{\upsilon }{\mathcal {L}}&=\left({\frac {S_{1}-S_{1}^{*}}{S_{1}}}\right)\left[r(M-N)-{\frac {a_{1}}{M}}\left(S_{1}-S_{1}^{*}\right)\left(I_{1}-I_{1}^{*}\right)+\beta \left(P_{1}-P_{1}^{*}\right)-\ell _{1}\left(S_{1}-S_{1}^{*}\right)\right]\\&\quad +\left({\frac {P_{1}-P_{1}^{*}}{P_{1}}}\right)\left[\alpha \left(S_{1}-S_{1}^{*}\right)-\ell _{2}\left(P_{1}-P_{1}^{*}\right)\right]\\&\quad +\left({\frac {E_{1}-E_{1}^{*}}{E_{1}}}\right)\left[{\frac {a_{1}}{M}}\left(S_{1}-S_{1}^{*}\right)\left(I_{1}-I_{1}^{*}\right)-\ell _{3}\left(E_{1}-E_{1}^{*}\right)\right]\\&\quad +\left({\frac {I_{1}-I_{1}^{*}}{I_{1}}}\right)\left[a_{2}\left(E_{1}-E_{1}^{*}\right)-\ell _{4}\left(I_{1}-I_{1}^{*}\right)\right]\\&\quad +\left({\frac {R_{1}-R_{1}^{*}}{R_{1}}}\right)\left[a_{3}\left(I_{1}-I_{1}^{*}\right)-\ell _{5}\left(R_{1}-R_{1}^{*}\right)\right].\qquad \end{aligned}}}$

(22)

They can be separated in two part as follows

${\displaystyle {\begin{aligned}^{ABC}D_{*}^{\upsilon }{\mathcal {L}}&=r(M-N)\left({\frac {S_{1}-S_{1}^{*}}{S_{1}}}\right)-\left({\frac {\left(S_{1}-S_{1}^{*}\right)^{2}}{S_{1}}}\right)\left({\frac {a_{1}}{M}}\left(I_{1}-I_{1}^{*}\right)+\ell _{1}\right)\\&\quad +\beta \left(P_{1}-P_{1}^{*}\right)\left({\frac {S_{1}-S_{1}^{*}}{S_{1}}}\right)+\alpha \left(S_{1}-S_{1}^{*}\right)\left({\frac {P_{1}-P_{1}^{*}}{P_{1}}}\right)\\&\quad -\ell _{2}\left({\frac {\left(P_{1}-P_{1}^{*}\right)^{2}}{P_{1}}}\right)+{\frac {a_{1}}{M}}\left(S_{1}-S_{1}^{*}\right)\left(I_{1}-I_{1}^{*}\right)\left({\frac {E_{1}-E_{1}^{*}}{E_{1}}}\right)\\&\quad -\ell _{3}\left({\frac {\left(E_{1}-E_{1}^{*}\right)^{2}}{E_{1}}}\right)+a_{2}\left(E_{1}-E_{1}^{*}\right)\left({\frac {I_{1}-I_{1}^{*}}{I_{1}}}\right)\\&\quad -\ell _{4}\left({\frac {\left(I_{1}-I_{1}^{*}\right)^{2}}{I_{1}}}\right)+a_{3}\left(I_{1}-I_{1}^{*}\right)\left({\frac {R_{1}-R_{1}^{*}}{R_{1}}}\right)\\&\quad -\ell _{5}\left({\frac {\left(R_{1}-R_{1}^{*}\right)^{2}}{R_{1}}}\right),\end{aligned}}}$

(23)

${\displaystyle {\begin{aligned}^{ABC}D_{*}^{\upsilon }{\mathcal {L}}&=r(M-N)-r(M-N){\frac {S_{1}^{*}}{S_{1}}}-{\frac {a_{1}}{M}}I_{1}\left({\frac {\left(S_{1}-S_{1}^{*}\right)^{2}}{S_{1}}}\right)+{\frac {a_{1}}{M}}I_{1}^{*}\left({\frac {\left(S_{1}-S_{1}^{*}\right)^{2}}{S_{1}}}\right)\\&\quad -\ell _{1}\left({\frac {\left(S_{1}-S_{1}^{*}\right)^{2}}{S_{1}}}\right)+\beta P_{1}-\beta P_{1}^{*}-\beta P_{1}{\frac {S_{1}^{*}}{S_{1}}}+\beta P_{1}^{*}{\frac {S_{1}^{*}}{S_{1}}}+\alpha S_{1}-\alpha S_{1}^{*}-\alpha S_{1}{\frac {P_{1}^{*}}{P_{1}}}\\&\quad +\alpha S_{1}^{*}{\frac {P_{1}^{*}}{P_{1}}}-\ell _{2}\left({\frac {\left(P_{1}-P_{1}^{*}\right)^{2}}{P_{1}}}\right)+{\frac {a_{1}}{M}}S_{1}I_{1}-{\frac {a_{1}}{M}}S_{1}I_{1}^{*}-{\frac {a_{1}}{M}}S_{1}I_{1}{\frac {E_{1}^{*}}{E_{1}}}\\&\quad +{\frac {a_{1}}{M}}S_{1}I_{1}^{*}{\frac {E_{1}^{*}}{E_{1}}}-{\frac {a_{1}}{M}}S_{1}^{*}I_{1}+{\frac {a_{1}}{M}}S_{1}^{*}I_{1}^{*}+{\frac {a_{1}}{M}}S_{1}^{*}I_{1}{\frac {E_{1}^{*}}{E_{1}}}-{\frac {a_{1}}{M}}S_{1}^{*}I_{1}^{*}{\frac {E_{1}^{*}}{E_{1}}}\\&\quad -\ell _{3}\left({\frac {\left(E_{1}-E_{1}^{*}\right)^{2}}{E_{1}}}\right)+a_{2}E_{1}-a_{2}E_{1}^{*}-a_{2}E_{1}{\frac {I_{1}^{*}}{I_{1}}}+a_{2}E_{1}^{*}{\frac {I_{1}^{*}}{I_{1}}}-\ell _{4}\left({\frac {\left(I_{1}-I_{1}^{*}\right)^{2}}{I_{1}}}\right)\\&\quad +a_{3}I_{1}-a_{3}I_{1}^{*}-a_{3}I_{1}{\frac {R_{1}^{*}}{R_{1}}}+a_{3}I_{1}^{*}{\frac {R_{1}^{*}}{R_{1}}}-\ell _{5}\left({\frac {\left(R_{1}-R_{1}^{*}\right)^{2}}{R_{1}}}\right).\end{aligned}}}$

(24)

This can be simplified as

${\displaystyle ^{ABC}D_{*}^{\upsilon }{\mathcal {L}}={\mathcal {L}}_{1}-{\mathcal {L}}_{2},}$

(25)

where

${\displaystyle {\begin{aligned}{\mathcal {L}}_{1}&=r(M-N)+{\frac {a_{1}}{M}}I_{1}^{*}\left({\frac {\left(S_{1}-S_{1}^{*}\right)^{2}}{S_{1}}}\right)+\beta P_{1}+\beta P_{1}^{*}{\frac {S_{1}^{*}}{S_{1}}}+\alpha S_{1}\\&\quad +\alpha S_{1}^{*}{\frac {P_{1}^{*}}{P_{1}}}+{\frac {a_{1}}{M}}S_{1}I_{1}+{\frac {a_{1}}{M}}S_{1}I_{1}^{*}{\frac {E_{1}^{*}}{E_{1}}}+{\frac {a_{1}}{M}}S_{1}^{*}I_{1}^{*}\\&\quad +{\frac {a_{1}}{M}}S_{1}^{*}I_{1}{\frac {E_{1}^{*}}{E_{1}}}+a_{2}E_{1}+a_{2}E_{1}^{*}{\frac {I_{1}^{*}}{I_{1}}}+a_{3}I_{1}+a_{3}I_{1}^{*}{\frac {R_{1}^{*}}{R_{1}}},\end{aligned}}}$

(26)

and

${\displaystyle {\begin{aligned}{\mathcal {L}}_{2}&=r(M-N){\frac {S_{1}^{*}}{S_{1}}}+{\frac {a_{1}}{M}}I_{1}\left({\frac {\left(S_{1}-S_{1}^{*}\right)^{2}}{S_{1}}}\right)+\ell _{1}\left({\frac {\left(S_{1}-S_{1}^{*}\right)^{2}}{S_{1}}}\right)+\beta P_{1}^{*}+\beta P_{1}{\frac {S_{1}^{*}}{S_{1}}}\\&\quad +\alpha S_{1}^{*}+\alpha S_{1}{\frac {P_{1}^{*}}{P_{1}}}+\ell _{2}\left({\frac {\left(P_{1}-P_{1}^{*}\right)^{2}}{P_{1}}}\right)+{\frac {a_{1}}{M}}S_{1}I_{1}^{*}+{\frac {a_{1}}{M}}S_{1}I_{1}{\frac {E_{1}^{*}}{E_{1}}}\\&\quad +{\frac {a_{1}}{M}}S_{1}^{*}I_{1}+{\frac {a_{1}}{M}}S_{1}^{*}I_{1}^{*}{\frac {E_{1}^{*}}{E_{1}}}+\ell _{3}\left({\frac {\left(E_{1}-E_{1}^{*}\right)^{2}}{E_{1}}}\right)+a_{2}E_{1}^{*}+a_{2}E_{1}{\frac {I_{1}^{*}}{I_{1}}}\\&\quad +\ell _{4}\left({\frac {\left(I_{1}-I_{1}^{*}\right)^{2}}{I_{1}}}\right)+a_{3}I_{1}^{*}+a_{3}I_{1}{\frac {R_{1}^{*}}{R_{1}}}+\ell _{5}\left({\frac {\left(R_{1}-R_{1}^{*}\right)^{2}}{R_{1}}}\right),\end{aligned}}}$

(27)

this implies ${\textstyle ^{ABC}D_{*}^{\upsilon }{\mathcal {L}}>0}$ if ${\textstyle {\mathcal {L}}_{1}>{\mathcal {L}}_{2}}$, ${\textstyle ^{ABC}D_{*}^{\upsilon }{\mathcal {L}}<0}$ if ${\textstyle {\mathcal {L}}_{2}>{\mathcal {L}}_{1}}$ and ${\textstyle ^{ABC}D_{*}^{\upsilon }{\mathcal {L}}=0}$ if ${\textstyle {\mathcal {L}}_{1}={\mathcal {L}}_{2}}$, this implies ${\textstyle S_{1}=S_{1}^{*}}$, ${\textstyle P_{1}=P_{1}^{*}}$, ${\textstyle E_{1}=E_{1}^{*}}$, ${\textstyle I_{1}-I_{1}^{*}}$ and ${\textstyle R_{1}=R_{1}^{*}}$.

We can now conclude that the largest compact invariant set for the plant diseases model in ${\textstyle \left\{S_{1}^{*},P_{1}^{*},E_{1}^{*},I_{1}^{*},R_{1}^{*}\in \Theta :{}^{ABC}D_{*}^{\upsilon }{\mathcal {L}}=0\right\}}$ is the point ${\textstyle {\mathcal {E}}^{*}}$ the endemic equilibrium of the plant diseases model.

3.3 Sensibility analysis of reproduction number (${\displaystyle \mathrm {\mathcal {R}} _{0}}$ ) without control3.3 Sensibility analysis of reproduction number ( R 0 {\displaystyle \mathrm {\mathcal {R}} {0}} ) without control

Since the parameters of the epizootic system are either predestined or equipped, this raises some doubt as to their values used to draw a conclusion about the underlying epidemic. Therefore, it's critical to identify the specific effects of each element on the dynamics of the pestilence and group the variables that have the most impact to limit or spread the outbreak. Within this section, a sensitivity analysis is conducted for the disease parameters identified with the suggested SPEIR model via the sensitivity indicator. Quantifying the most sensitive aspects of the basal reproductive number ${\textstyle \mathrm {\mathcal {R}} _{0}}$ can be done with the help of the Sensitivity Indicator strategy. The following equations give the standardized sensitivity indicator ${\textstyle \Psi _{*}^{\mathrm {\mathcal {R}} _{0}}}$ of ${\textstyle \mathrm {\mathcal {R}} _{0}}$ for all the parameters ${\textstyle \left(r,a_{1},a_{2},a_{3},b_{1},b_{2},\alpha ,\beta ,\gamma ,\eta \right)}$ used within the SPEIR model in Table 1 where ${\textstyle \Psi _{*}^{\mathrm {\mathcal {R}} _{0}}={\frac {\partial \mathrm {\mathcal {R}} _{0}}{\partial }}\times {\frac {*}{\left|\mathrm {\mathcal {R}} _{0}\right|}}}$

${\displaystyle {\begin{aligned}\Psi _{r}^{\mathrm {\mathcal {R}} _{0}}&={\frac {a_{1}a_{2}\gamma (\beta {+\gamma })}{A_{1}A_{2}(\gamma {+}r)^{2}(\alpha {+\beta }+\gamma )}}=0.266667>0,\\\Psi _{a_{1}}^{\mathrm {\mathcal {R}} _{0}}&={\frac {a_{2}r(\beta {+\gamma })}{A_{1}A_{2}(\gamma {+}r)(\alpha {+\beta }+\gamma )}}=1>0,\\\Psi _{a_{2}}^{\mathrm {\mathcal {R}} _{0}}&={\frac {a_{1}r(\beta {+\gamma })\left(b_{1}+\gamma \right)}{A_{1}^{2}A_{2}(\gamma {+}r)(\alpha {+\beta }+\gamma )}}=0.0229885>0,\\\Psi _{a_{3}}^{\mathrm {\mathcal {R}} _{0}}&=-{\frac {a_{1}a_{2}r(\beta {+\gamma })}{A_{1}A_{2}^{2}(\gamma {+}r)(\alpha {+\beta }+\gamma )}}=-0.300752<0,\\\Psi _{b_{1}}^{\mathrm {\mathcal {R}} _{0}}&=-{\frac {a_{1}a_{2}r(\beta {+\gamma })}{A_{1}^{2}A_{2}(\gamma {+}r)(\alpha {+\beta }+\gamma )}}=0,\\\Psi _{b_{2}}^{\mathrm {\mathcal {R}} _{0}}&=-{\frac {a_{1}a_{2}r(\beta {+\gamma })}{A_{1}A_{2}^{2}(\gamma {+}r)(\alpha {+\beta }+\gamma )}}=0,\\\Psi _{\alpha }^{\mathrm {\mathcal {R}} _{0}}&=-{\frac {a_{1}a_{2}r(\beta {+\gamma })}{A_{1}A_{2}(\gamma {+}r)(\alpha {+\beta }+\gamma )^{2}}}=-0.0909091<0,\\\Psi _{\beta }^{\mathrm {\mathcal {R}} _{0}}&={\frac {\alpha a_{1}a_{2}r}{A_{1}A_{2}(\gamma {+}r)(\alpha {+\beta }+\gamma )^{2}}}=0.0839161>0,\\\Psi _{\eta }^{\mathrm {\mathcal {R}} _{0}}&=-{\frac {a_{1}a_{2}r(\beta {+\gamma })}{A_{1}A_{2}^{2}(\gamma {+}r)(\alpha {+\beta }+\gamma )}}=-0.669173<0,\\\Psi _{\gamma }^{\mathrm {\mathcal {R}} _{0}}&={\frac {a_{1}a_{2}r\left(-\alpha \beta {-}(\beta {+\gamma })^{2}+\alpha r\right)}{A_{1}A_{2}(\gamma {+}r)^{2}(\alpha {+\beta }+\gamma )^{2}}}-{\frac {a_{1}a_{2}r(\beta {+\gamma })}{A_{1}^{2}A_{2}(\gamma {+}r)(\alpha {+\beta }+\gamma )}}\\&\quad -{\frac {a_{1}a_{2}r(\beta {+\gamma })}{A_{1}A_{2}^{2}(\gamma {+}r)(\alpha {+\beta }+\gamma )}}=-0.312737<0,\end{aligned}}}$

(28)

As shown in the previous calculations, some component of the sensitivity indicator are positive, like ${\displaystyle r}$, ${\displaystyle a_{1}}$, ${\displaystyle a_{2}}$ and ${\displaystyle \beta }$, while others, like ${\displaystyle a_{3}}$, ${\displaystyle \alpha }$, ${\displaystyle \gamma }$ and ${\displaystyle \eta }$ are negative. Furthermore, the most important feature of these indicators is the functionality of the SPEIR model parameters. This means that getting a small amendment in one of the parameters will amendment the epidemic dynamics. The value ${\displaystyle \Psi _{a_{3}}^{\mathrm {\mathcal {R}} _{0}}=-0.300752}$ displays that decreasing (increasing) ${\displaystyle a_{3}}$ for example by 70% increases (decreases) the basic reproductive number ${\displaystyle \mathrm {\mathcal {R}} _{0}}$ by about 70% A small change in a parameter can head to comparatively enormous quantitative changes, requiring these sensitive parameters to be understood. It can be shown from previous calculations that parameters ${\displaystyle a_{1}}$ (disease progression diversion rate for Latent Compartmentenglish) and ${\displaystyle \eta }$ (rate of roguingenglish) are, respectively, the maximum and minimum sensitivity epidemical parameters ${\displaystyle \mathrm {\mathcal {R}} _{0}}$.

4. Achieve existence and uniqueness

In this section, we will prove that model 4 has a unique solution, that the kernel satisfies Lipschitz's condition and that the functions in this model is bounded.

Now, we will analyze the fractional model (Eq.(1)). Usage of an integral fractional operator on Eq. (1), we are gaining

${\displaystyle S_{1}\left(t\right)-S_{1}\left(0\right)={\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\varrho _{1}\left(t,S_{1}\right)+{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}\varrho _{1}\left(\theta ,S_{1}\right)d\theta ,}$ ${\displaystyle P_{1}\left(t\right)-P_{1}\left(0\right)={\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\varrho _{2}\left(t,P_{1}\right)+{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}\varrho _{2}\left(\theta ,P_{1}\right)d\theta ,}$ ${\displaystyle E_{1}\left(t\right)-E_{1}\left(0\right)={\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\varrho _{3}\left(t,E_{1}\right)+{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}\varrho _{3}\left(\theta ,E_{1}\right)d\theta ,}$ (29) ${\displaystyle I_{1}\left(t\right)-I_{1}\left(0\right)={\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\varrho _{4}\left(t,I_{1}\right)+{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}\varrho _{4}\left(\theta ,I_{1}\right)d\theta ,}$ ${\displaystyle R_{1}\left(t\right)-R_{1}\left(0\right)={\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\varrho _{5}\left(t,R_{1}\right)+{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}\varrho _{5}\left(\theta ,R_{1}\right)d\theta ,}$

where

${\displaystyle {\begin{cases}\varrho _{1}\left(t,S_{1}\right)=r(M-N)-\gamma S_{1}\left(t\right)-{\frac {a_{1}}{M}}S_{1}\left(t\right)I_{1}\left(t\right)-\alpha S_{1}\left(t\right)+\beta P_{1}\left(t\right),\\\varrho _{2}\left(t,P_{1}\right)=\alpha S_{1}\left(t\right)+\beta P_{1}\left(t\right)-\gamma P_{1}\left(t\right),\\\varrho _{3}\left(t,E_{1}\right)={\frac {a_{1}}{M}}S_{1}\left(t\right)I_{1}\left(t\right)-\left(\gamma {+}a_{2}+b_{1}\right)E_{1}\left(t\right),\\\varrho _{4}\left(t,I_{1}\right)=a_{2}E_{1}\left(t\right)-\left(\gamma {+}a_{3}+b_{2}+\eta \right)I_{1}\left(t\right),\\\varrho _{5}\left(t,R_{1}\right)=a_{3}I_{1}\left(t\right)-\left(\gamma {+}b_{3}\right)R_{1}\left(t\right).\end{cases}}}$

(30)

When ${\displaystyle S_{1}\left(t\right)}$ has an upper limit, the Lipschitz condition for the ${\displaystyle \varrho _{1}\left(t,S_{1}\right)}$ will be fulfilled. So, if ${\displaystyle S_{1}\left(t\right)}$ has an upper limit, we find that

${\displaystyle {\begin{aligned}\left\Vert \varrho _{1}\left(t,S_{1}\right)-\varrho _{1}\left(t,{\tilde {S_{1}}}\right)\right\Vert &=\left\Vert -\gamma \left(S_{1}-{\tilde {S_{1}}}\right)-{\frac {a_{1}I_{1}}{M}}\left(S_{1}-{\tilde {S_{1}}}\right)-\alpha \left(S_{1}-{\tilde {S_{1}}}\right)\right\Vert \\&\leq \gamma \left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert +{\frac {a_{1}\phi }{M}}\left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert +\alpha \left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert \\&\leq \left\{\gamma +{\frac {a_{1}\phi }{M}}+\alpha \right\}\left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert ,\end{aligned}}}$

(31)

that is ${\displaystyle \left\Vert S_{1}\right\Vert \leq c_{1}}$ and ${\displaystyle \left\Vert {\tilde {S_{1}}}\right\Vert \leq c_{2}}$, where ${\displaystyle S_{1}}$ and ${\displaystyle {\tilde {S_{1}}}}$ are bounded functions and ${\displaystyle \phi =max\left\Vert I_{1}\right\Vert }$. We have that,

${\displaystyle \left\Vert \varrho _{1}\left(t,S_{1}\right)-\varrho _{1}\left(t,{\tilde {S_{1}}}\right)\right\Vert \leq X_{S_{1}}\left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert ,}$

similarly, we obtain the other kernels as following

${\displaystyle \left\Vert \varrho _{2}\left(t,P_{1}\right)-\varrho _{2}\left(t,{\tilde {P_{1}}}\right)\right\Vert \leq X_{P_{1}}\left\Vert P_{1}-{\tilde {P_{1}}}\right\Vert ,}$ (32) ${\displaystyle \left\Vert \varrho _{3}\left(t,E_{1}\right)-\varrho _{3}\left(t,{\tilde {E_{1}}}\right)\right\Vert \leq X_{E_{1}}\left\Vert E_{1}-{\tilde {E_{1}}}\right\Vert ,}$ (33) ${\displaystyle \left\Vert \varrho _{4}\left(t,I_{1}\right)-\varrho _{4}\left(t,{\tilde {I_{1}}}\right)\right\Vert \leq X_{I_{1}}\left\Vert I_{1}-{\tilde {I_{1}}}\right\Vert ,}$ (34) ${\displaystyle \left\Vert \varrho _{5}\left(t,R_{1}\right)-\varrho _{5}\left(t,{\tilde {R_{1}}}\right)\right\Vert \leq X_{R_{1}}\left\Vert R_{1}-{\tilde {R_{1}}}\right\Vert ,}$ (35)

where

${\displaystyle {\begin{aligned}X_{S_{1}}&=\gamma +{\frac {a_{1}\phi }{M}}+\alpha ,\\X_{P_{1}}&=\beta {+\gamma },\\X_{E_{1}}&=\gamma {+}a_{2}+b_{1},\\X_{I_{1}}&=\gamma {+}a_{3}+b_{2}+\eta ,\\X_{R_{1}}&=\gamma {+}b_{3},\end{aligned}}}$

(36)

and ${\displaystyle \left\Vert P_{1}\right\Vert \leq c_{3}}$, ${\displaystyle \left\Vert {\tilde {P_{1}}}\right\Vert \leq c_{4}}$, ${\displaystyle \left\Vert E_{1}\right\Vert \leq c_{5}}$, ${\displaystyle \left\Vert {\tilde {E_{1}}}\right\Vert \leq c_{6}}$, ${\displaystyle \left\Vert I_{1}\right\Vert \leq c_{7}}$, ${\displaystyle \left\Vert {\tilde {I_{1}}}\right\Vert \leq c_{8}}$, ${\displaystyle \left\Vert R_{1}\right\Vert \leq c_{9}}$, ${\displaystyle \left\Vert {\tilde {R_{1}}}\right\Vert \leq c_{10}}$. Hence, for the kernels ${\displaystyle \varrho _{1}\left(t,S_{1}\right)}$, ${\displaystyle \varrho _{2}\left(t,P_{1}\right)}$, ${\displaystyle \varrho _{3}\left(t,E_{1}\right)}$, ${\displaystyle \varrho _{4}\left(t,I_{1}\right)}$ and ${\displaystyle \varrho _{5}\left(t,R_{1}\right)}$, the Lipschitz condition is justified.

Theorem 4.1. Presume that ${\textstyle S_{1}\left(t\right)}$ is obliged, then the operator ${\textstyle \xi \left\{S_{1}\left(t\right)\right\}}$ is supplied by

${\displaystyle \xi \left\{S_{1}\left(t\right)\right\}=S_{1}\left(0\right)+{\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\varrho _{1}\left(t,S_{1}\right)+{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}\varrho _{1}\left(\theta ,S_{1}\right)d\theta ,}$

(37)

satisfies the Lipschitz condition.

Proof. Assume that ${\displaystyle S_{1}\left(t\right)}$ and ${\displaystyle {\tilde {S_{1}}}\left(t\right)}$ are bounded functions with ${\textstyle S_{1}\left(0\right)={\tilde {S_{1}}}\left(0\right)}$, then we have

${\displaystyle {\begin{aligned}\left\Vert \xi \left\{S_{1}\left(t\right)\right\}-\xi \left\{{\tilde {S_{1}}}\left(t\right)\right\}\right\Vert &=\left\Vert {\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\left(\varrho _{1}\left(t,S_{1}\right)-\varrho _{1}\left(t,{\tilde {S_{1}}}\right)\right)+{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}\left(\varrho _{1}\left(\theta ,S_{1}\right)-\varrho _{1}\left(\theta ,{\tilde {S_{1}}}\right)\right)d\theta \right\Vert \\&\leq {\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\left\Vert \varrho _{1}\left(t,S_{1}\right)-\varrho _{1}\left(t,{\tilde {S_{1}}}\right)\right\Vert +{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}\left\Vert \varrho _{1}\left(\theta ,S_{1}\right)-\varrho _{1}\left(\theta ,{\tilde {S_{1}}}\right)\right\Vert d\theta \\&\leq \left({\frac {1-\upsilon }{\chi \left(\upsilon \right)}}X_{S_{1}}-{\frac {X_{S_{1}}t^{\upsilon }}{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\right)\left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert .\end{aligned}}}$

(38)

This completes the proof. The same process can be applied to ${\textstyle P_{1}\left(t\right)}$, ${\textstyle E_{1}\left(t\right)}$, ${\textstyle I_{1}\left(t\right)}$ and ${\textstyle R_{1}\left(t\right)}$.

Theorem 4.2. If ${\textstyle S_{1}\left(t\right)}$ is a bounded, then the operator

${\displaystyle \xi _{1}\left\{S_{1}\left(t\right)\right\}=r(M-N)-\gamma S_{1}\left(t\right)-{\frac {a_{1}}{M}}S_{1}\left(t\right)I_{1}\left(t\right)-\alpha S_{1}\left(t\right)+\beta P_{1}\left(t\right),}$

(39)

satisfies

(i)  

${\displaystyle \left|\left\langle \xi _{1}\left(S_{1}\right)-\xi _{1}\left({\tilde {S_{1}}}\right),S_{1}-{\tilde {S_{1}}}\right\rangle \right|\leq X_{S_{1}}\left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert ^{2},}$

(40)

where ${\textstyle \langle {.},.\rangle }$ is the inner product space bounded in ${\textstyle {\mathcal {L}}^{2}}$.

(ii)

${\displaystyle \left|\left\langle \xi _{1}\left(S_{1}\right)-\xi _{1}\left({\tilde {S_{1}}}\right),D\right\rangle \right|\leq X_{S_{1}}\left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert \left\Vert D\right\Vert ,0<\left\Vert D\right\Vert <\infty {.}}$

(41)

Proof${\displaystyle \;}$(i). Suppose that ${\displaystyle S_{1}\left(t\right)}$ is bounded function, then

${\displaystyle {\begin{aligned}\left|\left\langle \xi _{1}\left(S_{1}\right)-\xi _{1}\left({\tilde {S_{1}}}\right),S_{1}-{\tilde {S_{1}}}\right\rangle \right|&=\left|\left\langle -\gamma \left(S_{1}-{\tilde {S_{1}}}\right)-{\frac {a_{1}I_{1}}{M}}\left(S_{1}-{\tilde {S_{1}}}\right)-\alpha \left(S_{1}-{\tilde {S_{1}}}\right),S_{1}-{\tilde {S_{1}}}\right\rangle \right|\\&\leq \left|\left\langle \gamma \left(S_{1}-{\tilde {S_{1}}}\right),S_{1}-{\tilde {S_{1}}}\right\rangle \right|+\left|\left\langle {\frac {a_{1}I_{1}}{M}}\left(S_{1}-{\tilde {S_{1}}}\right),S_{1}-{\tilde {S_{1}}}\right\rangle \right|+\left|\left\langle \alpha \left(S_{1}-{\tilde {S_{1}}}\right),S_{1}-{\tilde {S_{1}}}\right\rangle \right|\\&\leq \gamma \left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert \left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert +{\frac {a_{1}\phi }{M}}\left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert \left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert +\alpha \left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert \left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert \\&\leq \left\{\gamma +{\frac {a_{1}\phi }{M}}+\alpha \right\}\left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert ^{2}\\&\leq X_{S_{1}}\left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert ^{2}.\end{aligned}}}$

(42)

Proof${\displaystyle \;}$(ii). Suppose that ${\textstyle 0<\left\Vert D\right\Vert <\infty }$, since ${\displaystyle S_{1}\left(t\right)}$ is bounded function, so

${\displaystyle {\begin{aligned}\left|\left\langle \xi _{1}\left(S_{1}\right)-\xi _{1}\left({\tilde {S_{1}}}\right),D\right\rangle \right|&=\left|\left\langle -\gamma \left(S_{1}-{\tilde {S_{1}}}\right)-{\frac {a_{1}I_{1}}{M}}\left(S_{1}-{\tilde {S_{1}}}\right)-\alpha \left(S_{1}-{\tilde {S_{1}}}\right),D\right\rangle \right|\\&\leq \left|\left\langle \gamma \left(S_{1}-{\tilde {S_{1}}}\right),D\right\rangle \right|+\left|\left\langle {\frac {a_{1}I_{1}}{M}}\left(S_{1}-{\tilde {S_{1}}}\right),D\right\rangle \right|+\left|\left\langle \alpha \left(S_{1}-{\tilde {S_{1}}}\right),D\right\rangle \right|\\&\leq \gamma \left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert \left\Vert D\right\Vert +{\frac {a_{1}\phi }{M}}\left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert \left\Vert D\right\Vert +\alpha \left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert \left\Vert D\right\Vert \\&\leq \left\{\gamma +{\frac {a_{1}\phi }{M}}+\alpha \right\}\left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert \left\Vert D\right\Vert \\&\leq X_{S_{1}}\left\Vert S_{1}-{\tilde {S_{1}}}\right\Vert \left\Vert D\right\Vert .\end{aligned}}}$

(43)

This completes the proof. The same process can be applied to ${\textstyle P_{1}\left(t\right)}$, ${\textstyle E_{1}\left(t\right)}$, ${\textstyle I_{1}\left(t\right)}$ and ${\textstyle R_{1}\left(t\right)}$.

An inquiry into the existence and uniqueness of Eq.(1) will be discussed in the following. From Eq. (29) we can write

${\displaystyle \left(S_{1}\right)_{n}={\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\varrho _{1}\left(t,\left(S_{1}\right)_{n-1}\right)+{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}\varrho _{1}\left(\theta ,\left(S_{1}\right)_{n-1}\right)d\theta ,\;n=1,2,3,\cdots {.}}$

(44)

The difference of the successive term can be written as

${\displaystyle {\begin{aligned}\Upsilon _{n+1}\left(t\right)&=\left(S_{1}\right)_{n+1}-\left(S_{1}\right)_{n}={\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\left[\varrho _{1}\left(t,\left(S_{1}\right)_{n}\right)-\varrho _{1}\left(t,\left(S_{1}\right)_{n-1}\right)\right]\\&\quad +{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}\left[\varrho _{1}\left(\theta ,\left(S_{1}\right)_{n}\right)-\varrho _{1}\left(\theta ,\left(S_{1}\right)_{n-1}\right)\right]d\theta {.}\end{aligned}}}$

(45)

According to Castillo-Chavez et al. [34], it would be easy to write

${\displaystyle \left(S_{1}\right)_{n+1}={\stackrel {=}{\scriptscriptstyle I_{1}=1}}\Upsilon _{\scriptscriptstyle I_{1}-1}.}$

(46)

Then, from Eq. (45), we get

${\displaystyle \left\Vert \Upsilon _{n+1}\left(t\right)\right\Vert =\left\Vert \left(S_{1}\right)_{n+1}-\left(S_{1}\right)_{n}\right\Vert =\left\Vert {\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\left[\varrho _{1}\left(t,\left(S_{1}\right)_{n}\right)-\varrho _{1}\left(t,\left(S_{1}\right)_{n-1}\right)\right]\right\Vert .}$${\displaystyle \left\Vert .+{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}\left[\varrho _{1}\left(\theta ,\left(S_{1}\right)_{n}\right)-\varrho _{1}\left(\theta ,\left(S_{1}\right)_{n-1}\right)\right]d\theta \right\Vert .}$

(47)

By triangular inequality, the above Eq. turn into

${\displaystyle \left\Vert \Upsilon _{n+1}\left(t\right)\right\Vert \leq {\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\left\Vert \varrho _{1}\left(t,\left(S_{1}\right)_{n}\right)-\varrho _{1}\left(t,\left(S_{1}\right)_{n-1}\right)\right\Vert }$${\displaystyle +{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}\left\Vert \varrho _{1}\left(\theta ,\left(S_{1}\right)_{n}\right)-\varrho _{1}\left(\theta ,\left(S_{1}\right)_{n-1}\right)\right\Vert d\theta {.}}$

(48)

Whereas, the kernel fulfilled the Lipschitz condition. we have

${\displaystyle \left\Vert \Upsilon _{n+1}\left(t\right)\right\Vert \leq {\frac {1-\upsilon }{\chi \left(\upsilon \right)}}X_{S_{1}}\left\Vert \left(S_{1}\right)_{n}-\left(S_{1}\right)_{n-1}\right\Vert }$${\displaystyle +{\frac {\upsilon X_{S_{1}}}{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}\left\Vert \left(S_{1}\right)_{n}-\left(S_{1}\right)_{n-1}\right\Vert d\theta {.}}$

(49)

Theorem 4.3. If ${\textstyle t_{0}}$ fits the following condition

${\displaystyle {\frac {1-\upsilon }{\chi \left(\upsilon \right)}}X_{S_{1}}+{\frac {X_{S_{1}}t_{0}^{\upsilon }}{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\leq {1},}$

(50)

then, model (Eq.(1)) has a unique solution.

Proof. Suppose that ${\textstyle S_{1}(t)}$ is bounded. As the Lipschitz condition is fulfilled by the kernel, therefore, utilizing the recursive process of Eq. (49), we acquire

${\displaystyle \left\Vert \Upsilon _{n+1}\left(t\right)\right\Vert \leq \left\{{\frac {1-\upsilon }{\chi \left(\upsilon \right)}}X_{S_{1}}+{\frac {\upsilon X_{S_{1}}t_{0}^{\upsilon }}{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\right\}^{n+1}\left\Vert S_{1}\left(0\right)\right\Vert .}$

Therefore, the ${\textstyle S_{1}(t)}$ function offered by Eq. (46) exists and is smooth as well. Currently, we wish to illustrate that the above-mentioned functions are actually a solution to englishmodel (Eq.(1)). Presume that

${\displaystyle S_{1}(t)-S_{1}(0)=\left(S_{1}\right)_{n}-\left({\overline {S_{1}}}\right)_{n}}$

(51)

So that,

${\displaystyle {\begin{aligned}\left\Vert \left({\overline {S_{1}}}\right)_{n}\right\Vert &=\left\Vert {\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\left[\varrho _{1}\left(t,S_{1}\right)-\varrho _{1}\left(t,\left(S_{1}\right)_{n}\right)\right]+{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}\left[\varrho _{1}\left(\theta ,S_{1}\right)-\varrho _{1}\left(\theta ,\left(S_{1}\right)_{n}\right)\right]d\theta \right\Vert \\&\leq {\frac {1-\upsilon }{\chi \left(\upsilon \right)}}{\Bigl \Vert }\varrho _{1}\left(t,S_{1}\right)-\varrho _{1}\left(t,\left(S_{1}\right)_{n}\right){\Bigr \Vert }+{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}{\Bigl \Vert }\varrho _{1}\left(\theta ,S_{1}\right)-\varrho _{1}\left(\theta ,\left(S_{1}\right)_{n}\right){\Bigr \Vert }d\theta \\&\leq {\frac {1-\upsilon }{\chi \left(\upsilon \right)}}X_{S_{1}}\left\Vert S_{1}-\left(S_{1}\right)_{n}\right\Vert +{\frac {\upsilon X_{S_{1}}t^{\upsilon }}{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left\Vert S_{1}-\left(S_{1}\right)_{n}\right\Vert .\end{aligned}}}$

(52)

Using the recursive approach once more, we get

${\displaystyle \left\Vert \left({\overline {S_{1}}}\right)_{n}\right\Vert \leq \left\{{\frac {1-\upsilon }{\chi \left(\upsilon \right)}}+{\frac {\upsilon t^{\upsilon }}{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\right\}^{n+2}X_{S_{1}}^{n+2}.}$

(53)

If ${\textstyle t=t_{0}}$, we get

${\displaystyle \left\Vert \left({\overline {S_{1}}}\right)_{n}\right\Vert \leq \left\{{\frac {1-\upsilon }{\chi \left(\upsilon \right)}}+{\frac {\upsilon t_{0}^{\upsilon }}{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\right\}^{n+2}X_{S_{1}}^{n+2}.}$

(54)

Using the limit in Eq. (54) as ${\textstyle n}$ gets closer to ${\textstyle \infty }$ , we arrive at ${\textstyle \left\Vert \left({\overline {S_{1}}}\right)_{n}\right\Vert \rightarrow {0}}$. Thus, the existence is demonstrated. It is still necessary to demonstrate the uniqueness of the model english (Eq.(1)). Assume that ${\textstyle {\tilde {S_{1}}}\left(t\right)}$ is another solution of model (Eq.(1)), then

${\displaystyle S_{1}\left(t\right)-{\tilde {S_{1}}}\left(t\right)={\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\left[\varrho _{1}\left(t,S_{1}\right)-\varrho _{1}\left(t,{\tilde {S_{1}}}\right)\right]}$${\displaystyle +{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}\left[\varrho _{1}\left(\theta ,S_{1}\right)-\varrho _{1}\left(\theta ,{\tilde {S_{1}}}\right)\right]d\theta {.}}$

(55)

Using the norm for Eq. (55), we get

${\displaystyle \left\Vert S_{1}\left(t\right)-{\tilde {S_{1}}}\left(t\right)\right\Vert \leq {\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\left\Vert \varrho _{1}\left(t,S_{1}\right)-\varrho _{1}\left(t,{\tilde {S_{1}}}\right)\right\Vert }$${\displaystyle +{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}\left\Vert \varrho _{1}\left(\theta ,S_{1}\right)-\varrho _{1}\left(\theta ,{\tilde {S_{1}}}\right)\right\Vert d\theta {.}}$

(56)

Because the kernel fulfills the Lipschitz condition, thus we may write

${\displaystyle \left\Vert S_{1}\left(t\right)-{\tilde {S_{1}}}\left(t\right)\right\Vert \leq {\frac {1-\upsilon }{\chi \left(\upsilon \right)}}X_{S_{1}}\left\Vert S_{1}\left(t\right)-{\tilde {S_{1}}}\left(t\right)\right\Vert }$${\displaystyle +{\frac {\upsilon X_{S_{1}}}{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t-\theta \right)^{\upsilon {-1}}\left\Vert S_{1}\left(t\right)-{\tilde {S_{1}}}\left(t\right)\right\Vert d\theta {.}}$

(57)

Consequently,

${\displaystyle \left\Vert S_{1}\left(t\right)-{\tilde {S_{1}}}\left(t\right)\right\Vert \left(1-{\frac {1-\upsilon }{\chi \left(\upsilon \right)}}X_{S_{1}}-{\frac {X_{S_{1}}t_{0}^{\upsilon }}{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\right)\leq 0.}$

(58)

If

${\displaystyle \left(1-{\frac {1-\upsilon }{\chi \left(\upsilon \right)}}X_{S_{1}}-{\frac {X_{S_{1}}t_{0}^{\upsilon }}{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\right)\geq 0,}$

(59)

then,

${\displaystyle \left\Vert S_{1}\left(t\right)-{\tilde {S_{1}}}\left(t\right)\right\Vert =0,\qquad S_{1}\left(t\right)-{\tilde {S_{1}}}\left(t\right)=0,\qquad S_{1}\left(t\right)={\tilde {S_{1}}}\left(t\right).}$

(60)

Thus, the uniqueness is verified. We can prove the uniqueness of the rest of equations in model (Eq.(1)) by using the same method. Therefore model has a unique solution (Eq.(1)).

5. Numerical algorithm with ABC fractional derivative

It is not possible to solve various real and physical applications developed using fractional PDEs accurately. However, a numerical approach to the solution is always enough to take care of a problem in engineering and science. For the Adams-Bashforth-Moulton technique, it can be used here to score a solution. Compared to the RK4, ABMM offers many noteworthy benefits, due to the fact that RK4 calculates four function evaluations per integration step while ABMM only calculates two [42]. As a result of the wider interpolation interval, Adams-Moulton methods produce more precise approximations. Generally speaking, implicit procedures are more stable than their explicit counterparts and they also achieve a greater order with the same number of preceding steps. Naturally, its implicit nature makes it challenging to solve because it results in a non-linear equation.

In this part, we discuss the plant diseases model known as the SPEIR model with the Atangana-Baleanu fractional operator to show the effectiveness, excellence and generality of our approach. All analytical and numerical analyses were detailed throughout the time spent computation using the MATLAB software package.

Taking into account the following fractional differential equation

${\displaystyle {\begin{cases}^{ABC}D_{t}^{\upsilon }\varphi \left(t\right)={\mathcal {F}}\left(t,\varphi \left(t\right)\right),\\\varphi \left(0\right)=\varphi _{0}.\end{cases}}}$

(61)

We apply the basic calculus theorem in order to transform the Eq. (61) to

${\displaystyle \varphi \left(t\right)-\varphi \left(0\right)={\frac {1-\upsilon }{\chi \left(\upsilon \right)}}{\mathcal {F}}\left(t,\varphi \left(t\right)\right)+{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}{\mathcal {F}}\left(\chi ,\varphi \left(\chi \right)\right)\left(t-\chi \right)^{\upsilon {-1}}d\chi ,}$

(62)

at ${\textstyle t=t_{n+1},n=1,2,\cdots ,}$ we find that

${\displaystyle \varphi \left(t_{n+1}\right)-\varphi \left(0\right)={\frac {1-\upsilon }{\chi \left(\upsilon \right)}}{\mathcal {F}}\left(t_{n},\varphi _{n}\right)+{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}{\mathcal {F}}\left(t,\varphi \left(t\right)\right)\left(t_{n+1}-t\right)^{\upsilon {-1}}dt,}$

(63)

and at ${\textstyle t=t_{n}}$, we have

${\displaystyle \varphi \left(t_{n}\right)-\varphi \left(0\right)={\frac {1-\upsilon }{\chi \left(\upsilon \right)}}{\mathcal {F}}\left(t_{n-1},\varphi _{n-1}\right)+{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}{\mathcal {F}}\left(t,\varphi \left(t\right)\right)\left(t_{n}-t\right)^{\upsilon {-1}}dt.}$

(64)

The result of subtracting (64) from (63) is as follows

${\displaystyle {\begin{aligned}\varphi \left(t_{n+1}\right)-\varphi \left(t_{n}\right)&={\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\left\{{\mathcal {F}}\left(t_{n},\varphi _{n}\right)-{\mathcal {F}}\left(t_{n-1},\varphi _{n-1}\right)\right\}\\&\quad +{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}{\mathcal {F}}\left(t,\varphi \left(t\right)\right)\left(t_{n+1}-t\right)^{\upsilon {-1}}dt\\&\quad -{\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}{\mathcal {F}}\left(t,\varphi \left(t\right)\right)\left(t_{n}-t\right)^{\upsilon {-1}}dt\end{aligned}}}$

(65)

Consequently,

${\displaystyle \varphi \left(t_{n+1}\right)-\varphi \left(t_{n}\right)={\frac {1-\upsilon }{\chi \left(\upsilon \right)}}\left\{{\mathcal {F}}\left(t_{n},\varphi _{n}\right)-{\mathcal {F}}\left(t_{n-1},\varphi _{n-1}\right)\right\}+{\mathcal {A}}_{\upsilon }-{\mathcal {B}}_{\upsilon },}$

(66)

where

${\displaystyle {\mathcal {A}}_{\upsilon }={\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}{\mathcal {F}}\left(t,\varphi \left(t\right)\right)\left(t_{n+1}-t\right)^{\upsilon {-1}}dt,}$

(67)

and

${\displaystyle {\mathcal {B}}_{\upsilon }={\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}{\mathcal {F}}\left(t,\varphi \left(t\right)\right)\left(t_{n}-t\right)^{\upsilon {-1}}dt.}$

(68)

Then, we have

${\displaystyle {\begin{aligned}{\mathcal {A}}_{\upsilon }&={\frac {\upsilon }{\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t_{n+1}-t\right)^{\upsilon {-1}}\left\{{\frac {t-t_{n-1}}{h}}{\mathcal {F}}\left(t_{n},\varphi _{n}\right)-{\frac {t-t_{n}}{h}}{\mathcal {F}}\left(t_{n},\varphi _{n}\right)\right\}dt\\&={\frac {\upsilon {\mathcal {F}}\left(t_{n},\varphi _{n}\right)}{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t_{n+1}-t\right)^{\upsilon {-1}}{\mathcal {F}}\left(t-t_{n-1}\right)dt\\&\quad -{\frac {\upsilon {\mathcal {F}}\left(t_{n-1},\varphi _{n-1}\right)}{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}{\stackrel {=}{0}}\left(t_{n+1}-t\right)^{\upsilon {-1}}{\mathcal {F}}\left(t-t_{n-1}\right)dt\\&={\frac {\upsilon {\mathcal {F}}\left(t_{n},\varphi _{n}\right)}{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left\{{\frac {2ht_{n+1}^{\upsilon }}{\upsilon }}-{\frac {t_{n+1}^{\upsilon {+1}}}{\upsilon {+1}}}\right\}-{\frac {\upsilon {\mathcal {F}}\left(t_{n-1},\varphi _{n-1}\right)}{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left\{{\frac {ht_{n+1}^{\upsilon }}{\upsilon }}-{\frac {t_{n+1}^{\upsilon {+1}}}{\upsilon {+1}}}\right\}.\end{aligned}}}$

(69)

likewise, we obtain

${\displaystyle {\mathcal {B}}_{\upsilon }={\frac {\upsilon {\mathcal {F}}\left(t_{n},\varphi _{n}\right)}{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left\{{\frac {ht_{n}^{\upsilon }}{\upsilon }}-{\frac {t_{n}^{\upsilon {+1}}}{\upsilon {+1}}}\right\}-{\frac {\upsilon {\mathcal {F}}\left(t_{n-1},\varphi _{n-1}\right)}{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}.}$

(70)

The analytical solution is thus given as

${\displaystyle {\begin{aligned}\varphi \left(t_{n+1}\right)&=\varphi \left(t_{n}\right)+{\mathcal {F}}\left(t_{n},\varphi _{n}\right)\left\{{\frac {1-\upsilon }{\chi \left(\upsilon \right)}}+{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {2ht_{n+1}^{\upsilon }}{\upsilon }}-{\frac {t_{n+1}^{\upsilon {+1}}}{\upsilon {+1}}}\right]-{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {ht_{n}^{\upsilon }}{\upsilon }}-{\frac {t_{n}^{\upsilon {+1}}}{\upsilon {+1}}}\right]\right\}\\&\quad +{\mathcal {F}}\left(t_{n-1},\varphi _{n-1}\right)\left\{{\frac {\upsilon {-1}}{\chi \left(\upsilon \right)}}-{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {ht_{n+1}^{\upsilon }}{\upsilon }}-{\frac {t_{n+1}^{\upsilon {+1}}}{\upsilon {+1}}}+{\frac {t_{n}^{\upsilon {+1}}}{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\right]\right\}.\end{aligned}}}$

(71)

Therefore, the model's solution (Eq.(1)) is

${\displaystyle {\begin{aligned}\left(S_{1}\right)_{n+1}&=\left(S_{1}\right)_{n}+\left\{{\frac {1-\upsilon }{\chi \left(\upsilon \right)}}+{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {2ht_{n+1}^{\upsilon }}{\upsilon }}-{\frac {t_{n+1}^{\upsilon {+1}}}{\upsilon {+1}}}\right]-{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {ht_{n}^{\upsilon }}{\upsilon }}-{\frac {t_{n}^{\upsilon {+1}}}{\upsilon {+1}}}\right]\right\}\\&\quad \left\{r(M-N)-\left(S_{1}\right)_{n}\left(t_{n}\right)\left(\gamma -{\frac {a_{1}}{M}}\left(I_{1}\right)_{n}\left(t_{n}\right)-\alpha \right)+\beta \left(P_{1}\right)_{n}\left(t_{n}\right)\right\}\\&\quad +\left\{{\frac {\upsilon {-1}}{\chi \left(\upsilon \right)}}-{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {ht_{n+1}^{\upsilon }}{\upsilon }}-{\frac {t_{n+1}^{\upsilon {+1}}}{\upsilon {+1}}}+{\frac {t_{n}^{\upsilon {+1}}}{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\right]\right\}\\&\quad \left\{r(M-N)-\left(S_{1}\right)_{n-1}\left(t_{n-1}\right)\left(\gamma -{\frac {a_{1}}{M}}\left(I_{1}\right)_{n-1}\left(t_{n-1}\right)-\alpha \right)+\beta \left(P_{1}\right)_{n-1}\left(t_{n-1}\right)\right\},\end{aligned}}}$

(72)

${\displaystyle {\begin{aligned}\left(P_{1}\right)_{n+1}&=\left(P_{1}\right)_{n}+\left\{{\frac {1-\upsilon }{\chi \left(\upsilon \right)}}+{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {2ht_{n+1}^{\upsilon }}{\upsilon }}-{\frac {t_{n+1}^{\upsilon {+1}}}{\upsilon {+1}}}\right]-{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {ht_{n}^{\upsilon }}{\upsilon }}-{\frac {t_{n}^{\upsilon {+1}}}{\upsilon {+1}}}\right]\right\}\\&\quad \left\{\alpha \left(S_{1}\right)_{n}\left(t_{n}\right)+\left(P_{1}\right)_{n}\left(t_{n}\right)\left(\beta {-\gamma }\right)\right\}\\&\quad +\left\{{\frac {\upsilon {-1}}{\chi \left(\upsilon \right)}}-{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {ht_{n+1}^{\upsilon }}{\upsilon }}-{\frac {t_{n+1}^{\upsilon {+1}}}{\upsilon {+1}}}+{\frac {t_{n}^{\upsilon {+1}}}{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\right]\right\}\\&\quad \left\{\alpha \left(S_{1}\right)_{n-1}\left(t_{n-1}\right)+\left(P_{1}\right)_{n-1}\left(t_{n-1}\right)\left(\beta {-\gamma }\right)\right\},\end{aligned}}}$

(73)

${\displaystyle {\begin{aligned}\left(E_{1}\right)_{n+1}&=\left(E_{1}\right)_{n}+\left\{{\frac {1-\upsilon }{\chi \left(\upsilon \right)}}+{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {2ht_{n+1}^{\upsilon }}{\upsilon }}-{\frac {t_{n+1}^{\upsilon {+1}}}{\upsilon {+1}}}\right]-{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {ht_{n}^{\upsilon }}{\upsilon }}-{\frac {t_{n}^{\upsilon {+1}}}{\upsilon {+1}}}\right]\right\}\\&\quad \left\{{\frac {a_{1}}{M}}\left(S_{1}\right)_{n}\left(t_{n}\right)\left(I_{1}\right)_{n}\left(t_{n}\right)-\left(\gamma +a_{2}+b_{1}\right)\left(E_{1}\right)_{n}\left(t_{n}\right)\right\}\\&\quad +\left\{{\frac {\upsilon {-1}}{\chi \left(\upsilon \right)}}-{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {ht_{n+1}^{\upsilon }}{\upsilon }}-{\frac {t_{n+1}^{\upsilon {+1}}}{\upsilon {+1}}}+{\frac {t_{n}^{\upsilon {+1}}}{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\right]\right\}\\&\quad \left\{{\frac {a_{1}}{M}}\left(S_{1}\right)_{n-1}\left(t_{n-1}\right)\left(I_{1}\right)_{n-1}\left(t_{n-1}\right)-\left(\gamma {+}a_{2}+b_{1}\right)\left(E_{1}\right)_{n-1}\left(t_{n-1}\right)\right\},\end{aligned}}}$

(74)

${\displaystyle {\begin{aligned}\left(I_{1}\right)_{n+1}&=\left(I_{1}\right)_{n}+\left\{{\frac {1-\upsilon }{\chi \left(\upsilon \right)}}+{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {2ht_{n+1}^{\upsilon }}{\upsilon }}-{\frac {t_{n+1}^{\upsilon {+1}}}{\upsilon {+1}}}\right]-{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {ht_{n}^{\upsilon }}{\upsilon }}-{\frac {t_{n}^{\upsilon {+1}}}{\upsilon {+1}}}\right]\right\}\\&\quad \left\{a_{2}\left(E_{1}\right)_{n}\left(t_{n}\right)-\left(\gamma {+}a_{3}+b_{2}+\eta \right)\left(I_{1}\right)_{n}\left(t_{n}\right)\right\}\\&\quad +\left\{{\frac {\upsilon {-1}}{\chi \left(\upsilon \right)}}-{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {ht_{n+1}^{\upsilon }}{\upsilon }}-{\frac {t_{n+1}^{\upsilon {+1}}}{\upsilon {+1}}}+{\frac {t_{n}^{\upsilon {+1}}}{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\right]\right\}\\&\quad \left\{a_{2}\left(E_{1}\right)_{n-1}\left(t_{n-1}\right)-\left(\gamma {+}a_{3}+b_{2}+\eta \right)\left(I_{1}\right)_{n-1}\left(t_{n-1}\right)\right\},\end{aligned}}}$

(75)

${\displaystyle {\begin{aligned}\left(R_{1}\right)_{n+1}&=\left(R_{1}\right)_{n}+\left\{{\frac {1-\upsilon }{\chi \left(\upsilon \right)}}+{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {2ht_{n+1}^{\upsilon }}{\upsilon }}-{\frac {t_{n+1}^{\upsilon {+1}}}{\upsilon {+1}}}\right]-{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {ht_{n}^{\upsilon }}{\upsilon }}-{\frac {t_{n}^{\upsilon {+1}}}{\upsilon {+1}}}\right]\right\}\\&\quad \left\{a_{3}\left(I_{1}\right)_{n}\left(t_{n}\right)-\left(\gamma {+}b_{3}\right)\left(R_{1}\right)_{n}\left(t_{n}\right)\right\}\\&\quad +\left\{{\frac {\upsilon {-1}}{\chi \left(\upsilon \right)}}-{\frac {\upsilon }{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\left[{\frac {ht_{n+1}^{\upsilon }}{\upsilon }}-{\frac {t_{n+1}^{\upsilon {+1}}}{\upsilon {+1}}}+{\frac {t_{n}^{\upsilon {+1}}}{h\chi \left(\upsilon \right)\lambda \left(\upsilon \right)}}\right]\right\}\\&\quad \left\{a_{3}\left(I_{1}\right)_{n-1}\left(t_{n-1}\right)-\left(\gamma {+}b_{3}\right)\left(R_{1}\right)_{n-1}\left(t_{n-1}\right)\right\}.\end{aligned}}}$

(76)

6. Numerical simulation and discussion

This section employs the Adams-Bashforth-Moulton technique to numerically dissolve the fractional operator SPEIR model [40,41].

The values of the initial conditions for model (Eq.(1)) are given as follows: ${\textstyle M=1000}$, ${\textstyle S_{1}\left(0\right)=100}$, ${\textstyle P_{1}\left(0\right)=30}$, ${\textstyle E_{1}\left(0\right)=60}$, ${\textstyle I_{1}\left(0\right)=60}$ and ${\textstyle R_{1}\left(0\right)=60}$. The parameter values applied in the mathematical simulation were extracted from the classical case of the model as shown in Table 1 [8,9]. The outcomes of the numerical simulation of the SPEIR model are shown in the paragraphs that follow (with and without control).

Parameter	${\displaystyle a_{1}}$	${\displaystyle a_{2}}$	${\displaystyle a_{3}}$	${\displaystyle b_{1}}$	${\displaystyle b_{2}}$	${\displaystyle b_{3}}$	${\displaystyle r}$	${\displaystyle \alpha }$	${\displaystyle \beta }$	${\displaystyle \gamma }$	${\displaystyle \eta }$
Value (${\textstyle \mathrm {\mathcal {R}} _{0}<1}$)	0.06	0.17	0.04	0	0	0.01	0.011	0.0052	0.048	0.004	0.089
Value (${\textstyle \mathrm {\mathcal {R}} _{0}>1}$)	0.3	0.17	0.02	0	0	0.01	0.013	0.0052	0.048	0.0008	0.087

Figure 1 shows the numerical simulation of plant compartments Susceptible ${\textstyle S_{1}\left(t\right)}$, Protected ${\textstyle P_{1}\left(t\right)}$ and Latent ${\textstyle E_{1}\left(t\right)}$ with time history for various values of fractional order at ${\textstyle \mathrm {\mathcal {R}} _{0}<1}$ and ${\textstyle \mathrm {\mathcal {R}} _{0}>1}$. Figures 1(a) and 1(b) show that the maximum value of ${\textstyle S_{1}(t)}$ decreases whether ${\textstyle \mathrm {\mathcal {R}} _{0}<1}$ and ${\textstyle \mathrm {\mathcal {R}} _{0}>1}$, as the time increases and the fractional-order decreases. Figures 1(c) and 1(d) show that ${\textstyle P_{1}(t)}$ decreases as the fractional order decreases and on a big difference between the situation when ${\textstyle \mathrm {\mathcal {R}} _{0}<1}$ and ${\textstyle \mathrm {\mathcal {R}} _{0}>1}$. Figure 1(e) shows that ${\textstyle E_{1}(t)}$ decreases dramatically during the first period with increasing the fractional order until it reaches about 120 days, and then the process reverses after that. While Figure 1(f) shows that ${\textstyle E_{1}(t)}$ is decreasing, but only until 50 days before it starts increasing again.

Figure 1. Numerical simulation of plant compartments ${\displaystyle S_{1}\left(t\right),P_{1}\left(t\right),E_{1}\left(t\right)}$ for various values of fractional order with ${\displaystyle \mathrm {\mathcal {R}} _{0}<1}$ and ${\displaystyle \mathrm {\mathcal {R}} _{0}>1}$

Figure 2 shows the numerical simulation of plant compartments Infected ${\textstyle I_{1}\left(t\right)}$ and Removed ${\textstyle R_{1}\left(t\right)}$ with time history for several values of fractional order at ${\textstyle \mathrm {\mathcal {R}} _{0}<1}$ and ${\textstyle \mathrm {\mathcal {R}} _{0}>1}$. Figure 2(a) shows that ${\textstyle I_{1}(t)}$ initially decreases until close to 150 days with the value of the fractional order differing, and then the process reverses after that. While Figure 2(b) shows that ${\textstyle I_{1}(t)}$ decreases until the period from 60 to 80 days, but its value does not reach zero on the vertical axis, as happened with Figure 2(a).

Figure 2. Numerical simulation of plant compartments ${\displaystyle I_{1}\left(t\right),R_{1}\left(t\right)}$ for various values of fractional order with ${\displaystyle \mathrm {\mathcal {R}} _{0}<1}$ and ${\displaystyle \mathrm {\mathcal {R}} _{0}>1}$

Figure 3 shows the numerical simulation of plant compartments ${\textstyle S_{1}\left(t\right)}$, ${\textstyle P_{1}\left(t\right)}$, ${\textstyle E_{1}\left(t\right)}$, ${\textstyle I_{1}\left(t\right)}$ and ${\textstyle R_{1}\left(t\right)}$ with time history for various values of fractional order at ${\textstyle \mathrm {\mathcal {R}} _{0}<1}$ and ${\textstyle \mathrm {\mathcal {R}} _{0}>1}$.

Figure 3. Numerical simulation of plant compartments ${\displaystyle S_{1}\left(t\right),P_{1}\left(t\right),E_{1}\left(t\right),I_{1}\left(t\right),R_{1}\left(t\right)}$ with ${\displaystyle \mathrm {\mathcal {R}} _{0}<1}$ and ${\displaystyle \mathrm {\mathcal {R}} _{0}>1}$

Figure 4 shows the dynamic compartments of Susceptible and Infected with various roguing and replanting values at ${\textstyle \upsilon =0.85}$. Figures 4(a) and 4(b) show that the maximum value of ${\textstyle S_{1}(t)}$ increases as the rate of replanting decreases and the rate of roguing increases. Figures 4(c) and 4(d) show that infectious can be increased as the rate of replanting decreases and the rate of roguing increases.

Figure 4. Dynamic compartments of Susceptible and Infected with various roguing and replanting values at ${\displaystyle \upsilon =0.85}$

Figures 5 and 6 illustrate the effect of different parameters on plant compartments of americanthe SPEIR model at ${\textstyle \upsilon =0.85}$.

Figure 5. The effect of alteration the values of parameters ${\displaystyle a_{1}}$, ${\displaystyle a_{2}}$, ${\displaystyle b_{1}}$ and ${\displaystyle b_{2}}$ on all compartment stages where the fractional operator ${\displaystyle \upsilon =0.85}$

Figure 6. The effect of alteration the values of parameters ${\displaystyle \alpha }$, ${\displaystyle \beta }$, ${\displaystyle \gamma }$ and ${\displaystyle \eta }$ on all compartment stages where the fractional operator ${\displaystyle \upsilon =0.85}$

7. Conclusion

In this study, we considered and analyzed the SPEIR model displayed the dynamics of plant diseases with the Atangana-Baleanu fractional derivative in Caputo sense. Both the NEE and EE points were analyzed in terms of model equilibria and stability analysis (local-global). We also demonstrated the generic form of ${\textstyle \mathrm {\mathcal {R}} _{0}}$ and the effects of the controls proposed on it. The Adams-Bashforth-Moulton approach was used to study and solve numerical simulations of the suggested model. The value of the fractional order ${\textstyle \upsilon }$ as well as the parameters of the SPEIR model affect the numerical results that are obtained. Because of this, solutions generated by the fractional order model typically converge extremely quickly to real issues.

Conflict of Interest: The author declare that there is no Conflict of Interest.

Acknowledgments

This research project was funded by the Deanship of Scientific Research, Princess Nourah bint Abdulrahman University, through the Program of Research Project Funding After Publication, grant No (43- PRFA-P-19).

References