Degenerate Hopf bifurcation in a Leslie–Gower predator–prey model with predator harvest

Su, Juan

doi:10.1186/s13662-020-02656-3

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Published: 01 May 2020

Degenerate Hopf bifurcation in a Leslie–Gower predator–prey model with predator harvest

Juan Su ORCID: orcid.org/0000-0002-5259-0466¹

Advances in Difference Equations volume 2020, Article number: 194 (2020) Cite this article

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Abstract

In this paper, we investigate the degenerate Hopf bifurcation of a Leslie–Gower predator–prey system with predator harvest. The known work discussed the Hopf bifurcation of this system when the first Lyapunov number does not vanish and gave an example of a stable weak focus with order 2. However, the thorough discussion of center-type equilibrium for all possible parameters has not been completed. In this paper, by computing the first two focal values, we decompose the variety with resultant and prove that the center-type equilibrium is a weak focus with order at most 2 for all the possible parameter values. Moreover, numerical simulations are employed to show the appearance of two limit cycles from degenerate Hopf bifurcation. Our results finish the study of Hopf bifurcation in this system.

1 Introduction

The shortage of natural resources will be a severe problem of the social development in the near future. So how to exploit these resources in a reasonable way is of great importance for the sustainable development. Harvest is commonly practiced in fishery, forestry, and wildlife management. The maximum sustainable yield provides insight into the coexistence of all interacting species. Recently, much attention has been paid to the dynamics of predator–prey models with harvesting, and researchers have been trying to find how harvest affects the population dynamics (see, e.g., [2–4, 6, 16, 17]).

Lotka–Volterra predator–prey model is a pioneer work, which gives much insight into the description of interaction between predators and prey by an ordinary differential system. Since the model neglects some real situation, a number of studies have described the interaction in a more actual way. One of such works is Leslie–Gower predator–prey model [12, 13], which takes the form

$$ \textstyle\begin{cases} \dot{x}=r_{1}x(1-\frac{x}{K})-axy,\\ \dot{y}= r_{2}y(1-\frac{y}{bx}), \end{cases} $$

(1.1)

where $x(t)$, $y(t)$ denote the densities of prey and predators at time t, respectively. It assumes that the prey grows with intrinsic growth rate $r_{1}$ and carrying capacity K in the absence of predation, and ax describes the feeding rate of prey consumption by predators. The predator grows with intrinsic growth rate $r_{2}$ and carrying capacity bx proportional to the population of prey, where b is a measure of the food quality of prey for conversion into predator births. Moreover, $r_{1}$, $r_{2}$, a, b, and K are all positive constants. Hsu and Huang [9] investigated the global stability of system (1.1).

To describe the interaction of krill (prey) and baleen whale (predator) in Southern Ocean, May et al. [14] considered the harvest on system (1.1), i.e.,

$$ \textstyle\begin{cases} \dot{x}=r_{1}x(1-\frac{x}{K})-axy-H_{1}(x),\\ \dot{y}= r_{2}y(1-\frac{y}{bx})-H_{2}(y), \end{cases} $$

(1.2)

where $H_{1}$ and $H_{2}$ represent the harvests on prey and predators, respectively. When both prey and predators are harvested with constant-effort, i.e., $H_{i}(s)=ks$ ($i=1,2$), the maximum sustainable yield was analyzed in [2, 14]. As shown in [10], system (1.2) in this case can be written as the non-harvest form, i.e., system (1.1), so the dynamics of the two systems are similar. When prey are harvested at constant-yield and predators are harvested with constant-effort, i.e., $H_{1}(s)=h_{1}$ and $H_{2}(s)=ks$, respectively, Beddington and Cooke [1] studied the effects of predator harvest on the maximum sustainable yield for prey.

Moreover, the dynamics of system (1.2) are also investigated to see how harvest affects the interaction of prey and predators. When only prey are harvested at constant-yield, i.e., $H_{1}(s)=h_{1}$ and $H_{2}(s)=0$, system (1.2) exhibits rich bifurcation phenomena such as saddle-node bifurcation, degenerate Hopf bifurcations, and Bogdanov–Takens bifurcation [8, 15, 19]. When only predators are harvested at constant-yield, i.e., $H_{1}(s)=0$ and $H_{2}(s)=h_{2}$, Huang et al. [10, 11] investigated the local bifurcations of system (1.2), including saddle-node bifurcation, Hopf bifurcation, and Bogdanov–Takens bifurcation of codimension 2 and 3. Moreover, degenerate Hopf bifurcation was just studied by an example of a stable weak focus with order 2 (see [10, Theorem 3.6]). Thus, the dynamics of the center-type equilibrium is not studied thoroughly for all the parameters.

In this paper, we extend the study of the center-type equilibrium in [10] for all possible parameters and investigate the degenerate Hopf bifurcation of system (1.2) with $H_{1}(s)=0$ and $H_{2}(s)=h_{2}$, i.e.,

$$ \textstyle\begin{cases} \dot{x}=r_{1}x(1-\frac{x}{K})-axy,\\ \dot{y}= r_{2}y(1-\frac{y}{bx})-h_{2}. \end{cases} $$

(1.3)

The rest of the paper is organized as follows. In Sect. 2, we recall the dynamic properties of equilibria in [10] and compute the first two focal values at the center-type equilibrium. In Sect. 3, for all possible parameters, we prove that the center-type equilibrium is a weak focus of order at most 2 by the resultant elimination [7]. Moreover, we give the parameter condition of each order. In Sect. 4, we employ numerical simulation to show the appearance of two limit cycles from degenerate Hopf bifurcation and give a brief conclusion.

2 Preliminary results

With rescaling $x\rightarrow\frac{x}{K}$, $y\rightarrow\frac {ay}{r_{1}}$, and $t\rightarrow r_{1} t$, system (1.3) reads

$$ \textstyle\begin{cases} \dot{x}=x(1-x)-xy,\\ \dot{y}= y(\delta-\frac{\beta y}{x})-h, \end{cases} $$

(2.1)

where $\beta=\frac{r_{2}}{abK}$, $\delta=\frac{r_{2}}{r_{1}}$, and $h=\frac {ah_{2}}{r_{1}}$ are all positive. It is clear that system (2.1) is orbitally equivalent to system (1.3). By the biological sense, we discuss system (2.1) in the region

$$\mathbb{R}_{+}^{2}:=\bigl\{ (x,y)\in\mathbb{R}^{2}:x>0,y>0 \bigr\} . $$

Let $E(\overline{x},\overline{y})$ be an equilibrium of system (2.1). Then $\overline{y}=1-\overline{x}$, and x̅ is a positive zero of the function

$$f(x):=(\beta+\delta) x^{2}-(2\beta+\delta-h)x+\beta $$

in the interval $(0,1)$. By setting

$$ h_{1}:=2\beta+\delta-2\sqrt{\beta^{2}+ \beta\delta}, $$

(2.2)

Lemma 2.1 in [10] gives the following statement of the equilibria of system (2.1).

(i)
If $h>h_{1}$, system (2.1) has no equilibrium.
(ii)
If $h=h_{1}$, system (2.1) has only one equilibrium $E_{0}(\frac{\delta-h}{\delta+h},\frac{2h}{\delta+h})$.
(iii)
If $h< h_{1}$, system (2.1) has two equilibria $E_{1}(x_{1},y_{1})$ and $E_{2}(x_{2},y_{2})$, where $x_{1,2}=\frac{2\beta+\delta-h \mp\sqrt{(\delta-h)^{2}-4\beta h}}{2(\beta +\delta)}$ and $y_{1,2}=1-x_{1,2}$.

Moreover, Theorems 2.2 and 3.3 in [10] indicate that $E_{0}$ is either a saddle-node or a cusp of codimension at most 3, and Bogdanov–Takens bifurcations of codimension 2 and 3 are investigated in [10, Theorem 3.4] and [11, Theorem 2.3], respectively. For $E_{1}$ and $E_{2}$, the dynamics are given in the following lemma.

Lemma 2.1

([10, Theorem 2.3])

Letβ, $\delta>0$and$0< h< h_{1}$. Then$E_{1}$is an anti-saddle and$E_{2}$is a saddle. More exactly, $E_{1}$is a stable (resp. an unstable) node or focus if$h< h_{2}$ (resp. $h>h_{2}$) and center-type if$h=h_{2}$, where

$$ h_{2}=\frac{1}{4}\bigl\{ 6\beta-4 \beta^{2}+3 \delta-6\beta\delta-2\delta ^{2}+(-1+2\beta+2\delta)\sqrt{-8\beta+4 \beta^{2}+4\beta\delta+\delta^{2}}\bigr\} . $$

Huang, Gong, and Ruan [10] studied $E_{1}$ by computing the first Lyapunov number and discussed the supercritical and subcritical Hopf bifurcations when the first Lyapunov number does not vanish. Furthermore, they studied the degenerate Hopf bifurcation for $(\alpha,\beta,\delta)=(\frac{-4+\sqrt{51}}{100},\frac{-3+2\sqrt {51}}{25},\frac{4(1+\sqrt{51})}{125})$ and found that $E_{1}$ is a weak focus of order 2.

In order to study the center-type equilibrium for all parameters, the following preparations are made to compute the first two focal values. The time scaling $t\rightarrow x t$ changes system (2.1) into the polynomial system

$$ \textstyle\begin{cases} \dot{x}=x^{2}(1-x-y),\\ \dot{y}=y(\delta x-\beta y)-hx, \end{cases} $$

(2.3)

which is orbitally equivalent to system (2.1) in $\mathbb{R}_{+}^{2}$ . The Jacobian matrix of system (2.3) at $E_{1}(x_{1},y_{1})$ is given by

$$ J|_{E_{1}}= \left [ \textstyle\begin{array}{c@{\quad}c} -x_{1}^{2} & -x_{1}^{2} \\ (1-x_{1})\delta-h & -2\beta(1-x_{1})+\delta x_{1} \end{array}\displaystyle \right ], $$

where $y_{1}=1-x_{1}$ is used. Let D and T be the determinant and the trace of $J|_{E_{1}}$, respectively. Then

$$\begin{aligned} D=x_{1}^{2}\bigl(-2(\beta+\delta) x_{1}+2 \beta+\delta-h\bigr),\qquad T=2\beta x_{1}+\delta x_{1}-x_{1}^{2}-2 \beta. \end{aligned}$$

Since $x_{1}<\frac{2\beta+\delta-h}{2(\beta+\delta)}$, it follows that $D>0$. Moreover, substituting $x_{1}=x_{1}(\beta,\delta,h):= \frac{2\beta+\delta-h -\sqrt{(\delta-h)^{2}-4\beta h}}{2(\beta+\delta)}$ into $T=0$, we obtain $h=h_{2}$. Let

$$\mathcal{T}:=\bigl\{ (\beta,\delta,h)\in\mathbb{R}^{3}: \beta>0, \delta>0, 0< h< h_{1}, T=0\bigr\} . $$

For $(\beta,\delta,h)\in\mathcal{T}$, the Jacobian matrix has a pair of pure imaginary eigenvalues $\pm\mathbf{i}w$, where

$$w=x_{1}\sqrt{-2(\beta+\delta) x_{1}+2\beta+\delta-h}>0 $$

because of $D>0$.

Let $u=x-x_{1}$, $v=y-(1-x_{1})$. Then system (2.3) becomes

$$ \textstyle\begin{cases} \dot{u}=-x_{1}^{2} u -x_{1}^{2} v-2x_{1}u^{2} -2x_{1} uv-u^{3}-u^{2}v,\\ \dot{v}= (-\delta x_{1}+\delta-h)u +(2\beta x_{1}+\delta x_{1}-2\beta )v+\delta uv-\beta v^{2}. \end{cases} $$

(2.4)

With the transformation $u=2z_{1}$, $v=-(4 \beta x_{1} +2 \delta x_{1} -4 \beta)x_{1}^{-2} z_{1}+2wx_{1}^{-2}z_{2}$ and time rescaling $t\rightarrow wt$, system (2.4) is normalized as

$$ \textstyle\begin{cases} \dot{z_{1}}=-z_{2}-\frac{4}{x_{1}} z_{1}z_{2}-\frac{4}{2\beta x_{1}+\delta x_{1}-2\beta} z_{1}^{2}z_{2},\\ \dot{z_{2}}= z_{1} -{\frac{ 4\beta^{2} x_{1}+2\beta\delta x_{1}-8\beta x_{1}^{2}-\delta x_{1}^{2}+4x_{1}^{3}-4\beta^{2}+8\beta x_{1}}{w^{2}}z_{1}^{2}} \\ \phantom{\dot{z_{2}}=}{}+{\frac{ 2 ( 4 \beta^{2} x_{1}+2\beta\delta x_{1}-4\beta x_{1}^{2}-\delta x_{1}^{2}-4\beta^{2}+4\beta x_{1} ) }{w x_{1}^{2}}z_{1}z_{2}} -{\frac{2\beta}{x_{1}^{2}}z_{2}^{2}} -{\frac{4}{w} z_{1}^{2}z_{2}}. \end{cases} $$

(2.5)

In the coordination $z_{1}=r \cos\theta$, $z_{2}=r \sin\theta$, system (2.5) becomes

$$ \frac{dr}{d\theta}=R_{2}(\theta)r^{2}+R_{3}( \theta)r^{3}+R_{4}(\theta )r^{4}+R_{5}( \theta)r^{5}+O\bigl(r^{6}\bigr), $$

(2.6)

where $R_{i}(\theta)$ ($i=2,3,4,5$) is polynomials of $(\sin\theta,\cos \theta)$, and their coefficients are decided by those of system (2.5). To compute focal values, we consider the solutions of (2.5) in the formal series $r(\theta,r_{0})=\sum_{k=1}^{\infty}r_{k}(\theta) r_{0}^{k}$ together with the initial condition

$$ r(0,r_{0})=r_{0}, $$

(2.7)

where $r_{0}$ is sufficiently small. Substituting this formal series into (2.6) and comparing the coefficients, we get

$$ \begin{gathered} \dot{r}_{2}=R_{2},\qquad \dot{r}_{3}=R_{3}+2 R_{2}r_{2}, \dot{r}_{4}=R_{4}+3R_{3}r_{2}+R_{2} \bigl(r_{2}^{2}+2r_{3}\bigr), \\ \dot{r}_{5}=R_{5}+4 R_{4} r_{2}+3R_{3} \bigl(r_{2}^{2}+r_{3} \bigr)+2 R_{2}(r_{2} r_{3}+r_{4}). \end{gathered} $$

(2.8)

Initial condition (2.7) is equivalent to

$$ r_{1}(0)=1,\qquad r_{2}(0)=r_{3}(0)=r_{4}(0)=r_{5}(0)=0. $$

(2.9)

By (2.8) and (2.9), the first two focal values at $E_{1}$ are given by

$$ L_{1}:= \frac{1}{2 \pi}r_{3}(2 \pi) = \frac{-f_{1}(\beta,\delta,h,x_{1})}{2x_{1}^{4} w^{\frac{5}{2}}},\qquad L_{2}:= \frac{1}{2\pi}r_{5}(2 \pi) =\frac{f_{2}(\beta,\delta,h,x_{1})}{36 x_{1}^{10} w^{\frac{7}{2}}}, $$

(2.10)

where $f_{1}$ and $f_{2}$ are given in the Appendix, and $x_{1}=x_{1}(\beta,\delta,h)$.

3 Degenerate Hopf bifurcation at $E_{1}$

Having the first two focal values, we can obtain the dynamics of $E_{1}$ when it is of center type.

Theorem 3.1

For$(\beta,\delta,h)\in\mathcal{T}$, $E_{1}(x_{1},y_{1})$is a weak focus with order at most 2. More exactly, it is order 1 if$(\beta,\delta,h)\in\mathcal{T}_{1}:= \{ (\beta,\delta ,h)\in\mathcal{T}:\widetilde{f}_{1}(\beta,\delta,h)\neq0\}$; otherwise, it is order 2; where$\widetilde{f}_{1}(\beta,\delta,h):=g_{1}(\beta,\delta,h) \sqrt {(\delta- h)^{2}-4\beta h} +g_{2} (\beta,\delta,h)$, and$g_{1}$and$g_{2}$are given in theAppendix.

To prove Theorem 3.1, we need to show that the first two focal values have no common zeros for $(\beta,\delta,h)\in\mathcal{T}$. For this purpose, we first give the proof of the following lemma.

Lemma 3.1

Let$V(f_{0},f_{1},f_{2},T):=\{(\beta,\delta,h,x_{1})\in\mathbb {R}^{4}:f_{0}=f_{1}=f_{2}=T=0 \}$. Then

$$V(f_{0},f_{1},f_{2},T)\cap S=\emptyset, $$

where$f_{0}:=(\beta+\delta) x_{1}^{2}-(2\beta+\delta-h)x_{1}+\beta$and$S=\{(\beta,\delta,h,x_{1})\in\mathbb{R}^{4}: (\beta,\delta,h)\in\mathcal{T}, 0< x_{1}<\frac{2\beta+\delta-h}{2(\beta +\delta)}\}$.

Proof

Taking the order $x_{1} \prec\delta\prec\beta\prec h$ in elimination, we calculate the following resultants [7] by software Maple:

$$ \begin{gathered} r_{12} =T,\qquad r_{13}= \operatorname{res}(f_{0},f_{1},h)=x_{1} \widetilde{r}_{13},\qquad r_{14}= \operatorname{res}(f_{0},f_{2},h)=x_{1}^{3} \widetilde{r}_{14}, \\ r_{23}= \operatorname{res}(r_{12},r_{13}, \beta)=-8x_{1}^{6}(x_{1}-1)^{4}( \delta -x_{1})\widetilde{r} _{23}, \\ r_{24}= \operatorname{res}(r_{12},r_{14}, \beta)=256x_{1}^{16}(x_{1}-1)^{9}( \delta -x_{1})\widetilde{r}_{24}, \\ r_{34}= \operatorname{res}(r_{23},r_{24}, \delta)=0, \end{gathered} $$

(3.1)

where $\operatorname{res}(f,g,x)$ denotes the resultant of polynomials f and g with respect to the variable x, and $\widetilde{r} _{13}$ and $\widetilde{r} _{14}$ are given in the Appendix,

$$\begin{aligned} &\widetilde{r} _{23}=\delta x_{1}^{2}+x_{1}^{3}+ \delta^{2}+\delta x_{1}+2 x_{1}^{2}-2x_{1}, \\ &\begin{aligned}\widetilde{r} _{24}&= 21 \delta^{5}x_{1} ^{4}+39 \delta^{4}x_{1} ^{5}+15 \delta^{3}x_{1} ^{6}-5 \delta^{2}x_{1} ^{7}-4 \delta x_{1} ^{8}-2 x_{1} ^{9}+21 \delta^{6}x_{1} ^{2}+15 \delta^{5}x_{1} ^{3}+87 \delta^{4}x_{1} ^{4} \\ & \quad -45 \delta^{3}x_{1} ^{5}-200 \delta^{2}x_{1} ^{6} +30 \delta x_{1} ^{7}+92 x_{1} ^{8}-42 \delta^{6}x_{1}-45 \delta^{5}x_{1} ^{2}-342 \delta^{4}x_{1} ^{3}+136 \delta^{3}x_{1} ^{4} \\ & \quad +14 \delta^{2}x_{1} ^{5}-167 \delta x_{1} ^{6}+190 x_{1} ^{7} +21 {\delta}^{6} -32 \delta^{5}x_{1}+313 \delta^{4}x_{1} ^{2}-410 \delta^{3}x_{1} ^{3}+781 \delta^{2}x_{1} ^{4} \\ & \quad -70 \delta x_{1} ^{5}-347 x_{1} ^{6}+41 \delta^{5}-122 \delta^{4}x _{3}+443 \delta^{3}x_{1} ^{2}-971 \delta^{2}x_{1} ^{3} + 756 \delta x_{1} ^{4}-211 x_{1} ^{5} \\ & \quad +33 \delta^{4} -139 \delta^{3}x_{1}+455 \delta^{2}x_{1} ^{2}-725 \delta x_{1} ^{3}+376 x_{1} ^{4}-90 \delta^{2}x_{1}+180 \delta x_{1} ^{2}-90 x_{1} ^{3}.\end{aligned} \end{aligned}$$

Let $\operatorname{lcoeff}(\xi,x)$ denote the leading coefficient of ξ with respect to x. Then from $(\beta,\delta,h,x_{1})\in S$ it follows that

$$ \begin{gathered} \operatorname{lcoeff}(f_{0},h)=x_{1}> 0,\qquad \operatorname{lcoeff}(r_{12},\beta)=2(x_{1}-1)< 0, \\ \operatorname{lcoeff}(r_{23},\delta)=-8x_{1}^{5}(x_{1}-1)^{4}>0. \end{gathered} $$

(3.2)

By Theorem 1 in [5], we have the decomposition

$$ \begin{aligned}[b] V(f_{0},T,f_{1},f_{2})={}&V \bigl(f_{0},T,f_{1},f_{2}, \operatorname{lcoeff}(f_{0},h)\bigr) \\ & \cup V \biggl(\frac{f_{0},T,f_{1},f_{2},r_{12},r_{13},r_{14},\operatorname{lcoeff}(r_{12},\beta)}{\operatorname{lcoeff}(f_{0},h)} \biggr) \\ & \cup V \biggl(\frac {f_{0},T,f_{1},f_{2},r_{12},r_{13},r_{14},r_{23},r_{24},\operatorname{lcoeff}(r_{23},\delta)}{ \operatorname{lcoeff}(f_{0},h),\operatorname{lcoeff}(r_{12},\beta)} \biggr) \\ & \cup V \biggl(\frac{f_{0},T,f_{1},f_{2},r_{12},r_{13},r_{14},r_{23},r_{24},r_{34}}{ \operatorname{lcoeff}(f_{0},h),\operatorname{lcoeff}(r_{12},\beta),\operatorname{lcoeff}(r_{23},\delta)} \biggr), \end{aligned} $$

(3.3)

where $V(\frac{\xi_{1},\xi_{2},\ldots,\xi_{n}}{\eta_{1},\eta_{2},\ldots,\eta_{m}})=V(\xi _{1},\ldots,\xi_{n})\backslash(\bigcup_{k=1}^{m} V(\eta_{k}))$ as used in [5].

By (3.1)–(3.3), we can deduce that

$$ \begin{aligned}[b] V(f_{0},T,f_{1},f_{2}) \cap S&= V (f_{0},T,f_{1},f_{2},r_{12},r_{13},r_{14},r_{23},r_{24},r_{34} )\cap S, \\ & = V (f_{0},T,f_{1},f_{2},r_{13},r_{14},r_{23},r_{24} )\cap S. \end{aligned} $$

(3.4)

Moreover, by computing the resultant

$$ \begin{aligned}[b] \operatorname{res}(\widetilde{r}_{23}, \widetilde{r}_{24},\delta) &= 1152 x_{1}^{4}(x_{1}-1)^{4} (x_{1}-2-\sqrt{3}) (x_{1}+\sqrt{2}+1) \biggl(x_{1}+\frac{\sqrt{22}+4}{3}\biggr) \\ &\quad\times \biggl(x_{1}-\frac{\sqrt{22}-4}{3}\biggr) (x_{1}- \sqrt{2}+1) (x_{1}-2+\sqrt{3}), \end{aligned} $$

(3.5)

we see that the first five factors of the right-hand side are all positive because of $0< x_{1}<1$. By (3.1) and (3.5), (3.4) can be written as

$$V(f_{0},T,f_{1},f_{2})\cap S=V_{1} \cup V_{2}\cup V_{3}\cup V_{4}, $$

where

$$ \begin{gathered} V_{1}= V (f_{0},T,f_{1},f_{2}, \widetilde{r}_{13},\widetilde{r}_{14},x_{1}= \delta )\cap S, \\ V_{2}= V \biggl(f_{0},T,f_{1},f_{2}, \widetilde{r}_{13},\widetilde {r}_{14}, \widetilde{r}_{23},\widetilde{r}_{24},x_{1}= \frac{\sqrt {22}-4}{3} \biggr)\cap S, \\ V_{3}= V (f_{0},T,f_{1},f_{2},r_{13},r_{14}, \widetilde{r}_{23},\widetilde {r}_{24},x_{1}= \sqrt{2}-1 )\cap S, \\ V_{4}= V (f_{0},T,f_{1},f_{2},r_{13},r_{14}, \widetilde{r}_{23},\widetilde {r}_{24},x_{1}= 2-\sqrt{3} )\cap S. \end{gathered} $$

It suffices to prove that $V_{i}=\emptyset$, $i=1,2,3,4$. In fact, substituting $\delta=x_{1}$ into T, we see that

$$T|_{\delta=x_{1}}=2\beta(x_{1}-1)< 0, $$

showing that $V_{1}\subseteq V(T,\delta=x_{1})\cap S= \emptyset$. In order to obtain that $V_{2}=\emptyset$, we substitute $x_{1}=\frac{\sqrt{22}-4}{3}$ into $\widetilde{r}_{23}$ and $\widetilde{r}_{24}$, and obtain

$$\begin{aligned} &\widetilde{r}_{23}|_{x_{1}=\frac{\sqrt{22}-4}{3}}=-\frac{1}{27}(9\delta +2+\sqrt{22}) ( -3\delta-8+2\sqrt{22}), \\ &\begin{aligned}\widetilde{r}_{24}|_{x_{1}=\frac{\sqrt{22}-4}{3}}&={\frac{-71+14 \sqrt {22}}{19{,}683}}(9 \delta+2+\sqrt{22}) \bigl( 675\sqrt{22} {\delta}^{4}-5103 \delta^{5}+16{,}647\sqrt{22}\delta^{3} \\ & \quad -12{,}285 \delta^{4} +76{,}746\sqrt{22} \delta^{2}-78{,}519 \delta^{3} -28{,}254\sqrt{22}\delta-354{,}246 \delta^{2} \\ & \quad +130{,}842 \delta+705{,}280-150{,}340 \sqrt{22}\bigr).\end{aligned} \end{aligned}$$

Simple computation shows that

$$\{\delta\in\mathbb{R}_{+}: \widetilde{r}_{23}|_{x_{1}=\frac{\sqrt {22}-4}{3}}= \widetilde{r}_{24}|_{x_{1}=\frac{\sqrt{22}-4}{3}}=0\} =\emptyset. $$

Thus it follows that $V_{2} \subseteq V (\widetilde{r}_{23},\widetilde{r}_{24}, x_{1}=\frac{\sqrt {22}-4}{3})\cap S=\emptyset$. Similarly, we can prove that $V_{3}=\emptyset$. To obtain $V_{4}=\emptyset$, we substitute $x_{1}=2-\sqrt{3}$ into the equations $\widetilde {r}_{23}=\widetilde{r}_{23}=T=f_{0}=0$, and get $\delta=2\sqrt{3}-3$, $\beta=\frac{7}{2}-2\sqrt{3}$, and $h=2-\sqrt{3}$. For $(\beta,\delta,h)=(\frac{7}{2}-2\sqrt{3},2\sqrt{3}-3, 2-\sqrt{3})$, it immediately follows from (2.2) that $h_{1}=2-\sqrt{3}$. So $h=h_{1}$, and $(\frac{7}{2}-2\sqrt{3},2\sqrt{3}-3, 2-\sqrt{3}, 2-\sqrt{3})\notin S$. Therefore, $V_{4}\subseteq V(\widetilde{r}_{23},\widetilde {r}_{23},T,f_{0},x_{1}=2-\sqrt{3})\cap S=\emptyset$.

Since $V_{1}=V_{2}=V_{3}=V_{4}=\emptyset$, we see that $V(f_{0},f_{1},f_{2},T)\cap S=\emptyset$. □

Now we can give the proof of Theorem 3.1.

Proof of Theorem 3.1

Note that the zeros of $L_{i}$ are decided by the zeros of $f_{i}$ ($i=1,2$). By Lemma 3.1, we can see that $f_{1}$ and $f_{2}$ have no common zeros when $T=0$. Therefore, $L_{1}$ and $L_{2}$ have no common zeros for $(\beta,\delta ,h)\in\mathcal{T}$, showing that $E_{1}$ is a weak focus with order at most 2. More exactly, it is order 1 if and only if $f_{1}\neq0$. So substituting $x_{1}=\frac{2\beta+\delta-h -\sqrt{(\delta-h)^{2}-4\beta h}}{2(\beta+\delta)}$ into $f_{1}=0$, we get $\widetilde{f}_{1}(\beta,\delta,h)=g_{1}(\beta,\delta,h) \sqrt{(\delta -h)^{2}-4\beta h} +g_{2} (\beta,\delta,h)=0$. Therefore, $E_{1}$ is a weak focus of order 1 if and only if $(\beta,\delta,h)\in\mathcal{T}_{1}=\{(\beta,\delta,h)\in\mathcal{T}: \widetilde{f}_{1}(\beta,\delta,h)\neq0\}$.

To prove that $E_{1}$ is a weak focus of order 2, we need to show that $\{(\beta,\delta,h)\in\mathcal{T}, \widetilde{f}_{1}(\beta,\delta,h)=0\} \neq\emptyset$. In fact, it can be checked that if

$$(\beta,\delta,h)=\biggl(\frac{-4+\sqrt{51}}{125},\frac{2\sqrt{51}-3}{25}, \frac {4(\sqrt{51}+1)}{125}\biggr), $$

then $x_{1}=\frac{1}{4}$, $T=0$, and $\widetilde{f}_{1}=0$, showing that $(\frac{-4+\sqrt{51}}{125},\frac{2\sqrt{51}-3}{25},\frac {4(\sqrt{51}+1)}{125})\in\mathcal{T}_{1}$. Therefore, $E_{1}$ is a weak focus with order 2 if $(\beta,\delta,h)\in \mathcal{T}_{1}$. □

4 Simulation and conclusions

Let $(\beta_{*},\delta_{*},h_{*})=(\frac{\sqrt{51}-4}{100},\frac{2\sqrt {51}-3}{25},\frac{4(\sqrt{51}+1)}{125})$. Then it can be checked that $E_{1}(0.2,0.8)$ is a stable weak focus of order 2 if $(\beta,\delta,h)=(\beta_{*},\delta_{*},h_{*})$. To display two limit cycles from degenerate Hopf bifurcation, we plot three orbits of system (2.1) with $(\beta,\delta,h)=(\beta _{*}-1.428429\times10^{-5},\delta_{*},h_{*}-2.605207\times10^{-4})$. In Fig. 1, the orbits from $P_{1}=(0.1990005,0.801)$, $P_{2}=(0.199005,0.801)$, and $P_{3}=(0.19905,0.801)$ are plotted, separately. It is clear that the orbits from $P_{1}$ and $P_{2}$ spiral inward and outward, respectively. So by the Poincaré–Bendixson theorem [18], there is an unstable limit cycle between the orbits from $P_{1}$ and $P_{2}$. Moreover, since the orbit from $P_{3}$ spirals inward, there is a stable limit cycle between the orbits from $P_{2}$ and $P_{3}$. Therefore, there are two limit cycles surrounding $E_{1}(0.199,0.801)$, and the inner one is unstable and the outer one is stable.

In this paper, we extend the study of the center-type equilibrium in system (2.1) and obtain that it is a weak focus of order at most 2. In the previous work [10, 11], Huang et al. investigated various bifurcations including saddle-node bifurcation, subcritical and supercritical Hopf bifurcation, and Bogdanov–Takens bifurcation in this system. Moreover, degenerate Hopf bifurcation was just studied for a fixed parameter value in [10] and by Bogdanov–Takens bifurcation with codimension 3 in [11]. However, these results just show the occurrence of degenerate Hopf bifurcation in the neighborhood of the fixed parameter values, not for all possible parameters. For all parameters, our study proves that the center-type equilibrium in system (2.1) is a weak focus with order at most 2. Thus there are at most two limit cycles arising from degenerate Hopf bifurcation. The results in [10, 11] and this paper reveal that the codimension of local bifurcations in system (2.1) is at most 3.

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Acknowledgements

The author would like to thank the editors and reviewers sincerely.

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The author is supported financially by the Program of Chengdu Normal University (2018JY37).

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Department of Mathematics, Chengdu Normal University, Chengdu, China
Juan Su

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Juan Su
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Appendix

$f_{1}$ and $f_{2}$ in (2.10) are given by

$$\begin{aligned} f_{1}:={} & 8 x_{1} ^{7} \beta+x_{1} ^{7}\delta-28 x_{1} ^{6}\beta^{2}-16 x_{1} ^{6}\beta \delta-2 x_{1} ^{6}\delta^{2}+24 x_{1} ^{5}\beta^{3}+14 x_{1} ^{5}\beta^{2}\delta+2 x_{1}^{5} \beta\delta^{2}-24 x_{1} ^{4} \beta^{4} \\ & -24 x_{1}^{4}\beta^{3} \delta-8 x_{1} ^{4}\beta^{2} \delta^{2} -x_{1} ^{4}\beta \delta^{3}+16 x_{1} ^{3}\beta^{5}+24 { x_{1} }^{3}\beta^{4}\delta+12 x_{1} ^{3}\beta^{3}\delta^{ 2}+2 x_{1} ^{3}\beta^{2}\delta^{3} \\ & -hx_{1} ^{6}-4 h x_{1}^{4}\beta^{2}-hx_{1} ^{4}\beta\delta+4 hx_{1} ^{3} \beta^{3}+2 hx_{1} ^{3}\beta^{2}\delta-8 x_{1} ^{6}\beta+ x_{1} ^{6} \delta+48 x_{1} ^{5}\beta^{2}+12 x_{1} ^{5} \beta\delta \\ &-48 x_{1} ^{4}\beta^{3}-10 x_{1} ^{4} \beta^{2}\delta+x_{1} ^{4}\beta \delta^{2}+64 x_{1} ^{3}\beta^{4} +40 x_{1} ^{3}\beta^{3}\delta+6 x_{1} ^{3}\beta^{2}{ \delta}^{2}-48 x_{1} ^{2}\beta^{5}-48 x_{1} ^{2}\beta^{4 }\delta \\ & -12 x_{1} ^{2}\beta^{3}\delta^{2}+4 hx_{1} ^{3}{ \beta}^{2}-4 hx_{1} ^{2} \beta^{3}-20 x_{1} ^{4}\beta^{2}+24 x_{1} ^{3}\beta^{3}-4 x_{1} ^{3}\beta^{2}\delta-56 x_{1} ^{2}\beta^{4}-16 x_{1} ^{2}\beta^{3}\delta\\&+48 x_{1} \beta^{5}+24 x_{1} \beta^{4}\delta +16 x_{1} \beta^{4}-16 \beta^{5}, \\ f_{2}:={}& -4992x_{1}^{18} \beta^{2}-3120x_{1}^{18}\beta\delta- 312x_{1}^{18}\delta^{2}+37{,}440x_{1}^{17} \beta^{3}+ 41{,}136x_{1}^{17} \beta^{2}\delta \\ & +13{,}746x_{1}^{17}\beta{ \delta}^{2}+1296x_{1}^{17}\delta^{3}-95{,}040x_{1}^{16}{ \beta}^{4}-133{,}680x_{1}^{16} \beta^{3}\delta-69{,}624x_{1}^{16} \beta^{2}\delta^{2} \\ & -15{,}774x_{1}^{16} \beta\delta^{3}- 1242x_{1}^{16} \delta^{4}+104{,}736x_{1}^{15}\beta^{5}+ 125{,}776x_{1}^{15}\beta^{4} \delta+43{,}308x_{1}^{15}\beta ^{3} \delta^{2} \\ & -644x_{1}^{15}\beta^{2} \delta^{3}-2616{{ x_{1}}}^{15}\beta \delta^{4}-323x_{1}^{15}\delta^{5}-101{,}312x_{1}^{14}\beta^{6}-99{,}120x_{1}^{14} \beta^{5} \delta \\ & +24{,}656x_{1}^{14} \beta^{4}\delta^{2}+69{,}768x_{1} ^{14}\beta^{3}\delta^{3}+34{,}822x_{1}^{14} \beta^{2}\delta ^{4}+7110x_{1}^{14}\beta\delta^{5}+515x_{1}^{14}{ \delta}^{6} \\ &+102{,}656x_{1}^{13} \beta^{7}+184{,}960x_{1}^{13} \beta^{6}\delta+150{,}496x_{1}^{13} \beta^{5}\delta^{2}+77{,}520 x_{1}^{13} \beta^{4}\delta^{3}\\ & +28{,}788x_{1}^{13}\beta ^{3} \delta^{4}+7590x_{1}^{13} \beta^{2}\delta^{5}+1246{{ x_{1}}}^{13} \beta\delta^{6}+94x_{1}^{13} \delta^{7}+12{,}416 x_{1}^{12} \beta^{8} \\ &+158{,}496x_{1}^{12} \beta^{7}\delta +323{,}136x_{1}^{12}\beta^{6} \delta^{2}+293{,}736x_{1}^{12} \beta^{5}\delta^{3}+143{,}952x_{1}^{12} \beta^{4}\delta^{4} \\ & +39{,}480x_{1}^{12} \beta^{3}\delta^{5}+5722x_{1}^{12}{ \beta}^{2}\delta^{6}+345x_{1}^{12}\beta\delta^{7}+2176{ x_{1}}^{11}\beta^{9}-51{,}520x_{1}^{11} \beta^{8}\delta \\ & - 132{,}512x_{1}^{11} \beta^{7}\delta^{2}-138{,}128x_{1}^{11} \beta^{6}\delta^{3}-76{,}368x_{1}^{11} \beta^{5}\delta^{4}- 23{,}256x_{1}^{11}\beta^{4} \delta^{5}\\ &-3440x_{1}^{11}{ \beta}^{3}\delta^{6}-92x_{1}^{11} \beta^{2}\delta^{7}+23 x_{1}^{11} \beta\delta^{8}+11{,}264x_{1}^{10} \beta^{10}+ 65{,}920x_{1}^{10} \beta^{9}\delta \\ & +126{,}208x_{1}^{10}\beta ^{8} \delta^{2}+121{,}952x_{1}^{10} \beta^{7}\delta^{3}+69{,}120 x_{1}^{10} \beta^{6}\delta^{4}+24{,}392x_{1}^{10} \beta ^{5}\delta^{5} \\ & +5360x_{1}^{10} \beta^{4}\delta^{6}+674x_{1}^{10}\beta^{3} \delta^{7}+36x_{1}^{10}\beta^{2}{ \delta}^{8}-17{,}920x_{1}^{9} \beta^{11}-98{,}560x_{1}^{9}{ \beta}^{10}\delta \\ & -210{,}048x_{1}^{9} \beta^{9}\delta^{2}-238{,}144 x_{1}^{9} \beta^{8}\delta^{3}-160{,}480x_{1}^{9}\beta^{7} \delta^{4}-66{,}480x_{1}^{9} \beta^{6}\delta^{5} \\ &-16{,}600{{ x_{1}}}^{9} \beta^{5}\delta^{6}-2284x_{1}^{9} \beta^{4}{ \delta}^{7}-132x_{1}^{9} \beta^{3}\delta^{8}-16{,}384 x_{1}^{8} \beta^{12} -65{,}536x_{1}^{8}\beta^{11}\delta\\ &-114{,}688 x_{1}^{8}\beta^{10}\delta ^{2}-114{,}688x_{1}^{8}\beta^{9} \delta^{3}-71{,}680x_{1}^{8} \beta^{8}\delta^{4}-28{,}672x_{1}^{8} \beta^{7}\delta^{5} \\ & -7168x_{1}^{8}\beta^{6}{ \delta}^{6}-1024x_{1}^{8} \beta^{5}\delta^{7}-64x_{1} ^{8}\beta^{4}\delta^{8}+624hx_{1}^{17} \beta+312h{x_{1} }^{17}\delta+2448hx_{1}^{16} \beta^{2} \\ &+696hx_{1}^{16} \beta\delta -201hx_{1}^{16}\delta^{2}-19{,}776hx_{1}^{15 } \beta^{3}-24{,}768hx_{1}^{15} \beta^{2}\delta-9366h{x_{1} }^{15}\beta \delta^{2} \\ & -945hx_{1}^{15} \delta^{3}+17{,}056h{{ x_{1}}}^{14} \beta^{4}+33{,}292hx_{1}^{14}\beta^{3}\delta+ 23{,}612hx_{1}^{14}\beta^{2} \delta^{2}+7004hx_{1}^{14} \beta \delta^{3} \\ & +690hx_{1}^{14} \delta^{4}+2880h{x_{1} }^{13} \beta^{5}+8376hx_{1}^{13} \beta^{4}\delta+15{,}152hx_{1}^{13}\beta^{3} \delta^{2}+10{,}140hx_{1}^{13} \beta^{2 }\delta^{3} \\ & +2623hx_{1}^{13} \beta\delta^{4}+237h{{x_{1} }}^{13} \delta^{5}+31{,}392hx_{1}^{12} \beta^{6}+100{,}160h x_{1}^{12}\beta^{5} \delta\\ &+101{,}928hx_{1}^{12}\beta^{4}\delta ^{2}+45{,}860hx_{1}^{12}\beta^{3} \delta^{3}+9454hx_{1}^{12} \beta^{2}\delta^{4}+724hx_{1}^{12} \beta\delta^{5} \\ & + 14{,}976hx_{1}^{11}\beta^{7}+13{,}056hx_{1}^{11} \beta^{6} \delta+416hx_{1}^{11} \beta^{5}\delta^{2}-2344hx_{1}^{11} \beta^{4}\delta^{3}-228hx_{1}^{11} \beta^{3}\delta^{ 4} \\ &+340hx_{1}^{11} \beta^{2}\delta^{5} +82hx_{1}^{11} \beta\delta^{6}-6016hx_{1}^{10} \beta^{8}+3840h{x_{1} }^{10} \beta^{7}\delta+16{,}672hx_{1}^{10} \beta^{6}\delta^{2} \\ &+12{,}976hx_{1}^{10} \beta^{5}\delta^{3}+4392hx_{1}^{10} \beta^{4}\delta^{4} +668hx_{1}^{10}\beta^{3} \delta^{5}+ 30hx_{1}^{10} \beta^{2}\delta^{6}+1280hx_{1}^{9}{ \beta}^{9} \\ & -17{,}280hx_{1}^{9} \beta^{8}\delta-41{,}600hx_{1}^{9} \beta^{7}\delta^{2}-36{,}800hx_{1}^{9} \beta^{6}\delta^{3}-15{,}600hx_{1}^{9}\beta^{5} \delta^{4}\\ &-3160hx_{1}^{9} \beta^{4}\delta^{5}-240hx_{1}^{9} \beta^{3}\delta^{6}- 18{,}944hx_{1}^{8} \beta^{10}-56{,}832hx_{1}^{8} \beta^{9} \delta-71{,}040hx_{1}^{8} \beta^{8}\delta^{2} \\ & -47{,}360h x_{1}^{8}\beta^{7} \delta^{3}-17{,}760hx_{1}^{8} \beta^{6}\delta ^{4}-3552hx_{1}^{8} \beta^{5}\delta^{5}-296hx_{1}^{8} \beta^{4}\delta^{6}+9984x_{1}^{17} \beta^{2} \\ & +2496 x_{1}^{17}\beta\delta-312x_{1}^{17}\delta^{2}-107{,}328x_{1}^{16} \beta^{3}-79{,}728x_{1}^{16} \beta^{2}\delta-13{,}194 x_{1}^{16}\beta \delta^{2} \\ &+201x_{1}^{16}\delta^{3}+ 335{,}232x_{1}^{15}\beta^{4} +366{,}720x_{1}^{15}\beta^{3} \delta+141{,}600x_{1}^{15}\beta^{2} \delta^{2}+21{,}840{x_{1} }^{15}\beta \delta^{3} \\ & +945x_{1}^{15}\delta^{4}-365{,}664{{ x_{1}}}^{14}\beta^{5}-298{,}448x_{1}^{14} \beta^{4}\delta-49{,}660x_{1}^{14}\beta^{3} \delta^{2}+3152x_{1}^{14}{ \beta}^{2}\delta^{3} \\ & -2198x_{1}^{14} \beta\delta^{4}-690{ x_{1}}^{14} \delta^{5}+312{,}768x_{1}^{13} \beta^{6}+10{,}176{ x_{1}}^{13} \beta^{5}\delta-409{,}984x_{1}^{13}\beta^{4}{ \delta}^{2}\\ &-310{,}980x_{1}^{13} \beta^{3}\delta^{3}-89{,}286{{ x_{1}}}^{13} \beta^{2}\delta^{4}-9789x_{1}^{13} \beta{ \delta}^{5}-237x_{1}^{13} \delta^{6}-390{,}272x_{1}^{12}{ \beta}^{7} \\ & -551{,}232x_{1}^{12}\beta^{6} \delta-419{,}520x_{1} ^{12}\beta^{5} \delta^{2}-249{,}896x_{1}^{12} \beta^{4}{\delta }^{3}-102{,}636x_{1}^{12} \beta^{3}\delta^{4} \\ & -23{,}146x_{1} ^{12}\beta^{2}\delta^{5}-2124x_{1}^{12}\beta\delta^{6}- 325{,}760x_{1}^{11}\beta^{8}-1{,}445{,}760x_{1}^{11} \beta^{7} \delta \\ &-2{,}018{,}624x_{1}^{11} \beta^{6}\delta^{2}-1{,}335{,}504{ x}_{3}^{11} \beta^{5}\delta^{3} -463{,}424x_{1}^{11}\beta^{4}{ \delta}^{4}-82{,}156x_{1}^{11} \beta^{3}\delta^{5} \\ & -6208{ x}_{3}^{11} \beta^{2}\delta^{6}-82x_{1}^{11} \beta\delta^{7 }+139{,}392x_{1}^{10} \beta^{9}+688{,}640x_{1}^{10} \beta^{8 }\delta+1{,}034{,}016x_{1}^{10}\beta^{7} \delta^{2}\\&+731{,}296x_{1}^{10}\beta^{6} \delta^{3}+267{,}168x_{1}^{10} \beta^{5}{ \delta}^{4}+45{,}408x_{1}^{10} \beta^{4}\delta^{5}+1256 x_{1}^{10} \beta^{3}\delta^{6} \\ & -392x_{1}^{10}\beta^{2}{ \delta}^{7}-178{,}688x_{1}^{9} \beta^{10}-708{,}864x_{1}^{9}{ \beta}^{9}\delta-1{,}044{,}736x_{1}^{9} \beta^{8}\delta^{2} \\ & -788{,}160 x_{1}^{9} \beta^{7}\delta^{3}-339{,}360x_{1}^{9} \beta^{6}\delta^{4}-85{,}424x_{1}^{9}\beta^{5} \delta^{5}-11{,}872{{ x_{1}}}^{9} \beta^{4}\delta^{6} \\ & -708x_{1}^{9} \beta^{3}{ \delta}^{7}+177{,}664x_{1}^{8} \beta^{11}+809{,}984x_{1}^{8}{ \beta}^{10}\delta+1{,}440{,}384x_{1}^{8} \beta^{9}\delta^{2}\\ &+1{,}340{,}800x_{1}^{8}\beta^{8} \delta^{3}+716{,}960x_{1}^{8}{ \beta}^{7}\delta^{4}+221{,}952x_{1}^{8} \beta^{6}\delta^{5}+ 36{,}952x_{1}^{8} \beta^{5}\delta^{6} \\ & +2552x_{1}^{8}{ \beta}^{4}\delta^{7}+131{,}072x_{1}^{7} \beta^{12}+458{,}752 x_{1}^{7}\beta^{11} \delta+688{,}128x_{1}^{7}\beta^{10}{ \delta}^{2} \\ &+573{,}440x_{1}^{7} \beta^{9}\delta^{3}+286{,}720{{ x_{1}}}^{7} \beta^{8}\delta^{4}+86{,}016x_{1}^{7} \beta^{7}{ \delta}^{5} +14{,}336x_{1}^{7}\beta^{6} \delta^{6}\\&+1024x_{1}^{7}\beta^{5} \delta^{7}-570{h}^{2}x_{1}^{15} \beta-240 {h}^{2}x_{1}^{15} \delta-288{h}^{2}x_{1}^{14} \beta^{2}+ 180{h}^{2}x_{1}^{14} \beta\delta \\ & +171{h}^{2}x_{1}^{14}{ \delta}^{2}+1144{h}^{2}x_{1}^{13} \beta^{3} +2788{h}^{2}x_{1}^{13} \beta^{2}\delta+1475{h}^{2}x_{1}^{13} \beta{ \delta}^{2}+179{h}^{2}x_{1}^{13} \delta^{3} \\ & +5656{h}^{2}{x_{1}}^{12} \beta^{4}+8972{h}^{2}x_{1}^{12} \beta^{3}\delta +4028{h}^{2}x_{1}^{12} \beta^{2}\delta^{2}+478{h}^{2}{{ x_{1}}}^{12}\beta\delta^{3} \\ & +6080{h}^{2}x_{1}^{11} \beta^{ 5}+7376{h}^{2}x_{1}^{11} \beta^{4}\delta+3336{h}^{2}x_{1}^{11} \beta^{3}\delta^{2}+774{h}^{2}x_{1}^{11} \beta^{2}{ \delta}^{3}+95{h}^{2}x_{1}^{11} \beta\delta^{4} \\ &-2400{h}^{2 }x_{1}^{10} \beta^{6}-1080{h}^{2}x_{1}^{10} \beta^{5} \delta+24{h}^{2}x_{1}^{10} \beta^{4}\delta^{2} -114{h}^{2}x_{1}^{10} \beta^{3}\delta^{3}-48{h}^{2}x_{1}^{10}{ \beta }^{2}\delta^{4} \\ & +3168{h}^{2}x_{1}^{9} \beta^{7}+2064{h}^{2} x_{1}^{9} \beta^{6}\delta-648{h}^{2}x_{1}^{9} \beta^{5}{ \delta}^{2}-612{h}^{2}x_{1}^{9} \beta^{4}\delta^{3}-84{h}^{2}x_{1}^{9}\beta^{3} \delta^{4}\\ &-6400{h}^{2}x_{1}^{8}{ \beta}^{8}-12{,}800{h}^{2}x_{1}^{8} \beta^{7}\delta-9600{h}^{2} x_{1}^{8} \beta^{6}\delta^{2}-3200{h}^{2}x_{1}^{8}{ \beta}^{5}\delta^{3}-400{h}^{2}x_{1}^{8} \beta^{4}\delta^{ 4} \\ & -624hx_{1}^{16}\beta-4896hx_{1}^{15} \beta^{2}+444h x_{1}^{15}\beta \delta+480hx_{1}^{15}\delta^{2}+61{,}392 hx_{1}^{14}\beta^{3} \\ &+49{,}584hx_{1}^{14} \beta^{2}\delta +8226hx_{1}^{14}\beta\delta^{2}-342hx_{1}^{14}{ \delta }^{3}-81{,}904hx_{1}^{13} \beta^{4}-113{,}384hx_{1}^{13}{ \beta}^{3}\delta \\ & -53{,}736hx_{1}^{13} \beta^{2}\delta^{2}-9318 hx_{1}^{13} \beta\delta^{3}-358hx_{1}^{13}\delta^{4}+ 6624hx_{1}^{12}\beta^{5}-30{,}264hx_{1}^{12} \beta^{4} \delta \end{aligned}$$

$$\begin{aligned} \hphantom{f_{2}:={}}&-60{,}108hx_{1}^{12} \beta^{3}\delta^{2}-27{,}738h{{x_{1} }}^{12}\beta^{2}\delta^{3}-3598hx_{1}^{12} \beta\delta^{ 4} -201{,}984hx_{1}^{11}\beta^{6}\\ &-454{,}384hx_{1}^{11} \beta ^{5}\delta-327{,}136hx_{1}^{11} \beta^{4}\delta^{2}-95{,}752h{{ x_{1}}}^{11} \beta^{3}\delta^{3}-10{,}416hx_{1}^{11} \beta^{2 }\delta^{4} \\ & -190hx_{1}^{11}\beta\delta^{5}-29{,}376h x_{1}^{10}\beta^{7}+15{,}712hx_{1}^{10} \beta^{6}\delta+28{,}704h x_{1}^{10} \beta^{5}\delta^{2} \\ & +4464hx_{1}^{10} \beta^{ 4}\delta^{3}-3292hx_{1}^{10} \beta^{3}\delta^{4}-948h{{ x_{1}}}^{10}\beta^{2} \delta^{5}-13{,}312hx_{1}^{9} \beta^{8} \\& -117{,}312hx_{1}^{9} \beta^{7}\delta-142{,}368hx_{1}^{9}{ \beta}^{6}\delta^{2}-67{,}040hx_{1}^{9} \beta^{5}\delta^{3}- 13{,}752hx_{1}^{9} \beta^{4}\delta^{4} \\ & -996hx_{1}^{9}{ \beta}^{3} \delta^{5}+12{,}800hx_{1}^{8} \beta^{9}+137{,}600h{{ x_{1}}}^{8} \beta^{8}\delta+217{,}600hx_{1}^{8} \beta^{7}{ \delta}^{2} \\ &+136{,}000hx_{1}^{8} \beta^{6}\delta^{3}+37{,}600h{{ x_{1}}}^{8} \beta^{5}\delta^{4} +3800hx_{1}^{8}\beta^{4}{ \delta}^{5}+113{,}664hx_{1}^{7} \beta^{10} \\ &+284{,}160hx_{1}^{7 } \beta^{9}\delta+284{,}160hx_{1}^{7} \beta^{8}\delta^{2}+ 142{,}080hx_{1}^{7} \beta^{7}\delta^{3} +35{,}520hx_{1}^{7}{ \beta}^{6} \delta^{4}\\ &+3552hx_{1}^{7} \beta^{5}\delta^{5}- 4992x_{1}^{16} \beta^{2}+624x_{1}^{16}\beta\delta+ 102{,}336x_{1}^{15}\beta^{3}+41{,}040x_{1}^{15} \beta^{2} \delta \\ & +126x_{1}^{15}\beta\delta^{2}-240x_{1}^{15}{ \delta}^{3}-435{,}456x_{1}^{14} \beta^{4}-354{,}240x_{1}^{14} \beta^{3}\delta-96{,}504x_{1}^{14} \beta^{2}\delta^{2} \\ &-8406 x_{1}^{14} \beta\delta^{3}+171x_{1}^{14} \delta^{4} + 430{,}272x_{1}^{13}\beta^{5}+188{,}128x_{1}^{13} \beta^{4} \delta+20{,}524x_{1}^{13} \beta^{3}\delta^{2} \\ &+25{,}260x_{1} ^{13}\beta^{2}\delta^{3}+7843x_{1}^{13} \beta\delta^{4}+ 179x_{1}^{13} \delta^{5} -142{,}080x_{1}^{12}\beta^{6}+ 782{,}208x_{1}^{12}\beta^{5} \delta\\ &+993{,}824x_{1}^{12}{\beta }^{4} \delta^{2}+410{,}460x_{1}^{12} \beta^{3}\delta^{3}+65{,}790 x_{1}^{12} \beta^{2}\delta^{4}+3120x_{1}^{12} \beta{ \delta}^{5} \\ & +428{,}544x_{1}^{11}\beta^{7}+475{,}008x_{1}^{11} \beta^{6}\delta+566{,}064x_{1}^{11} \beta^{5}\delta^{2}+ 438{,}704x_{1}^{11} \beta^{4}\delta^{3} \\ & +149{,}388x_{1}^{11} \beta^{3}\delta^{4}+18{,}326x_{1}^{11} \beta^{2}\delta^{5}+95x_{1}^{11}\beta\delta^{6}+1{,}612{,}800x_{1}^{10} \beta ^{8}\\ &+4{,}658{,}048x_{1}^{10} \beta^{7}\delta+4{,}670{,}528x_{1}^{10 } \beta^{6}\delta^{2}+2{,}177{,}712x_{1}^{10} \beta^{5}\delta^{ 3}+489{,}232x_{1}^{10} \beta^{4}\delta^{4} \\ & +46{,}030x_{1}^{ 10}\beta^{3} \delta^{5}+996x_{1}^{10}\beta^{2} \delta^{6} -885{,}248x_{1}^{9} \beta^{9}-2{,}637{,}696x_{1}^{9} \beta^{8} \delta \\ & -2{,}716{,}800x_{1}^{9} \beta^{7}\delta^{2}-1{,}264{,}704 x_{1}^{9} \beta^{6}\delta^{3}-249{,}576x_{1}^{9}\beta^{5}{ \delta}^{4} -4356x_{1}^{9} \beta^{4}\delta^{5} \\ & +3416{{x_{1} }}^{9}\beta^{3}\delta^{6}+912{,}384x_{1}^{8} \beta^{10}+ 2{,}799{,}744x_{1}^{8} \beta^{9}\delta+3{,}244{,}160x_{1}^{8}{\beta }^{8}\delta^{2}\\ &+1{,}875{,}520x_{1}^{8}\beta^{7} \delta^{3}+ 581{,}760x_{1}^{8} \beta^{6}\delta^{4}+93{,}352x_{1}^{8}{ \beta}^{5}\delta^{5}+6152x_{1}^{8} \beta^{4}\delta^{6} \\ & - 741{,}888x_{1}^{7} \beta^{11}-2{,}790{,}144x_{1}^{7} \beta^{10} \delta-4{,}051{,}200x_{1}^{7}\beta^{9} \delta^{2}-2{,}981{,}760x_{1}^{7} \beta^{8}\delta ^{3}\\ &-1{,}188{,}000x_{1}^{7} \beta^{7}{ \delta}^{4}-244{,}464x_{1}^{7} \beta^{6}\delta^{5}-20{,}352 x_{1}^{7} \beta^{5}\delta ^{6}-458{,}752x_{1}^{6} \beta^{12} \\ & -1{,}376{,}256x_{1}^{6}\beta^{11} \delta-1{,}720{,}320x_{1}^{6}{ \beta}^{10} \delta^{2}-1{,}146{,}880x_{1}^{6} \beta^{9}\delta^{3} -430{,}080x_{1}^{6} \beta^{8}\delta^{4} \\ & -86{,}016x_{1}^{6}{ \beta}^{7}\delta^{5}-7168x_{1}^{6} \beta^{6}\delta^{6}+9 {h}^{3}x_{1}^{14} +72{h}^{3}x_{1}^{13} \beta+36{h}^{3} x_{1}^{13} \delta+192{h}^{3}x_{1}^{12} \beta^{2} \\ & +99{h}^{3} x_{1}^{12} \beta\delta+540{h}^{3}x_{1}^{11} \beta^{3}+ 342{h}^{3}x_{1}^{11} \beta^{2}\delta+36{h}^{3}x_{1}^{11 }\beta \delta^{2}-48{h}^{3}x_{1}^{10} \beta^{4} \\ & -108{h}^{3 }x_{1}^{10} \beta^{3}\delta-42{h}^{3}x_{1}^{10} \beta^{2 }\delta^{2}+432{h}^{3}x_{1}^{9} \beta^{5}+264{h}^{3} x_{1}^{9} \beta^{4}\delta+24{h}^{3}x_{1}^{9}\beta^{3} \delta ^{2}\\ &-672{h}^{3}x_{1}^{8} \beta^{6} -672{h}^{3}x_{1}^{8}{ \beta}^{5}\delta-168{h}^{3}x_{1}^{8} \beta^{4}\delta^{2}+570 {h}^{2}x_{1}^{14} \beta-27{h}^{2}x_{1}^{14}\delta \\ &-684{h }^{2}x_{1}^{13}\beta\delta -108{h}^{2}x_{1}^{13} \delta^{2}-4656{h}^{2}x_{1}^{12} \beta^{3}-6356{h}^{2}x_{1}^{ 12} \beta^{2}\delta -1559{h}^{2}x_{1}^{12} \beta\delta^{2} \\ & - 17{,}664{h}^{2}x_{1}^{11} \beta^{4}-18{,}760{h}^{2}x_{1}^{11} \beta^{3}\delta-4478{h}^{2}x_{1}^{11} \beta^{2}\delta^{2}- 108{h}^{2}x_{1}^{11} \beta\delta^{3} \\ &-17{,}056{h}^{2}{x_{1} }^{10}\beta^{5}-15{,}600{h}^{2}x_{1}^{10} \beta^{4}\delta-5220 {h}^{2}x_{1}^{10} \beta^{3}\delta^{2} -772{h}^{2}x_{1} ^{10} \beta^{2}\delta^{3}\\ &+2784{h}^{2}x_{1}^{9} \beta^{6}- 4752{h}^{2}x_{1}^{9} \beta^{5}\delta-2928{h}^{2}x_{1}^{ 9} \beta^{4}\delta^{2}-180{h}^{2}x_{1}^{9} \beta^{3}{\delta }^{3}-9696{h}^{2}x_{1}^{8} \beta^{7} \\ & -1728{h}^{2}x_{1}^{ 8} \beta^{6}\delta+3528{h}^{2}x_{1}^{8} \beta^{5}\delta^{2} +984{h}^{2}x_{1}^{8} \beta^{4}\delta^{3}+25{,}600{h}^{2}{{ x_{1}}}^{7}\beta^{8} \\ & +38{,}400{h}^{2}x_{1}^{7} \beta^{7}\delta+ 19{,}200{h}^{2}x_{1}^{7} \beta^{6}\delta^{2}+3200{h}^{2}x_{1}^{7} \beta^{5}\delta^{3}+2448hx_{1}^{14} \beta^{2}\\ &- 1140hx_{1}^{14}\beta\delta +27hx_{1}^{14}\delta^{2}- 63{,}456hx_{1}^{13}\beta^{3}-24{,}240hx_{1}^{13} \beta^{2} \delta+1152hx_{1}^{13}\beta\delta^{2} \\ &+108hx_{1}^{13} \delta^{3}+137{,}616hx_{1}^{12} \beta^{4}+125{,}868hx_{1}^{ 12} \beta^{3}\delta+35{,}244hx_{1}^{12} \beta^{2}\delta^{2} \\ & + 2821hx_{1}^{12} \beta\delta^{3}-28{,}320hx_{1}^{11}{ \beta}^{5}+72{,}360hx_{1}^{11} \beta^{4}\delta+87{,}216hx_{1} ^{11} \beta^{3}\delta^{2} \\ & +19{,}458hx_{1}^{11} \beta^{2}{\delta }^{3}+108hx_{1}^{11} \beta\delta^{4}+482{,}496hx_{1}^{10 } \beta^{6}+748{,}496hx_{1}^{10}\beta^{5} \delta\\&+347{,}640hx_{1}^{10}\beta^{4}\delta ^{2}+54{,}032hx_{1}^{10}\beta^{3}{ \delta}^{3}+1670hx_{1}^{10} \beta^{2}\delta^{4}-31{,}744h{{ x_{1}}}^{9} \beta^{7} \\ & -108{,}576hx_{1}^{9}\beta^{6}\delta-30{,}384 hx_{1}^{9}\beta^{5}\delta^{2}+15{,}712hx_{1}^{9} \beta ^{4}\delta^{3}+5496hx_{1}^{9} \beta^{3}\delta^{4} \\ & +151{,}040 hx_{1}^{8} \beta^{8}+419{,}328hx_{1}^{8} \beta^{7}\delta+ 318{,}432hx_{1}^{8}\beta^{6} \delta^{2}+92{,}272hx_{1}^{8}{ \beta}^{5}\delta^{3}\\ &+9000hx_{1}^{8} \beta^{4}\delta^{4}- 83{,}200hx_{1}^{7} \beta^{9}-377{,}600hx_{1}^{7} \beta^{8} \delta-403{,}200hx_{1}^{7} \beta^{7}\delta^{2} \\ & -161{,}600hx_{1}^{7}\beta^{6} \delta^{3}-22{,}000hx_{1}^{7} \beta^{5}{ \delta}^{4}-284{,}160hx_{1}^{6} \beta^{10}-568{,}320hx_{1}^{6 } \beta^{9}\delta \\ &-426{,}240hx_{1}^{6} \beta^{8}\delta^{2} -142{,}080hx_{1}^{6}\beta^{7} \delta^{3}-17{,}760hx_{1}^{6}{ \beta}^{6}\delta^{4}-32{,}448x_{1}^{14} \beta^{3} \\ & -2448x_{1}^{14}\beta^{2} \delta +570x_{1}^{14}\beta\delta^{2}-9 x_{1}^{14}\delta^{3}+245{,}376x_{1}^{13}\beta^{4}+143{,}040 x_{1}^{13}\beta^{3}\delta \\ & +24{,}240x_{1}^{13} \beta^{2}{ \delta}^{2}-540x_{1}^{13} \beta\delta^{3}-36x_{1}^{13 } \delta^{4}-144{,}192x_{1}^{12} \beta^{5}-8992x_{1}^{12} \beta^{4} \delta\\ &-56{,}436x_{1}^{12}\beta^{3} \delta^{2}-29{,}080 x_{1}^{12} \beta^{2}\delta^{3}-1361x_{1}^{12} \beta{ \delta}^{4}-533{,}120x_{1}^{11} \beta^{6} \\ & -1{,}425{,}312x_{1}^{11 } \beta^{5}\delta-886{,}928x_{1}^{11}\beta^{4} \delta^{2}- 202{,}260x_{1}^{11} \beta^{3}\delta^{3}-15{,}322x_{1}^{11}{ \beta}^{2}\delta^{4} \\ &-36x_{1}^{11} \beta\delta^{5}+133{,}376 x_{1}^{10} \beta^{7}-56{,}960x_{1}^{10} \beta^{6}\delta - 665{,}360x_{1}^{10}\beta^{5} \delta^{2}-434{,}232x_{1}^{10} \beta^{4}\delta^{3}\\&-77{,}448x_{1}^{10} \beta^{3}\delta^{4}- 856x_{1}^{10} \beta^{2}\delta^{5}-3{,}612{,}160x_{1}^{9}{ \beta}^{8}-7{,}345{,}024x_{1}^{9} \beta^{7}\delta \\ & -5{,}143{,}680{x_{1} }^{9}\beta^{6} \delta^{2}-1{,}545{,}648x_{1}^{9} \beta^{5}{\delta }^{3}-184{,}952x_{1}^{9} \beta^{4}\delta^{4}-5340x_{1}^{ 9} \beta^{3}\delta^{5} \\ & +2{,}267{,}392x_{1}^{8} \beta^{9}+4{,}674{,}560 x_{1}^{8} \beta^{8}\delta+3{,}189{,}760x_{1}^{8}\beta^{7}{ \delta}^{2}+793{,}856x_{1}^{8} \beta^{6}\delta^{3}\\ &+4680 x_{1}^{8} \beta^{5}\delta^{4}-17{,}640x_{1}^{8} \beta^{4}{ \delta}^{5}-2{,}352{,}640x_{1}^{7} \beta^{10}-5{,}672{,}960x_{1}^{7 } \beta^{9}\delta \\ & -5{,}053{,}440x_{1}^{7}\beta^{8} \delta^{2}- 2{,}117{,}120x_{1}^{7} \beta^{7}\delta^{3}-421{,}920x_{1}^{7}{ \beta}^{6}\delta^{4}-32{,}320x_{1}^{7} \beta^{5}\delta^{5} \\ &+ 1{,}723{,}904x_{1}^{6} \beta^{11} +5{,}250{,}560x_{1}^{6}\beta^{10 } \delta+6{,}001{,}920x_{1}^{6}\beta^{9} \delta^{2}+3{,}281{,}920 x_{1}^{6}\beta^{8} \delta^{3} \\ &+867{,}040x_{1}^{6} \beta^{7}{ \delta}^{4}+88{,}992x_{1}^{6} \beta^{6}\delta^{5} +917{,}504x_{1}^{5}\beta^{12}+2{,}293{,}760x_{1}^{5} \beta^{11}\delta \\ &+ 2{,}293{,}760x_{1}^{5} \beta^{10}\delta^{2}+1{,}146{,}880x_{1}^{5 } \beta^{9}\delta^{3}+286{,}720x_{1}^{5} \beta^{8}\delta^{4}+28{,}672x_{1}^{5}\beta^{7} \delta^{5}\\&-72{h}^{3}x_{1}^{ 12} \beta-192{h}^{3}x_{1}^{11} \beta^{2}-828{h}^{3}x_{1} ^{10} \beta^{3}-216{h}^{3}x_{1}^{10} \beta^{2}\delta+96{h}^{3}x_{1}^{9} \beta^{4} \\ & +108{h}^{3}x_{1}^{9} \beta^{3} \delta-864{h}^{3}x_{1}^{8} \beta^{5}-264{h}^{3}x_{1}^{8 } \beta^{4}\delta+1344{h}^{3}x_{1}^{7} \beta^{6}+672{h}^{3} x_{1}^{7} \beta^{5}\delta \\ &+288{h}^{2}x_{1}^{12} \beta^{2} +216{h}^{2}x_{1}^{12} \beta\delta +5880{h}^{2}x_{1}^{11} \beta^{3}+3568{h}^{2}x_{1}^{11} \beta^{2}\delta+18{,}360{h}^{ 2}x_{1}^{10} \beta^{4} \\ & +10{,}652{h}^{2}x_{1}^{10} \beta^{3} \delta+648{h}^{2}x_{1}^{10} \beta^{2}\delta^{2}+17{,}664{h}^{ 2}x_{1}^{9} \beta^{5}+12{,}048{h}^{2}x_{1}^{9} \beta^{4} \delta\\ &+2628{h}^{2}x_{1}^{9} \beta^{3}\delta^{2}+6048{h}^{2 }x_{1}^{8} \beta^{6}+12{,}744{h}^{2}x_{1}^{8} \beta^{5} \delta+2904{h}^{2}x_{1}^{8} \beta^{4}\delta^{2}+10{,}080{h}^{ 2}x_{1}^{7} \beta^{7} \\ & -2736{h}^{2}x_{1}^{7} \beta^{6} \delta-2880{h}^{2}x_{1}^{7} \beta^{5}\delta^{2}-38{,}400{h}^{ 2}x_{1}^{6} \beta^{8}-38{,}400{h}^{2}x_{1}^{6} \beta^{7} \delta \\ &-9600{h}^{2}x_{1}^{6} \beta^{6}\delta^{2}+21{,}840h{{ x_{1}}}^{12} \beta^{3} -576hx_{1}^{12}\beta^{2}\delta-216h x_{1}^{12}\beta\delta^{2}-97{,}744hx_{1}^{11} \beta^{4} \\ & - 50{,}512hx_{1}^{11} \beta^{3}\delta-6560hx_{1}^{11}\beta ^{2}\delta^{2}+16{,}416hx_{1}^{10} \beta^{5}-87{,}432hx_{1} ^{10}\beta^{4} \delta\\&-43{,}124hx_{1}^{10}\beta^{3} \delta^{2}- 648hx_{1}^{10} \beta^{2}\delta^{3}-549{,}504hx_{1}^{9}{ \beta}^{6}-538{,}064hx_{1}^{9} \beta^{5}\delta \\ & -130{,}224hx_{1}^{9}\beta^{4} \delta^{2}-5580hx_{1}^{9} \beta^{3}\delta^{3}+121{,}216hx_{1}^{8} \beta^{7}+100{,}896hx_{1}^{8} \beta^{6}\delta \end{aligned}$$

$$\begin{aligned} \hphantom{f_{2}:={}}&-27{,}008hx_{1}^{8} \beta^{5}\delta^{2} -17{,}832hx_{1}^{8}\beta^{4} \delta^{3}-350{,}720hx_{1}^{7} \beta^{8}- 592{,}512hx_{1}^{7} \beta^{7}\delta \\ & -276{,}448hx_{1}^{7}{\beta }^{6}\delta^{2}-38{,}208hx_{1}^{7} \beta^{5}\delta^{3}+179{,}200 hx_{1}^{6} \beta^{9}+480{,}000hx_{1}^{6}\beta^{8}\delta\\ &+ 320{,}000hx_{1}^{6}\beta^{7} \delta^{2}+62{,}400hx_{1}^{6}{ \beta}^{6}\delta^{3}+378{,}880hx_{1}^{5} \beta^{10}+568{,}320h{{ x_{1}}}^{5} \beta^{9}\delta \\ & +284{,}160hx_{1}^{5}\beta^{8}{ \delta}^{2}+47{,}360hx_{1}^{5} \beta^{7}\delta^{3}-50{,}112{{ x_{1}}}^{12} \beta^{4}-21{,}840x_{1}^{12} \beta^{3}\delta \\ & +288 x_{1}^{12} \beta^{2}\delta^{2}+72x_{1}^{12} \beta{ \delta}^{3}-63{,}456x_{1}^{11}\beta^{5}+18{,}512x_{1}^{11}{ \beta}^{4}\delta+44{,}632x_{1}^{11} \beta^{3}\delta^{2} \\ & +3184{ x_{1}}^{11} \beta^{2}\delta^{3}+843{,}840x_{1}^{10} \beta^{ 6}+967{,}728x_{1}^{10} \beta^{5}\delta+309{,}040x_{1}^{10}{ \beta}^{4} \delta^{2}\\ &+33{,}300x_{1}^{10} \beta^{3}\delta^{3}+ 216x_{1}^{10} \beta^{2}\delta^{4}-606{,}464x_{1}^{9}{ \beta}^{7}+58{,}752x_{1}^{9} \beta^{6}\delta+559{,}920x_{1}^{ 9} \beta^{5}\delta^{2} \\ & +171{,}824x_{1}^{9}\beta^{4} \delta^{3 }+2844x_{1}^{9} \beta^{3}\delta^{4}+4{,}401{,}280x_{1}^{8}{ \beta}^{8}+6{,}167{,}456x_{1}^{8} \beta^{7}\delta \\ & +2{,}747{,}072{x_{1} }^{8} \beta^{6}\delta^{2}+431{,}496x_{1}^{8} \beta^{5}\delta ^{3}+15{,}192x_{1}^{8}\beta^{4} \delta^{4}-3{,}089{,}280x_{1}^{7} \beta^{9}\\ &-4{,}290{,}880x_{1}^{7} \beta^{8}\delta-1{,}620{,}960{{ x_{1}}}^{7} \beta^{7}\delta^{2}-28{,}144x_{1}^{7} \beta^{6}{ \delta}^{3}+54{,}096x_{1}^{7} \beta^{5}\delta^{4} \\ & +3{,}543{,}040x_{1}^{6}\beta^{10}+6{,}564{,}480x_{1}^{6} \beta^{9}\delta+ 4{,}249{,}600x_{1}^{6} \beta^{8}\delta^{2}+1{,}150{,}560x_{1}^{6} \beta^{7}\delta^{3} \\ & +110{,}400x_{1}^{6} \beta^{6}\delta^{4}- 2{,}455{,}040x_{1}^{5} \beta^{11}-5{,}850{,}880x_{1}^{5}\beta^{10 } \delta-4{,}951{,}680x_{1}^{5}\beta^{9} \delta^{2} \\ &-1{,}791{,}040x_{1}^{5} \beta^{8}\delta ^{3}-235{,}520x_{1}^{5} \beta^{7}{ \delta}^{4}-1{,}146{,}880x_{1}^{4} \beta^{12} -2{,}293{,}760x_{1}^{4 }\beta^{11} \delta\\ &-1{,}720{,}320x_{1}^{4}\beta^{10} \delta^{2}- 573{,}440x_{1}^{4} \beta^{9}\delta^{3}-71{,}680x_{1}^{4}{ \beta}^{8}\delta^{4}+288{h}^{3}x_{1}^{9} \beta^{3}-48{h}^{ 3}x_{1}^{8} \beta^{4} \\ & +432{h}^{3}x_{1}^{7} \beta^{5}-672 {h}^{3}x_{1}^{6} \beta^{6} -2368{h}^{2}x_{1}^{10} \beta ^{3}-6352{h}^{2}x_{1}^{9} \beta^{4}-864{h}^{2}x_{1}^{9} \beta^{3}\delta \\ & -8480{h}^{2}x_{1}^{8} \beta^{5}-3824{h}^{2} x_{1}^{8} \beta^{4}\delta-10{,}848{h}^{2}x_{1}^{7} \beta^{6 }-6912{h}^{2}x_{1}^{7} \beta^{5}\delta-3744{h}^{2}x_{1} ^{6}\beta^{7} \\ & +2400{h}^{2}x_{1}^{6} \beta^{6}\delta+25{,}600{h }^{2}x_{1}^{5} \beta^{8}+12{,}800{h}^{2}x_{1}^{5} \beta^{7} \delta+24{,}976hx_{1}^{10}\beta^{4}+4736hx_{1}^{10}{ \beta }^{3}\delta\\&+11{,}232hx_{1}^{9} \beta^{5}+36{,}960hx_{1}^{9}{ \beta}^{4}\delta+864hx_{1}^{9} \beta^{3}\delta^{2}+302{,}496h x_{1}^{8} \beta^{6}+147{,}376hx_{1}^{8}\beta^{5}\delta \\ &+ 7792hx_{1}^{8}\beta^{4} \delta^{2}-104{,}064hx_{1}^{7}{ \beta}^{7}-4192hx_{1}^{7} \beta^{6}\delta+28{,}272hx_{1}^{ 7} \beta^{5}\delta^{2}+369{,}280hx_{1}^{6} \beta^{8} \\ & +377{,}088h x_{1}^{6}\beta^{7} \delta+83{,}712hx_{1}^{6}\beta^{6}{ \delta}^{2}-185{,}600hx_{1}^{5} \beta^{9}-291{,}200hx_{1}^{5} \beta^{8}\delta \\ & -92{,}800hx_{1}^{5} \beta^{7}\delta^{2} -284{,}160hx_{1}^{4} \beta^{10}-284{,}160hx_{1}^{4}\beta^{9}\delta -71{,}040hx_{1}^{4}\beta^{8} \delta^{2} \\ & +38{,}304x_{1}^{10}{ \beta}^{5}-24{,}976x_{1}^{10} \beta^{4}\delta-2368x_{1}^{ 10} \beta^{3}\delta^{2}-475{,}968x_{1}^{9} \beta^{6}-244{,}512{ x_{1}}^{9}\beta^{5} \delta\\ &-30{,}608x_{1}^{9}\beta^{4}{\delta }^{2}-288x_{1}^{9}\beta^{3} \delta^{3}+432{,}000x_{1}^{8 } \beta^{7}-200{,}256x_{1}^{8} \beta^{6}\delta-193{,}392{x_{1} }^{8} \beta^{5}\delta^{2} \\ & -3920x_{1}^{8}\beta^{4} \delta^{ 3}-3{,}033{,}216x_{1}^{7} \beta^{8}-2{,}654{,}720x_{1}^{7} \beta^{ 7}\delta-590{,}912x_{1}^{7} \beta^{6}\delta^{2} \\ & -21{,}792{{x_{1} }}^{7}\beta^{5}\delta^{3}+2{,}387{,}584x_{1}^{6} \beta^{9}+1{,}954{,}560x_{1}^{6}\beta^{8} \delta+164{,}832x_{1}^{6}\beta ^{7} \delta^{2}\\ &-94{,}176x_{1}^{6} \beta^{6}\delta^{3}-3{,}270{,}144 x_{1}^{5} \beta^{10} -4{,}404{,}480x_{1}^{5} \beta^{9}\delta- 1{,}849{,}088x_{1}^{5} \beta^{8}\delta^{2} \\ & -242{,}752x_{1}^{5}{ \beta}^{7} \delta^{3}+2{,}204{,}160x_{1}^{4} \beta^{11}+3{,}870{,}720{{ x_{1}}}^{4} \beta^{10}\delta+2{,}160{,}768x_{1}^{4} \beta^{9}{ \delta}^{2} \\ &+388{,}224x_{1}^{4} \beta^{8}\delta^{3} +917{,}504x_{1}^{3}\beta^{12}+1{,}376{,}256x_{1}^{3} \beta^{11}\delta+ 688{,}128x_{1}^{3} \beta^{10}\delta^{2} \\ & +114{,}688x_{1}^{3}{ \beta}^{9}\delta^{3}+1792{h}^{2}x_{1}^{7} \beta^{5}+4416{h }^{2}x_{1}^{6} \beta^{6}+192{h}^{2}x_{1}^{5}\beta^{7}- 6400{h}^{2}x_{1}^{4}\beta^{8} \\ & -8832hx_{1}^{8} \beta^{5} -64{,}896hx_{1}^{7} \beta^{6}-3584hx_{1}^{7} \beta^{5} \delta+28{,}480hx_{1}^{6} \beta^{7}-16{,}896hx_{1}^{6}\beta ^{6} \delta\\ &-187{,}904hx_{1}^{5}\beta^{8}-90{,}432hx_{1}^{5}{ \beta}^{7}\delta+94{,}720hx_{1}^{4} \beta^{9}+68{,}480hx_{1}^{4} \beta^{8}\delta \\ &+113{,}664hx_{1}^{3} \beta^{10} +56{,}832h x_{1}^{3}\beta^{9} \delta+95{,}872x_{1}^{8}\beta^{6}+8832{ x_{1}}^{8}\beta^{5}\delta-97{,}792x_{1}^{7} \beta^{7} \\ & +89{,}728 x_{1}^{7} \beta^{6}\delta+1792x_{1}^{7} \beta^{5}{ \delta}^{2}+1{,}114{,}880x_{1}^{6}\beta^{8}+462{,}016x_{1}^{6}{ \beta}^{7}\delta+12{,}480x_{1}^{6} \beta^{6}\delta^{2} \\ & -1{,}010{,}432 x_{1}^{5} \beta^{9}-317{,}440x_{1}^{5} \beta^{8}\delta+ 81{,}664x_{1}^{5} \beta^{7}\delta^{2}+1{,}829{,}888x_{1}^{4}{ \beta}^{10}\\ &+1{,}600{,}384x_{1}^{4} \beta^{9}\delta+327{,}296{x_{1} }^{4} \beta^{8}\delta^{2}-1{,}222{,}144x_{1}^{3} \beta^{11}- 1{,}410{,}304x_{1}^{3} \beta^{10}\delta \\ & -390{,}144x_{1}^{3}\beta^{9} \delta^{2} -458{,}752x_{1}^{2} \beta^{12}-458{,}752x_{1}^{2} \beta^{11}\delta-114{,}688x_{1}^{2}\beta ^{10}\delta^{2} +512hx_{1}^{5} \beta^{7} \\ & +37{,}632hx_{1}^{4} \beta^{8}-19{,}200hx_{1}^{3}\beta^{9}-18{,}944hx_{1}^{2} \beta^{10}- 2048x_{1}^{6} \beta^{7}-170{,}240x_{1}^{5} \beta^{8} \\ &-512 x_{1}^{5}\beta^{7} \delta+196{,}608x_{1}^{4}\beta^{9} -20{,}224x_{1}^{4}\beta^{8} \delta-571{,}904x_{1}^{3}\beta^{ 10}-244{,}224x_{1}^{3} \beta^{9}\delta \\ &+383{,}488x_{1}^{2}{ \beta}^{11}+218{,}624x_{1}^{2} \beta^{10}\delta+131{,}072x_{1} \beta^{12} +65{,}536x_{1}\beta^{11}\delta-8192x_{1}^{3 } \beta^{9}\\ &+76{,}800x_{1}^{2}\beta^{10}-52{,}224x_{1}{ \beta }^{11}-16{,}384\beta^{12}. \end{aligned}$$

$g_{1}$ and $g_{2}$ in Theorem 3.1 are given by

$$\begin{aligned} g_{1}={}& 256 h^{2} \beta^{9}-1408 h^{2} \beta^{8}\delta-3264 h^{2} \beta ^{7}\delta^{2} -4128 h^{2} \beta^{6}\delta^{3}-3072 h^{2} \beta^{5}\delta^{4}-1344 h^{2} \beta^{4}\delta^{5} \\ & -320 h ^{2} \beta^{3}\delta^{6}-32 h^{2} \beta^{2} \delta^{7}+1024 h \beta^{1}0 +6144 h\beta^{9}\delta+15{,}872 h \beta^{8}\delta^{2} +23{,}040 h\beta^{7} \delta^{3} \\ &+20{,}544 h\beta^{6}\delta^{4}+ 11{,}520 h \beta^{5}\delta^{5} +3968 h\beta^{4}\delta^{6}+768 h \beta ^{3}\delta^{7}+64 h\beta^{2} \delta^{8}-256 \beta^{9} \delta ^{2} \\ & -1408 \beta^{8}\delta^{3}-3456 \beta^{7} \delta^{4} -4992 \beta^{6}\delta^{5}-4608 \beta^{5}\delta^{6}-2688\beta^{4}\delta^{7}-896 \beta^{3} \delta^{8}\\&-128 \beta^{2} \delta ^{9}-64 h^{3}\beta^{7}-288 h^{3} \beta^{6}\delta-512 h^{3}\beta^{5} \delta^{2} -448 h^{3}\beta^{4} \delta^{3}-192 h^{3}\beta^{3} \delta^{4} \\ & -32 h^{3}\beta^{2} \delta^{5}+ 768 h^{2} \beta^{8}+3456 h^{2} \beta^{7}\delta+6624 h^{2} \beta ^{6} \delta^{2} +7104 h^{2} \beta^{5} \delta^{3}+4640 h^{2} \beta^{4} \delta^{4} \\ & +1824 h^{2} \beta^{3} \delta^{5}+384 h ^{2} \beta^{2} \delta^{6}+32 h^{2} \beta\delta^{7}-2304 h \beta ^{9}-11{,}136 h\beta^{8}\delta-23{,}808 h\beta^{7}\delta^{2} \\ &- 30{,}144 h\beta^{6}\delta^{3}-25{,}088 h\beta^{5} \delta^{4} -13{,}888 h\beta^{4}\delta^{5}-4800 h \beta^{3}\delta^{6}-896 h \beta ^{2} \delta^{7} \\ &-64 h\beta\delta^{8}+896 \beta^{8} \delta^{2} +3712 \beta^{7}\delta^{3}+6656 \beta^{6}\delta^{4}+7040 \beta ^{5} \delta^{5} +4928 \beta^{4}\delta^{6}+2240 \beta^{3} \delta^{7}\\& +576 \beta^{2} \delta^{8}+64 \beta \delta^{9}-96 h^{4}\beta^{5}-248 h^{4}\beta^{4}\delta-216 h^{4} \beta^{3} \delta^{2} -72 h^{4} \beta^{2} \delta^{3}-8 h^{4}\beta \delta ^{4} \\ &+960 h^{3} \beta^{6}+3072 h^{3}\beta^{5}\delta+ 3712 h^{3}\beta^{4}\delta^{2} +2112 h^{3}\beta^{3}\delta^{3}+576 h^{3}\beta^{2} \delta^{4}+64 h^{3}\beta\delta^{5} \\ & -3456 h^{2} \beta^{7}-12{,}544 h^{2} \beta^{6}\delta-18{,}944 h^{2} \beta^{5} \delta^{2} -15{,}584 h^{2} \beta^{4} \delta^{3}-7456 h^{2} \beta^{3} \delta^{4} \\ & -1952 h^{2} \beta^{2} \delta^{5}- 224 h^{2} \beta\delta^{6}+4864 h\beta^{8}+18{,}688 h\beta^{7} \delta+32{,}640 h \beta^{6}\delta^{2} \\ & +35{,}200 h\beta^{5} \delta^{3} +25{,}152 h\beta^{4}\delta^{4}+11{,}328 h \beta^{3}\delta^{5}+2880 h\beta^{2} \delta^{6}+320 h\beta\delta^{7}\\ &+384 \beta^{8} \delta-384 \beta^{7}\delta^{2} -3840 \beta^{6} \delta^{3}-6912 \beta^{5}\delta^{4}-6720 \beta^{4}\delta^{5}-4032 \beta^{3} \delta^{6}-1344 \beta^{2} \delta^{7} \\ & -192 \beta\delta^{8} +480 h^{4}\beta^{4}+960 h^{4}\beta^{3}\delta+672 h^{4} \beta ^{2} \delta^{2} +216 h^{4}\beta \delta^{3}+24 h^{4} \delta ^{4}-3840 h^{3}\beta^{5} \\ & -9600 h^{3} \beta^{4}\delta- 9216 h^{3}\beta^{3}\delta^{2} -4416 h^{3}\beta^{2} \delta^{3}-1056 h^{3}\beta\delta^{4}-96 h^{3} \delta^{5}+10{,}240 h ^{2} \beta^{6} \\ & +30{,}080 h^{2} \beta^{5}\delta+37{,}632 h^{2} \beta ^{4}\delta^{2}+26{,}368 h^{2} \beta^{3}\delta^{3}+10{,}752 h^{2} \beta ^{2} \delta^{4}+2400 h^{2} \beta\delta^{5} \\ & +224 h^{2} \delta ^{6}-10{,}240 h\beta^{7}-33{,}280 h\beta^{6} \delta-52{,}480 h \beta ^{5}\delta^{2}-52{,}480 h\beta^{4}\delta^{3}\\ &-33{,}536 h\beta ^{3}\delta^{4}-13{,}056 h\beta^{2} \delta^{5}-2816 h\beta \delta ^{6}-256 h \delta^{7}+512 \beta^{8}+1536 \beta^{7} \delta \\ & +5632 \beta^{6}\delta^{2}+11{,}648 \beta^{5}\delta^{3}+13{,}440 \beta ^{4}\delta^{4}+9856 \beta^{3} \delta^{5}+4480 \beta^{2} \delta ^{6}+1152 \beta\delta^{7} \\ &+128 \delta^{8}-8 h^{6} \beta-h^{6}\delta+120 h^{5}\beta^{2} +96 h^{5}\beta\delta+ 18 h^{5}\delta^{2} -1056 h^{4}\beta^{3}-1308 h^{4} \beta^{2} \delta \\ & -600 h^{4}\beta\delta^{2} -96 h^{4}\delta^{3}+5056 h^{3} \beta^{4}+8448 h^{3}\beta^{3}\delta+5808 h^{3} \beta ^{2} \delta^{2} +1952 h^{3}\beta\delta^{3}\\ &+264 h^{3} \delta ^{4}-10{,}880 h^{2} \beta^{5}-22{,}832 h^{2} \beta^{4}\delta- 21{,}760 h^{2} \beta^{3}\delta^{2} -11{,}488 h^{2} \beta^{2} \delta ^{3} \\ & -3328 h^{2} \beta\delta^{4}-416 h^{2} \delta^{5}+8064 h\beta^{6}+18{,}944 h\beta^{5} \delta+24{,}480 h\beta^{4}\delta^{2} +20{,}096 h \beta^{3}\delta^{3} \\ & +10{,}144 h\beta^{2} \delta^{4}+2880 h\beta\delta^{5}+352 h\delta^{6}-512 \beta^{7}-832 \beta ^{6}\delta-2688 \beta^{5} \delta^{2} -4480 \beta^{4}\delta^{3} \\ & -4480 \beta^{3}\delta^{4}-2688 \beta^{2} \delta^{5}-896 \beta\delta^{6}-128 \delta^{7}, \\ g_{2}={}& 384 h^{2}\beta^{8} \delta^{2}+1920 h^{2}\beta^{7} \delta^{3} +3936 h^{2}\beta^{6} \delta^{4}+4224 h^{2}\beta^{5} \delta ^{5}+2496 h^{2}\beta^{4}\delta^{6}+768 h^{2}\beta^{3} \delta^{7} \\ & +96 h^{2}\beta^{2}\delta^{8}-1536 h\beta^{9} \delta ^{2}-8448 h \beta^{8}\delta^{3}-19{,}584 h\beta^{7}\delta ^{4}-24{,}768 h\beta^{6}\delta^{5} \\ & -18{,}432 h \beta^{5}\delta^{6}- 8064 h\beta^{4} \delta^{7}-1920 h\beta^{3}\delta^{8}-192 h \beta ^{2}\delta^{9}+384 \beta^{8} \delta^{4}+1920 \beta^{7} \delta ^{5} \\ & +3968 \beta^{6}\delta^{6}+4352 \beta^{5} \delta^{7} +2688 \beta^{4}\delta^{8}+896 \beta^{3}\delta^{9}+128 \beta ^{2} \delta^{1}0-192 h^{4}\beta^{7}\\ &-768 h^{4} \beta^{6} \delta-1216 h^{4}\beta^{5} \delta^{2}-968 h^{4}\beta^{4} \delta ^{3}-408 h^{4}\beta^{3}\delta^{4}-88 h^{4}\beta^{2} \delta^{5}-8 h^{4} \beta\delta^{6} \\ &+1792 h^{3}\beta^{8} + 8192 h^{3}\beta^{7}\delta+15{,}456 h^{3} \beta^{6}\delta^{2}+ 15{,}552 h^{3} \beta^{5}\delta^{3}+8992 h^{3} \beta^{4}\delta ^{4} \\ & +2976 h^{3} \beta^{3}\delta^{5}+512 h^{3} \beta^{2} \delta ^{6}+32 h^{3}\beta \delta^{7}-4352 h^{2}\beta^{9}- 22{,}016 h^{2} \beta^{8}\delta \\ &-48{,}320 h^{2}\beta^{7} \delta^{2}- 60{,}384 h^{2}\beta^{6} \delta^{3}-47{,}104 h^{2}\beta^{5} \delta ^{4}-23{,}456 h^{2}\beta^{4} \delta^{5} -7264 h^{2}\beta^{3} \delta ^{6}\\ &-1280 h^{2}\beta^{2}\delta^{7}-96 h^{2}\beta \delta ^{8}+1024 h\beta^{1}0 +4608 h\beta^{9}\delta+12{,}928 h \beta ^{8} \delta^{2}+28{,}288 h\beta^{7}\delta^{3} \\ & +42{,}176 h\beta ^{6}\delta^{4}+39{,}680 h \beta^{5}\delta^{5}+23{,}168 h\beta^{4} \delta ^{6}+8192 h\beta^{3}\delta^{7}+1600 h \beta^{2}\delta^{8} \\ &+128 h\beta\delta^{9}-256 \beta^{9}\delta^{2} -1024 \beta ^{8}\delta^{3}-2560 \beta^{7} \delta^{4}-4992 \beta^{6} \delta^{5}-6400 \beta^{5}\delta^{6} \\ & -4928 \beta^{4} \delta^{7} -2240 \beta^{3}\delta^{8}-576 \beta^{2}\delta^{9}-64 \beta\delta^{1}0-32 h^{5}\beta^{5}-104 h^{5} \beta^{4} \delta-120 h^{5}\beta^{3} \delta^{2}\\ &-56 h^{5}\beta^{2} \delta ^{3}-8 h^{5}\beta\delta^{4}+832 h^{4}\beta^{6}+2688 h^{4} \beta^{5}\delta+3392 h^{4}\beta^{4} \delta^{2}+2128 h^{4}\beta^{3}\delta^{3} \\ &+672 h^{4}\beta^{2}\delta^{4}+80 h^{4} \beta\delta^{5}-5504 h^{3}\beta^{7}-19{,}840 h^{3} \beta ^{6}\delta-29{,}312 h^{3} \beta^{5}\delta^{2} \\ & -23{,}264 h^{3} \beta ^{4}\delta^{3}-10{,}720 h^{3}\beta^{3}\delta^{4}-2720 h ^{3}\beta^{2}\delta^{5}-288 h^{3} \beta\delta^{6}+11{,}520 h ^{2}\beta^{8} \\ & +46{,}336 h^{2}\beta^{7}\delta+81{,}088 h^{2} \beta^{6}\delta^{2}+81{,}984 h^{2}\beta^{5}\delta^{3}+52{,}448 h^{2} \beta ^{4}\delta^{4}+21{,}280 h^{2}\beta^{3}\delta^{5} \\ & +5088 h ^{2}\beta^{2}\delta^{6}+544 h^{2} \beta\delta^{7}-3072 h \beta ^{9}-11{,}648 h \beta^{8}\delta-27{,}264 h\beta^{7}\delta^{2}\\ &- 48{,}000 h \beta^{6}\delta^{3}-55{,}808 h\beta^{5} \delta^{4}-40{,}448 h\beta^{4}\delta^{5}-18{,}048 h \beta^{3}\delta^{6}-4608 h \beta ^{2} \delta^{7} \\ & -512 h\beta\delta^{8}+768 \beta^{8} \delta ^{2}+2304 \beta^{7} \delta^{3}+4224 \beta^{6}\delta^{4} +6528 \beta^{5}\delta^{5}+6720 \beta^{4} \delta^{6} \\ & +4032 \beta ^{3}\delta^{7}+1344 \beta^{2}\delta^{8}+192 \beta \delta ^{9}-56 h^{6}\beta^{3}-88 h^{6} \beta^{2}\delta-36 h ^{6}\beta\delta^{2}-4 h^{6}\delta^{3} \\ &+672 h^{5} \beta^{4} +1392 h^{5}\beta^{3}\delta+960 h^{5}\beta^{2}\delta^{2}+ 264 h^{5}\beta\delta^{3} +24 h^{5}\delta^{4}-4288 h^{4} \beta ^{5}\\&-10{,}752 h^{4}\beta^{4}\delta-10{,}512 h^{4}\beta^{3} \delta ^{2}-5200 h^{4}\beta^{2}\delta^{3}-1272 h^{4}\beta \delta ^{4}-120 h^{4} \delta^{5} \\ & +16{,}384 h^{3}\beta^{6}+48{,}128 h^{3} \beta^{5}\delta+59{,}904 h^{3}\beta^{4} \delta^{2}+41{,}728 h^{3}\beta^{3} \delta^{3}+16{,}896 h^{3}\beta^{2} \delta^{4} \\ &+ 3648 h^{3}\beta\delta^{5}+320 h^{3}\delta^{6} -27{,}520 h^{2} \beta^{7}-92{,}800 h^{2} \beta^{6}\delta-141{,}888 h^{2}\beta^{5} \delta^{2} \\ & -129{,}472 h^{2}\beta^{4} \delta^{3}-74{,}752 h^{2} \beta ^{3} \delta^{4}-26{,}880 h^{2}\beta^{2} \delta^{5}-5472 h ^{2}\beta\delta^{6}-480 h^{2} \delta^{7}\\ &+7680 h\beta^{8}+ 26{,}880 h\beta^{7} \delta+58{,}880 h\beta^{6}\delta^{2}+88{,}960 h \beta ^{5}\delta^{3}+85{,}632 h\beta^{4} \delta^{4} \\ & +52{,}352 h\beta ^{3}\delta^{5}+19{,}840 h \beta^{2}\delta^{6}+4224 h\beta \delta ^{7}+384 h\delta^{8}-2304 \beta^{7} \delta^{2}-6912 \beta^{6} \delta^{3} \\ & -11{,}648 \beta^{5}\delta^{4}-13{,}440 \beta^{4} \delta ^{5}-9856 \beta^{3}\delta^{6}-4480 \beta^{2} \delta^{7} -1152 \beta\delta^{8}-128 \delta^{9}-2 h^{7}\beta \\ & -2 h^{7} \delta+120 h^{6}\beta^{2}+92 h^{6}\beta\delta+21 h^{6} \delta ^{2}-1368 h^{5} \beta^{3}-1680 h^{5}\beta^{2}\delta- 720 h^{5}\beta\delta^{2} \\ &-114 h^{5} \delta^{3}+6976 h^{4} \beta^{4}+11{,}856 h^{4}\beta^{3}\delta+8196 h^{4} \beta^{2} \delta ^{2} +2696 h^{4}\beta\delta^{3}+360 h^{4} \delta^{4}\\ &- 18{,}784 h^{3}\beta^{5}-39{,}840 h^{3}\beta^{4}\delta-38{,}080 h^{3} \beta^{3}\delta^{2}-20{,}048 h^{3} \beta^{2}\delta^{3}-5664 h^{3}\beta \delta^{4} \\ & -680 h^{3}\delta^{5}+23{,}936 h^{2} \beta ^{6}+59{,}712 h^{2}\beta^{5}\delta+73{,}648 h^{2}\beta^{4} \delta ^{2}+54{,}976 h^{2}\beta^{3}\delta^{3} \\ &+25{,}344 h^{2} \beta ^{2}\delta^{4}+6656 h^{2}\beta\delta^{5} +768 h^{2} \delta ^{6}-6272 h\beta^{7}-15{,}872 h\beta^{6}\delta-30{,}208 h\beta^{5} \delta^{2} \\ & -37{,}920 h\beta^{4}\delta^{3}-29{,}952 h\beta^{3} \delta ^{4}-14{,}624 h\beta^{2}\delta^{5}-4032 h\beta\delta^{6} -480 h\delta^{7}-256 \beta^{7}\delta\\ &+960 \beta^{6}\delta^{2} +2688 \beta^{5}\delta^{3}+4480 \beta^{4} \delta^{4}+4480 \beta ^{3}\delta^{5}+2688 \beta^{2}\delta^{6} +896 \beta \delta ^{7}+128 \delta^{8}. \end{aligned}$$

$\widetilde{r}_{13}$ and $\widetilde{r}_{14}$ in (3.1) are given by

$$\begin{aligned} \widetilde{r}_{13}={}& 16 \beta^{5}x_{1}^{3}+24 \beta^{4}\delta x_{1}^{3}-28 \beta^{4}x_{1}^{4}+12 \beta^{3} \delta^{2}x_{1}^{3}-30 \beta^{3} \delta x_{1}^{4}+28 \beta^{3}x_{1}^{5}+2 { \beta}^{2}\delta^{3}x_{1}^{3} \\ & -10 \beta^{2}\delta^{2}x_{1}^{4}+19 \beta^{2}\delta x_{1}^{5}-28 \beta^{2}x_{1}^{6}-\beta \delta^{3}x_{1}^{4}+3 \beta \delta^{2}x_{1}^{5 }-16 \beta\delta x_{1}^{6}+9 \beta x_{1}^{7}-2 \delta ^{2}x_{1}^{6} \\ & +2 \delta x_{1}^{7}-48 \beta^{5}x_{1}^{2 }-48 \beta^{4}\delta x_{1}^{2}+76 \beta^{4}x_{1}^{3}-12 \beta^{3}\delta^{2}x_{1}^{2}+52 \beta^{3}\delta{x_{1} }^{3}-60 \beta^{3}x_{1}^{4}\\&+8 \beta^{2} \delta^{2}x_{1} ^{3}-20 \beta^{2} \delta x_{1}^{4}+48 \beta^{2}x_{1}^{5} +12 \beta\delta x_{1}^{5}-10 \beta x_{1}^{6}+48 \beta ^{5}x_{1}+24 \beta^{4}\delta x_{1}-68 \beta^{4}x_{1}^{2} \\ &-22 \beta^{3}\delta x_{1}^{2}+36 \beta ^{3}x_{1}^{3}+\beta^{2}\delta x_{1}^{3}-20 \beta^{2}x_{1}^{4}+ \beta x_{1}^{5}-16 \beta^{5}+20 \beta^{4}x_{1}-4 \beta^{3}x_{1}^{2}, \\ \widetilde{r}_{14}={}& 16{,}384 \beta^{12}x_{1}^{8}+65{,}536 \beta^{ 11}\delta x_{1}^{8}-1024 \beta^{11}x_{1}^{9}+114{,}688 { \beta}^{10}\delta^{2}x_{1}^{8}+22{,}784 \beta^{10}\delta x_{1}^{9} \\ &-3584 \beta^{10}x_{1}^{10} +114{,}688 \beta^{9}\delta^{ 3}x_{1}^{8}+82{,}176 \beta^{9}\delta^{2}x_{1}^{9}-56{,}320 { \beta}^{9}\delta x_{1}^{10}-12{,}032 \beta^{9}x_{1}^{11} \\ & + 71{,}680 \beta^{8}\delta^{4}x_{1}^{8}+119{,}744 \beta^{8}{\delta }^{3}x_{1}^{9}-143{,}488 \beta^{8}\delta^{2}x_{1}^{10}+38{,}256 \beta^{8}\delta x_{1}^{11}+5392 \beta^{8}x_{1}^{12} \\ & + 28{,}672 \beta^{7}\delta^{5}x_{1}^{8}+95{,}360 \beta^{7}\delta ^{4}x_{1}^{9}-165{,}152 \beta^{7}\delta^{3}x_{1}^{10}+142{,}176 \beta^{7}\delta^{2}x_{1}^{11}\\ &-123{,}024 \beta^{7}\delta x_{1}^{12}-77{,}392 \beta ^{7}x_{1}^{13}+7168 \beta^{6} \delta ^{6}x_{1}^{8}+45{,}168 \beta^{6}\delta^{5}x_{1}^{9}-105{,}120 \beta^{6}\delta^{4}x_{1}^{10} \\ & +164{,}428 \beta^{6}\delta^{3}{ x_{1}}^{11}-303{,}016 \beta^{6}\delta^{2}x_{1}^{12}-73{,}196 { \beta}^{6}\delta x_{1}^{13}+99{,}076 \beta^{6}x_{1}^{14} \\ & +1024 \beta^{5}\delta^{7}x_{1}^{8}+12{,}752 \beta^{5}\delta^{6}{ x_{1}}^{9}-39{,}152 \beta^{5}\delta^{5}x_{1}^{10}+94{,}516 { \beta}^{5}\delta^{4}x_{1}^{11}\\&-293{,}222 \beta^{5}\delta^{3}x_{1}^{12}+26{,}914 \beta ^{5}\delta^{2}x_{1}^{13}+92{,}054 { \beta}^{5}\delta x_{1}^{14}-88{,}632 \beta^{5}x_{1}^{15} \\ & +64 \beta^{4}\delta^{8}x_{1}^{8}+1988 \beta^{4}\delta^{7}x_{1}^{9}-8360 \beta^{4}\delta ^{6}x_{1}^{10}+28{,}928 \beta^{ 4}\delta^{5}x_{1}^{11}-145{,}936 \beta^{4}\delta^{4}x_{1}^{12} \\ & +54{,}948 \beta^{4}\delta^{3}x_{1}^{13}-26{,}074 \beta^{4}{ \delta}^{2}x_{1}^{14}-79{,}829 \beta^{4}\delta x_{1}^{15}+ 75{,}624 \beta^{4}x_{1}^{16}+132 \beta^{3} \delta^{8}x_{1} ^{9} \\ & -914 \beta^{3}\delta^{7}x_{1}^{10}+4222 \beta^{3}{ \delta}^{6}x_{1}^{11}-39{,}134 \beta^{3}\delta^{5}x_{1}^{12} +21{,}313 \beta^{3}\delta^{4}x_{1}^{13}-60{,}308 \beta^{3}{ \delta}^{3}x_{1}^{14} \\ & +6274 \beta^{3}\delta^{2}x_{1}^{15}+ 89{,}784 \beta^{3}\delta x_{1}^{16}-34{,}413 \beta^{3}x_{1}^{ 17}-36 \beta^{2}\delta^{8}x_{1}^{10}+122 \beta^{2}\delta ^{7}x_{1}^{11}\\ &-5252 \beta^{2}\delta^{6}x_{1}^{12}+1582 { \beta}^{2}\delta^{5}x_{1}^{13}-26{,}593 \beta^{2}\delta^{4}{x_{{1}}}^{14}+25{,}832 \beta^{2}\delta^{3}x_{1}^{15} \\ & +35{,}571 {\beta }^{2}\delta^{2}x_{1}^{16} -36{,}585 \beta^{2}\delta x_{1}^{ 17}+5616 \beta^{2}x_{1}^{18}-23 \beta \delta^{8}x_{1}^{ 11}-263 \beta \delta^{7}x_{1}^{12} \\ &-617 \beta \delta^{6}{x_{{1}}}^{13}-4692 \beta \delta^{5}x_{1}^{14} +8576 \beta\delta^{4}x_{1}^{15}+5121 \beta\delta^{3}x_{1}^{16}- 12{,}174 \beta \delta^{2}x_{1}^{17} \\ &+4056 \beta \delta{x_{1} }^{18}-94 \delta^{7}x_{1}^{13}-278 \delta^{6}x_{1}^{14}+ 834 \delta^{5}x_{1}^{15} +162 \delta^{4}x_{1}^{16}-1248 \delta^{3}x_{1}^{17}\\ &+624 \delta^{2}x_{1}^{18}-131{,}072 { \beta}^{12}x_{1}^{7}-458{,}752 \beta^{11}\delta x_{1}^{7}- 26{,}112 \beta^{11}x_{1}^{8}-688{,}128 \beta^{10}\delta^{2}x_{1}^{7} \\ & -279{,}552 \beta^{10}\delta x_{1}^{8}+137{,}728 \beta^{10 }x_{1}^{9}-573{,}440 \beta^{9}\delta^{3}x_{1}^{7}-673{,}152 { \beta}^{9}\delta^{2}x_{1}^{8} \\ & +713{,}344 \beta^{9}\delta x_{1}^{9}-112{,}928 \beta^{9}x_{1}^{10}-286{,}720 \beta^{8}\delta^{ 4}x_{1}^{7}-748{,}800 \beta^{8}\delta^{3}x_{1}^{8}\\ &+1{,}250{,}816 \beta^{8}\delta^{2}x_{1}^{9}-753{,}728 \beta^{8}\delta{x_{{1 }}}^{10}+250{,}592 \beta^{8}x_{1}^{11}-86{,}016 \beta^{7}\delta^{5}x_{1}^{7} \\ & -456{,}480 \beta^{7}\delta^{4}x_{1}^{8}+1{,}080{,}960 \beta^{7}\delta^{3}x_{1}^{9}-1{,}279{,}928 \beta^{7}\delta^{2 }x_{1}^{10}+1{,}360{,}552 \beta^{7}\delta x_{1}^{11} \\ & +167{,}264 { \beta}^{7}x_{1}^{12}-14{,}336 \beta^{6}\delta^{6}x_{1}^{7}-158{,}016 \beta^{6}\delta^{5}x_{1}^{8}+515{,}360 \beta^{6}{ \delta}^{4}x_{1}^{9}\\ &-975{,}888 \beta^{6}\delta^{3}x_{1}^{10} +2{,}034{,}944 \beta^{6}\delta^{2}x_{1}^{11}-219{,}388 \beta^{6} \delta x_{1}^{12}-275{,}684 \beta^{6}x_{1}^{13} \\ & -1024 \beta ^{5}\delta^{7}x_{1}^{7}-29{,}256 \beta^{5}\delta^{6}x_{1}^{8}+136{,}744 \beta^{5}\delta^{5}x_{1}^{9}-375{,}816 \beta^{5}{ \delta}^{4}x_{1}^{10} \\ & +1{,}374{,}780 \beta^{5}\delta^{3}x_{1}^{ 11}-539{,}720 \beta^{5}\delta^{2}x_{1}^{12}+57{,}612 \beta^{5} \delta x_{1}^{13}+257{,}536 \beta^{5}x_{1}^{14}\\ &-2256 \beta ^{4}\delta^{7}x_{1}^{8}+18{,}512 \beta^{4}\delta^{6}x_{1}^{9}-68{,}092 \beta^{4}\delta^{5}x_{1}^{10}+468{,}512 \beta^{4}{ \delta}^{4}x_{1}^{11} \\ & -299{,}474 \beta^{4}\delta^{3}x_{1}^{12 }+406{,}892 \beta^{4}\delta^{2}x_{1}^{13}+49{,}154 \beta^{4} \delta x_{1}^{14}-235{,}944 \beta^{4}x_{1}^{15} \\ & +948 \beta^{3} \delta^{7}x_{1}^{9}-3148 \beta^{3}\delta^{6}x_{1}^{ 10}+77{,}056 \beta^{3}\delta^{5}x_{1}^{11}-48{,}904 \beta^{3}{ \delta}^{4}x_{1}^{12}+251{,}810 \beta^{3}\delta^{3}x_{1}^{13 } \\ & -158{,}498 \beta^{3}\delta^{2}x_{1}^{14}-188{,}268 \beta^{3} \delta x_{1}^{15}+94{,}632 \beta^{3}x_{1}^{16}+362 \beta^{ 2}\delta^{7}x_{1}^{10}+4660 \beta^{2}\delta^{6}x_{1}^{ 11}\\ &+4654 \beta^{2}\delta^{5}x_{1}^{12}+56{,}508 \beta^{2}{ \delta}^{4}x_{1}^{13}-81{,}166 \beta^{2}\delta^{3}x_{1}^{14} -39{,}246 \beta^{2}\delta^{2}x_{1}^{15} \\ & +65{,}808 \beta^{2}\delta x_{1}^{16}-11{,}856 \beta^{2}x_{1}^{17}+1400 \beta{\delta }^{6}x_{1}^{12}+4050 \beta \delta^{5}x_{1}^{13}-10{,}576 \beta \delta^{4}x_{1}^{14} \\ & -1134 \beta \delta^{3}x_{1}^{15}+10{,}620 \beta\delta^{2}x_{1}^{16}-4368 \beta\delta{x_{ {1}}}^{17}+458{,}752 \beta^{12}x_{1}^{6}+1{,}376{,}256 \beta^{11} \delta x_{1}^{6} \\ & +211{,}456 \beta^{11}x_{1}^{7}+1{,}720{,}320 { \beta}^{10}\delta^{2}x_{1}^{6}+1{,}198{,}848 \beta^{10}\delta{x_{ {1}}}^{7}-840{,}704 \beta^{10}x_{1}^{8}\\ &+1{,}146{,}880 \beta^{9}{ \delta}^{3}x_{1}^{6}+2{,}133{,}120 \beta^{9}\delta^{2}x_{1}^{7} -3{,}028{,}224 \beta^{9}\delta x_{1}^{8}+970{,}208 \beta^{9}{x_{1} }^{9} \\ &+430{,}080 \beta^{8}\delta^{4}x_{1}^{6}+1{,}797{,}760 \beta^{8 }\delta^{3}x_{1}^{7}-4{,}015{,}360 \beta^{8}\delta^{2}x_{1}^{ 8}+3{,}289{,}488 \beta^{8}\delta x_{1}^{9} \\ &-1{,}539{,}232 \beta^{8}x_{1}^{10} +86{,}016 \beta^{7}\delta^{5}x_{1}^{6}+797{,}280 \beta^{7}\delta^{4}x_{1}^{7}-2{,}614{,}720 \beta^{7}\delta^{3}x_{1} ^{8} \\ & +3{,}781{,}240 \beta^{7}\delta^{2}x_{1}^{9}-4{,}760{,}864 \beta^{7 }\delta x_{1}^{10}+365{,}600 \beta^{7}x_{1}^{11}+7168 {\beta }^{6}\delta^{6}x_{1}^{6}\\ &+180{,}528 \beta^{6}\delta^{5}{x_{1} }^{7}-893{,}760 \beta^{6}\delta^{4}x_{1}^{8}+1{,}968{,}552 \beta^{6 }\delta^{3}x_{1}^{9}-4{,}910{,}872 \beta^{6}\delta^{2}x_{1}^{ 10} \\ & +1{,}668{,}756 \beta^{6}\delta x_{1}^{11}-6204 \beta^{6}{x_{{1 }}}^{12}+16{,}504 \beta^{5}\delta^{6}x_{1}^{7}-151{,}712 \beta^{ 5}\delta^{5}x_{1}^{8} \\ & +463{,}392 \beta^{5}\delta^{4}x_{1}^{ 9}-2{,}264{,}124 \beta^{5}\delta^{3}x_{1}^{10}+1{,}469{,}674 \beta^{5} \delta^{2}x_{1}^{11}-956{,}142 \beta^{5}\delta x_{1}^{12}\\ &- 139{,}128 \beta^{5}x_{1}^{13}-9792 \beta^{4}\delta^{6}{x_{{1} }}^{8}+32{,}348 \beta^{4}\delta^{5}x_{1}^{9}-473{,}008 \beta^{4} \delta^{4}x_{1}^{10} \\ & +407{,}540 \beta^{4}\delta^{3}x_{1}^{ 11}-923{,}824 \beta^{4}\delta^{2}x_{1}^{12}+335{,}165 \beta^{4} \delta x_{1}^{13}+232{,}392 \beta^{4}x_{1}^{14} \\ & -2306 \beta ^{3}\delta^{6}x_{1}^{9}-34{,}892 \beta^{3}\delta^{5}x_{1}^{10}+4698 \beta^{3}\delta^{4}x_{1}^{11}-276{,}618 \beta^{3}{ \delta}^{3}x_{1}^{12}\\ &+300{,}364 \beta^{3}\delta^{2}x_{1}^{13 }+82{,}116 \beta^{3}\delta x_{1}^{14}-81{,}813 \beta^{3}x_{1} ^{15}+82 \beta^{2} \delta^{6}x_{1}^{10}-8150 \beta^{2}{ \delta}^{5}x_{1}^{11} \\ & -23{,}493 \beta^{2}\delta^{4}x_{1}^{12} +56{,}769 \beta^{2}\delta^{3}x_{1}^{13}-5820 \beta^{2}{\delta }^{2}x_{1}^{14}-26{,}586 \beta^{2}\delta x_{1}^{15}+6864 { \beta}^{2}x_{1}^{16} \\ & +237 \beta\delta^{5}x_{1}^{12}+332 \beta \delta^{4}x_{1}^{13}-1179 \beta \delta^{3}x_{1}^{ 14}+306 \beta \delta^{2}x_{1}^{15}+312 \beta \delta{x_{{1} }}^{16} \\ & -917{,}504 \beta^{12}x_{1}^{5}-2{,}293{,}760 \beta^{11}\delta x_{1}^{5}-663{,}040 \beta^{11}x_{1}^{6}-2{,}293{,}760 \beta^{10 }\delta^{2}x_{1}^{5} \\ & -2{,}598{,}400 \beta^{10}\delta x_{1}^{6}+ 2{,}352{,}640 \beta^{10}x_{1}^{7}-1{,}146{,}880 \beta^{9}\delta^{3}{x_{{1}}}^{5}-3{,}444{,}480 \beta^{9}\delta^{2}x_{1}^{6}\\ &+6{,}412{,}160 { \beta}^{9}\delta x_{1}^{7}-2{,}780{,}960 \beta^{9}x_{1}^{8}- 286{,}720 \beta^{8}\delta^{4}x_{1}^{5}-2{,}097{,}920 \beta^{8}{ \delta}^{3}x_{1}^{6} \\ & +6{,}423{,}040 \beta^{8}\delta^{2}x_{1}^{7} -6{,}492{,}960 \beta^{8}\delta x_{1}^{8}+3{,}752{,}032 \beta^{8}{x_{{1} }}^{9}-28{,}672 \beta^{7}\delta^{5}x_{1}^{5} \\ &-606{,}560 \beta^{7} \delta^{4}x_{1}^{6} +3{,}009{,}920 \beta^{7}\delta^{3}x_{1}^{7 }-5{,}181{,}680 \beta^{7}\delta^{2}x_{1}^{8}+7{,}895{,}704 \beta^{7} \delta x_{1}^{9} \\ & -1{,}641{,}376 \beta^{7}x_{1}^{10}-67{,}680 {\beta }^{6}\delta^{5}x_{1}^{6}+661{,}920 \beta^{6}\delta^{4}{x_{1} }^{7}-1{,}700{,}848 \beta^{6}\delta^{3}x_{1}^{8}\\ &+5{,}539{,}456 \beta^{ 6}\delta^{2}x_{1}^{9}-3{,}043{,}100 \beta^{6}\delta x_{1}^{10} +796{,}252 \beta^{6}x_{1}^{11}+54{,}120 \beta^{5}\delta^{5}{x_{{ 1}}}^{7} \\ &-178{,}960 \beta^{5}\delta^{4}x_{1}^{8}+1{,}564{,}088 \beta ^{5}\delta^{3}x_{1}^{9}-1{,}459{,}312 \beta^{5}\delta^{2}{x_{1} }^{10}+1{,}584{,}272 \beta^{5}\delta x_{1}^{11} \\ & -259{,}008 \beta^{5}{ x_{1}}^{12}+6660 \beta^{4}\delta^{5}x_{1}^{8}+145{,}176 { \beta}^{4}\delta^{4}x_{1}^{9}-143{,}040 \beta^{4}\delta^{3}{x_{{1}}}^{10} \\ &+709{,}624 \beta^{4}\delta^{2}x_{1}^{11} -521{,}700 { \beta}^{4}\delta x_{1}^{12}-37{,}752 \beta^{4}x_{1}^{13}-1044 \beta^{3}\delta^{5}x_{1}^{9}\\ &+22{,}052 \beta^{3}\delta^{4}{ x_{1}}^{10} +73{,}958 \beta^{3}\delta^{3}x_{1}^{11}-160{,}300 { \beta}^{3}\delta^{2}x_{1}^{12}+41{,}544 \beta^{3}\delta{x_{{1} }}^{13} \\ &+16{,}776 \beta^{3}x_{1}^{14}-2642 \beta^{2}\delta^{4} x_{1}^{11}-3128 \beta^{2}\delta^{3}x_{1}^{12}+9558 { \beta}^{2}\delta^{2}x_{1}^{13}-2904 \beta^{2}\delta{x_{1} }^{14} \\ & -624 \beta^{2}x_{1}^{15}+1{,}146{,}880 \beta^{12}x_{1}^{ 4}+2{,}293{,}760 \beta^{11}\delta x_{1}^{4}+1{,}128{,}960 \beta^{11}{x_{{1}}}^{5} \\ &+1{,}720{,}320 \beta^{10}\delta^{2}x_{1}^{4}+3{,}198{,}720 { \beta}^{10}\delta x_{1}^{5} -3{,}722{,}240 \beta^{10}x_{1}^{6}+ 573{,}440 \beta^{9}\delta^{3}x_{1}^{4}\\ &+3{,}033{,}600 \beta^{9}{ \delta}^{2}x_{1}^{5}-7{,}662{,}080 \beta^{9}\delta x_{1}^{6}+ 4{,}146{,}400 \beta^{9}x_{1}^{7}+71{,}680 \beta^{8}\delta^{4}x_{1}^{4} \\ & +1{,}199{,}040 \beta^{8}\delta^{3}x_{1}^{5}-5{,}532{,}800 \beta ^{8}\delta^{2}x_{1}^{6}+6{,}812{,}560 \beta^{8}\delta x_{1}^{7 }-4{,}819{,}840 \beta^{8}x_{1}^{8} \\ & +170{,}400 \beta^{7}\delta^{4}{x_{{1}}}^{5}-1{,}673{,}760 \beta^{7}\delta^{3}x_{1}^{6}+3{,}524{,}240 { \beta}^{7}\delta^{2}x_{1}^{7}-6{,}879{,}376 \beta^{7}\delta x_{1}^{8} \\ & +2{,}271{,}104 \beta ^{7}x_{1}^{9}-178{,}400 \beta^{6} \delta^{4}x_{1}^{6}+577{,}452 \beta^{6}\delta^{3}x_{1}^{7}-2{,}957{,}336 \beta^{6}\delta^{2}x_{1}^{8}\\ &+2{,}404{,}508 \beta^{6}\delta{x_{{1}}}^{9}-1{,}076{,}660 \beta^{6}x_{1}^{10}-3132 \beta^{5}{\delta }^{4}x_{1}^{7}-368{,}814 \beta^{5}\delta^{3}x_{1}^{8} \\ & +530{,}918 \beta^{5}\delta^{2}x_{1}^{9}-972{,}678 \beta^{5}\delta{x_{ {1}}}^{10}+363{,}736 \beta^{5}x_{1}^{11}+5256 \beta^{4}\delta ^{4}x_{1}^{8} \\ &-20{,}872 \beta^{4}\delta^{3}x_{1}^{9}-144{,}938 \beta^{4}\delta^{2}x_{1}^{10} +237{,}541 \beta^{4}\delta x_{1}^{11}-55{,}944 \beta^{4}x_{1}^{12} \\ & -95 \beta^{3} \delta^{4} x_{1}^{9}+11{,}158 \beta^{3}\delta^{3}x_{1}^{10}+10{,}898 { \beta}^{3}\delta^{2}x_{1}^{11}-25{,}248 \beta^{3}\delta x_{1}^{12}+5433 \beta^{3}x_{1}^{13}\\ &-179 \beta^{2}\delta^{3}x_{1}^{11}-63 \beta^{2}\delta ^{2}x_{1}^{12}+267 \beta^{2 }\delta x_{1}^{13}-917{,}504 \beta^{12}x_{1}^{3}-1{,}376{,}256 { \beta}^{11}\delta x_{1}^{3} \\ & -1{,}143{,}296 \beta^{11}x_{1}^{4}- 688{,}128 \beta^{10}\delta^{2}x_{1}^{3}-2{,}279{,}424 \beta^{10} \delta x_{1}^{4}+3{,}556{,}864 \beta^{10}x_{1}^{5} \\ & -114{,}688 { \beta}^{9}\delta^{3}x_{1}^{3}-1{,}393{,}536 \beta^{9}\delta^{2}x_{1}^{4}+5{,}278{,}080 \beta^{9}\delta x_{1}^{5}-3{,}553{,}888 \beta ^{9}x_{1}^{6} \\ & -269{,}824 \beta^{8} \delta^{3}x_{1}^{4}+2{,}464{,}768 \beta^{8}\delta^{2}x_{1}^{5}-3{,}872{,}256 \beta^{8}\delta x_{1}^{6}+3{,}471{,}008 \beta^{8}x_{1}^{7}\\ &+362{,}752 \beta^{7}{ \delta}^{3}x_{1}^{5}-1{,}081{,}816 \beta^{7}\delta^{2}x_{1}^{6} +3{,}047{,}768 \beta^{7}\delta x_{1}^{7}-1{,}502{,}944 \beta^{7}x_{1}^{8} \\ & -33{,}696 \beta^{6}\delta^{3}x_{1}^{6}+583{,}168 \beta^{6} \delta^{2}x_{1}^{7}-814{,}548 \beta^{6}\delta x_{1}^{8}+ 568{,}884 \beta^{6}x_{1}^{9} \\ &-12{,}708 \beta^{5}\delta^{3}x_{1}^{7}-25{,}480 \beta^{5}\delta^{2}x_{1}^{8} +176{,}508 \beta^{5} \delta x_{1}^{9}-147{,}648 \beta^{5}x_{1}^{10}+898 \beta^{ 4}\delta^{3}x_{1}^{8} \\ &-21{,}716 \beta^{4}\delta^{2}x_{1}^{9 }-17{,}438 \beta^{4}\delta x_{1}^{10}+21{,}480 \beta^{4}x_{1} ^{11} +1262 \beta^{3}\delta^{2}x_{1}^{10}+36 \beta^{3} \delta x_{1}^{11}\\ &-624 \beta^{3}x_{1}^{12}+458{,}752 \beta^{12}x_{1}^{2}+458{,}752 \beta^{11}\delta x_{1}^{2}+691{,}712 { \beta}^{11}x_{1}^{3} \\ & +114{,}688 \beta^{10}\delta^{2}x_{1}^{2} +879{,}872 \beta^{10}\delta x_{1}^{3}-2{,}044{,}928 \beta^{10}x_{1}^{4}+262{,}272 \beta ^{9}\delta^{2}x_{1}^{3} \\ & -1{,}963{,}264 \beta^{9}\delta x_{1}^{4}+1{,}748{,}128 \beta^{9}x_{1}^{5}-446{,}976 { \beta}^{8}\delta^{2}x_{1}^{4}+1{,}085{,}808 \beta^{8}\delta{x_{{1 }}}^{5} \\ & -1{,}339{,}232 \beta^{8}x_{1}^{6}+95{,}768 \beta^{7}\delta^{ 2}x_{1}^{5}-538{,}048 \beta^{7}\delta x_{1}^{6}+466{,}400 \beta^{7}x_{1}^{7}+13{,}656 \beta^{6}\delta^{2}x_{1}^{6}\\ &+ 72{,}892 \beta^{6}\delta x_{1}^{7}-100{,}916 \beta^{6}x_{1}^{ 8}-2994 \beta^{5}\delta^{2}x_{1}^{7}+18{,}590 \beta^{5}\delta x_{1}^{8}+10{,}968 \beta^{5}x_{1}^{9} \\ &+36 \beta^{4}{\delta }^{2}x_{1}^{8}-2893 \beta^{4}\delta x_{1}^{9}+216 \beta ^{4}x_{1}^{10}+36 \beta^{3} \delta x_{1}^{10}+9 \beta^{3 }x_{1}^{11}-131{,}072 \beta^{12}x_{1} \\ & -65{,}536 \beta^{11}\delta x_{1}-231{,}936 \beta^{11}x_{1}^{2}-142{,}848 \beta^{10}\delta x_{1}^{2}+653{,}824 \beta^{10}x_{1}^{3} \\ & +306{,}304 \beta^{9} \delta x_{1}^{3}-449{,}888 \beta^{9}x_{1}^{4}-107{,}168 \beta ^{8}\delta x_{1}^{4}+222{,}752 \beta^{8}x_{1}^{5}-2712 { \beta}^{7}\delta x_{1}^{5} \\ & -46{,}816 \beta^{7}x_{1}^{6}+4076 \beta^{6}\delta x_{1}^{6}-5036 \beta^{6}x_{1}^{7}-216 { \beta}^{5}\delta x_{1}^{7}+2176 \beta^{5}x_{1}^{8}-72 { \beta}^{4}x_{1}^{9}\\ &+16{,}384 \beta^{12}+33{,}280 \beta^{11}x_{1} -89{,}600 \beta^{10}x_{1}^{2}+44{,}960 \beta^{9}x_{1}^{3}-3472 \beta^{8}x_{1}^{4} \\ & -1840 \beta^{7}x_{1}^{5}+288 \beta ^{6}x_{1}^{6}. \end{aligned}$$

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Su, J. Degenerate Hopf bifurcation in a Leslie–Gower predator–prey model with predator harvest. Adv Differ Equ 2020, 194 (2020). https://doi.org/10.1186/s13662-020-02656-3

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Received: 20 February 2020
Accepted: 20 April 2020
Published: 01 May 2020
DOI: https://doi.org/10.1186/s13662-020-02656-3

Degenerate Hopf bifurcation in a Leslie–Gower predator–prey model with predator harvest

Abstract

1 Introduction

2 Preliminary results

Lemma 2.1

3 Degenerate Hopf bifurcation at \(E_{1}\)

Theorem 3.1

Lemma 3.1

Proof

Proof of Theorem 3.1

4 Simulation and conclusions

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Degenerate Hopf bifurcation in a Leslie–Gower predator–prey model with predator harvest

Abstract

1 Introduction

2 Preliminary results

Lemma 2.1

3 Degenerate Hopf bifurcation at \(E_{1}\)

Theorem 3.1

Lemma 3.1

Proof

Proof of Theorem 3.1

4 Simulation and conclusions

References

Acknowledgements

Availability of data and materials

Funding

Author information

Authors and Affiliations

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Appendix

Appendix

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