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1. Introduction

Many nonlinear physical phenomena arise in various fields of engineering and science such as fluid dynamics, nuclear reactor dynamics, hydrodynamics, molecular biology, quantum mechanics, plasma physics, optical fibres, and solid state physics. To describe these complex physical phenomena, nonlinear differential equations play a significant role. Therefore, obtaining the solutions of these nonlinear equations is a topic of great interest in the study of many fields of science. To better understand the working of a physical problem, a mathematical model was brought into the picture in the form of nonlinear PDEs. The solutions of partial differential equations give the detailed summary about the nature of phenomena involved. Many numerical and analytical methods have been derived to deal with these kinds of scientific problems. We need to adopt an effective and powerful method to investigate such type of mathematical model which gives the solutions upholding physical reality. In most of the analytic techniques, linearization of the system is the main topic to focus on, and also, it is assumed that the nonlinearities are relatively insignificant. Sometimes, these assumptions make a strong effect on the solutions in respect to the real physics of the phenomena involved. Thus, finding the solutions of nonlinear ODEs and PDEs is still a significant problem. For this, we need new techniques to develop approximate and exact solutions. Several analytical and numerical techniques have been formulated for tackling these types of nonlinear models, including the Exp-function method [1, 2], the homotopy analysis method [3], the homotopy perturbation method [4], the ($G^{\prime }/G$)-expansion method [5], the improved $\tan \left(\varphi /2\right)$-expansion method ([6–8]), the Hirota bilinear method ([9–13]), the He variational principle [14, 15], the binary Darboux transformation [16], the Lie group analysis [17, 18], and the Bäcklund transformation method [19]. Moreover, many powerful methods have been used to investigate the new properties of mathematical models which are symbolizing serious real world problems ([20–24]). This study is aimed at investigating the following four forms of nonlinear PDEs:

(i)

Extended ($3+1$)-dimensional Jimbo-Miwa-like (JM) equations ([25–34]) is given as $$\begin{array}{}\text{(1)}& {\Psi }_{xxxy}+3{\Psi }_{xx}{\Psi }_y+3{\Psi }_x{\Psi }_{xy}+2{\Psi }_{yt}-3\left({\Psi }_{xz}+{\Psi }_{yz}+{\Psi }_{zz}\right)=0,\end{array}$$and $$\begin{array}{}\text{(2)}& {\Psi }_{xxxy}+3{\Psi }_{xx}{\Psi }_y+3{\Psi }_x{\Psi }_{xy}-3{\Psi }_{xz}+2\left({\Psi }_{xt}+{\Psi }_{yt}+{\Psi }_{zt}\right)=0,\end{array}$$explains some ($3+1$)-dimensional waves in physics [25, 26], in which $\Psi \left(x,y,z,t\right)$ is a function including spaces $x,y,z$ and time $t$. In addition, this equation cannot pass certain conventional integrability tests [27]. Qi et al. [32] studied the extended ($3+1$)-dimensional Jimbo-Miwa-like equation via the Hirota method and obtained the solitary-wave solutions and novel exact soliton solutions.

The soliton solutions to a few ($3+1$)-dimensional generalized nonlinear integrable equations have been constructed. The adopted approach is the multiple Exp-function method, which was presented earlier in the valuable work by Ma et al. [49]. Recently, special kinds of reductions of soliton solutions to rational functions that are being actively studied are lump solutions to nonlinear partial differential equations by Ma and Zhou [50] and their interactions with solitons to the Hirota-Satsuma-Ito equation in ($2+1$)-dimensions by Ma [51], even for linear PDEs by the same author [52]. Cordero et al. constructed the stability analysis of the fourth-order iterative method for finding multiple roots of nonlinear equations [53]. Gao et al. obtained the optical soliton solutions of the cubic-quartic nonlinear Schrödinger and resonant nonlinear Schrödinger equations with the parabolic law [54]. The truncated Painlevé expansion was employed to derive a Bäcklund transformation of a ($2+1$)-dimensional nonlinear system by Zhao and Han [55]. Also, Gao et al. studied on the conformable ($2+1$)-dimensional Ablowitz-KaupNewell-Segur equation in order to show the existence of complex combined dark-bright soliton solutions [56]. The same authors presented the nonlinear Zoomeron equation by using the newly extended direct algebraic technique [57]. The instability modulation for the ($2+1$)-dimension paraxial wave equation and its new optical soliton solutions in Kerr’s media by utilizing the modified auxiliary expansion method have been studied in [58]. In [59], the authors found new complex solitons to the perturbed nonlinear Schrödinger model with the help of an analytical method. In this paper, we will study the multiple Exp-function method for determining the multiple soliton solutions. The multiple Exp-function method used by some of the powerful authors for various nonlinear equations include the nonlinear evolution equations [60], the ($2+1$)-dimensional Calogero-Bogoyavlenskii-Schiff equation [61], the generalized ($1+1$)-dimensional and ($2+1$)-dimensional Ito equations [62], a new generalization of the associated Camassa-Holm equation [63], the ($3+1$)-dimensional generalized KP and BKP equations [64], and the new ($2+1$)-dimensional Korteweg-de Vries equation [65]. In [65], Liu et al. utilized the multiple Exp-function method for the most well-known equation, namely, the Korteweg-de Vries (KdV) equation, and gained one-soliton-, two-soliton-, and three-soliton-type solutions with interpretations for the obtained soliton solutions. Moreover, they analyzed and illustrated the propagation and interaction of some soliton solutions by selecting appropriate values. Also, the elasticity and being unchanged for some solutions when interacting among three solitons and after the collision were investigated.

The rest of this paper is structured as follows: the multiple Exp-function scheme is summarized in Section 2. In Sections 3–7, the extended JM equations, the extended CBS equation, the generalized BK equation, and the vDJKM equation, respectively, will be investigated to find one-soliton, two-soliton, and triple-soliton solutions. In the last section, the conclusions are given.

2. Multiple Exp-Function Method

This section elucidates a systematic explanation of the multiple Exp-function method [60–64] so that it can be further applied to the nonlinear PDEs in order to furnish its exact solutions:

3. Multiple Soliton Solutions for the Extended ($3+1$) JM Equation (1)

3.1. Set I: One-Wave Solution

We commence with a one-wave function based on the statement in Step 2 in the previous section; we suppose that equation (1) has the rational function of the one-wave solution as shown in the following form: $$\begin{array}{}\text{(13)}& \Psi \left(x,y,z,t\right)=\frac{{\Delta }_1}{{\Omega }_1},\hspace{1em}{\Omega }_1=1+{\rho }_1{e}^{{\alpha }_{1}x+{\beta }_{1}y+{\gamma }_{1}z-{\delta }_{1}t},{\Delta }_1={\sigma }_1+{\rho }_1{\sigma }_2{e}^{{\alpha }_{1}x+{\beta }_{1}y+{\gamma }_{1}z-{\delta }_{1}t},\end{array}$$in which ${\sigma }_1$ and ${\sigma }_2$ are unfound constants. Plugging (13) into equation (1), we gain to the following case: $$\begin{array}{c}\text{(14)}& {\rho }_1={\rho }_1,{\sigma }_1={\sigma }_1,\\ {\sigma }_2=\frac{{\rho }_2\left(2{\alpha }_1{\rho }_1+{\sigma }_1\right)}{{\rho }_1},\\ {\delta }_1=\frac{{\alpha }_1^3{\beta }_1-3{\alpha }_1{\gamma }_1-3{\beta }_1{\gamma }_1-3{\gamma }_1^2}{2{\beta }_1}.\end{array}$$

Therefore, the resulting one-wave solution reads as $$\begin{array}{}\text{(15)}& \Psi \left(x,y,z,t\right)=\frac{{\sigma }_1+{\rho }_2\left(2{\alpha }_1{\rho }_1+{\sigma }_1\right)e^{{\alpha }_{1}x+{\beta }_{1}y+{\gamma }_{1}z-\left(\left({\alpha }_1^3{\beta }_1-3{\alpha }_1{\gamma }_1-3{\beta }_1{\gamma }_1-3{\gamma }_1^2\right)/\left(2{\beta }_1\right)\right)t}}{1+{\rho }_1{e}^{{\alpha }_{1}x+{\beta }_{1}y+{\gamma }_{1}z-\left(\left({\alpha }_1^3{\beta }_1-3{\alpha }_1{\gamma }_1-3{\beta }_1{\gamma }_1-3{\gamma }_1^2\right)/\left(2{\beta }_1\right)\right)t}}.\end{array}$$

By selecting the suitable values of parameters, the graphic presentation of the periodic wave solution is presented in Figure 1 including the 3D plot, the contour plot, the density plot, and the 2D plot when three spaces arise at spaces $x=-1$, $x=0$, and $x=1$.

3.2. Set II: Two-Wave Solutions

We commence with the two-wave functions based on the statement in Step 2 in the previous section; we suppose that equation (1) has the rational function of two-wave solutions as shown in the following form: $$\begin{array}{c}\text{(16)}& \Psi \left(x,y,z,t\right)=\frac{{\Delta }_2}{{\Omega }_2},\text{(17)}& {\Omega }_2=1+{\sigma }_1{e}^{{\alpha }_{1}x+{\beta }_{1}y+{\gamma }_{1}z-{\delta }_{1}t}+{\sigma }_2{e}^{{\alpha }_{2}x+{\beta }_{2}y+{\gamma }_{2}z-{\delta }_{2}t}+{\sigma }_1{\sigma }_2{\sigma }_{12}{e}^{\left({\alpha }_1+{\alpha }_2\right)x+\left({\beta }_1+{\beta }_2\right)y+\left({\gamma }_1+{\gamma }_2\right)z-\left({\delta }_1+{\delta }_2\right)t},{\Delta }_2={\rho }_1{e}^{{\alpha }_{1}x+{\beta }_{1}y+{\gamma }_{1}z-{\delta }_{1}t}+{\rho }_2{e}^{{\alpha }_{2}x+{\beta }_{2}y+{\gamma }_{2}z-{\delta }_{2}t}+{\rho }_1{\rho }_2{\rho }_{12}{e}^{\left({\alpha }_1+{\alpha }_2\right)x+\left({\beta }_1+{\beta }_2\right)y+\left({\gamma }_1+{\gamma }_2\right)z-\left({\delta }_1+{\delta }_2\right)t}.\end{array}$$

Plugging (16) along with (17) into equation (1), we get to the following case: $$\begin{array}{c}\text{(18)}& {\sigma }_1={\sigma }_1,{\sigma }_2={\sigma }_2,\\ {\delta }_1=\frac{1}{2}{\alpha }_1^3,\\ {\delta }_2=\frac{1}{2}{\alpha }_2^3,\\ {\rho }_1=2{\alpha }_1{\sigma }_1,\\ {\rho }_2=2{\alpha }_2{\sigma }_2,\\ {\rho }_{12}=\frac{\left({\beta }_1-{\beta }_2\right)\left({\alpha }_1-{\alpha }_2\right)}{2{\alpha }_1{\alpha }_2\left({\beta }_1+{\beta }_2\right)},\\ {\sigma }_{12}=\frac{\left({\beta }_1-{\beta }_2\right)\left({\alpha }_1-{\alpha }_2\right)}{\left({\beta }_1+{\beta }_2\right)\left({\alpha }_1+{\alpha }_2\right)}.\end{array}$$

Therefore, the resulting two-wave solution reads as $$\begin{array}{}\text{(19)}& {\Psi }_2\left(x,y,z,t\right)=\frac{2{\alpha }_1{\sigma }_1{e}^{{\Lambda }_1}+2{\alpha }_2{\sigma }_2{e}^{{\Lambda }_2}+2{\sigma }_1{\sigma }_2\left(\left(\left({\beta }_1-{\beta }_2\right)\left({\alpha }_1-{\alpha }_2\right)\right)/\left({\beta }_1+{\beta }_2\right)\right)e^{{\Lambda }_1+{\Lambda }_2}}{1+{\sigma }_1{e}^{{\Lambda }_1}+{\sigma }_2{e}^{{\Lambda }_2}+{\sigma }_1{\sigma }_2\left(\left(\left({\beta }_1-{\beta }_2\right)\left({\alpha }_1-{\alpha }_2\right)\right)/\left(\left({\beta }_1+{\beta }_2\right)\left({\alpha }_1+{\alpha }_2\right)\right)\right)e^{{\Lambda }_1+{\Lambda }_2}},\end{array}$$in which ${\Lambda }_i={\alpha }_{i}x+{\beta }_{i}y+{\gamma }_{i}z-\left(1/2\right){\alpha }_i^{3}t,i=1,2$. By selecting the suitable values of parameters, the graphic representation of the periodic wave solution is presented in Figure 2 including the 3D plot, the contour plot, the density plot, and the 2D plot when three spaces arise at spaces $x=-10$, $x=0$, and $x=10$.

3.3. Set III: Triple-Wave Solutions

We commence with three-wave functions based on the statement in Step 2 in the previous section; we suppose that equation (1) has the rational function of triple-wave solutions as shown in the following form: $$\begin{array}{c}\text{(20)}& \Psi \left(x,y,z,t\right)=\frac{{\Delta }_3}{{\Omega }_3},\text{(21)}& {\Omega }_3=1+{\rho }_1{e}^{{\Lambda }_1}+{\rho }_2{e}^{{\Lambda }_2}+{\rho }_3{e}^{{\Lambda }_3}+{\rho }_1{\rho }_2{\rho }_{12}{e}^{{\Lambda }_1+{\Lambda }_2}+{\rho }_1{\rho }_3{\rho }_{13}{e}^{{\Lambda }_1+{\Lambda }_3}+{\rho }_2{\rho }_3{\rho }_{23}{e}^{{\Lambda }_2+{\Lambda }_3}+{\rho }_1{\rho }_2{\rho }_3{\rho }_{12}{\rho }_{13}{\rho }_{23}{e}^{{\Lambda }_1+{\Lambda }_2+{\Lambda }_3},{\Delta }_3={\sigma }_1{e}^{{\Lambda }_1}+{\sigma }_2{e}^{{\Lambda }_2}+{\sigma }_3{e}^{{\Lambda }_3}+{\sigma }_1{\sigma }_2{\sigma }_{12}{e}^{{\Lambda }_1+{\Lambda }_2}+{\sigma }_1{\sigma }_3{\sigma }_{13}{e}^{{\Lambda }_1+{\Lambda }_3}+{\sigma }_2{\sigma }_3{\sigma }_{23}{e}^{{\Lambda }_2+{\Lambda }_3}+{\sigma }_1{\sigma }_2{\sigma }_3{\sigma }_{12}{\sigma }_{13}{\sigma }_{23}{e}^{{\Lambda }_1+{\Lambda }_2+{\Lambda }_3},\end{array}$$in which ${\Lambda }_i={\alpha }_{i}x+{\beta }_{i}y+{\gamma }_{i}x-{\delta }_{i}t,i=1,2,3$. Plugging (20) along with (21) into equation (1), we obtain the following case: $$\begin{array}{c}\text{(22)}& {\sigma }_i={\sigma }_i,{\delta }_i=\frac{1}{2}{\alpha }_i^3,\\ {\rho }_i=2{\alpha }_i{\sigma }_i,\\ \hspace{1em}i=1,2,3,\\ {\rho }_{12}=\frac{\left({\beta }_1-{\beta }_2\right)\left({\alpha }_1-{\alpha }_2\right)}{2{\alpha }_1{\alpha }_2\left({\beta }_1+{\beta }_2\right)},\\ {\sigma }_{12}=\frac{\left({\beta }_1-{\beta }_2\right)\left({\alpha }_1-{\alpha }_2\right)}{\left({\beta }_1+{\beta }_2\right)\left({\alpha }_1+{\alpha }_2\right)},\\ {\rho }_{13}=\frac{\left({\beta }_1-{\beta }_3\right)\left({\alpha }_1-{\alpha }_3\right)}{2{\alpha }_1{\alpha }_3\left({\beta }_1+{\beta }_3\right)},\\ {\sigma }_{13}=\frac{\left({\beta }_1-{\beta }_3\right)\left({\alpha }_1-{\alpha }_3\right)}{\left({\beta }_1+{\beta }_3\right)\left({\alpha }_1+{\alpha }_3\right)},\\ {\rho }_{23}=\frac{\left({\beta }_2-{\beta }_3\right)\left({\alpha }_2-{\alpha }_3\right)}{2{\alpha }_2{\alpha }_3\left({\beta }_2+{\beta }_3\right)},\\ {\sigma }_{23}=\frac{\left({\beta }_2-{\beta }_3\right)\left({\alpha }_2-{\alpha }_3\right)}{\left({\beta }_2+{\beta }_3\right)\left({\alpha }_2+{\alpha }_3\right)}.\end{array}$$

Therefore, the resulting three-wave solution reads as $$\begin{array}{}\text{(23)}& {\Psi }_3\left(x,y,z,t\right)=\frac{{\Delta }_3}{{\Omega }_3},\end{array}$$in which ${\Delta }_3$ and ${\Omega }_3$ with their relations are given in (21) and (22). By selecting suitable values of parameters, the graphic representation of the periodic wave solution is presented in Figure 3 including the 3D plot, the contour plot, the density plot, and the 2D plot when three spaces arise at spaces $x=-10$, $x=0$, and $x=10$.

4. Multiple Soliton Solutions for the Extended ($3+1$) JM Equation (2)

4.1. Set I: One-Wave Solution

We commence with the one-wave function based on the statement in Step 2 in the previous section; we suppose that equation (2) has the rational function of the one-wave solution as shown in the following form: $$\begin{array}{}\text{(24)}& \Psi \left(x,y,z,t\right)=\frac{{\Delta }_1}{{\Omega }_1},\hspace{1em}{\Omega }_1={\rho }_1+{\rho }_2{e}^{{\alpha }_{1}x+{\beta }_{1}y+{\gamma }_{1}z-{\delta }_{1}t},{\Delta }_1={\sigma }_1+{\sigma }_2{e}^{{\alpha }_{1}x+{\beta }_{1}y+{\gamma }_{1}z-{\delta }_{1}t},\end{array}$$in which ${\rho }_1,{\rho }_2,{\sigma }_1,$ and ${\sigma }_2$ are unfound constants. Plugging (24) into equation (1), we gain the following case: $$\begin{array}{c}\text{(25)}& {\rho }_1={\rho }_1,{\rho }_2={\rho }_2,\\ {\sigma }_1={\sigma }_1,\\ {\sigma }_2=\frac{{\rho }_2\left(2{\alpha }_1{\rho }_1+{\sigma }_1\right)}{{\rho }_1},\\ {\delta }_1=\frac{{\alpha }_1\left({{\alpha }_1}^2{\beta }_1-3{\gamma }_1\right)}{2{\alpha }_1+2{\beta }_1+2{\gamma }_1}.\end{array}$$

Therefore, the resulting one-wave solution reads as $$\begin{array}{}\text{(26)}& \Psi \left(x,y,z,t\right)=\frac{{\sigma }_1+{\rho }_2\left(2{\alpha }_1{\rho }_1+{\sigma }_1\right)e^{{\alpha }_{1}x+{\beta }_{1}y+{\gamma }_{1}z-\left(\left({\alpha }_1\left({\alpha }_1^2{\beta }_1-3{\gamma }_1\right)\right)/\left(2{\alpha }_1+2{\beta }_1+2{\gamma }_1\right)\right)t}}{{\rho }_1+{\rho }_2{e}^{{\alpha }_{1}x+{\beta }_{1}y+{\gamma }_{1}z-\left(\left({\alpha }_1\left({\alpha }_1^2{\beta }_1-3{\gamma }_1\right)\right)/\left(2{\alpha }_1+2{\beta }_1+2{\gamma }_1\right)\right)t}}.\end{array}$$

By choosing the suitable values of parameters, the graphic representation of the periodic wave solution is presented in Figure 4 containing the 3D plot, the contour plot, the density plot, and the 2D plot when three spaces arise at spaces $x=-1$, $x=0$, and $x=1$.

4.2. Set II: Two-Wave Solutions

We commence with two-wave functions based on the statement in Step 2 in the previous section; we suppose that equation (2) has the rational function of two-wave solutions as shown in the following form: $$\begin{array}{c}\text{(27)}& \Psi \left(x,y,z,t\right)=\frac{{\Delta }_2}{{\Omega }_2},\text{(28)}& {\Omega }_2=1+{\sigma }_1{e}^{{\alpha }_{1}x+{\beta }_{1}y+{\gamma }_{1}z-{\delta }_{1}t}+{\sigma }_2{e}^{{\alpha }_{2}x+{\beta }_{2}y+{\gamma }_{2}z-{\delta }_{2}t}+{\sigma }_1{\sigma }_2{\sigma }_{12}{e}^{\left({\alpha }_1+{\alpha }_2\right)x+\left({\beta }_1+{\beta }_2\right)y+\left({\gamma }_1+{\gamma }_2\right)z-\left({\delta }_1+{\delta }_2\right)t},{\Delta }_2={\rho }_1{e}^{{\alpha }_{1}x+{\beta }_{1}y+{\gamma }_{1}z-{\delta }_{1}t}+{\rho }_2{e}^{{\alpha }_{2}x+{\beta }_{2}y+{\gamma }_{2}z-{\delta }_{2}t}+{\rho }_1{\rho }_2{\rho }_{12}{e}^{\left({\alpha }_1+{\alpha }_2\right)x+\left({\beta }_1+{\beta }_2\right)y+\left({\gamma }_1+{\gamma }_2\right)z-\left({\delta }_1+{\delta }_2\right)t}.\end{array}$$

Plugging (27) along with (28) into equation (2), we get to the following case: $$\begin{array}{c}\text{(29)}& {\sigma }_i={\sigma }_i,{\delta }_i=\frac{{\alpha }_i^3{\beta }_i}{2{\alpha }_i+2{\beta }_i},\\ {\rho }_i=2{\alpha }_i{\sigma }_i,\\ \hspace{1em}i=1,2,\\ {\rho }_{12}=\frac{{\Sigma }_{12}}{2{\alpha }_1{\alpha }_2{\Gamma }_{12}},\\ {\sigma }_{12}=\frac{{\text{Y}}_{12}}{{\Phi }_{12}}.\\ \text{(30)}& {\Sigma }_{12}={\alpha }_1{\alpha }_2\left({\alpha }_1^2{\beta }_2+2{\alpha }_1{\alpha }_2{\beta }_1-2{\alpha }_1{\alpha }_2{\beta }_2-{\alpha }_2^2{\beta }_1+3{\beta }_1^2{\beta }_2-3{\beta }_1{\beta }_2^2\right)\left({\alpha }_1^2-{\alpha }_2^2\right)+{\alpha }_2^2{\beta }_1^2\left({\alpha }_1+{\alpha }_2\right)\left(3{\alpha }_1^2-3{\alpha }_1{\alpha }_2+{\alpha }_2^2\right)+2{\alpha }_1{\alpha }_2{\beta }_1{\beta }_2\left({\alpha }_1+{\alpha }_2\right)\left({\alpha }_1^2-3{\alpha }_1{\alpha }_2+{\alpha }_2^2\right)+{\alpha }_1^2{\beta }_2^2\left({\alpha }_1+{\alpha }_2\right)\left({\alpha }_1^2-3{\alpha }_1{\alpha }_2+3{\alpha }_2^2\right),{\Gamma }_{12}={\alpha }_1{\alpha }_2\left({\alpha }_1+{\alpha }_2\right)\left({\alpha }_1^2{\beta }_2+2{\alpha }_1{\alpha }_2{\beta }_1+2{\alpha }_1{\alpha }_2{\beta }_2+{\alpha }_2^2{\beta }_1+3{\beta }_1^2{\beta }_2+3{\beta }_1{\beta }_2^2\right)+{\alpha }_2^2{\beta }_1^2\left(3{\alpha }_1^2+3{\alpha }_1{\alpha }_2+{\alpha }_2^2\right)+2{\alpha }_1{\alpha }_2{\beta }_1{\beta }_2\left({\alpha }_1^2+3{\alpha }_1{\alpha }_2+{\alpha }_2^2\right)+{\alpha }_1^2{\beta }_2^2\left({\alpha }_1^2+3{\alpha }_1{\alpha }_2+3{\alpha }_2^2\right),\\ {\text{Y}}_{12}={\alpha }_1{\alpha }_2\left({\alpha }_1-{\alpha }_2\right)\left({\alpha }_1^2{\beta }_2+2{\alpha }_1{\alpha }_2{\beta }_1-2{\alpha }_1{\alpha }_2{\beta }_2-{\alpha }_2^2{\beta }_1+3{\beta }_1^2{\beta }_2-3{\beta }_1{\beta }_2^2\right)+{\alpha }_2^2{\beta }_1^2\left(3{\alpha }_1^2-3{\alpha }_1{\alpha }_2+{\alpha }_2^2\right)+2{\alpha }_1{\alpha }_2{\beta }_1{\beta }_2\left({\alpha }_1^2-3{\alpha }_1{\alpha }_2+{\alpha }_2^2\right)+{\alpha }_1^2{\beta }_2^2\left({\alpha }_1^2-3{\alpha }_1{\alpha }_2+3{\alpha }_2^2\right),\\ {\Phi }_{12}={\alpha }_1{\alpha }_2\left({\alpha }_1+{\alpha }_2\right)\left({\alpha }_1^2{\beta }_2+2{\alpha }_1{\alpha }_2{\beta }_1+2{\alpha }_1{\alpha }_2{\beta }_2+{\alpha }_2^2{\beta }_1+3{\beta }_1^2{\beta }_2+3{\beta }_1{\beta }_2^2\right)+{\alpha }_2^2{\beta }_1^2\left(3{\alpha }_1^2+3{\alpha }_1{\alpha }_2+{\alpha }_2^2\right)+2{\alpha }_1{\alpha }_2{\beta }_1{\beta }_2\left({\alpha }_1^2+3{\alpha }_1{\alpha }_2+{\alpha }_2^2\right)+{\alpha }_1^2{\beta }_2^2\left({\alpha }_1^2+3{\alpha }_1{\alpha }_2+3{\alpha }_2^2\right).\end{array}$$

Therefore, the resulting two-wave solution reads as $$\begin{array}{}\text{(31)}& {\Psi }_2\left(x,y,z,t\right)=\frac{2{\alpha }_1{\sigma }_1{e}^{{\Lambda }_1}+2{\alpha }_2{\sigma }_2{e}^{{\Lambda }_2}+2{\sigma }_1{\sigma }_2\left({\Sigma }_{12}/{\Gamma }_{12}\right)e^{{\Lambda }_1+{\Lambda }_2}}{1+{\sigma }_1{e}^{{\Lambda }_1}+{\sigma }_2{e}^{{\Lambda }_2}+{\sigma }_1{\sigma }_2\left({\text{Y}}_{12}/{\Phi }_{12}\right)e^{{\Lambda }_1+{\Lambda }_2}},\end{array}$$in which ${\Lambda }_i={\alpha }_{i}x+{\beta }_{i}y+{\gamma }_{i}z-\left({\alpha }_i^3{\beta }_i/\left(2{\alpha }_i+2{\beta }_i\right)\right)t,i=1,2$. By selecting the suitable values of parameters, the graphic representation of the periodic wave solution is presented in Figure 5 including the 3D plot, the contour plot, the density plot, and the 2D plot when three spaces arise at spaces $x=-10$, $x=0$, and $x=10$.

4.3. Set III: Triple-Wave Solutions

We commence with three-wave functions based on the statement in Step 2 in the previous section; we suppose that equation (2) has the rational function of triple-wave solutions as shown in the following form: $$\begin{array}{c}\text{(32)}& \Psi \left(x,y,z,t\right)=\frac{{\Delta }_3}{{\Omega }_3},\hspace{1em}\text{(33)}& {\Omega }_3=1+{\rho }_1{e}^{{\Lambda }_1}+{\rho }_2{e}^{{\Lambda }_2}+{\rho }_3{e}^{{\Lambda }_3}+{\rho }_1{\rho }_2{\rho }_{12}{e}^{{\Lambda }_1+{\Lambda }_2}+{\rho }_1{\rho }_3{\rho }_{13}{e}^{{\Lambda }_1+{\Lambda }_3}+{\rho }_2{\rho }_3{\rho }_{23}{e}^{{\Lambda }_2+{\Lambda }_3}+{\rho }_1{\rho }_2{\rho }_3{\rho }_{12}{\rho }_{13}{\rho }_{23}{e}^{{\Lambda }_1+{\Lambda }_2+{\Lambda }_3},{\Delta }_3={\sigma }_1{e}^{{\Lambda }_1}+{\sigma }_2{e}^{{\Lambda }_2}+{\sigma }_3{e}^{{\Lambda }_3}+{\sigma }_1{\sigma }_2{\sigma }_{12}{e}^{{\Lambda }_1+{\Lambda }_2}+{\sigma }_1{\sigma }_3{\sigma }_{13}{e}^{{\Lambda }_1+{\Lambda }_3}+{\sigma }_2{\sigma }_3{\sigma }_{23}{e}^{{\Lambda }_2+{\Lambda }_3}+{\sigma }_1{\sigma }_2{\sigma }_3{\sigma }_{12}{\sigma }_{13}{\sigma }_{23}{e}^{{\Lambda }_1+{\Lambda }_2+{\Lambda }_3},\end{array}$$in which ${\Lambda }_i={\alpha }_{i}x+{\beta }_{i}y+{\gamma }_{i}x-{\delta }_{i}t,i=1,2,3$. Plugging (32) along with (33) into equation (2), we obtain the following case: $$\begin{array}{c}\text{(34)}& {\sigma }_i={\sigma }_i,{\delta }_i=\frac{{\alpha }_i^3{\beta }_i}{2{\alpha }_i+2{\beta }_i},\\ {\rho }_i=2{\alpha }_i{\sigma }_i,\\ \hspace{1em}i=1,2,3,\\ {\rho }_{12}=\frac{{\Sigma }_{12}}{2{\alpha }_1{\alpha }_2{\Gamma }_{12}},\\ {\sigma }_{12}=\frac{{\text{Y}}_{12}}{{\Phi }_{12}}.\\ \text{(35)}& {\rho }_{13}=\frac{{\Sigma }_{13}}{2{\alpha }_1{\alpha }_3{\Gamma }_{13}},{\sigma }_{13}=\frac{{\text{Y}}_{13}}{{\Phi }_{13}},\\ {\rho }_{23}=\frac{{\Sigma }_{23}}{2{\alpha }_2{\alpha }_3{\Gamma }_{23}},\\ {\sigma }_{23}=\frac{{\text{Y}}_{23}}{{\Phi }_{23}},\\ \hspace{1em}{\Sigma }_{13}=\text{substitute}\left\{{\alpha }_2={\alpha }_3,{\beta }_2={\beta }_3\right\},\text{at}{\Sigma }_{12},\\ \hspace{1em}{\Sigma }_{23}=\text{substitute}\left\{{\alpha }_1={\alpha }_2,{\beta }_1={\beta }_2\right\},\text{at}{\Sigma }_{13},\\ \hspace{1em}{\Gamma }_{13}=\text{substitute}\left\{{\alpha }_2={\alpha }_3,{\beta }_2={\beta }_3\right\},\text{at}{\Gamma }_{12},\\ \hspace{1em}{\Gamma }_{23}=\text{substitute}\left\{{\alpha }_1={\alpha }_2,{\beta }_1={\beta }_2\right\},\text{at}{\Gamma }_{13},\\ \hspace{1em}{\text{Y}}_{13}=\text{substitute}\left\{{\alpha }_2={\alpha }_3,{\beta }_2={\beta }_3\right\},\text{at}{\text{Y}}_{12},\\ \hspace{1em}{\text{Y}}_{23}=\text{substitute}\left\{{\alpha }_1={\alpha }_2,{\beta }_1={\beta }_2\right\},\text{at}{\text{Y}}_{13},\\ \hspace{1em}{\Phi }_{13}=\text{substitute}\left\{{\alpha }_2={\alpha }_3,{\beta }_2={\beta }_3\right\},\text{at}{\Phi }_{12},\\ \hspace{1em}{\Phi }_{23}=\text{substitute}\left\{{\alpha }_1={\alpha }_2,{\beta }_1={\beta }_2\right\},\text{at}{\Phi }_{13}.\end{array}$$