We study the exact traveling wave solutions of a general fifth-order nonlinear wave equation and a generalized sixth-order KdV equation. We find the solvable lower-order subequations of a general related fourth-order ordinary differential equation involving only even order derivatives and polynomial functions of the dependent variable. It is shown that the exact solitary wave and periodic wave solutions of some high-order nonlinear wave equations can be obtained easily by using this algorithm. As examples, we derive some solitary wave and periodic wave solutions of the Lax equation, the Ito equation, and a general sixth-order KdV equation.
1. Introduction
In this paper we study a well-known general fifth-order nonlinear wave equation [1–5](1)uxxxxx+αuuxxx+βuxuxx+γu2ux+ut=0,where α,β, and γ are real-valued constants, and the general sixth-order KdV equation [6](2)uxxxxxx+auxuxxxx+buxxuxxx+cux2uxx+dutt+euxxxt+fuxuxt+gutuxx=0,where a,b,c,d,e,f, and g are arbitrary constants.
Equation (1) includes many important nonlinear equations that have been studied in the literature. For example, the Lax equation, the Sawada-Kortera (SK) equation, the Caudrey-Dodd-Gibbon (CDG) equation, the Ito equation, and the Kaup-Kupershmidt (KK) equation are all expressed by (1) in terms of different special values of α,β, and γ. Indeed, scaling analysis (by rescaling u to u/α) shows that only the ratios β/α and γ/α2 matter. The Lax equation [3, 7] arises when β/α=2 and γ/α2=3/10. The KK equation [2, 8–10] corresponds to β/α=5/2 and γ/α2=1/5. The SK equation [2, 9–11] and CDG equation [12] are obtained when β/α=1 and γ/α2=1/5. The Ito equation arises when β/α=2 and γ/α2=2/9. It has been shown in the literature that the properties of (1) drastically change as α,β, and γ take different values. For instance, the Lax equation and the SK equation are completely integrable and possess N-soliton solution. The KK equation is integrable and has bilinear representation. However, the Ito equation is not completely integrable but has a finite number of conservation laws. For more details, see [1–4, 9–11, 13] and the references in them.
We investigate the traveling wave solutions of the nonlinear wave equation (1) in the form u(x,t)=y(x-ct)=y(ξ), where c is the wave speed and ξ=x-ct. Under the traveling wave coordinates, the nonlinear wave equation (1) can be reduced to a nonlinear ordinary differential equation (ODE) of the independent variable ξ. Integrating the reduced ODE once with respect to ξ gives(3)d4ydξ4+αyd2ydξ2+12β-αdydξ2+13γy3-cy+g=0,where g is a constant of integration. Clearly, y(ξ)=y(x-ct) is a traveling wave solution of (1) if and only if y(ξ) satisfies (3) with the wave speed c and any constant g. The equilibrium points and linearized system of (3) were studied in [7, 14, 15]. By using the method of dynamical systems and Cosgrove’s results [16], Li [7, 14, 15] obtained some exact solitary wave and quasiperiodic wave solutions of the CDG equation.
Generally, we have to study the dynamical behavior of the fourth-order ODE (3) in the 4-dimensional phase space, for which it is usually very difficult to obtain the orbits. However, for the case when the first integrals of this equation can be found, this problem can be reduced to the one in the lower dimensional space which might be easier to handle. It has been a successful idea to find exact solutions of nonlinear PDEs by reducing them into ODEs, especially for some solvable ODEs. A lot of methods in the literatures use this idea, for instance, the tanh-function method and extended tanh-function method [3, 4, 17], simple transformation method [18], the Riccati equation method [19], the Jacobi elliptic function method [20], the exp-function method [21], the homogeneous balance method [22], the (G′/G)-expansion method [23], and subequation method [24]. Also a direct and systematical approach to find exact solutions of nonlinear equations was proposed by using rational function transformations and thus was named as the transformed rational function method by Ma [25]. However, if the dynamics and bifurcation of these ODEs are not investigated, some solutions obtained by different methods, which are presented in different forms, can easily be misunderstood as different solutions [26, 27]. For example, a solution in the form f(tanh2ξ) obtained by the tanh-method can be expressed as f(1-sech2ξ) or f((ex-e-x)2/(ex+e-x)2), which also can be derived by the sech-method and the Exp-function method.
Notice that (3) contains the terms d4y/dξ4, d2y/dξ2, (dy/dξ)2, and polynomial of y. Suppose that y satisfies the equation(4)dydξ2=Pmy,where Pm(y) is a polynomial function of degree m; then(5)d2ydξ2=12Pm′y,(6)d4ydξ4=12Pm′′′yPmy+14Pm′′yPm′y,which are both polynomials of y. This observation motivates us to try to find some possible integer m and undetermined coefficients of the polynomial Pm such that y solves higher-order equation (3) if y is a solution of (4) which is obviously easier to study.
Following the idea we mentioned above, in Section 2, we derive the subequation of a more general fourth-order ODE(7)d4ydξ4+Ay+Bd2ydξ2+Cdydξ2+Dy3+Ey2+Fy+G=0firstly and then investigate the bifurcations and bounded solutions of (7) through the obtained subequations. By the formulas presented in Section 2 and with the help of computer algebra and symbolic computation, we study the bounded traveling wave solutions of the Lax equation and the Ito equation as examples in Section 3. In Section 4, we extend the formulas obtained in Section 2 to study the exact traveling wave solutions of a generalized sixth-order KdV equation.
2. Subequations and Exact Solutions of the Fourth-Order Equation (7)
Suppose that y satisfies (4); then the first three terms of the left-hand side of (7) are all polynomials of y and their degrees are 2m-3, m and m, respectively. Consequently, we assume m=3 (a3≠0) to find the possible polynomial P3(y) such that it solves (7) if y solves (4).
Definition 1.
We say that equation A is a subequation of equation B if any solutions of equation A are also solutions of equation B.
We now prove that 4th-order ODE (7) possesses a class of lower-order solvable subequations.
Theorem 2.
Suppose that D≤1/120(3A+2C)2. Then ODE (7) has the following subequation:(8)dydξ2=P3y=a3y3+a2y2+a1y+a0,where(9)a3=-1303A+2C±3A+2C2-120D,a2=-3Ba3+2E2C+15a3+2A,a1=-2Ba2+a22+F9a3+2C+A,a0=-Ba1+a1a2+2G2C+3a3.That is, the function y=y(ξ) solves the fourth-order differential equation (7) if it solves (8).
Proof.
By differentiating (8) with respect to ξ once and three times, we obtain d2y/dξ2=1/2P3′(y) and d4y/dξ4=1/2P3′′′(y)P3(y)+1/4P3′′yP3′(y) which are (5) and (6) with m=3, respectively. Inserting (8), (5), and (6) with m=3 into (7) and comparing the coefficients of like powers of y, we have(10)y3: D+32Aa3+152a32+Ca3=0,y2: Ca2+32Ba3+152a2a3+Aa2+E=0,y1: F+92a1a3+a22+Ba2+Ca1+12Aa1=0,y0: 12a1a2+Ca0+3a0a3+12Ba1+G=0.Solving system (10) gives us (9).
Remark 3.
Note that all the denominators in (9) are supposed to be nonzero. If some of them are zero, we have to go back to the algebraic equations (10) to find the possible solutions.
According to the conclusion of Theorem 2, we know that the fourth-order ODE (7) can be reduced into the first-order nonlinear ODE (8) provided that D≤(3A+2C)2/120, which is really an inspiring result because the bifurcation and the exact solutions of the first-order nonlinear ODE (8) have been presented in [8]. We recall the theorem below to derive the exact solutions of (7) and thus obtain the exact traveling wave solutions of the fifth-order nonlinear wave equation (1) and the sixth-order KdV equation (2).
Theorem 4.
Let h±=2Δ(-a2±Δ)+3a1a2a3/54a32 and ye±=-a2±Δ/3a3, where Δ=a22-3a1a3>0; then the following conclusions hold.
(1) For a0=2h+, (8) has a bounded solution approaching ye+ as ξ goes to infinity given by(11)y=-a2+Δ3a3-Δa3sech212Δ1/4ξ-ξ0,a constant solution(12)y=-a2+Δ3a3,and an unbounded solution(13)y=-a2+Δ3a3+Δa3csch212Δ1/4ξ-ξ0, where ξ0 is an arbitrary constant.
(2) Suppose that a0∈(2h-,2h+).
Case (a). If a3>0, then, for any y3∈-a2+2Δ/3a3,-a2+Δ/3a3,(14)y=y3-123y3+a2a3+Δ+sn2Ω+ξ-ξ0,k+is a family of smooth periodic solutions of (8). Here k+=23y32+2a2/a3y3+a1/a3/-3y3-a2/a3+Δ+, Ω+=2/4-3a3y3-a2+a3Δ+, Δ+=-3y32-2a2/a3y3+a2/a32-4a1/a3, and sn represents the Jacobian elliptic sine-amplitude function.
Case (b). If a3<0, then, for any y1∈-a2+Δ/3a3,-a2+2Δ/3a3,(15)y=y1-123y1+a2a3-Δ-sn2Ω-ξ-ξ0,k-is a family of smooth periodic solutions of (8). Here k-=23y12+2a2/a3y1+a1/a3/3y1+a2/a3+Δ- and Ω-=2/4-3a3y1-a2-a3Δ- and Δ-=-3y12-2a2/a3y1+a2/a32-4a1/a3.
(3) For a0∈(-∞,2h-]∪(2h+,+∞), (8) has no nontrivial bounded solutions. When a0=2h-, an unbounded solution is given by(16)y=-a2+Δ3a3+Δa3sec212Δ1/4ξ-ξ0,and a constant solution is given by(17)y=-a2+Δ3a3.
Remark 5.
From Theorem 4, we conclude that (11)–(17) are solutions of the second-order ODE d2y/dξ2=1/2P3′(y)=1/2(3a3y2+2a2y+a1).
Inserting A=α, B=0, C=(β-α)/2, D=γ/3, E=0, F=-c, and G=g into (7) gives (3). Consequently, in terms of Theorem 2, we get the subequation of (3).
Theorem 6.
Suppose that γ≤(2α+β)2/40 and γ∉{-3α2/10-αβ/2-β2/5,-9α2/8+3αβ/2-3β2/8,αβ/3-β2/9}. Then ODE (3) admits the subequation (8) with(18)a3=-1302α+β±2α+β2-40γ,a2=0,a1=2c9a3+β,a0=2gα-β-6a3.
From the proof of Theorem 2, one can easily find that the undetermined coefficients of the subequation (8) are determined by the equations corresponding to (10). Thus we may find more solutions for the case when the denominators of (18) are 0. If γ≤(2α+β)2/40 and γ∉{-3α2/10-αβ/2-β2/5,-9α2/8+3αβ/2-3β2/8,αβ/3-β2/9}, then a3∉{-(α+β)/15,(α-β)/6,-β/9}. Then the determining equations of a0,a1, and a2 will have unique solutions for the determined a3. However, for the case when γ=-3α2/10-αβ/2-β2/5 and thus a3=-(α+β)/15, a2 can be arbitrary constant; for the case when γ=-9α2/8+3αβ/2-3β2/8 and thus a3=(α-β)/6, a0 can be arbitrary constant if g is chosen to be zero; for γ=αβ/3-β2/9 and thus a3=-β/9, a0 can be arbitrary constant if c is chosen to be zero.
3. Exact Traveling Wave Solutions of a Class of 5th-Order Nonlinear Wave Equations
In Section 2, we derived some subequations of the fourth-order ODE (3) which determines the traveling wave solutions of the fifth-order nonlinear wave equation (1). Therefore, one can derive the exact traveling wave solutions of (1) through Theorems 4 and 6. Note that a0 is determined by an arbitrary integration constant g, so a0 is also an arbitrary constant. Clearly,(19)Δ±=a22-3a1a3=2c-2α+β±2α+β2-40γ7α-4β∓2α+β2-40γ.According to Theorem 4, if 2c-(2α+β)±(2α+β)2-40γ/7α-4β∓(2α+β)2-40γ>0, the bounded solutions of (4) can be obtained from (11)–(17).
We now study the Lax equation and the Ito equation as examples of the application of the approach we proposed in this paper.
3.1. Exact Traveling Wave Solutions of the Lax Equation
The Lax equation which has been studied in [3, 7] is given by(20)uxxxxx+10uuxxx+20uxuxx+30u2ux+ut=0.This is (1) with α=10,β=20, and γ=30.
Theorem 7.
The Lax equation (20) has the following four families of bounded traveling wave solutions.
(1) The Lax equation (20) has a peak-form solitary wave solution (see Figure 1)(21)ux,t=-14c14+314c14sech21227c1/4x-ct-ξ0,where the wave speed c>0.
(2) For any arbitrary constant a2, the Lax equation (20) has a family of peak-form solitary wave solutions(22)ux,t=16a2-6c-5a22+126c-5a22sech2126c-5a221/4x-ct-ξ0,where c>5/6a22.
(3) For any arbitrary c>0 and u1∈1/1414c,1/714c,(23)ux,t=u1+12Δ1-3u1sn2Ω1x-ct-ξ0,k1is a family of smooth periodic traveling wave solutions of the Lax equation (20). Here Ω1=1/69u1+3Δ1, k1=12u12-6/7c/3u1+Δ1, and Δ1=6/7c-3u12.
(4) For any arbitrary a2,c>5/6a22 and u1∈1/6(a2+6c-5a22),1/6(a2+26c-5a22),(24)ux,t=u1+123u1+12a2+Δ2sn2Ω2x-ct-ξ0,k2is a family of smooth periodic traveling wave solutions of the Lax equation (20) (see Figure 2). Here Δ2=2c-3u12+a2u1-7/4a22, Ω2=1/412u1-2a2+4Δ2, and k2=212u12-4a2u1+2a22-2c/6u1-a2+2Δ2.
Three-dimensional portrait of the solitary wave solution of the Lax equation (20) with c=1.
Portrait of the periodic wave solution of the Lax equation (20) with c=1. (a) Three-dimensional portrait; (b) overhead view with contour plot.
Proof.
Inserting α=10, β=20, and γ=30 into the first equation of (18) gives a3=2/3 and a3=-2. Note that 1/15(α+β)=2. Using these values with a3=-2/3, (18) and (19) give a2=0, a1=1/7c, a0=-1/3g, and Δ+=2/7c and so from (11), we obtain (21) which is a peak-form solitary wave solution of the Lax equation.
Further, since g is an arbitrary constant, we suppose that 2/3u3-1/7cu+1/3g=2/3(u1-u)(u2-u)(u-u3) for certain value of g, where u1>u2>u3. Then by the relationship between coefficients and roots of a polynomial, we have(25)u1+u2+u3=0,u1u2+u1u3+u2u3=-314c.
Obviously, 1/1414c<u1<1/714c. By letting Δ1=6/7c-3u12, from (25), we obtain(26)u2=-12u1-Δ1,u3=-12u1+Δ1.Inserting (26) into (15) gives (23).
For the second value of a3=-2, we note that the denominator and numerator of a2 in (9) are both zero for α=10, β=20, and γ=30. Thus we have to go back to the algebraic equations (10). Clearly, A=10, B=0, C=5, and D=10 when α=10, β=20, and γ=30. Substituting a3=-2 into (10) gives(27)a22+a1-c=0,12a1a2-a0+g=0.Solving (27) for a2, a1, and a0 gives a1=c-a22 and a0=g+1/2a2c-1/2a23 and a2 can be an arbitrary constant. Inserting these results into (11) and (14) gives (22) and (24), respectively.
Remark 8.
We note that we recover the solutions of the Lax equation obtained in [3] as special cases of our solutions. The solitary wave solutions (22) are consistent with the solutions (138) in [3], but the solution (21) and other two families of periodic wave solutions are new.
3.2. Exact Traveling Wave Solutions of the Ito Equation
The Ito equation [13] is given by(28)uxxxxx+3uuxxx+6uxuxx+2u2ux+ut=0and can be retrieved from (1) by letting α=3, β=6, and γ=2.
Theorem 9.
The Ito equation (28) has the following four families of bounded traveling wave solutions.
(1) It has a peak-form solitary wave solution(29)ux,t=-5126c+546csech212c61/4x-ct-ξ0,where the wave speed c>0.
(2) For any arbitrary constant u0, the Ito equation (28) has a family of peak-form solitary wave solutions(30)ux,t=-2u02+6u02sech2u0x-ξ0.The wave speed of this family of waves is zero; that is, these are standing waves.
(3) For any arbitrary c>0 and u1∈5/126c,5/66c,(31)ux,t=u1+12Δ3-3u1sn2Ω3x-ct-ξ0,k3is a family of smooth periodic traveling wave solutions of the Ito equation. Here Ω3=1/6060(3u1+Δ3), k3=48u12-50c/6u1+2Δ3, and Δ3=25/2c-3u12.
(4) For any arbitrary a1>0 and u1∈1/22a1,2a1,(32)ux,t=u1+12Δ4-3u1sn2Ω4x-ξ0,k4is a family of smooth periodic traveling wave solutions of the (28). Here Δ4=6a1-3u12, Ω4=1/69u1+3Δ4, and k4=12u12-6a1/3u1+Δ4.
Proof.
Inserting α=3, β=6, and γ=2 into the first equation of (19) gives a3=-2/15 or a3=-2/3. Using the values of α,β, and γ with a3=-2/15, (19) gives a2=0 and a1=5/12c. Thus Δ+=1/6c. Inserting these results into (11) gives (29) which is a peak-form solitary wave solution of the Ito equation.
Further, we suppose that -2/15u3+1/7cu-1/3g=-2/15(u1-u)(u2-u)(u-u3) for certain value of g, where u1>u2>u3. Using the relationship between coefficients and roots of a polynomial, we have(33)u1+u2+u3=0,u1u2+u1u3+u2u3=-258c.
Clearly, 5/126c<u1<5/66c. Letting Δ3=50c-12u12, from (33), we obtain(34)u2=-142u1-Δ3,u3=-142u1+Δ3.Inserting (34) into (15) gives (31).
Now, for a3=-2/3, the denominator of a1 in (9) is zero when α=3, β=6, and γ=2, so we have to go back to the algebraic equations (10). Clearly, A=3, B=0, C=3/2, D=2/3, and E=0 when α=3, β=6, and γ=2. From the second equation of (10), we obtain a2=0. Clearly, when a3=-2/3 and a2=0, any arbitrary a1 solves the third equation of (10) if F=0; that is, c=0. Then from the last equation of (10), we obtain a0=2g. Using these values into (11) and (15) we obtain (30) and (32), respectively.
Remark 10.
The solitary wave solutions (29) and (30) are consistent with the solutions (89) and (91) in [3], respectively. However, the periodic solutions (31) and (32) are new.
4. Application to the General Sixth-Order KdV Equation (2)
We now generalize this approach to study a new sixth-order nonlinear wave equation (2) which was derived by Karasu-Kalkanli et al. [6] in 2008. Letting u(x,t)=u(x-vt)=u(ξ), setting y=du/dξ, and integrating it once with respect to ξ, we have(35)d4ydξ4+ay-evd2ydξ2+12b-adydξ2+13cy3-12vf+gy2+dv2y+β=0,where β is an integration constant.
Obviously, the traveling wave solutions of the sixth-order KdV equation (2) are given by u(ξ)=∫y(ξ)dξ, where y(ξ) solves ODE (35) which is similar to (7). By letting A=a, B=-ev, C=1/2(b-a), D=1/3c, E=-1/2v(f+g), F=dv2, and G=β in (9), we have the following lemma.
Lemma 11.
Suppose c≤1/40(b+2a)2. If y=y(ξ) solves (35), then it solves (8), where(36)a3=-130b+2a±b+2a2-40c,a2=vf+g+3eva315a3+b+a,a1=2eva2-dv2-a229a3+b,a0=eva1-a1a2-2β6a3+b-a.
Remark 12.
If any denominators of a2,a1, or a0 are zero, we need to go back to the equations(37)y3: 15a32+3aa3+b-aa3+23c=0,y2: 15a2a3+4aa2-3a3ev+b-aa2-vf+g=0,y1: 92a1a3+a22-2a2ev+aa1+12b-aa1+dv2=0,y0: a1a2+6a0a3-2a1ev+b-aa0+2β=0to find possible solutions.
Note that here a0 can be arbitrary number because β is an arbitrary integration constant. From Lemma 11 and Theorem 4, it is easy to see that the traveling wave solutions of the six-order KdV equations (2) can be obtained by detecting the relationship between the coefficients ai, i=0,1,2,3, which are determined by (36). The two families of exact solutions exist if a1,a2, and a3 defined by (36) satisfy a22-3a1a3>0, because a0 is an integration constant. With the help of Maple, we can obtain the traveling waves of the six-order KdV equation (2) automatically.
Equation (2) with a=20, b=40, c=120, d=0, e=1, f=8, and g=4, namely,(38)uxxxxxx+20uxuxxxx+40uxxuxxx+120ux2uxx+uxxxt+8ux2uxt+4ut2uxx=0,was studied in [28]. According to (36) and Theorem 4, we obtain a3=-4/3, a2=1/5v, a1=2/175v2, a0=2/2625v3-1/6β, or a3=-4, a1=1/2(va2-a22), and a0=1/8(2va22-v2a2-a23+4β), and a2 is an arbitrary constant.
Note that β is an arbitrary integration constant. Consequently, from Theorem 4, we obtain the exact solutions of (38) as u(x,t)=∫y(ξ)dξ, where ξ=x-vt and y(ξ) is defined as follows.
(2) For arbitrary a2,(40)y=112a2--5a22+6a2v+146a2v-5a22sech212-5a22+6a2v1/4ξ-ξ0.
(3) For any arbitrary v≠0 and 1/140(7v+105v)<y1<1/140(7v+2105v),(41)y=y1+32y1+340v+12Δ5sn2Ω5ξ-ξ0,k5,where Ω5=1/601800y1-90v+600Δ5, k5=-42v2-1470vy1+14700y12/35(3y1-3/20v+Δ5), and Δ5=3/10vy1+159/2800v2-3y12.
(4) For any arbitrary a2, v≠0, and 1/12(a2+-5a22+6va2)<y1<1/12(a2+2-5a22+6va2),(42)y=y1+32y1+18a2+12Δ6sn2Ω6ξ-ξ0,k6,where Ω6=1/424y1-2a2+8Δ6, k6=48y12-8a2y1-2a2v+2a22/6y1-1/2a2+2Δ6, and Δ6=1/2a2y1-7a22+1/2va2-3y12.
Remark 13.
Obviously, this algorithm also can be used to study the sixth-order KdV equation (2) with other coefficients values.
5. Conclusion and Discussion
The exact traveling wave solutions of a general fifth-order nonlinear wave equation and a generalized sixth-order KdV equation were studied in this paper. A systematic algorithm was proposed to study the exact solutions of an associated fourth-order ODE possessing even order derivatives. By using this algorithm, with the help of symbolic computation, the exact solitary wave and periodic wave solutions of a very general class of higher-order nonlinear wave equations can be obtained systematically. Here we obtained two families of solitary wave and periodic wave solutions of the Lax equation, the Ito equation, and a generalized sixth-order KdV equation. From the results of this paper, it is easy to see that this method can be used to find the traveling wave solutions of higher-order wave equations which can be reduced to the ODEs in the form F(y(2k),y(2k-2),…,y(2),y′2,y)=0, where F is a polynomial function.
It has been shown that the equations with nonlinear dispersion, usually related to singular dynamical systems, possess nonsmooth singular wave solutions, such as compacton and peakon, by using the dynamical system method and other methods [14, 29–32]. However, as far as we know, the dynamical system method has been well used to investigate the nonlinear wave equations which can be reduced to planar dynamical systems. Can we find the subequations of the higher-order wave equations with nonlinear dispersion in the form (dy/dξ)2=R(y)? Here R(y) is a rational function. How the theorems of planar singular dynamical systems [14, 33, 34] can be applied to find the singular wave solutions to higher-order nonlinear wave equations will be considered in our future work.
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
Acknowledgments
Lijun Zhang thanks the North-West University for the postdoctoral fellowship and DST-NRF Centre of Excellence in Mathematical and Statistical Sciences (CoE-MaSS). This work is partially supported by the Nature Science Foundation of China (nos. 11101371 and 11422214) and the Nature Science Foundation of Zhejiang (LY15A010021). The authors are also grateful to the referees for their valuable comments, which have led to several improvements.
HeremanW.NuseirA.Symbolic methods to construct exact solutions of nonlinear partial differential equations1997431132710.1016/S0378-4754(96)00053-5MR1438817ZBL0866.650632-s2.0-0030829213IncM.On numerical soliton solution of the Kaup-Kupershmidt equation and convergence analysis of the decomposition method20061721728510.1016/j.amc.2005.01.1202-s2.0-31144467784WazwazA.-M.Abundant solitons solutions for several forms of the fifth-order KdV equation by using the tanh method2006182128330010.1016/j.amc.2006.02.0472-s2.0-33750813325HuibinL.KelinW.Exact solutions for two nonlinear equations. I199023173923392810.1088/0305-4470/23/17/0212-s2.0-36149031409HongW.-P.JungY.-D.Auto-Backlund transformation and solitary-wave solutions to nonintegrable generalized fifth-order nonlinear evolution equations1999548-9549553Karasu-KalkanliA.KarasuA.SakovichA.SakovichS.TurhanR.A new integrable generalization of the Korteweg-de Vries equation20084972634263910.1063/1.29534742-s2.0-49249093587LiJ. B.ZhangY.Homoclinic manifolds, center manifolds and exact solutions of four-dimensional traveling wave systems for two classes of nonlinear wave equations201121252754310.1142/s02181274110285812-s2.0-79953862930ZhangL. J.KhaliqueC. M.Exact solitary wave and periodic wave solutions of the Kaup-Kuperschmidt equation201553485495MR3342832ParkerA.On soliton solutions of the Kaup-Kupershmidt equation. I. Direct bilinearisation and solitary wave20001371-2253310.1016/s0167-2789(99)00166-9MR1738764ParkerA.On soliton solutions of the Kaup–Kupershmidt equation. II. ‘Anomalous’ N-soliton solutions20001371-2344810.1016/s0167-2789(99)00167-02-s2.0-0346684395SawadaK.KoteraT.A method for finding N-soliton solutions for the K.d.V. equation and K.d.V.-like equation19745151355136710.1143/ptp.51.1355CaudreyP. J.DoddR. K.GibbonJ. D.A new hierarchy of Korteweg-de Vries equation1976351166640742210.1098/rspa.1976.01492-s2.0-0017022715ItoM.An extension of nonlinear evolution equations of the K-dV (mK-dV) type to higher orders198049277177810.1143/JPSJ.49.7712-s2.0-0000531288LiJ. B.2013Beijing, ChinaScience PressLiJ. B.ZhangY.The exact traveling wave solutions to two integrable KdV6 equations201233217919010.1007/s11401-012-0704-5MR28925912-s2.0-84863250979CosgroveC. M.Higher-order Painlevé equations in the polynomial class I. Bureau symbol P22000104116510.1111/1467-9590.001302-s2.0-0000424311MalflietW.HeremanW.The tanh method I: exact solutions of nonlinear evolution and wave equations199654656356810.1088/0031-8949/54/6/003MR1427913YanC. T.A simple transformation for nonlinear waves19962241-277842-s2.0-0043093642MaW. X.FuchssteinerB.Explicit and exact solutions to a Kolmogorov-Petrovskii-Piskunov equation199631332933810.1016/0020-7462(95)00064-x2-s2.0-0030145528ParkesE. J.DuffyB. R.AbbottP. C.The Jacobi elliptic-function method for finding periodic-wave solutions to nonlinear evolution equations20022955-628028610.1016/s0375-9601(02)00180-92-s2.0-0036539957HeJ.-H.WuX.-H.Exp-function method for nonlinear wave equations200630370070810.1016/j.chaos.2006.03.020ZBL1141.354482-s2.0-33745177020WangM. L.ZhouY. B.LiZ. B.Application of a homogeneous balance method to exact solutions of nonlinear equations in mathematical physics19962161–567752-s2.0-30244524644WangM.LiX.ZhangJ.The (G'/G)-expansion method and travelling wave solutions of nonlinear evolution equations in mathematical physics2008372441742310.1016/j.physleta.2007.07.051ZhangH. Q.New exact travelling wave solutions of nonlinear evolution equation using a sub-equation200939287388110.1016/j.chaos.2007.01.1322-s2.0-62549161310MaW.-X.LeeJ.-H.A transformed rational function method and exact solutions to the 3 + 1 dimensional Jimbo-Miwa equation20094231356136310.1016/j.chaos.2009.03.0432-s2.0-67650383727ZhangL. J.HuoX. W.On the Exp-function method for constructing travelling wave solutions of nonlinear equations in nonlinear and modern mathematical physics1212Proceedings of the 1st International Workshop2010Beijing, China280285KudryashovN. A.Seven common errors in finding exact solutions of nonlinear differential equations2009149-103507352910.1016/j.cnsns.2009.01.0232-s2.0-63449123795WenX.-Y.GaoY.-T.WangL.Darboux transformation and explicit solutions for the integrable sixth-order KdV equation for nonlinear waves20112181556010.1016/j.amc.2011.05.0452-s2.0-79959749287ZhangL. J.ChenL.-Q.HuoX. W.The effects of horizontal singular straight line in a generalized nonlinear Klein-Gordon model equation201372478980110.1007/s11071-013-0753-72-s2.0-84878577428ShenJ. W.XuW.LiW.Bifurcations of travelling wave solutions in a new integrable equation with peakon and compactons200627241342510.1016/j.chaos.2005.04.0202-s2.0-22844440384WangY.BiQ.Different wave solutions associated with singular lines on phase plane20126941705173110.1007/s11071-012-0380-8ZBL1263.340512-s2.0-84866109205RuiW. G.Different kinds of exact solutions with two-loop character of the two-component short pulse equations of the first kind201318102667267810.1016/j.cnsns.2013.01.0202-s2.0-84877593459ChowS. N.HaleJ. K.1981New York, NY, USASpringerGuckenheimerJ.HolmesP.1983New York, NY, USASpringer