In this paper, the ansatze method is implemented to study the exact solutions for the modified Benjamin-Bona-Mahony equation (mBBM). The singular-shaped traveling wave solution, the Bell-shape is traveling wave solution, the kink-shaped traveling wave solution and the periodic traveling wave solution is obtained. With the assist of computational software MATLAB, the graphical exemplifications of solutions are illustrated of the two-dimension (2D) and three-dimension (3D) plots.
Nonlinear evolution equations are extensively used as models to describe intricate physical phenomena in diverse fields of the sciences, peculiarly in fluid mechanics, solid state physics, plasma physics, and chemical physics [
The Benjamin-Bona-Mahony (BBM) equation
u t + u x + u n u x + u x x t = 0 (1)
is the most famous model in physical applications. This equation model long waves in a nonlinear dispersive system. The solution of the BBM equation exhibits definite soliton-like behavior that is not explainable by any known theory [
u t + u x + a u 2 u x + b u x x t = 0 , (2)
Here a and b are nonzero constants, u ( x , t ) is an unknown function, with respect to the spatial variable x and temporal variable t.
Kamruzzaman Khan and M.Ali Akbar [
The article is prepared as follows: In Section 2, we discuss the exact traveling wave solutions of modified Benjamin-Bona-Mahoney equation, In Section 3, we provide the dynamic behaviors of the traveling wave solutions of mBBM equation, and the short conclusions are given in Section 4.
Using the Following Traveling Wave Transformation
u ( x , t ) = u ( ξ ) = u ( x + ω t ) , (3)
Equation (2) can be reduced into the following ordinary differential equation (ODE).
( ω + 1 ) u ′ + a u 2 u ′ + b ω u ‴ = 0. (4)
Integrating (4) once with respect to ξ , and choosing constant of integration as zero, we can obtain the following ODE.
( ω + 1 ) u + 1 3 a u 3 + b ω ″ = 0. (5)
Suppose that the solutions of Equation (5) have the following form.
u ( ξ ) = ∑ i = 1 m sinh i − 1 α ( B i sinh α + A i cosh α ) + A 0 . (6)
Balancing the highest nonlinear terms u 3 and the highest derivative term u ″ in Equation (5), we obtain 3m = m+ 2, which gives m = 1.
By (6) we can write as
u ( ξ ) = B 1 sinh α + A 1 cosh α + A 0 . (7)
where A 0 , A 1 and B 1 are undetermined constants. Let be the ansatze
d α d ξ = sinh α . (8)
By Substituting (7), (8) into Equation (5), this yields the polynomial of sinh i α cosh i α ( i = 0 , 1 , 2 , 3 ) , setting the coefficients of each power sinh i α cosh i α ( i = 0 , 1 , 2 , 3 ) to zero, we can obtain the following algebraic equations with respect to A 0 , A 1 , B 1 and ω .
{ ( ω + 1 ) A 0 + 1 3 a A 0 3 + a A 0 2 A 1 = 0 , ( ω + 1 ) B 1 + a A 1 2 B 1 + a A 0 2 B 1 + b ω B 1 = 0 , a A 0 B 1 2 + a A 0 2 A 1 = 0 , 1 3 a B 1 3 + a A 1 2 B 1 + 2 b ω B 1 = 0 , ( ω + 1 ) A 1 − a A 1 B 1 2 + a A 0 2 A 1 − 2 b ω A 1 = 0 , 1 3 a A 1 3 + a A 1 B 1 2 + 2 b ω A 1 = 0 , 2 a A 0 A 1 B 1 = 0. (9)
Solving the above algebraic Equations (9), we can obtain the following three sets of solutions,
Case 1. A 0 = 0 , A 1 = 0 , B 1 = ± − 6 b ω a , ω = − 1 1 + b ; (10)
Case 2. A 0 = 0 , B 1 = 0 , A 1 = ± − 6 b ω a , ω = − 1 1 − 2 b ; (11)
Case 3. A 0 = 0 , A 1 = ± − ( ω + 1 ) − b ω a , B 1 = ± ( ω + 1 ) − 2 b ω a , ω = − 2 2 − b . (12)
By applying the method of separating into variables to solve Equation (8), with choosing constant of integration to zero, we obtain:
sinh α = − csch ξ , cosh α = − coth ξ . (13)
Using (10), (13), (3) and (7), we have:
u 1 , 2 ( ξ ) = ∓ − 6 b ω a csch ξ , (14)
where ξ = x − 1 1 + b t , u 1 takes “+”, u 2 takes “−”.
Using (11), (13), (3) and (7), we have:
u 3 , 4 ( ξ ) = ∓ − 6 b ω a coth ξ , (15)
where ξ = x − 1 1 − 2 b t , u 3 takes “+”, u 4 takes “−”.
Using (12), (13), (3) and (7), we have:
u 5 , 6 , 7 , 8 ( ξ ) = ∓ ( ω + 1 ) − 2 b ω a csch ξ ∓ − ( ω + 1 ) − b ω a coth ξ , (16)
where ξ = x − 2 2 − b t , u 5 takes “+, +”, u 6 takes “−, −”, u 7 takes “+, −”, u 8 takes “−, +”.
By the above analysis, we can obtain the solutions of Equation (2), as follows:
Proposition 1.
1) If a b ( 1 + b ) > 0 , Equation (2) have the following hyperbolic function solutions
u 1 , 2 ( x , t ) = ∓ 6 b a ( 1 + b ) csch ( x − t 1 + b ) ,
2) If a b ( 2 b − 1 ) < 0 , Equation (2) have the following hyperbolic function solutions
u 3 , 4 ( x , t ) = ∓ 6 b a ( 1 − 2 b ) coth ( x − t 1 − 2 b ) ,
3) If a b ( b − 2 ) < 0 , Equation (2) have the following hyperbolic function solutions
u 5 , 6 , 7 , 8 ( x , t ) = ∓ 3 b a ( 2 − b ) ( csch ( x + 2 b − 2 t ) ∓ coth ( x + 2 b − 2 t ) ) .
Suppose that the solutions of Equation (5) have the following form.
u ( ξ ) = ∑ i = 1 m sin i − 1 α ( B i sin α + A i cos α ) + A 0 . (17)
Balancing the highest nonlinear terms u 3 and the highest derivative terms u ″ in Equation (5), we obtain m = 1.
By (17) we can write as
u ( ξ ) = B 1 sin α + A 1 cos α + A 0 , (18)
where A 0 , A 1 and B 1 are undetermined constants. Let be the ansatze
d α d ξ = sin α . (19)
By Substituting (18), (19) into Equation (5), this yields the polynomial of sinh i α cosh i α ( i = 0 , 1 , 2 , 3 ) , setting the coefficients of each power sinh i α cosh i α ( i = 0 , 1 , 2 , 3 ) to zero, we can obtain the following algebraic equations with respect to A 0 , A 1 , B 1 and ω .
{ ( ω + 1 ) A 0 + 1 3 a A 0 3 + a A 0 A 1 2 = 0 , ( ω + 1 ) B 1 + a A 1 2 B 1 + a A 0 2 B 1 + b ω B 1 = 0 , a A 0 B 1 2 − a A 0 A 1 2 = 0 , 1 3 a B 1 3 − a A 1 2 B 1 − 2 b ω B 1 = 0 , ( ω + 1 ) A 1 + a A 1 B 1 2 + a A 0 2 A 1 − 2 b ω A 1 = 0 , 1 3 a A 1 3 − a A 1 B 1 2 + 2 b ω A 1 = 0 , 2 a A 0 A 1 B 1 = 0. (20)
Solving the above algebraic Equations (20), we can obtain the following two sets of solutions,
Case 1. A 0 = 0 , A 1 = 0 , B 1 = ± 6 b ω a , ω = − 1 1 + b (21)
Case 2. A 0 = 0 , B 1 = 0 , A 1 = ± − 6 b ω a , ω = − 1 1 − 2 b . (22)
By applying the method of separating into variables to Equation (19), with choosing constant of integration to zero, we obtain:
sin α = sec h ξ , cos α = ± tanh ξ . (23)
Using (21), (23), (3) and (18), we have:
u 1 , 2 ( ξ ) = ± 6 b ω a sech ξ , (24)
where ξ = x − 1 1 + b t , u 1 takes “+”, u 2 takes “−”.
Using (22), (23), (3) and (18), we have:
u 3 , 4 ( ξ ) = ± − 6 b ω a tanh ξ , (25)
where ξ = x − 1 1 − 2 b t , u 3 takes “+”, u 4 takes “−”.
By the above analysis, we can obtain the solutions of Equation (2), as follows:
Proposition 2.
1) If a b ( 1 + b ) < 0 , Equation (2) have the following hyperbolic function solutions
u 1 , 2 ( x , t ) = ∓ − 6 b a ( 1 + b ) sech ( x − t 1 + b ) ,
2) If a b ( 1 − 2 b ) > 0 , Equation (2) have the following hyperbolic function solutions
u 3 , 4 ( x , t ) = ∓ 6 b a ( 1 − 2 b ) tanh ( x − t 1 − 2 b ) .
For (6) and (7), Let be the ansatze
d α d ξ = cosh α . (26)
By Substituting (7), (26) into Equation (5), this yields the polynomial of sinh i α cosh i α ( i = 0 , 1 , 2 , 3 ) , setting the coefficients of each power sinh i α cosh i α ( i = 0 , 1 , 2 , 3 ) to zero, we can obtain the following algebraic equations with respect to A 0 , A 1 , B 1 and ω .
{ ( ω + 1 ) A 0 + 1 3 a A 0 3 + a A 0 2 A 1 = 0 , ( ω + 1 ) B 1 + a A 1 2 B 1 + a A 0 2 B 1 + 2 b ω B 1 = 0 , a A 0 B 1 2 + a A 0 2 A 1 = 0 , 1 3 a B 1 3 + a A 1 2 B 1 + 2 b ω B 1 = 0 , ( ω + 1 ) A 1 − a A 1 B 1 2 + a A 0 2 A 1 − b ω A 1 = 0 , 1 3 a A 1 3 + a A 1 B 1 2 + 2 b ω A 1 = 0 , 2 a A 0 A 1 B 1 = 0. (27)
Solving the above algebraic Equations (27), we can obtain the following three sets of solutions,
Case 1. A 0 = 0 , A 1 = 0 , B 1 = ± − 6 b ω a , ω = − 1 1 + 2 b ; (28)
Case 2. A 0 = 0 , B 1 = 0 , A 1 = ± − 6 b ω a , ω = − 1 1 − b ; (29)
Case 3. A 0 = 0 , A 1 = ± − ( ω + 1 ) − 2 b ω a , B 1 = ± ( ω + 1 ) − b ω a , ω = − 2 2 + b . (30)
By applying the method of separating into variables to Equation (26), with choosing constant of integration to zero, we obtain:
sinh α = − cot ξ , cosh α = − csc ξ . (31)
Using (28), (31), (3) and (7), we have:
u 1 , 2 ( ξ ) = ∓ − 6 b ω a cot ξ , (32)
where ξ = x − 1 1 + 2 b t , u 1 takes “+”, u 2 takes “−”.
Using (29), (31), (3) and (7), we have:
u 3 , 4 ( ξ ) = ∓ − 6 b ω a csc ξ , (33)
where ξ = x − 1 1 − b t , u 3 takes “+”, u 4 takes “−”.
Using (30), (31), (3) and (7), we have:
u 5 , 6 , 7 , 8 ( ξ ) = ∓ ( ω + 1 ) − 2 b ω a cot ξ ∓ − ( ω + 1 ) − b ω a csc ξ , (34)
where ξ = x − 2 2 + b t , u 5 takes “+, +”, u 6 takes “−, −”, u 7 takes “+, −”, u 8 takes “−, +”.
By the above analysis, we can obtain the solutions of Equation (2), as follows:
Proposition 3.
1) If a b ( 1 + 2 b ) > 0 , Equation (2) have the following trigonometric function solutions
u 1 , 2 ( x , t ) = ∓ 6 b a ( 1 + 2 b ) cot ( x − t 1 + 2 b ) ,
2) If a b ( b − 1 ) < 0 , Equation (2) have the following trigonometric function solutions
u 3 , 4 ( x , t ) = ∓ 6 b a ( 1 − b ) csc ( x − t 1 − b ) ,
3) If a b ( b + 2 ) > 0 , Equation (2) have the following trigonometric function solutions
u 5 , 6 , 7 , 8 ( x , t ) = ∓ 5 b a ( 2 + b ) cot ( x − 2 2 + b t ) ∓ b a ( 2 + b ) csc ( x − 2 2 + b t ) .
The solution (14) is the singular-shape traveling wave solution.
The solution (24) is the Bell-shape traveling wave solution.
the interval − 5 ≤ x , t ≤ 5 ). By
The solution (32) is the periodic traveling wave solution.
and multiple peaks and varies in height. The solution (33) is the periodic traveling wave solution.
In this paper, we apply the ansatze method to find the exact solutions of the mBBM equation. Including the singular-shape traveling wave solution, the Bell-shape traveling wave solution, the kink-shape traveling wave solution and the periodic traveling wave solution, the dynamic behaviors of solutions are given.
Sincere thanks to the members of JAMP for their professional performance.
The authors declare no conflicts of interest regarding the publication of this paper.
Zhu, Y., Liu, X.H., Huang, X. and Ye, F.Y. (2022) Traveling Wave Solution of the Modified Benjamin- Bona-Mahony Equation. Journal of Applied Mathematics and Physics, 10, 3143-3155. https://doi.org/10.4236/jamp.2022.1010209