New solitary and optical wave structures to the (1 + 1)-dimensional combined KdV–mKdV equation

Bulut, Hasan; Sulaıman, Tukur Abdulkadir; Baskonus, Hacı Mehmet; Sandulyak, A. A.

doi:10.1016/j.ijleo.2017.01.071

Cited by 52 publications

(25 citation statements)

References 13 publications

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“…Nonlinear evolution equations are often used to describe some physical aspects that arise in the various fields of nonlinear sciences, such as plasma physics, quantum mechanics, biological sciences, chemistry, chemical physics, and so forth. Various powerful techniques have been formulated and used by different scholars to find the solutions of some NLEEs, such as the sine-Gordon expansion method [1][2][3], the generalized Kudryashov method [4,5], the extended tanh method [6,7], the new generalized and improved (G /G)-expansion method [8], the Jacobi elliptic function method [9,10], the improved Bernoulli subequation function method [11], the tanh method [12,13], the sine-cosine method [14], the Lie group analysis method [15][16][17], the homogeneous balance method [18], the modified simple equation method [19,20], the meshless method of radial basis functions [21], He's variational iteration method [22], the explicit multistep Galerkin finite element method [23], the differential quadrature based numerical method [24], the partitioned second-order method [25], the adaptive pseudo-transient-continuation-Galerkin methods [26]. In general, various efficient techniques have been implemented to explore the search for the solutions of the different kind of NLEEs [27][28][29][30][31][32][33][34][35][36][37][38].…”

Section: Introductionmentioning

confidence: 99%

Numerical simulation and solutions of the two‐component second order KdV evolutionarysystem

Yokuş¹,

Baskonus²,

Sulaıman³

et al. 2017

Numerical Methods Partial

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126

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In this study, with the aid of Wolfram Mathematica 11, the modified exp (− (η))-expansion function method is used in constructing some new analytical solutions with novel structure such as the trigonometric and hyperbolic function solutions to the well-known nonlinear evolutionary equation, namely; the two-component second order KdV evolutionary system. Second, the finite forward difference method is used in analyzing the numerical behavior of this equation. We consider equation (6.5) and (6.6) for the numerical analysis. We examine the stability of the two-component second order KdV evolutionary system with the finite forward difference method by using the Fourier-Von Neumann analysis. We check the accuracy of the finite forward difference method with the help of L 2 and L ∞ norm error. We present the comparison between the exact and numerical solutions of the two-component second order KdV evolutionary system obtained in this article which and support with graphics plot. We observed that the modified exp (− (η))-expansion function method is a powerful approach for finding abundant solutions to various nonlinear models and also finite forward difference method is efficient for examining numerical behavior of different nonlinear models. K E Y W O R D Sanalytical solutions, numerical solutions, the FDM, the MEFM, the twocomponent second order KdV evolutionary system Numer Methods Partial Differential Eq. 2018;34:211-227.wileyonlinelibrary.com/journal/num

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Section: Introductionmentioning

confidence: 99%

Numerical simulation and solutions of the two‐component second order KdV evolutionarysystem

Yokuş¹,

Baskonus²,

Sulaıman³

et al. 2017

Numerical Methods Partial

Self Cite

126

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“…For solving the nonlinear partial differential equations, there have been many schemes applied such as the Kudryashov method by M. Foroutan et al in [15] and K. K. Ali et al in [16]; the modified Kudryashov method by K. Hosseini et al in [17,18], D. Kumar et al in [19], A. K. Joardar et al in [20] and A.R. Seadawy et al in [21]; the generalized Kudryashov method by F. Mahmud et al in [22], S. T. Demiray et al in [23] and S. Bibi et al in [24]; the sine-cosine method by K. R. Raslan et al in [25]; the sine-Gordon method by H. Bulut et al in [26]; the sinh-Gordon equation expansion method by H. M. Baskonus et al in [27], Y. Xian-Lin et al in [28] and A. Esen et al in [29]; the extended trial equation method by K. A. Gepreel in [30], Y. Pandir et al in [31] and Y. Gurefe et al in [32]; the Exp-function method by L.K. Ravi et al in [33], A. R. Seadawy et al in [34] and M. Nur Alam et al in [35]; the Jacobi elliptic function method by S. Liu et al in [36]; the F-expansion method by A. Ebaid et al in [37]; and the extended G G method by E. M. E. Zayed and S. Al-Joudi et al in [38].…”

Section: Introductionmentioning

confidence: 99%

Modified Kudryashov Method to Solve Generalized Kuramoto-Sivashinsky Equation

Kılıçman

Silambarasan

2018

Symmetry

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The generalized Kuramoto–Sivashinsky equation is investigated using the modified Kudryashov method for the new exact solutions. The modified Kudryashov method converts the given nonlinear partial differential equation to algebraic equations, as a result of various steps, which upon solving the so-obtained equation systems yields the analytical solution. By this way, various exact solutions including complex structures are found, and their behavior is drawn in the 2D plane by Maple to compare the uniqueness and wave traveling of the solutions.

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“…Nonlinear evolution equation are often used to describe complex aspects of various models arising in the field of nonlinear sciences such as mathematical physics, chemical physics, chemistry, biological sciences etc. Attention from different researchers has been paid to this area in searching for new solutions to the different class of NLEEs where various powerful method are formulated such as the generalized and improved   / GG  -expansion method [1], the Jacobi elliptic-function method [2], the modified simple equation method [3,4], the sine-Gordon expansion method [5][6][7], the extended tanh method [8], the improved Bernoulli sub-equation function method [9], the rational sine-cosine method [10], the RicattiBernoulli sub-ODE method [11], the Homotopy perturbation method [12] and so on. However, in this work we aim at investigating solution of the ill-posed Boussinesq equation [13] by using the modified exp…”

Section: Introductionmentioning

confidence: 99%

New soliton properties to the ill-posed Boussinesq equation arising in nonlinear physical science

Duran¹,

Askin²,

Sulaıman³

2017

Int. J. Optim. Control, Theor. Appl. (IJOCTA)

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In manuscript, with the help of the Wolfram Mathematica 9, we employ the modified exponential function method in obtaining some new soliton solutions to the ill-posed Boussinesq equation arising in nonlinear media. Results obtained with use of technique, and also, surfaces for soliton solutions are given. We also plot the 3D and 2D of each solution obtained in this study by using the same program in the Wolfram Mathematica 9.

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New solitary and optical wave structures to the (1 + 1)-dimensional combined KdV–mKdV equation

Cited by 52 publications

References 13 publications

Numerical simulation and solutions of the two‐component second order KdV evolutionarysystem

Numerical simulation and solutions of the two‐component second order KdV evolutionarysystem

Modified Kudryashov Method to Solve Generalized Kuramoto-Sivashinsky Equation

New soliton properties to the ill-posed Boussinesq equation arising in nonlinear physical science

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