HAUSDORFF FRACTAL NEW COUPLED NONLINEAR SCHRÖDINGER MODEL AND ITS NOVEL SOLITARY WAVE SOLUTION
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Publication:5082113
DOI10.1142/S0218348X21502522OpenAlexW3195480397MaRDI QIDQ5082113
Publication date: 15 June 2022
Published in: Fractals (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1142/s0218348x21502522
NLS equations (nonlinear Schrödinger equations) (35Q55) Soliton solutions (35C08) Fractional partial differential equations (35R11)
Cites Work
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- A numerical approximation based on the Bessel functions of first kind for solutions of Riccati type differential-difference equations
- Numerical solutions of fractional Riccati type differential equations by means of the Bernstein polynomials
- A tutorial review on fractal spacetime and fractional calculus
- Solitons and other solutions to a new coupled nonlinear Schrödinger type equation
- A coupled nonlinear Schrödinger type equation and its explicit solutions
- Singularity analysis and explicit solutions of a new coupled nonlinear Schrödinger type equation
- Homogeneous balance method and chaotic and fractal solutions for the Nizhnik-Novikov-Veselov equation
- Variational principles for some nonlinear partial differential equations with variable coefficients
- Derivation of soliton solutions to nonlinear evolution equations using He's variational principle
- New soliton solutions of the generalized Zakharov equations using He's variational approach
- Time-space fabric underlying anomalous diffusion
- A collocation approach to solve the Riccati-type differential equation systems
- Numerical solution of the Bagley–Torvik equation by the Bessel collocation method
- Legendre Collocation Method to Solve the Riccati Equations with Functional Arguments
- MACLAURIN SERIES METHOD FOR FRACTAL DIFFERENTIAL-DIFFERENCE MODELS ARISING IN COUPLED NONLINEAR OPTICAL WAVEGUIDES
- FRACTAL LAKSHMANAN–PORSEZIAN–DANIEL MODEL WITH DIFFERENT FORMS OF NONLINEARITY AND ITS NOVEL SOLITON SOLUTIONS
- CAUCHY PROBLEMS WITH FRACTAL–FRACTIONAL OPERATORS AND APPLICATIONS TO GROUNDWATER DYNAMICS
- A modified perturbation method for mathematical models with randomness: An analysis through the steady‐state solution to Burgers' partial differential equation
