Litcius/Paper detail

A fast computational technique to solve fourth-order parabolic equations: application to good Boussinesq, Euler-Bernoulli and Benjamin-Ono equations

Sachin Sharma, Naina Sharma

2024International Journal of Computer Mathematics12 citationsDOI

Abstract

In this article, we introduce a novel cubic spline method for the numerical solution of a class of fourth-order time-dependent parabolic partial differential equations. The method employs uniform mesh discretization, achieving a spatial accuracy of four and a temporal accuracy of two. Here, the key contribution is that this method can be directly applied to singular parabolic problems due to the consideration of half-step points in spatial direction. The model linear fourth-order partial differential equation is used to discuss the method's stability. The method we propose has multiple advantages, including high accuracy and seamless point-to-point interpolation capabilities. It is a versatile technique that can easily adapt to solve various nonlinear problems without the need to change or linearize the nonlinear terms to produce numerical solutions. Benchmark linear and nonlinear problems like single and double-soliton of the good Boussinesq equation, the Euler-Bernoulli beam model and the Benjamin-Ono equation, are solved.

Topics & Concepts

Bernoulli's principleMathematicsEuler equationsEuler's formulaBackward Euler methodApplied mathematicsMathematical analysisBoussinesq approximation (buoyancy)MechanicsPhysicsHeat transferNatural convectionThermodynamicsRayleigh numberNonlinear Waves and SolitonsDifferential Equations and Numerical MethodsFractional Differential Equations Solutions