Lucas Polynomial Approach for Second Order Nonlinear Differential Equations

Gümgüm, Sevin; Baykuş-Savaşaneril, Nurcan; Kürkçü, Ömür Kıvanç; Sezer, Mehmet

doi:10.19113/sdufenbed.546847

Cited by 6 publications

(1 citation statement)

References 28 publications

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“…In recent years, the papers including various methods such as variational iteration method, [6][7][8][9][10] homotopy perturbation method, 11,12 Adomian decomposition method, [13][14][15] Lucas polynomial method, 16 Taylor matrix and collocation method, 17 Bessel function method, 18,19 Keller-Segel method, 20,21 Mathieu-Duffing system 22 and Bayesian network [23][24][25] have been published for solving the Riccati differential equations.…”

Section: Introductionmentioning

confidence: 99%

Shifted Legendre method for solutions of Riccati type functional differential equations and application of RL circuit model

Elmacı,

Yüzbaşı,

Baykuş Savaşaneril

2023

Int J Numerical Modelling

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In order to solve the Riccati type functional differential equations under mixed condition, this research suggests a collocation approach based on shifted Legendre polynomials. These equations are seen in physics and electronic sciences. By means of the evenly spaced collocation points, the shifted Legendre polynomials, their derivatives and matrix forms, the method is constructed. It reduces the problem into a system nonlinear algebraic equations. Error analysis is made. The method is applied to numerical examples and their results are compared with other methods from literature. And also, the method is applied to nonlinear RL electrical circuit model. The results show that the method is effective.

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Section: Introductionmentioning

confidence: 99%

Shifted Legendre method for solutions of Riccati type functional differential equations and application of RL circuit model

Elmacı,

Yüzbaşı,

Baykuş Savaşaneril

2023

Int J Numerical Modelling

Self Cite

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Pell–Lucas series approach for a class of Fredholm-type delay integro-differential equations with variable delays

et al. 2021

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Numerical solutions of Troesch and Duffing equations by Taylor wavelets

Özaltun

Gümgüm

2023

Hacettepe Journal of Mathematics and Statistics

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The aim of this study is obtain accurate numerical results for the Troesch and Duffing equations by using Taylor wavelets. Orthonormality property of these polynomials is an advantage of the method since it reduces the computational cost. These equations are known to be stiff equations, thus most of the numerical methods approximates the nonlinear terms and the force function while wavelets do not require such an approximation which is another advantage of the method. Troesch and Duffing equations are solved for several parameters to show the accuracy and efficiency of the applied method. Results show that the proposed method is highly efficient in the solution of indicated type of problems by using quite low degree polynomials.

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Lucas Polynomial Approach for Second Order Nonlinear Differential Equations

Cited by 6 publications

References 28 publications

Shifted Legendre method for solutions of Riccati type functional differential equations and application of RL circuit model

Shifted Legendre method for solutions of Riccati type functional differential equations and application of RL circuit model

Pell–Lucas series approach for a class of Fredholm-type delay integro-differential equations with variable delays

Numerical solutions of Troesch and Duffing equations by Taylor wavelets

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