Numerical analysis of time fractional Black–Scholes European option pricing model arising in financial market

Golbabai, A.; Nikan, O.; Nikazad, Touraj

doi:10.1007/s40314-019-0957-7

Cited by 79 publications

(46 citation statements)

References 59 publications

(50 reference statements)

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“…FC has many applications in the branch of science and engineering Communicated by Agnieszka Malinowska. B H. Safdari such as optimal control, physics, economics, chemistry, polymeric materials, and social science (Golbabai and Nikan 2019;Golbabai et al 2019a;Henry and Wearne 2002;Metzler and Klafter 2000;Reyes-Melo et al 2005).…”

Section: Introductionmentioning

confidence: 99%

Convergence analysis of the space fractional-order diffusion equation based on the compact finite difference scheme

et al. 2020

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This paper develops a numerical method for approximating the space fractional diffusion equation in Caputo derivative sense. In this discretization process, firstly, the compact finite difference with convergence order O(δτ 2) is used to obtain the semi-discrete in time derivative. Afterward, the spatial fractional derivative is discretized by using the Chebyshev collocation method of the third-kind. This collocation scheme is based on the operational matrix. In addition, time-discrete stability and convergence are theoretically proved in detail. We solve two examples by the proposed method and the obtained results are compared with other numerical methods. The numerical results show that our method is much more accurate than existing methods.

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Section: Introductionmentioning

confidence: 99%

Convergence analysis of the space fractional-order diffusion equation based on the compact finite difference scheme

et al. 2020

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“…In the last few years, several procedures have been used for solving FDEs such as finite differences, finite elements (Atangana 2015;Chen et al 2008;Sweilam et al 2011;Deng 2008;Zhao and Li 2012) and spectral methods (Safdari et al 2020;Bhrawy et al , 2016bBhrawy et al , a, 2017Bhrawy and Zaky 2015;Borhanifar and Sadri 2014;Golbabai et al 2019). Spectral methods are global methods and one of the efficient procedures to solve FDEs.…”

Section: Introductionmentioning

confidence: 99%

A tau method based on Jacobi operational matrix for solving fractional telegraph equation with Riesz-space derivative

et al. 2020

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In this paper, we have presented an accurate and impressive spectral algorithm for solving fractional telegraph equation with Riesz-space derivative and Dirichlet boundary conditions. The proposed method is based on Jacobi tau spectral procedure together with the Jacobi operational matrices of Riemann-Liouville fractional integral and left-and right-sided Caputo fractional derivatives. Primarily, we implement the proposed algorithm in both temporal and spatial discretizations. This algorithm reduces the problem to a system of algebraic equations which considerably simplifies the problem. In addition, an error bound is established in the L ∞-norm for the suggested spectral Jacobi tau method. Illustrative examples are included to demonstrate the validity and accuracy of the presented technique.

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“…Most fractional differential equations do not have exact analytical solutions, so for tackling such approximation and numerical schemes must be applied. There are many researchers which have been interested to develop novel numerical methods for fractional partial differential equations (Ren and Wang 2017;Xing and Yan 2018;Zhang and Yang 2018;Sakar et al 2018;Mirzaee and Samadyar 2018) such as explicit finite difference (Shen et al 2011;Sousa 2012;Zhang and Yang 2018;Costa and Pereira 2018), implicit finite difference (Burrage et al 2012;Karatay et al 2011;Sunarto et al 2014), compact finite difference (Cui 2012;Wang and Ren 2019;Wang 2015), finite element (Ford et al 2011;Jiang and Ma 2011;Li and Yang 2017), spline (Arshed 2017;Siddiqi and Arshed 2015;Qiao and Xu 2018), Fourier analysis (Li et al 2018), radial basis functions (Golbabai et al 2019;Ahmadi et al 2017;Dehghan et al 2016;Hosseini et al 2016;Ghehsareh et al 2018), wavelets (Heydari et al 2015;Kargar and Saeedi 2017;Soltani Sarvestani et al 2019), sinc radial basis function (Permoon et al 2016), local radial basis function-generated finite difference (Nikan et al 2020b;Nikan et al 2020a) and spectral methods (Rashidinia and Mohmedi 2018;Yang et al 2018;Zaky 2018a, b;Aghdam et al 2020)…”

Section: Introductionmentioning

confidence: 99%

Approximate solution of the multi-term time fractional diffusion and diffusion-wave equations

Rashidinia

Mohmedi

2020

Comp. Appl. Math.

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We develop a numerical scheme for finding the approximate solution for one-and twodimensional multi-term time fractional diffusion and diffusion-wave equations considering smooth and nonsmooth solutions. The concept of multi-term time fractional derivatives is conventionally defined in the Caputo view point. In the current research, the convergence analysis of Legendre collocation spectral method was carried out. Spectral collocation method is consequently tested on several benchmark examples, to verify the accuracy and to confirm effectiveness of proposed method. The main advantage of the method is that only a small number of shifted Legendre polynomials are required to obtain accurate and efficient results. The numerical results are provided to demonstrate the reliability of our method and also to compare with other previously reported methods in the literature survey.

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Numerical analysis of time fractional Black–Scholes European option pricing model arising in financial market

Cited by 79 publications

References 59 publications

Convergence analysis of the space fractional-order diffusion equation based on the compact finite difference scheme

Convergence analysis of the space fractional-order diffusion equation based on the compact finite difference scheme

A tau method based on Jacobi operational matrix for solving fractional telegraph equation with Riesz-space derivative

Approximate solution of the multi-term time fractional diffusion and diffusion-wave equations

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