The paper discusses new cubature formulas for the Riesz potential and the fractional Laplacian (Formula presented.), (Formula presented.), in the framework of the method approximate approximations. This approach, combined with separated representations, makes the method successful also in high dimensions. We prove error estimates and report on numerical results illustrating that our formulas are accurate and provide the predicted convergence rate 2, 4, 6, 8 up to dimension (Formula presented.). © 2021 Informa UK Limited, trading as Taylor & Francis Group
Ordinary differential equations (ODEs) with fractional order derivatives are infinite dimensional sy...
Abstract. We study the extremal solution for the problem (−∆)su = λf(u) in Ω, u ≡ 0 in Rn \ Ω, where...
This paper presents an algorithmic approach for numerically solving Caputo fractional differentiation...
In this paper, we propose accurate and efficient finite difference methods to discretize the two- an...
We present a survey of fractional differential equations and in particular of the computational cost...
In Chapter 1, we gave a partial contribution to the Mainardi's conjecture, concerning only small int...
We report here on some recent results obtained in collaboration with V. Maz'ya and G. Schmidt cite{L...
In this work, we extend the fractional linear multistep methods in [C. Lubich, SIAM J. Math. Anal., ...
Fractional calculus is the generalization of integer-order calculus to rational order. This subject ...
This paper starts by introducing the Grünwald–Letnikov derivative, the Riesz potential and the probl...
This article is not available through ChesterRep.This article discusses the development of efficient...
The fractional Laplacian has been strongly studied during past decades. In this paper we present a d...
This paper deals with some numerical issues about the rational approximation to fractional different...
This paper deals with some numerical issues about the rational approximation to fractional different...
We propose a rational preconditioner for an efficient numerical solution of linear systems arising f...
Ordinary differential equations (ODEs) with fractional order derivatives are infinite dimensional sy...
Abstract. We study the extremal solution for the problem (−∆)su = λf(u) in Ω, u ≡ 0 in Rn \ Ω, where...
This paper presents an algorithmic approach for numerically solving Caputo fractional differentiation...
In this paper, we propose accurate and efficient finite difference methods to discretize the two- an...
We present a survey of fractional differential equations and in particular of the computational cost...
In Chapter 1, we gave a partial contribution to the Mainardi's conjecture, concerning only small int...
We report here on some recent results obtained in collaboration with V. Maz'ya and G. Schmidt cite{L...
In this work, we extend the fractional linear multistep methods in [C. Lubich, SIAM J. Math. Anal., ...
Fractional calculus is the generalization of integer-order calculus to rational order. This subject ...
This paper starts by introducing the Grünwald–Letnikov derivative, the Riesz potential and the probl...
This article is not available through ChesterRep.This article discusses the development of efficient...
The fractional Laplacian has been strongly studied during past decades. In this paper we present a d...
This paper deals with some numerical issues about the rational approximation to fractional different...
This paper deals with some numerical issues about the rational approximation to fractional different...
We propose a rational preconditioner for an efficient numerical solution of linear systems arising f...
Ordinary differential equations (ODEs) with fractional order derivatives are infinite dimensional sy...
Abstract. We study the extremal solution for the problem (−∆)su = λf(u) in Ω, u ≡ 0 in Rn \ Ω, where...
This paper presents an algorithmic approach for numerically solving Caputo fractional differentiation...