A finite difference method for fractional
diffusion equations with Neumann boundary
conditions

Szekeres, Béla J.; Izsák, Ferenc

doi:10.1515/math-2015-0056

Cited by 19 publications

(13 citation statements)

References 35 publications

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“…Remark: We still think that non-local analysis in [20] is a proper tool for modeling anomalous diffusion but the zero extension in (8) does not correspond to the Dirichlet boundary conditions. Instead, in the one-dimensional case, one should apply the extension in [5].…”

Section: Resultsmentioning

confidence: 99%

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Models of space-fractional diffusion: A critical review

Izsák

Szekeres

2017

Applied Mathematics Letters

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Space-fractional diffusion problems are investigated from the modeling point of view. It is pointed out that the elementwise power of the Laplacian operator in R n is an inadequate model of fractional diffusion. Also, the approach with fractional calculus using zero extension is not a proper model of homogeneous Dirichlet boundary conditions. At the time, the spectral definition of the fractional Dirichlet Laplacian seems to be in many aspects a proper model of fractional diffusion.

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Section: Resultsmentioning

confidence: 99%

“…In many real situations, one should use Neumann boundary conditions in the models. A corresponding analysis can be found in [4] and [5].…”

Section: Introductionmentioning

confidence: 96%

Models of space-fractional diffusion: A critical review

Izsák

Szekeres

2017

Applied Mathematics Letters

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“…Ha például zárt térben (kémcső, lombik, tartály) végbemenő anyagtranszportot modellezünk, akkor annak határán mindig homogén Neumannféle peremfeltételt kell vennünk. Az egydimenziós esetben sikerült a homogén feltételt a modellbe beépíteni [13]…”

Section: További Kérdések Nyitott Problémákunclassified

Törtrendű diffúzió modelljei és szimulációja

Izsák¹,

Szekeres²

2019

AML

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“…The favor of this approach is not only that we can deal with complex domains but also that in the corresponding bilinear forms the homogeneous boundary conditions can be included in a natural way. The choice of an appropriate boundary condition -which corresponds to the real-life phenomenon to simulate and leads to a well-posed problem -is not obvious [20], [21] due to the non-local nature [9] of the fractional Laplacian.…”

Section: Introductionmentioning

confidence: 99%

Finite element approximation of fractional order elliptic boundary value problems

Szekeres

Izsák

2016

Journal of Computational and Applied Mathematics

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A finite element numerical method is investigated for fractional order elliptic boundary value problems with homogeneous Dirichlet type boundary conditions. It is pointed out that an appropriate stiffness matrix can be obtained by taking the prescribed fractional power of the stiffness matrix corresponding to the non-fractional elliptic operators.It is proved that this approach, which is also called the matrix transformation or matrix transfer method, delivers optimal rate of convergence in the L 2 -norm.

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A finite difference method for fractional diffusion equations with Neumann boundary conditions

Cited by 19 publications

References 35 publications

Models of space-fractional diffusion: A critical review

Models of space-fractional diffusion: A critical review

Törtrendű diffúzió modelljei és szimulációja

Finite element approximation of fractional order elliptic boundary value problems

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