The Bramson delay in a Fisher–KPP equation with log-singular nonlinearity

This paper proposes a numerical approach to the solution of the Fisher-KPP reaction-diffusion equation in which the space variable is developed using a purely finite difference scheme and the time development is obtained using a hybrid Laplace Transform Finite Difference Method (LTFDM). The travelling wave solutions usually associated with the Fisher-KPP equation are, in general, not deemed suitable for treatment using Fourier or Laplace transform numerical methods. However, we were able to obtain accurate results when some degree of time discretisation is inbuilt into the process. While this means that the advantage of using the Laplace transform to obtain solutions for any time t is not fully exploited, the method does allow for considerably larger time steps than is otherwise possible for finite-difference methods.

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A quantitative theory of vegetation patterns based on plant structure and the non-local F–KPP equation

Comptes Rendus Mécanique ◽

10.1016/j.crme.2012.10.030 ◽

2012 ◽

Vol 340 (11-12) ◽

pp. 818-828 ◽

Cited By ~ 15

Author(s):

René Lefever ◽

John W. Turner

Keyword(s):

Vegetation Patterns ◽

Plant Structure ◽

Kpp Equation ◽

Quantitative Theory ◽

Non Local

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Positive solutions for nonlinear Choquard equation with singular nonlinearity

Complex Variables and Elliptic Equations ◽

10.1080/17476933.2016.1260559 ◽

2017 ◽

Vol 62 (8) ◽

pp. 1044-1071 ◽

Cited By ~ 9

Author(s):

Tuhina Mukherjee ◽

K. Sreenadh

Keyword(s):

Positive Solutions ◽

Choquard Equation ◽

Singular Nonlinearity ◽

Nonlinear Choquard Equation

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Estimating the extent of glioblastoma invasion

Journal of Mathematical Biology ◽

10.1007/s00285-021-01563-9 ◽

2021 ◽

Vol 82 (1-2) ◽

Author(s):

Christian Engwer ◽

Michael Wenske

Keyword(s):

Analytic Solution ◽

Glioma Cells ◽

Diffusion Reaction ◽

Kpp Equation ◽

Advection Diffusion ◽

Clinical Interest ◽

Inhomogeneous Diffusion ◽

Reaction Equations ◽

Advection Diffusion Reaction Equations ◽

Tumor Extent

AbstractGlioblastoma Multiforme is a malignant brain tumor with poor prognosis. There have been numerous attempts to model the invasion of tumorous glioma cells via partial differential equations in the form of advection–diffusion–reaction equations. The patient-wise parametrization of these models, and their validation via experimental data has been found to be difficult, as time sequence measurements are mostly missing. Also the clinical interest lies in the actual (invisible) tumor extent for a particular MRI/DTI scan and not in a predictive estimate. Therefore we propose a stationalized approach to estimate the extent of glioblastoma (GBM) invasion at the time of a given MRI/DTI scan. The underlying dynamics can be derived from an instationary GBM model, falling into the wide class of advection-diffusion-reaction equations. The stationalization is introduced via an analytic solution of the Fisher-KPP equation, the simplest model in the considered model class. We investigate the applicability in 1D and 2D, in the presence of inhomogeneous diffusion coefficients and on a real 3D DTI-dataset.

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