A High-Order Method of Lines with SSPRK54 Time Integration for the One-Dimensional Nonlinear Fisher Equation: Accuracy, Stability, and Benchmarking

Mohammad Khalid  Storai; Gul Agha Jan  Assar

doi:10.61231/nkww1e18

Authors

Mohammad Khalid Storai Department of Applied Mathematics, Faculty of Mathematics, Kabul University, Afghanistan
Gul Agha Jan Assar Department of Applied Mathematics, Faculty of Mathematics, Kabul University, Afghanistan

DOI:

https://doi.org/10.61231/nkww1e18

Keywords:

Fisher Equation, Reaction–Diffusion, Method of lines, SSP Runge–Kutta, SSP RK54, Traveling Wave, Numerical Stability, Convergence Analysis

Abstract

We present a rigorously documented, reproducible, and benchmarked high‑order numerical framework for the one‑dimensional nonlinear Fisher (Fisher–KPP) equation. The method combines second‑order central finite differences for spatial discretization within the method‑of‑lines (MOL) framework and a five‑stage, fourth‑order strong stability‑preserving Runge–Kutta integrator (SSP‑RK54) for time integration. The resulting semi‑discrete system is advanced with an explicit SSP integrator whose coefficients are given in full; we provide the Butcher tableau, algorithmic pseudocode, and practical guidance for CFL selection. We verify the method on two canonical traveling‑wave test problems with known closed‑form solutions, perform systematic spatial and temporal convergence studies, and compare cost‑normalized accuracy against representative published methods. A detailed truncation‑error derivation, Von Neumann linear stability analysis, and nonlinear positivity discussion are included. Numerical experiments demonstrate fourth‑order temporal convergence and second‑order spatial convergence, with error levels consistent with the theoretical O(Δt⁴+h²) behavior. We provide reproducibility materials, implementation notes for MATLAB, and recommendations for extensions to stiff regimes, IMEX variants, and multi‑dimensional problems

References

Aronson, D.G. and Weinberger, H.F. (1978). Multidimensional nonlinear diffusion arising in population genetics. Advances in Mathematics, Vol. 30, pp. 33-76.

Ben-Jacob, E., Brand, H., Dee, G., Moore, L., and Levine, H. (1985). Pattern propagation in nonlinear dissipative systems. Physica D, Vol. 14, pp. 348-364.

Byrne, H.M. (1997). Modelling avascular tumour growth. In: Horn, M.A. et al. (eds) Mathematical Models in Medical and Health Science. Nashboro Press, Nashville, pp. 99-130.

Fife, P.C. and McLeod, J.B. (1977). The approach of solutions of nonlinear diffusion equations to travelling front solutions. Archive for Rational Mechanics and Analysis, Vol. 65, pp. 335-361.

Fisher, R.A. (1937). The wave of advancement of advantageous genes. Annals of Eugenics, Vol. 7, pp. 355-369.

Gottlieb, S., Shu, C.W., and Tadmor, E. (2001). Strong stability-preserving high-order time discretization methods. SIAM Review, Vol. 43, pp. 89-112.

Grindrod, P. (1996). The Theory and Applications of Reaction-Diffusion Equations. Oxford University Press, Oxford.

Hundsdorfer, W. and Verwer, J.G. (2003). Numerical Solution of Time-Dependent Advection-Diffusion-Reaction Equations. Springer, Berlin.

Hussen, I. and Mebrate, B. (2022). Semi-implicit scheme of the Fisher equation based on the Crank-Nicolson method. Palestine Journal of Mathematics, Vol. 11, No. 3.

Khruslov, E.Y. and Pismen, L.M. (1990). Front motion in the bistable reaction-diffusion system. Physica D, Vol. 43, pp. 335-344.

Kolmogorov, A.N., Petrovsky, I.G., and Piskunov, N.S. (1937). Étude de l'équation de la diffusion avec croissance de la quantité de matière. Moscow University Bulletin, Vol. 1, pp. 1-25.

Mittal, R.C. and Jiwari, R. (2009). Numerical study of Fisher's equation by using the differential quadrature method. International Journal of Systems Science, Vol. 5, pp. 143-160.

Mollison, D. (1977). Spatial contact models for ecological and epidemic spread. Journal of the Royal Statistical Society, Series B, Vol. 39, pp. 283-326.

Murray, J.D. (2002). Mathematical Biology I: An Introduction. Springer, New York.

Quarteroni, A. and Valli, A. (1994). Numerical Approximation of Partial Differential Equations. Springer, Berlin.

Rothe, E. (1930). Zweidimensionale parabolische Randwertaufgaben als Grenzfall eindimensionaler Randwertaufgaben. Mathematische Annalen, Vol. 102, pp. 650-670.

Rvachev, V.A. and Longini, I.M. (1985). A mathematical model for the global spread of influenza. Mathematical Biosciences, Vol. 75, pp. 3-22.

Schiesser, W.E. (1991). The Numerical Method of Lines. Academic Press, San Diego.

Sherratt, J.A. and Chaplain, M.A.J. (2001). On the classification of plausible nutrient transport mechanisms for malignant tumour growth. Mathematical and Computer Modelling, Vol. 33, pp. 657-669.

Shigesada, N. and Kawasaki, K. (1997). Biological Invasions: Theory and Practice. Oxford University Press, Oxford.

Shu, C.W. (1988). Total-variation-diminishing time discretizations. SIAM Journal on Scientific and Statistical Computing, Vol. 9, pp. 1073-1084.

Shu, C.W. (2009). High-order weighted essentially nonoscillatory schemes for convection-dominated problems. SIAM Review, Vol. 51, pp. 82-126.

Spiteri, R.J. and Ruuth, S.J. (2002). A new class of optimal high-order strong-stability-preserving time discretization methods. SIAM Journal on Numerical Analysis, Vol. 40, pp. 469-491.

Strikwerda, J.C. (2004). Finite Difference Schemes and Partial Differential Equations. SIAM, Philadelphia.

Vimal, V., Kumari, R., and Sinha, R.K. (2024b). Higher-order numerical technique based on a strong stability preserving method for solving the nonlinear Fisher equation. Communications in Mathematics and Applications, Vol. 15, No. 3, pp. 997-1010.

Vimal, V., Sinha, R.K., and Pannikkal, L. (2024c). Numerical methods for solving the nonlinear Fisher equation using the backward differentiation formula. Applications and Applied Mathematics, Vol. 19, Iss. 4, Article 4.

Vimal, V., Sinha, R.K., and Liju, P. (2024d). An unconditionally stable numerical scheme for solving the nonlinear Fisher equation. Nonlinear Engineering, Vol. 13, No. 1, pp. 20240006.