Saved in:
Bibliographic Details
Main Authors: Kumari, Shweta, Mehra, Mani
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.13542
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866916907931664384
author Kumari, Shweta
Mehra, Mani
author_facet Kumari, Shweta
Mehra, Mani
contents Standard finite difference (SFD) schemes often suffer from limited stability regions, especially when applied in explicit setup to partial differential equations. To address this challenge, this study investigates the efficacy of nonstandard finite difference (NSFD) schemes in enhancing stability of explicit SFD schemes for 1D and 2D Caputo-type time-fractional diffusion equations (TFDEs). A nonstandard L1approximation is proposed for the Caputo fractional derivative, and its local truncation error is derived analytically. This nonstandard L1 formulation is used to construct the NSFD scheme for a Caputo-type time-fractional initial value problem. The absolute stability of the resulting scheme is rigorously examined using the boundary locus method, and its performance is validated through numerical simulations on test examples for various choices of denominator functions. Based on this framework, two explicit NSFD schemes are developed for 1D and 2D cases of the Caputo-type TFDE. Their stability is further assessed through the discrete energy method, with particular focus on the expansion of stability region relative to SFD schemes. The convergence of the proposed NSFD schemes is also established. Finally, a comprehensive set of numerical experiments is conducted to demonstrate the accuracy and stability advantages of proposed methods, with results presented through tables and graphical illustrations.
format Preprint
id arxiv_https___arxiv_org_abs_2508_13542
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A stability-enhanced nonstandard finite difference framework for solving one and two-dimensional nonlocal differential equations
Kumari, Shweta
Mehra, Mani
Numerical Analysis
Standard finite difference (SFD) schemes often suffer from limited stability regions, especially when applied in explicit setup to partial differential equations. To address this challenge, this study investigates the efficacy of nonstandard finite difference (NSFD) schemes in enhancing stability of explicit SFD schemes for 1D and 2D Caputo-type time-fractional diffusion equations (TFDEs). A nonstandard L1approximation is proposed for the Caputo fractional derivative, and its local truncation error is derived analytically. This nonstandard L1 formulation is used to construct the NSFD scheme for a Caputo-type time-fractional initial value problem. The absolute stability of the resulting scheme is rigorously examined using the boundary locus method, and its performance is validated through numerical simulations on test examples for various choices of denominator functions. Based on this framework, two explicit NSFD schemes are developed for 1D and 2D cases of the Caputo-type TFDE. Their stability is further assessed through the discrete energy method, with particular focus on the expansion of stability region relative to SFD schemes. The convergence of the proposed NSFD schemes is also established. Finally, a comprehensive set of numerical experiments is conducted to demonstrate the accuracy and stability advantages of proposed methods, with results presented through tables and graphical illustrations.
title A stability-enhanced nonstandard finite difference framework for solving one and two-dimensional nonlocal differential equations
topic Numerical Analysis
url https://arxiv.org/abs/2508.13542