Numerical methods for fractional differential equations

Fractional differential equations have received much attention in recent decades likely due to its powerful ability in modeling `memory' processes, which are mostly observed in real world. Fractional models have been widely investigated and applied in many fields such as physics, biochemistry,...

Full description

Saved in:
Bibliographic Details
Main Author: Li, Xuhao
Other Authors: Wong Jia Yiing, Patricia
Format: Theses and Dissertations
Language:English
Published: 2018
Subjects:
Online Access:https://hdl.handle.net/10356/85055
http://hdl.handle.net/10220/46678
Tags: Add Tag
No Tags, Be the first to tag this record!
Institution: Nanyang Technological University
Language: English
id sg-ntu-dr.10356-85055
record_format dspace
spelling sg-ntu-dr.10356-850552023-07-04T16:26:30Z Numerical methods for fractional differential equations Li, Xuhao Wong Jia Yiing, Patricia School of Electrical and Electronic Engineering DRNTU::Science::Mathematics::Applied mathematics::Numerical analysis DRNTU::Engineering::Mathematics and analysis::Simulations Fractional differential equations have received much attention in recent decades likely due to its powerful ability in modeling `memory' processes, which are mostly observed in real world. Fractional models have been widely investigated and applied in many fields such as physics, biochemistry, electrical engineering, continuum and statistical mechanics. It is shown by many researchers that fractional derivatives can provide more accurate models than integer order derivatives do. However, for most models involving fractional operators, it is very challenging if not impossible to get analytical solutions. This motivates us to propose numerical techniques, especially those that can obtain numerical approximations both efficiently and effectively. In this thesis, we aim to construct high order accuracy numerical scheme for two categories: (i) four classes of typical fractional problems, and (ii) some classes of generalized fractional problems. In tackling the first category, we focus on the improvement of the theoretical spatial convergence order mainly using {\it parametric quintic spline}. The parametric spline method has been used in previous work and has been numerically shown to get satisfying performance. Unfortunately, no strict theoretical result is established and we note that the analysis is not trivial. Due to this reason, we are greatly motivated to further investigate this method and provide strict analysis which is extremely important for a numerical method. Our contributions for topics in the first category mainly lies in two aspects: 1) we develop new numerical methods for fractional problems that improve the spatial convergence order achieved so far in the literature; 2) we establish the solvability, stability and convergence results of the proposed methods that are not given in previous work relating to parametric spline method. The other category is about numerical treatment on some classes of generalized fractional problems. As the name suggests, the generalized fractional problems include typical fractional problems as special cases and may represent even more: both existing and potential new cases. In fact, it is shown that many integral equations can be solved in a much elegant way using generalized fractional operators and it can somehow blur the distinction between the differential and integral equations. For this topic, the numerical investigations are very scarce and the temporal convergence order of the existing work is not so satisfying and may not meet the demand in reality. Motivated by these two observations, we shall construct some new approximations of generalized fractional derivatives through generalizations of some typical techniques, e.g. $L2-1_\sigma$ method and weighted shifted Gr\"unwald-Letnikov method to improve the temporal convergence order. This will help to solve this kind of problems more efficiently and effectively. Doctor of Philosophy 2018-11-21T14:36:18Z 2019-12-06T15:56:19Z 2018-11-21T14:36:18Z 2019-12-06T15:56:19Z 2018 Thesis Li, X. (2018). Numerical methods for fractional differential equations. Doctoral thesis, Nanyang Technological University, Singapore. https://hdl.handle.net/10356/85055 http://hdl.handle.net/10220/46678 10.32657/10220/46678 en 236 p. application/pdf
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic DRNTU::Science::Mathematics::Applied mathematics::Numerical analysis
DRNTU::Engineering::Mathematics and analysis::Simulations
spellingShingle DRNTU::Science::Mathematics::Applied mathematics::Numerical analysis
DRNTU::Engineering::Mathematics and analysis::Simulations
Li, Xuhao
Numerical methods for fractional differential equations
description Fractional differential equations have received much attention in recent decades likely due to its powerful ability in modeling `memory' processes, which are mostly observed in real world. Fractional models have been widely investigated and applied in many fields such as physics, biochemistry, electrical engineering, continuum and statistical mechanics. It is shown by many researchers that fractional derivatives can provide more accurate models than integer order derivatives do. However, for most models involving fractional operators, it is very challenging if not impossible to get analytical solutions. This motivates us to propose numerical techniques, especially those that can obtain numerical approximations both efficiently and effectively. In this thesis, we aim to construct high order accuracy numerical scheme for two categories: (i) four classes of typical fractional problems, and (ii) some classes of generalized fractional problems. In tackling the first category, we focus on the improvement of the theoretical spatial convergence order mainly using {\it parametric quintic spline}. The parametric spline method has been used in previous work and has been numerically shown to get satisfying performance. Unfortunately, no strict theoretical result is established and we note that the analysis is not trivial. Due to this reason, we are greatly motivated to further investigate this method and provide strict analysis which is extremely important for a numerical method. Our contributions for topics in the first category mainly lies in two aspects: 1) we develop new numerical methods for fractional problems that improve the spatial convergence order achieved so far in the literature; 2) we establish the solvability, stability and convergence results of the proposed methods that are not given in previous work relating to parametric spline method. The other category is about numerical treatment on some classes of generalized fractional problems. As the name suggests, the generalized fractional problems include typical fractional problems as special cases and may represent even more: both existing and potential new cases. In fact, it is shown that many integral equations can be solved in a much elegant way using generalized fractional operators and it can somehow blur the distinction between the differential and integral equations. For this topic, the numerical investigations are very scarce and the temporal convergence order of the existing work is not so satisfying and may not meet the demand in reality. Motivated by these two observations, we shall construct some new approximations of generalized fractional derivatives through generalizations of some typical techniques, e.g. $L2-1_\sigma$ method and weighted shifted Gr\"unwald-Letnikov method to improve the temporal convergence order. This will help to solve this kind of problems more efficiently and effectively.
author2 Wong Jia Yiing, Patricia
author_facet Wong Jia Yiing, Patricia
Li, Xuhao
format Theses and Dissertations
author Li, Xuhao
author_sort Li, Xuhao
title Numerical methods for fractional differential equations
title_short Numerical methods for fractional differential equations
title_full Numerical methods for fractional differential equations
title_fullStr Numerical methods for fractional differential equations
title_full_unstemmed Numerical methods for fractional differential equations
title_sort numerical methods for fractional differential equations
publishDate 2018
url https://hdl.handle.net/10356/85055
http://hdl.handle.net/10220/46678
_version_ 1772827474584928256