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1	On the design and implementation of a hybrid numerical method for singularly perturbed two-point boundary value problems Nyamayaro, Takura T. A. January 2014 (has links) >Magister Scientiae - MSc / With the development of technology seen in the last few decades, numerous solvers have been developed to provide adequate solutions to the problems that model different aspects of science and engineering. Quite often, these solvers are tailor-made for specific classes of problems. Therefore, more of such must be developed to accompany the growing need for mathematical models that help in the understanding of the contemporary world. This thesis treats two point boundary value singularly perturbed problems. The solution to this type of problem undergoes steep changes in narrow regions (called boundary or internal layer regions) thus rendering the classical numerical procedures inappropriate. To this end, robust numerical methods such as finite difference methods, in particular fitted mesh and fitted operator methods have extensively been used. While the former consists of transforming the continuous problem into a discrete one on a non-uniform mesh, the latter involves a special discretisation of the problem on a uniform mesh and are known to be more accurate. Both classes of methods are suitably designed to accommodate the rapid change(s) in the solution. Quite often, finite difference methods on piece-wise uniform meshes (of Shishkin-type) are adopted. However, methods based on such non-uniform meshes, though layer-resolving, are not easily extendable to higher dimensions. This work aims at investigating the possibility of capitalising on the advantages of both fitted mesh and fitted operator methods. Theoretical results are confirmed by extensive numerical simulations. Singular perturbation problems Higher order numerical methods Convergence Analysis
2	Higher Order Numerical Methods for Singular Perturbation Problems. Munyakazi, Justin Bazimaziki. January 2009 (has links) <p>In recent years, there has been a great interest towards the higher order numerical methods for singularly perturbed problems. As compared to their lower order counterparts, they provide better accuracy with fewer mesh points. Construction and/or implementation of direct higher order methods is usually very complicated. Thus a natural choice is to use some convergence acceleration techniques, e.g., Richardson extrapolation, defect correction, etc. In this thesis, we will consider various classes of problems described by singularly perturbed ordinary and partial differential equations. For these problems, we design some novel numerical methods and attempt to increase their accuracy as well as the order of convergence. We also do the same for existing numerical methods in some instances. We &macr / nd that, even though the Richardson extrapolation technique always improves the accuracy, it does not perform equally well when applied to different methods for certain classes of problems. Moreover, while in some cases it improves the order of convergence, in other cases it does not. These issues are discussed in this thesis for linear and nonlinear singularly perturbed ODEs as well as PDEs. Extrapolation techniques are analyzed thoroughly in all the cases, whereas the limitations of the defect correction approach for certain problems is indicated at the end of the thesis</p> Singular perturbation problems Fitted finite difference methods Higher order numerical methods Richardson extrapolation Self-adjoint problems Turning point problems Parabolic problems Elliptic problems Maximum and minimum principles Convergence analysis.
3	Higher Order Numerical Methods for Singular Perturbation Problems. Munyakazi, Justin Bazimaziki. January 2009 (has links) <p>In recent years, there has been a great interest towards the higher order numerical methods for singularly perturbed problems. As compared to their lower order counterparts, they provide better accuracy with fewer mesh points. Construction and/or implementation of direct higher order methods is usually very complicated. Thus a natural choice is to use some convergence acceleration techniques, e.g., Richardson extrapolation, defect correction, etc. In this thesis, we will consider various classes of problems described by singularly perturbed ordinary and partial differential equations. For these problems, we design some novel numerical methods and attempt to increase their accuracy as well as the order of convergence. We also do the same for existing numerical methods in some instances. We &macr / nd that, even though the Richardson extrapolation technique always improves the accuracy, it does not perform equally well when applied to different methods for certain classes of problems. Moreover, while in some cases it improves the order of convergence, in other cases it does not. These issues are discussed in this thesis for linear and nonlinear singularly perturbed ODEs as well as PDEs. Extrapolation techniques are analyzed thoroughly in all the cases, whereas the limitations of the defect correction approach for certain problems is indicated at the end of the thesis</p> Singular perturbation problems Fitted finite difference methods Higher order numerical methods Richardson extrapolation Self-adjoint problems Turning point problems Parabolic problems Elliptic problems Maximum and minimum principles Convergence analysis.
4	Equações com impasse e problemas de perturbação singular / Cardin, Pedro Toniol. January 2011 (has links) Orientador: Paulo Ricardo da Silva / Banca: João Carlos da Rocha Medrado / Banca: Fernando de Osório Mello / Banca: Claudio Aguinaldo Buzzi / Banca: Vanderlei Minori Horita / Resumo: Neste trabalho estudamos sistemas diferenciais forçados, também conhecidos como sistemas de equações com impasse. Estudamos os casos onde tais sistemas são suaves e os casos onde são possivelmente descontínuos. Usando técnicas de perturbação singular obtemos alguns resultados sobre a dinâmica destes sistemas em vizinhanças dos conjuntos de impasse. No caso suave, a Teoria de Fenichel clássica e crucial para o desenvolvimento dos principais resultados. Para o caso com descontinuidades, uma teoria similar a Teoria de Fenichel 'e desenvolvida. Além disso, estudamos a bifurcação de ciclos limites das órbitas periódicas de um centro diferencial linear quando perturbamos tal centro dentro de uma classe de sistemas diferenciais lineares por partes com impasse / Abstract: In this work we study constrained diﬀerential systems, also known as systems of equations with impasse. We study the cases where such systems are smo oth and the cases where they are p ossibly discontinuous. Using singular p erturbation techniques we obtain some results on the dynamic of these systems in neighb orho o ds of the impasse sets. In smo oth case, the classical Fenichel's Theory is crucial for the development of the main results. For the case with discontinuity, a similar theory to Fenichel's Theory is develop ed. Moreover, we study the bifurcation of limit cycles from the p erio dic orbits of a linear diﬀerential center when we p erturb such center inside a class of piecewise linear diﬀerential systems with impasse / Doutor Sistemas dinâmicos diferenciais. Equações diferenciais ordinárias. Campos vetoriais. Perturbação singular (Matematica) Constrained systems. eng Singular perturbation problems. eng Impasse set. eng Discontinuous vector ﬁelds. eng Averaging method. eng
5	Equações com impasse e problemas de perturbação singular Cardin, Pedro Toniol [UNESP] 18 March 2011 (has links) (PDF) Made available in DSpace on 2014-06-11T19:32:50Z (GMT). No. of bitstreams: 0 Previous issue date: 2011-03-18Bitstream added on 2014-06-13T18:07:15Z : No. of bitstreams: 1 cardin_pt_dr_sjrp.pdf: 479456 bytes, checksum: 52785d20631e0d11a14a241fde1ae7c9 (MD5) / Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) / Neste trabalho estudamos sistemas diferenciais forçados, também conhecidos como sistemas de equações com impasse. Estudamos os casos onde tais sistemas são suaves e os casos onde são possivelmente descontínuos. Usando técnicas de perturbação singular obtemos alguns resultados sobre a dinâmica destes sistemas em vizinhanças dos conjuntos de impasse. No caso suave, a Teoria de Fenichel clássica e crucial para o desenvolvimento dos principais resultados. Para o caso com descontinuidades, uma teoria similar a Teoria de Fenichel ´e desenvolvida. Além disso, estudamos a bifurcação de ciclos limites das órbitas periódicas de um centro diferencial linear quando perturbamos tal centro dentro de uma classe de sistemas diferenciais lineares por partes com impasse / In this work we study constrained diﬀerential systems, also known as systems of equations with impasse. We study the cases where such systems are smo oth and the cases where they are p ossibly discontinuous. Using singular p erturbation techniques we obtain some results on the dynamic of these systems in neighb orho o ds of the impasse sets. In smo oth case, the classical Fenichel’s Theory is crucial for the development of the main results. For the case with discontinuity, a similar theory to Fenichel’s Theory is develop ed. Moreover, we study the bifurcation of limit cycles from the p erio dic orbits of a linear diﬀerential center when we p erturb such center inside a class of piecewise linear diﬀerential systems with impasse Sistemas dinâmicos diferenciais Equações diferenciais ordinarias Campos vetoriais Perturbação singular (Matematica) Sistemas dinâmicos Constrained system Singular perturbation problems Impasse set Discontinuous vector ﬁelds Averaging method
6	Numerical Treatment of Non-Linear singular pertubation problems Shikongo, Albert January 2007 (has links) Magister Scientiae - MSc / This thesis deals with the design and implementation of some novel numerical methods for non-linear singular pertubations problems (NSPPs). It provide a survey of asymptotic and numerical methods for some NSPPs in the past decade. By considering two test problems, rigorous asymptotic analysis is carried out. Based on this analysis, suitable numerical methods are designed, analyzed and implemented in order to have some relevant results of physical importance. Since the asymptotic analysis provides only qualitative information, the focus is more on the numerical analysis of the problem which provides the quantitative information. / South Africa Asymptotic Analysis Fitted Mesh Finite Difference Methods Stability Error Estimates Convergence Enzyme Kinetics Numerical Analysis
7	Higher order numerical methods for singular perturbation problems Munyakazi, Justin Bazimaziki January 2009 (has links) Philosophiae Doctor - PhD / In recent years, there has been a great interest towards the higher order numerical methods for singularly perturbed problems. As compared to their lower order counterparts, they provide better accuracy with fewer mesh points. Construction and/or implementation of direct higher order methods is usually very complicated. Thus a natural choice is to use some convergence acceleration techniques, e.g., Richardson extrapolation, defect correction, etc. In this thesis, we will consider various classes of problems described by singularly perturbed ordinary and partial differential equations. For these problems, we design some novel numerical methods and attempt to increase their accuracy as well as the order of convergence. We also do the same for existing numerical methods in some instances. We find that, even though the Richardson extrapolation technique always improves the accuracy, it does not perform equally well when applied to different methods for certain classes of problems. Moreover, while in some cases it improves the order of convergence, in other cases it does not. These issues are discussed in this thesis for linear and nonlinear singularly perturbed ODEs as well as PDEs. Extrapolation techniques are analyzed thoroughly in all the cases, whereas the limitations of the defect correction approach for certain problems is indicated at the end of the thesis. / South Africa Singular perturbation problems Fitted finite difference methods Higher order numerical methods Richardson extrapolation Self-adjoint problems Turning point problems Parabolic problems Elliptic problems Maximum and minimum principles Convergence analysis
8	Numerical treatment of non-linear singular perturbation problems Shikongo, Albert January 2007 (has links) >Magister Scientiae - MSc / This thesis deals with the design and implementation of some novel numerical methods for nonlinear singular perturbations problems (NSPPs). We provide a survey of asymptotic and numerical methods for some NSPPs in past decade. By considering two test problems, rigorous asymptotic analysis is carried out. Based on this analysis, suitable numerical methods are designed, analyzed and implemented in order to have some relevant results of physical importance. Since the asymptotic analysis provides only qualitative information, the focus is more on the numerical analysis of the problem which provides the quantitative information. Asymptotic Analysis Numerical Analysis Fitted Mesh Finite Difference Methods Stability Error Estimates Convergence Enzyme Kinetics
9	High Accuracy Fitted Operator Methods for Solving Interior Layer Problems Sayi, Mbani T January 2020 (has links) Philosophiae Doctor - PhD / Fitted operator finite difference methods (FOFDMs) for singularly perturbed problems have been explored for the last three decades. The construction of these numerical schemes is based on introducing a fitting factor along with the diffusion coefficient or by using principles of the non-standard finite difference methods. The FOFDMs based on the latter idea, are easy to construct and they are extendible to solve partial differential equations (PDEs) and their systems. Noting this flexible feature of the FOFDMs, this thesis deals with extension of these methods to solve interior layer problems, something that was still outstanding. The idea is then extended to solve singularly perturbed time-dependent PDEs whose solutions possess interior layers. The second aspect of this work is to improve accuracy of these approximation methods via methods like Richardson extrapolation. Having met these three objectives, we then extended our approach to solve singularly perturbed two-point boundary value problems with variable diffusion coefficients and analogous time-dependent PDEs. Careful analyses followed by extensive numerical simulations supporting theoretical findings are presented where necessary. Stability analysis Convergence analysis Extrapolation methods Higher order numerical methods Two-point boundary value problems Turning point problems Interior layers Singular perturbation problems

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