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Numerical Smoothness on Linear Multistep Methods For Solving Ordinary Differential EquationsEschborn, Brandon T. 23 August 2022 (has links)
No description available.
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Perturbed Strong Stability Preserving Time-Stepping Methods For Hyperbolic PDEsHadjimichael, Yiannis 30 September 2017 (has links)
A plethora of physical phenomena are modelled by hyperbolic partial differential
equations, for which the exact solution is usually not known. Numerical methods
are employed to approximate the solution to hyperbolic problems; however, in many
cases it is difficult to satisfy certain physical properties while maintaining high order
of accuracy. In this thesis, we develop high-order time-stepping methods that
are capable of maintaining stability constraints of the solution, when coupled with
suitable spatial discretizations. Such methods are called strong stability preserving
(SSP) time integrators, and we mainly focus on perturbed methods that use both
upwind- and downwind-biased spatial discretizations.
Firstly, we introduce a new family of third-order implicit Runge–Kuttas methods
with arbitrarily large SSP coefficient. We investigate the stability and accuracy of
these methods and we show that they perform well on hyperbolic problems with large
CFL numbers. Moreover, we extend the analysis of SSP linear multistep methods to
semi-discretized problems for which different terms on the right-hand side of the
initial value problem satisfy different forward Euler (or circle) conditions. Optimal
perturbed and additive monotonicity-preserving linear multistep methods are studied
in the context of such problems. Optimal perturbed methods attain augmented
monotonicity-preserving step sizes when the different forward Euler conditions are
taken into account. On the other hand, we show that optimal SSP additive methods achieve a monotonicity-preserving step-size restriction no better than that of the corresponding
non-additive SSP linear multistep methods. Furthermore, we develop the
first SSP linear multistep methods of order two and three with variable step size, and
study their optimality. We describe an optimal step-size strategy and demonstrate
the effectiveness of these methods on various one- and multi-dimensional problems.
Finally, we establish necessary conditions to preserve the total variation of the solution
obtained when perturbed methods are applied to boundary value problems.
We implement a stable treatment of nonreflecting boundary conditions for hyperbolic
problems that allows high order of accuracy and controls spurious wave reflections.
Numerical examples with high-order perturbed Runge–Kutta methods reveal that this
technique provides a significant improvement in accuracy compared with zero-order
extrapolation.
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Sequential Monte Carlo Parameter Estimation for Differential EquationsArnold, Andrea 11 June 2014 (has links)
No description available.
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Efficient Simulation, Accurate Sensitivity Analysis and Reliable Parameter Estimation for Delay Differential EquationsZivariPiran, Hossein 03 March 2010 (has links)
Delay differential equations (DDEs) are a class of differential equations that have received considerable recent attention and
been shown to model many real life problems, traditionally formulated as systems of ordinary differential equations (ODEs),
more naturally and more accurately. Ideally a DDE modeling package should provide facilities for approximating the solution,
performing a sensitivity analysis and estimating unknown parameters. In this thesis we propose new techniques for efficient simulation, accurate sensitivity analysis and reliable parameter estimation of DDEs.
We propose a new framework for designing a delay differential equation (DDE) solver which works with any supplied initial value
problem (IVP) solver that is based on a general linear method (GLM) and can provide dense output. This is done by treating a
general DDE as a special example of a discontinuous IVP. We identify a precise process for the numerical techniques used when solving the implicit equations that arise on a time step, such as when the underlying IVP solver is implicit or the delay vanishes.
We introduce an equation governing the dynamics of sensitivities for the most general system of parametric DDEs. Then, having a similar view as the simulation (DDEs as discontinuous ODEs), we introduce a formula for finding the size of jumps that appear at discontinuity points when the sensitivity equations are integrated. This leads to an algorithm which can compute
sensitivities for various kind of parameters very accurately.
We also develop an algorithm for reliable parameter identification of DDEs. We propose a method for adding extra constraints to the
optimization problem, changing a possibly non-smooth optimization to a smooth problem. These constraints are effectively handled
using information from the simulator and the sensitivity analyzer.
Finally, we discuss the structure of our evolving modeling package DDEM. We present a process that has been used for incorporating
existing codes to reduce the implementation time. We discuss the object-oriented paradigm as a way of having a manageable design with reusable and customizable components. The package is programmed in C++ and provides a user-friendly calling sequences. The numerical results are very encouraging and show the effectiveness of the techniques.
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Efficient Simulation, Accurate Sensitivity Analysis and Reliable Parameter Estimation for Delay Differential EquationsZivariPiran, Hossein 03 March 2010 (has links)
Delay differential equations (DDEs) are a class of differential equations that have received considerable recent attention and
been shown to model many real life problems, traditionally formulated as systems of ordinary differential equations (ODEs),
more naturally and more accurately. Ideally a DDE modeling package should provide facilities for approximating the solution,
performing a sensitivity analysis and estimating unknown parameters. In this thesis we propose new techniques for efficient simulation, accurate sensitivity analysis and reliable parameter estimation of DDEs.
We propose a new framework for designing a delay differential equation (DDE) solver which works with any supplied initial value
problem (IVP) solver that is based on a general linear method (GLM) and can provide dense output. This is done by treating a
general DDE as a special example of a discontinuous IVP. We identify a precise process for the numerical techniques used when solving the implicit equations that arise on a time step, such as when the underlying IVP solver is implicit or the delay vanishes.
We introduce an equation governing the dynamics of sensitivities for the most general system of parametric DDEs. Then, having a similar view as the simulation (DDEs as discontinuous ODEs), we introduce a formula for finding the size of jumps that appear at discontinuity points when the sensitivity equations are integrated. This leads to an algorithm which can compute
sensitivities for various kind of parameters very accurately.
We also develop an algorithm for reliable parameter identification of DDEs. We propose a method for adding extra constraints to the
optimization problem, changing a possibly non-smooth optimization to a smooth problem. These constraints are effectively handled
using information from the simulator and the sensitivity analyzer.
Finally, we discuss the structure of our evolving modeling package DDEM. We present a process that has been used for incorporating
existing codes to reduce the implementation time. We discuss the object-oriented paradigm as a way of having a manageable design with reusable and customizable components. The package is programmed in C++ and provides a user-friendly calling sequences. The numerical results are very encouraging and show the effectiveness of the techniques.
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Métodos numéricos para o retoque digitalSantos, Claudia Augusta dos [UNESP] 25 February 2005 (has links) (PDF)
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santos_ca_me_sjrp.pdf: 757765 bytes, checksum: bd1f77ee4f0f4cdebfc0a29af4d9bc39 (MD5) / Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) / O objetivo deste trabalho þe aplicar Mþetodos Numþericos de ordem de precisão mais alta ao problema de Retoque Digital, visando melhorar a qualidade da aproximação quando comparada com o Método de Euler, que þe geralmente utilizado para esse tipo de problema. Para testar a eficiência de tais métodos, utilizamos três modelos de Retoque Digital: o modelo proposto por Bertalmþýo, Sapiro, Ballester e Caselles (BSBC), o modelo de Rudin, Osher e Fatemi conhecido como Variacional Total (TV) e o modelo de Chan e Shen, chamado de Difusão Guiada pela Curvatura (CDD). / The purpose of this work is to apply Numerical Methods of higher order to the problem of Digital Inpainting, aiming to improve the quality of the approach when compared with the Euler s Method which is generally used for this kind of problem. To test the e ciency of these methods we use three models of Digital Inpainting: the model considered by Bertalmþýo, Sapiro, Ballester and Caselles (BSBC), the model of Rudin, Osher and Fatemi known as Total Variation (TV) and the model of Chan and Shen, named Curvature Driven Di usion (CDD)
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Métodos numéricos para o retoque digital /Santos, Claudia Augusta dos. January 2005 (has links)
Orientador: Maurílio Boaventura / Banca: Antonio Castelo Filho / Banca: Heloisa Helena Marino Silva / Resumo: O objetivo deste trabalho þe aplicar Mþetodos Numþericos de ordem de precisão mais alta ao problema de Retoque Digital, visando melhorar a qualidade da aproximação quando comparada com o Método de Euler, que þe geralmente utilizado para esse tipo de problema. Para testar a eficiência de tais métodos, utilizamos três modelos de Retoque Digital: o modelo proposto por Bertalmþýo, Sapiro, Ballester e Caselles (BSBC), o modelo de Rudin, Osher e Fatemi conhecido como Variacional Total (TV) e o modelo de Chan e Shen, chamado de Difusão Guiada pela Curvatura (CDD). / Abstract: The purpose of this work is to apply Numerical Methods of higher order to the problem of Digital Inpainting, aiming to improve the quality of the approach when compared with the Eulers Method which is generally used for this kind of problem. To test the e ciency of these methods we use three models of Digital Inpainting: the model considered by Bertalmþýo, Sapiro, Ballester and Caselles (BSBC), the model of Rudin, Osher and Fatemi known as Total Variation (TV) and the model of Chan and Shen, named Curvature Driven Di usion (CDD) / Mestre
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Stabilita a konvergence numerických výpočtů / Stability and convergence of numerical computationsSehnalová, Pavla Unknown Date (has links)
Tato disertační práce se zabývá analýzou stability a konvergence klasických numerických metod pro řešení obyčejných diferenciálních rovnic. Jsou představeny klasické jednokrokové metody, jako je Eulerova metoda, Runge-Kuttovy metody a nepříliš známá, ale rychlá a přesná metoda Taylorovy řady. V práci uvažujeme zobecnění jednokrokových metod do vícekrokových metod, jako jsou Adamsovy metody, a jejich implementaci ve dvojicích prediktor-korektor. Dále uvádíme generalizaci do vícekrokových metod vyšších derivací, jako jsou např. Obreshkovovy metody. Dvojice prediktor-korektor jsou často implementovány v kombinacích modů, v práci uvažujeme tzv. módy PEC a PECE. Hlavním cílem a přínosem této práce je nová metoda čtvrtého řádu, která se skládá z dvoukrokového prediktoru a jednokrokového korektoru, jejichž formule využívají druhých derivací. V práci je diskutována Nordsieckova reprezentace, algoritmus pro výběr proměnlivého integračního kroku nebo odhad lokálních a globálních chyb. Navržený přístup je vhodně upraven pro použití proměnlivého integračního kroku s přístupe vyšších derivací. Uvádíme srovnání s klasickými metodami a provedené experimenty pro lineární a nelineární problémy.
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