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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Issues in Interpolatory Model Reduction: Inexact Solves, Second-order Systems and DAEs

Wyatt, Sarah Alice 25 May 2012 (has links)
Dynamical systems are mathematical models characterized by a set of differential or difference equations. Model reduction aims to replace the original system with a reduced system of significantly smaller dimension that still describes the important dynamics of the large-scale model. Interpolatory model reduction methods define a reduced model that interpolates the full model at selected interpolation points. The reduced model may be obtained through a Krylov reduction process or by using the Iterative Rational Krylov Algorithm (IRKA), which iterates this Krylov reduction process to obtain an optimal ℋ₂ reduced model. This dissertation studies interpolatory model reduction for first-order descriptor systems, second-order systems, and DAEs. The main computational cost of interpolatory model reduction is the associated linear systems. Especially in the large-scale setting, inexact solves become desirable if not necessary. With the introduction of inexact solutions, however, exact interpolation no longer holds. While the effect of this loss of interpolation has previously been studied, we extend the discussion to the preconditioned case. Then we utilize IRKA's convergence behavior to develop preconditioner updates. We also consider the interpolatory framework for DAEs and second-order systems. While interpolation results still hold, the singularity associated with the DAE often results in unbounded model reduction errors. Therefore, we present a theorem that guarantees interpolation and a bounded model reduction error. Since this theorem relies on expensive projectors, we demonstrate how interpolation can be achieved without explicitly computing the projectors for index-1 and Hessenberg index-2 DAEs. Finally, we study reduction techniques for second-order systems. Many of the existing methods for second-order systems rely on the model's associated first-order system, which results in computations of a 2𝑛 system. As a result, we present an IRKA framework for the reduction of second-order systems that does not involve the associated 2𝑛 system. The resulting algorithm is shown to be effective for several dynamical systems. / Ph. D.
2

Estudio de la percepción social del territorio y de los servicios ecosistémicos en Alto Mayo, Región San Martín, Perú / Estudio de la percepción social del territorio y de los servicios ecosistémicos en Alto Mayo, Región San Martín, Perú

Codato, Daniele 10 April 2018 (has links)
Ecosystem services (ES) are defined as the benefits people obtain from ecosystems. The inclusion of the ES is being acknowledged as very important, as well as the local actors knowledge and getting an estimation of the perceived social, economic or biophysics values in order to evaluate the complete range of ecosystem values. Social values are may be described as the socio are estimated through social evaluations and other non utilitarian techniques. Alto Mayo in San Martin Region is part of an Andean variety of ES and unusual characteristics; it is also a territory that is under major transformations with different negative impacts both on human and natural capital, which could lead to a decline in the quality of life of its population. In the last ten years the Regional Government of San Martin, along with the collaboration of various NGOs and other agencies, has carried out several initiatives to revert environmental degradation of the area. In this presentation, a research project will be presented to study the knowledge and perception of local actors about the Alto Mayo territory and the ES that may contribute to the conservation of ecosystems in the area. We will focus on the work methodology used, that is, the study conducted through questionnaires, interviews and participatory mapping with various actors in the area and the use of the G.I.S. tool SolVES (the Social Values ​​for Ecosystem Services). / Los Servicios Ecosistémicos (SE) son definidos como  los servicios que el capital natural provee a los seres humanos. Se está reconociendo siempre más importancia a la inclusión de los SE, al conocimiento de los actores locales y al brindar una estimación de los valores sociales percibidos, además de los económicos o biofísicos, para evaluar el rango completo de valores ecosistémicos. Los valores sociales se pueden definir como la percepción socio cultural del bienestar humano brindado por los ecosistemas.El Alto Mayo en la Región de San Martín es parte de una cuenca andino características peculiares y gran proveedora de diferentes SE, pero también es un territorio bajo grandes trasformaciones con diferentes impactos negativos sobre su capital natural y humano que podrían llevar a una disminución de la calidad de vida de su población. En los últimos diez años el Gobierno Regional de San Martin con la colaboración de diferentes ONGs y agencias de cooperación ha empezado diferentes iniciativas para revertir los procesos de degradación ambiental en el área.Se presentará un proyecto de investigación que mira a estudiar el conocimiento y la percepción de los actores locales sobre el territorio del Alto Mayo y sus SE que pueda contribuir a la conservación de los ecosistemas del área. Se dará amplio espacio a la metodología de trabajo utilizada, es decir el estudio a través de cuestionarios, entrevistas y mapeo participativo a diferentes actores del área y el utilizo de la herramienta SIG SolVES (the Social Values for Ecosystem Services).
3

Iterative methods for criticality computations in neutron transport theory

Scheben, Fynn January 2011 (has links)
This thesis studies the so-called “criticality problem”, an important generalised eigenvalue problem arising in neutron transport theory. The smallest positive real eigenvalue of the problem contains valuable information about the status of the fission chain reaction in the nuclear reactor (i.e. the criticality of the reactor), and thus plays an important role in the design and safety of nuclear power stations. Because of the practical importance, efficient numerical methods to solve the criticality problem are needed, and these are the focus of this thesis. In the theory we consider the time-independent neutron transport equation in the monoenergetic homogeneous case with isotropic scattering and vacuum boundary conditions. This is an unsymmetric integro-differential equation in 5 independent variables, modelling transport, scattering, and fission, where the dependent variable is the neutron angular flux. We show that, before discretisation, the nonsymmetric eigenproblem for the angular flux is equivalent to a related eigenproblem for the scalar flux, involving a symmetric positive definite weakly singular integral operator(in space only). Furthermore, we prove the existence of a simple smallest positive real eigenvalue with a corresponding eigenfunction that is strictly positive in the interior of the reactor. We discuss approaches to discretise the problem and present discretisations that preserve the underlying symmetry in the finite dimensional form. The thesis then describes methods for computing the criticality in nuclear reactors, i.e. the smallest positive real eigenvalue, which are applicable for quite general geometries and physics. In engineering practice the criticality problem is often solved iteratively, using some variant of the inverse power method. Because of the high dimension, matrix representations for the operators are often not available and the inner solves needed for the eigenvalue iteration are implemented by matrix-free inneriterations. This leads to inexact iterative methods for criticality computations, for which there appears to be no rigorous convergence theory. The fact that, under appropriate assumptions, the integro-differential eigenvalue problem possesses an underlying symmetry (in a space of reduced dimension) allows us to perform a systematic convergence analysis for inexact inverse iteration and related methods. In particular, this theory provides rather precise criteria on how accurate the inner solves need to be in order for the whole iterative method to converge. The theory is illustrated with numerical examples on several test problems of physical relevance, using GMRES as the inner solver. We also illustrate the use of Monte Carlo methods for the solution of neutron transport source problems as well as for the criticality problem. Links between the steps in the Monte Carlo process and the underlying mathematics are emphasised and numerical examples are given. Finally, we introduce an iterative scheme (the so-called “method of perturbation”) that is based on computing the difference between the solution of the problem of interest and the known solution of a base problem. This situation is very common in the design stages for nuclear reactors when different materials are tested, or the material properties change due to the burn-up of fissile material. We explore the relation ofthe method of perturbation to some variants of inverse iteration, which allows us to give convergence results for the method of perturbation. The theory shows that the method is guaranteed to converge if the perturbations are not too large and the inner problems are solved with sufficiently small tolerances. This helps to explain the divergence of the method of perturbation in some situations which we give numerical examples of. We also identify situations, and present examples, in which the method of perturbation achieves the same convergence rate as standard shifted inverse iteration. Throughout the thesis further numerical results are provided to support the theory.
4

Rational Krylov Methods for Operator Functions

Güttel, Stefan 26 March 2010 (has links) (PDF)
We present a unified and self-contained treatment of rational Krylov methods for approximating the product of a function of a linear operator with a vector. With the help of general rational Krylov decompositions we reveal the connections between seemingly different approximation methods, such as the Rayleigh–Ritz or shift-and-invert method, and derive new methods, for example a restarted rational Krylov method and a related method based on rational interpolation in prescribed nodes. Various theorems known for polynomial Krylov spaces are generalized to the rational Krylov case. Computational issues, such as the computation of so-called matrix Rayleigh quotients or parallel variants of rational Arnoldi algorithms, are discussed. We also present novel estimates for the error arising from inexact linear system solves and the approximation error of the Rayleigh–Ritz method. Rational Krylov methods involve several parameters and we discuss their optimal choice by considering the underlying rational approximation problems. In particular, we present different classes of optimal parameters and collect formulas for the associated convergence rates. Often the parameters leading to best convergence rates are not optimal in terms of computation time required by the resulting rational Krylov method. We explain this observation and present new approaches for computing parameters that are preferable for computations. We give a heuristic explanation of superlinear convergence effects observed with the Rayleigh–Ritz method, utilizing a new theory of the convergence of rational Ritz values. All theoretical results are tested and illustrated by numerical examples. Numerous links to the historical and recent literature are included.
5

Rational Krylov Methods for Operator Functions

Güttel, Stefan 12 March 2010 (has links)
We present a unified and self-contained treatment of rational Krylov methods for approximating the product of a function of a linear operator with a vector. With the help of general rational Krylov decompositions we reveal the connections between seemingly different approximation methods, such as the Rayleigh–Ritz or shift-and-invert method, and derive new methods, for example a restarted rational Krylov method and a related method based on rational interpolation in prescribed nodes. Various theorems known for polynomial Krylov spaces are generalized to the rational Krylov case. Computational issues, such as the computation of so-called matrix Rayleigh quotients or parallel variants of rational Arnoldi algorithms, are discussed. We also present novel estimates for the error arising from inexact linear system solves and the approximation error of the Rayleigh–Ritz method. Rational Krylov methods involve several parameters and we discuss their optimal choice by considering the underlying rational approximation problems. In particular, we present different classes of optimal parameters and collect formulas for the associated convergence rates. Often the parameters leading to best convergence rates are not optimal in terms of computation time required by the resulting rational Krylov method. We explain this observation and present new approaches for computing parameters that are preferable for computations. We give a heuristic explanation of superlinear convergence effects observed with the Rayleigh–Ritz method, utilizing a new theory of the convergence of rational Ritz values. All theoretical results are tested and illustrated by numerical examples. Numerous links to the historical and recent literature are included.

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