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Reciprocity in vector acousticsDeal, Thomas J. 03 1900 (has links)
Approved for public release; distribution is unlimited / Reissued 30 May 2017 with Second Reader’s non-NPS affiliation added to title page. / The scalar reciprocity equation commonly stated in underwater acoustics relates pressure fields and monopole sources. It is often used to predict the pressure measured by a hydrophone for multiple source locations by placing a source at the hydrophone location and calculating the field everywhere for that source. That method, however, does not work when calculating the orthogonal components of the velocity field measured by a fixed receiver. This thesis derives a vector-scalar reciprocity equation that accounts for both monopole and dipole sources. This equation can be used to calculate individual components of the received vector field by altering the source type used in the propagation calculation. This enables a propagation model to calculate the received vector field components for an arbitrary number of source locations with a single model run for each received field component instead of requiring one model run for each source location. Application of the vector-scalar reciprocity principle is demonstrated with analytic solutions for a range-independent environment and with numerical solutions for a range-independent and a range-dependent environment using a parabolic equation model. / Electronics Engineer, Naval Undersea Warfare Center
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Feature-Based Uncertainty VisualizationWu, Keqin 11 August 2012 (has links)
While uncertainty in scientific data attracts an increasing research interest in the visualization community, two critical issues remain insufficiently studied: (1) visualizing the impact of the uncertainty of a data set on its features and (2) interactively exploring 3D or large 2D data sets with uncertainties. In this study, a suite of feature-based techniques is developed to address these issues. First, a framework of feature-level uncertainty visualization is presented to study the uncertainty of the features in scalar and vector data. The uncertainty in the number and locations of features such as sinks or sources of vector fields are referred to as feature-level uncertainty while the uncertainty in the numerical values of the data is referred to as data-level uncertainty. The features of different ensemble members are indentified and correlated. The feature-level uncertainties are expressed as the transitions between corresponding features through new elliptical glyphs. Second, an interactive visualization tool for exploring scalar data with data-level and two types of feature-level uncertainties — contour-level and topology-level uncertainties — is developed. To avoid visual cluttering and occlusion, the uncertainty information is attached to a contour tree instead of being integrated with the visualization of the data. An efficient contour tree-based interface is designed to reduce users’ workload in viewing and analyzing complicated data with uncertainties and to facilitate a quick and accurate selection of prominent contours. This thesis advances the current uncertainty studies with an in-depth investigation of the feature-level uncertainties and an exploration of topology tools for effective and interactive uncertainty visualizations. With quantified representation and interactive capability, feature-based visualization helps people gain new insights into the uncertainties of their data, especially the uncertainties of extracted features which otherwise would remain unknown with the visualization of only data-level uncertainties.
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Autonomous Path-Following by Approximate Inverse Dynamics and Vector Field PredictionGerlach, Adam R. 23 October 2014 (has links)
No description available.
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Spectral, Combinatorial, and Probabilistic Methods in Analyzing and Visualizing Vector Fields and Their Associated FlowsReich, Wieland 29 March 2017 (has links) (PDF)
In this thesis, we introduce several tools, each coming from a different branch of mathematics, for analyzing real vector fields and their associated flows.
Beginning with a discussion about generalized vector field decompositions, that mainly have been derived from the classical Helmholtz-Hodge-decomposition, we decompose a field into a kernel and a rest respectively to an arbitrary vector-valued linear differential operator that allows us to construct decompositions of either toroidal flows or flows obeying differential equations of second (or even fractional) order and a rest. The algorithm is based on the fast Fourier transform and guarantees a rapid processing and an implementation that can be directly derived from the spectral simplifications concerning differentiation used in mathematics.
Moreover, we present two combinatorial methods to process 3D steady vector fields, which both use
graph algorithms to extract features from the underlying vector field. Combinatorial approaches are known to be less sensitive to noise than extracting individual trajectories. Both of the methods are extensions of an existing 2D technique to 3D fields.
We observed that the first technique can generate overly coarse results and therefore we present a second method that works using the same concepts but produces more detailed results. Finally, we discuss several possibilities for categorizing the invariant sets with respect to the flow.
Existing methods for analyzing separation of streamlines are often restricted to a finite time or a local area. In the frame of this work, we introduce a new method that complements them by allowing an infinite-time-evaluation of steady planar vector fields. Our algorithm unifies combinatorial and probabilistic methods and introduces the concept of separation in time-discrete Markov chains. We compute particle distributions instead of the streamlines of single particles. We encode the flow into a map and then into a transition matrix for each time direction. Finally, we compare the results of our grid-independent algorithm to the popular Finite-Time-Lyapunov-Exponents and discuss the discrepancies.
Gauss\' theorem, which relates the flow through a surface to the vector field inside the surface, is an important tool in flow visualization. We are exploiting the fact that the theorem can be further refined on polygonal cells and construct a process that encodes the particle movement through the boundary facets of these cells using transition matrices. By pure power iteration of transition matrices, various topological features, such as separation and invariant sets, can be extracted without having to rely on the classical techniques, e.g., interpolation, differentiation and numerical streamline integration.
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[en] FEATURE-PRESERVING VECTOR FIELD DENOISING / [pt] REMOÇÃO DE RUÍDO EM CAMPO VETORIALJOAO ANTONIO RECIO DA PAIXAO 14 May 2019 (has links)
[pt] Nos últimos anos, vários mecanismos permitem medir campos vetoriais reais, provendo uma compreensão melhor de fenômenos importantes, tais como dinâmica de fluidos ou movimentos de fluido cerebral. Isso abre um leque de novos desafios a visualização e análise de campos vetoriais em muitas aplicações de engenharia e de medicina por exemplo. Em particular, dados reais são geralmente corrompidos por ruído, dificultando a compreensão na hora da visualização. Esta informação necessita de uma etapa de remoção de ruído como pré-processamento, no entanto remoção de ruído normalmente remove as descontinuidades
e singularidades, que são fundamentais para a análise do campo vetorial. Nesta dissertação é proposto um método inovador para remoção de ruído em campo vetorial baseado em caminhadas aleatórias que preservam certas descontinuidades. O método funciona em um ambiente desestruturado, sendo rápido, simples de implementar e mostra um desempenho melhor do que a tradicional técnica Gaussiana de remoção de ruído. Esta tese propõe também uma metodologia semi-automática para remover ruído, onde o usuário controla a escala visual da filtragem, levando em consideração as mudanças topológicas que ocorrem por causa da filtragem. / [en] In recent years, several devices allow to measure real vector fields, leading to a better understanding of fundamental phenomena such as fluid dynamics or brain water movements. This gives vector field visualization and analysis new challenges in many applications in engineering and in medicine. In particular
real data is generally corrupted by noise, puzzling the understanding provided by visualization tools. This data needs a denoising step as preprocessing, however usual denoising removes discontinuities and singularities, which are fundamental for vector field analysis. In this dissertation a novel method for vector field denoising based on random walks is proposed which preserves certain discontinuities. It works in a unstructured setting; being fast, simple to implement, and shows a better performance than the traditional Gaussian denoising technique. This dissertation also proposes a semi-automatic vector field denoising methodology, where the user visually controls the filtering scale by validating topological changes caused by classical vector field filtering.
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Estudo qualitativo de campos suaves por partes via problema de perturbação singular / Qualitative study of piecewise smooth vector field via singular pertubation problemSantos, Mayk Joaquim dos 16 January 2017 (has links)
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Previous issue date: 2017-01-16 / In this work we will show that, given a piecewise smooth vector field, we can apply the regularization method and, from it, via blow-up, turn it into a singular perturbation problem. By doing that, we can use the tools from singular perturbation theory to perform a qualitative study of piecewise smooth vector fields. Finally, we will show that, through successive changes of coordinates, a singularity of a discontinuous submanifold of codimension k, where k=1 or k=2, can be transformed into a singularity of codimension 0 in order to study the qualitative behavior in this submanifold, where the Filippov’s convention holds. / Neste trabalho mostraremos que, dado um campo de vetores suaves por partes, podemos aplicar o método de regularização e, a partir deste, via “blow-up”, o transformamos em um problema de perturbação singular. Podemos, dessa forma, fazer uso das ferramentas da teoria de perturbação singular para realizar um estudo qualitativo dos campos de vetores suaves por partes. Por último, mostraremos que através de sucessivas mudanças de coordenadas podemos transformar uma singularidade de uma subvariedade de descontinuidade de codimensão k, onde k=1 ou k=2, em uma uma singularidade de codimensão 0 e estudar o comportamento qualitativo ao longo desta subvariedade, onde é válida a convenção de Filippov.
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Spectral, Combinatorial, and Probabilistic Methods in Analyzing and Visualizing Vector Fields and Their Associated FlowsReich, Wieland 21 March 2017 (has links)
In this thesis, we introduce several tools, each coming from a different branch of mathematics, for analyzing real vector fields and their associated flows.
Beginning with a discussion about generalized vector field decompositions, that mainly have been derived from the classical Helmholtz-Hodge-decomposition, we decompose a field into a kernel and a rest respectively to an arbitrary vector-valued linear differential operator that allows us to construct decompositions of either toroidal flows or flows obeying differential equations of second (or even fractional) order and a rest. The algorithm is based on the fast Fourier transform and guarantees a rapid processing and an implementation that can be directly derived from the spectral simplifications concerning differentiation used in mathematics.
Moreover, we present two combinatorial methods to process 3D steady vector fields, which both use
graph algorithms to extract features from the underlying vector field. Combinatorial approaches are known to be less sensitive to noise than extracting individual trajectories. Both of the methods are extensions of an existing 2D technique to 3D fields.
We observed that the first technique can generate overly coarse results and therefore we present a second method that works using the same concepts but produces more detailed results. Finally, we discuss several possibilities for categorizing the invariant sets with respect to the flow.
Existing methods for analyzing separation of streamlines are often restricted to a finite time or a local area. In the frame of this work, we introduce a new method that complements them by allowing an infinite-time-evaluation of steady planar vector fields. Our algorithm unifies combinatorial and probabilistic methods and introduces the concept of separation in time-discrete Markov chains. We compute particle distributions instead of the streamlines of single particles. We encode the flow into a map and then into a transition matrix for each time direction. Finally, we compare the results of our grid-independent algorithm to the popular Finite-Time-Lyapunov-Exponents and discuss the discrepancies.
Gauss\'' theorem, which relates the flow through a surface to the vector field inside the surface, is an important tool in flow visualization. We are exploiting the fact that the theorem can be further refined on polygonal cells and construct a process that encodes the particle movement through the boundary facets of these cells using transition matrices. By pure power iteration of transition matrices, various topological features, such as separation and invariant sets, can be extracted without having to rely on the classical techniques, e.g., interpolation, differentiation and numerical streamline integration.
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Developing and Utilizing the Concept of Affine Linear Neighborhoods in Flow VisualizationKoch, Stefan 07 May 2021 (has links)
In vielen Forschungsbereichen wie Medizin, Natur- oder Ingenieurwissenschaften spielt die wissenschaftliche Visualisierung eine wichtige Rolle und hilft Wissenschaftlern neue Erkenntnisse zu gewinnen. Der Hauptgrund hierfür ist, dass Visualisierungen das Unsichtbare sichtbar machen können. So können Visualisierungen beispielsweise den Verlauf von Nervenfasern im Gehirn von Probanden oder den Luftstrom um Hindernisse herum darstellen. Diese Arbeit trägt insbesondere zum Teilgebiet der Strömungsvisualisierung bei, welche sich mit der Untersuchung von Prozessen in Flüssigkeiten und Gasen beschäftigt.
Eine beliebte Methode, um Einblicke in komplexe Datensätze zu erhalten, besteht darin, einfache und bekannte Strukturen innerhalb eines Datensatzes aufzuspüren. In der Strömungsvisualisierung führt dies zum Konzept der lokalen Linearisierung und Linearität im Allgemeinen. Dies liegt daran, dass lineare Vektorfelder die einfachste Form von nicht-trivialen Feldern darstellen und diese sehr gut verstanden sind. In der Regel werden simulierte Datensätze in einzelne Zellen diskretisiert, welche auf linearer Interpolation basieren. Beispielsweise können auch stationäre Punkte in der Vektorfeldtopologie mittels linearen Strömungsverhaltens charakterisiert werden. Daher ist Linearität allgegenwärtig.
Durch das Verständnis von lokalen linearen Strömungsverhalten in Vektorfeldern konnten verschiedene Visualisierungsmethoden erheblich verbessert werden. Ähnliche Erfolge sind auch für andere Methoden zu erwarten. In dieser Arbeit wird das Konzept der Linearität in der Visualisierung weiterentwickelt. Zunächst wird eine bestehende Definition von linearen Nachbarschaften hin zu affin-linearen Nachbarschaften erweitert. Affin-lineare Nachbarschaften sind Regionen mit einem überwiegend linearem Strömungsverhalten. Es wird eine detaillierte Diskussion über die Definition sowie die gewählten Fehlermaße durchgeführt. Weiterhin wird ein Region Growing-Verfahren vorgestellt, welches affin-lineare Nachbarschaften um beliebige Positionen bis zu einem bestimmten, benutzerdefinierten Fehlerschwellwert extrahiert. Um die lokale Linearität in Vektorfeldern zu messen, wird ein komplementärer Ansatz, welcher die Qualität der bestmöglichen linearen Näherung für eine gegebene n-Ring-Nachbarschaft berechnet, diskutiert. In einer ersten Anwendung werden affin-lineare Nachbarschaften an stationären Punkten verwendet, um deren Einflussbereich sowie ihre Wechselwirkung mit der sie umgebenden, nichtlinearen Strömung, aber auch mit sehr nah benachbarten stationären Punkten zu visualisieren.
Insbesondere bei sehr großen Datensätzen kann die analytische Beschreibung der Strömung innerhalb eines linearisierten Bereichs verwendet werden, um Vektorfelder zu komprimieren und vorhandene Visualisierungsansätze zu beschleunigen. Insbesondere sollen eine Reihe von Komprimierungsalgorithmen für gitterbasierte Vektorfelder verbessert werden, welche auf der sukzessiven Entfernung einzelner Gitterkanten basieren. Im Gegensatz zu vorherigen Arbeiten sollen affin-lineare Nachbarschaften als Grundlage für eine Segmentierung verwendet werden, um eine obere Fehlergrenze bereitzustellen und somit eine hohe Qualität der Komprimierungsergebnisse zu gewährleisten. Um verschiedene Komprimierungsansätze zu bewerten, werden die Auswirkungen ihrer jeweiligen Approximationsfehler auf die Stromlinienintegration sowie auf integrationsbasierte Visualisierungsmethoden am Beispiel der numerischen Berechnung von Lyapunov-Exponenten diskutiert.
Zum Abschluss dieser Arbeit wird eine mögliche Erweiterung des Linearitätbegriffs für Vektorfelder auf zweidimensionalen Mannigfaltigkeiten vorgestellt, welche auf einer adaptiven, atlasbasierten Vektorfeldzerlegung basiert. / In many research areas, such as medicine, natural sciences or engineering, scientific visualization plays an important role and helps scientists to gain new insights. This is because visualizations can make the invisible visible. For example, visualizations can reveal the course of nerve fibers in the brain of test persons or the air flow around obstacles. This thesis in particular contributes to the subfield of flow visualization, which targets the investigation of processes in fluids and gases.
A popular way to gain insights into complex datasets is to identify simple and known structures within a dataset. In case of flow visualization, this leads to the concept of local linearizations and linearity in general. This is because linear vector fields represent the most simple class of non-trivial fields and they are extremely well understood. Typically, simulated datasets are discretized into individual cells that are based on linear interpolation. Also, in vector field topology, stationary points can be characterized by considering the local linear flow behavior in their vicinity. Therefore, linearity is ubiquitous.
Through the understanding of local linear flow behavior in vector fields by applying the concept of local linearity, some visualization methods have been improved significantly. Similar successes can be expected for other methods. In this thesis, the use of linearity in visualization is investigated. First, an existing definition of linear neighborhoods is extended towards the affine linear neighborhoods. Affine linear neighborhoods are regions of mostly linear flow behavior. A detailed discussion of the definition and of the chosen error measures is provided. Also a region growing algorithm that extracts affine linear neighborhoods around arbitrary positions up to a certain user-defined approximation error threshold is introduced. To measure the local linearity in vector fields, a complementary approach that computes the quality of the best possible linear approximation for a given n-ring neighborhood is discussed. As a first application, the affine linear neighborhoods around stationary points are used to visualize their region of influence, their interaction with the non-linear flow around them as well as their interaction with closely neighbored stationary points.
The analytic description of the flow within a linearized region can be used to compress vector fields and accelerate existing visualization approaches, especially in case of very large datasets. In particular, the presented method aims at improving over a series of compression algorithms for grid-based vector fields that are based on edge collapse. In contrast to previous approaches, affine linear neighborhoods serve as the basis for a segmentation in order to provide an upper error bound and also to ensure a high quality of the compression results. To evaluate different compression approaches, the impact of their particular approximation errors on streamline integration as well as on integration-based visualization methods is discussed on the example of Finite-Time Lyapunov Exponent computations.
To conclude the thesis, a first possible extension of linearity to fields on two-dimensional manifolds, based on an adaptive atlas-based vector field decomposition, is given.
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Segmentação e exploração de campos vetoriais usando projeção multidimensional / Segmentation and exploration of vector fields using multidimensional projectionMotta, Danilo Andrade 12 November 2013 (has links)
Neste trabalho propomos uma nova maneira de visualizar campos vetoriais, dados de considerável importância em vários ramos da ciência. Fizemos uma revisão bibliográfica sobre segmentação de campos vetoriais e desenvolvemos nosso próprio método. Neste método são extraídas informações do campo e, de distribuições de frequências dos dados coletados são formados vetores multidimensionais. Esses vetores são projetados em duas dimensões e os agrupamentos destes pontos são utilizados para formar a segmentação do campo original. Os profissionais que fazem uso de ferramentas de visualização científica possuem, em geral, informações relevantes sobre o domínio do campo vetorial, mas essa informação é raramente aproveitada nas técnicas de segmentação. A técnica desenvolvida permite que o usuário interaja com os resultados, de maneira intuitiva, corrigindo e explorando a segmentação usando seu próprio conhecimento. Como contribuições desta pesquisa podemos citar o mecanismo de interação com o usuário para o auxílio da segmentação e uma nova maneira para representar os dados colhidos de campos vetoriais em dimensão alta / In this research we introduce a novel method for visualizing vector fields, data of considerable importance in several branches of science. We did a literature review targeting vector fields and developed our own method. In this method information is extracted from the field and, from frequency distributions of the collected data multidimensional vectors are created. These vectors are projected in two dimensions and clusters of these points are used to form a segmentation of the original field. The professionals that make use of scientific visualization tools have, in general, relevant information about the domain of the vector field, but this information is rarely exploited by segmentation techniques. The developed technique allows the user to interact with the results, intuitively, exploring and correcting the segmentation using his own knowledge. As contributions of this research include the mechanism of interaction with the user to aid the segmentation and a new method to represent the collected data from vector fields in high dimension
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[en] INVARIANT ALGEBRAIC VARIETIES BY FOLIATIONS ON PROJECTIVE SPACE / [pt] CONJUNTOS ALGÉBRICOS INVARIANTES DE FOLHEAÇÕES NO ESPAÇO PROJETIVOJOANA DARC ANTONIA SANTOS DA CRUZ 14 December 2006 (has links)
[pt] A regularidade de Catelnuovo-Munford r de uma variedade V
contida no espaço projetivo P, n, k é um limite superior
para o grau das hipersuperfícies que definem V. Neste
trabalho damos uma cota superior para r quando V é uma
curva aritmeticamente Cohen-Macaulay e subcanônica que é
invariante por um campo vetorial sobre o espaço projetivo
P, n, k (com coeficientes em um fibrado de retas), sob
certas condições no corpo k. Além disso, damos uma cota
superior para r (ou ainda, para o grau de V), quando V é
uma hipersuperfície solução de um campo de Pfaff de posto 1
sobre o espaço projetivo P, n, k, sob certas condições no
corpo k. Estes limites obtidos são generalizações do limite
dado por E. Esteves em [17]. / [en] The Castelnuovo-Mumford regularity r of the variety V
contained in a projective space P, n, k is an upper bound
for the degrees of the hypersurfaces necessary to cut out
V. In this work we give a bound for r when V is an
arithmetically Cohen-Macaulay and sub-canonical curve which
is invariant by a vector field on projective space P, n, k
with coefficients in an invertible sheaf, under some
conditions on the field k. Furthermore, we give a bound for
r (i.e.for the degree of the V) when V is a hypersurface
solution of the Pfaff equation of the rank 1, under some
conditions on the field k. In both limits we consider the
positions of the singularities of the V. These limits are
the generalizations of the bounds given by E. Esteves in
[17].
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