Bachelor Thesis
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- 2019 (25) (remove)
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- Bachelor Thesis (25) (remove)
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- Immersion (2)
- Cybersickness (1)
- ECSA (1)
- Entity Component System Architecture (1)
- Material point method (1)
- Motion Sickness (1)
- Physiksimulation (1)
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Institute
- Institut für Computervisualistik (25) (remove)
Ist es möglich, allein mittels VR-Headset bei Nutzern Immersion zu
erzeugen? Zur Beantwortung dieser Frage werden zwei Simulationen einer
Achterbahnfahrt ohne haptisches Feedback mittels der Unreal Engine
4.20.3 für ein HTC-Vive VR Headset entwickelt und implementiert. Die
zweite Simulation unterscheidet sich von der ersten durch die Darbietung
außergewöhnlicher Ereignisse während der Fahrt, für die vermutet wird,
dass sie das Immersionserleben verstärken. Elf Probanden nahmen an der
Untersuchung teil. Die Auswertung eines Fragebogens zur Erfassung der
Intensität der Immersion und der Antworten auf offenen Fragen zeigt, dass
Immersion in beiden Simulation erfolgreich erzeugt werden konnte. Manche
Merkmale der Simulation vertieften bei einzelnen Probanden das immersive
Erleben, bei anderen dagegen nicht. Die Bedeutung der Ergebnisse
und Optimierungsmöglichkeiten für künftige Studien werden diskutiert.
The goal of this bachelor thesis was to add an image processing step to the music recognition software AudiVeris, in order to extract data even from faulty music sheet images. The procedure starts with a binarization using a regional version of Otsu's method. Following this the music sheet is searched for possible bendings, similar to those a hardcover book would cause. To achieve this the Hough transform is used for line detection and the k-means algorithm for cluster detection. Thereafter the music image is straightened using the discovered curvature.
Bildsynthese durch Raytracing gewinnt durch Hardware-Unterstützung in Verbraucher-Grafikkarten eine immer größer werdende Relevanz. Der Linespace dient dabei als eine neue, vielversprechende Beschleunigungsstruktur. Durch seine richtungsbasierte Natur ist es sinnvoll, ihn in andere Datenstrukturen zu integrieren. Bisher wurde er in ein Uniform-Grid integriert. Problematisch werden einheitlich große Voxel allerdings bei Szenen mit variierbarem Detailgrad. Diese Arbeit führt den adaptiven Linespace ein, eine Kombination aus Octree und Linespace. Die Struktur wird hinsichtlich ihrer Beschleunigungsfähigkeit untersucht und mit dem bisherigen Grid-Ansatz verglichen. Es wird gezeigt, dass der adaptive Linespace für hohe Grid-Auflösungen besser skaliert, durch eine ineffiziente GPU-Nutzung allerdings keine optimalen Werte erzielt.
The mitral valve is one of four human heart valves. It is located in the left heart and acts as a unidirectional passageway for blood between the left atrium and the left ventricle. A correctly functioning mitral valve prevents a backflow of blood into the pulmonary circulation (lungs) and thus constitutes a vital part of the cardiac cycle. Pathologies of the mitral valve can manifest in a variety of symptoms with severity ranging from chest pain and fatigue to pulmonary edema (fluid accumulation in the tissue and air space of lungs), which may ultimately cause respiratory failure.
Malfunctioning mitral valves can be restored through complex surgical interventions, which greatly benefit from intensive planning and pre-operative analysis. Visualization techniques provide a possibility to enhance such preparation processes and can also facilitate post-operative evaluation. The work at hand extends current research in this field, building upon patient-specific mitral valve segmentations developed at the German Cancer Research Center, which result in triangulated 3D models of the valve surface. The core of this work will be the construction of a 2D-view of these models through global parameterization, a method that can be used to establish a bijective mapping between a planar parameter domain and a surface embedded in higher dimensions.
A flat representation of the mitral valve provides physicians with a view of the whole surface at once, similar to a map. This allows assessment of the valve's area and shape without the need for different viewing angles. Parts of the valve that are occluded by geometry in 3D become visible in 2D.
An additional contribution of this work will be the exploration of different visualizations of the 3D and 2D mitral valve representations. Features of the valve can be highlighted by associating them with specified colors, which can for instance directly convey pathology indicators.
Quality and effectiveness of the proposed methods were evaluated through a survey conducted at the Heidelberg University Hospital.
In dieser Arbeit wird das Echtzeitrendering von Wolken von der Theorie bis hin zur Entwicklung derselben behandelt. Dabei sollen die visuellen Eigenschaften der Wolken sowie die unterschiedliche Wolkentypen simuliert werden. Dabei ist die Berechnung der Beleuchtung essentiell für ein glaubwürdiges Ergebnis. Die Rendertechniken nutzen dabei unterschiedliche Noise-Texturen; für die Modulierung der Wolken sind es hauptsächlich Perlin- und Perlin-Worley-Texturen. Das Rendern der Wolken wird per Compute-Shader durchgeführt um die Echtzeitfähigkeit zu gewährleisten. Um die Performance zu steigern, werden Temporal Reprojektion und andere Optimierungstechniken angewendet.
Simulation von Rauch
(2019)
This bachelor thesis deals with the simulation of smoke in a particle
system. Here the possibilities are investigated to implement smoke as
realistically as possible in a particle system and to calculate it in real time.
The physical simulation is based on the work of Müller and
Ren, who deal with the physical properties of fluids and gases.
The simulation was implemented on the GPU using C++, OpenGL and
the compute shaders available in OpenGL. Special attention was paid
to the performance of the simulation. Hoetzlein techniques are
used to accelerate the particle system. Two acceleration methods were
then implemented and compared. The runtime, but also the used memory
space of the GPU is discussed.
Global-Illumination is an important part of the rendering of realistic images. However, the computational complexity of an accurate simulation of these effects is too high for the use in real time applications. In this paper Light-Propagation-Volumes, Screen-Space-Reflections and multiple variants of Screen-Space-Ambient-Occlusion are investigated as a solution for real time rendering. It is shown that they are fast enough for the use in real time applications. The various techniques approximate only a few aspects of the light transport, but complement each other.
This bachelor thesis implements a system for camera tracking based on a particle filter. For this purpose, a marker tracking is realized and the camera position is calculated based on the marker position. The marker is to be found with a particle filter and in order to accomplish this possible marker positions are simulated, also called particles, and weighted with Likelyhood-Functions. The focus lies on the evaluation of different Likelihood-Functions of the particle filter. The Likelyhood functions were implemented in CUDA as part of the implementation.
The following bachelor thesis gives an overview of various approaches and techniques for procedural generation of three-dimensional city models. Especially the usage of generative grammars is being examined and later used for the implementation of an own application. Its focus was the embedding of predetermined primary street networks as well as the procedural generation of secondary street networks and different kinds of buildings. The application allows the efficient creation of extensive and variably structured city models. However, there are restrictions regarding the realism and variation of the results.