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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

Development and Implementation of an Algorithm for the Automatic Computation of Layouts for UML2.0 Class Diagrams

Schrepfer, Matthias January 2008 (has links)
<p>Reverse Engineering of software is a complex task. It is supported by various analyses and the computation of certain software quality metrics. To get an overview of the structure of the analysed software it is often necessary to visualize the relations between different components of software.</p><p>The VizzAnalyzer tool was developed for these purposes and allows visualizing the internal structure of software systems as UML2.0 class diagrams. The existing Eclipse-based visualization plug-in does not allow to automatically lay out the computed graph. Applying the layout manually is not feasible for larger graphs. A proper layout is needed to understand the provided information intuitively and the usefulness of the visualization is, on top of that, strongly connected to its layout.</p><p>In this thesis, we first state requirements for the development and implementation process of a suitable layout algorithm. We further describe the development, design, and implementation of the Sugiyama layout algorithm into the existing Eclipse-based visualization plug-in. We add these new functionalities to be able to automatically compute a layout for given UML2.0 class diagrams achieving a proper Sugiyama layout for this type of diagrams.</p><p>At the end of this thesis, we compare the results achieved by the implemented algorithm with the results achieved by yEd given the same diagrams as input.</p>
2

Development and Implementation of an Algorithm for the Automatic Computation of Layouts for UML2.0 Class Diagrams

Schrepfer, Matthias January 2008 (has links)
Reverse Engineering of software is a complex task. It is supported by various analyses and the computation of certain software quality metrics. To get an overview of the structure of the analysed software it is often necessary to visualize the relations between different components of software. The VizzAnalyzer tool was developed for these purposes and allows visualizing the internal structure of software systems as UML2.0 class diagrams. The existing Eclipse-based visualization plug-in does not allow to automatically lay out the computed graph. Applying the layout manually is not feasible for larger graphs. A proper layout is needed to understand the provided information intuitively and the usefulness of the visualization is, on top of that, strongly connected to its layout. In this thesis, we first state requirements for the development and implementation process of a suitable layout algorithm. We further describe the development, design, and implementation of the Sugiyama layout algorithm into the existing Eclipse-based visualization plug-in. We add these new functionalities to be able to automatically compute a layout for given UML2.0 class diagrams achieving a proper Sugiyama layout for this type of diagrams. At the end of this thesis, we compare the results achieved by the implemented algorithm with the results achieved by yEd given the same diagrams as input.
3

Evaluation and Improvement of a 2D UML Class Diagram Layout Algorithm

Schrepfer, Matthias January 2009 (has links)
<p> </p><p>Measuring the quality of software is a complex task. Various analyses and computations of software quality metrics support this process. For certain investigations it is helpful to visualize the relations between different components of software in order to check quality aspects. The VizzAnalyzer tool was developed for these purposes and allows the visualization of software systems as UML2.0 class diagrams. The visualization plug-in lays out the internal structure and ensures a high readability of the layouts.</p><p>In this thesis the layout algorithm embedded in the plug-in is optimized to increase its performance and the readability of layouts computed. The interaction with other applications is an important aspect. The current visualization plug-in is extended to meet the requirements of the Quick Orientation Viewer and to support future applications. The optimizations and extensions are further addressed to enhance the usability and the functions provided by the layout algorithm.</p><p> </p>
4

Evaluation and Improvement of a 2D UML Class Diagram Layout Algorithm

Schrepfer, Matthias January 2009 (has links)
Measuring the quality of software is a complex task. Various analyses and computations of software quality metrics support this process. For certain investigations it is helpful to visualize the relations between different components of software in order to check quality aspects. The VizzAnalyzer tool was developed for these purposes and allows the visualization of software systems as UML2.0 class diagrams. The visualization plug-in lays out the internal structure and ensures a high readability of the layouts. In this thesis the layout algorithm embedded in the plug-in is optimized to increase its performance and the readability of layouts computed. The interaction with other applications is an important aspect. The current visualization plug-in is extended to meet the requirements of the Quick Orientation Viewer and to support future applications. The optimizations and extensions are further addressed to enhance the usability and the functions provided by the layout algorithm.
5

Utilisation de la visualisation interactive pour l’analyse des dépendances dans les logiciels

Bouvier, Simon 08 1900 (has links)
La compréhension de la structure d’un logiciel est une première étape importante dans la résolution de tâches d’analyse et de maintenance sur celui-ci. En plus des liens définis par la hiérarchie, il existe un autre type de liens entre les éléments du logiciel que nous appelons liens d’adjacence. Une compréhension complète d’un logiciel doit donc tenir compte de tous ces types de liens. Les outils de visualisation sont en général efficaces pour aider un développeur dans sa compréhension d’un logiciel en lui présentant l’information sous forme claire et concise. Cependant, la visualisation simultanée des liens hiérarchiques et d’adjacence peut donner lieu à beaucoup d’encombrement visuel, rendant ainsi ces visualisations peu efficaces pour fournir de l’information utile sur ces liens. Nous proposons dans ce mémoire un outil de visualisation 3D qui permet de représenter à la fois la structure hiérarchique d’un logiciel et les liens d’adjacence existant entre ses éléments. Notre outil utilise trois types de placements différents pour représenter la hiérarchie. Chacun peut supporter l’affichage des liens d’adjacence de manière efficace. Pour représenter les liens d’adjacence, nous proposons une version 3D de la méthode des Hierarchical Edge Bundles. Nous utilisons également un algorithme métaheuristique pour améliorer le placement afin de réduire davantage l’encombrement visuel dans les liens d’adjacence. D’autre part, notre outil offre un ensemble de possibilités d’interaction permettant à un usager de naviguer à travers l’information offerte par notre visualisation. Nos contributions ont été évaluées avec succès sur des systèmes logiciels de grande taille. / Understanding the structure of software is an important first step in solving tasks of analysis and maintenance on it. However, in addition to the links defined by the hierarchy, there exists another type of links between elements of software that are called adjacency links. A complete understanding of software must take account of all these types of links. Visualization tools are generally effective in helping a developer in his understanding of software by presenting the information in a clear and concise manner. However, viewing these two types of links generate in general a lot of visual clutter, making these visualizations inefficient to provide useful information on these links. We propose in this M.Sc. thesis a 3D visualization tool that can represent both the hierarchical structure of an application and the adjacency relationships between its elements. Our tool uses three different types of layout to represent the hierarchy. Each layout can support efficiently the display of adjacency links. To represent adjacency links, we propose a 3D version of the Hierarchical Edge Bundles algorithm. We also use a metaheuristic algorithm to improve our layouts to further reduce visual clutter in the adjacency links. Moreover, our tool provides a set of interaction possibilities that allows a user to navigate through the information provided by our visualization. Our contributions have been evaluated successfully on large software systems.
6

Utilisation de la visualisation interactive pour l’analyse des dépendances dans les logiciels

Bouvier, Simon 08 1900 (has links)
La compréhension de la structure d’un logiciel est une première étape importante dans la résolution de tâches d’analyse et de maintenance sur celui-ci. En plus des liens définis par la hiérarchie, il existe un autre type de liens entre les éléments du logiciel que nous appelons liens d’adjacence. Une compréhension complète d’un logiciel doit donc tenir compte de tous ces types de liens. Les outils de visualisation sont en général efficaces pour aider un développeur dans sa compréhension d’un logiciel en lui présentant l’information sous forme claire et concise. Cependant, la visualisation simultanée des liens hiérarchiques et d’adjacence peut donner lieu à beaucoup d’encombrement visuel, rendant ainsi ces visualisations peu efficaces pour fournir de l’information utile sur ces liens. Nous proposons dans ce mémoire un outil de visualisation 3D qui permet de représenter à la fois la structure hiérarchique d’un logiciel et les liens d’adjacence existant entre ses éléments. Notre outil utilise trois types de placements différents pour représenter la hiérarchie. Chacun peut supporter l’affichage des liens d’adjacence de manière efficace. Pour représenter les liens d’adjacence, nous proposons une version 3D de la méthode des Hierarchical Edge Bundles. Nous utilisons également un algorithme métaheuristique pour améliorer le placement afin de réduire davantage l’encombrement visuel dans les liens d’adjacence. D’autre part, notre outil offre un ensemble de possibilités d’interaction permettant à un usager de naviguer à travers l’information offerte par notre visualisation. Nos contributions ont été évaluées avec succès sur des systèmes logiciels de grande taille. / Understanding the structure of software is an important first step in solving tasks of analysis and maintenance on it. However, in addition to the links defined by the hierarchy, there exists another type of links between elements of software that are called adjacency links. A complete understanding of software must take account of all these types of links. Visualization tools are generally effective in helping a developer in his understanding of software by presenting the information in a clear and concise manner. However, viewing these two types of links generate in general a lot of visual clutter, making these visualizations inefficient to provide useful information on these links. We propose in this M.Sc. thesis a 3D visualization tool that can represent both the hierarchical structure of an application and the adjacency relationships between its elements. Our tool uses three different types of layout to represent the hierarchy. Each layout can support efficiently the display of adjacency links. To represent adjacency links, we propose a 3D version of the Hierarchical Edge Bundles algorithm. We also use a metaheuristic algorithm to improve our layouts to further reduce visual clutter in the adjacency links. Moreover, our tool provides a set of interaction possibilities that allows a user to navigate through the information provided by our visualization. Our contributions have been evaluated successfully on large software systems.

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