05 Fakultät Informatik, Elektrotechnik und Informationstechnik

Permanent URI for this collectionhttps://elib.uni-stuttgart.de/handle/11682/6

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Institute: search.filters.UBSInstitut.Institut für Rechnergestützte IngenieursystemePublication Type: search.filters.UBSTyp.Dissertation

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    A framework for similarity recognition of CAD models in respect to PLM optimization
    (2022) Zehtaban, Leila; Roller, Dieter (Univ.-Prof. Hon.-Prof. Dr.)
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    3D printing-as-a-service for collaborative engineering
    (2017) Baumann, Felix W.; Roller, Dieter (Univ.-Prof. Hon.-Prof. Dr.)
    3D printing or Additive Manufacturing (AM) are utilised as umbrella terms to denote a variety of technologies to manufacture or create a physical object based on a digital model. Commonly, these technologies create the objects by adding, fusing or melting a raw material in a layer-wise fashion. Apart from the 3D printer itself, no specialised tools are required to create almost any shape or form imaginable and designable. The possibilities of these technologies of these technologies are plentiful and cover the ability to manufacture every object, rapidly, locally and cost-efficiently without wasted resources and material. Objects can be created to specific forms to perform as perfectly fitting functions without consideration of the assembly process. To further the advance the availability and applicability of 3D printing, this thesis identifies the problems that currently exist and attempts to solve them. During the 3D printing process, data (i. e., files) must be converted from their original representation, e. g., CAD file, to the machine instructions for a specific 3D printer. During this process, information is lost, and other information is added. Traceability is lacking in 3D printing. The actual 3D printing can require a long period of time to complete, during which errors can occur. In 3D printing, these errors are often non-recoverable or reversible, which results in wasted material and time. In addition to the lack of closed-loop control systems for 3D printers, careful planning and preparation are required to avoid these costly misprints. 3D printers are usually located remotely from users, due to health and safety considerations, special placement requirements or out of comfort. Remotely placed equipment is impractical to monitor in person; however, such monitoring is essential. Especially considering the proneness of 3D printing to errors and the implications of this as described previously. Utilisation of 3D printers is an issue, especially with expensive 3D printers. As there are a number of differing 3D printing technologies available, having the required 3D printer, might be problematic. 3D printers are equipped with a variety of interfaces, depending on the make and model. These differing interfaces, both hard- and software, hinder the integration of different 3D printers into consistent systems. There exists no proper and complete ontology or resource description schema or mechanism that covers all the different 3D printing technologies. Such a resource description mechanism is essential for the automated scheduling in services or systems. In 3D printing services the selection and matching of appropriate and suitable 3D printers is essential, as not all 3D printing technologies are able to perform on all materials or are able to create certain object features, such as thin walls or hollow forms. The need for companies to sell digital models for AM will increase in scenarios where replacement or customised parts are 3D printed by consumers at home or in local manufacturing centres. Furthermore, requirements to safeguard these digital models will increase to avoid a repetition of the problems from the music industry, e. g., Napster. Replication and ‘theft’ of these models are uncontrollable in the current situation. In a service oriented deployment, or in scenarios where the utilisation is high, estimations of the 3D printing time are required to be available. Common 3D printing time estimations are inaccurate, which hinder the application of scheduling. The complete and comprehensive understanding of the complexity of an object is discordant, especially in the domain of AM. This understanding is required to both support the design of objects for AM and match appropriate manufacturing resources to certain objects. Quality in AM and FDM have been incompletely researched. The quality in general is increased with maturity of the technology; however, research on the quality achievable with consumer-grade 3D printers is lacking. Furthermore, cost-sensitive measurement methods for quality assessment are expandable. This thesis presents the structured design and implementation of a 3D printing service with associated contributions that provide solutions to particular problems present in the AM domain. The 3D printing service is the overarching component of this thesis and provides the platform for the other contributions with the intention to establish an online, cloud-based 3D printing service for use in end-user and professional settings with a focus on collaboration and cooperation.
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    A viable architecture for autonomic management of distributed software components
    (2010) Stoyanov, Emil; Roller, Dieter (Prof.Dr.)
    Autonomic Computing is a brand of system design approaches which enable IT systems with self-management capabilities such as self-configuration, self-healing, self-protection and self-optimization. Although the field of distributed system management has achieved considerable advances, building autonomic management solutions for heterogeneous component-based systems presents five major challenges. First, component deployment and its management gets difficult with the growth of the system, because of the variety of component models with their own specifics. Second, each component framework provides its own way and interface for management creating redundancy and variety of management routines. Third, software components evolve separately which introduces problems with compatibility upon system upgrade. Forth, there are remote dependencies which are difficult to tack and this may cause unpredicted inconsistency of the system after component update. Finally, the integration of a management sub-system influences the overall system complexity by making it dependent on interfaces and functionality of the management module. This thesis introduces an architectural approach which addresses these challenges. An organizational meta-model represents the architectural constraints for encapsulation of software components and defines requirements for feedback loops adapted from the Viable System Model for software components. It enables modeling of viable organization and communication management on the levels of component deployment and runtime operations. The autonomic management architecture consists of modules that facilitate monitoring component states, an operation manager that allows inspection of distributed dependencies by utilizing the notion of the managed communication channel. Its design conforms with the recommendations of the proposed organizational model. A channel management middleware implements the necessary functionality for establishing communication channels and provides interfaces for integration of autonomic managers which follow the requirements of the organizational and communication model. A prototype of the middleware has been developed to implement the architectural approach for real-world scenarios in two separate domains - Smart Home and Distributed Product Development Support Systems. It has demonstrated the usability of the architecture by satisfying the management requirements of these domains and addressing the management challenges.
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    3D digital analysis of mammographic composition
    (2009) Lampasona, Constanza; Roller, Dieter (Prof. Dr.)
    Breast cancer represents the most frequent cancer within women. Besides clinical examination and self-examination, breast imaging plays a very important role in detecting breast cancer before tumors turn clinically visible. The mammography, a radiograph of the breast, is the most widespread test for the early detection of breast cancer. The images obtained through mammography are known as mammograms and they visualize the breast structure. The woman breast consists of fibroglandular and fatty tissue. Increased mammographic breast density, an increase of fibroglandular tissue, is a factor that influences the risk of becoming affected with breast cancer. Computer-based image analysis could help to find such abnormal changes in the breast tissues from digital mammograms. Full-field digital mammograms are acquired using an electronic detector and they are stored using the DICOM standard file format. In this thesis we first describe the image acquisition process, the DICOM file format as well as the conventional and digital mammography, together with its advantages for computer-based image processing. Former image processing methods and their application into mammograms were also studied. These methods include the measurement of area and volumetric mammographic breast density, the segmentation and the registration of mammograms and methods that could be applied to visualize the breast density. Based on the knowledge on the acquisition process, the DICOM file format and the former methods, computer-based image analysis methods were developed during this research project. All the methods were implemented in a software prototype to test them. The software architecture of the prototype is also shown in this thesis. The main contribution of this work is a new method for the measurement of volumetric breast density. This measurement of volumetric breast density consists in the interpretation of pixels gray levels from full-field digital mammograms to determine which combinations of tissues they represent. In order to be able to compare many images, after performing the measurements, the images are standardized and registered. From the breast composition and its changes, a conclusion could be reached in relation to a suspected cancer or an elevated breast cancer risk. Additionally, some image processing methods were developed to prepare the images for the analysis. These methods segment the mammogram into background, pectoral muscle and breast tissue. The information obtained from the analysis of the mammograms could also be used for the detection of microcalcifications and the skin line or breast border. The mammograms are then graphically shown using different two and three-dimensional views. The last chapters show the results of the computer-based image analysis of the full-filed digital mammograms using the software prototype, conclusions and future work.