The last decade has seen an increasing demand from the industrial field of computerized visual inspection. Applications rapidly become more complex and often with more demanding real time constraints. However, from 2004 onwards the clock frequency of CPUs has not increased significantly. Computer Vision applications have an increasing demand for more processing power but are limited by the performance capabilities of sequential processor architectures. The only way to get more performance using commodity hardware, like multi-core processors and graphics cards, is to go for parallel programming. This article focuses on the practical question: How can the processing time for vision algorithms be improved, by parallelization, in an economical way and execute them on multiple platforms?
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Author Supplied: In the last decades, architecture has emerged as a discipline in the domain of Information Technology (IT). A well-accepted definition of architecture is from ISO/IEC 42010: "The fundamental organization of a system, embodied in its components, their relationships to each other and the environment, and the principles governing its design and evolution." Currently, many levels and types of architecture in the domain of IT have been defined. We have scoped our work to two types of architecture: enterprise architecture and software architecture. IT architecture work is demanding and challenging and includes, inter alia, identifying architectural significant requirements (functional and non-functional), designing and selecting solutions for these requirements, and ensuring that the solutions are implemented according to the architectural design. To reflect on the quality of architecture work, we have taken ISO/IEC 8402 as a starting point. It defines quality as "the totality of characteristics of an entity that bear on its ability to satisfy stated requirements". We consider architecture work to be of high quality, when it is effective; when it answers stated requirements. Although IT Architecture has been introduced in many organizations, the elaboration does not always proceed without problems. In the domain of enterprise architecture, most practices are still in the early stages of maturity with, for example, low scores on the focus areas ‘Development of architecture’ and ‘Monitoring’ (of the implementation activities). In the domain of software architecture, problems of the same kind are observed. For instance, architecture designs are frequently poor and incomplete, while architecture compliance checking is performed in practice on a limited scale only. With our work, we intend to contribute to the advancement of architecture in the domain of IT and the effectiveness of architecture work by means of the development and improvement of supporting instruments and tools. In line with this intention, the main research question of this thesis is: How can the effectiveness of IT architecture work be evaluated and improved?
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Twirre is a new architecture for mini-UAV platforms designed for autonomous flight in both GPS-enabled and GPS-deprived applications. The architecture consists of low-cost hardware and software components. High-level control software enables autonomous operation. Exchanging or upgrading hardware components is straightforward and the architecture is an excellent starting point for building low-cost autonomous mini-UAVs for a variety of applications. Experiments with an implementation of the architecture are in development, and preliminary results demonstrate accurate indoor navigation
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The specific objective of HyScaling is to achieve a 25-30% cost reduction for levelized cost of hydrogen. This cost reduction will be achieved in 2030 when the HyScaling innovations have been fully implemented. HyScaling develops novel hardware (such as stacks & cell components), low-cost manufacturing processes, optimized integrated system designs and advanced operating and control strategies. In addition to the goal of accelerating implementation of hydrogen to decarbonize energy-intensive industry, HyScaling is built around industrial partners who are aiming to build a business on the HyScaling innovations. These include novel components for electrolysers (from catalysts to membranes, from electrode architectures to novel coatings) as well as electrolyser stacks and systems for different applications. For some innovations (e.g. a coating from IonBond, an electrode design from Veco) the consortium aims at starting commercialisation before the end of the program. A unique characteristic of the HyScaling program is the orientation on Use Cases. In addition to partners representing the Dutch manufacturing industry, end-users and technology providers are partner in the consortium. This enables the consortium to develop the electrolyser technology specifically for different applications. In order to be able to come to an assessment of the market for electrolysers and components, the use cases also include decentralized energy systems.Projectpartners:Nouryon, Tejin, Danieli Corus, VDL, Hauzer, VECO, lonbond, Fluor, Frames, Magneto, VONK, Borit, Delft IMP, ZEF, MTSA, SALD, Dotx control, Hydron Energy, MX, Polymers, VSL, Fraunhofer IPT, TNO, TU Delft, TU Eindhoven, ISPT, FMC.
