@inproceedings{6670, author = {{Bendfeld, Jörg and Balluff, Stefan and Krauter, Stefan}}, booktitle = {{Proceedings of the 10th Conference on Sustainable Development of Energy, Water and Enviroment Systems - SDEWES}}, title = {{{Offshore wind energy development based on Merra data}}}, year = {{2015}}, } @inproceedings{6671, author = {{Bendfeld, Jörg and Balluff, Stefan and Krauter, Stefan}}, booktitle = {{Proceedings of the 10th Conference on Sustainable Development of Energy, Water and Enviroment Systems - SDEWES}}, title = {{{Offshore metocean station for energy purposes}}}, year = {{2015}}, } @inproceedings{6672, author = {{Bendfeld, Jörg and Balluff, Stefan and Krauter, Stefan}}, booktitle = {{EWEA Forecasting 2015 Technology Workshop}}, location = {{Leuven, Belgium}}, title = {{{Short term wind and energy prediction for offshore wind farms using neural networks}}}, year = {{2015}}, } @inproceedings{6726, author = {{Czerwinski, Wojciech and Martens, Wim and van Rooijen, Lorijn and Zeitoun, Marc}}, booktitle = {{Fundamentals of Computation Theory - 20th International Symposium, (FCT) 2015, Gdańsk, Poland, August 17-19, 2015, Proceedings}}, pages = {{173--185}}, title = {{{A Note on Decidable Separability by Piecewise Testable Languages}}}, doi = {{10.1007/978-3-319-22177-9\_14}}, year = {{2015}}, } @article{6769, author = {{Tönnies, Merle}}, journal = {{Dramatic Minds. Performance, Cognition, and the Representation of Interiority}}, pages = {{243--260}}, publisher = {{Peter Lang}}, title = {{{Between Authenticity and Objectification: Narrating the Self in Contemporary British Drama}}}, year = {{2015}}, } @misc{694, author = {{Stilow, Georg}}, publisher = {{Universität Paderborn}}, title = {{{Mobile Agenten in Netzwerken: Analyse von Hotspots}}}, year = {{2015}}, } @inbook{6952, author = {{Bouyraaman, Yassin and Bendfeld, Jörg and Breymann, Philipp and Krauter, Stefan}}, booktitle = {{Renewable Energy in the Service of Mankind Vol I}}, isbn = {{9783319177762}}, pages = {{845--854}}, publisher = {{Springer International Publishing}}, title = {{{Integration of Wind Energy in Power System—Modelling of a Market Oriented Energy Concept}}}, doi = {{10.1007/978-3-319-17777-9_76}}, year = {{2015}}, } @book{6978, editor = {{Kremer, H.-Hugo and Beutner, Marc}}, title = {{{Individuelle Kompetenzentwicklungswege: Bildungsarbeit in einer dualisierten Ausbildungsvorbereitung. Ergebnisse und Reflexionen aus dem Forschungs- und Entwicklungsprojekt InBig}}}, year = {{2015}}, } @unpublished{16449, abstract = {{We consider the following variant of the two dimensional gathering problem for swarms of robots: Given a swarm of $n$ indistinguishable, point shaped robots on a two dimensional grid. Initially, the robots form a closed chain on the grid and must keep this connectivity during the whole process of their gathering. Connectivity means, that neighboring robots of the chain need to be positioned at the same or neighboring points of the grid. In our model, gathering means to keep shortening the chain until the robots are located inside a $2\times 2$ subgrid. Our model is completely local (no global control, no global coordinates, no compass, no global communication or vision, \ldots). Each robot can only see its next constant number of left and right neighbors on the chain. This fixed constant is called the \emph{viewing path length}. All its operations and detections are restricted to this constant number of robots. Other robots, even if located at neighboring or the same grid point cannot be detected. Only based on the relative positions of its detectable chain neighbors, a robot can decide to obtain a certain state. Based on this state and their local knowledge, the robots do local modifications to the chain by moving to neighboring grid points without breaking the chain. These modifications are performed without the knowledge whether they lead to a global progress or not. We assume the fully synchronous $\mathcal{FSYNC}$ model. For this problem, we present a gathering algorithm which needs linear time. This result generalizes the result from \cite{hopper}, where an open chain with specified distinguishable (and fixed) endpoints is considered.}}, author = {{Abshoff, Sebastian and Cord-Landwehr, Andreas and Fischer, Matthias and Jung, Daniel and Meyer auf der Heide, Friedhelm}}, booktitle = {{arXiv:1510.05454}}, title = {{{Gathering a Closed Chain of Robots on a Grid}}}, year = {{2015}}, } @unpublished{16452, abstract = {{We consider the problem of dominating set-based virtual backbone used for routing in asymmetric wireless ad-hoc networks. These networks have non-uniform transmission ranges and are modeled using the well-established disk graphs. The corresponding graph theoretic problem seeks a strongly connected dominating-absorbent set of minimum cardinality in a digraph. A subset of nodes in a digraph is a strongly connected dominating-absorbent set if the subgraph induced by these nodes is strongly connected and each node in the graph is either in the set or has both an in-neighbor and an out-neighbor in it. Distributed algorithms for this problem are of practical significance due to the dynamic nature of ad-hoc networks. We present a first distributed approximation algorithm, with a constant approximation factor and O(Diam) running time, where Diam is the diameter of the graph. Moreover we present a simple heuristic algorithm and conduct an extensive simulation study showing that our heuristic outperforms previously known approaches for the problem.}}, author = {{Abu-Khzam, Faisal N. and Markarian, Christine and Meyer auf der Heide, Friedhelm and Schubert, Michael}}, booktitle = {{arXiv:1510.01866}}, title = {{{Approximation and Heuristic Algorithms for Computing Backbones in Asymmetric Ad-Hoc Networks}}}, year = {{2015}}, }