@inproceedings{22109, author = {{Reschetnik, W. and Grylls, R. and Bauer, B. and Richard, H.A. and Kullmer, G.}}, title = {{{Fatigue Life Manipulation of SLM Parts}}}, year = {{2016}}, } @inproceedings{22128, author = {{Brüggemann, J.P. and Riemer, A. and Reschetnik, W. and Aydinöz, M.E. and Kullmer, G. and Richard, H.A. and Schaper, M.}}, booktitle = {{DVM - Tagung - Additiv gefertigte Bauteile und Strukturen, Deutscher Verband für Materialforschung und -prüfung e.V.}}, pages = {{101--112}}, title = {{{Optimierung von Fahrradtretkurbeln mittels additiver Fertigung}}}, year = {{2016}}, } @inproceedings{22130, author = {{Reschetnik, W. and Brüggemann, J.P. and Aydinöz, M.E. and Kullmer, G. and Richard, H.A. and Schaper, M.}}, booktitle = {{DVM - Tagung - Additiv gefertigte Bauteile und Strukturen, Deutscher Verband für Materialforschung und -prüfung e.V.}}, pages = {{131--140}}, title = {{{Lebensdauerbeeinflussung durch Additive Fertigung}}}, year = {{2016}}, } @inproceedings{22132, author = {{Riemer, A. and Leuders, L. and Kullmer, G. and Richard, H.A.}}, booktitle = {{DVM - Tagung - Additiv gefertigte Bauteile und Strukturen, Deutscher Verband für Materialforschung und -prüfung e.V.}}, pages = {{161--174}}, title = {{{Materialkennwerte lasergeschmolzener Werkstoffe}}}, year = {{2016}}, } @inproceedings{22146, abstract = {{manufacturing in electrical engineering applications.}}, author = {{Reschetnik, W. and Brüggemann, J.P. and Aydinöz, M.E. and Grydin, O. and Hoyer, K.P. and Kullmer, G. and Richard, H.A.}}, booktitle = {{Procedia Structural Integrity}}, pages = {{3040--3048}}, title = {{{Fatigue crack growth behavior and mechanical properties of additively processed EN AW-7075 aluminium alloy}}}, year = {{2016}}, } @inproceedings{22149, author = {{Riemer, A. and Richard, H.A.}}, booktitle = {{Procedia Structural Integrity}}, pages = {{1229--1236}}, title = {{{Crack Propagation in Additive Manufactured Materials and Structures}}}, year = {{2016}}, } @inproceedings{22180, abstract = {{The implementation of lattice structures into additive manufactured parts is an important method to decrease part weight maintaining a high specific payload. However, the manufacturability of lattice structures and mechanical properties for polymer laser sintering are quite unknown yet. To examine the manufacturability, sandwich structures with different cell types, cell sizes and lattice bar widths were designed, manufactured and evaluated. A decisive criterion is for example a sufficient powder removal. In a second step, manufacturable structures were analyzed using four-point-bending tests. Experimental data is compared to the density of the lattice structures and allows for a direct comparison of different cell types with varied geometrical attributes. The results of this work are guidelines for the design and dimensioning of laser sintered lattice structures.}}, author = {{Josupeit, Stefan and Delfs, Patrick and Menge, Dennis and Schmid, Hans-Joachim}}, booktitle = {{27th Annual International Solid Freeform Fabrication Symposium }}, pages = {{2077--2086}}, title = {{{Manufacturability and Mechanical Characterization of Laser Sintered Lattice Structures}}}, doi = {{http://utw10945.utweb.utexas.edu/sites/default/files/2016/166-Josupeit.pdf}}, volume = {{27}}, year = {{2016}}, } @article{22185, abstract = {{The layered structure of Additive Manufacturing processes results in a stair- stepping effect of the surface topographies. In general, the impact of this effect strongly depends on the build angle of a surface, whereas the overall surface roughness is additionally caused by the resolution of the specific AM process. The aim of this work is the prediction of the surface quality in dependence of the building orientation of a part. These results can finally be used to optimize the orientation to get a desired surface quality. As not all parts of the component surface are equally important, a preselection of areas can be used to improve the overall surface quality of relevant areas. The model uses the digital AMF format of a part. Each triangle is assigned with a roughness value and by testing different orientations the best one can be found. This approach needs a database for the surface qualities. This must be done separately for each Additive Manufacturing process and is shown exemplarily with a surface topography simulation for the laser sintering process.}}, author = {{Delfs, Patrick and Tows, Marcel and Schmid, Hans-Joachim}}, isbn = {{2214-8604}}, journal = {{Additive Manufacturing}}, number = {{12, Part B}}, pages = {{214--320}}, publisher = {{Elsevier}}, title = {{{Optimized build orientation of additive manufactured parts for improved surface quality and build time}}}, doi = {{10.1016/j.addma.2016.06.003}}, volume = {{2}}, year = {{2016}}, } @inproceedings{22190, author = {{Delfs, Patrick and Schmid, Hans-Joachim}}, booktitle = {{Fraunhofer Direct Digital Manufacturing Conference}}, isbn = {{978-3-8396-1001-5}}, pages = {{411--414}}, title = {{{Extended Analysis of the Surface Topography of Laser Sintered Polymer Parts }}}, doi = {{https://www.bookshop.fraunhofer.de/buch/fraunhofer-direct-digital-manufacturing-conference-ddmc-2016/245111#}}, volume = {{3}}, year = {{2016}}, } @inproceedings{22194, author = {{Josupeit, Stefan and Schmid, Hans-Joachim}}, booktitle = {{International Congress on Particle Technology (PARTEC) }}, title = {{{Thermal properties of polyamide 12 powder for application in laser sintering}}}, year = {{2016}}, } @article{222, abstract = {{Virtual field programmable gate arrays (FPGA) are overlay architectures realized on top of physical FPGAs. They are proposed to enhance or abstract away from the physical FPGA for experimenting with novel architectures and design tool flows. In this paper, we present an embedding of a ZUMA-based virtual FPGA fabric into a complete configurable system-on-chip. Such an embedding is required to fully harness the potential of virtual FPGAs, in particular to give the virtual circuits access to main memory and operating system services, and to enable a concurrent operation of virtualized and non-virtualized circuitry. We discuss our extension to ZUMA and its embedding into the ReconOS operating system for hardware/software systems. Furthermore, we present an open source tool flow to synthesize configurations for the virtual FPGA, along with an analysis of the area and delay overheads involved.}}, author = {{Wiersema, Tobias and Bockhorn, Arne and Platzner, Marco}}, journal = {{Computers & Electrical Engineering}}, pages = {{112----122}}, publisher = {{Elsevier}}, title = {{{An Architecture and Design Tool Flow for Embedding a Virtual FPGA into a Reconfigurable System-on-Chip}}}, doi = {{10.1016/j.compeleceng.2016.04.005}}, year = {{2016}}, } @inproceedings{22200, abstract = {{In the polymer laser sinter process, part quality depends on many influencing factors along the process chain. For application of the technology in series production and an integration of laser sintered parts into a technical environment, the dimensional accuracy of parts has to be taken into account. Therefore, occuring deviatons and their scattering have to be reduced and homogenized based on process parameters and build job layout. In this work, the dimensional accuracy of laser sintered parts is analyzed for varied parameter values. Influences of different process and geometrical build job parameters on dimensional deviatons are figured out. The experimental results allow an evaluation of more and less important influences. Finally, measures are deduced to reduce and homogenize dimensional deviations.}}, author = {{Josupeit, Stefan and Delfs, Patrick and Lieneke, Tobias and Adam, Guido and Gessler, Monika and Pfisterer, H. and Schmid, Hans-Joachim}}, booktitle = {{Rapid Tech - International Trade Show & Conference for Additive Manufacturing }}, isbn = {{978-3-446-45060-8}}, pages = {{107--120}}, title = {{{Dimensional accuracy of polymer laser sintered parts: Influences and measures}}}, doi = {{10.3139/9783446450608.009}}, year = {{2016}}, } @misc{223, abstract = {{We consider the problem of aggregation in overlay networks. We use a synchronous time model in which each node has polylogarithmic memory and can send at most a polylogarithmic number of messages per round. We investigate how to quickly compute the result of an aggregate functionf over elements that are distributed among the nodes of the network such that the result is eventually known by a selected root node. We show how to compute distributive aggregate functions such as SUM, MAX, and OR in time $O(\log n / \log\log n)$ using a tree that is created in a pre-processing phase. If only a polylogarithmic number of data items need to be aggregated, we show how to compute the result in time $O(\sqrt{\log n / \log\log n})$. Furthermore, we show how to compute holistic aggregate functions such as DISTINCT, SMALLEST(k) and MODE(k) in time $O(\log n / \log\log n)$. Finally, we show a lower bound of $\Omega(\sqrt{\log n / \log\log n})$ for deterministic algorithms that compute any of the aggregate functions in the scope of the thesis.}}, author = {{Hinnenthal, Kristian}}, publisher = {{Universität Paderborn}}, title = {{{Aggregation in Overlay Networks}}}, year = {{2016}}, } @inproceedings{224, abstract = {{In modern software development, paradigms like component-based software engineering (CBSE) and service-oriented architectures (SOA) emphasize the construction of large software systems out of existing components or services. Therein, a service is a self-contained piece of software, which adheres to a specified interface. In a model-based software design, this interface constitutes our sole knowledge of the service at design time, while service implementations are not available. Therefore, correctness checks or detection of potential errors in service compositions has to be carried out without the possibility of executing services. This challenges the usage of standard software error localization techniques for service compositions. In this paper, we review state-of-the-art approaches for error localization of software and discuss their applicability to service compositions.}}, author = {{Krämer, Julia and Wehrheim, Heike}}, booktitle = {{Proceedings of the 5th European Conference on Service-Oriented and Cloud Computing (ESOCC 2016)}}, pages = {{248----262}}, title = {{{A short survey on using software error localization for service compositions}}}, doi = {{10.1007/978-3-319-44482-6_16}}, year = {{2016}}, } @inproceedings{22403, abstract = {{Additive manufacturing processes offer great freedom in the design of components. This enables a high level of function integration. Also in terms of vibration damping, additive manufacturing yields opportunities for the selective implementation of damping functions due to their characteristics. In powder-based processes the disperse support material can be kept inside the cavities of the structure. This powder material can act as a particle damper. Due to the freedoms in design, the damping behavior can be adjusted selectively by varying the geometrical features of the cavities. Within this paper, investigations on the damping behavior of additive manufactured parts regarding free bending vibrations are focused.}}, author = {{Künneke, Thomas and Zimmer, Detmar}}, booktitle = {{DVM Tagung - Additiv gefertigte Bauteile und Strukturen}}, pages = {{151--160}}, title = {{{Funktionsintegration additiv gefertigter Dämpfungsstrukturen bei Biegeschwingungen}}}, year = {{2016}}, } @inproceedings{22404, abstract = {{Additive Manufacturing (AM), also known as 3D printing, is a relatively new technology which enables the toolless production of components and entire assemblies directly from a CAD file. Today, the technology is still not widely used in industrial production. It is mainly limited to special applications, although it shows great potential. In this paper, first approaches are shown to apply AM to the production of rotors for permanent magnet synchronous machines (PMSM). The possibilities of a lightweight design with a low moment of inertia as well as the influence on the magnetic anisotropy for an improved sensorless control of PMSM are pointed out. The results clearly demonstrate the great potential of additive manufacturing in electrical engineering applications.}}, author = {{Lammers, Stefan and Adam, Guido and Schmid, Hans-Joachim and Mrozek, Rafael and Oberacker, Rainer and Hoffmann, Michael and Quattrone, Francesco and Ponick, Bernd}}, booktitle = {{EDPC 2016}}, isbn = {{978-1-5090-2908-2}}, title = {{{Additive Manufacturing of a Lightweight Rotor for a Permanent Magnet Synchronous Machine}}}, doi = {{10.1109/EDPC.2016.7851312}}, year = {{2016}}, } @inproceedings{22408, author = {{Josupeit, Stefan and Delfs, Patrick and Lieneke, Tobias and Schmid, Hans-Joachim}}, booktitle = {{27th Annual International Solid Freeform Fabrication Symposium }}, title = {{{Influences on the dimensional Accuracy of Laser Sintered Parts along the Process Chain}}}, year = {{2016}}, } @inproceedings{22409, author = {{Lieneke, Tobias and de Groot, Stefan and Adam, Guido and Zimmer, Detmar}}, booktitle = {{ASPE 2016 Summer Topical Meeting}}, pages = {{S.9--15}}, title = {{{Dimensional tolerances for additive manufacturing: Experimental investigation of manufacturing accuracy for selective laser melting}}}, year = {{2016}}, } @inproceedings{22410, author = {{Knoop, Frederick and Lieneke, Tobias and Schoeppner, Volker}}, booktitle = {{ASPE Spring Topical Meeting}}, pages = {{S.3--8}}, title = {{{Reproducibility of the Dimensional Accuracy - Investigations for FDM}}}, doi = {{10.3139/9783446454606.004}}, year = {{2016}}, } @inproceedings{22411, author = {{Knoop, Frederick and Lieneke, Tobias and Schoeppner, Volker}}, booktitle = {{Summer Topical Meeting 2016}}, title = {{{Reproducibility of the Dimensional Accuracy - Investigations for FDM}}}, year = {{2016}}, }