@inbook{9672, author = {{Strauß, Sara}}, booktitle = {{Dementia and Subjectivity. Aesthetic, Literary and Philosophical Perspectives}}, editor = {{Ringkamp, Daniela and Strauß, Sara and Süwolto, Leonie}}, publisher = {{Lang}}, title = {{{Introduction}}}, year = {{2017}}, } @inbook{9673, author = {{Strauß, Sara}}, booktitle = {{Presence of the Body: Awareness In and Beyond Experience}}, editor = {{Hofmann, Gert and Zorić , Snježana}}, pages = {{139--153}}, publisher = {{Rodopi}}, title = {{{Neuroethical Reflections on Body and Awareness in Kazuo Ishiguro’s Never Let Me Go and Ian McEwan’s Saturday}}}, year = {{2017}}, } @article{9681, author = {{Volk, Martin F. and Rüter, Christian E. and Santandrea, Matteo and Eigner, Christof and Padberg, Laura and Herrmann, Harald and Silberhorn, Christine and Kip, Detlef}}, issn = {{2159-3930}}, journal = {{Optical Materials Express}}, title = {{{Fabrication of low-loss Rb-exchanged ridge waveguides in z-cut KTiOPO_4}}}, doi = {{10.1364/ome.8.000082}}, year = {{2017}}, } @inproceedings{9682, author = {{Brecht, Benjamin and Lazo-Arjona, O. and Kaczmarek, K. T. and Parker, T. and Ricken, R. and Quiring, V. and Eigner, Christof and Luo, K. H. and Herrmann, Harald and Silberhorn, Christine and Walmsley, I. A.}}, booktitle = {{Frontiers in Optics 2017}}, isbn = {{9781943580330}}, title = {{{A monolithic, doubly-resonant parametric down-conversion source for Caesium Raman memories}}}, doi = {{10.1364/fio.2017.jw4a.3}}, year = {{2017}}, } @article{9684, author = {{Stefszky, M. and Ricken, R. and Eigner, Christof and Quiring, V. and Herrmann, Harald and Silberhorn, Christine}}, issn = {{2331-7019}}, journal = {{Physical Review Applied}}, title = {{{Waveguide Cavity Resonator as a Source of Optical Squeezing}}}, doi = {{10.1103/physrevapplied.7.044026}}, year = {{2017}}, } @article{9685, author = {{Sansoni, Linda and Luo, Kai Hong and Eigner, Christof and Ricken, Raimund and Quiring, Viktor and Herrmann, Harald and Silberhorn, Christine}}, issn = {{2056-6387}}, journal = {{npj Quantum Information}}, title = {{{A two-channel, spectrally degenerate polarization entangled source on chip}}}, doi = {{10.1038/s41534-016-0005-z}}, year = {{2017}}, } @article{9692, author = {{Tönnies, Merle}}, journal = {{Journal of Contemporary Drama in English}}, number = {{1}}, pages = {{156--172}}, title = {{{The Immobility of Power in British Political Theatre after 2000: Absurdist Dystopias}}}, volume = {{5}}, year = {{2017}}, } @inbook{9693, author = {{Tönnies, Merle}}, booktitle = {{Finance, Terror, and Science on Stage. Current Public Concerns in 21st-Century British Drama}}, editor = {{Frank, Kerstin and Lusin, Caroline}}, pages = {{19--39}}, publisher = {{Narr Francke Attempto}}, title = {{{Still/Again 'Political'? New Approaches to Questioning Power in Mike Bartlett's 13 (2011)}}}, volume = {{82}}, year = {{2017}}, } @misc{9696, author = {{Tönnies, Merle}}, booktitle = {{Anglistik. International Journal of English Studies}}, number = {{1}}, pages = {{175--177}}, title = {{{Pope, G.: Reading London's Suburbs}}}, volume = {{28}}, year = {{2017}}, } @inproceedings{97, abstract = {{Bridging the gap between informal, imprecise, and vague user requirements descriptions and precise formalized specifications is the main task of requirements engineering. Techniques such as interviews or story telling are used when requirements engineers try to identify a user's needs. The requirements specification process is typically done in a dialogue between users, domain experts, and requirements engineers. In our research, we aim at automating the specification of requirements. The idea is to distinguish between untrained users and trained users, and to exploit domain knowledge learned from previous runs of our system. We let untrained users provide unstructured natural language descriptions, while we allow trained users to provide examples of behavioral descriptions. In both cases, our goal is to synthesize formal requirements models similar to statecharts. From requirements specification processes with trained users, behavioral ontologies are learned which are later used to support the requirements specification process for untrained users. Our research method is original in combining natural language processing and search-based techniques for the synthesis of requirements specifications. Our work is embedded in a larger project that aims at automating the whole software development and deployment process in envisioned future software service markets.}}, author = {{van Rooijen, Lorijn and Bäumer, Frederik Simon and Platenius, Marie Christin and Geierhos, Michaela and Hamann, Heiko and Engels, Gregor}}, booktitle = {{2017 IEEE 25th International Requirements Engineering Conference Workshops (REW)}}, isbn = {{978-1-5386-3489-9}}, keywords = {{Software, Unified modeling language, Requirements engineering, Ontologies, Search problems, Natural languages}}, location = {{Lisbon, Portugal}}, pages = {{379--385}}, publisher = {{IEEE}}, title = {{{From User Demand to Software Service: Using Machine Learning to Automate the Requirements Specification Process}}}, doi = {{10.1109/REW.2017.26}}, year = {{2017}}, } @book{9712, editor = {{Strauß, Sara and Ringkamp, Daniela and Süwolto, Leonie}}, publisher = {{Lang}}, title = {{{Dementia and Subjectivity. Aesthetic, Literary and Philosophical Perspectives}}}, year = {{2017}}, } @inproceedings{9717, author = {{Strauß, Sara}}, booktitle = {{Narrative and Mental Health}}, location = {{Paderborn}}, title = {{{Fragments of a Life Remembered: Fragmentation and Silences in Dementia Narratives}}}, year = {{2017}}, } @inproceedings{98, abstract = {{Today, modern IT-systems are often an interplay of third-party web services. Developers in their role as requesters integrate existing services of different providers into new IT-systems. Providers use frameworks like Open API to create syntactic service specifications from which requesters generate code to integrate services. Proper service discovery is crucial to identify usable services in the growing plethora of third-party services. Most advanced service discovery approaches rely on semantic specifications, e.g., OWL-S. While semantic specification is crucial for a precise discovery, syntactical specification is needed for service invocation. To close the gap between semantic and syntactic specifications, service grounding establishes links between the semantic and syntactic specifications. However, for a large number of web services still no semantic specification or grounding exists. In this paper, we present an approach that semi-automates the semantic specification of web services for service providers and additionally helps service requesters to leverage semantic web services. Our approach enables a higher degree of automation than other approaches. This includes the creation of semantic specifications and service groundings for service providers as well as the integration of services for requesters by using our code generator. As proof-of-concept, we provide a case study, where we derive a sophisticated semantic OWL-S specification from a syntactic Open API specification.}}, author = {{Schwichtenberg, Simon and Gerth, Christian and Engels, Gregor}}, booktitle = {{Proceedings of the 24th IEEE International Conference on Web Services (ICWS)}}, pages = {{484----491}}, title = {{{From Open API to Semantic Specifications and Code Adapters}}}, year = {{2017}}, } @inproceedings{981, abstract = {{Benchmarking and profiling virtual network functions (VNFs) generates input knowledge for resource management decisions taken by management and orchestration systems. Such VNFs are usually not executed in isolation but are often deployed as part of a service function chain (SFC) that connects single functions into complex structures. To manage such chains, isolated performance profiles of single functions have to be combined to get insights into the overall behavior of an SFC. This becomes particularly challenging in highly agile DevOps environments in which profiling processes need to be fully automated and detailed insights about a chain's internal structures are not always available. In this paper, we introduce a fully automatable, flexible, and platform-agnostic profiling system that allows to profile entire SFCs at once. This obviates manual modeling procedures to combine profiling results from single VNFs to reflect SFC performance. We use a case study with different SFC configurations to show that it is hard to model the resulting SFC performance based on single-VNF measurements and that performance interactions between real, non-trivial functions that are deployed in a chain exist. }}, author = {{Peuster, Manuel and Karl, Holger}}, booktitle = {{IEEE Conference on Network Function Virtualisation and Software Defined Networks (NFV-SDN)}}, location = {{Berlin}}, title = {{{Profile Your Chains, Not Functions. Automated Network Service Profiling in DevOps Environments}}}, doi = {{10.1109/NFV-SDN.2017.8169826}}, year = {{2017}}, } @inproceedings{983, author = {{Auroux, Sébastien and Scholz, S. and Karl, Holger}}, booktitle = {{Proc. European Wireless}}, title = {{{Assessing Genetic Algorithms for Placing Flow Processing-aware Control Applications}}}, year = {{2017}}, } @article{9831, author = {{Burenkov, I. A. and Sharma, A. K. and Gerrits, T. and Harder, G. and Bartley, Tim and Silberhorn, Christine and Goldschmidt, E. A. and Polyakov, S. V.}}, issn = {{2469-9926}}, journal = {{Physical Review A}}, title = {{{Full statistical mode reconstruction of a light field via a photon-number-resolved measurement}}}, doi = {{10.1103/physreva.95.053806}}, year = {{2017}}, } @article{9834, author = {{Meyer-Scott, Evan and Montaut, Nicola and Tiedau, Johannes and Sansoni, Linda and Herrmann, Harald and Bartley, Tim and Silberhorn, Christine}}, issn = {{2469-9926}}, journal = {{Physical Review A}}, title = {{{Limits on the heralding efficiencies and spectral purities of spectrally filtered single photons from photon-pair sources}}}, doi = {{10.1103/physreva.95.061803}}, year = {{2017}}, } @article{9862, abstract = {{In order to improve the credibility of modern simulation tools, uncertainties of different kinds have to be considered. This work is focused on epistemic uncertainties in the framework of continuum mechanics, which are taken into account by fuzzy analysis. The underlying min-max optimization problem of the extension principle is approximated by α-discretization, resulting in a separation of minimum and maximum problems. To become more universal, so-called quantities of interest are employed, which allow a general formulation for the target problem of interest. In this way, the relation to parameter identification problems based on least-squares functions is highlighted. The solutions of the related optimization problems with simple constraints are obtained with a gradient-based scheme, which is derived from a sensitvity analysis for the target problem by means of a variational formulation. Two numerical examples for the fuzzy analysis of material parameters are concerned with a necking problem at large strain elastoplasticity and a perforated strip at large strain hyperelasticity to demonstrate the versatility of the proposed variational formulation. }}, author = {{Mahnken, Rolf}}, issn = {{ 2325-3444}}, journal = {{Mathematics and Mechanics of complex systems}}, keywords = {{fuzzy analysis, α-level optimization, quantities of interest, optimization with simple constraints, large strain elasticity, large strain elastoplasticity}}, number = {{3-4}}, title = {{{"A variational formulation for fuzzy analysis in continuum mechanics"}}}, volume = {{5}}, year = {{2017}}, } @inbook{9872, author = {{Mahnken, Rolf}}, booktitle = {{Encyclopedia of Computational Mechanics}}, editor = {{Stein, Erwin and de Borst, Rene and Hughes, Thomas J.R.}}, isbn = {{978-1-119-00379-3}}, pages = {{1165}}, publisher = {{John Wiley & Sons}}, title = {{{,,Identification of Material Parameters for Constitutive Equations “}}}, volume = {{4}}, year = {{2017}}, } @inproceedings{99, author = {{Wehrheim, Heike}}, booktitle = {{Proceedings of the 14th International Conference on Formal Aspects of Component Software (FACS)}}, title = {{{Fault localization in service compositions}}}, year = {{2017}}, }