% % This file was created by the TYPO3 extension % bib % --- Timezone: CEST % Creation date: 2020-10-24 % Creation time: 20-37-43 % --- Number of references % 8 % @Article { 2020_niemietz_stamping, title = {Stamping Process Modelling in an Internet of Production}, journal = {Procedia Manufacturing}, year = {2020}, month = {7}, day = {11}, volume = {49}, pages = {61-68}, abstract = {Sharing data between companies throughout the supply chain is expected to be beneficial for product quality as well as for the economical savings in the manufacturing industry. To utilize the available data in the vision of an Internet of Production (IoP) a precise condition monitoring of manufacturing and production processes that facilitates the quantification of influences throughout the supply chain is inevitable. In this paper, we consider stamping processes in the context of an Internet of Production and the preliminaries for analytical models that utilize the ever-increasing available data. Three research objectives to cope with the amount of data and for a methodology to monitor, analyze and evaluate the influence of available data onto stamping processes have been identified: (i) State detection based on cyclic sensor signals, (ii) mapping of in- and output parameter variations onto process states, and (iii) models for edge and in-network computing approaches. After discussing state-of-the-art approaches to monitor stamping processes and the introduction of the fineblanking process as an exemplary stamping process, a research roadmap for an IoP enabling modeling framework is presented.}, note = {Proceedings of the 8th International Conference on Through-Life Engineering Service (TESConf '19), October 27-29, 2019, Cleveland, OH, USA}, keywords = {Stamping Process; Industry 4.0; Fine-blanking; Internet of production; Condition monitoring; Data analytics}, tags = {internet-of-production}, url = {https://www.comsys.rwth-aachen.de/fileadmin/papers/2020/2020-niemietz-stamping-modelling.pdf}, publisher = {Elsevier}, ISSN = {2351-9789}, DOI = {10.1016/j.promfg.2020.06.012}, reviewed = {1}, author = {Niemietz, Philipp and Pennekamp, Jan and Kunze, Ike and Trauth, Daniel and Wehrle, Klaus and Bergs, Thomas} } @Inproceedings { 2020_buckhorst_lmas, title = {Holarchy for Line-less Mobile Assembly Systems Operation in the Context of the Internet of Production}, year = {2020}, month = {7}, abstract = {Assembly systems must provide maximum flexibility qualified by organization and technology to offer cost-compliant performance features to differentiate themselves from competitors in buyers’ markets. By mobilization of multipurpose resources and dynamic planning, Line-less Mobile Assembly Systems (LMASs) offer organizational reconfigurability. By proposing a holarchy to combine LMASs with the concept of an Internet of Production (IoP), we enable LMASs to source valuable information from cross-level production networks, physical resources, software nodes, and data stores that are interconnected in an IoP. The presented holarchy provides a concept of how to address future challenges, meet the requirements of shorter lead times, and unique lifecycle support. The paper suggests an application of decision making, distributed sensor services, recommender-based data reduction, and in-network computing while considering safety and human usability alike.}, keywords = {Internet of Production; Line-less Mobile Assembly System; Industrial Assembly; Smart Factory}, tags = {internet-of-production}, url = {https://jpennekamp.de/wp-content/papercite-data/pdf/bmw+20.pdf}, publisher = {Elsevier}, booktitle = {Proceedings of the 14th CIRP Conference on Intelligent Computation in Manufacturing Engineering (ICME '20), July 14-17, 2020, Gulf of Naples, Italy}, event_place = {Gulf of Naples, Italy}, event_date = {July 14-17, 2020}, state = {accepted}, reviewed = {1}, author = {Buckhorst, Armin F. and Montavon, Benjamin and Wolfschl{\"a}ger, Dominik and Buchsbaum, Melanie and Shahidi, Amir and Petruck, Henning and Kunze, Ike and Pennekamp, Jan and Brecher, Christian and H{\"u}sing, Mathias and Corves, Burkhard and Nitsch, Verena and Wehrle, Klaus and Schmitt, Robert H.} } @Inproceedings { 2020-mann-ur-weldseamstudy, title = {Study on weld seam geometry control for connected gas metal arc welding systems}, year = {2020}, month = {6}, url = {https://www.comsys.rwth-aachen.de/fileadmin/papers/2020/2020-mann-weld-seam-geometry-control.pdf}, booktitle = {Proceedings of the 2020 Internal Conference on Ubiquitous Robots}, event_name = {Internal Conference on Ubiquitous Robots}, event_date = {June 22-26, 2020}, state = {accepted}, DOI = {10.1109/UR49135.2020.9144839}, reviewed = {1}, author = {Mann, Samuel and Glebke, Ren{\'e} and Kunze, Ike and Scheurenberg, Dominik and Sharma, Rahul and Reisgen, Uwe and Wehrle, Klaus and Abel, Dirk} } @Article { 2019-kunze-ccwild-tnsm, title = {Congestion Control in the Wild - Investigating Content Provider Fairness}, journal = {IEEE Transactions on Network and Service Management}, year = {2019}, month = {12}, day = {27}, volume = {17}, number = {2}, pages = {1224 - 1238}, url = {https://www.comsys.rwth-aachen.de/fileadmin/papers/2019/2019-kunze-ccwild-tnsm.pdf}, ISSN = {1932-4537}, DOI = {10.1109/TNSM.2019.2962607}, reviewed = {1}, author = {Kunze, Ike and R{\"u}th, Jan and Hohlfeld, Oliver} } @Inproceedings { 2019-glebke-in-network-cv, title = {Towards Executing Computer Vision Functionality on Programmable Network Devices}, year = {2019}, month = {12}, day = {9}, tags = {reflexes,maki,internet-of-production}, url = {https://www.comsys.rwth-aachen.de/fileadmin/papers/2019/2019-glebke-in-network-cv.pdf}, misc2 = {Online}, publisher = {ACM}, booktitle = {1st ACM CoNEXT Workshop on Emerging in-Network Computing Paradigms (ENCP '19)}, language = {en}, ISBN = {978-1-4503-7000-4/19/12}, DOI = {10.1145/3359993.3366646}, reviewed = {1}, author = {Glebke, Ren{\'e} and Krude, Johannes and Kunze, Ike and R{\"u}th, Jan and Senger, Felix and Wehrle, Klaus} } @Inproceedings { 2019-rueth-ccfness, title = {An Empirical View on Content Provider Fairness}, year = {2019}, month = {6}, day = {19}, tags = {maki}, url = {https://www.comsys.rwth-aachen.de/fileadmin/papers/2019/2019-rueth-ccfness.pdf}, web_url2 = {https://arxiv.org/abs/1905.07152}, publisher = {IFIP/IEEE}, booktitle = {In Proceedings of the Network Traffic Measurement and Analysis Conference (TMA '19)}, event_place = {Paris, France}, event_name = {Network Traffic Measurement and Analysis Conference}, event_date = {19.06.2019 - 21.06.2019}, DOI = {10.23919/TMA.2019.8784684}, reviewed = {1}, author = {R{\"u}th, Jan and Kunze, Ike and Hohlfeld, Oliver} } @Article { rueth:iw:TNSM19, title = {TCP’s Initial Window – Deployment in the Wild and its Impact on Performance}, journal = {IEEE Transactions on Network and Service Management}, year = {2019}, month = {1}, day = {30}, volume = {16}, number = {2}, pages = {389--402}, tags = {maki}, url = {http://www.comsys.rwth-aachen.de/fileadmin/papers/2019/2019-rueth-iwtnsm.pdf}, ISSN = {1932-4537}, DOI = {10.1109/TNSM.2019.2896335}, reviewed = {1}, author = {R{\"u}th, Jan and Kunze, Ike and Hohlfeld, Oliver} } @Article { 2017-ziegeldorf-bmcmedgenomics-bloom, title = {BLOOM: BLoom filter based Oblivious Outsourced Matchings}, journal = {BMC Medical Genomics}, year = {2017}, month = {7}, day = {26}, volume = {10}, number = {Suppl 2}, pages = {29-42}, abstract = {Whole genome sequencing has become fast, accurate, and cheap, paving the way towards the large-scale collection and processing of human genome data. Unfortunately, this dawning genome era does not only promise tremendous advances in biomedical research but also causes unprecedented privacy risks for the many. Handling storage and processing of large genome datasets through cloud services greatly aggravates these concerns. Current research efforts thus investigate the use of strong cryptographic methods and protocols to implement privacy-preserving genomic computations. We propose FHE-Bloom and PHE-Bloom, two efficient approaches for genetic disease testing using homomorphically encrypted Bloom filters. Both approaches allow the data owner to securely outsource storage and computation to an untrusted cloud. FHE-Bloom is fully secure in the semi-honest model while PHE-Bloom slightly relaxes security guarantees in a trade-off for highly improved performance. We implement and evaluate both approaches on a large dataset of up to 50 patient genomes each with up to 1000000 variations (single nucleotide polymorphisms). For both implementations, overheads scale linearly in the number of patients and variations, while PHE-Bloom is faster by at least three orders of magnitude. For example, testing disease susceptibility of 50 patients with 100000 variations requires only a total of 308.31 s (\(\sigma\)=8.73 s) with our first approach and a mere 0.07 s (\(\sigma\)=0.00 s) with the second. We additionally discuss security guarantees of both approaches and their limitations as well as possible extensions towards more complex query types, e.g., fuzzy or range queries. Both approaches handle practical problem sizes efficiently and are easily parallelized to scale with the elastic resources available in the cloud. The fully homomorphic scheme, FHE-Bloom, realizes a comprehensive outsourcing to the cloud, while the partially homomorphic scheme, PHE-Bloom, trades a slight relaxation of security guarantees against performance improvements by at least three orders of magnitude.}, note = {Proceedings of the 5th iDASH Privacy and Security Workshop 2016}, keywords = {Secure outsourcing; Homomorphic encryption; Bloom filters}, tags = {sscilops,mynedata}, url = {https://www.comsys.rwth-aachen.de/fileadmin/papers/2017/2017-ziegeldorf-bmcmedgenomics-bloom.pdf}, misc2 = {Online}, publisher = {BioMed Central}, event_place = {Chicago, IL, USA}, event_date = {November 11, 2016}, language = {en}, ISSN = {1755-8794}, DOI = {10.1186/s12920-017-0277-y}, reviewed = {1}, author = {Ziegeldorf, Jan Henrik and Pennekamp, Jan and Hellmanns, David and Schwinger, Felix and Kunze, Ike and Henze, Martin and Hiller, Jens and Matzutt, Roman and Wehrle, Klaus} }