% % This file was created by the TYPO3 extension % bib % --- Timezone: CET % Creation date: 2024-03-29 % Creation time: 12-13-23 % --- Number of references % 10 % @Inproceedings { 2020_pennekamp_benchmarking, title = {Revisiting the Privacy Needs of Real-World Applicable Company Benchmarking}, year = {2020}, month = {12}, day = {15}, pages = {31-44}, abstract = {Benchmarking the performance of companies is essential to identify improvement potentials in various industries. Due to a competitive environment, this process imposes strong privacy needs, as leaked business secrets can have devastating effects on participating companies. Consequently, related work proposes to protect sensitive input data of companies using secure multi-party computation or homomorphic encryption. However, related work so far does not consider that also the benchmarking algorithm, used in today's applied real-world scenarios to compute all relevant statistics, itself contains significant intellectual property, and thus needs to be protected. Addressing this issue, we present PCB — a practical design for Privacy-preserving Company Benchmarking that utilizes homomorphic encryption and a privacy proxy — which is specifically tailored for realistic real-world applications in which we protect companies' sensitive input data and the valuable algorithms used to compute underlying key performance indicators. We evaluate PCB's performance using synthetic measurements and showcase its applicability alongside an actual company benchmarking performed in the domain of injection molding, covering 48 distinct key performance indicators calculated out of hundreds of different input values. By protecting the privacy of all participants, we enable them to fully profit from the benefits of company benchmarking.}, keywords = {practical encrypted computing; homomorphic encryption; algorithm confidentiality; benchmarking; key performance indicators; industrial application; Internet of Production}, tags = {internet-of-production}, url = {https://www.comsys.rwth-aachen.de/fileadmin/papers/2020/2020-pennekamp-company-benchmarking.pdf}, web_url = {https://eprint.iacr.org/2020/1512}, publisher = {HomomorphicEncryption.org}, booktitle = {Proceedings of the 8th Workshop on Encrypted Computing \& Applied Homomorphic Cryptography (WAHC '20), December 15, 2020, Virtual Event}, event_place = {Virtual Event}, event_date = {December 15, 2020}, ISBN = {978-3-00-067798-4}, DOI = {10.25835/0072999}, reviewed = {1}, author = {Pennekamp, Jan and Sapel, Patrick and Fink, Ina Berenice and Wagner, Simon and Reuter, Sebastian and Hopmann, Christian and Wehrle, Klaus and Henze, Martin} } @Proceedings { fink-lcn-demons-2020, title = {Extending MUD to Smartphones}, year = {2020}, month = {11}, day = {15}, tags = {nerd-nrw}, url = {https://www.comsys.rwth-aachen.de/fileadmin/papers/2020/2020-fink-lcn-mud-smartphone.pdf}, publisher = {IEEE}, howpublished = {online}, event_place = {Sydney, Australia}, event_name = {45th IEEE Conference on Local Computer Networks (LCN)}, event_date = {November 16-19, 2020}, DOI = {10.1109/LCN48667.2020.9314782}, reviewed = {1}, author = {Fink, Ina Berenice and Serror, Martin and Wehrle, Klaus} } @Article { serror-iiotsec-tii-2020, title = {Challenges and Opportunities in Securing the Industrial Internet of Things}, journal = {IEEE Transactions on Industrial Informatics}, year = {2020}, month = {9}, day = {11}, volume = {17}, number = {5}, pages = {2985-2996}, tags = {nerd-nrw}, url = {https://comsys.rwth-aachen.de/fileadmin/papers/2020/2020-serror-tii-iiotsec.pdf}, web_url = {https://ieeexplore.ieee.org/document/9195014}, howpublished = {online}, ISSN = {1941-0050}, DOI = {10.1109/TII.2020.3023507}, reviewed = {1}, author = {Serror, Martin and Hack, Sacha and Henze, Martin and Schuba, Marko and Wehrle, Klaus} } @Inproceedings { 2020-kirchhof-wowmom-ccncps, title = {Improving MAC Protocols for Wireless Industrial Networks via Packet Prioritization and Cooperation}, year = {2020}, month = {8}, day = {31}, tags = {internet-of-production, reflexes}, url = {https://comsys.rwth-aachen.de/fileadmin/papers/2020/2020-kirchhof-wireless-mac-improvements.pdf}, publisher = {IEEE Computer Society}, howpublished = {online}, booktitle = {International Symposium on a World of Wireless, Mobile and Multimedia Networks: Workshop on Communication, Computing, and Networking in Cyber Physical Systems (WoWMoM-CCNCPS'2020), August 31 - September 3, 2020, Cork, Ireland}, event_place = {Cork, Ireland}, event_date = {August 31 - September 3, 2020}, DOI = {10.1109/WoWMoM49955.2020.00068}, reviewed = {1}, author = {Kirchhof, J{\"o}rg Christian and Serror, Martin and Glebke, Ren{\'e} and Wehrle, Klaus} } @Inproceedings { 2020-schemmel-porse, title = {Symbolic Partial-Order Execution for Testing Multi-Threaded Programs}, year = {2020}, month = {7}, tags = {symbiosys}, url = {https://arxiv.org/pdf/2005.06688.pdf}, web_url2 = {https://arxiv.org/abs/2005.06688}, booktitle = {Computer Aided Verification (CAV 2020)}, event_name = {32nd International Conference on Computer Aided Verification}, DOI = {10.1007/978-3-030-53288-8_18}, reviewed = {1}, author = {Schemmel, Daniel and B{\"u}ning, Julian and Rodr{\'i}guez, C{\'e}sar and Laprell, David and Wehrle, Klaus} } @Inproceedings { 2020-serror-networking-qwin, title = {QWIN: Facilitating QoS in Wireless Industrial Networks Through Cooperation}, year = {2020}, month = {6}, day = {21}, tags = {consent}, url = {https://comsys.rwth-aachen.de/fileadmin/papers/2020/2020-serror-qwin.pdf}, web_url = {https://ieeexplore.ieee.org/abstract/document/9142792}, publisher = {IFIP}, howpublished = {online}, booktitle = {Proceedings of the 19th IFIP Networking 2020 Conference (NETWORKING '20), June 22-26, 2020, Paris, France}, event_place = {Paris, France}, event_name = {IFIP NETWORKING Conference}, event_date = {June 22-26, 2020}, ISBN = {978-3-903176-28-7}, reviewed = {1}, author = {Serror, Martin and Wagner, Eric and Glebke, Ren{\'e} and Wehrle, Klaus} } @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}, 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 { 2020_gleim_factDAG, title = {FactDAG: Formalizing Data Interoperability in an Internet of Production}, journal = {IEEE Internet of Things Journal}, year = {2020}, month = {4}, day = {14}, volume = {7}, number = {4}, pages = {3243-3253}, abstract = {In the production industry, the volume, variety and velocity of data as well as the number of deployed protocols increase exponentially due to the influences of IoT advances. While hundreds of isolated solutions exist to utilize this data, e.g., optimizing processes or monitoring machine conditions, the lack of a unified data handling and exchange mechanism hinders the implementation of approaches to improve the quality of decisions and processes in such an interconnected environment. The vision of an Internet of Production promises the establishment of a Worldwide Lab, where data from every process in the network can be utilized, even interorganizational and across domains. While numerous existing approaches consider interoperability from an interface and communication system perspective, fundamental questions of data and information interoperability remain insufficiently addressed. In this paper, we identify ten key issues, derived from three distinctive real-world use cases, that hinder large-scale data interoperability for industrial processes. Based on these issues we derive a set of five key requirements for future (IoT) data layers, building upon the FAIR data principles. We propose to address them by creating FactDAG, a conceptual data layer model for maintaining a provenance-based, directed acyclic graph of facts, inspired by successful distributed version-control and collaboration systems. Eventually, such a standardization should greatly shape the future of interoperability in an interconnected production industry.}, keywords = {Data Management; Data Versioning; Interoperability; Industrial Internet of Things; Worldwide Lab}, tags = {internet-of-production}, url = {https://comsys.rwth-aachen.de/fileadmin/papers/2020/2020-gleim-iotj-iop-interoperability.pdf}, publisher = {IEEE}, ISSN = {2327-4662}, DOI = {10.1109/JIOT.2020.2966402}, reviewed = {1}, author = {Gleim, Lars and Pennekamp, Jan and Liebenberg, Martin and Buchsbaum, Melanie and Niemietz, Philipp and Knape, Simon and Epple, Alexander and Storms, Simon and Trauth, Daniel and Bergs, Thomas and Brecher, Christian and Decker, Stefan and Lakemeyer, Gerhard and Wehrle, Klaus} } @Article { 2020_mann_welding_layers, title = {Connected, digitalized welding production — Secure, ubiquitous utilization of data across process layers}, journal = {Advanced Structured Materials}, year = {2020}, month = {4}, day = {1}, volume = {125}, pages = {101-118}, abstract = {A connected, digitalized welding production unlocks vast and dynamic potentials: from improving state of the art welding to new business models in production. For this reason, offering frameworks, which are capable of addressing multiple layers of applications on the one hand and providing means of data security and privacy for ubiquitous dataflows on the other hand, is an important step to enable the envisioned advances. In this context, welding production has been introduced from the perspective of interlaced process layers connecting information sources across various entities. Each layer has its own distinct challenges from both a process view and a data perspective. Besides, investigating each layer promises to reveal insight into (currently unknown) process interconnections. This approach has been substantiated by methods for data security and privacy to draw a line between secure handling of data and the need of trustworthy dealing with sensitive data among different parties and therefore partners. In conclusion, the welding production has to develop itself from an accumulation of local and isolated data sources towards a secure industrial collaboration in an Internet of Production.}, note = {Proceedings of the 1st International Conference on Advanced Joining Processes (AJP '19)}, keywords = {Welding Production; Industrie 4.0; Internet of Production; Data Security; Data Privacy}, tags = {Internet-of-Production}, url = {https://www.comsys.rwth-aachen.de/fileadmin/papers/2020/2020-mann-welding-layers.pdf}, publisher = {Springer}, event_place = {Ponta Delgada, Azores, Portugal}, event_date = {October 24-25, 2019}, ISBN = {978-981-15-2956-6}, ISSN = {1869-8433}, DOI = {10.1007/978-981-15-2957-3_8}, reviewed = {1}, author = {Mann, Samuel and Pennekamp, Jan and Brockhoff, Tobias and Farhang, Anahita and Pourbafrani, Mahsa and Oster, Lukas and Uysal, Merih Seran and Sharma, Rahul and Reisgen, Uwe and Wehrle, Klaus and van der Aalst, Wil} } @Article { 2020-wehrle-digitalshadows, title = {Mit ''Digitalen Schatten'' Daten verdichten und darstellen : Der Exzellenzcluster ''Internet der Produktion'' forscht {\"u}ber die Produktionstechnik hinaus}, journal = {Der Profilbereich ''Information \& Communication Technology''}, year = {2020}, ISSN = {0179-079X}, DOI = {10.18154/RWTH-2021-02496}, author = {Jarke, Matthias and van der Aalst, Wil and Brecher, Christian and Brockmann, Matthias and Koren, Istv{\'a}n and Lakemeyer, Gerhard and Rumpe, Bernhard and Schuh, G{\"u}nther and Wehrle, Klaus and Ziefle, Martina} }