% % This file was created by the TYPO3 extension % bib % --- Timezone: CET % Creation date: 2024-03-28 % Creation time: 15-56-23 % --- Number of references % 7 % @Inproceedings { 2021_pennekamp_laser, title = {Collaboration is not Evil: A Systematic Look at Security Research for Industrial Use}, year = {2021}, month = {12}, day = {21}, abstract = {Following the recent Internet of Things-induced trends on digitization in general, industrial applications will further evolve as well. With a focus on the domains of manufacturing and production, the Internet of Production pursues the vision of a digitized, globally interconnected, yet secure environment by establishing a distributed knowledge base. Background. As part of our collaborative research of advancing the scope of industrial applications through cybersecurity and privacy, we identified a set of common challenges and pitfalls that surface in such applied interdisciplinary collaborations. Aim. Our goal with this paper is to support researchers in the emerging field of cybersecurity in industrial settings by formalizing our experiences as reference for other research efforts, in industry and academia alike. Method. Based on our experience, we derived a process cycle of performing such interdisciplinary research, from the initial idea to the eventual dissemination and paper writing. This presented methodology strives to successfully bootstrap further research and to encourage further work in this emerging area. Results. Apart from our newly proposed process cycle, we report on our experiences and conduct a case study applying this methodology, raising awareness for challenges in cybersecurity research for industrial applications. We further detail the interplay between our process cycle and the data lifecycle in applied research data management. Finally, we augment our discussion with an industrial as well as an academic view on this research area and highlight that both areas still have to overcome significant challenges to sustainably and securely advance industrial applications. Conclusions. With our proposed process cycle for interdisciplinary research in the intersection of cybersecurity and industrial application, we provide a foundation for further research. We look forward to promising research initiatives, projects, and directions that emerge based on our methodological work.}, tags = {internet-of-production}, url = {https://www.comsys.rwth-aachen.de/fileadmin/papers/2021/2021-pennekamp-laser-collaboration.pdf}, publisher = {ACSA}, booktitle = {Proceedings of the Workshop on Learning from Authoritative Security Experiment Results (LASER '20), co-located with the 36th Annual Computer Security Applications Conference (ACSAC '20), December 7-11, 2020, Austin, TX, USA}, event_place = {Austin, TX, USA}, event_name = {Learning from Authoritative Security Experiment Results (LASER '20)}, event_date = {December 8, 2020}, ISBN = {978-1-891562-81-5}, DOI = {10.14722/laser-acsac.2020.23088}, reviewed = {1}, author = {Pennekamp, Jan and Buchholz, Erik and Dahlmanns, Markus and Kunze, Ike and Braun, Stefan and Wagner, Eric and Brockmann, Matthias and Wehrle, Klaus and Henze, Martin} } @Inproceedings { 2021_pennekamp_bootstrapping, title = {Confidential Computing-Induced Privacy Benefits for the Bootstrapping of New Business Relationships}, year = {2021}, month = {11}, day = {15}, number = {RWTH-2021-09499}, abstract = {In addition to quality improvements and cost reductions, dynamic and flexible business relationships are expected to become more important in the future to account for specific customer change requests or small-batch production. Today, despite reservation, sensitive information must be shared upfront between buyers and sellers. However, without a trust relation, this situation is precarious for the involved companies as they fear for their competitiveness following information leaks or breaches of their privacy. To address this issue, the concepts of confidential computing and cloud computing come to mind as they promise to offer scalable approaches that preserve the privacy of participating companies. In particular, designs building on confidential computing can help to technically enforce privacy. Moreover, cloud computing constitutes an elegant design choice to scale these novel protocols to industry needs while limiting the setup and management overhead for practitioners. Thus, novel approaches in this area can advance the status quo of bootstrapping new relationships as they provide privacy-preserving alternatives that are suitable for immediate deployment.}, keywords = {bootstrapping procurement; business relationships; secure industrial collaboration; privacy; Internet of Production}, tags = {internet-of-production}, url = {https://www.comsys.rwth-aachen.de/fileadmin/papers/2021/2021-pennekamp-bootstrapping.pdf}, publisher = {RWTH Aachen University}, booktitle = {Blitz Talk at the 2021 Cloud Computing Security Workshop (CCSW '21), co-located with the 28th ACM SIGSAC Conference on Computer and Communications Security (CCS '21), November 15-19, 2021, Seoul, Korea}, institution = {RWTH Aachen University}, event_place = {Seoul, Korea}, event_date = {November 14, 2021}, DOI = {10.18154/RWTH-2021-09499}, author = {Pennekamp, Jan and Fuhrmann, Frederik and Dahlmanns, Markus and Heutmann, Timo and Kreppein, Alexander and Grunert, Dennis and Lange, Christoph and Schmitt, Robert H. and Wehrle, Klaus} } @Article { 2021_matzutt_coinprune_v2, title = {CoinPrune: Shrinking Bitcoin's Blockchain Retrospectively}, journal = {IEEE Transactions on Network and Service Management}, year = {2021}, month = {9}, day = {10}, volume = {18}, number = {3}, pages = {3064-3078}, abstract = {Popular cryptocurrencies continue to face serious scalability issues due to their ever-growing blockchains. Thus, modern blockchain designs began to prune old blocks and rely on recent snapshots for their bootstrapping processes instead. Unfortunately, established systems are often considered incapable of adopting these improvements. In this work, we present CoinPrune, our block-pruning scheme with full Bitcoin compatibility, to revise this popular belief. CoinPrune bootstraps joining nodes via snapshots that are periodically created from Bitcoin's set of unspent transaction outputs (UTXO set). Our scheme establishes trust in these snapshots by relying on CoinPrune-supporting miners to mutually reaffirm a snapshot's correctness on the blockchain. This way, snapshots remain trustworthy even if adversaries attempt to tamper with them. Our scheme maintains its retrospective deployability by relying on positive feedback only, i.e., blocks containing invalid reaffirmations are not rejected, but invalid reaffirmations are outpaced by the benign ones created by an honest majority among CoinPrune-supporting miners. Already today, CoinPrune reduces the storage requirements for Bitcoin nodes by two orders of magnitude, as joining nodes need to fetch and process only 6 GiB instead of 271 GiB of data in our evaluation, reducing the synchronization time of powerful devices from currently 7 h to 51 min, with even larger potential drops for less powerful devices. CoinPrune is further aware of higher-level application data, i.e., it conserves otherwise pruned application data and allows nodes to obfuscate objectionable and potentially illegal blockchain content from their UTXO set and the snapshots they distribute.}, keywords = {blockchain; block pruning; synchronization; bootstrapping; scalability; velvet fork; Bitcoin}, tags = {mynedata; impact_digital; digital_campus}, url = {https://www.comsys.rwth-aachen.de/fileadmin/papers/2021/2021-matzutt-coinprune-v2.pdf}, language = {English}, ISSN = {1932-4537}, DOI = {10.1109/TNSM.2021.3073270}, reviewed = {1}, author = {Matzutt, Roman and Kalde, Benedikt and Pennekamp, Jan and Drichel, Arthur and Henze, Martin and Wehrle, Klaus} } @Inproceedings { 2021_mangel_reshare, title = {Data Reliability and Trustworthiness through Digital Transmission Contracts}, year = {2021}, month = {6}, day = {8}, volume = {12731}, pages = {265-283}, abstract = {As decision-making is increasingly data-driven, trustworthiness and reliability of the underlying data, e.g., maintained in knowledge graphs or on the Web, are essential requirements for their usability in the industry. However, neither traditional solutions, such as paper-based data curation processes, nor state-of-the-art approaches, such as distributed ledger technologies, adequately scale to the complex requirements and high throughput of continuously evolving industrial data. Motivated by a practical use case with high demands towards data trustworthiness and reliability, we identify the need for digitally-verifiable data immutability as a still insufficiently addressed dimension of data quality. Based on our discussion of shortcomings in related work, we thus propose ReShare, our novel concept of digital transmission contracts with bilateral signatures, to address this open issue for both RDF knowledge graphs and arbitrary data on the Web. Our quantitative evaluation of ReShare’s performance and scalability reveals only moderate computation and communication overhead, indicating significant potential for cost-reductions compared to today’s approaches. By cleverly integrating digital transmission contracts with existing Web-based information systems, ReShare provides a promising foundation for data sharing and reuse in Industry 4.0 and beyond, enabling digital accountability through easily-adoptable digitally-verifiable data immutability and non-repudiation.}, note = {Lecture Notes in Computer Science (LNCS), Volume 12731}, keywords = {Digital transmission contracts; Trust; Data immutability; Non-repudiation; Accountability; Data dynamics; Linked Data; Knowledge graphs}, tags = {internet-of-production}, url = {https://www.comsys.rwth-aachen.de/fileadmin/papers/2021/2021-mangel-eswc-reshare.pdf}, publisher = {Springer}, booktitle = {Proceedings of the 18th Extended Semantic Web Conference (ESWC '21), June 6-10, 2021, Heraklion, Greece}, event_place = {Heraklion, Greece}, event_date = {June 6-10, 2021}, ISBN = {978-3-030-77384-7}, ISSN = {0302-9743}, DOI = {10.1007/978-3-030-77385-4_16}, reviewed = {1}, author = {Mangel, Simon and Gleim, Lars and Pennekamp, Jan and Wehrle, Klaus and Decker, Stefan} } @Inproceedings { 2021_gleim_factstack, title = {FactStack: Interoperable Data Management and Preservation for the Web and Industry 4.0}, year = {2021}, month = {5}, day = {31}, volume = {P-312}, pages = {371-395}, abstract = {Data exchange throughout the supply chain is essential for the agile and adaptive manufacturing processes of Industry 4.0. As companies employ numerous, frequently mutually incompatible data management and preservation approaches, interorganizational data sharing and reuse regularly requires human interaction and is thus associated with high overhead costs. An interoperable system, supporting the unified management, preservation and exchange of data across organizational boundaries is missing to date. We propose FactStack, a unified approach to data management and preservation based upon a novel combination of existing Web-standards and tightly integrated with the HTTP protocol itself. Based on the FactDAG model, FactStack guides and supports the full data lifecycle in a FAIR and interoperable manner, independent of individual software solutions and backward-compatible with existing resource oriented architectures. We describe our reference implementation of the approach and evaluate its performance, showcasing scalability even to high-throughput applications. We analyze the system's applicability to industry using a representative real-world use case in aircraft manufacturing based on principal requirements identified in prior work. We conclude that FactStack fulfills all requirements and provides a promising solution for the on-demand integration of persistence and provenance into existing resource-oriented architectures, facilitating data management and preservation for the agile and interorganizational manufacturing processes of Industry 4.0. Through its open source distribution, it is readily available for adoption by the community, paving the way for improved utility and usability of data management and preservation in digital manufacturing and supply chains.}, note = {Lecture Notes in Informatics (LNI), Volume P-312}, keywords = {Web Technologies; Data Management; Memento; Persistence; PID; Industry 4.0}, tags = {internet-of-production}, url = {https://comsys.rwth-aachen.de/fileadmin/papers/2021/2021-gleim-btw-iop-interoperability-realization.pdf}, publisher = {Gesellschaft f{\"u}r Informatik}, booktitle = {Proceedings of the 19th Symposium for Database Systems for Business, Technology and Web (BTW '21), September 13-17, 2021, Dresden, Germany}, event_place = {Dresden, Germany}, event_date = {September 13-17, 2021}, ISBN = {978-3-88579-705-0}, ISSN = {1617-5468}, DOI = {10.18420/btw2021-20}, reviewed = {1}, author = {Gleim, Lars and Pennekamp, Jan and Tirpitz, Liam and Welten, Sascha and Brillowski, Florian and Decker, Stefan} } @Inproceedings { 2021_dahlmanns_entrust, title = {Transparent End-to-End Security for Publish/Subscribe Communication in Cyber-Physical Systems}, year = {2021}, month = {4}, day = {28}, pages = {78–87}, abstract = {The ongoing digitization of industrial manufacturing leads to a decisive change in industrial communication paradigms. Moving from traditional one-to-one to many-to-many communication, publish/subscribe systems promise a more dynamic and efficient exchange of data. However, the resulting significantly more complex communication relationships render traditional end-to-end security futile for sufficiently protecting the sensitive and safety-critical data transmitted in industrial systems. Most notably, the central message brokers inherent in publish/subscribe systems introduce a designated weak spot for security as they can access all communication messages. To address this issue, we propose ENTRUST, a novel solution for key server-based end-to-end security in publish/subscribe systems. ENTRUST transparently realizes confidentiality, integrity, and authentication for publish/subscribe systems without any modification of the underlying protocol. We exemplarily implement ENTRUST on top of MQTT, the de-facto standard for machine-to-machine communication, showing that ENTRUST can integrate seamlessly into existing publish/subscribe systems.}, keywords = {cyber-physical system security; publish-subscribe security; end-to-end security}, tags = {internet-of-production, rfc}, url = {https://www.comsys.rwth-aachen.de/fileadmin/papers/2021/2021-dahlmanns-entrust.pdf}, publisher = {ACM}, booktitle = {Proceedings of the 1st ACM Workshop on Secure and Trustworthy Cyber-Physical Systems (SaT-CPS '21), co-located with the 11th ACM Conference on Data and Application Security and Privacy (CODASPY '21), April 26-28, 2021, Virtual Event, USA}, event_place = {Virtual Event, USA}, event_name = {ACM Workshop on Secure and Trustworthy Cyber-Physical Systems}, event_date = {April 28, 2021}, ISBN = {978-1-4503-8319-6/21/04}, DOI = {10.1145/3445969.3450423}, reviewed = {1}, author = {Dahlmanns, Markus and Pennekamp, Jan and Fink, Ina Berenice and Schoolmann, Bernd and Wehrle, Klaus and Henze, Martin} } @Article { 2021-wehrle-energy, title = {A Novel Receiver Design for Energy Packetā€Based Dispatching}, journal = {Energy Technology}, year = {2021}, volume = {9}, number = {2}, DOI = {10.1002/ente.202000937}, reviewed = {1}, author = {Wiegel, Friedirch and De Din, Edoardo and Monti, Antonello and Wehrle, Klaus and Hiller, Marc and Zitterbart, Martina and Hagenmeyer, Veit} }