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Traffic Injury Prevention Volume 20, 2019 - Issue sup1: Peer-Reviewed Journal for the 26th International Technical Conference on the Enhanced Safety of Vehicles (ESV)
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Articles

A framework for definition of logical scenarios for safety assurance of automated driving

Hendrik WeberInstitute for Automotive Engineering (ika), RWTH Aachen University, Aachen, Germany; Correspondence[email protected]
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Julian BockInstitute for Automotive Engineering (ika), RWTH Aachen University, Aachen, Germany; View further author information
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Jens Klimkefka GmbH, Aachen, GermanyView further author information
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Christian RoesenerInstitute for Automotive Engineering (ika), RWTH Aachen University, Aachen, Germany; View further author information
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Johannes HillerInstitute for Automotive Engineering (ika), RWTH Aachen University, Aachen, Germany; View further author information
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Robert KrajewskiInstitute for Automotive Engineering (ika), RWTH Aachen University, Aachen, Germany; View further author information
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Adrian Zlockifka GmbH, Aachen, GermanyView further author information
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Lutz EcksteinInstitute for Automotive Engineering (ika), RWTH Aachen University, Aachen, Germany; View further author information
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Pages S65-S70 | Received 09 Nov 2018, Accepted 09 Jun 2019, Published online: 05 Aug 2019

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Huizhao Tu, Min Wang, Hao Li & Lijun Sun. (2023) Safety risk assessment for autonomous vehicle road testing. Traffic Injury Prevention 24:7, pages 652-661.
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L. Garrett Bangert, Theodore Lubash, John M. Scanlon, Kristofer D. Kusano & Luke E. Riexinger. (2023) Determination of functional scenarios for intersection collisions. Accident Analysis & Prevention 193, pages 107326.
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Manuel Hirschle, Dmitrii Kirov, Rosario Aievola, Stefano Sinisi, Serena Iovino & Jürgen Adamy. (2023) Scenario-Based Methods for Machine Learning Assurance. Scenario-Based Methods for Machine Learning Assurance.
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Tobias Moers, Lennart Vater, Robert Krajewski, Julian Bock, Adrian Zlocki & Lutz Eckstein. (2022) The exiD Dataset: A Real-World Trajectory Dataset of Highly Interactive Highway Scenarios in Germany. The exiD Dataset: A Real-World Trajectory Dataset of Highly Interactive Highway Scenarios in Germany.
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Maximilian Bauder, Klaus Böhm, Tibor Kubjatko, Lothar Wech & Hans-Georg Schweiger. (2022) C-ITS Relevant Critical Vehicle-to-Vehicle Accident Scenarios for Accident Analysis. Sensors 22:9, pages 3562.
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Chen Sun, Zejian Deng, Wenbo Chu, Shen Li & Dongpu Cao. (2022) Acclimatizing the Operational Design Domain for Autonomous Driving Systems. IEEE Intelligent Transportation Systems Magazine 14:2, pages 10-24.
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Nobuyuki UCHIDA. (2022) Scenario Construction for Safety Assurance of Automated Vehicles: Introduction of SAKURA Project自動運転車の安全性評価のためのシナリオ構築. TRENDS IN THE SCIENCES 27:2, pages 2_82-2_86.
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Adrian Zlocki, Alexander Konig, Julian Bock, Hendrik Weber, Husam Muslim, Hiroki Nakamura, Sandra Watanabe, Jacobo Antona-Makoshi & Satoshi Taniguchi. (2022) Logical Scenarios Parameterization for Automated Vehicle Safety Assessment: Comparison of Deceleration and Cut-In Scenarios From Japanese and German Highways. IEEE Access 10, pages 26817-26829.
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Markus Steimle, Nico Weber & Markus Maurer. (2022) Toward Generating Sufficiently Valid Test Case Results: A Method for Systematically Assigning Test Cases to Test Bench Configurations in a Scenario-Based Test Approach for Automated Vehicles. IEEE Access 10, pages 6260-6285.
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Robert Maier, Lisa Grabinger, David Urlhart & Jürgen Mottok. 2022. Model-Based Safety and Assessment. Model-Based Safety and Assessment 116 129 .
Marzana Khatun, Heinrich Litagin, Rolf Jung & Michael Glaß. 2022. Computer Safety, Reliability, and Security. SAFECOMP 2022 Workshops. Computer Safety, Reliability, and Security. SAFECOMP 2022 Workshops 166 177 .
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Marianna Cossu, Jorge Leonardo Quimi Villon, Francesco Bellotti, Alessio Capello, Alessandro De Gloria, Luca Lazzaroni & Riccardo Berta. 2022. Applications in Electronics Pervading Industry, Environment and Society. Applications in Electronics Pervading Industry, Environment and Society 229 235 .
Jack Stilgoe. (2021) How can we know a self-driving car is safe?. Ethics and Information Technology 23:4, pages 635-647.
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Leonard Stepien, Silvia Thal, Roman Henze, Hiroki Nakamura, Jacobo Antona-Makoshi, Nobuyuki Uchida & Pongsathorn Raksincharoensak. (2021) Applying Heuristics to Generate Test Cases for Automated Driving Safety Evaluation. Applied Sciences 11:21, pages 10166.
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Daniel Bogdoll, Jasmin Breitenstein, Florian Heidecker, Maarten Bieshaar, Bernhard Sick, Tim Fingscheidt & J. Marius Zollner. (2021) Description of Corner Cases in Automated Driving: Goals and Challenges. Description of Corner Cases in Automated Driving: Goals and Challenges.
Jacco van de Sluis, Olaf Op den Camp, Jeroen Broos, Ihsan Yalcinkaya & Erwin de Gelder. (2021) Describing I2V Communication in Scenarios for Simulation-Based Safety Assessment of Truck Platooning. Electronics 10:19, pages 2362.
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David Reiher & Axel Hahn. (2021) Review on the Current State of Scenario- and Simulation-Based V&V in Application for Maritime Traffic Systems. Review on the Current State of Scenario- and Simulation-Based V&V in Application for Maritime Traffic Systems.
Max Paul Bauer, Anthony Ngo & Michael Resch. (2021) The YASE Framework: Holistic Scenario Modeling with Behavior Trees. The YASE Framework: Holistic Scenario Modeling with Behavior Trees.
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Alexander Tenbrock, Alexander Konig, Thomas Keutgens & Hendrik Weber. (2021) The ConScenD Dataset: Concrete Scenarios from the highD Dataset According to ALKS Regulation UNECE R157 in OpenX. The ConScenD Dataset: Concrete Scenarios from the highD Dataset According to ALKS Regulation UNECE R157 in OpenX.
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Rong Guo, Ze Hong & Xiang Xue. Reward Function Design via Human Knowledge Graph and Inverse Reinforcement Learning for Intelligent Driving. Reward Function Design via Human Knowledge Graph and Inverse Reinforcement Learning for Intelligent Driving.
Maike Scholtes, Lukas Westhofen, Lara Ruth Turner, Katrin Lotto, Michael Schuldes, Hendrik Weber, Nicolas Wagener, Christian Neurohr, Martin Herbert Bollmann, Franziska Kortke, Johannes Hiller, Michael Hoss, Julian Bock & Lutz Eckstein. (2021) 6-Layer Model for a Structured Description and Categorization of Urban Traffic and Environment. IEEE Access 9, pages 59131-59147.
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Koichi Shimizu, Daisuke Suzuki, Ryo Muramatsu, Hisashi Mori, Tomoyuki Nagatsuka & Tsutomu Matsumoto. 2021. Computer Safety, Reliability, and Security. Computer Safety, Reliability, and Security 67 81 .
Christian Neurohr, Lukas Westhofen, Tabea Henning, Thies de Graaff, Eike Mohlmann & Eckard Bode. (2020) Fundamental Considerations around Scenario-Based Testing for Automated Driving. Fundamental Considerations around Scenario-Based Testing for Automated Driving.
Patrick Schneider, Martin Butz, Christian Heinzemann, Jens Oehlerking & Matthias Woehrle. (2020) Scenario-based threat metric evaluation based on the highd dataset. Scenario-based threat metric evaluation based on the highd dataset.
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