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Journal Article
Modeling and Validating Foreseeable Misuse in Safety of the Intended Functionality: A Case Study of Automated Emergency Braking
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- Authors
- Do Wook Kang, Woojin Kim, Eun Hye Jang, Mi Chang, Daesub Yoon, Youn-Seon Jang
- Issue Date
- 2026-01
- Citation
- SAE International Journal of Connected and Automated Vehicles, v.9, no.3, pp.1-10
- ISSN
- 2574-0741
- Publisher
- SAE
- Language
- English
- Type
- Journal Article
- Abstract
- This study presents a structured evaluation framework for reasonably foreseeable misuse in automated driving systems (ADS), grounded in the ISO 21448 Safety of the Intended Functionality (SOTIF) lifecycle. Although SOTIF emphasizes risks that arise from system limitations and user behavior, the standard lacks concrete guidance for validating misuse scenarios in practice. To address this gap, we propose an end-to-end methodology that integrates four components: (1) hazard modeling via system–theoretic process analysis (STPA), (2) probabilistic risk quantification through numerical simulation, (3) verification using high-fidelity simulation, and (4) empirical validation via driver-in-the-loop system (DILS) experiments. Each component is aligned with specific SOTIF clauses to ensure lifecycle compliance. We apply this framework to a case of driver overreliance on automated emergency braking (AEB) at high speeds—a condition where system intervention is intentionally suppressed. Initial numerical analysis suggested that the scenario narrowly satisfies the acceptance criteria. Applying the proposed framework to this scenario reveals that significant safety risks can persist even when the system functions according to its design intent. Our findings demonstrate that foreseeable misuse can be formally modeled, simulated, and empirically validated within the SOTIF framework. The proposed approach enables system developers to quantify behavioral risk and assess human-centered edge cases with greater rigor. This work contributes to operationalizing SOTIF for behavioral safety assurance and lays the foundation for future research on risk mitigation through adaptive HMI and context-aware alerts.
- Keyword
- SOTIF, ISO 21448, Foreseeable misuse, Automated emergency braking, Driver-in-the-loop systems, Behavioral safety, STPA, Human–machine interaction, Risk validation, Automated driving systems
- KSP Keywords
- Acceptance criteria, Adaptive HMI, Automated driving systems, Automated emergency braking, Case studies, Context aware, Design intent, Empirical validation, End to End(E2E), Four components, High-fidelity simulation