Related papers: Systematic Hazard Analysis for Frontier AI using STPA

Systematic Hazard Analysis for Frontier AI using STPA

URL: http://arxiv.org/abs/2506.01782v1
Date: Mon, 02 Jun 2025 15:28:34 GMT
Title: Systematic Hazard Analysis for Frontier AI using STPA
Authors: Simon Mylius,
Abstract summary: frontier AI companies currently do not describe in detail any structured approach to identifying and analysing hazards.<n>A (Systems-Theoretic Process Analysis) is a systematic methodology for identifying how complex systems can become unsafe, leading to hazards.<n>We evaluateA's ability to broaden the scope, improve traceability and strengthen the robustness of safety assurance for frontier AI systems.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: All of the frontier AI companies have published safety frameworks where they define capability thresholds and risk mitigations that determine how they will safely develop and deploy their models. Adoption of systematic approaches to risk modelling, based on established practices used in safety-critical industries, has been recommended, however frontier AI companies currently do not describe in detail any structured approach to identifying and analysing hazards. STPA (Systems-Theoretic Process Analysis) is a systematic methodology for identifying how complex systems can become unsafe, leading to hazards. It achieves this by mapping out controllers and controlled processes then analysing their interactions and feedback loops to understand how harmful outcomes could occur (Leveson & Thomas, 2018). We evaluate STPA's ability to broaden the scope, improve traceability and strengthen the robustness of safety assurance for frontier AI systems. Applying STPA to the threat model and scenario described in 'A Sketch of an AI Control Safety Case' (Korbak et al., 2025), we derive a list of Unsafe Control Actions. From these we select a subset and explore the Loss Scenarios that lead to them if left unmitigated. We find that STPA is able to identify causal factors that may be missed by unstructured hazard analysis methodologies thereby improving robustness. We suggest STPA could increase the safety assurance of frontier AI when used to complement or check coverage of existing AI governance techniques including capability thresholds, model evaluations and emergency procedures. The application of a systematic methodology supports scalability by increasing the proportion of the analysis that could be conducted by LLMs, reducing the burden on human domain experts.

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