Efficient Determination of Safety Requirements for Perception Systems

Perception systems operate as a subcomponent of the general autonomy stack, and perception system designers often need to optimize performance characteristics while maintaining safety with respect to the overall closed-loop system. For this reason, it is useful to distill high-level safety requireme...

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Main Authors: Katz, Sydney M., Corso, Anthony L., Yel, Esen, Kochenderfer, Mykel J.
Format: Conference Proceeding
Language:English
Subjects:
Aerospace electronics
black-box estimation
Closed box
Estimation
Gaussian processes
perception
Safety
Smoothing methods
System performance
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Corso, Anthony L.
Yel, Esen
Kochenderfer, Mykel J.
description Perception systems operate as a subcomponent of the general autonomy stack, and perception system designers often need to optimize performance characteristics while maintaining safety with respect to the overall closed-loop system. For this reason, it is useful to distill high-level safety requirements into component-level requirements on the perception system. In this work, we focus on efficiently determining sets of safe perception system performance characteristics given a black-box simulator of the fully-integrated, closed-loop system. We combine the advantages of common black-box estimation techniques such as Gaussian processes and threshold bandits to develop a new estimation method, which we call smoothing bandits. We demonstrate our method on a vision-based aircraft collision avoidance problem and show improvements in terms of both accuracy and efficiency over the Gaussian process and threshold bandit baselines.
doi_str_mv 10.1109/DASC58513.2023.10311157
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subjects Aerospace electronics
black-box estimation
Closed box
Estimation
Gaussian processes
perception
Safety
Smoothing methods
System performance
title Efficient Determination of Safety Requirements for Perception Systems
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