Learning Vision-Based Neural Network Controllers with Semi-Probabilistic Safety Guarantees

Xinhang Ma; Junlin Wu; Hussein Sibai; Yiannis Kantaros; Yevgeniy Vorobeychik

doi:10.1609/aaai.v40i42.40882

Authors

Xinhang Ma Washington University in St. Louis
Junlin Wu Washington University in St. Louis
Hussein Sibai Washington University in St. Louis
Yiannis Kantaros Washington University in St. Louis
Yevgeniy Vorobeychik Washington University in St. Louis

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https://doi.org/10.1609/aaai.v40i42.40882

Abstract

Ensuring safety in autonomous systems with vision-based control remains a critical challenge due to the high dimensionality of image inputs and the fact that the relationship between true system state and its visual manifestation is unknown. Existing methods for learning-based control in such settings typically lack formal safety guarantees. To address this challenge, we introduce a novel semi-probabilistic verification framework that integrates reachability analysis with conditional generative networks and distribution-free tail bounds to enable efficient and scalable verification of vision-based neural network controllers. Next, we develop a gradient-based training approach that employs a novel safety loss function, safety-aware data-sampling strategy to efficiently select and store critical training examples, and curriculum learning, to efficiently synthesize safe controllers in the semi-probabilistic framework. Empirical evaluations in X-Plane 11 airplane landing simulation, CARLA-simulated autonomous lane following, F1Tenth vehicle lane following in a physical visually-rich miniature environment, and Airsim-simulated drone navigation and obstacle avoidance demonstrate the effectiveness of our method in achieving formal safety guarantees while maintaining strong nominal performance.

Learning Vision-Based Neural Network Controllers with Semi-Probabilistic Safety Guarantees

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