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Formal verification of robustness and resilience of learning-enabled state estimation systems
This paper presents a formal verification guided approach for a principled design and implementation of robust and resilient learning-enabled systems. We focus on learning-enabled state estimation systems (LE-SESs), which have been widely used in robotics applications to determine the current state (e.g., location, speed, direction, etc.) of a complex system. The LE-SESs are networked systems, composed of a set of connected components including: Bayes filters for state estimation, and neural networks for processing sensory input. We study LE-SESs from the perspective of formal verification, which determines the satisfiabilty of a system model against the specified properties. Over LE-SESs, we investigate two key properties – robustness and resilience – and provide their formal definitions. To enable formal verification, we reduce the LE-SESs to a novel class of labelled transition systems, named {PO}2-LTS in the paper, and formally express the properties as constrained optimisation objectives. We prove that the verification problems are NP-complete. Based on {PO}2-LTS and the optimisation objectives, practical verification algorithms are developed to check the satisfiability of the properties on the LE-SESs. As a major case study, we interrogate a real-world dynamic tracking system which uses a single Kalman Filter (KF) – a special case of Bayes filter – to localise and track a ground vehicle. Its perception system, based on convolutional neural networks, processes a high-resolution Wide Area Motion Imagery (WAMI) data stream. Experimental results show that our algorithms can not only verify the properties of the WAMI tracking system but also provide representative examples, the latter of which inspired us to take an enhanced LE-SESs design where runtime monitors or joint-KFs are required. Experimental results confirm the improvement in the robustness of the enhanced design.
Funding
UK Robotics and Artificial Intelligence Hub for Offshore Energy Asset Integrity Management
Department for Business, Energy and Industrial Strategy
Find out more...EnnCore: End-to-End Conceptual Guarding of Neural Architectures
Engineering and Physical Sciences Research Council
Find out more...UK Dstl projects on Test Coverage Metrics for Artificial Intelligence
National Key Research and Development Program of China (Project No. 2022YFB4500900)
History
School
- Loughborough University, London
Published in
NeurocomputingVolume
585Issue
2024Publisher
ElsevierVersion
- AM (Accepted Manuscript)
Rights holder
© ElsevierPublisher statement
This paper was accepted for publication in Neurocomputing published by Elsevier. The final publication is available at https://doi.org/10.1016/j.neucom.2024.127643. This manuscript version is made available under the CC-BY-NC-ND 4.0 license https://creativecommons.org/licenses/by-nc-nd/4.0/Acceptance date
2024-03-29Publication date
2024-04-03Copyright date
2024ISSN
0925-2312eISSN
1872-8286Publisher version
Language
- en