Georgios Kourtis scite author profile

The advent of sophisticated robotics and AI technology makes sending humans into hazardous and distant environments to carry out inspections increasingly avoidable. Being able to send a robot, rather than a human, into a nuclear facility or deep space is very appealing. However, building these robotic systems is just the start and we still need to carry out a range of verification and validation tasks to ensure that the systems to be deployed are as safe and reliable as possible. Based on our experience across three research and innovation hubs within the UK’s “Robots for a Safer World” programme, we present an overview of the relevant techniques and challenges in this area. As the hubs are active across nuclear, offshore, and space environments, this gives a breadth of issues common to many inspection robots.

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A Review of Verification and Validation for Space Autonomous Systems

Cardoso

Kourtis

Dennis

et al. 2021

Curr Robot Rep

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Purpose of Review The deployment of hardware (e.g., robots, satellites, etc.) to space is a costly and complex endeavor. It is of extreme importance that on-board systems are verified and validated through a variety of verification and validation techniques, especially in the case of autonomous systems. In this paper, we discuss a number of approaches from the literature that are relevant or directly applied to the verification and validation of systems in space, with an emphasis on autonomy. Recent Findings Despite advances in individual verification and validation techniques, there is still a lack of approaches that aim to combine different forms of verification in order to obtain system-wide verification of modular autonomous systems. Summary This systematic review of the literature includes the current advances in the latest approaches using formal methods for static verification (model checking and theorem proving) and runtime verification, the progress achieved so far in the verification of machine learning, an overview of the landscape in software testing, and the importance of performing compositional verification in modular systems. In particular, we focus on reporting the use of these techniques for the verification and validation of systems in space with an emphasis on autonomy, as well as more general techniques (such as in the aeronautical domain) that have been shown to have potential value in the verification and validation of autonomous systems in space.

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Parameterized verification of leader/follower systems via first-order temporal logic

Kourtis

Dixon

Fisher

et al. 2021

Form Methods Syst Des

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We introduce a framework for the verification of protocols involving a distinguished machine (referred to as a leader) orchestrating the operation of an arbitrary number of identical machines (referred to as followers) in a network. At the core of our framework is a high-level formalism capturing the operation of these types of machines together with their network interactions. We show that this formalism automatically translates to a tractable form of first-order temporal logic. Checking whether a protocol specified in our formalism satisfies a desired property (expressible in temporal logic) then amounts to checking whether the protocol’s translation in first-order temporal logic entails that property. Many different types of protocols used in practice, such as cache coherence, atomic commitment, consensus, and synchronization protocols, fit within our framework. First-order temporal logic also facilitates parameterized verification by enabling us to model such protocols abstractly without referring to individual machines.

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Correction: Parameterized verification of leader/follower systems via first-order temporal logic

Kourtis

Dixon

Fisher

et al. 2023

Form Methods Syst Des

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Verification for space robotics

Cardoso

Farrell

Kourtis

et al. 2021

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