Towards formal proofs of feedback control theory

Jasim, Omar A.; Veres, Sándor M.

doi:10.1109/icstcc.2017.8107009

“…-Applicability Theorem-proving has been widely used for software seen in the RuLes LayeR, and techniques such as Hoare Logic [107] and tools such as Isabelle [194] are often used there. Theorem-proving has been used for the Reactions LayeR, most notably verification of NASA's aerospace systems via PVS [97,188,189,199], verification of, e.g., automotive protocols through the KeyMaera system [201,202], and the use of theorem-proving tools to prove control system stability [159]. See [45] for an introduction to PVS specification for a Boeing autopilot.…”

Section: Verification Of Autonomous Software Systemsmentioning

confidence: 99%

Towards a framework for certification of reliable autonomous systems

Fisher

¹

,

Mascardi

²

,

Rozier

³

et al. 2020

Auton Agent Multi-Agent Syst

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A computational system is called autonomous if it is able to make its own decisions, or take its own actions, without human supervision or control. The capability and spread of such systems have reached the point where they are beginning to touch much of everyday life. However, regulators grapple with how to deal with autonomous systems, for example how could we certify an Unmanned Aerial System for autonomous use in civilian airspace? We here analyse what is needed in order to provide verified reliable behaviour of an autonomous system, analyse what can be done as the state-of-the-art in automated verification, and propose a roadmap towards developing regulatory guidelines, including articulating challenges to researchers, to engineers, and to regulators. Case studies in seven distinct domains illustrate the article.

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“…-Applicability Theorem-proving has been widely used for software seen in the RuLes LayeR, and techniques such as Hoare Logic [107] and tools such as Isabelle [194] are often used there. Theorem-proving has been used for the Reactions LayeR, most notably verification of NASA's aerospace systems via PVS [97,188,189,199], verification of, e.g., automotive protocols through the KeyMaera system [201,202], and the use of theorem-proving tools to prove control system stability [159]. See [45] for an introduction to PVS specification for a Boeing 737 autopilot.…”

Section: Verification Of Autonomous Software Systemsmentioning

confidence: 99%

Towards a framework for certification of reliable autonomous systems

Fisher¹,

Mascardi²,

Rozier³

et al. 2020

Preprint

View full text Add to dashboard Cite

A computational system is called autonomous if it is able to make its own decisions, or take its own actions, without human supervision or control. The capability and spread of such systems have reached the point where they are beginning to touch much of everyday life. However, regulators grapple with how to deal with autonomous systems, for example how could we certify an Unmanned Aerial System for autonomous use in civilian airspace? We here analyse what is needed in order to provide verified reliable behaviour of an autonomous system, analyse what can be done as the state-of-the-art in automated verification, and propose a roadmap towards developing regulatory guidelines, including articulating challenges to researchers, to engineers, and to regulators. Case studies in seven distinct domains illustrate the article.

show abstract

“…• Applicability: Theorem-proving has been widely used for software seen in the RULES LAYER, and techniques such as Hoare Logic [95] and tools such as Isabelle [178] are often used there. Theorem-proving has been used for the REACTIONS LAYER, most notably verification of NASA's aerospace systems via PVS [85,182,172,173], verification of, e.g., automotive protocols through the KeyMaera system [185,184], and the use of theorem-proving tools to prove control system stability [146]. See [44] for an introduction to PVS specification for a Boeing 737 autopilot.…”

Section: Consider Licensing Requirementsmentioning

confidence: 99%

Towards a Framework for Certification of Reliable Autonomous Systems

Fisher¹,

Mascardi²,

Rozier³

et al. 2020

Preprint

View full text Add to dashboard Cite

A computational system is called autonomous if it is able to make its own decisions, or take its own actions, without human supervision or control. The capability and spread of such systems have reached the point where they are beginning to touch much of everyday life. However, regulators grapple with how to deal with autonomous systems, for example how could we certify an Unmanned Aerial System for autonomous use in civilian airspace? We here analyse what is needed in order to provide verified reliable behaviour of an autonomous system, analyse what can be done as the state-of-the-art in automated verification, and propose a roadmap towards developing regulatory guidelines, including articulating challenges to researchers, to engineers, and to regulators. Case studies in seven distinct domains illustrate the article.

show abstract

Towards formal proofs of feedback control theory

Cited by 10 publications

References 21 publications

Towards a framework for certification of reliable autonomous systems

Towards a framework for certification of reliable autonomous systems

Towards a framework for certification of reliable autonomous systems

Towards a Framework for Certification of Reliable Autonomous Systems

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