Safety model construction for a complex automatic transportation system

Ozerov, Alexey; Ol'Shanskii, A. M.

doi:10.21683/1729-2646-2021-21-2-31-37

Cited by 6 publications

(2 citation statements)

References 5 publications

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“…Further evolution of Rail Operations Control Centres, taking into account the target state of ROCC 4.0, involves the automation of intelligent control functions, i.e. the implementation of real-time control systems based on artificial intelligence (machine learning), Big Data processing methods and predictive analytics [4]. ROCC 4.0 is in fact a control model with constant feedback, and the target state can be achieved by expanding the feedback and increasing the efficiency and reliability of information through the application of different control, monitoring and diagnostics tools, including mobile (for example, drones with computer vision and other tools for video and photo recording) and fixed devices (computer vision systems at passenger and freight stations, integrated checkpoints for diagnostic and monitoring rolling stock at marshalling yards, distributed acoustic sensing systems for fiber optic lines, etc.…”

Section: Discussionmentioning

confidence: 99%

Evolution of Rail Operations Control Centres

Розенберг

Ozerov

2022

JITA

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The article gives an overview of the evolution trends and stages of rail operations control centres (ROCCs) and outlines their future development and challenges in the context of the digital transformation of railway transport. It addresses the key aspects of further evolution of ROCCs in terms of closer integration of various functional layers and systems, automation of control and supervision functionalities, application of new data processing methods based on artificial intelligence.

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Section: Discussionmentioning

confidence: 99%

Evolution of Rail Operations Control Centres

Розенберг

Ozerov

2022

JITA

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“…This happens because the strategy to compute an accident probability requires the exclusion of critical causal factors that are not stochastic or do not have probabilistic data. Therefore, STPA aims to investigate unsafe control actions by identifying the path to accidents or risk scenarios (Ozerov et al, 2021). Then, it incorporates causal factors that traditional analysis techniques do not fully consider, such as: uncontrolled component interactions, incorrect requirements, insufficient coordination between multiple controllers, and poor decision management (Plioutsias et al, 2018).…”

Section: Safety Analysismentioning

confidence: 99%

Digital Twins for Trust Building in Autonomous Drones through Dynamic Safety Evaluation

Iqbal¹,

Bühnová²,

Cioroaica³

2023

Preprint

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The adoption process of innovative software-intensive technologies leverages complex trust concerns in different forms and shapes. Perceived safety plays a fundamental role in technology adoption, being especially crucial in the case of those innovative software-driven technologies characterized by a high degree of dynamism and unpredictability, like collaborating autonomous systems. These systems need to synchronize their maneuvers in order to collaboratively engage in reactions to unpredictable incoming hazardous situations. That is however only possible in the presence of mutual trust. In this paper, we propose an approach for machineto-machine dynamic trust assessment for collaborating autonomous systems that supports trust-building based on the concept of dynamic safety assurance within the collaborative process among the software-intensive autonomous systems. In our approach, we leverage the concept of digital twins which are abstract models fed with real-time data used in the run-time dynamic exchange of information. The information exchange is performed through the execution of specialized models that embed the necessary safety properties. More particularly, we examine the possible role of the Digital Twins in machine-to-machine trust building and present their design in supporting dynamic trust assessment of autonomous drones. Ultimately, we present a proof of concept of direct and indirect trust assessment by employing the Digital Twin in a use case involving two autonomous collaborating drones.

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Improving the Reliability of Automotive Systems

Gumiel

2024

Recent Advances in Microelectronics Reliability

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Safety model construction for a complex automatic transportation system

Cited by 6 publications

References 5 publications

Evolution of Rail Operations Control Centres

Evolution of Rail Operations Control Centres

Digital Twins for Trust Building in Autonomous Drones through Dynamic Safety Evaluation

Improving the Reliability of Automotive Systems

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