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Modern wireless technologies: problems of application for modernization of systems for the in-line diagnostics of gas pipelines
Iureva Radda Alekseevna
PhD in Technical Science
graduate student, Department of Safety of Information Technology, St. Petersburg National Research University of Information Technologies, Mechanics and Optics
197701, Russia, g. Saint Petersburg, Kronverkskii prospekt,, 49, kab. 231
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raddayurieva@gmail.com
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Vedernikov Kirill Alexandrovich
Master's degree student of the Department of Technogenic Security Systems and Technologies at ITMO University
197101, Russia, Saint Petersburg, str. Kronverksky Prospect, 49
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vedernikov@diakont.com
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Timko Andrei Sergeevich
student, Saint Petersburg National Research University of Information Technologies, Mechanics and Optics
197101, Russia, Saint Petersburg, str. Kronverkski Prospect, 49
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timko.andrew@gmail.com
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Perezyabov Oleg Arkadevich
assistant, Saint Petersburg National Research University of Information Technologies, Mechanics and Optics
197900, Russia, g. Saint Petersburg, ul. Kronverkskii, 49
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nurmanity@yandex.ru
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Abstract. Currently, the main method of monitoring of operating gas pipelines laid by the ground, has become in-line diagnostics, carried out by scanning their inner surface. The use of automated cyber-physical systems of non-destructive testing of gas pipelines will increase the level of man-made safety. The article discusses the types of wireless technologies, analyzes the effectiveness of using WFi technology to modernize the process of non-destructive testing of the pipeline in real time. A hypothesis is put forward on the operation of the pipeline as a waveguide for wireless data transmission. To solve this problem, the methods of data transfer theory, graph theory, analytical and simulation modeling are used. The scientific novelty consists in choosing and justifying the choice of using the method of transmitting data from non-destructive testing results over a wireless link in real time based on the analysis of transmitted data and existing technologies, as well as upgrading the design of the cyber-physical system for in-line diagnostics of the gas pipeline laid underground.
Keywords:
robotic system, data transfer, nondestructive testing, pipeline inspection, wireless technology, WiFi, cyberphysical system, visual diagnoistic, WiMax, laser profilometry
DOI: 10.25136/2306-4196.2018.4.27242
Article was received:
31-08-2018
Review date:
26-08-2018
Publish date:
15-09-2018
This article written in Russian. You can find full text of article in Russian
here
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