NETWORK OF AUTONOMOUS MODULES FOR RELIABLE MONITORING OF COMPLEX INDUSTRIAL FACILITIES

O.A. Chemerys, O.V. Bushma, O.S. Lytvyn

Èlektron. model. 2021, 43(6):107-122

https://doi.org/10.15407/emodel.43.06.107

ABSTRACT

Authors consider the relevant and perspective IIoT (Industrial Internet-of-Things) development concept - a scalable heterogeneous network consisting of fixed and mobile nodes for monitoring the state of complex distributed technological ob-jects. Many issues must be solved comprehensively at designing and creating such a network. This is especially true for control systems, data transmission channels and data stream processing, their analysis, scalability, decision making. The paper describes a new concept for development of a multi-level architecture IoT network for monitoring the state of geographically distributed technological objects, consisting of a heterogeneous set of nodes (stationary and mobile units) equipped with various sensors and video cameras.

KEYWORDS

monitoring, Internet of things, security of industrial facilities, distributed information system.

REFERENCES

1. Mosyagin, A.A. (2009), “Monitoring of potentially dangerous objects based on logical and proba-bilistic modeling”, Abstract of Cand. Sci. (Tech.), Academy of the Ministry of Internal Affairs, Moscow, Russia, available at: https://tekhnosfera.com/view/309856/a?#?page=1
2. Solozhentsev, E.D. (2004), Stsenarnoye logiko-veroyatnostnoye upravleniye riskom v biznese i tekhnike [Scenario logic-probabilistic risk management in business and technology], Izd. dom “Biznes-pressa”, Saint Petersburg, Russia.
3. Tkachenko, T.E. (2013), “Monitoring of industrial objects as the basis for the prevention of techno-genic emergencies”, Scientific and educational problems of civil protection, Vol. 1, pp. 62-65, available at: https://cyberleninka.ru/article/ n/monitoringpromyshlennyh-obektov-kak-osnova-preduprezhdeniya-chrezvychaynyh-situa- tsiy-tehnogennogoharaktera
4. Predictive Emission Monitoring Systems Monitoring Emissions from Industry (2019), ABB measurement & Analytics, available at: https://library.e.abb.com/public/ 8d5f837418774f4a83d61cbc935c49e0/PB_PEMS-EN_A.pdf
5. Rakesh, T. and Vishal, V. (2013), “Real-Time Monitoring and Control System for Industry”, IJSRD - International Journal for Scientific Research & Development, Vol. 1, no. 2, pp. 142-147, available at: https://www.academia.edu/ 6792977/Real_Time_Monitoring_ and_Control_System_for_Industry
6. Russell, J. (2019), “Facebook is reportedly testing solar-powered internet drones again — this time with Airbus”, Retrieved, available at: https://techcrunch.com/ 2019/ 01/21/facebook-airbus-solar-drones-internet-program/
7. UAVIA Releases Its “Uavia Inside” Program For Drone Solutions Providers (2019), Paris, France, available at: https://www.uavia.eu/PR_20190506_ UAVIA_INSIDE
8. Kharchenko, V., Yastrebenetsky, M., Fesenko, H., Sachenko, A. and Kochan, V. (2017), “NPP Post-Accident Monitoring System Based on Unmanned Aircraft Vehicle: Reliability Models”, Nuclear and Radiation Safety, Vol. 4, no. 76, pp. 50-55.
   https://doi.org/10.32918/nrs.2017.4(76).08
9. Sachenko, A., Kochan, V., Kharchenko, V., Yastrebenetsky, M., Fesenko, H. and Yanovsky, M. (2017), “NPP Post-Accident Monitoring System Based on Unmanned Aircraft Vehicle: Concept, Design Principles”, Nuclear and Radiation Safety, Vol. 1, no. 73, pp. 24-29, available at: 
   https://doi.org/10.32918/nrs.2017.1(73).04
10. Younana, M., Housseina, E.H., Elhoseny, M. and Alia, A.A. (2020), “Challenges and recommended technologies for the industrial internet of things: A comprehensive review”, Measurement, Vol. 151, available at:
    https://doi.org/10.1016/j.measurement.2019.107198
11. Grösser, S.N. (2017), Complexity Management and System Dynamics Thinking, Springer, Cham, Switzerland, available at: 
    https://doi.org/10.1007/978-3-319-45438-2_5
12. Pevnev, V.Ya., Torianyk, V.V. and Kharchenko, V.S. (2020), “Cybersecurity of wireless smart systems: channels of interference and radio frequency vulnerabilities”, Radioelektronni i kompʼyuterni systemy, Vol. 4, no. 96, pp. 79-92, 
    https://doi.org/10.32620/reks.2020.4.07
    
13. EN 1990:2002 E, Eurocode — Basis of Structural Design, CEN (2005), available at: https://www.phd.eng.br/wp-content/uploads/2015/12/en.1990.2002.pdf.
14. SSTU 2862-94 Reliability of equipment. Methods of calculating reliability indicators. General requirements, available at: https:// dnaop.com/ html/43856/doc-ДСТУ_2864-94.
15. Vincent, G. Duffy (2016), Handbook of Digital Human Modeling: Research for Applied Ergonomics and Human Factors Engineering, CRC Press.
    https://doi.org/10.1201/9781420063523
    
16. Cruz, Pedro Miguel Amaral Melo da (2016), “Semantic figurative metaphors in information visualization”, Abstract of Cand. Sci. (Tech.), Coimbra, Portugal, available at: www: http://hdl.handle.net/10316/31166.
17. Bushma, A.V. and Turukalo, A.V. (2020), “Software controlling the LED bar graph displays”, Semi-conductor Physics, Quantum Electronics & Optoelectronics, Vol. 23, no. 3, pp. 329-335, available at:
    https://doi.org/10.15407/spqeo23.03.329
18.  Bushma, O.V. and Turukalo, A.V. (2021), “Multi-element scale indicator devices in embedded systems”, Kiberbezpeka: osvita, nauka, tekhnika, Vol. 3, no. 11, pp. 43-60.
    https://doi.org/10.28925/2663-4023.2021.11.4360
    

Full text: PDF