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The use of abstract moore automaton to control the sensors of a service-oriented alarm and emergency notification network

НазваThe use of abstract moore automaton to control the sensors of a service-oriented alarm and emergency notification network
Назва англійськоюThe use of abstract moore automaton to control the sensors of a service-oriented alarm and emergency notification network
АвториOlha Kryazhych, Victoria Itskovych, Kateryna Iushchenko, Veronika Hrytsyshyna, Danylo Bruvier, Vyacheslav Nykytyuk, Ihor Bodnarchuk
ПринадлежністьInstitute of Telecommunications and Global Information Space of National Academy of Sciences of Ukraine, Kyiv, Ukraine Ternopil Ivan Puluj National Technical University, Ternopil, Ukraine Institute of Telecommunications and Global Information Space of National Academy of Sciences of Ukraine, Kyiv, Ukraine Volodymyr Dahl East Ukrainian National University, Severodonetsk, Ukraine
Бібліографічний описThe use of abstract moore automaton to control the sensors of a service-oriented alarm and emergency notification network / Olha Kryazhych, Victoria Itskovych, Kateryna Iushchenko, Veronika Hrytsyshyna, Danylo Bruvier, Vyacheslav Nykytyuk, Ihor Bodnarchuk // Scientific Journal of TNTU. — Tern.: TNTU, 2023. — Vol 109. — No 1. — P. 111–120.
Bibliographic description:Kryazhych O., Itskovych V., Iushchenko K., Hrytsyshyna V., Bruvier D., Nykytyuk V., Bodnarchuk I. (2023) The use of abstract moore automaton to control the sensors of a service-oriented alarm and emergency notification network. Scientific Journal of TNTU (Tern.), vol 109, no 1, pp. 111–120.
DOI: https://doi.org/10.33108/visnyk_tntu2023.01.111
УДК

004.415

Ключові слова

Aufenkamp-Honu algorithm, equivalence, trigger, synchronous transition, graph, signal, combination, parameter.

The paper aims to achieve the ability of an abstract Moore automaton to control the sensors of a service-oriented alarm system for notification of emergency situations in a metropolis. An important procedure is minimization of the internal settings of the automaton, on the basis of which there will be a graph of transitions to the machine for which a synchronous trigger is turned on – a switch between sensors, - which allows not only to receive information, but also to confirm that it is necessary to notify about the current emergency situation. The relevance of those proves the need for security of living in the urban environment. Constant monitoring of the parameters of the medium is of high necessity. This allows to balance the key factors influencing the system in order to make a sound management decision. The possible ways of using an abstract Moore automaton to control the sensors of a service-oriented alarm system about emergency situations in a metropolis is analysed.

ISSN:2522-4433
Перелік літератури
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References:
  1. British Standards Institution. URL: https://www.bsigroup.com/.
  2. Batty M. et al. 2012. Smart Cities of the Future. European Physical Journal ST. 214: 481–518. Doi:10.1140/epjst/e2012-01703-3.
  3. Maksymov A., Vakhovych I., Hutnichenko T., Babicheva P., Vakulenko N., Iholnikova N., Tsyfra T.,
    Molodid O., Molodid O., Bielienkova O., Iachmenova Yu., Doroshuk Yu., Skrypnyk A., Vakoliuk A.,
    Boiko V., Sehedii M., Vakhovych D. Enerhoefektyvnist v munitsypalnomu sektori. Navchalnyi posibnyk dlia posadovykh osib mistsevoho samovriaduvannia. Asotsiatsiia mist Ukrainy. K.: TOV “Pidpryiemstvo “VI EN EI”, 2015. 184 p. [In Ukrainian].
  4. Raza U., Kulkarni P., Sooriyabandara M., Low power wide area networks: an overview, IEEE Commun. Surv. Tutor. 19 (2). 2017. P. 855–873. URL: http://dx.doi.org/10.1109/COMST.2017.2652320.
  5. LoRaWAN Specification. v1.1, LoRa Alliance/ 2017. URL: https://lora-alliance.org/resource_hub/lorawan-specification-v1-1/.
  6. Ploennigs J., Cohn J., Stanford-Clark А., The future of IoT, IEEE Internet Things Mag. 1 (1). 2018. P. 28–33. URL: http://dx.doi.org/10.1109/IOTM.2018.1700021.
  7. Shepard, Mark 2011. Sentient City: Ubiquitous Computing, Architecture, and the Future of Urban Space. New York City. Architectural League of New York. The Architect's Newspaper. ISBN 978-0262515863.
  8. Zghurovskyi M. Z., Pankratova N. D. Systemnyi analiz. Problemy, metodolohiia zastosuvannia. K.: “Naukova dumka”, 2011. 728 p. [In Ukrainian].
  9. Gill A. Vvedenie v teoriyu konechnikh avtomatov. M.: Nauka, 1966. 272 p. [In Russian].
  10. Glushkov V. M. Abstraktnaya teoriya avtomatov, UMN, 16:5(101) (1961), 3–62; Russian Math. Surveys, 16:5 (1961), 1–53. [In Russian].
  11. Aufenkamp D. D., Khon F. Ye., Analiz posledovatelnostnikh mashin. Matematika, 3:3 (1959), 129–148; IRE Trans., 6 (1957), 276–285. [in Russian].
  12. Glushkov V. M. Sintez tsifrovikh avtomatov. M.: GIFML, 1962. 476 p. [In Russian].
  13. Butsiy R., Lupenko S. Comparative analysis of neurointerface technologies for the problem of their reasonable choice in human-machine information systems. Scientific Journal of TNTU. 2020. Vol. 100. No 4. P. 135–148.
  14. Yemets V. Technological systems investigation machines tools with parallel structure kinematic. Scientific Journal of TNTU. 2021. Vol. 102. No. 2. P. 37–44.
  15. Mano, M. Morris; Kime, Charles R. 2004. Logic and Computer Design Fundamentals, 3rd Edition. Upper Saddle River, NJ, USA: Pearson Education International. P. 283. ISBN 0-13-191165-1.
  16. Lukac M., Kameyam M., Perkowskі M. Quantum Finite State Machines – a Circuit Based Approach. International Journal of Unconventional Computing. 2013. Vol. 9. Issue 3/4. P. 267–301. 35 p.
  17. Elshabrawy T., Robert J. Interleaved chirp spreading lora-based modulation, IEEE Internet Things J. 6 (2). 2019. P. 3855–3863. URL: http://dx.doi.org/10.1109/.
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