T-Comm_Article 8_8_2021

Извините, этот техт доступен только в “Американский Английский”. For the sake of viewer convenience, the content is shown below in the alternative language. You may click the link to switch the active language.

THE ARCHITECTURE OF SMART HOME INTERNET OF THINGS

Al namer Zainal, Moscow Technical University of Communications
and Informatics, Moscow, Russia, zainalnamer29@gmail.com

Abstract
Modern society lives in the age of high and smart technologies. Innovative technologies are included in every part of our life. Almost all people use the innovations of scientific and technological progress in order to reduce costs, effort and time. Smart technology – a new approach to the organization of its goals, which allows to combine all available information at an early stage, to determine the list of necessary materials, set deadlines for execution of works and perform the task and clear to all participants of the process. Smart Home is a solution in which the operation and control of all systems at the level of an individual household is automated, providing a specific room with a high level of security and all the necessary living conditions, while remotely without unnecessary interference from service organizations. The building is equipped with special monitors with sensors that help detect threats to both the system and the residents themselves. One of the popular and developing trends and technologies in the Internet of Things today is «Smart- Home Internet of Things» (smart home of the Internet of Things) – SH-IoTs, which is designed for the most comfortable life of people through the use of modern high-tech means. In the modern concept of the smart home system of the Internet of Things SH-IoTs, as a rule, they invest in the automation of everyday, routine actions. For example, in the event of a fire in a room with special sensors installed, the smart home system will de-energize all electrical appliances in this room, etc.

Keywords: Smart home, smart buildings, smart devices, gateway, network topology.

References

1. S. Goldstein, A.E. Kucheryavy (2013). Communication networks post NGN. St. Petersburg: BHV-S. Petersburg. 160 p.
2. V. Roslyakov, S.V. Vanyashin, A.Y. Grebeshkov, M.Yu. Samsonov (2014). Internet of Things. Samara: PSUTI, As Guard Publishing House. 342 p.
3. Suresh and P. V. Sruthi (2015), “A review on smart home technology,” in 2015 Online International Conference on Green Engineering and Technologies (IC-GET), Nov 2015, pp. 1-3.
4. Lobaccaro, S. Carlucci, and E. Löfström (2016), “A review of systems and technologies for smart homes and smart grids,” Energies, vol. 9, no. 5, pp. 1-33.
5. Saad al-sumaiti, M.H. Ahmed, and M.M. A. Salama (2014), “Smart Home Activities: A Literature Review,” Electr. Power Components Syst., vol. 42, no. 3-4, pp. 294-305.
6. Double-Digit Growth Expected in the Smart Home Market. https: //www.idc.com/getdoc.jsp?containerId=prUS44971219, March 2019.
7. Cisco Visual Networking Index: Forecast and Trends, 2017–2022, White Paper, 2019.
8. Sivanathan, H. H. Gharakheili, F. Loi, A. Radford, C. Wijenayake, A. Vishwanath, and V. Sivaraman (2018). Classifying IoT Devices in Smart Environments Using Network Traffic Characteristics. In IEEE Transactions on Mobile Computing’18.
9. Ortiz, C. Crawford, and F. Le (2019). DeviceMien: network device behavior modeling for identifying unknown IoT devices. In ACM IoTDI’19.
10. M. Antonakakis, T. April, M. Bailey, M. Bernhard, E. Bursztein, J. Cochran, Z. Durumeric, J. A. Halderman, L. Invernizzi, M. Kallitsis, D. Kumar, C. Lever, Z. Ma, J. Mason, D. Menscher, C. Seaman, N. Sullivan, K. Thomas, and Y. Zhou (2017). Understanding the Mirai Botnet. In USENIX Security’17.
11. Franceschi-Bicchierai (2016). How 1.5 Million Connected Cameras hijacked to make an Unprecedented Botnet. https://motherboard.vice.com/en us/article/8q8dab/15-millionconnected- cameras-ddos-botnet-brian-krebs.
12. Chu, N. Apthorpe, and N. Feamster (2019). Security and Privacy Analyses of Internet of Things Childrens Toys. IEEE Internet of Things’19.
13. Wood, N. Apthorpe, and N. Feamster (2017). Cleartext Data Transmissions in Consumer IoT Medical Devices. In ACM Workshop on Internet of Things Security and Privacy (IoT S&P)’17.
14. Ren, D. J. Dubois, D. Choffnes, A. M. Mandalari, R. Kolcun, and H. Haddadi (2019). Information Exposure from Consumer IoT Devices. In ACM IMC’19.
15. Alrawi, C. Lever, M. Antonakakis, and F. Monrose (2019). SoK: Security Evaluation of Home-Based IoT Deployments. In IEEE Symposium on Security and Privacy (S&P)’19.
16. Marikyan, S. Papagiannidis, and E. Alamanos (2019), »A systematic review of the smart home literature: A user perspective,» Technol. Forecasting Social Change, vol. 138, pp. 139-154, Jan. 2019.
17. Pfeffer (2016), »Dynamic changing tier service on test device,» U.S. Patent 9 425 977, Aug. 23, 2016.
18. (2018). Internet Connection and Recommended Encoding Settings. Accessed: Dec. 16, 2018 [Online]. Available: https://support.video. ibm.com/hc/en-us/articles/207852117-Internet-connection-andrecommended- encoding-settings.
19. Leister, P. A. Floor, Y. B. Woldegiorgis, I. Balasingham, and H. Abie (2012), »De_ning the asset lab,» Norsk Regnesentral, Norway, Tech. Rep., 2012. [Online]. Available: http://publications.nr.no/1362402875/DART-16-2012.pdf.

Information about author:

Al namer Zainal, PhD student, Moscow Technical University of Communications and Informatics, Moscow, Russia