Development of a new wireless communication standard for local needs

Cover Page

Cite item

Full Text

Open Access Open Access
Restricted Access Access granted
Restricted Access Subscription or Fee Access

Abstract

Modern local area networks of the Wi-Fi standard have many advantages: high communication speed, mobility and a large number of simultaneously connected devices. Nevertheless, there is a significant drawback of this standard related to the small communication radius, which significantly limits the scope of this technology. First of all, this concerns the connection of Internet of Things (IoT) devices. For these purposes, it is necessary to develop separate standards, for example: LPWAN, NB-IoT, LoRA and others. This article substantiates the possibility of using the DECT standard as a universal standard for the IoT, digital telephony, etc. The paper formulates the basic requirements for a wireless network for local needs, such as an extended communication radius, an unfilled frequency spectrum, and energy-saving capabilities. It is shown that DECT satisfies all conditions well. The fundamental possibility of encapsulating MQTT messages in SIP messages is demonstrated. A new communication scheme has been proposed that allows for the transmission of MQTT control messages to an IoT sensor. It describes how the delivery of IoT control messages based on subscriber numbers in SIP can be implemented. The proposed communication scheme allows simultaneous provision of two communication services: radiotelephony and last mile for wireless connection of IoT devices. The application of the proposed solution for the creation of remote laboratories for the research and study of IoT networks and DECT technology is described.

About the authors

E. S. Sagatov

Samara National Research University; Volga Region State University of Telecommunications and Informatics; HSE University

Author for correspondence.
Email: sagatov@ya.ru

Ph.D., Associate Professor

Russian Federation, Samara, 443086; Samara, 443010; Moscow, 123458

N. I. Vinogradov

Samara National Research University; Volga Region State University of Telecommunications and Informatics; HSE University

Email: ampelos@list.ru

Ph.D., Associate Professor

Russian Federation, Samara, 443086; Samara, 443010; Moscow, 123458

A. M. Sukhov

Samara National Research University; Volga Region State University of Telecommunications and Informatics; HSE University

Email: sukhov@ssau.ru

Dr. Sc., Senior Researcher

Russian Federation, Samara, 443086; Samara, 443010; Moscow, 123458

O. V. Urazova

Samara National Research University; Volga Region State University of Telecommunications and Informatics; HSE University

Email: urazova.oksana2017@yandex.ru

Student

Russian Federation, Samara, 443086; Samara, 443010; Moscow, 123458

A. A. Americanov

Samara National Research University; Volga Region State University of Telecommunications and Informatics; HSE University

Email: aamerikanov@hse.ru

Ph.D., Associate Professor

Russian Federation, Samara, 443086; Samara, 443010; Moscow, 123458

References

  1. Mozaffariahrar E., Theoleyre F., Menth M. A survey of Wi-Fi 6: Technologies, advances, and challenges, Future Internet, 2022, vol. 14, no. 10, Art. No. 293.
  2. Venu D. N., Arun Kumar A., Vaigandla K. K. Review of internet of things (iot) for future generation wireless communications, International Journal for Modern Trends in Science and Technology, 2022, vol. 8, no. 03, pp. 01—08.
  3. Aboubakar M., Kellil M., Roux P. A review of IoT network management: Current status and perspectives, Journal of King Saud University-Computer and Information Sciences, 2022, vol. 34, no. 7, pp. 4163—4176.
  4. Hukkeri G. S. et al. The Impact of Protocol Conversions in the Wireless Communication of IOT Network, International Journal of Advances in Soft Computing & Its Applications, 2024, vol. 16, no. 1, pp. 18—39.
  5. Showail A. et al. An internet of secure and private things: A service-oriented architecture, Computers & Security, 2022, vol. 120, Art. No. 102776.
  6. Mekhanik A. Microcircuits are being prepared for domestic printing, Expert, 2022, no. 12 (1245), pp. 36—41.
  7. Al-Shareeda M. A. et al. Bluetooth low energy for internet of things: review, challenges, and open issues, Indonesian Journal of Electrical Engineering and Computer Science, 2023, vol. 31, no. 2, pp. 1182—1189”
  8. Alipio M., Bures M. Current testing and performance evaluation methodologies of LoRa and LoRaWAN in IoT applications: Classification, issues, and future directives, Internet of thin/ss, 2024, vol. 25, Art. No. 101053.
  9. Muteba K. F., Djouani K., Olwal T. 5G NB-IoT: Design, considerations, solutions and challenges, Procedia Computer Science, 2022, vol. 198, pp. 86—93.
  10. Stanco G. et al. On the performance of IoT LPWAN technologies: the case of Sigfox, LoRaWAN and NB-IoT, ICC 2022-IEEE International Conference on Communications, IEEE, 2022, pp. 2096—2101.
  11. Tunegolovets D. K. Assessment of applicability of lorawan technologies for the organization of a backup communication channel for meteorological support of airfields, Bulletin of Voronezh State Technical University, 2021, vol. 17, no. 5, pp. 25—31.
  12. Islam M. et al. Future Industrial Applications: Exploring LPWAN-Driven IoT Protocols, Sensors, 2024, vol. 24, no. 8, Art. No. 2509.
  13. Makhmutov A. R., Vulfin A. V. M. M., Mironov K. V. Investigation of autonomous operation capabilities of the Internet of Things end-devices, System Engineering and Information Technologies , 2023, vol. 5, no. 1 (10), pp. 41—47.
  14. Sukhov A., Sorokin I., Meil D. New life for cordless communication, old regrets for software projects, Communications of the ACM, 2021, vol. 64, no. 10, pp. 6—7.
  15. Petrenko S. et al. Development of a Cyber-Resistant Platform for the Internet of Things Based on Dynamic Control Technology, Futuristic Trends in Network and Communication Technologies: Third International Conference, FTNCT 2020, Taganrog, Russia, October 14—16, 2020, Revised Selected Papers, Part I 3, Springer Singapore, 2021, pp. 144—154.
  16. Ebraheem A., Ivanov I. Towards automated and optimal IIoT design, Informatics and Automation, 2024, vol. 23, no. 2, pp. 377—406.
  17. Zinovieva O. M. et al. Digitalization of industrial safety management systems in mining, Mining information and analytical bulletin (scientific and technical journal), 2021, no. 2-1, pp. 113—123.
  18. Penner M., Nabeel M., Peissig J. URLLC performance evaluation of IMT-2020 candidate technology: DECT-2020 new radio, 2021 IEEE 94th Vehicular Technology Conference (VTC2021-Fall), IEEE, 2021, pp. 1—7.
  19. Samuylov A. et al. Performance Assessment of DECT-2020 NR and Classic DECT Coexistence Mechanisms, 2023 IEEE 97th Vehicular Technology Conference (VTC2023-Spring), IEEE, 2023, pp. 1—7.
  20. Hong Y. G. et al. RFC 9453 Applicability and Use Cases for IPv6 over Networks of Resource-constrained Nodes (6lo), 2023, 24 p.
  21. Muchaxo A. et al. Wireless data communications using DECT air interface, ACM SIGCOMM Computer Communication Review, 1999, vol. 29, no. 2, pp. 24—40.
  22. Sinyavskiy I. V., Sorokin I. M., Sukhov A. M. Prototype wireless network for internet of things based on DECT standard, Telfor Journal, 2022, vol. 14, no. 1, pp. 8—11.
  23. Marin M. C. et al. A Multi-Protocol IoT Platform for Enhanced Interoperability and Standardization in Smart Home, 2024 IEEE 21st Consumer Communications & Networking Conference (CCNC), IEEE, 2024, pp. 1—6.
  24. Romanov A. Y. Ed. Digital Synthesis: RISC-V, Moscow, DMK Press, 2024, 636 p.
  25. Cui E., Li T., Wei Q. RISC-V instruction set architecture extensions: A survey, IEEE Access, 2023, vol. 11, pp. 24696—24711.
  26. Amerikanov A. A., Vinarsky V. M., Evtushenko L. G., Zunin V. V., Romanova I. I. Development of Remote Labs Architectures for FPGA Design Training, Informacionnye Tehnologii, 2025, vol. 31, no. 3, pp. 124—130.
  27. Parks D. F. et al. IoT cloud laboratory: Internet of Things architecture for cellular biology, Internet of Things, 2022, vol. 20, Art. No. 100618.
  28. Monzo C. et al. Remote laboratory for online engineering education: The rlab-uoc-fpga case study, Electronics, 2021, vol. 10, no. 9, Art. No. 1072.
  29. Jacko P. et al. Remote IoT education laboratory for microcontrollers based on the STM32 chips, Sensors, 2022, vol. 22, no. 4, Art. No. 1440.
  30. Guermandi D. et al. A 2-V 0.35-pm CMOS DECT RF front end with on-chip frequency synthesizer, VLSI Circuits and Systems II, SPIE, 2005, vol. 5837, pp. 426—437.
  31. Xiao Z. et al. Antenna array enabled space/air/ground communications and networking for 6G, IEEE Journal on Selected Areas in Communications, 2022, vol. 40, no. 10, pp. 2773—2804.
  32. Michel F. et al. A first look at Starlink performance, Proceedings of the 22nd ACM Internet Measurement Conference, 2022, pp. 130—136.Ad condicae ad aurio inte terem in dierem ocum

Supplementary files

Supplementary Files
Action
1. JATS XML
Download

Copyright (c) 2025 Informacionnye Tehnologii


СМИ зарегистрировано Федеральной службой по надзору в сфере связи, информационных технологий и массовых коммуникаций (Роскомнадзор).
Регистрационный номер и дата принятия решения о регистрации СМИ: серия ПИ № 77 - 15565 от 02 июня 2003 г.