Development of a stratospheric airship-based network architecture for telecommunication in remote areas

Authors

DOI:

https://doi.org/10.15587/1729-4061.2025.340990

Keywords:

high-altitude platform stations (HAPS), stratospheric airship, telecommunication network, LoRa technology, sub-GHz frequency

Abstract

The object of this study is a stratospheric airship-based telecommunication platform, employed as a high-altitude platform station (HAPS), designed to operate at altitudes of 20–30 km and provide broadband connectivity in regions with limited terrestrial infrastructure such as rural and remote areas of the Republic of Kazakhstan. The key research problem is to ensure stable connectivity of HAPS-based telecommunication platforms under strong stratospheric winds, with limited payload capacity and energy resources, while developing a scalable network architecture for multi-airship coordination.

This paper proposes a network concept based on modular nano-airships, which reduces drag, enhances maintainability, and ensures continuous service. Calculations of lifting capacity, aerodynamic drag of different envelope shapes, energy balance, and the coverage radius of a single station were performed. Experimental tests of a prototype confirmed the feasibility of using the sub-GHz band (433 MHz) to provide long-range communication under ground test conditions, where signal attenuation was found to be minimal compared to higher frequencies.

Due to the obtained characteristics, the hypothesis of employing a group of smaller airships instead of a single large carrier was confirmed. This is explained by their reduced sensitivity to wind loads, flexibility in network configuration, and lower operational risks. Unlike traditional satellite systems, which are expensive to launch and maintain, stratospheric airships can be recovered, repaired, and redeployed at relatively low cost, offering an economically viable solution for developing regions.

The results can be applied in the creation of national communication networks for remote and sparsely populated areas of the Republic of Kazakhstan, in emergency response operations, and as a complementary layer to satellite constellations. The proposed concept demonstrates that modular HAPS networks are a realistic and scalable alternative, capable of providing broadband access under real-world atmospheric and geographic constraints

Author Biographies

Mukhit Abdullayev, Satbayev University

PhD

Department of Electronics, Telecommunications, and Space Technologies

Ainur Kuttybayeva, Satbayev University

PhD, Associate Professor

Department of Electronics, Telecommunications and Space Technologies

Kalmukhamed Tazhen, Satbayev University

Master Student

Department of Electronics, Telecommunications and Space Technologies

Anar Khabay, Satbayev University

PhD, Associate Professor

Department of Electronics, Telecommunications and Space Technologies

Nurzhamal Ospanova, International IT University

PhD, Associate Professor

Department of Radio Engineering, Electronics and Telecommunications

Yerlan Tashtay, Satbayev University

PhD, Associate Professor, Head of Department

Department of Electronics, Telecommunications and Space Technologies

Arnur Sabyrbayev, Satbayev University

Master Student

Department of Electronics, Telecommunications and Space Technologies

Iliyas Samat, Satbayev University

Master of Technical Sciences, Lecturer

Department of Cybersecurity, Information Processing and Storage

Rimma Abdykadyrqyzy, Ministry of Science and Higher Education of the Republic of Kazakhstan

Head of Department

Media and Press Department of the RSE "Gylym Ordasy" under the Committee of Science

Daria Zhumakhanova, Shakarim University

Senior Lecturer

Department of Physics and Informatics

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Development of a stratospheric airship-based network architecture for telecommunication in remote areas

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Published

2025-10-28

How to Cite

Abdullayev, M., Kuttybayeva, A., Tazhen, K., Khabay, A., Ospanova, N., Tashtay, Y., Sabyrbayev, A., Samat, I., Abdykadyrqyzy, R., & Zhumakhanova, D. (2025). Development of a stratospheric airship-based network architecture for telecommunication in remote areas. Eastern-European Journal of Enterprise Technologies, 5(9 (137), 82–92. https://doi.org/10.15587/1729-4061.2025.340990

Issue

Vol. 5 No. 9 (137) (2025): Information and controlling system

Section

Information and controlling system

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Copyright (c) 2025 Mukhit Abdullayev, Ainur Kuttybayeva, Kalmukhamed Tazhen, Anar Khabay, Nurzhamal Ospanova, Yerlan Tashtay, Arnur Sabyrbayev, Iliyas Samat, Rimma Abdykadyrqyzy, Daria Zhumakhanova

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