O.P. Supchinsky1, A.V. Obryvalin2, A.A. Voronova3

1–3 Omsk State University of Railway Transport (Omsk, Russia)

1sunchinyan@mail.ru, 2av.obr@yandex.ru, 3alyonavoronova446@gmail.com

The article offers a comprehensive approach to improving the effectiveness of metrological control through the introduction and development of technologies for remote verification of measuring instruments. The prerequisites caused by the digital transformation of industry (Industry 4.0) and the need to optimize metrological processes are considered. The methodological foundations of remote verification are presented in detail, including a comparative analysis of two organizational options, a detailed algorithm for implementation and requirements for technical infrastructure (software, equipment, communications). Significant advantages in terms of economic efficiency, efficiency and safety are emphasized. A comprehensive analysis of risks and limitations has been carried out. The key directions for ensuring the reliability and legitimacy of remote verification are formulated: the synchronous development of the technological base (reliable software, secure channels), the formation of a clear regulatory framework and the creation of a system for training qualified specialists. The prospects of remote methods are substantiated under the condition of a systematic solution of existing problems.

Supchinsky O.P., Obryvalin A.V., Voronova A.A. An integrated approach to the implementation and development of remote verification of measuring instruments in the context of industry 4.0. Electromagnetic waves and electronic systems. 2026. V. 31. № 3. P. 24−31. DOI: https://doi.org/10.18127/j15604128-202603-03 (in Russian)

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