All sciences. №8, 2023. International Scientific Journal

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Here:

• Device to be monitored – the measuring device shown in Figure1.

• UART- universal asynchronous receiver/transmitter – universal asynchronous receiver – transmitter;

• Microcontroller – microcontroller with analog-to-digital converter;

• SPI – serial information transfer interface;

• EtherSield – Ethernet module;

• Hardware – a set of programmable measuring devices.

Fig. 3. Block diagram of the system

Here:

• Hardware – technical means of the system installed in the cities of Fergana, Tashkent, Samarkand;

• A web server is an application server that collects and processes information.

In order to implement the proposed information and measurement system, three “Software and Hardware measuring systems” have been installed in the cities of Fergana, Tashkent and Samarkand. The measurement results obtained from these complexes are entered into the information base through the web server applications on the website pribori.uz. Figure 3 shows a block diagram of the system.

Fig.– 4. Interface for visualization of system data

Figure 4 below shows the data visualization interface of the system.

Conclusions

During the analysis of the results of preliminary experiments conducted at different times in the cities of Tashkent and Ferghana, an assumption arose about the existence of a correlation between the parameters of an earthquake and neutron and charged particle fluxes, i.e. neutron and charged particle fluxes carry informative signs about upcoming earthquakes in the near future. According to this assumption, they can be attributed to the precursors of earthquakes.

The proposed information and measurement system will allow a deep study of the relationship between the parameters of the upcoming earthquake and the fluxes of neutrons and charged particles.

The conditions for the prediction of all parameters of the upcoming earthquake, such as the hypocenter, magnitude and time of the upcoming earthquakes, are determined.

Literature

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