L.A. Morozova1, S.V. Savel’ev2

1,2 The Institute of Radioengineering and Electronics
of Russian Academy of Sciences (Fryazino, Moscow region, Russia)

This article reports about investigations the physical properties of a magnetic field concentrator, which is a dielectric structure without active elements of power sources. The scientific literature has repeatedly noted the significant effect of the concentrator on water and other objects, the result of which was recorded in experiments. In this work, the physical properties of the radiation of the concentrator and the possibility of its application in the diagnosis of non-standard conditions of the human body are investigated. Determine the electromagnetic properties of the magnetic field concentrator signal. To reveal the possibility of using a magnetic field concentrator as an external signal source for the method of active radiothermometry of the human body.

The radiation of a magnetic field concentrator is experimentally investigated, which is a sequence of antinodes of an ultra-wide wavelength range, which are located from the end of the concentrator at distances of multiples of 488 millimeters. In the experiment, 4 antinodes were recorded with a sequential decrease in the intensity of the electromagnetic field at the maximum intensity of the first antinode – 105 dBm. A comparative analysis of the external impact of a magnetic field concentrator and extremely high frequency therapy devices on a highly organized biological object - a person - has been carried out. Was found that the effect of the concentrator significantly increases the information content of the method of active radiothermometry of the human body.

The results obtained in this work on measuring the physical properties of the magnetic field concentrator show a significant possibility of using it for the study of aquatic environments, biological objects of varying complexity, as well as in restorative and diagnostic medicine. Has been established that the information activity of this method when using the magnetic field concentrator is integrally higher than the efficiency of the one when using single-frequency extremely high frequency electromagnetic field signals.

Morozova L.A., Savel’ev S.V. Biological object and magnetic field concentrator. Biomedicine Radioengineering. 2022. V. 25. № 1. Р. 31-39. DOI: https://doi.org/10.18127/j15604136-202201-04 (In Russian).

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