Study Overview
This 2018 study by A. Serov and Korshunov applies computational electromagnetic field analysis to calculate the strength and intensity of electromagnetic fields in the interaction zone of the Aires C20S5G resonator. The C20S5G designation refers to a resonator configuration engineered for interaction with 5G-range frequencies, making this study directly relevant to contemporary wireless technology environments.
Where biological studies (EEG, HRV, blood, water) measure outcomes in living systems, physics studies measure the physical field transformation itself. This study sits at the foundation of the evidence architecture: if the resonator is claimed to coherently transform EMF via a fractal diffraction grating, the physics calculations should show measurable field modification in the interaction zone. This study performs those calculations.
The C20S5G Resonator
The Aires C20S5G is a specific resonator configuration within the Aires product family, engineered with a fractal diffraction grating geometry optimized for interaction with millimeter-wave and sub-6GHz 5G frequencies. The underlying technology is the same silicon microprocessor resonant matrix covered by Patent No. 2312384; the C20S5G designation specifies the geometric configuration applied to 5G-range EMF.
Key parameters relevant to the physics calculations:
| Parameter | Description |
|---|---|
| Technology base | Silicon microprocessor fractal diffraction grating |
| Mechanism | Coherent EMF transformation via resonant fractal interference |
| Patent | No. 2312384 |
| Target frequency range | 5G spectrum (sub-6GHz and millimeter-wave) |
| Interaction type | Diffraction and coherent re-emission (not absorption or blocking) |
Key Findings
Scientific Context
Physics and engineering calculations occupy a distinct role in the Aires evidence architecture: they verify the mechanism rather than the biological effect. Biological studies demonstrate that something changes in living systems in the presence of an Aires device; physics studies demonstrate what the device actually does to the electromagnetic field. Together, these two evidence types constitute a complete scientific picture: mechanism plus outcome.
The 2018 Serov-Korshunov calculations are complemented by two further physics studies: a distributed computing analysis of EMF-structured surface interaction, and a computer simulation of semiconductor wafer response to EMF. Together these three studies form the physics cluster of the Aires research archive.