Year: 2018Type: R&D Simulation ReportDevice: Aires C28S / Aires Defender ProFrequency: 2.4 GHz WiFiCluster: Physics & Engineering
Report Overview
This R&D simulation report calculates the strength and intensity of the electromagnetic field produced in the interaction of 2.4 GHz WiFi radiation with the Aires C28S resonator microprocessor — the silicon fractal diffraction grating component used in the Aires Defender Pro (2018 model). Using custom physical and mathematical models built specifically for Aires resonator interaction (existing commercial packages do not account for counter-wave interaction and derivative resonances on the resonator surface), the report characterizes how the C28S topology transforms incident WiFi radiation.
Research Team
| Role |
Researcher |
| Project Manager |
I. Serov |
| Responsible Researcher |
K. Korshunov |
| Researcher |
I. Soltovskaya |
| Researcher |
T. Shamko |
| Consultant |
Prof. Dr. of Technical Sciences A. Kopyltsov |
| Consultant |
Prof. Department of Physics Dr. A. Jukna |
Physical Model
Aires resonators are self-affine circular diffraction gratings. The simulation models counter-wave interaction on the resonator surface and the derivative resonances arising from these processes — phenomena that standard commercial EM simulation packages do not capture and which are necessary to accurately model the resonator’s behavior. The physical model was validated against experimental observations of Aires resonator behavior across multiple prior studies.
This report was produced by the Aires Human Genome Research Foundation research team. Custom simulation software was developed because existing commercial packages model EM interactions only in the context of classical physics, without accounting for counter-wave resonance phenomena central to the Aires mechanism.
Key Results
Quantified Field Parameters — Aires C28S at 2.4 GHz
13.34 V/m
Peak field strength (Eₘₐˣ)
~22×
Increase over baseline
178.0 V/m²
Peak field intensity (Iₘₐˣ)
Finding 1 — Coherent Holographic Conversion ConfirmedSimulations confirm that the Aires C28S resonator converts incident 2.4 GHz electromagnetic radiation into a coherent spatio-temporal self-affine form described as a hologram. The energy is redistributed across space, frequencies, phases, and interaction diagram — not attenuated or blocked, but coherently transformed into a self-affine stationary structure matching the resonator’s own topological lattice.
Finding 2 — Singularity at Resonator CenterCounter-harmonization along ring diameters creates a maximally neutral zone at the center, where potential density increases sharply and amplitude tends to zero — the singularity phenomenon. The focal point intensity reaches (Iₘₐˣ)² = (178.0)² = 31,684 V/m². Active potential continuously redistributes from maximum activity zones into this neutral center, maintaining a highly stable superposition.
Finding 3 — Gabor-Denisyuk Hologram PropertiesThe resulting field is self-affine and holographic. Per the Gabor-Denisyuk theory of holograms — any hologram bears all the same traits as the initiating agent — the resonator output becomes a coherent transformer of any subsequent waves interacting with it in the corresponding frequency range. This is the mechanism by which the device continues to coherently transform incoming EMF after initial field establishment.
Relationship to C32S Report
The C28S and C32S reports share the same research team, methodology, and frequency (2.4 GHz WiFi), but characterize different resonator topologies used in different products: C28S in the Aires Defender Pro, C32S in the Aires Guardian. The different topological configurations produce different quantified field parameters but the same fundamental coherent transformation mechanism. This product-by-product characterization establishes that the mechanism is robust across resonator design variants.
Related Research
