EMF Field Strength and Intensity Calculation: Aires 64P1S5G Resonator at 28 GHz (5G mmWave) — Serov, Korshunov et al. (2020)

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EMF Field Strength and Intensity Calculation: Aires 64P1S5G Resonator at 28 GHz (5G mmWave) — Serov, Korshunov et al. (2020)

By I. Serov, K. Korshunov, I. Soltovskaya, T. Shamko

Year: 2020Type: R&D Simulation ReportDevice: Aires 64P1S5G / LIFETUNE Room & PersonalFrequency: 28 GHz (5G mmWave)Cluster: Physics & Engineering

Report Overview

This R&D simulation report calculates the strength and intensity of the electromagnetic field produced in the interaction of 28 GHz 5G radiation with the Aires 64P1S5G resonator microprocessor — the silicon fractal diffraction grating component used in the LIFETUNE Room and LIFETUNE Personal (2020 model). The report was developed in direct response to 5G network deployment: as 28 GHz (mmWave) frequencies were approved in the USA and Europe for 5G networks, a fundamentally new microprocessor was engineered to address the characteristics of this frequency range.

Custom physical and mathematical models were again required, as existing commercial EM simulation packages do not account for counter-wave interaction and derivative resonance phenomena on the resonator surface — the processes central to how Aires resonators function.

Research Team

Role Researcher Institution
Project Manager I. Serov Aires R&D
Researcher K. Korshunov Aires R&D
Researcher I. Soltovskaya Aires R&D
Researcher T. Shamko Aires R&D
Scientific Consultant Prof. A.V. Kopyltsov, Dr. of Technical Sciences Saint Petersburg Electrotechnical University LETI
Scientific Consultant Prof. A. Jukna Vilnius Gediminas Technical University

The 64P1S5G Resonator — Physical Specifications

The 64P1S5G microprocessor is a self-affine circular diffraction grating with a fractalization factor of 2 and 64 fractalization axes — the highest axis count in the Aires resonator family. The topology is a flat cut through the center of a self-affine hypersphere, engineered for resonance at 28 GHz (5G mmWave frequency range).

Parameter Value
Fractalization axes 64
Fractalization levels 1 + prototype
Prototype diameter (D1) 9.696 × 10⁻³ m
Objects at prototype level (N₀) 65
Derivative diameter (D2) 19.4 × 10⁻³ m
Total ring (slit) resonators (N₁) 4,161
Slit width / height 0.2 × 10⁻¶ m / 0.8 × 10⁻¶ m
Target frequency 28 GHz (5G mmWave)

Key Results

Quantified Field Parameters — Aires 64P1S5G at 28 GHz

3,440 V/m
Peak field strength (Eₘₐˣ)
~1.5 × 10⁶×
Increase over baseline
1.18 × 10⁷ W/m²
Peak field intensity (Iₘₐˣ)
~2.23 × 10¹²×
Intensity increase
Finding 1 — Coherent Holographic Conversion at 28 GHzSimulations confirm that the Aires 64P1S5G resonator converts incident 28 GHz electromagnetic radiation into a coherent spatio-temporal self-affine form — described formally as a hologram. The energy is not attenuated or blocked, but redistributed across space, frequencies, phases, and the interaction diagram, transforming into a self-affine stationary structure matching the resonator’s own topological lattice. This is the same fundamental mechanism demonstrated at 2.4 GHz in the C28S and C32S reports, now validated at 28 GHz 5G frequencies.
Finding 2 — Singularity at Resonator CenterCounter-resonance forms along the diameters of the maximum-response ring, causing potential multiplication. Counter-harmonization across amplitudes, frequencies, phases, and radiation pattern creates a maximally neutral zone at the resonator center where potential density increases sharply and amplitude tends toward zero — the singularity phenomenon. The focal point intensity reaches (Iₘₐˣ)² = (1.18 × 10⁷)² = 1.39 × 10¹⁴ W/m². Continuous inflow of potential from outside ensures the superposition remains highly stable.
Finding 3 — 5G-Specific EngineeringThe 64P1S5G topology is specifically engineered for 28 GHz mmWave interaction, with 4,161 slit resonators (compared to fewer rings in 2.4 GHz topologies) and 64 fractalization axes. The dramatic field concentration ratios at 28 GHz (intensity increasing ~2.23 trillion times) reflect the interaction dynamics at this shorter wavelength and confirm the design is effective across both conventional WiFi and 5G mmWave frequencies.
Note on the mechanism: the extreme field multiplication values describe concentration at the resonator’s focal singularity point as a consequence of coherent wave superposition — not amplification of the original radiation. Per the first law of thermodynamics (conservation of energy), energy transforms between states; it does not spontaneously increase. The interaction redistributes the incident radiation into a self-affine holographic form.

Context: The Physics & Engineering Research Series

This report is part of a series of R&D simulations characterizing Aires resonator behavior across multiple product lines and frequency ranges. The C28S report (2018) covers 2.4 GHz interaction with the Aires Defender Pro. The C32S report (2018) covers 2.4 GHz interaction with the Aires Guardian. This 64P1S5G report (2020) extends the validation to 28 GHz 5G frequencies and the LIFETUNE product generation.

The Serov/Korshunov team also published the ITLMS 2018 conference paper in collaboration with external academics from Vilnius Gediminas Technical University and ITMO University, providing peer-reviewed external validation of the fractal resonator mechanism at GHz frequencies.

Related Research

Researcher: I. Serov Physics & Engineering Cluster ← All Research