Testing of EMR Resonator-Converter Prototype: Phase I Report
Prof. Artūras Jukna
Head of the Physics Department
2016
Customer UAB AIRESLITA Vilniaus str. 31, LT-01119 Vilnius, Lithuania Contact person Director Darius Višinskas
Tests conducted at Laboratory of Photovoltaic Technology Sauletekio av. 3, LT-10257 Vilnius Lithuania Contact person Head of the Laboratory Dainius Jasaitis
TESTING OF ELECTROMAGNETIC RADIATION RESONATOR-CONVERTER
PROTOTYPE
Phase I Report
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Contents
1. INTRODUCTION ..................................................................................................................................... 2
2. TESTING OBJECT ................................................................................................................................. 3
3. METHODS ................................................................................................................................................ 4
4. RESULTS AND DISCUSSION ............................................................................................................. 6
5. CONCLUSIONS ...................................................................................................................................... 8
Further plans: ............................................................................................................................................. 9
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1. INTRODUCTION
All remotely-operating devices/equipment, which use a wireless method for
receiving/transmitting of information, are sources of electromagnetic radiation (EMR) (for users
of these specific signals) or sources of electromagnetic smog (for other people). The
permissible EMR power density (10 µW/cm2) set forth by the Lithuanian Hygiene Standard
(HN 80:2015) is created by household appliances used on a daily basis: Personal computers
(50 – 1000 MHz frequency band), mobile-/smartphones iPhone/iPad (900 – 2100 MHz), smart
TV sets (54 – 1600 MHz), microwave ovens (300 MHz – 3 GHz), wireless routers (2,4 – 5
GHz), etc. Due to constantly increasing demand for such devices, their reliable operation at
maximum distance and increasing the flux and volume of data transmitted by such devices,
the EMR power of devices manufactured by competing companies will inevitably grow. Thus,
naturally, the measures protecting against or partially suppressing the electromagnetic smog
(e.g. the metal threads/fibres integrated into smart clothing or smart building structures) are
becoming more and more relevant. Our test subject is the prototype of electromagnetic
radiation resonator-converter (R-C) developed by AIRES TECHNOLOGIES. R-C is designed
to partially suppress the excessive electromagnetic smog without interfering with the
information receiving/transmitting devices’ ability to remotely exchange information.
The aim of the work is to conduct the tests of EMR R-C prototype: to measure the
electric/magnetic field strength, EMR flux density in the far-field zone (distance > 10 λ, where λ
is the central wavelength of the wide-frequency-band electromagnetic wave incident onto
device) and near-field zone (distance < 10 λ); to test the efficiency of the prototype in the 0 –
8 GHz frequency band and make recommendations to the manufacturer for development and
optimization of R-C prototypes for specific EMR wavelength/frequency ranges.
Objective of the Phase:
To determine the flux density, residual electric/magnetic field strength,
frequency of radiation and variation in frequency bandwidth due to EMR
interaction with three different types of R-Cs (Aires Black Crystal, Aires Shield
and Aires Defender) as well as the efficiency of the R-Cs in far-field and near-
field zones relative to EMR source in the 0 – 8 GHz frequency band, compare
their efficiencies and the characteristic parameters (according to the customer
demand);
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In accordance with our established criteria, to select, to recommend and to
manufacture R-Cs of specific characteristics, necessary for further tests
foreseen in the project.
2. TESTING OBJECT
Three types of Aires EMR R-Cs (Fig. 1), which consist of Aires chip and resonator
antenna.
Fig. 1 Aires electromagnetic radiation resonators-converters: a) Aires Black Crystal; b) Aires
Shield; c) Aires Defender.
Aires chip is a monocrystalline silicon panel covered in matrix, a two-piece circular
EMR wave diffraction cell of special construction, creating maximums and minimums of
amplitude of reflected EMR, which interact with the external variable electromagnetic (EM)
field, resulting in EMR power redistribution along the frequency band of an incident EMR. The
resonator antenna, made of electric conductor, covers the circular base of the matrix (Fig. 2).
Fig. 2 Equivalent circuit of electromagnetic resonator-converter.
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Thus, the equivalent circuit of the device is a capacitor comprising two conductive
electrodes separated by an insulating layer. The interaction of the capacitor with incident EM
wave results in charging up of the capacitor. More details on structure and a way of operation
of the device are available on the Aires Technologies website: http://www.aireslita.com/en/.
3. METHODS
Experimental part of the work conducted in the Photovoltaic Technology Research
Laboratory of Vilnius Gediminas Technical University (VGTU) and in field-conditions imitating
EM waves emitted by radiation sources of household appliances and measuring the change of
their amplitude and bandwidth using Signal Hound Spectrum analyzer in the frequency band
100 Hz – 8 GHz (the “receiver”) at room temperature (in the laboratory) or similar to it (at field-
conditions). Absolute error of relative EMR power measurement does not exceed 1.0 dB, the
measuring accuracy of the electric/magnetic EMR component strength is not more than 1.0 dB
(in the frequency range between 50 MHz and 1.9 GHz) and 2.4 dB (in the frequency band
between 1.9 GHz and 35 GHz) and isotropic deviation is not more than 1.0 dB. EMR
bandwidths that fell on R-C and interacted with R-C were analyzed by Signal Hound Spectrum
analyzer using the FFT method (Fast Fourier Transformation of pulsed signal).
In each individual measurement, it was attempted to move away from other EMR
sources or to make sure that the power of EM waves emitted by other sources (i.e. noise)
would not affect the test results of our selected source (the “transmitter”) radiation.
Changing the distance between the receiver and the transmitter, the power of incident
signals (in dBm) was recorded at freely chosen distances and then converted into electric field
strength values of EM field strength values, presuming that all EMR sources are ideal electric
dipoles with antenna gain of 2.15 dBi. Introducing the R-C into our experimental setup (see
Fig. 3) the experimental measurements were repeated holding approximately the same
distances between source (transmitter) and receiver.
Fig. 3 Resonator-converter efficiency measurement setup.
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To test the efficiency of R-C in the regime of optical transmission and optical
reflection, the source of EM radiation together with the R-C has been fixed at a distance of 2 –
10 λ from the signals receiver: a) in an optical transmission regime (the R-C is located
between the transmitter and the receiver); and b) optical reflectance regime (the R-C is one
side faced to the receiver and the transmitter). At fixed distances between the receiver and the
R-C, the R-Cs were gradually moved away from the transmitter (Fig. 4).
Fig. 4 The scheme explaining the experimental procedure of measurements of the transmitter signal power,
where the resonator-converter is located at distance of 2 – 10 λ a) in the regime of optical transmission and
b) in the regime of optical reflection.
The sources of EM waves transmitting power in range between 1 and 800 W were
selected for our measurements, however to minimize errors of measurements we performed
our measurements using the most powerful sources.
When measuring the values of electromagnetic fields, the Lithuanian Hygiene
Standard HN 80:2011 “Electromagnetic field at the workplace and living environment. Values
and measurement requirements with standardized parameters in 10 KHz ÷ 300 GHz radio
frequency band” was observed.
Theoretical simulation of our experimental results will be carried out by prof. Gennadi
Lukyanov, Professor of University of Information Technologies, Mechanics and Optics (ITMO),
Saint Petersburg, Russia, partner of the Electromagnetic Radiation Resonator-Converter
Prototype Testing project, and Aires Technologies, manufacturer of EMR resonator-converter.
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4. RESULTS AND DISCUSSION
The efficiency of different types of R-C converters was tested experimentally using the
0.5 – 800 W power sources generating EMR in the 900 – 2.5 GHz frequency band and the
residual signal power was measured by means of receiver which is constantly moving away
from the transmitter. Electric field strength at fixed locations with R-C added the transmitter (in
optical transmission mode) (ER-C) and without it (E0) (Fig. 4). Here: Transmitter 1 is 0.5 W,
transmitter 2 – 2 W, transmitter 3 – 400 W, and transmitter 4 – 800 W. Fig. 5 ΔE – difference
of electric field strength E0 – ER-C, calculated at a fixed point in space.
Fig. 5 The electric field strength of incident wave versus the distance from the source.
During interaction with R-C, the electric field strength of incident 0.9 – 2.5 GHz EM
wave decreases by 27 % on average (grey curve). The difference of electric field (given as E
= E0 – ER-C) was measured using R-C placed directly in front of the transmitter. However, as
the distance between the receiver and the transmitter was gradually increasing, the parameter
E gradually decreased due to EM wave interaction with R-C and in the case of 800 W source
it eventually vanished for the distance larger than 1.2 m.
As it follows from our measurement results the minimum power necessary for the R-C
excitation by means of an incident 0.9 – 2.5 GHz frequency band EM wave is Emin,0.8–1.8 GHz ~ 2
experimental results suggest that Emin is determined by the number of incident onto R-C
photons and by the quantum energy of these photons.
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The dependence of the transmitter's electric field strength amplitude on the distance
to the receiver is shown in Figures 6 and 7. Figure 6 shows a case, where R-C in optical
transmission mode is at a distance of 2 – 5 λ from the receiver (here λ is the wavelength of
source emitted radiation: λ ~ 12 cm) and Figure 7 represents the R-C in an optical reflectance
mode at a distance of 2 – 5 λ from the receiver. In both experimental cases, transmitter
radiation power was of 800 W.
Fig. 6 The electric field strength recorded by the receiver versus the distance between the receiver and the
transmitter dependence, where the resonator-converter was in the optical transmission regime at a distance
of 2 – 5 λ away from the receiver.
Fig. 7 The electric field strength recorded by the receiver versus the distance between the receiver and the
transmitter dependence, where the resonator-converter was in the optical reflectance regime at a distance of
2 – 5 λ away from the receiver.
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The amplitude of an incident EM wave decreases considerably as a result of wave’s
not depend on the distance between R-C and the receiver (Fig. 6). Similar results obtained
when replacing the R-C by the conductive (metal) plate, screening the electric field component
of an incident EM wave.
In optical reflectance mode, maximum R-C efficiency was observed at a distance
between the receiver and the R-C of 2 – 3 λ or with the R-C mounted directly in front the
receiver. Thus, R-C is more efficient in optical reflectance mode located in a near-field zone,
because only in the near-field zone the electric field’s amplitude of an incident EM wave
surpasses the threshold Emin value necessary for the R-C excitation.
5. CONCLUSIONS
Resonator-converter (R-C) suppresses power of an EM wave. Maximum efficiency can
be achieved when the R-C is located directly in front of the transmitter (source of EM
waves). The minimal power of 0.9 – 2.5 GHz frequency bandwidth of an incident EM
wave necessary for excitation of the R-C is Emin,0.9–2.5 GHz ≥ 2 W. If the frequency of the
Our preliminary results suggest that two factors determining Emin are number of incident
photons and their quantum energy.
While in the optical transmission regime the EM wave interaction with the R-C looks very
similar to that of a metal conductive plate (i.e. screening the electric field component of
an incident EM wave), the same interaction in optical reflectance regime expresses itself
in different way. The R-C damps the EM wave power demonstrating the maximal
efficiency when it is located directly on the receiver or fixed at a distance shorter than 3λ
from it.
The R-C is more efficient in the regime of optical reflectance if located in a near-field
zone. In the near-field zone the incident power is high enough for reaching the Emin
threshold power value necessary for the R-C excitation.
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Further plans:
We plan to test the electric properties of individual R-C of the same type and groups of
R-Cs of the same type under incident EM waves in frequency range between 0 and 8 GHz.
We are going to investigate the EMR distribution capacity, threshold EMR power for R-C
excitation and power’s dependence versus frequency of an incident EM waves and R-C
dimensions, power suppression efficiency for individual R-C groups, where the EMR
transmitter is located in the near-field and far-field zones with respect to R-C.
Placing an order with Aires Technologies for production of several Aires Black Crystal,
Aires Shield and Aires Defender R-Cs with identical dimensions and antenna shapes. Having
results of test we will be able to select devices with the most similar properties and dimensions
for our further experiments.