RU2721874C2 - Method of detecting oscillations of low-current electromagnetic fields - Google Patents

Abstract

FIELD: diagnostics methods by physical parameters.

SUBSTANCE: invention relates to diagnostics of electromagnetic fluctuations of biologically active zones and their effect on the human organism, as well as to diagnostics of a human organism in case of disorders at the cellular level. Method for detecting oscillations of low-current electromagnetic fields, in which weak electromagnetic radiation with frequencies from a set of desired frequencies is successively generated near the survey object, then parameters of amplitude attenuation of frequency are registered in circuit of inductance coil and obtained data are compared with measurement data of similar parameters in absence of object of investigation, in case of detection of discrepancies specified frequency is identified as required, data on it are entered into database for further comparative analysis.

EFFECT: disclosed is a method of detecting oscillations of low-current electromagnetic fields.

1 cl, 4 dwg

Description

The invention relates to methods for diagnosing physical parameters, in particular for diagnosing electromagnetic fluctuations in biologically active zones and their effects on the human body, as well as for diagnosing the human body with disorders at the cellular level.

It is known that, at a distance of 6 cm from the forearm in practically healthy people, the field voltage values range from 36 ± 2.6-820 + 23 mV, and on the skin surface they had values of 1.3-30.0 V. The field strength of the forearms is 21-486 V / m (at a distance of 6 cm) [journal "Medical News", publishing house YupokomInfoMed, article "The electromagnetic field of a person and his role in the life of the body", Medical News. - 1996. - No. 10. - S. 34-43, electronic version http://www.mednovosti.by/journal.aspx?article=1322].

The presence of electrical tension means the presence of electromagnetic characteristics of living organisms in the range available for measurement, which has become the starting point for conducting a search to create methods and means for detecting these emissions.

The negative impact of geopathogenic zones (GPZ) of the Earth on living organisms, in particular on humans, is also known. GPZs are extensive geophysical anomalies characterized by altered (different from average) environmental parameters: geomagnetic field, soil electrical conductivity, electromagnetic fields of the atmosphere, level of radioactivity, etc. Within the GPZ local areas are noted (rarely more than 20 × 20 cm ² ), which have an exceptional pathogenic effect. The definition of ILI through biolocation is widely known, which is based on the ability of a person (~ 10% of the world's population) to respond to gradients of weak physical fields of both natural and artificial origin with the help of simple devices [See, for example: description of the invention to RF patent No. 2130625 ]. The simplest methods of biolocation allow us to determine the location of the GPZ, but do not allow to establish the physical parameters of the GPZ.

A known method for determining the geopathic zone by anomalies of the electrostatic field of the Earth in the habitat [RF Patent No. 2130625], which consists in measuring the constant component of the electrostatic field strength and determining its sign in at least one of the points of the habitat, comparing the data with an interval normal background values and judge the presence of a geopathic zone by exceeding the measured value of the limiting values of the mentioned interval and / or changing its sign. The output of the values of the electrostatic field strength beyond the normal background (that is, constantly present) interval is only one of the characteristics of the GEA. This patent is interesting in that it defines an interval of normal background values of the constant component of the electrostatic field strength - 90-450 V / m. This patent also indicates the possibility of deviations of background values from accepted depending on various external factors, and shows the need and usefulness of accumulating information (creating databases) about the physical characteristics (tension) of various objects and sections of the territory.

A measuring inductor is known [RF Patent No. 62503 U1], comprising a core of magnetic material with high magnetic permeability and an inductor that is wound on the core and made multilayer, characterized in that the core is a cylindrical rod turning into a truncated cone, while the coil of the inductor is placed on the cylindrical end of the rod, and the end of the cone-shaped part of the rod is made straight or bent at an angle, while in the range of the error of the measuring device, the length of the rod is five maximum diameter of the rod, the length of the coil is the maximum diameter of the rod, and the thickness of the coil is 0. 4 maximum bar dia. This inductor can be used in conjunction with a device for determining the bioelectromagnetic reactivity of living organ tissues as an electromagnetic field sensor. A coil (sensor) is part of a measuring open oscillatory circuit tuned to a pulsed complex-modulated mode of operation. In addition to the sensor, the oscillatory circuit also includes a pulsed complex-modulated electromagnetic field generator, a balanced demodulator, a detector, and an equalizer. The vibrational circuit is excited at the moment the sensor touches the surface of living tissue. The diagnostic method using the known coil is limited to the surface of a living organism and requires direct contact with such a surface, presumably due to the low sensitivity of the sensor.

From the level of technology it follows that the registration (measurement) of low-current electromagnetic fields and their fluctuations at significant time intervals is relevant for human life and health. Moreover, the methods for determining such fields vary from semi-artisanal to completely scientifically substantiated. Moreover, the accumulated and accumulated experimental and experimental data on the effect of low-current electromagnetic fields with various characteristics on living organisms are currently important. It should also be noted that the known methods are similar both to each other and to the claimed method, only by purpose, and therefore it is not possible to choose among them one closest analogue.

The objective of the invention is the determination of uncharacteristic magnetic (electromagnetic) anomalies in the study area for further analysis and application of the results in construction, everyday life and early diagnosis medicine.

The indicated problem is solved by the method of detecting oscillations of low-current electromagnetic fields, in which weak electromagnetic radiation with frequencies from the set of sought frequencies is successively generated near the object of study, then the parameters of the frequency attenuation amplitude are recorded in the inductor circuit and the obtained data are compared with the measurement data of similar parameters in the absence of the object of study , in case of discrepancies, the specified frequency is identified as the desired one, data about it is entered into the database for subsequent comparative analysis.

The claimed invention is illustrated by drawings.

The registration of oscillations of low-current electromagnetic fields is based on the generation of the desired frequency of electromagnetic oscillations in the master circuit and the measurement of the rate and attenuation amplitude of this oscillation in the measuring circuit by the resonance method according to the tuning fork as shown in FIG. 1.

In FIG. 2 shows a diagram of a hardware implementation of the method.

In FIG. 3 shows an example of a visualization of the method on a computer monitor.

In FIG. 4 shows the results of applying the method as part of a comprehensive assessment of the electromagnetic activity of the human body and its wave characteristics.

The method of recording oscillations of low-current electromagnetic fields can be implemented using two main modules:

- The master module 1 of electromagnetic waves based on a low-current inductive radiator with a ferrite core (module A);

- A recording module 2 of electromagnetic oscillations based on an inductor with an amplifier based on a current mirror and an emitter follower (module B);

Module 1 generates a certain given frequency, and module 2 registers the parameters of the amplitude of the attenuation of the frequency in the circuit of the inductor. The modules are controlled using an external microcontroller. The data obtained are compared with passive measurements of similar parameters of the desired data.

Calculations of the presence of the desired frequency are carried out according to the formula:

A = A ₀ ,

where A is the result of passive measurements, and A ₀ is the result of current measurements. If these indicators are not equal, then this indicates the presence of the desired frequency in the range of low-current electromagnetic radiation. To calculate A, the following formula is used:

where H ₀ is the magnetic field strength of the induction coil of the receiver in the phase of generating the resonant frequency of the radiating induction coil of the generator, H ₁ is the magnetic field strength of the induction coil of the receiver in the phase of attenuation of the amplitude after the exposure to the electromagnetic field of the induction coil of the generator at the lowest measurement point, k _zat is the coefficient attenuation and t is the decay time of the oscillation.

The magnetic field H can be calculated by the formula:

- индукция катушки, f - частота генерируемого импульса, а μ - величина магнитной проницаемости среды и равна μ₀=4π⋅10^-7 Гн/м(Н/А²) - магнитная постоянная.Where

is the induction of the coil, f is the frequency of the generated pulse, and μ is the magnetic permeability of the medium and is equal to μ ₀ = 4π⋅10 ^-7 GN / m (N / A ² ) is the magnetic constant.

The attenuation coefficient k _{zt is} calculated by the formula:

where R is the resistance of the induction coil circuit, and L is the maximum circuit inductance.

Thus, this method allows you to detect the presence of magnetic field oscillations of low-current sources of electromagnetic fields, and to analyze the field for subsequent use.

A complete hardware implementation diagram of the method may include (Fig. 2) the already mentioned modules 1 and 2, the control unit 3, its task is to transfer data from an external control device (computer) 4 to the master module 1 (pulse generator) and the reverse transmission of information from registration module 2 (registration unit). This is done using the internal software processor of the Resonance scanner. Position 5 indicates the object of study.

Computer 4 transmits frequency values for reproducing by module 1 of frequencies under control of unit 3. The program code of control unit 3 sets the criteria for reproducing frequencies to module 1. Module 1 reproduces the frequency inside its own closed loop. The object of study 5 has its own frequencies, which are in continuous reproduction. When the frequency of the object of study 5 coincides with one of the reproducible frequencies of the "Computer 4 - Block 3 - Module 1" system, in module 2 oscillations with a longer period are recorded than in the absence of the influence of the object of study 5. In this case, a resonance phenomenon is observed, which is recorded module 2.

Information about all successful matches is transmitted to control unit 3. And then the information goes to computer 4. In computer 4, a special program analyzes the received data arrays and then processes them (data is interpolated). Further, the obtained result can be displayed on the computer screen 4 in an accessible for understanding and further analysis form. Examples of readings are shown in FIG. 3, where 6 denotes a signal on the generator of module 1, 7 - a signal on the radiating inductor of module 1, 8 - a signal on the receiving inductor (module 2), 9 - combination of positions 6 and 7, 10 - combination of positions 6 and 8. You can see the direct relationship between the two coils (modules 1 and 2) and informational feedback, which helps to determine the external electromagnetic fields in a certain frequency range by the resonance method.

Further analysis of the data depends entirely on the availability of a database in the field of research, as well as the knowledge and experience of the operator.

An example implementation of the method.

A patient of a private clinic, a woman of 63 years old, with a diagnosis of "chronic heart failure", with symptoms of swelling of the lower extremities (item 11 in Fig. 4). As a result of the analysis of the claimed method, it was found that one of the reasons for this condition was the location of the berth, in which the legs fell into the area of increased magnetic anomaly. It was recommended to move the bed to another place. For three weeks, a special diet and electromagnetic limb stimulation were also recommended. The first signs of remission began to appear within a week, after three weeks the condition of the limbs was as in pos. 12.

One of the experimental devices that allows implementing the method of registering the fluctuations of low-current electromagnetic fields is preparing to go through the stages of State registration as a medical device in the Russian Federation in order to obtain a Registration Certificate of the Ministry of Health. In the Russian Federation, the device will be manufactured according to TU 26.60.12-001-97750475-2017. It is already ready to undergo Toxicological tests, Technical tests and the materials of these tests will be transferred to Roszdravnadzor for initial registration and admission to clinical trials.

In general, the application of the claimed method will allow:

- in construction - to correctly design the location of future buildings and their structures on the ground, according to the biological activity of the terrain, in order to avoid the high frequency of repair and maintainability in general;

- in everyday life - to organize the arrangement of furniture and other interior elements correctly, contributing to their better and more efficient use, as well as reduce the risk of biologically active fields affecting human life

- in medicine - to conduct early diagnosis of pathologies and changes in the functional state of organs and the body as a whole, at the cellular level, manifested in the form of changes in the oscillation of the person’s own electromagnetic field depending on the state of organs and systems, in certain frequency ranges

Claims (1)

 A method for detecting oscillations of low-current electromagnetic fields, in which weak electromagnetic radiation with frequencies from a set of sought frequencies is successively generated near the object of study, then the parameters of the frequency attenuation amplitude are recorded in the inductor circuit and the obtained data are compared with the measurement data of similar parameters in the absence of the object of study, in the case identifying discrepancies, the given frequency is identified as the desired one, data about it is entered into the database for subsequent comparative analysis.

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