WO2006115426A1 - Method for controlling biological processes and a device for carrying out said method - Google Patents

Abstract

The invention relates to medicine and bioengineering. The inventive method for adjusting biological processes consists in fixing the growth-propagation range boundaries according to the beginning and termination of the curve positive slope of a recorded radiosignal intensity ratio in the mid- and low-frequency ranges, in fixing the accumulation-mutation range boundaries according to the beginning and termination of the curve negative slope of a recorded radiosignal intensity ratio, in controlling cell culture growths within the growth-propagation boundaries, in particular by signal generation, in carrying out an accelerated product growth, in stabilising, within the accumulation-mutation range, the transition biochemical processes which are generated by mutations or in selecting the thus obtained product or in inducing and maintaining processes exposed to the action of a given state of cells. Structure charts and the description of an electromagnetic oscillation generator and an electromagnetic oscillation recording device are also disclosed.

Description

 A method for regulating biochemical processes and a device for its implementation

Technical field

The invention relates to the field of medicine and biotechnology, in particular, it can be applied both in the widest areas of bioproduction for accelerated growth of bioproducts, for example, in microbiology, crop production and animal husbandry, and in medicine for correction of biochemical processes of certain functions of the human body with a view to its recovery, prevention and treatment of diseases, as well as in the postoperative period.

It is known the invention of "Medicament for regulating the growth of cereal and cereal crops" (patent CH 2054869, A01 N37 / 20 from 1996.02.27), in which the inventive mixtures - plant growth regulators can, for example, inhibit plant growth. By the method of inhibition of plant growth is meant the regulation of their natural development without changing, at the same time, determined by the genetic properties of the plant life cycle, i.e. without causing mutations. The regulatory effect on plant growth is carried out at a specific, in each case, phase of plant development. Treatment with a mixture of active substances can be carried out before seedlings or after seedlings of plants. For example, it can already process seeds or seedlings, roots, tubers, stems, leaves, flowers or other parts of plants. For this purpose, the active substance, as such or in the form of an agent, can, for example, be applied to plants or treated with a plant nutrient medium (soil). It is preferable to use the proposed synergistic means to inhibit the growth of primarily monocotyledonous crops, such as cereals, herbs, as well as dicotyledonous crops by post-emergence treatment.

Plant growth regulators are compounds which, when introduced into the plant or when they are treated with plants, cause agronomically desirable biochemical and / or physiological and / or morphological changes in it. Active substances contained in the proposed products, depending on the time of use, dosage, method of application and environmental conditions, They have different effects on plant growth. With the help of plant growth regulators, it is possible to exert a qualitative (for example, latex flow) or quantitative (for example, sugar content) effect on the crop, suppress apical dominance, promote the development of lateral shoots (for example, in the case of ornamental plants), fall of flowers and fruits (for example , in order to remove excess shoots from fruit trees for disruption of rotation, for abscissa of fruits in olives for mechanized harvesting). With the help of growth regulators, it is possible to further harmonize, accelerate or slow down the ripening of fruits (for example, opening cotton bolls, ripening tomatoes or bananas).

With the help of growth regulators, it is possible to increase the resistance of plants to harsh environmental influences, such as drought, frost or soil salinity. And, finally, with their help it is possible to induce defoliation of cultivated plants in time, due to which mechanized harvesting of crops such as cotton, potatoes or grapes becomes easier or even possible.

The disadvantage of this invention is the uncertainty in determining the growth parameters of the cells of the biological product. The invention is known "A method of regulating intracellular energy production and its use (4 options)" (application RU 94031515, C12N5 / 00; A61 G10 / 00, from 1996.07.20), in which the method of regulating intracellular energy production consists in placing living organisms or individual cells in a sealed chamber filled with a medium containing oxygen and other life support equipment, and increasing the pressure in the medium filling the chamber to a predetermined level by at least a one-time increase in the biologically inactive composition of the medium determining the maximum specified level of pressure of the medium in the chamber upon reaching the required intensity of intracellular energy production and maintaining the specified level of pressure of the medium in the chamber for the time necessary to fix the required intensity of energy production in organisms or individual cells. The objects of application of the invention can be cells of any kind of organisms (including unicellular), cell and tissue cultures, as well as multicellular organisms in general, and it can be used, in particular, in medicine to correct disorders of the energy metabolism of cells, cellular systems, tissues organs and multicellular organisms in general; in biology, to study the characteristics of the energy of cellular systems, for example, to synchronize a cell culture (to obtain a population of microorganisms in the same development phase); in genetic engineering to increase the yield of proteins synthesized by microorganisms.

The disadvantage of this method is the limited regulatory capabilities.

A known method of treating pain of spinal osteochondrosis and a device for its implementation (RU patent Ns2240156, publ. 2004.11.20), the invention consists in the fact that in the method of treating pain of spinal osteochondrosis by exposure to physical factors, the effect is carried out by an alternating electromagnetic field, which It is formed by an amplitude-modulated sinusoidal signal with a carrier frequency in the frequency range Ш0 - 2000 kHz and a constantly changing modulation frequency in the range of 15 - 8000 Hz, with simultaneous irradiation of visible and near-infrared wavelength ranges with a small spectral width nizkointensivnym quasimonochromatic radiation. When exposed, a combined exposure element is used containing an emitter of electromagnetic waves in the range of 100 - 2000 kHz and an emitter of electromagnetic waves in the optical range.

A device for therapeutic treatment contains a sinusoidal signal generator in the form of an oscillator with a carrier frequency of 100 - 2000 kHz. The inductive element of the oscillatory circuit of the oscillator is simultaneously the emitter of the exposure element. The device is equipped with a low-frequency generator, the output of which is connected through a modulator to the oscillator circuit, and is equipped with a control path, the input of which is connected to the oscillator circuit and which contains an amplitude detector connected in series, DC amplifier and indicator. The device also contains M LEDs connected in series and a power source. The power source and low-frequency generator are made in the form of a separate functional element. The device uses a treatment effect on biological tissues with an electromagnetic field formed by an amplitude-modulated high-frequency sinusoidal signal with a carrier frequency in the frequency range 100 - 2000 kHz, with a constantly changing modulation frequency in the range 15 - 8000 Hz, and low-intensity quasi-monochromatic radiation of visible and near infrared with a small spectral width. Exposure, without causing the generation of endogenous heat in biological tissues, restores blood circulation and activates microcirculation in tissues, improves the rheological properties of blood, causes a relaxing and analgesic effect, helps normalize the blood picture.

In this method and device does not take into account the electromagnetic environment in a given place in space, i.e. external electromagnetic fields that change in time and space.

The invention is known “A device for determining the state of a biosystem, patent RU NQ2064176, G01 N25 / 04, dated 1996.07.20), which describes a method for selecting certain conditions for conducting biochemical processes, provides examples of plotting the intensity (temperature of the biomass at the cellular level) of biochemical processes from time, or so-called heating curves, a method is also given for indirectly determining the time intervals of the state of cells - “growth - multiplication” (expansion) and “accumulation - mutation * (compression), obtained before the notion of spatiotemporal correlation and the ability to relate t _lab in an experiment with heating biological products of a given organism with a real lifetime t _pea l. In accordance with this, regulation of biochemical processes can be carried out.

The disadvantages of the prototype is the very great complexity and low accuracy of determining time intervals, which implies the practical impossibility of using the method proposed in the prototype Yes, to regulate and adjust bioprocesses in order to increase efficiency, in particular, productivity and product quality.

Disclosure of invention

The objective of the invention is to increase the accuracy and efficiency of the regulation of the biochemical process by simply and directly determining the time intervals of the state of the cells of the biosystem, allowing according to the indication of the device to clearly regulate the biochemical process, eliminating possible harmful deviations in the process of cell division, which leads to an increase in product quality. This problem is solved by creating a method for regulating biochemical processes in a given place in space by registering time intervals of the state of cells “growth-multiplication” and “accumulation-mutation”, in which the boundaries of the interval “growth-multiplication” are fixed at the beginning and end of the positive slope of the relationship curve the intensities of the recorded radio signals, respectively, in the mid-frequency and low-frequency ranges, and the boundary of the interval “accumulation - mutation” is fixed at the beginning and end of the negative slope of the relationship curve the intensities of the recorded radio signals, respectively, in the mid-frequency and low-frequency ranges, while in the boundaries of the intervals “height-sheath size” they regulate the growth of cell cultures or accelerate the cultivation of products or the regeneration of biological structures or carry out processes that are affected by this state of biological object cells, and in the boundaries of the “accumulation-mutation” intervals stabilize transient biochemical processes caused by mutations or perform the selection of the products obtained or initiate and support the processes that are affected by this state of the cells.

In addition, the recorded radio signals are fixed in the ranges respectively 250-1250 kHz in the frequency band 10-20 kHz and 100-250 kHz in the frequency band 10-20 kHz. Also, this problem is solved by creating a method for regulating biochemical processes in a given place in space by registering time intervals of the state of cells “growth-multiplication” and “accumulation-mutation”, in which within the limits of the interval “growth-multiplication” to regulate the growth of cell cultures or accelerated growing products or the regeneration of biostructures or processes that are affected by a given state of bioobject cells generate a signal whose spectrum corresponds to a positive slope of the intensity curve of the recorded radio signals, acting like a catalyst, and within the limits of the “accumulation-mutation” interval to stabilize transitional biochemical mutations processes or the selection of the products obtained or the initiation and maintenance of processes that are affected by a given state of cells, eneriruyut signal spectrum which corresponds to a negative slope of the curve of the intensity ratio detected radio signals, acting as an inhibitor.

In addition, the recorded radio signals are fixed in the ranges respectively 250-1250 kHz in the frequency band 10-20 kHz and 100-250 kHz in the frequency band 10-20 kHz. In addition, the generation of signals is performed by an electromagnetic oscillation generator.

This problem is also solved by creating a method for regulating biochemical processes in a given place in space by registering time intervals of the state of cells “growth-multiplication” and “accumulation-mutation”, in which a signal with a positive spectrum is generated to record the interval “growth-multiplication” the slope of the ratio of the intensities of the recorded radio signals, acting as a catalyst, and within the boundaries of the accumulation - mutation interval generate a signal whose spectrum corresponds to the negative the slope of the curve of the ratio of the intensities of the recorded radio signals, acting as an inhibitor, while regulating the growth of cell cultures or accelerating the cultivation of products or the regeneration of bio-structures or performing processes that are affected by this state of bioobject cells within the boundaries of the “growth-growth” intervals, and within the boundaries of the “accumulation-mutation” intervals, they stabilize transient biochemical processes caused by mutations or perform selection of the obtained products or initiate and support the process Sy, are affected by this state of the cells. In addition, the recorded radio signals are fixed in the ranges respectively 250-1250 kHz in the frequency band 10-20 kHz and 100-250 kHz in the frequency band 10-20 kHz.

In addition, the generation of signals is performed by a generator of electronic oscillations.

This problem is also solved by creating a device for detecting electromagnetic waves, comprising a detector, an amplifier and a display device, in which at least two receiving devices, a second amplifier, two analog-to-digital converters, as well as a computing device, including random access memory, are additionally introduced and the amplifiers are configured to normalize the amplitude, with each of the outputs of the receiving device connected to the corresponding input of the amplifier, each of passages connected to a respective input of an analog-digital converter, whose outputs are connected to respective inputs of the computing device, which is connected to the output display device.

In addition, the receiving device is made in the form of a resonant antenna. In addition, the computing device is configured to connect a display, non-volatile memory, keyboard and external devices using a communication interface.

In addition, non-volatile memory is made in the form of a ferromagnetic memory. This problem is also solved by creating a device for detecting electromagnetic waves, comprising a detector, an amplifier and a display device, in which at least two receiving devices, a second amplifier, two analog-to-digital converters, and also a computing device, including an operative device, are additionally introduced storage device, non-volatile memory, communication interface of external devices with a computing device, and the receiving device is made in the form of a resonant antenna, amplifiers ying, with normalization of amplitudes, each of the receiver outputs connected to the corresponding input an amplifier, each of the outputs of which is connected to the corresponding input of an analog-to-digital converter, the outputs of which are connected to the corresponding inputs of a computing device, configured to connect a display device, non-volatile memory, an interface for communication of external devices with a computing device.

In addition, non-volatile memory is made in the form of a ferromagnetic memory.

This problem is also solved by creating an electromagnetic oscillation generator containing a master carrier frequency generator, a modulator, a modulator generator, in which a frequency divider, a modulation depth control device, an amplifier in series, an output voltage control device and an antenna are connected in series, and a carrier frequency master made with the ability to adjust the frequency, the frequency divider is made with the choice of the division coefficient, and the modulator generator you it is capable of adjusting the modulation period, while the output of the modulator generator is connected to the input of the modulation depth adjustment device, the output of which is connected to one of the inputs of the modulator, the output of which is connected to the input of the amplifier, and the second input of the modulator is connected to the output of the frequency divider, the input of which connected to the output of the master oscillator of the carrier frequency.

The main distinguishing feature of the invention is the selection of frequencies that are tuned to an external electromagnetic effect, and the ratio of amplitudes in different ratios of the frequency range, which leads to meaningful, thoughtful regulation of biochemical processes by exposure, dependent on the measurement of external electromagnetic fields and the ratio of signal amplitudes in different frequency ranges. The regulation of the biochemical process can be carried out by registering a device for registering electromagnetic oscillations of the boundaries of the intervals of state of cells “growth” and “accumulation - mutation”, and knowing the boundaries of these intervals, start the regulation of biochemical processes in a given place if necessary, or knowing the boundaries of the intervals, we can run generator of electromagnetic waves, and by combining these signals to achieve either a positive slope of the intensity curve of the recorded radio signals ("asset") or a negative slope of the relationship of the intensity of the recorded radio signals ("asset"). We can also not register the boundaries of time intervals using an electromagnetic oscillation generator, and if necessary, create a positive or negative slope of the intensity curve of the recorded radio signals. Thus, the regulation of the biochemical process can be carried out not only in accordance with the indications of the indicator of the device, but also in combination with the heating curve constructed for this case, which allows you to program complex technological processes for any period, bearing in mind their correction in accordance with our proposed in a way that can be extended to the life of people, animals and plants (see patent RU Ne 2064176).

In the method of regulating biochemical processes that we propose, the registration of time intervals “growth” and “accumulation - mutation” is carried out by fixing the values of the ratio of the intensities of noise-like radio signals of the medium frequency range (250-1250 kHz, in the frequency band 10-20 kHz), reflecting the activity of somatic tissue, and the intensities of noise-like low-frequency radio signals (100-250 kHz, in the frequency band 10-20 kHz), reflecting the activity of one's own viral complex in the interval “accumulation - mutation and "(see patent RU NQ 2064176) or cells of acupuncture zones and nerve tissue.

Brief Description of the Drawings

Figure 1 shows a graph of the level of the radio signal amplified and taken from the display device for recording electromagnetic oscillations of the radio signal (U in mV and μV) versus time in hours on August 7, 1997.

Figure 2 shows a device for recording electromagnetic waves. Fig. 3 shows a block diagram of a block diagram of an electromagnetic oscillation generator.

Figure 4 presents copies of photographs that show the effect on a sprouted wheat grain of a signal whose spectrum corresponds to a positive slope of the intensity curve of the recorded radio signals, acting as a catalyst, or a signal whose spectrum corresponds to the negative slope of the relationship of the intensity of recorded radio signals, acting as an inhibitor: a) wheat grain was not exposed; b) ceteris paribus, the wheat grain was influenced by a signal acting as an inhibitor; c) wheat grain was influenced by a signal acting as a catalyst.

Figure 5 presents copies of thermograms showing the effect of a signal whose spectrum corresponds to a positive slope of the intensity curve of the recorded radio signals acting as a catalyst, or a signal whose spectrum corresponds to a negative slope of the relationship of the intensity of the recorded radio signals acting as an inhibitor , on, on the human body: a) the thermogram shows the temperature of the patient's face before the experiment; b, c,) the thermogram shows the temperature of the face during application of the electromagnetic oscillation generator to regulate biochemical processes; d) the thermogram shows the temperature of the face after exposure.

Figure 6 presents copies of thermograms showing the results of experiments on the effect of mobile phones on the blood circulation of the brain: a) the face of the patient; b) the thermogram shows the temperature of the patient's face before the experiment; c, d,) the thermogram shows the temperature of the face after using a cell phone; d) the thermogram shows the temperature of the face after exposure to an electromagnetic oscillation generator to regulate biochemical processes.

The best embodiment of the invention

As can be seen from figure 1 in the inventive method according to any of the variants of the invention, the boundaries of the intervals "growth-multiplication" are recorded at the beginning and end of the positive slope of the relationship of the corresponding signals depending on changes in the Earth’s magnetic field, the boundary of the accumulation – mutation interval ”is recorded at the beginning and end of the negative slope of the curve of the ratio of the intensities of the decline section of the curve. In the terminology of I. Prigogine (G. Nikolis, I. Prigogy, “Recognizing a Complicated”, Moscow, 1990), the interval “growth-reproduction” reflects the stationary process of the metabolism of an object, and “accumulation - mutation” - an unsteady process of metabolism of an object. The boundary state located between the two named states will mean a quasistationary process or a horizontal section of the curve of figure 1.

It is known (see, for example, patent RU Ns 2064176) that the state of the cells of the “growth-multiplication” biosystems is associated with the division of cell structures, and otherwise it can be called the heating state, in which the enhancement of metabolic processes, apparently, makes a significant contribution to the intensity of radio emission in a certain frequency range.

It is also known that any biosystem is characterized by a certain chain of stationary processes connected by non-stationary processes (G.Nikolis, I. Prigogy “Recognizing the Complex. Moscow, 1990), and the series of“ stability-non-stability ”of the metabolism of the biosystem is realized through transitions to new stationary states by changing (usually increasing) the internal (bound) energy of cellular metabolism, or by mutations and free energy of metabolism (E. Schroodipger "What is! ife?", Cambridge, 1944). It is also known (see patent RU N ^Q 2064176) that the complex of viral cells defined for each biosystem is a kind of “stove” that heats the body to an array of several average values characteristic of one or another stationary process that removes the body from non-stationary (“ so-called mutation) of states to stationary (“growth-multiplication).

It can be assumed in this case that an increase through the mechanism of viral recharge of the biosystem with energy from the environment, or an increase in the internal energy of cell metabolism under unsteady (“accumulation-mutation”) states of the biosystem, in the same way as in the first case, makes a significant contribution to radio emission from a biosystem in the form of an increase in the intensity of radio emission, but in a different frequency range, since its main source is the enhanced “operation” of the viral complex in unsteady states, or, in our terminology, in the “accumulation-mutation” intervals. This radio emission, as in the first case, was detected empirically in the above frequency range.

Therefore, it is possible to register the effect of enhanced “operation” of the virus complex, and not in one way, but the simplest, most direct, accurate and effective is the method for recording a “noise-like” radio-frequency signal considered in this application using the device described here — a device for recording electromagnetic waves or an integrated intensity level of these noise-like radio signals.

Thus, an accurate measurement of the indicated intervals of the states of the biosystem allows us to introduce the concept of true or real time, i.e. alternating mutational compression intervals and regeneration-propagating expansion intervals.

So, our method of measuring the indicated intervals of the states of the biosystem allows us to determine the alternation order and the duration of these intervals. If at the same time we, according to the method described in RU Patent Ns2064276, construct a curve of the intensity of the biochemical process versus time (heating curve) T (Laboratory) for some object and measure the first interval of this curve by our method, then we can predict other intervals in the area of a given longitude and latitude for the life of a given object. An example of an experiment with “live” yeast is described below (see Appendix 1, tables 1, 2), instead of yeast, various microbiological cultures can be taken, the period of noticeable growth of which would fit into the interval “growth-reproduction”. In this experiment, the same amount of “live” yeast is placed in several cuvettes with the same amount of sweetened water, with the only difference being that both processes of yeast division go to saturation in different intervals, one in the interval of cell state “growth” the other is in the “accumulation” cell range of the state of cells. As a result, in all experiments, faster division of yeast occurs in the “growth-multiplication” intervals, and a quantitative increase by weight compared to a similar process, but going in the interval "accumulation-mutation", up to 20%.

Thus, the experience with “live” yeast additionally confirms the studies and conclusions set forth in patent RU N ° 2064276. Apparently, one can state the presence of real (true) time for biosystems in the form of alternating aperiodic intervals, which can be called the intervals “growth-sheath size” (expansion) and “accumulation” (compression), with the most significant contribution Into the system (order) of their alternation introduces the daily rotation of the Earth and the influence of the moon. This fact is important for predicting (programming) a number of technological processes, i.e. to build heating curves (treal), which in turn can be adjusted during the process using the proposed device for recording electromagnetic oscillations of both intervals. In addition, our device for registering electromagnetic waves with an indicator of one kind or another, in combination with any temporary sensor, will be very convenient for practical use in various fields of human activity, since it allows you to adjust not only the course of the production process in accordance with the work of cells in their various states, but also to do the same in the course of the life of an ordinary person, allowing, as it were, to harmonize it in accordance with the current state of the cells of the whole organism .

The inventive method of regulating biochemical processes according to options 1, 2, 3 is carried out using a device for recording electromagnetic waves in predetermined frequency ranges (medium and low frequency) (figure 2). The inventive method of regulating biochemical processes is carried out according to the following algorithm:

1. A device for registering electromagnetic waves is located in a predetermined place in space. 2. This device accepts electromagnetic radiation in the specified frequency ranges - mid-frequency (MF) 250-1250 kHz, in the band of modulating frequencies 10-20 kHz, and low-frequency (LF) 100-250 kHz, in the frequency band 10-20 kHz. 3. Convert the analog values of the intensities of the recorded radio signals into digital form (A1-HCH, B1-CCH) ..

4. Measure the ratio of the intensities of the recorded radio signals between two channels in each frequency range 5. Calculate the ratio of the intensities of the recorded radio signals With 1 = B1 / Al

6. Remember the ratio of the intensities of the recorded radio signals.

7. Perform items 2-6 of the algorithm after a certain time, of the order of 5-10 minutes. The result is the ratio of the intensities of the recorded radio signals C2. The process is repeated during the observation time.

8. A comparison is made of the ratio of the intensities of the recorded radio signals C1 and C2. If C1 is greater than C2, then we have “accumulation-mutation” (“passive”), if C1 is less than C2, then we have “growth-multiplication” (“active”).

9. A curve is constructed of the ratio of the intensities of the recorded radio signals in the mid-frequency and low-frequency ranges, according to which the boundaries of the time intervals of cell states “growth” and “accumulation - mutation” are fixed in which the regulation of biochemical processes is started.

10. Next, the boundaries of the “distance-multiplication” interval are fixed at the beginning and end of the positive slope of the intensity-ratio curve of the recorded radio signals in the mid-frequency and low-frequency ranges, respectively, and the boundary of the “accumulation-mutation” interval is fixed at the beginning and end of the negative slope of the intensity-ratio curve of the recorded radio signals mid-frequency and low-frequency ranges.

11. Also within the boundaries of the interval “growth-multiplication”, a signal is generated whose spectrum corresponds to a positive slope of the intensity curve of the recorded radio signals, acting as a catalyst, and within the boundaries of the interval “accumulation-mutation”, a signal is generated whose spectrum corresponds to a negative slope curve of the ratio of the intensities of the recorded radio signals, acting as an inhibitor.

To generate signals using a generator of electromagnetic waves (Fig. 3). 12. Also generate a signal whose spectrum corresponds to a positive slope of the intensity curve of the recorded radio signals, acting like a catalyst, and to record the interval “accumulation - mutation” generate a signal whose spectrum corresponds to a negative slope of the intensity curve of the recorded radio signals, acting like inhibitor,.

The generator for generating signals is made in the form of a generator of electromagnetic waves (figure 2).

The specified frequency ranges when receiving electromagnetic radiation are determined empirically by studying the absorption spectra of various biological objects. The ratio of high-frequency and low-frequency components of the spectrum is a characteristic of changes in the state of biosystems at the measurement site. A striking example of measuring the intensity of the signals themselves and their relationships is an example of the experiments shown in figure 1 from 08/07/97. Similarly, it is possible to easily and accurately measure and plot curves similar to those shown in FIG.

In accordance with the algorithm of the device, curve 1 - B, curve 2 -A, curve 3 - C (figure 1).

It can be seen from curve C that, for example, on 7.08.97, from 8-00 to 13-00 there was observed “passive”, from 13-00 to 17-10 - “active”, from 17-10 to 19-20 - "saving", and then, until 24-00 - a quasi-stationary process, characterized by the horizontal course of curve C.

Numerous experiments showed the presence of a large increase in green mass in plants in the active intervals "growth-multiplication" in comparison with the intervals "accumulation-mutation". In particular, the experiments of option 3 with germinated grain revealed an excess of 2 times the green mass of the “growth” interval to the “mutation" interval. The experiments were conducted with an electromagnetic oscillation generator. The circuit of the electromagnetic oscillation generator allows you to work in two-channel mode, i.e. give out two signals simultaneously. Its circuit is a combination of two natural low-frequency and low-frequency background radio signal generators. This allows you to reproduce the above algorithm, carrying out the regulation process in active mode, i.e. give out simultaneously two LF and MF signals and with their combination set one or another slope of the intensity curve of the recorded radio signals.

In the example below, we show a change in the behavior of cellular structures in accordance with a change in time intervals determined, as we have already shown, by a change in the radio signal intensities in a series of experiments with “live” yeast.

The intervals “growth-spacing” and “accumulation” according to options 1, 2, 3 can be fixed by the method described in patent RU N ° 2064276, but the latter is too complicated, time-consuming and for practical purposes completely unacceptable, in contrast to the claimed way. By distinguishing the indicated intervals by our method, it is possible to adjust certain biochemical processes for them, moreover, for individual processes it will be quite sufficient to monitor the current state of cells, for example, for everyday activities of an ordinary person, but for complex technological processes it is preferable to simulate technological processes by plotting the dependence of the biochemical process on time (heating curve), for example, according to the method described in patent RU N ° 2064276, and our technique is used for the current correction of oatsa.

Since the product yield is greater in the “growth-diversity” interval, then in the case of its accurate registration, and this is characteristic of our methodology, processes are conducted in this interval to accumulate the desired product and other processes associated with active life, characteristic for this interval , for which it is possible to combine our device for registering electromagnetic waves, for example, with any temporary sensor.

Whenever possible, other technological processes are carried out in the registered “accumulation-mutation” interval, for example, for the selection and stabilization of the resulting product, and also conduct other work not directly related to the direct receipt of the product. As for ordinary life activity, this time of energy accumulation can be used for rest, reflection, etc. During this period of “incarnation-mutation”, all operations related to heightened sensitivity, i.e. the ability to sharply perceive information, you can negotiate, business and stock transactions, games and so on. However, all operations associated with the need for increased regenerative function of the body must be carried out in the active period. The latter include surgical operations, military operations associated with offensive operations of manpower, where large losses of personnel and so on are possible.

We also take such a problem as the use of cell division stimulants. It is very closely related to the state of the cells, and the use of stimulants in the interval “accumulation-mutation” causes irreparable harm to the human body. There are a lot of such examples, and all of them say that the proposed method for regulating biochemical processes based on accurate measurement of the boundaries of the “growth” and “accumulation-mutation” intervals and their regulation can be very widely used and bring significant benefits. It is known that the uncontrolled use of doping, steroids brings irreparable harm to the health of athletes. The role of growth stimulators for the state of a plant is known in case of their excessive use, which does not take into account the development of living structures described in this method for the curve of the ratio of the intensities of the recorded radio signals.

The device for recording electromagnetic waves according to option 1 (figure 2), contains at least two receiving devices 1, 2, two amplifiers 3, 4, two detectors 5, 6, two analog-to-digital converters 7, 8, a computing device 9, a display device 10, each of the outputs of the receiving devices 1, 2 connected to the respective inputs of the amplifiers 3, 4, each of the outputs of which is connected to the corresponding inputs of the analog-to-digital converters 7, 8, the outputs of which are connected to the corresponding inputs of the computing device and 9, the output of which is connected to a display device. According to option 2, it further comprises a communication interface 11, non-volatile memory 12, a keyboard 13, receiving devices 1, 2 are made in the form of a resonant antenna with the possibility of frequency tuning, the computing device 9 is configured to connect a display device, non-volatile memory, keyboard and connecting external devices using the communication interface.

In addition, the receiving devices 1, 2 can be made in the form of a resonant antenna with the ability to tune the frequency, for example, in the form of an inductor with a certain number of turns and a tuning capacitor connected to it, forming a resonant circuit, and one receiving device 1 is configured to receive low-frequency electromagnetic waves, and the second 2 - mid-frequency electromagnetic waves.

Detectors 5, 6 can be performed using transistors as well as integrated technology, and amplitude detectors can be used as detectors 5, 6.

Computing device 9 can be made based on the microprocessor MSP430F149. Also in the computing device 9 is provided the ability to perform operations of shift, addition, subtraction, division, memorization,

External non-volatile memory 12 can be made in the form of a ferromagnetic memory.

As a communication interface 11 for connecting, for example, with a computer, a USB interface can be used to store information on an external computer about the history, calibration, normalization of the signal by amplitude and signal correlation between the two channels.

A device for recording electromagnetic oscillations works as follows.

The device is installed in a given place in space. After switching on, the receiving device 1 receives external electromagnetic radiation in the low-frequency range, and the receiving device 2 - in the medium-frequency range, where the electromagnetic signal is recorded on resonant antennas tuned to frequencies in the range from 100 to

250 kHz and from 250 to 1250 kHz. The signal from each of the outputs of the receiving device The properties are amplified by amplifiers 3, 4, which have the ability to adjust the gain to ensure normalization of the signals in the channels in amplitude. Next, the signals are fed to the detectors 5, b, emitting envelopes of the signals. The normalized envelopes of the signals are fed to analog-to-digital converters 7, 8, where they are digitized and fed to the corresponding inputs of the computing device 9, where they are processed according to a given algorithm.

In the computing device 9, the ratio of the intensities of the recorded radio signals corresponding to each channel C1 = B1 / A1 at a certain point in time is calculated, where A1 is the signal corresponding to the low-frequency range, B1 is the signal corresponding to the medium-frequency range. The ratios of the intensities of the recorded radio signals are stored in the memory of the computing device 9. After a certain time, about 5-10 minutes, the previous steps are performed according to the above algorithm. The result is the ratio of the intensities of the recorded radio signals C2. The process is repeated during the observation time. Next, in the computing device 9, the intensity ratios of the recorded radio signals C1 and C2 are compared. If C1 is greater than C2, then we have “accumulation-mutation” (“passive”), if C1 is less than C2, then we have “growth-multiplication” (“active”).

Then, using a computing device 9, a curve is constructed of the ratio of the intensities of the recorded radio signals in the mid-frequency and low-frequency ranges, along which the boundaries of the time intervals of the cell state “growth-spacing” and “accumulation-mutation” are fixed in which the regulation of biochemical processes is started. The processed data is stored in non-volatile memory and subsequently can be displayed.

The main difference of this device is that in addition to measuring electromagnetic signals, the amplitudes of the signals are compared in different frequency ranges taking into account the current time.

When constructing the device, it is possible to use microchips of the K-176 series (CMOS), as well as microprocessor technology. The electromagnetic oscillation generator (FIG. 3) comprises a carrier frequency driver 14, a frequency divider 15, a modulator generator 16, a modulation depth adjustment device 17, a modulator 18, an amplifier 19, an output voltage control device 20, an antenna 21, and a carrier carrier frequency 14 is configured to adjust the frequency, the frequency divider 15 is configured to select a division coefficient, and the modulator generator 16 is configured to adjust the modulation period, while the output of the mod generator The oscillator 16 is connected to the input of the modulation depth adjustment device 17, the output of which is connected to one of the inputs of the modulator 18, the output of which is connected to the input of the amplifier 19, and the second input of the modulator 18 is connected to the output of the frequency divider 15, the input of which is connected to the output of the carrier frequency oscillator .

The electromagnetic oscillation generator operates as follows.

The master oscillator of the carrier frequency 14 generates high-frequency oscillations to obtain the desired oscillation frequency in each frequency range. It is designed to form electrical signals in the frequency range 80 kHz. -1250 kHz. The signal from the master oscillator of the carrier frequency 14 is fed to the input of the frequency divider 15, which divides the input frequency a predetermined number of times, for example, 2, 4, 8 and 16 times, while the frequency divider allows you to select, for example, using a passive mechanical switch to four positions one of the four frequency ranges of the carrier frequency: 80 kHz - 160 kHz; 160 kHz - 320 kHz; 320 kHz - 640 kHz; 640 kHz - 1280 kHz. As a frequency divider 15, for example, a binary counter with parallel outputs can be used. The signal from the output of the frequency divider 15 is fed to one of the inputs of the modulator 18, the second input of which receives a signal from the device for controlling the depth of modulation 17.

The modulator 18 multiplies the oscillations of the carrier and modulating frequencies, at the output of the modulator 18 receive an amplitude-modulated signal. The modulator can be performed, for example, on one inverter. A device for controlling the depth of modulation 17 provides a signal with a different amplitude of modulation at the output of the modulator 18. It can be implemented, for example, in the form of a passive mechanical switch to two positions or a variable resistor. The modulator generator 16, the signal from which is input to the modulation depth control device 17, is configured to adjust the modulation period and generates low-frequency oscillations with a period of 10 to 100 ms.

The amplifier 19 provides coordination of the output of the modulator 18 with the device for regulating the output voltage 20. As the amplifier 19 can be used, for example, a power amplifier or an emitter follower, and it can be made in the form of, for example, one or more inverters.

Next, the signal from the amplifier 19 is fed to the input of the output voltage control device 20, made, for example, in the form of a variable resistor, with the help of which a smooth change in the output voltage (from zero to maximum value) is carried out, which subsequently goes to the antenna 21, which can be made in the form of one or more turns of wire. The circuit of the master oscillator of the carrier frequency 14 can be, for example, performed on three inverters with frequency-dependent feedback. The electric circuit of the modulator generator 16 is similar to the circuit of the master oscillator of the carrier frequency 14. The differences are in the magnitude of the parameters of the RC circuits that determine the frequency of generation. The modulation frequency is determined experimentally depending on the nature of the expected impact. Moreover, the modulator generator 16 is configured to provide overlapping over the frequency range more than ten times.

As regulating elements of the modulator oscillator 16 and the carrier frequency master oscillator 14, for example, variable resistors with a linear characteristic are used.

When constructing the circuit, it is possible to use K-176 series microcircuits (CMOS). It is also possible to use circuits based on microprocessor technology. Power is provided, for example, from an external source attached to the generator of electromagnetic waves. The inclusion and control of availability is provided by the toggle switch and a red LED.

If it is necessary to work with several frequency ranges, several generators are used simultaneously, with one or several antennas attached to them.

Examples of the invention are given for all variants of the invention.

Example 1. We carry out the process of cell division of "living" yeast in a sweetened aqueous medium. We begin fixing for a given location (Moscow) using the device described above for recording electromagnetic oscillations of boundaries and the duration of the “growth-multiplication”, “accumulation-mutation” intervals and trying to get exactly at each interval, we carry out about 100 procedures for cell division of “living” yeast in a sweetened aquatic environment. This operation can also be carried out using the constructed schedule of successive intervals (Appendix 1 - table 1, 2). For brevity, we call the active period of the state of cells “growth-multiplication” - active (“asset”), and the relatively passive period of the state of cells “accumulate” - passive (“passive”).

The process is as follows. We place the packaged “live” yeast in one of 5 cuvettes calibrated by volume, fill them with ordinary clean water with sugar added at the beginning of the “active” time interval, having previously determined the exact total volume and mass of this mixture. We leave this open cuvette with this mixture for 2–3 hours until completion, due to saturation, of the division process. If the mass of “live” yeast is 100 grams, the volume of water is 10 ml, the mass of added sugar is 20 grams, then the reaction will take about 2.5 hours. This completes the process of growth in the volume and mass of the yeast, and to determine the volume and mass of the resulting yeast product, it is necessary to wait another 22 hours until a clear boundary appears between the yeast fraction and the residual solution above it. Air temperature, atmospheric pressure, and air humidity are practically unchanged. Similarly, repeat the procedure at the beginning already interval “accumulating”, following the indications of the device described above for recording electromagnetic oscillations of the indicated time intervals. Similarly, repeat the procedure at the beginning of the next interval. In total, experiments are carried out with five cuvettes during the day. The duration of the full experiment was about 3 months. All data are summarized in Appendix 1 (tables 1, 2), attached to the application.

To illustrate the calculations and explain the results, we present the indicators of several experiments with “live” yeast (table 3). Using the knowledge of the boundaries of the “active” intervals, “saving”, we start the process of yeast division within these intervals, which allows us to judge our actions as regulating the growth and reproduction process.

Table 3

Example 2

The total mass of the composition in the cell 2 at the beginning of the experiment is 220 g, its mass at the end of the experiment, together with the released yeast fraction, minus the evaporated substance after sedimentation, is 211 g, volume composition at the beginning of the experiment - 192 ml, after sedimentation, the volume together with the yeast fraction is 180 ml, the density of the solution over the released yeast fraction (p1) is 0.77 g / ml, the volume of this solution (Vl) is 90 ml.

The total mass of the composition in cell 3 at the beginning of the experiment was 220 g, after the sediment its mass was 211 g, the volume of the composition at the beginning of the experiment was 192 ml, after the sediment it was 180 ml, the density of the solution over the released yeast fraction (p1), which in addition to direct measurement, by weight and volume of the evaporated liquid, 0.77 g / ml, the volume of solution above the released yeast fraction (V2) is 55 ml, and the yeast fraction (V2b) is 125 ml.

The mass of precipitated yeast sediment can be determined in different ways. In particular, the mass and density of yeast sediment, respectively, y1 and y2 in the 2nd and 3rd cells can be obtained from the following equations: x1 V1 + y1 V1в = 211 x1 -V2 + y2-V2в = 211

Substituting the above numerical values into the equations, we obtain: the mass of yeast sediment in the 2nd cuvette is 141 g, its density y1 is 1.57 g / ml, the mass of the yeast fraction in the third cuvette is 168, 75 g, and its density y2 - 1, 34 g / ml.

Thus, the difference between the volumes of the yeast precipitate obtained in both cuvettes is 35 ml, and the mass difference is 27.75 g. If we take the mass of the yeast fraction in the 2nd cuvette as 100%, then in the 3rd cuvette the mass of yeast sediment will be approximately 20% more. If you do the same in terms of volume, then the volume of the yeast fraction in the 3rd cell will be 38% more than in the 2nd one. Summing up the results of three-month experiments (see Appendix 1 in the form of tables 1, 2 to the application), it should be noted that the increase in the volume of “live” yeast when certain conditions were created for their division (division in the “asset”) turned out to be 25-30% more in comparison with the similar process in the “passive”.

It should also be noted that these figures are characteristic only for those experiments, the time interval for reactions, in which, before saturation, clearly fits into the “active” or “positive” intervals, respectively. When superimposing the division process to one degree or another on both intervals (see Fig. 1 and tables 1, 2 in Appendix 1), i.e. the beginning of the process is carried out, for example, in “asset”, and its completion is carried out in “liability”, and when the process partially enters the transition period, from one state of cells to another, these figures decrease, which further confirms our assumptions about various phenomena in cells of organisms in the "asset" and liabilities "(quasi-stationary process).

As a result of such a simple registration of the boundaries of a change in the state of cellular structures, it becomes possible to regulate any biochemical processes by carrying out the entire process or its “active” part in a “necessary” time interval, also taking into account their alternation. So, comparing experiment N ° 5, table 1 from 7.8.97 of Fig. 1, we found a direct relationship between the minima of biomass in cuvettes 1 and 3 and the maxima in cuvettes 2, 4, 5 and, respectively, the “pass”, “active” and “ quasistationary "process. Here we see that, say, the difference in the volumes of the yeast fractions of the “assets” and “liabilities” is only 20% (example NQ2). The explanation is that these “assets”, as can be seen from the curves, are located near the “quasi-stability”. According to option 3, by tracking the “asset-passive” intervals and starting the growth process, for example, of yeast, in the “asset”, we include feedback in the regulation system of the biochemical process. If the “asset” is short, then an electromagnetic oscillation generator is used to regulate biochemical processes, as a catalyst generating a spectrum by which a positive slope of the intensity ratio curve of the recorded radio signals is obtained. If “passive” is needed, then an electromagnetic oscillation generator is used to control biochemical processes, as an inhibitor, by which a negative slope of the intensity curve of recorded radiosignals is obtained.

Example 3. An illustration of option 3 can serve as experiments with sprouted grain, the results of which are shown in figure 4. The photographs show the germinated grain on the seventh day after the start of the experiment. In FIG. 2 shows the following stages of grain growth: a) grain is not exposed it was exposed to an electromagnetic oscillation generator to regulate biochemical processes, the sprouts reached 8.0 cm, b) ceteris paribus, the grain was influenced by an electromagnetic oscillator to regulate biochemical processes, used as an inhibitor, the sprouts reached 6.5 cm, c) the grain under the influence of an electromagnetic oscillation generator for regulating biochemical processes used as a catalyst, the germs reached 11.5-12 cm.

Example 4. Athlete M. and athlete O. play tennis. They have the same game technique. In the sparring, depending on the slope of the intensity-ratio curve of the recorded radio signals, the player was shown the game style: aggressive style with positive slopes of the intensity-ratio of the recorded radio signals and negative - a game from defense, which led to one hundred percent dominance of player M., to his clear advantage.

Example 5. Patient A. He complained of inflammation of the maxillary sinuses. Diagnosis: sinusitis, frontal sinusitis. The surface temperature of the face was measured using a thermal imager, in areas prone to frontal sinusitis and sinusitis, the temperature was 37.5-38 ° C (figa - 1 - red). We determined the slope of the intensity ratio curve of the recorded radio signals, which corresponded to the negative slope - “positive”, set the amplitude of the electromagnetic oscillation generator to a value higher than the natural background of the “positive” state. 15 minutes after turning on the electromagnetic oscillation generator, the temperature dropped to 36.8-37.2 ° C (Fig. 56 - 1 is red). In the second procedure, the surface temperature in the areas prone to frontal sinusitis and sinusitis was 37.5 ° C (Fig.5c - 1 - red, 2 - green), the slope of the intensity ratio curve of the recorded radio signals corresponded to the positive slope - "active" and in this case, the intensity of the electromagnetic oscillation generator was set at the natural level, which is significantly less than in the first case, the temperature dropped to 36.8 ° C (Fig. δg).

It is well known that magnetic storms affect people's well-being. A magnetic storm is a change in the Earth’s magnetic field that occurs 4-6 km above sea level for 6-12 hours within 6-10 ml Gauss. and the consequences of its implementation on Earth in the form of gloomy statistics of diseases and deaths. At the same time, the influence of electrical appliances is many times greater than the influence of magnetic storms. One approach to the television is equivalent to the action of 14 ml of Gauss. The action of an electric razor gives 300 mlGauss, and the outgoing electric train in the metro 500 mlGauss on the platform and 1500 mlGauss in the train, which is 700 times higher than the maximum permissible norm (MPL), which is 2 mlGauss for the value of the magnetic field. The experiments showed that the use of the catalytic properties of an electromagnetic oscillation generator for regulating biochemical processes (according to option 3) makes it possible to compensate for the harmful effects of anthropogenic nature and increase the body's immunity to the influence of these factors. By turning on the electromagnetic oscillation generator for regulating biochemical processes, which has two channels, and the intensity of the channels is different from each other, we ensure that the intensity of each of the two channels is greater than the intensity of the natural background at a given point in space, while the ratio of intensities between create “active” or “passive” channels, depending on the solution of certain tasks. Experiments were carried out on the effect of mobile phones on the blood circulation of the brain, which are accurately recorded by encephalograms and thermograms. In FIG. 66 the thermogram shows the temperature of the patient's face before the experiment - 1 - red; on figb, c, d the thermogram shows the temperature of the face after using a cell phone - 1 - red color, showing a temperature of about 37.5-38 ° C. 2 minutes after connecting the electromagnetic oscillation generator, the readings of the thermograph and the encepholograph indicate the norm in the body. This means that the body has compensated for the harmful effects (Fig. 6e). Thus, the inventive method of regulating biochemical processes can improve the accuracy and efficiency of regulation of the biochemical process by simple and direct determination of the time intervals of the state of the cells of the biosystem, allowing according to the indications of the device for recording electromagnetic waves clearly regulate the biochemical process, eliminating possible harmful deviations in the process of cell division, which leads to improved product quality.

Industrial applicability The invention can be applied in the broadest areas of bioproduction for accelerated growth of bioproducts, for example, in microbiology, crop production and animal husbandry, in medicine for the correction of biochemical processes of certain functions of the human body with the aim of improving it, preventing and treating diseases, and also in the postoperative period.

Appendix 1 Table Ns 1

thirty

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31

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32-

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eleven

51.

SUBSTITUTE SHEET (RULE 26) Table Ne 2

The content of the cuvette before the experiment: 100 g of live yeast, 30 g of sugar, 200 ml of water. Quantity of ditches: 5 Volume of a ditch - 3 l

The volume content of the yeast fraction was determined 24 hours after the start of the experiment on the formed border of the yeast and water fractions.

Claims

Claim

1. A method for regulating biochemical processes in a given place in space by registering time intervals of cell states “growth-multiplication” and “accumulation-mutation”, characterized in that the boundaries of the “growth-multiplication” interval are fixed at the beginning and end of a positive slope of the intensity ratio curve of the recorded of radio signals, respectively, in the mid-frequency and low-frequency ranges, and the boundary of the “accumulation - mutation” interval is fixed at the beginning and end of the negative slope of the intensity relation curve radio signals, respectively, in the mid-frequency and low-frequency ranges, while within the boundaries of the “growth-multiplication” intervals, they regulate the growth of cell cultures or accelerate the cultivation of products or regeneration of biological structures or carry out processes that are affected by this state of bioobject cells, and within the limits of the intervals “accumulation mutation ”stabilize transient biochemical processes caused by mutations or perform selection of the resulting product or initiate and support processes that are affected by this e state of the cells.

2. The method for regulating biochemical processes in a given place in space according to claim 1, characterized in that the recorded radio signals are fixed in the ranges of 250-900 kHz in the frequency band 10-20 kHz and 100-250 kHz in the frequency band 10-20 kHz.

3. A method for regulating biochemical processes in a given place in space by registering time intervals of cell states “growth-growth” and “accumulation-mutation”, characterized in that within the boundaries of the “growth-growth” interval, to regulate the growth of cell cultures or accelerated cultivation of products or regeneration of biostructures or processes that are affected by a given state of cells of biological objects are performed, a signal is generated whose spectrum corresponds to a positive slope of the intensity ratio curve radio signals, acting as a catalyst, and the boundaries of the interval "nakoplenie -

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SUBSTITUTE SHEET (RULE 26) mutation ”to stabilize transient biochemical processes caused by mutations or to select products obtained or to initiate and maintain processes that are affected by a given state of cells, generate a signal whose spectrum corresponds to a negative slope of the intensity curve of the recorded radio signals, acting like an inhibitor.

4. A method for regulating biochemical processes in a given place in space according to claim 3, characterized in that the recorded radio signals are fixed in the ranges of 250-900 kHz in the frequency band 10-20 kHz and 100-250 kHz in the frequency band 10-20 kHz.

5. A method for controlling biochemical processes in a given place in space according to any one of claims 3, 4, characterized in that the generation of signals is performed by an electromagnetic oscillation generator.

6. A method for regulating biochemical processes in a given place in space by registering time intervals of the state of cells “growth-multiplication” and “accumulation-mutation”, characterized in that for recording the interval “growth-multiplication” a signal is generated whose spectrum corresponds to a positive slope of the relationship curve the intensities of the recorded radio signals, acting like a catalyst, and within the boundaries of the “accumulation - mutation” interval, a signal is generated whose spectrum corresponds to the negative slope of the relationship curve and of the intensities of the recorded radio signals, acting as an inhibitor, at the same time, within the boundaries of the intervals “height-sheath”, they regulate the growth of cell cultures or accelerate the cultivation of products or regenerate biostructures or carry out processes that are affected by this state of biological object cells, and within the intervals “ accumulation - mutation ”stabilize transient biochemical processes caused by mutations or perform selection of the resulting product or initiate and support processes that are affected by this standing cells.

7. The method of regulating biochemical processes in a given place in space according to claim 6, characterized in that

56

SUBSTITUTE SHEET (RULE 26) the recorded radio signals are fixed in the ranges of 250-900 kHz in the frequency band 10-20 kHz and 100-250 kHz in the frequency band 10-20 kHz.

8. The method of regulating biochemical processes in a given place in space according to any one of paragraphs.6, 7, characterized in that the generation of signals is performed by an electromagnetic oscillation generator.

9. A device for recording electromagnetic waves, comprising a detector, an amplifier and a display device, characterized in that at least two receiving devices, a second amplifier, two analog-to-digital converters, as well as a computing device including random access memory are additionally introduced into it the device, and the amplifiers are configured to normalize the amplitude, with each of the outputs of the receiving device is connected to the corresponding input of the amplifier, each of the outputs of which are connected ene with an input analog-to-digital converter, whose outputs are connected to respective inputs of the computing device, which is connected to the output display device.

10. A device for recording electromagnetic waves according to claim 9, characterized in that the receiving device is made in the form of a resonant antenna.

11. The device for recording electromagnetic waves according to claim 9, characterized in that the computing device is configured to connect a display, non-volatile memory, keyboard and external devices using a communication interface.

12. The device for recording electromagnetic waves according to claim 11, characterized in that the non-volatile memory is made in the form of a ferromagnetic memory.

13. A device for recording electromagnetic waves, comprising a detector, an amplifier and a display device, characterized in that at least two receiving devices, a second amplifier, two analog-to-digital converters, as well as a computing device including random access memory are additionally introduced into it device, non-volatile memory,

57

SUBSTITUTE SHEET (RULE 26) an interface for communication of external devices with a computing device, the receiving device being made in the form of a resonant antenna, the amplifiers are capable of normalizing the amplitude, and each of the outputs of the receiving device is connected to the corresponding input of the amplifier, each of the outputs of which is connected to the input of an analog-to-digital converter, the outputs which are connected to the corresponding inputs of a computing device configured to connect a display device, non-volatile memory, int rfeysa connection of external devices with the computing device.

14. A device for recording electromagnetic waves according to claim 13, characterized in that the non-volatile memory is made in the form of a ferromagnetic memory.

15. An electromagnetic oscillation generator comprising a master carrier frequency generator, a modulator, a modulator generator, characterized in that it further includes a frequency divider, a modulation depth control device, an amplifier connected in series, an output voltage control device and an antenna, the carrier frequency driving generator with the ability to adjust the frequency, the frequency divider is made with the choice of the division coefficient, and the modulator generator is made with the possibility of p adjusting the modulation period, while the output of the modulator generator is connected to the input of the modulation depth adjustment device, the output of which is connected to one of the modulator inputs, the output of which is connected to the amplifier input, and the second modulator input is connected to the output of the frequency divider, the input of which is connected to the output of the master oscillator carrier frequency.

58

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