RU2004267C1 - Method and device for forming non-invasive programmable effect on biological object - Google Patents

Abstract

The invention relates to reflexology and physiotherapy and can be used for therapeutic and prophylactic purposes. The technical result - expanding the programming range, increasing the efficiency of exposure by providing the possibility of remote exposure, providing the possibility of using a wide range of working substances to comply with the full coordination of the parameters of the radiation and the object of exposure, reducing the excitation energy of the working substance and providing the ability to control the parameters of the secondary radiation - is achieved that in a method of forming a non-invasive programmable air effects on the biological object, including the effect of external exciting energy on the substance, the interaction of which with the biological object changes the functional state of the latter, the controlled substance is influenced by the controlled external exciting energy, and the secondary substance of the transforming substance is affected by the working substance, the output secondary radiation of which interacts with the biological object , and a device for forming a non-invasive programmed effect on a biological object contains a source block of an exciting energy and a substance located in the zone of action of the external exciting energy in the container as a converting substance, and the working substance is located along the working axis of the secondary radiation of the converting substance, while the block of the external exciting energy source is made in the form of a controlled magnetic or electric field. 8 s.p. f-ly, 7 ill. d to o about U s ON -4 p

Description

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The invention relates to reflexology and physiotherapy and can be used for therapeutic and prophylactic purposes.

The aim of the invention is to expand the programming range and increase the efficiency of exposure by providing the possibility of remote exposure, providing the possibility of using a wide range of working substances the most complete harmonization of the parameters / frequency spectra) of the radiation and the object of exposure, reducing the excitation energy of the working substance, eliminating the degradation of working substances under the impact of external exciting energy, reducing the value of the side uncontrolled output zlucheni, permit an optimum control of the secondary radiation parameters (shape, the spatial orientation of the flow, and the energy of the frequency spectrum).

Fig. 1 is a schematic diagram illustrating the proposed method; in FIG. 2 shows a functional diagram of the device; in FIG. 3 and 4 show various embodiments of an external field excitation source; FIG. 5 illustrates the relative position and interaction of the longitudinal and transverse exciting fields; FIG. 6, explains the principle of generating a flow of exciting radiation; Fig. 7 conventionally shows the trajectory of the secondary radiation particles.

A method for generating a non-invasive programmed effect on a biological object is illustrated in the following specific example.

In a certain volume into which the transforming substance 1 is placed, a magnetic field is created with a pulsating directivity vector 2. Under the influence of energy pulsating in the direction of magnetization (SiNi - S2N2), the transforming substance, whose physical properties are consistent with the nature of the external exciting signal, will propagate the fluxes of secondary radiation particles in the directions of the averaged position of the north 3 and south 4 poles pulsating in the direction of the magnetic field. The deviations of the directivity vector of the external exciting energy, depending on the type of sources used and the deviation systems contained in them, can be programmed in the plane or solid angle of the converting substance. Thus, the formation

secondary radiation by creating a time-periodic anisotropy of the external exciting energy in the planar or solid angle of the converting substance. Periodic anisotropy of the external excitation energy, when using magnetic or electric fields as the external excitation energy, is carried out by periodically deflecting the stress vector of the exciting field in the corresponding plane or solid angle of the converting substance.

Further, the working substance 5 is located directly along the middle axis of the secondary radiation of the converting substance, and the resulting biological radiation output stream acts on the biological object 6.

The angle of divergence of the secondary radiation flux (i.e., the maximum deviation from the middle axis of the radiation) depends on the characteristics of the exciting magnetic field and the inertia of the nuclear spin procession, therefore, it depends on the frequency and intensity of the magnetizing field and on the conversion substance used. Flow density i.e. the number of small particles per unit time depends on the magnitude of the magnetization, i.e. energy of each act, and the number of acts of polarity change per unit time (magnetization reversal frequency).

The main wavelength of the secondary radiation flux obtained by this method upon excitation (use as a converting substance) of water, controlled by diffraction gratings, is about 0.8 microns. In addition, when exposed to biological objects, the number of modulating vibrations, the frequencies of which depend on the type (spectrum of intramolecular vibrations) of the exciting substance, has a significant effect.

Thus, the secondary radiation of the converting substance contains a fundamental radiation frequency (carrier) and modulation frequencies equal to or a multiple of the spectrum of intrinsic molecular vibrations of the converting substance. Using the working substance as a matching substance in this method, the secondary radiation is necessary to be adjusted according to the frequency spectrum required to affect the biological object in each case. In addition, this method makes it possible to use a wide range of working substances,

since their degradation by the action of force fields of the external exciting energy is excluded, the energy of their excitation is reduced, the requirement of strict matching of their parameters with the characteristics of the external exciting energy (force fields) is eliminated.

It has been experimentally shown that it is possible to focus secondary radiation using geometric, magnetic, and electrostatic optics, and the use of these systems allows one to control the shape and spatial orientation of the flow. Electrostatic optics systems also provide additional control over the energy (wavelength, frequency) of the secondary radiation. In order to simplify the design of devices implementing this method, reduce their weight, dimensions, decrease the power of additional force fields used, sections with this field may contain an intermediate substance that fills the interpole gaps of focusing and control systems, the physical properties of which are consistent with the nature of the additional force field (respectively, substances with high magnetic permeability for magnetic focusing systems and substances with high dielectric constant for electrostatic iCal focusing and steering systems). The intermediate used in this way will affect the focusing and energy conversion parameters of the secondary radiation flux. At the same time, it can act as a working substance.

According to this method of generating an action, including preliminary energy conversion in a unit of a controlled source of external exciting energy containing a transforming substance, the functions of the working substance, which matches the frequency spectrum of the secondary radiation with the parameters of the object of influence, can be performed by a transforming substance, a system that converts a substance - a working substance, the intermediate substance of the section of the additional force field (focusing, control systems) directly part of the substance of the object Procedure.

A device that implements this method (a block of an external exciting energy source, see FIG. 3) contains a pair of alternately switched magnets (electromagnets 7), the magnetic fluxes of which pass at a small angle to each other through a container with an excited transforming substance 1. Radiation axes are located between the poles of the same name with magnets 8. A change in the nature of the excitation (sedative - tonic) can be accomplished by changing the polarity of the magnets.

Structurally, it is much more convenient device made according to the scheme shown in figure 4. In this example, variations in the direction of magnetic flux (± c) (see Fig. 5) are provided by two components: a polarizing longitudinal magnetic field, the vector of which determines the nature of the action, and when the direction changes to the opposite, the nature of the effect ( sedative - tonic); a transverse deflecting magnetic field, a system of magnetic deviation, the vector ± b of which is directed perpendicular to the polarization vector. The use of such a scheme of an external exciting energy source simplifies the design and significantly reduces the power supply of the deflecting magnetic field system, makes it easy to ensure high frequency variations in the direction of the voltage vector of the resulting magnetic field (s), and therefore the directivity vector of the secondary radiation, which is necessary to ensure biological informational impact. The resulting magnetic flux, depending on the deflecting magnetic field system used, changes the spatial direction in the form of a plane or telescopic angle (see Fig. B). By applying a transverse deflecting magnetic field system of three or more poles, a rotating magnetic field can be created, and therefore a conical rotation of the secondary radiation flux.

Practice shows that such topological dynamics during right-handed movement are most actively perceived by the bio-object as an increase in toning, and left-handed movement enhances the sedative effect. Moreover, the rotational speed is a significant biotropic factor. For secondary radiation, the application of several low-frequency modulations is possible, for example:

1. The frequency of the directivity vector in the angle of radiation is chosen equal to the frequency of the free procession of proton spins in the Earth’s magnetic field (about 2100 Hz for Moscow).

2. Lower frequency in the range 1 - 15 Hz (addressable) definable system

the biological object that will be most affected.

These frequencies can be adjusted automatically through sensors that record the actual magnitude of the Earth's external magnetic field in the area of the target and the state of the target, for example, by the magnitude of the skin-galvanic response.

The beam path in space will look like a double helical spiral (see Fig. 7). The amplitude of the higher frequency rotation of the indicated ones turns out to be smaller due to the inertia in the reorientation of the nuclear spins. The amplitude of the low-frequency oscillations (i.e., the diameter of the flow cone when it hits the target) is determined by the required processing area at the target.

The device can be made by systems of geometric, electrostatic and magnetic optics, with which it is possible to control the shape, spatial orientation of the secondary radiation flux. For example, an electrostatic optics system is a longitudinally-dragging or longitudinally-braking electric field. As studies show, in this case, depending on the gradient of this field, not only does the focal length change, i.e. the place of the maximum flux density, but the wavelength of the main secondary radiation flux (carrier frequency) also changes. The following dependence of the transformation (change) of the wavelength on the parameters of a section with a longitudinal electrostatic field was experimentally found.

So for the initial wavelength of about 1 μm, the following dependence was found:

± | .KI

L 1 L

L l e °

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where - - with a pulling field:

+ - with a braking field;

AO - initial wavelength;

E is the applied potential;

e is the dielectric constant of the dielectric;

1 - the path length of the flow in the dielectric;

K is the coefficient (0.7).

Studies have shown that it is advisable to use for influencing biological objects, depending on the tasks, the wavelength (i.e. color) of the primary (carrier) secondary radiation in the range of 0.3 - 2 microns. Combined

the joint program change of the rotation frequencies of the directivity vector of the secondary radiation, its size (shape) and focus of the flow, wavelength, including due to the choice of working substances, allows controlling the parameters of the output acting secondary radiation in such a way that using this method and devices , implementing it, it is possible to solve many problems of reflexology. This is especially significant in the presence of functional changes in the body and borderline states (fatigue, stress, dysfunctions of the neurogenic order). Several standard points or zones, for example, an ear, eyes, etc., are selected for influencing a biological object, which is especially important for automating the processes of regulating the vital activity of an organism.

A diagram of a device that implements these capabilities when using a magnetic force field is shown in FIG. 2. A magnetic core 10, a polarizing magnet 11 for receiving a magnetic flux vector are placed in a common housing 9, magnetic circuits 12 with pole shoes and windings 13 are an alternating magnetic deviation system for deflecting a vector of an exciting magnetic field, a longitudinal electrostatic field cell with a dielectric 14 and electrodes 15 , 16, a container with a converting substance 1, a container with a modulating working substance 5, a system of geometric or magnetic optics for focusing secondary radiation, reflecting interference e mirror 17, lens 18 or a cell of a magnetic element with a longitudinal field; The radiation directions of the secondary radiation flux are shown (forward 19, reverse 20).

The device operates as follows.

The longitudinal field of the external exciting energy source, caused by the polarizing magnet 11, acts on the volume in which the container with the transforming substance 1 is placed. The direction of the vector of this field is determined by the direction of the axis (vector) of the main radiation flux (19). The deviation system (12, 13) excites an alternating magnetic deflecting flux, usually directed at a right angle to the polarizable flux. The total directional vector will move in space. If the number of pairs of alternately excited poles in the deviation system is two or more, then the movement of the total magnetization vector, and consequently the induced secondary radiation of the converting substance, will be carried out within the plane or

solid angle with frequency control system deviation. After conversion to the north pole of a polarizing longitudinal magnetic field, a sedative stream of secondary radiation of the transforming substance propagates in nature, and tonic in the opposite direction. Thus, a change in the nature of the secondary radiation flux can be made by varying the sign of the polarizing magnetic field and the direction of rotation of the magnetic field of the deviation. The secondary radiation flux passes through a cell 14-16 with a longitudinal electrostatic field E, and the energy of the flux particles and, accordingly, the radiation wavelength (depending on the value of E) change. The wavelength-converted stream passes through a container with a working modulating substance 5, exciting its own intramolecular vibrations. The output exposure radiation is programmatically matched in spectral composition with the frequencies of natural, including intramolecular, vibrations of a substance

CLAIM

Claims (10)

1. A method of forming a non-invasive programmed effect on a biological object, including the action of an external excitatory energy on a substance, the interaction of which with a biological object changes the functional state of the latter, characterized in that, in order to expand the programming range and increase the efficiency of exposure by providing the possibility of remote exposure to ensure the possibility of applying a wide, in the spectrum of frequencies, coordination of the parameters of the acting radiation and the target , reducing the excitation energy of the working substance and eliminating the degradation of working substances under the influence of external exciting energy, reducing the amount of spontaneous uncontrolled output radiation controlled by external exciting energy, affects the converting substance, and the secondary radiation of the converting substance affects the working substance, the output secondary radiation of which interacts with a biological object, and the physical properties of the transforming substance used are consistent with the nature in external excitation signal and provide the possibility of using a wide range of required working substances, which have the ability to change the distance of the object of exposure. The spectral characteristics of the secondary radiation flux serve as a key for the object to determine the nature of changes in the body's vital processes. Changes in the configuration of the flux density in space, for example, focusing at a given distance, are provided by an optical or magnetic object 18. The reflective interference mirror performs the function of increasing the efficiency of the device due to the effective reorientation of the reverse secondary flow. The design of the device according to this method is similar, using electric field sources as the source of external exciting energy. In this case, instead of magnetic cores and poles, which create, respectively, a polarizing and deflecting magnetic field, electrodes are located, between which, with appropriate connection of power sources, a polarizing and deflecting electrostatic field is created, respectively. nor to a bioobject, the output secondary radiation of which is programmatically matched in the frequency spectrum with the frequencies of intramolecular vibrations of the substance of the target. 2. The method according to claim 1, characterized in that magnetic or electric fields are used as external exciting energy. 3. The method according to claim 1, characterized in that the secondary radiation is formed by creating a time-periodic change in the anisotropy of the external exciting energy in the plane or solid angle of the converting substance. 4. The method according to claims 2 and 3, characterized in that the periodic anisotropy of the exciting field is created by periodically varying the stress vector of the external exciting field in the corresponding plane or solid angle of the converting substance. 5. The method according to claims 1 to 4, characterized in that, in order to change the nature of the action from the exciting to the inhibiting, the polarity of the longitudinal component of the stress vector of the exciting field is reversed. 6. The method according to claim 1, characterized in that, for the purpose of controlling energy and spectrum of the secondary radiation, the working substance is affected by an additional exciting field with a longitudinal orientation of the stress vector relative to the working axis of the working substance. 7. A device for generating a non-invasive programmable action on a biological object comprising an external excitation energy source unit and a substance located in the external excitation energy action zone, characterized in that, in order to expand the programming range and increase the impact efficiency by providing the possibility of remote exposure , providing the possibility of applying a wide spectrum of frequencies, matching the parameters of the acting radiation and the object of influence, reducing the energy ology excitation of the working medium and avoid degradation of the working media under the influence of an external excitation energy, reducing the magnitude of the output side of uncontrolled radiation introduced into it from a container converting substance, Figure 1 located in the working zone of the external exciting energy, and the working substance is located along the working line of the secondary radiation of the converting substance. 8. The device according to claim 7, characterized in that the block of the source of external exciting energy is made in the form of a source of controlled magnetic or electric field. 9. The device according to claim 8, characterized in that, in order to generate secondary radiation, the external excitation energy source unit is made in the form of a longitudinal polarizing field source and at least one transverse deflecting field source connected through a switch to a source nutrition. 10. The device according to claim 9, characterized in that the sensor of the state of the object of influence is introduced into it, and the power supply system of the transverse deflecting field source is made in the form of a oscillating frequency generator, the control input of which is connected to the output of the state sensor of the object. 77 -X U twenty 9 P L / 315 11 1B 101 eighteen At nineteen F-. N-flffi Ihi 5 J j i Fm.Z ; / Y 3- /; Yu Fig. B .7