Method and device for activation of ion transport

 

The invention relates to the field of Biophysics. The essence lies in the fact that the developed method the activation of ion transport across cell membranes and capillary walls of living organisms and is exposed to the pulsed electromagnetic fields of extremely low frequencies generated by pulses of electric current. Use two types of signals, as well as their combination in the form of successive packages/ group packages/ series of groups of packages, sets, series, groups, packages or combinations of series of groups of packages, to provide simultaneous magnetomechanical and electrodynamic effects on ions of different elements, which causes the ion cyclotron resonance. The device for activation of ion transport contains the control and the control panel is connected to the infrared receiver operated at a distance from the remote transmitter of infrared radiation. The management and the control panel is connected to the control unit of the microprocessor, containing random access memory and non-volatile electrically erasable programmable programmed device. The control unit of the microprocessor is connected using the voltage amplifier, shimeki result - expanding Arsenal of therapeutic effects with the help of electro-magnetic fields. 2 N. and 17 C.p. f-crystals, 18 ill., table 2.

Background of the invention

The present invention relates to a method of activating the movement of ions, mainly through cell membranes and capillary walls in living organisms, and to a device for implementing this method.

Known methods to create a movement of ions based on pulsed electromagnetic fields of extremely low frequencies on living organisms. Magnetic field with negligible electrical component is generated with pulses of electric current. Method and device for creating a movement of ions across cell membranes known from a European patent application EP 0407006. The described method is based on the simultaneous activation of different kinds of ions, in particular, the CA++and mg++using the resonance frequency of the magnetic cyclotron resonance. The influence of a uniform magnetic field with a very low frequency, generated using sinusoidal pulses of electric current, with non-zero average value, is used for this purpose, when power lines are computers the change of the magnetic flux at the frequency of the cyclotron resonance, which is determined using equation

fc=Bq/2m,

where fcthe frequency of the alternating magnetic field, Hz;

q/m is the ratio of the ion charge-to-mass C/kg;

To - average flux density along the axis in Tesla.

A device for using the method in accordance with the above patent application comprises a generator of sinusoidal electrical pulses, which is connected with the constant and determined by the circuit constant current and the amplifier, the outputs of both of them are controlled by a switch that controls the pair of Helmholtz coils, which operate as a Converter of electrical impulse in the magnetic signal.

In another embodiment, presented in the European patent EP 0594655, the main current pulse, consisting of a rectangular wave, superimposed on an exponentially increasing current, is used to transfer ions, followed by a pause, at least, as long as at least the duration of the pulse. Pulses and pauses wave form from 100 to 1000 Hz. Pulse amplitude modulated with a signal from 0.5 to 35 Hz, the envelope modulation is triangular (close to an isosceles triangle). Posledovatel 1, then followed by a pause of from 0.7 to 5.0 C. Packets of pulses is converted into a signal of an alternating magnetic field, electrodynamically and magnetomechanical acting on ions and, in particular, protons, to cause their transfer across the cell membrane. Device for the transport of ions, as described in the cited patent, consists of a control panel connected to the control unit of the microprocessor, and then, by using the amplifier in the transmitting coil, which converts the current pulses in the magnetic signals. The control scheme consists of a microprocessor, clock generator, memory address generator and analog-to-digital Converter.

A brief description and purpose of the invention

In accordance with the present invention, the method of activation of ion transport across cell membranes and capillary walls in living organisms is based on the effects of pulsed electromagnetic fields of extremely low frequencies, generated with pulses of electric current. There are two types of signals and their combination in successive packages, group packages, a series of groups of packets, sets a series of groups of packages, combinations of sets of series of groups of packages. They magnetomechanical and El is o organisms. In the electrodynamic effects of magnetic fields on biological system approximately cylindrical shape, is induced by the electric field. The intensity of the field E depends on the rate of change of induction dB/dt according to equation

where r represents the radius of the cylinder.

Alternating field E induces an inductive ion current density j, as defined by the equation

j=0E,

where0represents the electrical conductivity of biological systems. When exceeded electric current density of 10 mA/m2there are changes in the metabolism of carbohydrates and changes the permeability of lipid membranes of cells, facilitating the transport of ions across cell membranes.

Effect of ion cyclotron resonance associated with the phenomenon of ion eddy currents. As the angular frequencyand linear cyclotron resonance frequency fc=with/2depend on the induction of the magnetic field in a specific area of the living organism and the relationship of charge q, mass m, according to the formula

Magnetomechanical force F represents the gradient of the magnetic field, dB/dx, and can be expressed using equation

where V is the volume of uncompensated spins

the relative magnetic permeability of biological systems,

0- magnetic permeability of vacuum.

Characteristics of induction as a function of time B=f(t) for both types of signals used in the present invention, represent a broken line, increasing from zero to bmax. The characteristic signal of the first type is a polygonal line consisting of seven segments, with a total duration of from 3.0 to 9.4 MS. Within his first cut, induction increases linearly from zero to 1/3 Bmaxin the course of from 0.5 to 1.6 MS. Within its second segment, which is parallel to the axis t, the induction has a constant value 1/3 Bmaxin the course of from 0.5 to 1.2 MS, then, within his third cut, it linearly increases from 1/3 Bmaxup to 2/3 Inmaxin the course of from 0.4 to 1.5 MS. Within its fourth handle the s from 0.1 to 0.5 MS. Within their fifth segment, induction increases linearly to bmaxin the course of from 0.5 to 1.5 MS. Within his sixth segment, which is approximately perpendicular to the axis t, the induction decreases sharply to zero within 0.1 MS or less, remaining at zero value within its seventh segment in the course of from 0.5 to 1.5 MS.

The characteristic signal of the second type has the form of a broken line consisting of five lines with a total length from 5.0 to 9.4 MS. Within his first cut, induction increases linearly to a value of 1/2 Inmaxin the course of from 0.7 to 1.3 MS. Within its second segment, which is parallel to the axis t, the induction is maintained constant at the value 1/2 Inmaxin the course of from 1.8 to 2.8 MS, then, within his third cut, it increases linearly to bmaxin the course of from 0.5 to 1.2 MS. Within his fourth segment, which is approximately perpendicular to the axis t, the induction decreases sharply to zero within a maximum of 0.1 MS, remaining at zero value within their fifth segment in the course of 1 to 2 MS.

For signals of both types, the induction does not exceed the effective value of Bsk=100 MKT. Its linear vosnovnom electrodynamic and magnetomechanical effect.

On the other hand, the induction of which is maintained constant at the levels 1/3max, 2/3maxand 1/2 Bmaxand presents the characteristic B=f(t) in the form of segments parallel to the axis t, leads mainly to the emergence of ion cyclotron resonance. The frequency of the alternating magnetic field represent a frequency fcion resonance for different items. The ratio of fcby induction In an alternating magnetic field is equal to the ratio of the electric charge of ions of a particular element to the mass of the ions.

In the method according to the present invention, the signals of both types are combined into packages, each of which consists of a series of consecutive individual signals between successive packets included a pause, the length of the pause between successive signals of the first type is longer than the length of the pause between successive signals of the second type. Packages consisting of four signals of the first type and the five signals of the second type are often used. The duration of the packet signals of the first type is from 10 to 50 MS, and the length of the pause is equal to 40 to 60 MS.

The duration of the packet signals of the second type of composition is formed into groups of packets from the signals of both types. Each group consists of a series of packet signals of a particular type, with a pause between successive groups.

The packet signals of the first type last from 250 to 400 MS pause duration is from 40 to 60 MS.

The packet signals of the second type last from 140 to 300 MS, the length of the pause is from 80 to 200 MS. To use packet signals of the first type is advantageous to include at least five packages and package groups of signals of the second type contain at least four packages. Moreover, is the concatenation of groups of packets in the series, and then to combine sets into sets.

Each series consists of a specific sequence of groups of the packet signals, the pause occurs between successive series of groups of packages. The duration of a series of groups of packets of signals of the first type is from 7 to 10, the pause between the series continues for 3 to 4 C.

The duration of a series of groups of blocks of signals of the second type is from 5 to 9, pause between each series lasts for 2 to 4 C.

A series of groups of blocks of signals of the first type is usually from twenty to twenty - six groups, mainly from the four groups, mainly, from twenty-two groups.

Is used to combine sets into sets, each set consists of a sequence of series of groups of blocks of signals of a particular type. The duration of the series of groups of blocks of signals of the first and second types is in the range between 90 and 240 C.

Positive and negative polarization, as a rule, a variable is used to set a series of groups of blocks of signals of a particular type. Is primary when a set series of groups of blocks of signals of the first type consists of at least ten series, and when the set of series of groups of blocks of signals of the second type consists of at least eleven episodes. The signal amplitude in both types of sets of groups of blocks of signals is maintained at a specified level not exceeding the effective value of Bsk=MKT 100, and/or changes step by step in successive series.

Combination sets of the series of groups of blocks of signals of the first and second types in the form of at least two sets of series of groups of blocks of signals of the first type, followed by at least two sets of groups of blocks of signals of the second type are often used.

Use different polarization sets detoit from the management and the control panel with buttons to control the signal lamps, connected to the control unit microprocessor with generator and memory and, further, with the amplifier. The amplifier is connected to the Converter and with a dummy load using a symmetric current source and the Executive system. The Executive system is directly connected to the system control microprocessor. The Converter current pulse in the electromagnetic signal, usually manufactured in the form of a magnetic applicator containing at least one electromagnetic coil, generating an inhomogeneous magnetic field. The management and the control panel is connected to the infrared receiver, controlled by a remote controller. The control unit microprocessor has memory, predominantly type random access memory (RAM) for direct control, and non-volatile, electrically erasable programmable ROM (non-volatile EEPROM for external programming device functions. Random access memory (RAM) contains the form of current signals of both types, the sequence of their implementation, combinations and forms packages, group packages, a series of groups of packages, sets a series of groups of packets with time Emoe programmable ROM contains the standard, ready-to-use program combining signals in packages, group packages, a series of groups of packets and sets a series of groups of packets with temporal relationships and changes of amplitudes taken into consideration. The voltage amplifier has two operational amplifier. The input of the voltage amplifier is connected directly to the non-inverting input of the first operational amplifier and, via a resistor, to the inverting input of the second operational amplifier. The second operational amplifier, together with four resistors, form a differential amplifier non-inverting input connected to the output of the first operational amplifier.

Parallel connected circuit consisting of a resistance included in series with the keys attached between ground and the inverting input of the first operational amplifier to generate the negative feedback circuit of the first operational amplifier.

The amplifier output voltage represents the output of the second operational amplifier. The output voltage of the voltage amplifier depends on the keys according to the formula;

and Uwy=0 for n=0,

where Uwy- output of neprezentare transport of ions across cell membranes of living organisms under the influence of an inhomogeneous magnetic field with a very low frequency provides an increase in the number of movable ions of a given element and the number of types of elements, ions which are transferred. This effect is a result of the introduction of two types of magnetic signals with characteristics, formed according to the present invention, which leads to the simultaneous occurrence of three types of effects: electrodynamic effect, magnetomechanical effect and the effect of ion cyclotron resonance.

The possibility of combining signals in packages, group packages, a series of groups of packets and sets a series of groups of packages, together with the possibility of changes in the duration and amplitude, provides a quantitative and qualitative control of a large set of transmitted ions by changing the proportion of a particular type of magnetic field. Device for application of the method of activation of ion transport, coupled with the control unit of the microprocessor, connected to the amplifier and Converter using a symmetric current source, makes possible the generation, amplification and transmission of two types of signals with characteristics in accordance with the present invention.

Random access memory (RAM) control unit of the microprocessor makes possible the direct task of the combinations of the signals of both types in the form of packages, group packages, series GRU is that all controlled from the control panel. The Association of the control unit of the microprocessor and the remote control and infrared receiver, and together with an additional electrically erasable programmable read-only memory makes possible the selection and switching of sets of combinations of signals that have already been created, and to take into account changes in the duration and amplitude.

The main advantage of this solution is the possibility of remote switching device in the absence of long-term contact of personnel with the magnetic field. Managed using binary voltage amplifier with parallel connected circuits of the series resistance and key ensures that the management of the amplitude of the output depends on the selected program. Moreover, the connection device with the Executive scheme with equivalent load makes possible the simulation of the operation of the device.

Brief description of drawings

Fig.1 illustrates the characteristic changes of induction, as a function of the length of the first signal type;

Fig.2 illustrates the characteristic changes of induction, as a function of the length of the second signal type;

Fig.3 represents the characteristic smectitic change induction, as a function of time, for a package of five signals of the second type;

Fig.5 illustrates the characteristic changes of induction, as a function of time, for a group of five packets of signals of the first type;

Fig.6 is a characteristic change of the induction as a function of time, for a group of four packets of signals of the second type;

Fig.7 illustrates the characteristic changes of induction, as a function of time, for a series of twenty-four groups of packets of signals of the first type;

Fig.8 illustrates the characteristic changes of induction, as a function of time, for a series of twenty-two groups of blocks of signals of the second type;

Fig.9 is a characteristic change of the induction as a function of time for two sets of fifteen series of groups of blocks of signals of the first type in each;

Fig.10 illustrates the characteristic changes of induction, as a function of time for two sets of eighteen series of groups of blocks of signals of the second type in each;

Fig.11 illustrates the characteristic changes of induction, as a function of time for two sets of ten series of groups of blocks of signals of the first type in each;

Fig.12 illustrates the characteristic changes of induction, as a function of time, for distich change induction, as a function of time, for a combination of the two sets of series of groups of blocks of signals of the first type with two sets of series of groups of blocks of signals of the second type;

Fig.14 is a characteristic change of the induction as a function of time, for the combination of two series of groups of blocks of signals of the second type with two sets of series groups packet signal of the first type;

Fig.15 illustrates the characteristic changes of induction, as a function of time, for the combination of two series of groups of blocks of signals of the second type, and two sets of a series of groups of blocks of signals of the first type, with the amplitude increasing step by step in each set;

Fig.16 illustrates the characteristic changes of induction, as a function of time, for a combination of the two sets of series of groups of blocks of signals of the first type and two sets of series of groups of blocks of signals of the second type with the amplitude increasing speed in the first set and falling speed in the last set.

Fig.17 is a block diagram of the device for activation of ion transport;

Fig.18 is a schematic drawing of the voltage amplifier.

A detailed description of the preferred options of vypolnyali in the form of successive packets, groups of packages, a series of groups of packages, sets, series, groups, packages or combinations of sets of series of groups of packages. For both signals, the characteristic changes of the induction as a function of time t, are in the form of two different broken lines.

The line for the signal of the first type, as shown in Fig.1, is formed of seven segments a, b, C, d, e, f, g, with a total duration of T1=5,33 MS. Within his first cut and with a duration t'1=1,2 MS, induction increases linearly from zero to 1/3 Inmax=30 ILC, then it remains constant at this value during time t2=0.8 msec, within segment b. Within the segment with induction increases to 2/3 Inmax=60 MKT for t3=1.0 MS, then it remains constant at this value during time t4=0.3 MS, within segment d. Further, the induction increases linearly within the segment e to bmax=90 MKT for t5=0,95 MS, then, within the segment f, it decreases sharply to zero for t6=0,08 MS, remaining within the segment g, a value of zero for t7=1 MS.

The line for the signal of the second type, as shown in Fig.2, is formed of five sections k, l, m, n, r c for a total duration of T2=of 5.53 MS. In pH=40 MKT, then remains constant at this value during time t2'=2,3 MS, within segment 1. Within the segment m, it increases linearly to bmax=80 ILC, for t3'=0,75 MS, then decreases sharply within the segment n, to zero, for t4'=0,08 MS, and remains equal to zero, within a segment of r, for t5'=1.5 MS.

Linear increase in induction, as shown, within segments a, C, e characteristics of signals of the first type and lengths k, m, characteristics of signals of the second type causes mainly electrodynamic and magnetomechanical effects. Constant induction within segments b, d (=30 MKT and=60 ILC, respectively), for signals of the first type, and within segment 1 (=40 ICB), for signals of the second type causes mainly ion cyclotron resonance, whose frequency fcfor ions of different elements are equal to the frequencies of the alternating magnetic field. The ratio of the frequencies fcto the induction of an alternating magnetic field is equal to the ratio of the electric charge of an ion of a given element q to its mass m

Frequency ion cyclotron resonance fcfor SEL is received in table 1.

Table 2 shows the ratio of the electric charge q to the ion mass m for the elements of table 1.

Use the incorporation of both types of signals in the packets. The packet signals of the first type, as shown in Fig.3, consists of four successive signals for a total duration of Tp1=one-21.32 MS. Use the pause between packets with a duration of tp1=50 MS. The packet signals of the second type, as shown in Fig.4, consists of five signals for a total duration of TP2=27,65 MS, with a pause between packets with a duration of tp2=35 MS. In turn, the packets are combined into a group of signals of the same type. Group packet signals of the first type, as shown in Fig.5, contains five packages, four signal in each. The total duration of the group of packets is Tg1=306,6 MS pause between groups of packets has a duration of tg1=50 MS.

Group packet signals of the second type, as shown in Fig.6, the package contains four, five signals in each. The total duration of the group of packets is Tg2=215,6 MS, with a pause between groups of packets having a duration of tg2=130 MS.

G is of type as shown in Fig.7, consists of twenty-four groups of five packages each. The total length of the series is equal to Ts1=8,5, with a pause between each series of duration ts1=3,5 with. a Series of groups of blocks of signals of the second type, as shown in Fig.8, consists of twenty-two groups, four in each package. The total duration of the series is Ts2=7,5, with a pause between each series of duration ts22.5 C.

Series of groups of packets are additionally combined in sets with one type of signals.

Set a series of groups of blocks of signals of the first type, as shown in Fig.9, contains fifteen episodes, twenty-four groups each. The duration of the set isz1=3 minutes Polarization successive sets alternates between positive and negative. Set a series of groups of blocks of signals of the second type, as shown in Fig.12, contains twelve episodes, twenty-two groups each. The duration of the set is Tz2=2 min. Variable positive and negative polarization are used in successive sets.

Program I, for a duration of 10 min, as shown in Fig.13, is used to living organisms. It is with the series of groups of blocks of signals of the second type, for two minutes each. Successive sets change their polarization on the back.

Example 2

Used a series of signals of the first and second types, as described in example 1 and combined into sets. The set of series of groups of blocks of signals of the first type, as shown in Fig.11, consists of ten series, twenty-four groups each, with a total duration of Tz1=2 min. Variable positive and negative polarization are used in successive sets.

The set of series of groups of blocks of signals of the second type, as shown in Fig.10, contains eighteen series of twenty-two groups each, for a total duration of Tz2=3 min. Variable positive and negative polarization are used in successive sets.

Program II a duration of 10 min, as shown in Fig.14, is used to living organisms. It is a combination of the two sets of series of groups of blocks of signals of the second type, three minutes each, and two sets of series of groups of blocks of signals of the first type, for two minutes each. Successive sets change their polarization on the back.

Example 3

Use of a series of signals of the first and second tee is a of Fig.15, used to living organisms. It is a combination of two series of groups of packages types of signals of the second type and two series of groups of blocks of signals of the first type.

The duration of the sets of signals of the second type is six minutes. One set contains twelve episodes, total duration of two minutes, and the following set contains twenty-four episodes, total duration of four minutes.

The duration of the sets of signals of the first type is six minutes. One set contains twenty series and lasts for four minutes, and the following set contains ten series and lasts for two minutes.

The amplitude of each series varies stepwise manner within the cycle from minimum induction to the value of Bskfor a set, the same cycle is repeated in all the sets.

Example 4

Used a series of signals of the first and second types, as described in example 1 and combined in sets.

Program IV duration of twelve minutes, as shown in Fig.16, is used to living organisms. It is a combination of two series of groups of blocks of signals of the first type and two series of groups of blocks of signals of the second type.

the total duration of two minutes, and the following set contains twenty series, for a total duration of four minutes.

The duration of the sets of signals of the second type is six minutes. One set contains twenty-four episodes, total duration of four minutes, and the following set contains twelve episodes, total duration of two minutes.

Within the first set, the amplitude of the series is changed step by step from the minimum value of induction to 0.8 Bsk.

Within the Central sets, the amplitude of the series remains constant and equal to Bsk.

Within the last set, the amplitude of the series varies from 0.8 Vskto the minimum value of induction.

Example 5

Device to enable migration of ions, as shown in Fig.17, consists of a control and a control panel PS-buttons and signal lamps connected to a control unit of the microprocessor MUS generator, as well as random access memory device (RAM) and electrically erasable programmable ROM (EEPROM), and then, with amplifier W Amp W connected with symmetric current source IS and the Executive system UW Converter RA and the equivalent load PL. Executive UW system Suaeda with infrared receiver IR controlled by a remote controller R. the control Unit microprocessor MUS contains random access memory (RAM) for direct control and additional non-volatile electrically erasable programmable read-only memory for programming machine functions from the outside world.

Random access memory (RAM) contains the form of current signals of two types, the sequence of their appearance, the combination of signals in packages, group packages, a series of groups of packets and sets a series of groups of packages, taking into account their timing and amplitude.

Non-volatile electrically erasable programmable ROM contains ready-to-use program blocks from combinations of sets of series of groups of packages, taking into account their timing and amplitude.

The voltage amplifier, as shown in Fig.18, contains two operational amplifier W1 and W2. The input WE gain amplifier connects directly to the non-inverting input (+) of the first operational amplifier W1 and is connected through a resistance R1 to the inverting input (-) of the second operational amplifier. Operational amplifier W2, together with look no further than the with the output of the first operational amplifier W1. Between ground and the inverting (-) input of the first amplifier W1 are connected in parallel circuit consisting of a series of keys K1, K2, K3....CP is connected in series with resistors R, R/2, R/4,...R/2n-1as the negative feedback circuit of the first operational amplifier W1. The output of the second operational amplifier W2 serves simultaneously as the output WY amplifier W voltage. The output voltage Uwyamplifier W voltage varies enable keys K1, K2, K3...KP, according to the formula

and Uwy=0 for n=0

where Uwy- the output voltage of amplifier W and

Uwe- input voltage of the amplifier W.

The device starts working after selecting the programme and enable the buttons on the control panel PS or the remote controller R.

The control unit microprocessor MUS generates two types of pulses and their combinations in packages, group packages, a series of groups of packages, sets a series of groups of packages and combinations of sets of series of groups of packets stored in the random access memory device (RAM) and electrically erasable programmable read-only memory in digital form. The signal amplitude is controlled by using a managed binary codes utilitiesrates communication. Amplifier W voltage actuates the symmetric current source IS, which makes it possible for non-contact switching the polarization of the pulses which actuate the transducer RA through the Executive scheme UW when it is in its ground state. The current pulses are converted in the Converter RA signals in alternating magnetic fields that affect a living organism.

When simulated operation of the device, the Executive scheme UW is switched into the second state in which it is loaded with equivalent load PL.

Claims

1. The activation method of transport of ions across cell membranes and capillary walls of living organisms, consisting in effect of pulsed electromagnetic fields of extremely low frequencies generated by pulses of electric current, characterized in that the signals of two types and their combination in the form of successive packages, group packages, a series of groups of packages, sets, series, groups, packages or combinations of sets of series of groups of packages used for simultaneous magnetomechanical and electrodynamic effects on ions of different elements, resulting also in ostavlaet a broken line, distinguished for both types of signals and increasing from zero to bmaxwhere the characteristic signals of the first type is a polygonal line consisting of seven segments (a, b, C, d, e, f, g) with a total duration (T1) from 3.0 to 9.4 MS, while induction increases linearly within the first line (a) from 0 to 1/3 Inmaxand remains at this level within the second segment (b), which is parallel to the axis t, then within the third segment (C) induction increases linearly from 1/3maxup to 2/3 Bmaxand remains at the last value within the fourth segment (d), which is parallel to the axis t, then it increases linearly to bmaxwithin the fifth segment (e), and then it decreases sharply to zero within the sixth segment (f), which is approximately perpendicular to the axis t, and then remains at zero within the seventh segment (g), then the characteristic signal of the second type also represents a polygonal line consisting of five segments (k, l, m, n, r) total duration (T2) from 5.0 to 9.4 MS, where induction increases linearly within the first segment (k) from 0 to 1/2 Bmaxand remains at this level within the second segment (1), which is parallel to the axis t, the m it decreases sharply to zero within the fourth segment (n), which is approximately perpendicular to the axis t, and remains at the zero level within the fifth segment (r), when the effective value of induction for both types of signals do not exceed InSK=100 MKT, and where the linear increase of the induction, represented as line segments (a, C, e) and (k, m), inclined relative to the axis t, the signal characteristics of both types cause, mainly, electrodynamic and Electromechanical effects, and permanent induction In the supported values 1/3 Bmax, 2/3maxand 1/2max, and represented as components (b, d) and (1) parallel to the axis t, the result mainly of ion cyclotron resonance.

2. The method according to p. 1, wherein using the signal of the first type, in which the duration (t1the first segment (a) is in the range from 0.5 to 1.6 MS, the duration (t2the second segment (b) is in the range from 0.5 to 1.2 MS, the duration (t3) the third segment (C) is in the range from 0.4 to 1.5 MS, the duration (t4fourth segment (d) is in the range from 0.1 to 0.5 MS, the duration (t5the fifth segment (e) is in the range from 0.5 to 1.5 MS, the duration, what the limits of from 0.5 to 1.5 MS; also use the signal of the second type, in which the duration (t1the first segment (k) is in the range from 0.7 to 1.3 MS, the duration (t2the second segment (1) is in the range from 1.8 to 2.8 MS, the duration (t3) the third segment (m) is in the range from 0.5 to 1.2 MS, the duration (t4fourth segment (n) does not exceed 0.1 MS and the duration (t5the fifth segment (d) is in the range from 1 to 2 MS.

3. The method according to p. 2, characterized in that use packets of signals of both types, each of which consists of a sequence of consecutive individual signals of this type, and use the pause between successive packets, and the length of the packet signals of the first type (Tp1) is in the range from 10 to 50 MS, and the length of the pause (tp1) is in the range from 40 to 60 MS, the duration of the packet signals of the second type (Tp2) is from 20 to 30 MS, and the duration (tp2between packages pause ranges from 20 to 50 MS, and the duration (tp1) pause between consecutive packets of the signals of the first type is greater than the duration (tp2) pause between packets of signals vinisha least four signals each.

5. The method according to p. 3, characterized in that use packets of signals of the second type, consisting of at least five signals each.

6. The method according to p. 3, characterized in that the use of the package group signals of both types, and each group consists of a series of packet signals of a given type, and use the pause between successive groups, the duration (Tp1) group packet signal of the first type is from 250 to 400 MS, and pause (tp1) lasts for 40 to 60 MS, the duration (Tp2) group packet signals of the second type is from 140 to 300 MS, and pause (tp1) lasts for 80 to 200 MS.

7. The method according to p. 6, characterized in that the use of a group of packets of signals of the first type, consisting of at least five packages each.

8. The method according to p. 6, characterized in that the use of a group of packets of signals of the second type, consisting of at least four packages each.

9. The method according to p. 6, characterized in that the use of a series of groups of packets of the signals of both types, with each series consists of a series of groups of blocks of signals of a given type, and use the pause between successive series, the duration (Ts1) seal from 3 to 4, the duration (Ts2series of groups of blocks of signals of the second type is from 5 to 9, and pause (tp1between the series is from 2 to 4 C.

10. The method according to p. 9, characterized in that the use of a series of groups of blocks of signals of the first type, with each series consists of 20 - 26 groups, with 24 groups are predominant.

11. The method according to p. 9, characterized in that the use of a series of groups of blocks of signals of the second type, with each series consists of 20 to 24 groups, with 22 groups are predominant.

12. The method according to p. 9, characterized in that use sets of series of groups of packets of the signals of both types, and each set consists of a series of groups of blocks of signals of a given type, the duration (Tz1, Tz2series of groups of blocks of signals of the first and second types is in the range from 90 to 240 C, using both positive and negative polarization for a set of series of groups of blocks of signals of a given type.

13. The method according to p. 12, characterized in that use sets of series of groups of blocks of signals of the first type, and each set consists of at least ten series, using a variable positive and negative polarization for sleduushuu second type, each set consists of at least twelve episodes, using a variable positive and negative polarization for consecutive sets.

15. The method according to p. 12, characterized in that the amplitude of the signals in the sets of the series of groups of packets of the signals of both types of support at a certain level that does not exceed the effective value of InSK=MKT 100, and/or change step by step in successive series.

16. The method according to p. 12, characterized in that use combinations of sets of series of groups of blocks of signals of the first and second types in the form of at least two sets of series of groups of blocks of signals of the first type, followed by at least two sets of series of groups of blocks of signals of the second type, and use the opposite polarization for the other sets.

17. Device to enable migration of ions containing the control and the control panel with push-buttons and signal lamps, which are connected with the control unit of the microprocessor with the pulse generator of low frequency and storage device, and also connected through the amplifier to the transducer pulses of current in the electromagnetic Signoria, controlled by a remote controller (R), and the control unit microprocessor (MUS) contains memory type random access memory (RAM), mainly for direct control, as well as additional non-volatile electrically erasable programmable read-only memory for programming the external features of the device, while random access memory (RAM) contains the waveforms of both types, the sequence of their appearance, the combination of their parameters in packages, group packages, a series of groups of packages, sets a series of groups of packets with temporal correlations and amplitude changes taken into account, and non-volatile electrically erasable programmable ROM contains the standard ready-to-use program to specify combinations of signals in packages, group packages, a series of groups of packages, sets a series of groups of packets with temporal relationships and changes in the amplitude taken into account, in addition, managed the binary codes power (W) voltage connected to the symmetrical current source (IS) and additionally connected with the switching actuator circuit (UW), which is driven directly from the power panel is l (W) contains two voltage operational amplifier (W1, W2), and input (WE) of the voltage amplifier is directly connected to reinvestiruet (+) input of the first operational amplifier (W1) and through a resistance (R1) with the inverting input (-) of the second operational amplifier (W2), while the second operational amplifier with four resistors (R1) forms a differential amplifier with reinvestiruet input ( + ) connected to the output of the first operational amplifier (W1), and then between ground and the inverting input (-) of the first operational amplifier (W1), and the branches of series-connected switches (K1To2To3...Ton) and resistances (R, R/2, R/4... R/2n-1) is connected in the negative feedback circuit of the first operational amplifier (W1), and output (WY) of the amplifier (W) voltage represents both the output of the second operational amplifier (W2).

18. The device under item 17, characterized in that the output voltage (Uwy) of the amplifier (W) voltage changes depending on the key (K1To2To3... Ton), switchable according to the formula

and

Uwy=0 for n=0,

where Uwy- the output voltage of the amplifier;

Uwe- input voltage usilitel which serves as a magnetic applicator.

 

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