UA68728A - Device for controlling electrophysiological state of acupuncture points - Google Patents

Abstract

The device for controlling the electrophysiological state of acupuncture points comprises additional elements and their interconnections providing for improving the parameters of the electrophysiological state of acupuncture points in terms of the noise voltage generated by the body. Such a design eliminates the negative effects of the electric current on the body providing for extending the functional potential of the device.

Description

Description of the invention

The invention relates to medical technology and can be used to assess the electrophysiological state of 2 acupuncture points by their electrical resistance and temperature for the purpose of diagnosis and therapy.

Methods based on the measurement of electrical resistance of the skin and temperature at acupuncture points (TA) are widely used in acupuncture diagnostics. Since the temperature of the skin reflects the state of the parasympathetic part of the autonomic nervous system, and the electrical resistance - the sympathetic, the joint measurement of these parameters is more informative for diagnosis and correct interpretation of the results. 70 The measurement of the electrical resistance of the TA and individual areas of the skin is carried out using direct current devices with a voltage source of units and even tens of volts (according to the Voll method - 1.2-28, Nakatani method - up to 128) with currents in the units of tens of microamperes . According to the indicators of the microammeter, which measures the current of the electrode applied to the tested TA, the value of the electrical resistance is judged. It is known that living tissue consists of cells surrounded by an intercellular medium. At the same time, each cell is surrounded by 12 membranes. The equivalent scheme of TA can be presented in the form of parallel connected active resistance (intercellular liquid medium) and reactive (membrane structures and intracellular medium) due to cellular conductivity. The direct current signal used in measuring the electrical resistance of the skin flows only through the extracellular medium, because the cell membrane is an insulator in relation to direct current | see A.N. Remizov Medical and biological physics. - M.: Vyissaya Shkola, 20 1999, - P. 332-334). In addition, passing direct current through living tissue causes the phenomenon of polarization in the tissue, which introduces an additional error into the measurement result.

The measurement of the TA temperature is carried out by measuring the resistance of the thermistor, which is brought into thermal contact with

AND. First, the temperature is measured, and then the current is measured to determine the electrical resistance of the skin at the same points (according to the method of Nechushkin, Haydamakina - power source voltage 1.5-3V, short-circuit current - 20μA, 25 temperature measurement range - from 22 to 3722). The temperature is measured by electric thermometers, for example the TPEM-1 thermometer with a point thermistor sensor.

A well-known device for monitoring the electrophysiological state of acupuncture points, containing twenty-four thermistor sensors for measuring the temperature of TAs located at these points | see A.M. Nechushkin, A.M.

Haydamakina. The standard method of determining the tone of the autonomic nervous system! in the norm and with pathologies 09 30 in the Journal of experimental and clinical medicine. - 1981. - Mo2). In addition, the specified device contains CM twenty-four active and one passive electrodes for measuring electrical resistance, a potentiometer, a commutator and a microammeter. -

The disadvantage of the device is the use of two electrode sensors for measuring TA parameters, as well as low accuracy and considerable time required to diagnose the condition of one patient.

Known device for monitoring the electrophysiological state of acupuncture points (US patent Mo5339827, class ii-oi

Ab1NZ39/02, 1994), which contains a probing electrode and a reference electrode, the conductive surface of which is 25 times larger than the area of the end of the probing electrode, to which a generator is connected that generates electrical signals with a high content of harmonic components. A converter of electrical resistance "K frequency" is connected to both electrodes, the output of which is connected to a computer, on the screen of which the resistance value is reproduced. At the same time, the Z 70 computer is equipped with a program for analyzing the received data. c The disadvantage of the device is the lack of elements to protect the body from the negative impact of electric current on TA, as well as the low probability of measurement results. The unstable position of the electrodes on the human skin reduces the probability of the obtained data, which increases the number of interferences and introduces significant subjective errors during measurements. Currently, the negative consequences of electropuncture effects on the human body are reliably recorded, see VA Zagryadskyi, V.P. Zlokazov, Metrology and electrical safety in electrical electrodiagnostics //

F Izvestiya of the Taganrog Radiotechnical University. - Taganrog Ministry of the Interior of TRTU, 1998. - P. 68-71). (o) Studies have shown that the testing signal during electropuncture effects acts on TA, their corresponding tissues, internal organs, as well as the whole organism. - A well-known device for monitoring the electrophysiological state of acupuncture points | see Makats V.G. Basis of 250 acupuncture biodiagnostics - Vinnytsia, 1991. - pp. 73-78), containing one positive and twenty-four measuring electrodes connected in series, an input switch, a filter, an amplifier, an analog-to-digital converter (ADC), the output of which connected to the input of a personal computer.

This device is designed to compare the electrophysiological activity of twenty-four subjects

AND along the course of the twelve classical meridians to the right and left in relation to the umbilical region. It does not use an external current source, but measures the current generated by the biological object, which reduces to minimal harmful effect on the latter.

The disadvantage of this device is the low probability of measurement results when monitoring the state of the TA during diagnostics or their search, which reduces the accuracy of diagnostics. The reasons for the low probability of the obtained results are the weakness of the registered bioelectrical signal compared to noise during measurements. 60 A device for monitoring the electrophysiological state of acupuncture points is also known (RF patent Mo2123318, cl. AbЕ1НЗ9/00, 1998, bull. Mo35), which contains a block of thirty measuring electrodes and a block of four positive electrodes, two commutators, the inputs of one of them with connected to the measuring electrodes, the inputs of another commutator are connected to the positive electrodes, the analog-to-digital converter, the controller unit, the input is connected to the output of the analog-to-digital converter, and the personal computer, the input is connected to the output of the controller unit . In addition, the control device includes a measuring resistor, a filter,

the amplifier and the unit for the formation of measuring voltages, the switches of the sources of measuring voltages and groups, and the sources of measuring voltages are connected by a common wire, and the switches are connected to the mode control bus, and a measuring resistor is included between the common wire and the connection point of the switch of measuring currents and the filter.

Despite the good reliability of the obtained measurement results and the presence of some elements of electrical safety of patients, the known device for monitoring the electrophysical condition of the TA does not provide reliable protection of the body against the harmful effects of electric current passing through the TA. A decrease in the level of probing signals leads to a decrease in sensitivity to changes in the measured signal and loss of information about the 7/0 state of the TA due to the increasing influence of noise and interference. In addition, the known device does not provide information about the temperature of the tested TAs.

The invention is based on the task of creating such a device for monitoring the electrophysiological state of acupuncture points, in which the introduction of new elements and their connections would ensure an increase in the accuracy of measuring the parameters of the electrophysiological state AND by the value of the noise voltage generated by the organism itself, which would eliminate the negative influence electric current on the body and will expand the functionality of the device.

The task is solved by the fact that the device for monitoring the electrophysiological state of acupuncture points, which contains a block of thirty measuring electrodes and a block of four positive electrodes, two switches, the inputs of one of them are connected to the measuring electrodes, the inputs of the other switch are connected to 2o positive electrodes, an analog-to-digital converter, a controller unit, the input is connected to the output of the analog-to-digital converter, and a personal computer, the input is connected to the output of the controller unit, according to the invention, additionally contains two automatic switches, a voltage repeater, two differential voltage splitters, a rectangular alternating signal generator, an adder, a bandpass amplifier, a quadratic detector, a low-pass filter, an operational amplifier with a negative feedback circuit, an alternating voltage amplifier and a decoupling capacitor through which the output of the commutator of the measuring electrodes is connected to inputs of the voltage repeater and the first differential ial "voltage splitter, the outputs of which are connected to the inputs of the first automatic switch, the output of which is connected to one input of the adder, the other input of which is connected to the output of the voltage repeater, a band amplifier, a quadratic detector are connected in series to the output of the adder , a low-pass filter, an operational amplifier with a negative feedback circuit, an alternating voltage amplifier and a second differential voltage divider, the outputs of which are connected to the inputs of the second automatic switch, the output of which is connected to the input of the analog-to-digital converter, and the control input of the second automatic switch is connected to the control input of the first automatic switch and is connected to the output of the generator of a rectangular alternating sign signal, the input of which is connected to the frequency output of the controller block, the first digital output of which is connected to the control input of the switch of measuring electrodes , the second digital output is connected to the control input of the switch p positive electrodes, the output of which is connected to the common grounded point of the device.

It is advisable in the device for monitoring the electrophysiological state of acupuncture points to perform the negative feedback circuit of the operational amplifier in the form of a series-connected positive electrode, "

A measuring electrode and a sample resistor included between the output of the operational amplifier and its (2-3 s inverse input, as well as a key connected in parallel with the sample resistor, while the control input of the key is connected to the logic output of the controller unit. ;" It is appropriate in a device for to control the electrophysiological state of acupuncture points, additionally introduce a large-capacity capacitor and a second key connecting the output of the measuring electrode switch to one of the electrodes of the large-capacity capacitor, the other electrode of which is connected to the common ground point b of the device, and the control input of the second key to connected to the second logical output of the controller block.

Introduction to the device for monitoring the electrophysiological state of acupuncture points of two automatic SO switches, a voltage repeater, two differential voltage splitters, an adder, a band-I amplifier, a quadrature detector, a low-pass filter, an operational amplifier with an exemplary 5p resistor and a key in the feedback circuit , an alternating voltage amplifier and a separation capacitor, as well as a second key and a large-capacity capacitor, included in the specified manner, allows to isolate the first signal proportional to the electrical resistance and temperature, and the second a signal proportional only to the temperature, from which, after computational processing in the controller processor, two results are obtained, one of which is proportional to the temperature, and the second only to the electrical resistance, regardless of the level of the inherent noise of the measuring circuit and the zero drift of its converting blocks, which will allow you to eliminate the pulsating effect of electric current on

P organism and expand the functionality of the control device by obtaining simultaneous information about the resistance and temperature of the tested TA.

The drawing shows the functional scheme of the device for monitoring the electrophysiological state of acupuncture points.

The device includes unit 1 of thirty measuring electrodes, unit 2 of four positive electrodes, input switches C and 4 electrodes, separation capacitor 5, voltage repeater 6, differential voltage splitter 7, automatic switch 8, adder 9, band amplifier 10, quadrature detector 11 , low-pass filter 12, key 13, sample resistor 14, operational amplifier 15, amplifier 16 of alternating voltage b5, second differential voltage splitter 17, second automatic switch 18, analog-to-digital converter (ADC) 19, controller unit 20, shaper of rectangular alternating sign signal

21, personal computer 22, capacitor 23 of large capacity, second key 24.

The inputs of block 1 of measuring electrodes I-XXX are connected to the inputs of switch 3, the outputs of block 2 of positive electrodes XXXI-XXXIM are connected to the outputs of switch 4, the output of which is connected to the common ground point of the device. The output of the switch C through the separation capacitor 5 is connected to the input of the voltage repeater 6 and the input of the differential splitter 7. The outputs of the differential splitter 7 are connected to the inputs of the automatic switch 8, the output of which is connected to one of the inputs of the adder 9, the other input of which is connected to the output of the voltage follower 6. A band-pass amplifier 10, a quadratic detector 11, a low-pass filter 12 and an operational amplifier 15 are connected in series to the output of the adder 9, in which a key 13 and a sample resistor are included in the feedback circuit 7/0 14. A differential splitter 17 is connected to the output of the operational amplifier 15 through the amplifier 16 of alternating voltage, the outputs of which are connected to the inputs of the automatic switch 18. The output of the automatic switch 18 is connected to the input of the ADC 19, the digital input of which is connected to the input of the controller unit 20. A rectangular alternating signal generator 21 is connected to the frequency output of the controller block 20, the output of which is connected to the controller by the inputs of automatic switches 8 and 18. The first and second digital outputs of the controller unit 20 are connected to the control inputs of the switches C and 4, the third digital output is connected to the input of the personal computer 22. The logical outputs of the controller unit 20 are connected to control inputs of keys 13 and 24. Capacitor 23 of large capacity is connected to the output of switch 3 through key 24 with its potential electrode.

The claimed device for monitoring the electrophysiological state of acupuncture points works according to the program embedded in the non-volatile memory device of the controller unit 20 under the control of commands coming from the personal computer 22. Before removing the signals from the electrodes fixed on the patient's body, the measuring part of the device is calibrated. The calibration result is processed in the controller 20, reported to the personal computer 22 and taken into account when processing the measurement results in the working mode.

The control device works as follows.

Twenty-four measuring electrodes from unit 1 are attached to the patient's body to control the twelve main meridians on the left and right, and six additional ones for the meridian of three cavities: thoracic, abdominal, and pelvic, and four positive electrodes from unit 2 on the patient's four limbs. In the operating mode, at the command from the computer 22, one of the thirty measuring electrodes (I-XXX) is connected with the help of the switch C, and with the help of the switch 4 - one of the four positive electrodes (XXXI-XXXIM). The included positive electrode is grounded, and the included measuring electrode is connected through the capacitor 5 to the inputs of the voltage repeater 6 and the differential voltage splitter 7.

With the help of the included measuring electrode from the point of acupuncture (TA), the noise electric M voltage arising in the heated electrophysiological environment, which has active physiological losses, is removed. In such an environment, thermal and electrical fluctuations necessarily exist, which is the source of thermal noise. In accordance with the Nyquist equation, the average value of the square of the noise voltage of the control unit has the form: "о пш-аКАгтвх о) where K-1.38710723 J/k is Boltzmann's constant;

A - frequency band in which the noise voltage is released; "

TU - absolute temperature TA on the Kelvin scale;

EC, - electrical resistance TA. If the noise voltage (1) is presented in the complex form I), then it is repeated at the output of the repetitive:z" of the voltage 6, performed on the operational amplifier, covered by a deep negative feedback id, sh- schi - At the output of the differential splitter 7 , performed on an operational amplifier with negative feedback on both inputs, two identical voltages with opposite signs are formed:

Ф 05 - Оу "(5 --oschoF) (ee) At the patient's temperature of 308-310K (35-37"C), the noise voltage from various TAs is at the same level as the own noises of the operational amplifiers. 7 Therefore, the output voltages of the voltage repeater 6 and the differential we will present the splitter 7 in the form of 20 complex total voltages: s (sh t Osh voshi, (3) 5 - Oshch nOuv that --ushch- that, 59 detsu - inherent noises of the voltage repeater 6;

R ОЦscho is the inherent noise of the differential voltage splitter 7.

Anti-phase voltages (p and 14) are received at the inputs of the automatic switch 8. With periodic connections, packets of noise voltages and (Kk) alternately pass through its output:

Od - Shsh in the eyes of her. 9 2E

Tsa - -Ш zocr.y-e "their 1 2E E 65 where E is the switching frequency of noise voltages.

The energy band of the spectrum of thermal fluctuations is within the range of Her frequencies from 10kHz to 200kHz at the indicated temperature of the patient's body. Therefore, the switching frequency is chosen less than the lower limit of the frequency band of thermal fluctuations (E«Tmim):

E-(0.5-7)Hz (5)

One input of the adder 9 continuously receives a voltage, while its other input receives alternating voltage packets (.

As a result of the summation of the noise voltages at the output of the adder 9, packets of complex voltages are formed: . . . . 6 is the basket Ov Ošche|osi ve" (5) . . . 1 1

KO - more) - 1, tyu V «Yush she) zr E de Ku - transfer coefficient of the adder 9.

Packages of total voltages (6) and (7) are alternately amplified by a bandpass amplifier 10, the bandwidth of which corresponds to the energy band of thermal fluctuations. Amplified voltages are squared in turn by the detector 11, which has a quadratic amplitude characteristic, and averaged by the filter 12 of the lower 79 frequencies: p. ---- : : 18) and -vi/kka zosh voshi OO ik nk : : : 2 1 1.08)

Tsvirni shi - Oshe zov) point 2E E de Ko - amplification factor of the band amplifier 10; 51 - the slope of the quadratic transformation of the amplitude detector 11;

Tsuv is the voltage of the inherent noise of the amplifier 10, brought to the input of the amplifier.

When evaluating the averaged values 1) and и, it is worth considering that the inherent noises of the converters 6, 7 and the bandpass amplifier 10 are not correlated with each other. Therefore, the average values of products of natural noises are equal to zero (Scia Le - 0 Oshi Otse - 0, Otse Otse -0). Similarly, the noise voltage TA is not correlated with the own noises of the units of the measuring circuit Io - 00 still - OO that Ov -o - Taking into account the properties of the voltages of correlated and uncorrelated noises, we obtain: со 3 potu тт 1:49 сч 0, - Viki ku (ОВ я Od, i Od i Odz oh yar cha - zrar2 it? t2 11 1.11) s - vikuka Oh z de z Ov yav hih so de SMy, Od, Kz - dispersion of noise signals. "at

When the key 13 is closed, the operational amplifier 15 works in the voltage repeater mode. Therefore, packages of averaged voltages (10) and (11) affect the input of the AC voltage amplifier 16 without additional scaling. From the temporal sequence of voltage packets CP, and Ts, the variable component of the averaged voltages is amplified by the amplifier 16: sl oo. M more sh s tso(d-k;- 5 vidpeipirya g ef) M, 9) :z» where ziapzipayaRi is the rectangular envelope of the temporal sequence of packets of averaged voltages;

F - envelope phase at the output of the detector;

Kz - gain coefficient of the 16 variable voltage amplifier;

Ge" M4(5) is the noise voltage in the passband of the amplifier 16.

The alternating voltage (12) is split into two equal opposite-phase voltages by the differential splitter 17, which in turn are fed through the automatic switch 18 to the input of the analog-to-digital converter 19 of the integrating type. Switches 8 and 18 work synchronously because they are controlled by the same voltage of low bor frequency (5). As a result of switching the input voltages of the splitter 17 with a frequency that is synchronous with the frequency of the change in the amplitude of this voltage, there is a rectification of the alternating voltage and a transformation of the noise spectrum that has passed:

Kk - ; (13) so What - o, -Щ)nmei) where M2(Ю)) is the noise voltage of the combinational frequencies near the zero value of the frequency.

The rectified voltage (13) is averaged by the ADC 19 of the integrating type and converted into a digital code p. p7jj-j y to 1 v» mr- 850 - 52. Sh- mitAiu 2 a de 4 - step of constant voltage quantization; in Z" - steepness of ADC conversion 19.

If the averaging time t in the ADC is much longer than the period of the variable voltage (122177), then the noise voltage of the combinational frequencies is close to zero (still) - Then, taking into account the values 1 and 1 from expressions (10) and (11), we obtain the value of the digital code: 22 2. da Me got used to Yuk Wa Sha (15)

If we substitute the value o with (1) into expression (15), we finally get the digital code mi-akAg8IKkikiKk.8ot,v, 9-8, 9) where v-v8kKAG VIKI with 82 Ch is the resulting sensitivity of a single-channel measuring circuit.

It can be seen from the obtained expression (16) that the Mi code is proportional to both the resistance K, TA, and its temperature T..

For the separate measurement of Ki Tu, the Mu code is entered into the memory of the computer 22. At the command of the computer, the key 13 is opened and a resistor 14 with a known resistance Ko is included in the negative feedback circuit of the operational amplifier 15. At the same time, in series with the exemplary resistor 14 with resistance Ko, resistance TA is included between the measuring electrode of block 1 and the positive electrode from block 2 with resistance Ku. The gain of the operational amplifier 15 becomes proportional to the ratio of these resistors, i.e. Ko / Ku. Taking this into account, the alternating voltage (12) takes the form sh0-bo OVT x

Taking into account the value of the square of the noise voltage (1), the digital code (16) takes the value of the variable x

Thus, the Mo code obtained is proportional only to the TA temperature.

The M" code is entered into the computer's memory 22. The computer processor calculates the value of resistance TA using the M. and Mo codes

M (19)

Kh--No

Mo and temperature value TA

Ma (20) «

you --

ZE

The accuracy of measuring K and Tu is largely determined by the synchronous operation of automatic switches 8 and 18.

This operation is provided by a single square-wave voltage of fixed frequency E acting on the control inputs of these 00 switches. To form a rectangular voltage, a rectangular alternating signal generator Щ 21 is used, which is connected to the output of the programmable timer of the controller unit 20. The frequency division coefficient is chosen in such a way as to ensure the fulfillment of condition (5). The rectangular shape of the output voltage of the shaper and - a rectangular alternating signal ensures fast switching of measuring signals and symmetrical operation of the switch. The value of the resistance and temperature of the tested TA is displayed on the computer display 22.

Next, at the command of the computer, with the help of switches 1 and 2, another pair of electrodes is switched and after (Ce) processing of noise signals, the resistance and temperature of the next TA is induced.

The principle of operation of the proposed device for monitoring the electrophysiological state of TA does not change depending on the choice of the sequence of polling points. The choice of TA and the order of inclusion of one of the measuring and positive electrodes is determined by the program recorded in the computer's non-volatile memory device. The program also provides for periodic calibration of the device's measuring circuit. t s Calibration is carried out by measuring the zero shift voltage of the ADC 19 when connecting the capacitor 23 h of large capacity using the key 24 to the output of the switch 1. Due to the large capacity (about 2-5 μF), thermal noise at the output of the measuring electrode is practically completely eliminated. Therefore, the zero shift of the ADC can occur only due to the presence of a correlated component of the inherent noise of the measuring circuit blocks.

The result of the calibration is remembered and taken into account when processing the results of measurements in the working mode. (22) The proposed calibration mode does not require short-circuiting the measuring electrode with the positive electrode. Therefore, calibration can be carried out after fixing the electrodes on the patient's body or even in the process of working measurements to exclude relatively fast changes of the zero shift. The absence of external probing voltage on the measuring electrodes ensures complete electrical safety of the patient. of 20 EPKK-2 brand electrodes manufactured by REMA (Lviv) in accordance with TUb2-1-3175-76 are used as measuring electrodes in the device, and electrocardiographic brand ME.443.101 electrodes are used as positive electrodes. The switches are made on the basis of microcircuits of the KBOOKNb and KObIKG3 type. K544UD2A integrated circuits are used for all operational amplifiers. The device uses a personal computer type

A computer connected via the K5-232 interface to the Ayteda103 controller! (Aiitei), the analog-to-digital converter connected to the input is based on operational amplifiers with double integration, and its input code does not depend on the instability of the time-setting elements. Simultaneous measurement of electrical resistance in the range from 30 to 250 kΩ and temperature TA (normally 28-29"С, asymmetry does not exceed 0.47С) allows to increase the reliability of diagnostic information by detecting and registering the temperature and electrical asymmetry of the acupuncture points of the patient's body. The possibility of establishing a correlation between thermal and 60 electrical states, TA increases the accuracy of diagnosis of a number of diseases that occur in a hidden form and the absence of obvious symptoms. simultaneous measurement of resistance and temperature AND with the help of standard medical electrodes. b5

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Claims (2)

The formula of the invention (ee) What What And And And 1. A device for monitoring the electrophysiological state of acupuncture points, containing a block of thirty and measuring electrodes and a block of four positive electrodes, two switches, the inputs of one of them are connected to 50 with the measuring electrodes, the inputs of the other switch are connected to the positive electrodes , an analog-to-digital converter, a controller unit, the input is connected to the output of the analog-to-digital converter, and a personal computer, the input is connected to the output of the controller unit, which is distinguished by the fact that it additionally contains two automatic switches, a voltage repeater, two differential voltage splitters, a rectangular alternating signal generator, an adder, a bandpass amplifier, a 5o quadrature detector, a low-pass filter, an operational amplifier with a negative feedback circuit, an alternating voltage amplifier and a decoupling capacitor through which the output of the commutator of the measuring electrodes is connected with the inputs of the voltage follower and the first differential splitter voltage, the outputs of which are connected to the inputs of the first automatic switch, the output of which is connected to one input of the adder, the other input of which is connected to the output of the voltage follower, 60 series-connected band amplifiers, quadratic detectors are connected to the output of the adder a low-pass filter, an operational amplifier with a negative feedback circuit, an alternating voltage amplifier and a second differential voltage divider, the outputs of which are connected to the inputs of a second automatic switch, the output of which is connected to the input of an analog-to-digital converter, and the control input of the second of the automatic switch is connected to the control input of the first automatic switch and is connected to the output of the generator of the square wave signal, the input of which is connected to the frequency output of the controller block, the first digital output of which is connected to the control input of the commutator of the measuring electrodes, the second digital output of connected to the control input of the switch of positive electrodes, the output of which connected to the common earth point of the device. 2. The device according to claim 1, which is characterized by the fact that the negative feedback circuit of the operational amplifier is made in the form of a series-connected positive electrode, a measuring electrode and a sample resistor included between the output of the operational amplifier and its inverse input, as well as a key, included in parallel with the sample resistor, while the control input of the key is connected to the logic output of the controller block. C. The device according to claims 1 and 2, which is distinguished by the fact that a large-capacity capacitor and 70 second key are additionally introduced into it, which connects the output of the switch of the measuring electrodes with one of the electrodes of the large-capacity capacitor, the other electrode of which is connected to the common grounded point of the system, and the control input of the second key is connected to the second logical output of the controller unit. Official bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated 7/5 microcircuits", 2004, M 8, 15.08.2004. State Department of Intellectual Property of the Ministry of Education and Science of Ukraine. « (ee) with (ee) (Se) - and? (o) (ee) -i ime) IR e) 60 b5