SU1275299A1 - Optoelectronic dial indicator - Google Patents

Abstract

The invention can be used to measure and visually monitor electrical quantities. The purpose of the invention — extending the functionality — is achieved by ensuring that the maximum value of the measured value is fixed for a given Ofei time interval, and the quality of the display is improved by indicating the current and maximum values of the input value in different colors. To do this, a second counting trigger 4, an optical signal to electric signal converter 5, a setter of 6 time intervals, logic gates 9 and 10, control 11 and trigger 13 LEDs (LEDs), resistors 16 and 17, and each cell are entered into the device. the light-emitting scale is equipped with the second indication LEDs 19.1-19.P and the third photo thyristor 24.1-24оП. The device also holds the amplitude-time converter I, a generator of 2 pulses, (L C first trigger 3, elements AND 7 and 8, triggering LED 12, power bus 14, resistor 15, first indicating LEDs 18-1-18.p. The communication LEDs are 20-1-20op and 21.1-21.p, photothyristors 21.1-22.p llS and 23 "1-23.p, current-supplying resistors 25-28. 1 ill.

Description

This invention relates to electrical measuring equipment for measuring and visually monitoring electrical quantities. The purpose of the invention is to expand the functionality by ensuring that the maximum value of the measured value is fixed for a given time interval, as well as the quality of the display is improved by, for example, displaying the current and maximum values of the input value in different colors. The drawing shows the functional diagram of the device. The device contains an amplitude-time converter 1, a pulse generator, the first 3 and second 4 counting triggers, an optical signal-to-electric converter 5, an adjusting device 6 time intervals, first 7, second 8, third 9 and fourth 10 NAND logic gates, control LED 11, first 12 and second 13 triggering LEDs, power bus 14, first. 15, the second 16 and third 17 resistors, the first and second 19, 19 indicator LEDs, the first connections and the second communication diodes, the first 22, 22, the second and third 24, -24 photo thyristors, the first 25, the second 26, the third 27 and fourth 28 current supplying resistors. The input of the amplitude-time converter 1 is connected to the bus, and the output is connected to the installation of installation 1 of trigger 3 and the first input of the first 7 and second 8 AND-NES elements, which are connected to the cathode of the first triggering LED 12. The anode of the first triggering LED 12 is connected to The first pin of the resistor 15, the second pin of which is connected to the power supply bus 14; The direct output of the trigger 3 is connected to the second input of the first AND-HE unit 7, and the inverse output to the second input of the second AND-HE unit 8. The output of the pulse generator 2 is connected with the counting input of the first the trigger 3, with the input of the setpoint generator 6 time intervals and with the first output of the resistor 17, the second output of which is connected to the anode of the control LED 11, the optical output of which is optically connected to the optical input of the optical signal to optical converter 5, the output of which is connected to the trigger input of the trigger 4. The output of the setpoint generator of time intervals 6 is connected to the first number 1 and the inputs of the third 9 and fourth 10 NAND elements and to the installation input 1 of the second trigger 4, as well as to the cathode of the second triggering LED 13, the anode of which Erez resistor 16 is connected to a power bus 14. The direct output of the trigger 4 is connected to the second input of the element AND-HE 9, the inverse output to the second input of the element AND-NOT 10. Indicator LEDs 18 and 19, LEDs 20 and 21, photothyristors 22-24 form pits, each of which contains consistently connected iDiconation LEDs 1B, LEDs 20, and photo thyristors 22, according to the serially connected indicator LED .19, LED 21 and phototiristor 24, and phototiristor 23, the cathode of which is connected to the junction of the LED 20 and phototiristor 22, with the anodes ino , ciccation LEDs 18 and 19 are combined. The anodes of all indicator LEDs J and are connected to the power bus 14. LED indications 18 j-18 | and 9. have different colors of luminescence - llB LEDs, -18 have red color of luminescence, and LEDs 19., - 19 - green. The anodes of all photothyristors 23j-23 are connected to the cathode of control LED 11. The optical output of the first triggering LED 12 is optically connected to the optical input of the photothyristor 24 of the first cell, and the optical output of the second triggering LED 13 is optically connected to the optical input of the photothyristor 22. of the first cell Photocathodes of the photothyristor 22 the odd cells are connected via a resistor 27 with the output of the third NAND element, and the cathodes of the photo thyristors 22 even cells with the output of the fourth element NAND through the resistor 28. The cathodes of the photo thyristors 24 odd cells are connected via a resistor 25 with the output of the first element NAND 7, and photothyristor cathodes 24 partial cells through a resistor 26 to the output of the second element NAND 8. The optical output of the LED 21 - each i-th cell is optically connected to the optical input of the photothyristor 23j of the same cell and the optical input of the photothyristor 24 -,., the next () -th cell. The optical output of the LED 20. of each i-th cell is optically connected to the optocator. Input of the photo thyristor 22 / of the next (1 + 1) -th cell. Indicator LEDs and 19 19 form a linear digitized scale, and the LEDs and 19. designate a common optical aperture. The device works as follows. In the absence of an input signal at the input of the amplitude-time converter 1, there is zero voltage at its output, which is fed to the cathode of the firing LED 12 and to the first inputs of the AND-NE elements 7 and 8. As a result, the LED 12 is in an excited state, and At the outputs of the elements NE-7 and 8, there is a high voltage corresponding to a logical unit that goes to the cathodes of the photothyristors 24, -24 "and does not allow them to open. So the indicator LED 19 and the LED 2 C cannot light up, although the photothyristor 24. ,, to which they are connected, the radiation of the triggering diode 12 comes. At the output of the setter of 6 time intervals before the measurement starts, there is a zero voltage, which maintains a logical 1 voltage at the outputs of the AND-HE elements 9 and 10 which prevents the current from passing through the photothyristors 22-22, which are in the locked state. The firing LED 13 at the same time radiates, since a zero voltage is present at its cathode. Its radiation enters the optical input of the photothyristor 22 and prepares it for operation. If the measurement process has begun, then at the moment of the beginning of the specified time interval for fixing the maximum of the input value, the setting device 6 switches, and the output voltage appears logical I At this, the LED 13 goes out, the forward output of the trigger 4 appears (since its input voltage of installation 1 receives a positive voltage drop from the output of setpoint 6. A voltage of logic 1 is applied to both inputs of the NAND 9 element, as a result of which a zero voltage appears at its output, resulting in a photothyristor 22since it was previously prepared to be triggered by the starting LED 13, current is flowing through the LEDs 18 and 20. If the input signal is not present at the input of the converter 1, this state of the device is maintained for the entire specified time. the time interval for fixing the maximum of the input value; i.e., only the LEDs 18 and 20 are hot. If the input signal to the converter 1 is input, it is converted into a sequence of pulses, the period of which is constant, and for pulse duration proportional to the value of the input variable. These pulses are fed to the input of the installation 1 of the trigger 3 and to the first inputs of the elements NE-NE 7 and 8. When a pulse arrives from the output of the converter 1, the forward output of the trigger 3 establishes a voltage of logic 1, and an inverse voltage - a zero voltage that triggers the LED 12 goes out, the zero voltage is set at the output of the NAND 7, and the logical voltage of the output of the NAND 8 element is set as a consequence of this. The phototransformer 24; |, which was previously prepared for release by the emitting LED 12, opens through the LEDs 19 and 2T ne The ditch cells begin to flow and they become energized. The radiation of the LED 21., is supplied to the optical inputs of the photo thyristors 23 and 24 ". Phototi-. The resistor 24, j is thus prepared for operation, but cannot open, since the voltage from the logical 1 is applied to its cathode from the output of the AND-HE element 8. The switching of the trigger 3 is controlled by the pulses of the generator 2 fed to its counting input. The pulse period of generator 2 is equal to T, so that antiphase sequences of rectangular pulses are formed at its outputs, the period of which is 2T, and the duration T. If there is a pulse at the first inputs of the AND-NE elements 7 and 8, the pulses from the outputs of trigger 3 are allowed to pass the outputs of these elements, so that the cathodes of the photothyristors 24 of odd and even cells alternately receive pulses of a high level duration

T equal to the pulse period of generator 2. During the first clock cycle of duration T, zero voltage is applied to the photothyristors 24 odd-cell cathodes, and the first cell LEDs 19 and 21 light up and the light signal from the optical output of the LED 21 goes to. the photothyristor 23a of the first cell and the photothyristor 24 of the second cell, which are thereby prepared for operation. However, before the end of the first clock cycle, the photothyristor 24 of the second cell cannot operate, since the logical voltage 1 from the output of the YNE element 8 is applied to its cathode. When the next pulse arrives from the generator 2 output, the counting input of the trigger 3 is switched to its forward output is the zero voltage, and on the inverse the voltage is logical 1, as a result, the output of the element AND-NE 7 appears voltage of logical 1 and the output of the second element AND-NOT 8 is zero voltage

Now the cathode of the photocell of the second cell 24 is under zero voltage, and the cathode of the photo thyristor 24 of the first cell is under voltage logical 1. This leads to the fact that the LEDs 19 and 2C go out, and the photothyristor 24 of the second cell that is prepared for operation in the previous clock cycle, the LED 2C opens, causing the second cell LEDs to light up, the radiation from LED 21, j, goes to the second cell photo thyristor 23 and the third 24 photo thyristor, which will work in the next cycle Photo-thyristors 24 flashing, LEDs 21 and indicator LEDs, 19 seconds, continue until the end of the pulse at the amplitude-time converter 1 o At the time this pulse ends, the outputs of the AND-HE elements 7 and 8 cause a logical voltage, so that LEDs 19 and 21 all the cells go out, the photodotas 24 of all the cells close, and the first triggering LED 12 lights up. At the output of the zero voltage converter 1, prepare the photothyristor 24. the first cell is triggered at the beginning of the next measurement and indication cycle, which starts at the moment after the output of the converter 1 of the next pulse. The process of triggering the LEDs 19, the LEDs 21 and the photothyristors 24 cells is synchronized by the generator 2 pulses. During each cycle, the duration of which is equal to the duration of the pulse generator 2, one and only one cell starts, and the next cell starts to operate only at the end of the previous one. tact and the beginning of the next. Therefore, the number m of triggered cells and the number of illuminated LEDs of LEDs 19 equal to it are determined by the duration t И5 "pulse at the output of the amplitude-time converter I and the duration of the cycle

tv

m,

(one)

where m is the number of triggered cells, equal to the number of illuminated indicator LEDs 19; tj is the pulse duration at the converter output; T - the duration of the Fact, is equal to the period of following kmpulses of the generator 2,

The duration t of the output pulse of the amplitude-time converter is proportional to the magnitude of the input signal

(2)

x bh

where k is the proportionality coefficient; 8p „- the value of the input signal.

Thus, the length of the light portion of the indicator scale, determined by the number of LEDs 19, is proportional to the value of the input signal i

In order for the scale to be perceived in the form of a continuously light band, the period T of the pulse of the amplitude-time converter 1 up to be such that the inertia of the vision appears, which is provided by the relation

(3)

T 20 ms.

The duration of the time interval during which the maximum value of the input quantity is fixed. it is set by means of a generator of 2 pulses and a setpoint generator of 6 time intervals. As the latter, a frequency divider with a variable division factor is used, which generates a sequence of pulses from the generator 2 pulses, the duration of which is equal to the duration of the specified time interval, and the duration of the pause between them is equal to the generator 2 pulse duration. The start-up LED 3 is on, the radiation of which is preparing the photo thyristor 22 of the first cell to be activated, and the outputs of the elements AND-HE 9 and 10 are present matic 1 ,. preventing the opening of the photothyristor 22 of the first cell and the excitation of the LEDs 18 and 2P. When the logic voltage 1 appears at the output of the setting device 6, the firing LED 13 goes out, the logical voltage M appears at the forward output of the trigger 4, and zero at the inverse , a zero voltage appears at the output of the NAND 9 element, and a logical voltage at the output of the AND-flE 10 element. At that, the LED 13 goes out, and the photo thyristor 22, which is prepared for its operation, opens, and the LEDs 18 and 20 excited by the onset of a pulse and the output of the converter 1 starts srabatshanie fototiristo15ov 24 and LEDs 21 and 19 cells. When the first cell is triggered, the radiation of the LED 21 is fed to the photo thyristor 23 and prepares it for triggering. Since the output of the NANDI element 9 is at that time, the left voltage is present and the photo thyristor 22 is already open, when a pulse appears at the output of the generator 2, the photo thyristor 23 opens, from the output of the generator 2, through a resistor 17, the control LED 11, the photo thyristors 23 and 22 a current flows, as a result of which the control LED 11 is energized and gives a light pulse to the optical input of the optical signal converter 5 electric, about which output to the counting input of the trigger 4 receives an electric pulse under the action of which Trigger switch 4 is off, a logical voltage 1 appears at the output of element 29998 at the output of the AND-HE element 9, and zero output, at the output of the AND-HE element 10, Trigger 3 and 4 are switched by one and the same pulse generator 2, so that in each clock cycle one cell is triggered, and first the photo thyristor 24 and the LEDs 19 and 2i of the cell work first, and then the photo thyristors 23 and 22 and the LEDs 18 and 20 of this cell. Thus, in the next cycle as a result , which is described above, the photo-thyristor 24 and the LEDs 21 and 1 are triggered 9 of the second cell, the photo-thyristor 23 receives radiation from the LED 21 ", and the cathode of the photo-thyristor 22-. A zero voltage is applied to the Photo Thyristor 22, as it is illuminated by emitting the LED 20, the Photo Thyristor 23 is opened by the radiation of the LED 21. The LEDs 18 and 20 are energized, if a pulse is present at the generator 2 output, the current flows through the resistor 17, 1 I LED and photo thyristors 23 ,, and 222 to the output of the NE-10 element, due to all of which LED 11 produces a light pulse, causing a trigger switching 4 "Thus, if the output of the amplitude-time converter 1 of the first and The pulse is triggered by the cells, consisting in that in each clock cycle the photo thyristor 24 and the LEDs 19 and 21 are triggered first, and then the photo thyristor 23, the photo thyristor 22, and the LEDs 18 and 20 o. And this process is synchronized by the generator 2 pulses. 1 is terminated, then the outputs of the AND-HE elements 7 and 8 are set to a voltage of logical 1, since zero voltage is applied to the first inputs. As a result, all phototransistors 24 close, all LEDs 19 and 2 go out, and the firing LED 12 lights up, preparing the photo thyristor 24 to trigger by its radiation. At this time, the output of the setting device 6 has a voltage of logical 1, and the start-up LED 13 does not light up. Since the LEDs 21 of all cells go out, the photo thyristors 23 of all cells during the pause between generator 9 2 pulses in the absence of radiation from the LEDs 21 are closed, the current through the LED 1I does not leak and does not send light pulses to the input of the optical signal to electric converter 5, therefore trigger A saves the state it is switched to in the last clock cycle. At the same time, at the output of one of the AND-HE elements 9 or 10 there is a zero voltage, and at the output of the other - a logical one voltage, and the cathode of the photo thyristor 22. the last triggered cell is connected to the output of the INE element, on which there is a zero voltage, so that the photothyristor 22 remains open, and the LEDs 18 and 20 of this cell remain energized. However, the photothyristors of the 22 previous cells flash in cycles, preceding the last, and therefore emit only the LEDs 18 and 20 of the last triggered cell. The LED 18 of this cell indicates the stored maximum value of the input is not the value, and the LED 20 illuminates the photo thyristor 22 of the next cell. If the value of the input value now exceeds the maximum value stored by the indicator, the pulse width of the converter 1 increases and becomes greater than the maximum duration of the previous pulses of the measurement cycle whose duration is equal to the duration of a given time interval. In this case, the sequential process already indicated proceeds. The photo thyristors 24 and the LEDs 19 and 21 cells preceding the cell that stores the previous maximum value are triggered. At the same time, the photo thyristors 22 and 23 of these cells remain closed and only the LEDs 21 and the LED LEDs 199 do not control and the LEDs do not turn on and the three LEDs turn on and the LEDs 199 and the LED LEDs 199 do not energize and the three LEDs turn on and the LEDs three are illuminated and the LEDs 199 and the LED LEDs 199 do not turn on and the three LEDs turn on and the three LEDs turn on and the LEDs 199 and the LED LEDs 199 do not energize and the three LEDs do not turn on and the three LEDs turn on, the LEDs 21 and the LED LEDs 199, the control LED 11 do not turn on, and the three LEDs light up and the LEDs 199 and the LED LEDs 199 do not turn on and the three LEDs turn on and the three LEDs turn on, and the LEDs 199 and the LED LEDs 199 do not turn on and the three LEDs turn on. switches. When the process of photo-thyristors 24 and LEDs 9 and 21 has reached the cell, indicating the stored maximum value of the input value, the photo thyristor 22 of which is open, and the LEDs 21 and 19 of this cell are energized, the radiation of the diode 21 enters the photo-thyristor 23 of this cell and upon receipt of a pulse from this generator 2 photothyristor 99. O is expelled. At the same time, a current flows through the LED 11, it is excited, its light signal enters the optical signal to electric converter converter 5, and the output signal of the converter 5 switches the trigger 4. As a result, the next cell starts to operate: the cathode of its photothyristor 24, which is prepared for operation by emitting the LED 21 of the previous cell, a zero voltage arrives and it opens, which leads to the excitation of the diodes 19 and 21 by the photo thyristor 22 of this cell, prepared for triggering radiation The photothyristor, 22 opens, which leads to the excitation of the LEDs 20 and 18 of this cell, the photothyristor 23 is prepared to be triggered by the radiation of the LED 21 of the same cell, upon receipt of the next generator pulse 2, it is triggered by light; iodine 1 1 a current flows, it is energized and gives a light pulse, as a result, trigger 4 is switched. Next comes the described process of sequential cell clearing, which ends at the end of the amplitude-time pulse 1 ate the fact that some cell indicates the new value of Maxi. input signal maximum indication of the input signal is performed for the entire time while the output of the time interval 6 setpoint generator has a logic 1 voltage. The device is reset to its initial state by applying a zero voltage pulse to the first inputs of the AND-HE elements 9 and 10. wives At the same time, the outputs of the AND-HE elements 9 and 10 are set to single-level voltages, as a result of which the LEDs 18 and 20 of all cells go out, the photocrystals 22 and 23 close, and the firing LED 13 lights up. Indication LEDs 18 and 19 have different colors of the glow G, LEDs 18 are red, and LEDs 19 are green. Since the LEDs 18 and 19 of each cell have a common output optical aperture, the color of the cabinet depends on the mode of operation. At the time when both indicators come on. 18 and 19 cells. the scale turns yellow (as red and green colors decrease, wht occurs during the first pulse of the amplitude-time converter and when the input signal exceeds the previous maximum value). The stored maximum value of the input signal is indicated by the diode 18 of the corresponding cell as a red dot on the scale. The input value less than the stored maximum-value is indicated by green LEDs 19, a color in the form of a luminous green band whose length is proportional to the value of the input value. Suppose now that a pulse arrives from the output of the amplitude-time converter 1, the duration of which is less than the duration of the previous one (due to a decrease in the input signal). Then, starting from the moment this pulse arrives, the described process of sequential operation of the photo thyristors 24 and the LEDs 21 and 19 of the cells occurs. However, due to the fact that the output of the setting device 6 has a voltage of logic 1, the triggering LED 13 does not izgchchaet. Since the LED 13 does not refresh; the photo thyristor 22, this photo thyristor remains closed. At all cycles, which prevents excitation of the blue diodes 20, and 18 of the first cell. Since the photo thyristor 22 remains closed and the photo thyristors 2 close in the preceding cycles, LED 11 does not flow and it does not emit. Therefore, the trigger input does not receive pulses from the output-converter 5 of the optical signal, this trigger does not switch and stores the state it switches to when the maximum value of the input value is displayed during the preceding pulse. Thus, only the photothyristor 22 of the cell, which corresponds to the last memorized value of the input quantity, remains open, since its cathode constantly receives a zero voltage from the output of the AND-HE element 9 or 10. Since the LEDs 18 and 20. being excited, the photo thyristors 22 and 23 will not be able to open and the LEDs 18 and 20 of the subsequent cells will be energized. Thus, in 29912 in this case, the indicator LEDs 19, the number of which is proportional to the value of the input quantity, turn on, and the LED 18 of one cell lights, the number of which is proportional to the memorized maximum value of the input quantity. Resistors 15-17 set the currents through the corresponding LEDs, and resistors 25-28 stabilize the currents through the cells in the process of their operation and eliminate the influence of the variation of the parameters of the elements on the value of the currents of the cells. If the parameters of the cell elements are identical, resistors 25–28 may be missing. Formulas of the invention: An optoelectronic dial indicator containing an amplitude-time converter, whose input is an indicator input, a pulse generator, a first counting trigger, the unit setting input of which is connected to an output of an amplitude-time converter, and a counting input with a pulse generator output, the first and second elements of AND-NOT, the first inputs of which are connected to the amplitude-time converter, also connected to the cathode of the first triggering LED, the anode of which through the first p A resistor is connected to the power bus, the second inputs of the NAND elements are connected respectively to the direct and inverse outputs of the first counting trigger, a light-emitting scale containing the cells, each of which includes a first LED indicator connected in series with one another and the first photo-thyristor, as well as the second photo-thyristor and the second communication LED, the first communication LED of each cell is optically coupled to the first photo-thyristor of the next cell, which differs in that opportunities by providing a fixation of the maximum value of the measured value, as well as improving the quality of the display, a time interval adjuster, an optical signal to electric converter, a second counting trigger, a third and a fourth elements of the EI, a control LED, a second triggering LED, and a second and the third resistors, and each cell of the light-emitting scale is equipped with a second indication LED and a third photo thyristor; the time interval master input is connected to the output of the gene pulse generator, the anode of the second triggering LED through the second resistor is connected to the power bus, the unit setup input of the second counting trigger is connected to the cathode of the second triggering LED, and the counting input is connected to the output of the optical signal to electric converter, the first inputs of the third and fourth elements AND-NOT are connected to the cathode of the second triggering LED and with the output of the time interval setting unit, the anode of the control LED through the third resistor is connected to the output of the pulse generator, in each In the light emitting diodes, the second indication LED, the second communication LED and the third photo thyristor are connected according to and in series, the anodes of all of the indicator LEDs are connected to the power bus, the cathode of the second photo thyristor of each cell is connected to the anode of the first photo thyristor of this cell, the anodes of the second photo thyristors of all cells are combined with the cathode of the control LED, the optical output of which is optically connected to the optical input of the optical signal to electric converter, the cathode The other phototransistors of the odd cells are connected to the output of the first NAND element, and the cathodes of the third photothyristors of even cells are connected to the output of the second AND element, the cathodes of the first photothyristors of the odd cells are connected to the output of the third INE element, and the cathodes of the first photothyristors of even cells, with the output the fourth element is NOT. the optical output of the first triggering LED is optically coupled to the optical input of the third photothyristor of the first cell; the optical output of the second triggering LED is optically connected with the optical input of the first photothyristor of the first cell; in each cell, the optical output of the second communication LED is optically coupled to the optical inputs of the second photothyristor of this cell and the third photothyristor of the next cell, with the first indicator LED of each cell having a red glow, and the second one - green, first and second m-indicator LEDs of each cell have a common optical output. which is the cell exit.

Claims (1)

Formula of the invention ^{20 An} optoelectronic scale indicator containing an amplitude-time converter, the input of which is an indicator input, a pulse generator, a first counting trigger, the unit setting input of which is connected to the output of a time-amplitude converter, and a counting input with an output of a pulse generator, the first and second elements NAND, first 30 inputs of which are connected to the output of the amplitude-time converter, also connected to the cathode of the first triggering LED, the anode of which is connected 55 to the power bus through the first resistor, the second inputs of the NAND elements are connected respectively to the direct and inverse outputs of the first counting trigger, a light-emitting scale, containing η cells, 10, each of which includes, in series, the first indicator LED, the first communication LED and the first photo thyristor, as well as the second photo thyristor 45 and a second communication LED, the first communication LED of each cell is optically connected to the first photothyristor of the next cell, characterized in that, in order to expand the functional capabilities by ensuring the fixing of the maximum value of the measured value, as well as improving the quality of the indication, a time interval adjuster is introduced into it , 55 optical to electrical signal converter, second counting trigger, third and fourth INE elements, control LED, second triggering LED, second and third res ora, and each cell of the light-emitting scale is equipped with a second indicator LED and a third photo-thyristor, the input of the time interval master is connected to the output of the pulse generator, the anode of the second triggering LED is connected to the power bus through the second resistor, the installation input of the unit of the second counting trigger is connected to the cathode of the second triggering LED, and the counting input - with the output of the optical signal to electric converter, the first inputs of the third and fourth elements are NOT connected to the cathode of the second of the dimming LED and with the output of the time interval setter, the anode of the control LED is connected through the third resistor to the output of the pulse generator, in each cell of the light emitting scale there is a second LED, a second communication LED and a third photo thyristor connected in series with each other, and the anodes of all the LEDs are connected to the power bus, the cathode of the second photothyristor of each cell is connected to the anode of the first photothyristor of this cell, the anodes of the second photothyristor of all cells are combined and connected s with the cathode of the control LED, the optical output of which is optically connected to the optical input of the optical signal to electric converter, the cathodes of the third third third odd-cell photothyristors' are connected to the output of the first NAND element, and the cathodes of the third even-phototyristor cells are connected to the output of the second NAND element , the cathodes of the first 10 odd-cell photo thyristors are connected to the output of the third INE element, and the cathodes of the first even-cell photothyristors are connected to the output of the fourth AND-NOT element. the optical output of the first triggering LED is optically coupled to the optical input of the third photothyristor of the first cell, the optical output of the second triggering LED is optically connected to the optical input of the first photothyristor 'of the first cell, in each cell the optical output of the second communication LED is optically connected to the optical inputs of the second photothyristor of this ²⁵ and third cell fototiristory next cell, wherein the first LED Indication each cell has a red color luminescence, and the second - green, with it first and vto30 swarm-indicator LEDs of each cell have a common optical output. · which is the output of the cell.