SU1591069A1

SU1591069A1 - Indicating device

Info

Publication number: SU1591069A1
Application number: SU884409621A
Authority: SU
Inventors: Vladimir P Kozhemyako; Vladimir A Podorozhnyuk; Stepan N Belan; Dmitrij D Sobolev; Yurij L Zuev
Original assignee: Vinnitsky Politekhn Inst
Priority date: 1988-04-12
Filing date: 1988-04-12
Publication date: 1990-09-07

Description

The invention relates to automation and instrumentation and can be used in measuring systems for state display

remotely remote sensors in conditions of high noise levels -.

The purpose of the invention is to increase the reliability of the device. The device contains a pulse generator 1, the first counter 2, the display unit 3, optoelectronic converters 4 and 5, single vibrators 6 and 7, keys 8 on photoresistors, limiting element 9 on a resistor, light emitter 10, the second counter 11. The purpose of the invention is achieved by transmitting information optical signals and automatic synchronization of the counters 2 and 11 in each cycle of receiving and displaying information ”3 Il.

FIG. one

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The invention relates to automation and instrumentation and can be used in measurement and control systems for displaying the state of remotely located sensors in conditions of increased level of interference.

The purpose of the invention is to increase the reliability of the device.

Fig, 1 shows a functional, θ diagram of the device; figure 2 - functional diagram of the first and second counters; FIG. 3 is a functional block diagram of the display unit.

The device (Fig. 1) contains 1 5 pulse generators, the first counter 2, the indication unit 3, the first 4 and second 5 optoelectronic converters ^ the first 6 and second 7 single vibrators, the keys 8 on phototransistors, the limit element 9 on the resistor, light emitter 10, second counter 11, optical outputs 12 of second counter 11, control 13 and information 14 inputs of indication unit 3, information 25 and counting 16 inputs of the first 2 and second 11 counters, installation inputs 17 of the first 2 and second 11 counters.

The first and second counters (figure 2) 39

contain optical outputs 12, counting 16 and installation 17 inputs, section; row cells 18 of LEDs 19 and photothyristors 20, LED 21, resistors 22-25, AND-NE elements 26 and 27 and counting trigger 28, power supply bus 29.

The display unit (FIG. 3) contains indicator LEDs 30, an optoelectronic inverter 31, an inverter 32, dd discharge cells 33, LEDs 34 and 35, limiting resistors 36, phototransistors 37 and 38, photothyristors 39 and a power bus 40.

The information inputs 15 of the device are supplied with binary "high" signals corresponding to the code to be reflected in the display unit 3. Optical pulses from the output of the generator 1 are fed to the optical inputs of the first 4 and second 5 optoelectronic converters, which convert them into electrical pulses, arriving respectively at the inputs of the first 6 and second 7 one-shot and counting inputs 16 of the first 2 and second 11 counters. Counters 2 and 11 function synchronously in a single-position code, i.e. Only one output of each signal is always in an excited state, and the ac / arrival of each new pulse switches to the higher bits.

At the moment when the excited output of the first counter 2 turns on the key 8 on the phototransistor, on the collector of which there is a single potential, a flow circuit of> current from the collector of the phototransistor 8 through the resistor 9 and the light emitter 10 to the common bus is created. The light emitter 10 outputs an optical pulse to the information input 14 of the display unit 3. The corresponding discharge of the display unit 3 is excited, since at the corresponding control input 13 of the block 3 there is an optical signal from the corresponding output of the second counter 11.

Counters 2 and 11 operate as a ring, and if in the next cycle of operation of counters 2 and 11 zero potential appears at the input 15, then the corresponding discharge of the display unit 3 will be reset due to the fact that at its information input 14 the optical signal will be absent, those. Only the cells of the display unit 3 are activated, corresponding to the information inputs 15, to which single signals have been input.

For example, if at the initial moment the first, second and last information inputs of the device 15 are supplied.

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single signals, and all others - zero, then. with the arrival of the first optical pulse from the output of the generator 1 to the inputs of optoelectronic converters 4 and 5, the first inputs of counters 2 and 11 are excited ^ and due to the fact that the first input 15 has a single signal, the light emitter 10 outputs an optical signal to the input 14 of the display 3 of the display, the first cell of which is excited, since the first output of the second counter 11 is also excited,

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With the arrival of the second optical pulse from the generator 1, the second outputs of counters 2 and 11 are excited, and the first ones are reset. Due to the fact that a single signal is also present at the second input 15, an optical signal from the light emitter 10 is present at the input 14 of the display 3 of the display

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and its second cell is also excited.

With the arrival of the third pulse, the third outputs of the counters 2 and 11 are excited, but the light emitter 10 does not generate an optical signal to the display unit 3, since a zero signal is present at the third input 15 of the device. As a consequence, the third cell of the display unit 3 is not excited. Similarly, with the arrival of the fourth and subsequent pulses, the fourth and subsequent cells of the display unit 3 are also not excited.

With the arrival of the last pulse, the last outputs of the counters 2 and 11 are excited. At the same time, the optical signal 10 arrives at the input 14 of the display unit 3 of the display, from the light emitter 10, as at. the last input 15 of the device is a single signal.

As a result, the last cell of the display unit 3 ′ is energized. With the arrival of the next impulse, the first discharges of counters 2 and 11 are excited again and the whole process repeats.

Counters 2 and 11 (figure 2) work as follows.

At the starting time of 30

bus 29 supply voltage, and at the inputs 16 and 17 there are zero signals. The trigger 28 is set to one state, i.e. on its direct and inverse outputs there are logical “G” and “0”, and at the outputs of the AND-NE elements 26 and 27 - single potentials. The discharge cells are reset and only the LED 21 turns on, since the input 17 is zero Howling potential · and this LED is connected through a resistor 22 between the power bus 29 and the input 17.

With the arrival of the first electrical impulse to the input 16, the counting trigger 45 28 does not switch, because at the moment when the leading edge of the pulse arrives at its counting input at the 5 input of the trigger, the logical "0" is not yet present, because of the delay time of the single vibrator 50 6 (7 ) (figure 1). Therefore, the first pulse does not affect the switching of the trigger 28.

After the delay time of the one-shot 6 (7), an electric pulse with a duration equal to Т-T appears at the input 17 (T is the repetition period of the optical pulses from the generator 1,.

N is the number of cells in the display unit 3).

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When this pulse arrives, two logical "1" are present at the inputs of the AND-NE 26 element, therefore, a logical "0" appears at its output, arriving at the cathodes of the photothyristors 20 odd cells 18p 18 ^,.,.,

18,. Due to the fact that on. The photo-detector 20 of the first cell 18 ₁ from the LED 21 is fed an optical signal, it goes into a conducting state. Consequently, the current flows through the circuit: power bus 29, resistor 23, LED 19, photo-thyristor 20, resistor 24, output of the AND-NE element 26.

With the arrival of the second pulse, the trigger 28 is switched, i.e. the logical “1” appears on its inverse output, and the logical “0” appears on the direct output, and the logical “1” and “0” appear on the outputs of the AND-NE elements 26 and 27.

At this moment, the photothyristor 20 of the second cell 18 ^ enters the conducting state due to the fact that there is a zero potential at its cathode, and an optical signal arrives from the LED 19 of the first cell 18. The photothyristor 20 of the first cell 18 is locked as a logical "Ι" is fed to its cathode. Similarly, other cells are switched as the next pulses arrive. At the end of the Νth pulse, a single pulse ends and at the installation input 17, zeroing all the cells of the counter. With the arrival of the next Ν + 1th pulse, a single pulse with a duration of N T appears at the input 17, and the process is repeated as for the first Ν-χ pulses.

Thus, the counters 2 and 11 par bot as ring, but the first 18 and last 18 _Ν cells are not interconnected. Therefore, failure leads to disruption of the counter for only one cycle, which increases the noise immunity of the counter.

The display unit 3 (FIG. 3) operates as follows.

At the initial moment of time, a supply voltage is supplied to the power bus 40, there is no optical signal at information input 14, optical signals do not reach the phototransistor 38, and they are closed.

At the moment when the phototransistor

38th cell 33χ receives optical 7

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cue signal from the th control input 13, it opens. If there is no optical signal at information input 14, a high potential is present at the output of optoelectronic inverter 31. From its output, the current flows through the LED 34 and the phototransistor of the 38th cell 33c. The optical signal from the LED 34 of the k-th cell 33 "arrives at the phototransistor 37 of the cell 33. It enters a conducting state, and the current will flow through the resistor 36 and the junction collector emitter of the phototransistor 37. The photothyristor 39 of this cell is closed, and the indicator LED 30 does not light up.

If an optical signal appears on the phototransistor 38 of cell 33 ", and an optical signal is present at the optical input 14 of the display unit 3, then an optical potential at the output of the optoelectronic inverter 31 appears at the output of the inverter 32, and a high potential appears at the output. Through the LED of the 35th cell 33 "current flows, and the optical signal from it is fed to the photo thyristor 39 of the same cell, which passes into the conducting state. Consequently, the current flows through the resistor 36, the indicator LED 30 and the photothyristor 39 of the k-th cell and the indicator LED of the 30 k-h h cell emits light. 35

This state of the kth cell is still preserved. In the display unit, a static operation mode of the indicator LEDs 30 is implemented.

Claims

Claim

A device for indicating, containing a pulse generator, a first counter'ich and an indication unit, characterized in that, in order to increase the reliability of the device, two optoelectronic transducers, two single-vibrators, keys on phototransistors, a limiting element on a resistor, a light emitter and the second counter, the outputs of which are optically connected to the control inputs of the display unit, whose information input is optically connected to the light emitter, whose input through a resistor .. is connected to the emitters phototransistor ^ G ollektory information which are input devices; ' the phototransistor pins are optically connected to the outputs of the first counter, the output of the pulse generator is optically connected to the inputs of the first and second optoelectronic transducers, the outputs of which are connected to the counting inputs of the first and second counters, respectively, the input and output of the first single-oscillator and the installation input of the first counter , respectively, and the input and output of the second one-shot are connected to the output

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