SU1058074A1 - Dynamic flip-flop - Google Patents

Abstract

Dynamic trigger containing a driver for clock pulses: photothyristors and LEDs in a diode-thyristor optocoupler, characterized in that, in order to expand its functionality, diodes, resistors, capacitors, anode of the photothyristor of the first optocoupler are connected to the first output of the clock former impulses, its cathode is connected through the first capacitor to the second output of the clock pulse generator, and through the series connection of the first resistor and the first diode to the first output device, which through the second diode, a second optocoupler diode and the second resistor is connected to the anode of the third optocoupler's LED, whose cathode is connected to the third output of the clock pulse generator, to which the cathode of the fourth optocoupler is connected, the anode of which is connected to the first output of the third resistor j the fourth thyristor of the fourth optocoupler The anti-thyristor of the first optocoupler is connected in parallel to the photothyristor; the photothyristor cathode of the third optocoupler is connected to the first output of the clock pulse generator; the solid resistor and the third diode are connected to the second output of the device, and the second diode is connected counter-parallel to the third optocoupler of the third optocoupler, and the photothyristor of the second optocoupler is connected to the second output of the clock of the third optocoupler (P. pulses, cut-through through the third capacitor to the first output of the clock pulse generator and through a serial connection of the fifth resistor and the fifth diode to the third output of the device and to the anode of the first optocouple diode, whose cathode is connected to the fourth output of the clock pulse former, the cathode of the photothyristor The first optocoupler is connected to the cathode of the sixth diode, the anode 00 of which is connected to the first input O of the device, the anode of the LED of the second optocoupler is connected to the cathode of the seventh | the diode, the anode of which is connected to the input of the device, the second output of the third resistor is connected to the fourth input, and the photothyristor cathode of the first optocoupler - to the fifth input of the device.

Description

The invention relates to a pulsed technique, in particular, to pulsed logic elements on optocouplers, and is intended for use in automatic control and monitoring systems, namely, to implement the memory logic function.

Known dynamic trigger containing the elements AND, OR, NOT and the delay line 1.

The lack of a trigger is the heterogeneity of the element base. Also known is a dynamic trigger containing a clock pulse shaper, a photodetector (for example, a photothyristor) and a light source, for example, a Svetodio, and).

However, in a known trigger, limited functionality, namely the presence of only optical outputs. . . 20

The purpose of the invention is to expand the functionality, which is to provide electrical output signals with an increased, on-load capacity on the outputs, -c with a high resistance on the inputs.

The goal is achieved by the fact that in dynamically, a trigger, containing a clock driver, photo thyristors and LEDs,

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diode-thyristor optocouplers, iodines, resistors, capacitors, anode of the photothyristor of the first optocoupler are connected to the first output of the clock pulse generator, its cathode is connected through the first capacitor 35 to the second output of the clock pulse former and through a serial connection of the first resistor and the first diode - to the first y of the device output, which through the second diode 40 is the LED of the second optocoupler and the second resistor is connected to the anode of the light-emitting diode of the third optocoupler whose cathode is connected to the third output of the driver The 45-optodiode cathode of the fourth optocoupler, the anode of which is connected to the first output of the third resistor, is connected to the 45-optocoupler of the fourth optocoupler of the first optocoupler of the third optocoupler connected to the first output of the fourth: the resistor and the third diode are connected to the second output of the device and, through the second capacitor, to the second output of the clock puller, counter-parallel to the photo thyristor The Fourth rd photocoupler enabled diode, the anode fototiristory second photocoupler 60 is connected to the second output of the clock pulse. owls, the cathode through the third capacitor to the first output of the clock pulse generator and through the last-ov-5

Direct connection of the fifth resistor and the fifth diode to the third output of the device and to the anode of the LED of the first optocoupler, the cathode of which is connected to the quad / iy output of the clock pulse generator, the cathode of the photo-thyristor of the first optocoupler is connected to the cathode of the sixth diode, the anode of which is connected to the first input of the device, the anode of the LED of the second optocoupler is connected to the cathode of the seventh diode, the anode of which is connected to the third input of the device, the second output of the third resistor is connected to the fourth input, and the cathode of the photothyristor of the first PTON - to the p input of the device.

Fig. 1 is a schematic diagram of a dynamic trigger; figure 2 - diagram of the maker tactr impulses (options); 3. FIG. 3 —time diagrams of voltages and currents at characteristic points of the circuit.

In the dynamic trigger (figure 1), containing the clock, pulses ,. photothyristors and LEDs in the diode-thyristor optocouplers, diodes, resistors, capacitors, anode of the photothyristor of the first optocoupler 1 are connected to the first OUTPUT 2 of the driver 3 clock pulses, the cathode through the first capacitor 4 is connected to the second output 5 of the driver 3 clock pulses and through a serial connection of the first resistor b and the first diode 7 to the first output 8 of the device, which is connected via the second diode 9 to the anode of the LED of the second optocoupler 10, the cathode of which is the second resistor 11 and the tert LED its optocoupler 12 is connected to the third output 13 of the 3-clock pulse generator, to which the cathode of the LED of the fourth optocoupler 14 is connected, the anode of which is connected to the first terminal of the third resistor 15, the photothyristor of the fourth optocoupler 14 is connected counter-parallel to the photothyristor of the first optocoupler 1, the photodistor of the third optocoupler 14 12 is connected to the first output 2 of the 3 clock pulse generator, the anode through the fourth resistor 16 and the third diode 17 is connected to the second output 18 of the device and through the second capacitor 19 to the second output 5 f ormirovatel 3 clock pulses antiparallel fototiristory third photocoupler 12 is turned on the fourth diode 20, the anode fototiristory vtorrgo photocoupler 10 is connected to a second output 5 shaper 3 clock pulses, the cathode through the third capacitor 21 - to nepBOMv vyodu 2 shaper 3 clock mpulsov and through posledrvatelnoe Connections 5 of the resistor 22 and that diode 23 - to the third output of the device 24 and to the anode of the light-diode of the first optocoupler 1, the cathode of the co-ordinate is connected to the fourth output of the 25 generator 3 clock pulses, the cathode, the photothyristor The first optocoupler 1 is connected to the cathode of the natural diode 26, the anode of which is connected to the first input 27 of the device, the anode of the LED of the second optocoupler 10 is connected to the cathode of the seventh diode 27, the anode of which is connected to the secondary input 28 of the device, the first output 2 of the clock pulse generator is connected to the third input 29, the second terminal of the third resistor 15 is connected to the fourth input 30, and the cathode of the photothyristor of the first optocoupler 1 is connected to the fifth input 31 of the device.

The clock pulse generator of FIG. 2) contains a transformer 32 with a primary winding 33 and secondary windings 34 and 35, resistors 36 and 37, diode-thyristor optocouplers 38-41, diodes 42 and 43.

The device works in the following way.

In the initial state, prior to the supply of power / alternating voltage, the optocouplers 1,10, 12 and are closed, the capacitors 4 and 21 are discharged. In the positive semi-power supply capacitor 19 is periodically charged along the circuit: output 2, diode 20, capacitor 19, output 5. A current through the circuit flows through the LED of the optocoupler 38: the beginning of the winding 35, the light diode of the optocoupler 38, diode 43, the end of the winding 35, and the optocoupler periodically opens into positive memory periods. In the same half-periods, the optocouplers 39-4i are closed because their current diodes are current does not leak. In the negative half-periods, the optocouplers 39,41 and diode 42 LEDs are flowing and they open. With the opening of the -peron 39, the outputs 13 and 5 are periodically connected to the negative half-polyols through its photo-thyristor and with the opening of the optocoupler 41 through the LED of the optocoupler 40 current flows through the circuit: the end winding 35 of the transformer 32, diode 42, photo-thyristor of the optocoupler 41, the LED of the optocoupler 40, resistor 37, the beginning of the winding 35. At the same time, the optocoupler 40. periodically decelerates into negative half-periods, opens and connects the outputs 13 and 5 through its photo-thyristor and photo-thyristor of the optocoupler 39. Between the output 43 and the inverse output 18, depending on the logical operations inputs are logic elements (LEDs in Scheme photocouplers are not shown). For example, when a load is connected to the inverse output 18 of the input of another pulsed logic element, a sequence of pulses is formed on it. In the negative half-cycle, a short pulse is formed on it due to the discharge current of the capacitor 19 along the circuit: left capacitor plate 19, resistor 16, diode 17, output 18, inputs of logic elements, output 43, phototristor of the optocoupler 40, phototristor of the optron 39, output- 5, the right side of the capacitor plate 19. Thus, at the outputs 8 and 24, the signal corresponds to a logical zero, and at the output

18 is a logical unit. When the circuit is closed, the input 27 - output 2, the capacitor 4 in the positive half-cycle s periodically charged along the circuit: output 2, input 27, diode 26, condensation-. torus 4, output 5. During negative periods, the capacitor 4 is periodically discharged along the circuit: its left lining, resistor b, diode 7, output 8, diode 9, optocoupler LED 10, resistor 11, optocoupler LED 12, output 13, optocoupler photo-thyristor 39 , output

5, the right side of the capacitor plate 4. In the negative semiconducts of the tact generator 3, the optocoupler 40 is opened. The flow of current into the negative half-cycle in the LED of the optocoupler 10 causes it to periodically unlock in these half-periods and charge the capacitor 21, and the flow of current in the LED of the optocoupler 12 causes also its periodic unlocking, therefore, the flow of current through the capacitor 19 and its discharge. The current through the capacitor 19 flows through the circuit: output 5, capacitor 19, photo-thyristor optocoupler 12, output 2. as a result leaked Ani AC through the capacitor

19 at the exit. 18 signal corresponds to a logical zero. . Due to the fact that the optocouplers 39 and 3 are opened earlier than the optocoupler 40, at the output the interference signal is almost zero. The charged capacitor 21 is periodically discharged in a positive half-cycle along the feedback circuit: its lining is right, resistor 22, diode 23, output 24, LED of the optocoupler 1, output 25, photo-thyristor 38, bus

21, left its facing. In semi-positive half-periods, the tact 3 shaper opens the optocoupler 38. Further, the described opening cycle of the optocouplers 1 and 10, the charge of the capacitors 4 and 21, and their discharge associated with the opening of the optocouplers, periodically repeats. At the same time, a signal of a logical unit is generated at output 8, and a logical zero signal is output at output 18. At output 24, as well as at output 8, a signal of a logical unit is formed, but only in positive positive periods. Resetting the dingyi trigger to the initial state can be accomplished by opening the circuit, input 29 - output 2, closing the circuit input 31 - output 2, while through the capacitor 4 alternating current flows through the circuit: output 5, capacitor 4, input 31, output 2 and its discharge through resistor b, dio 7 and output 8 does not occur. Resetting the dynamic trigger can also be accomplished by unlocking the optocoupler 14, for which purpose, input 30 must be given a signal of a logical unit from the output of another element. The current through the LED of the optocoupler 14 flows through the circuit similarly to the circuit that carries current in the input circuits of the optocoupler 10 and 12, the LEDs of which are connected to output 8, only with the difference that input 30 is connected to the output of another logic element. Dynamic trigger triggering can also be performed by applying an input signal to input 28. Output 24 in combination with output B can be used to control two thyristors when powering the load with alternating current or to control a symmetric thyristor. Resistors 11 and 15 are provided for equalizing the control currents of the optocouplers in parallel with their connection to the output of the cell. Fig. 3 shows time diagrams of voltage at the corresponding points of the circuit, in particular UC voltage (21.7) in the presence of a logical unit signal at outputs 8 (24.18), voltage U on capacitor 19 in the presence of signal 18 at output logical zero, voltage at output 18 in the presence of a logical zero, and the form of output voltages Ug (18,24) with different loads on the corresponding outputs. . The proposed dynamic trigger has a large functional potential compared to the prototype, since it generates signals on three outputs depending on the state of the inputs, and the signals from outputs 8 and 24 provide the control of the thyristor when the load is supplied with alternating current. Inputs 27.29 and 31 allow the inclusion of control elements with a wide resistance range in the range from Ohms to 1000 ° C and, if necessary, large values can be obtained by selecting the capacitance of the capacitor 4. The presence of inputs 27, 29 and 31 with the ability to connect to them elements with different resistance values allows their inputs to include the control sensors directly, eliminating the need to use the output contacts of the appliance relays. When power is detected at outputs 2 and 5 of shaper 3 or when the voltage is removed from these buses and re-enabled, the dynamic trigger automatically returns to its original state. The circuit is made on a single semiconductor element base, the main element of which is a diode-thyristor optocoupler. The scatter of the parameters of the optocouplers, both during the initial assembly of the elements and their changes during operation, practically do not affect the operation of the dynamic trigger, which increases its reliability in operation.

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25

Claims (1)

A dynamic trigger containing a clock shaper: photothyristors and LEDs as a part of diode-thyristor optocouplers, characterized in that, in order to expand the functionality, diodes, resistors, capacitors are introduced into it, and the anode of the thyristor of the first optocoupler is connected to the first output of the shaper clock pulses, its cathode through the first capacitor is connected to the second output of the clock shaper, and through the serial connection of the first resistor and the first diode to the first output of the device a property that is connected through the second diode, the LED of the second optocoupler, and the second resistor to the anode of the LED of the third optocoupler, the cathode of which is connected to the third output of the pulse shaper, to which * the cathode of the LED of the fourth optocoupler, the anode of which is connected to the first output of the third resistor, is a photo thyristor the fourth optocoupler is connected counter-parallel to the photothyristor of the first optocoupler, the cathode of the photothyristor of the third optocoupler is connected to the first output of the clock shaper, the anode through the fourth cut Side and a third diode connected to the second output device. and through the second capacitor — to the second output of the pulse shaper, the fourth diode is connected counter-parallel to the fist of the third optocoupler, the anode of the photothyristor of the second optocoupler is connected to the second output of the pulse shaper, the cathode through the third capacitor to the first output of the pulse shaper and through serial the fifth resistor and the fifth diode are connected to the third output of the device and to the anode, the LEDs of the first optocoupler, the cathode of which is connected to the fourth output of the clock shaper O pulses cathode fototiristory first optocoupler connected to the cathode of the sixth diode anode. which is connected to the first input of the device, the anode of the LED of the second optocoupler is connected to the cathode of the seventh diode, the anode · of which is connected to the second input of the device, the second output of the third resistor is connected to the fourth input, and the cathode of the photothyristor of the first optocoupler is connected to the fifth input of the device.