SU1119181A1 - Optronic module - Google Patents

Abstract

OPTOELECTRONIC MODULE, containing in each discharge a regenerative optocoupler, common for all bits in a full regenerative optocoupler, an additional light source, an optoelectronic switch, switches, in each regenerative optocoupler a light source is connected between the first power bus and the transistor collector, the emitter of which is connected to common bus, the base - to the first conclusions of the first, second and third photodetectors, in the regenerative optocoupler of each bit the second step of the first photodetector is connected to the first bus of the power supply The light source in the first discharge is optically connected with the first photodetector of its discharge and with the second photodetector of the subsequent discharge, in all bits except the first, the light source is optically connected with the first photoreceiver: its discharge, with the second photoreception. With a third photodetector of the previous discharge, in the optoelectronic switch, the light source is connected between the first power bus and the collector of the transistor, the emitter of which is connected to the common bus, the base to the first terminals of the first resistor and f The optoelectronic key receiver, in the additional regenerative optocoupler, the light source is associated with the first photodetector, the second high 5 (the third photo receiver is connected to the second power supply bar, the third photo receiver of the additional regenerative optocoupler is optically connected with the light source of the additional regenerative optocoupler, which is also optically connected to the photoelectric switch of the optoelectronic switch, an additional light source is connected between the first power bus and the common bus and is optically connected to the second photo An additional regenerative optocoupler is used, characterized in that, in order to increase the reliability of the function, enhance the functionality, a pulse generator, a counting CO trigger, an analog switch, the first and second additional photodetectors, 00 second and third resistors and each regenerative The optocoupler is the fourth and fifth resistors, the first. the outputs of which are connected to the transistor base of the regenerative optocoupler, the second output of the nth resistor is connected to a common bus, the second output of the fourth resistor is connected to the output of the analog switch and to the first output of the second resistor, the second of which is connected to the transistor

Description

the active optocoupler and the first output of the third resistor, the second output of which is connected to the common bus, the second output of the second photodetector of the additional regenerative optocoupler connected to the disconnecting contact of the first switch, the closing contact of which is connected to the control input of the analog key, the signal input of which is connected to the analog input of the device , the switching contact of the first switch is connected to the output of the pulse generator and to the counting input of the counting trigger, the setup input of which is connected It is connected to the reset input, the direct output of the counting trigger is connected to the switching contact of the first group of the second switch, the disconnecting contact of the first group of which is connected to the second output of the second photodetector of the regenerative optocoupler of each odd digit and to the closing contact of the second group of the second switch, the inverse output of the counting trigger is connected to the switching contact, the third group of the second switch, the disconnecting contact of which is connected to the second output of the second photodetector is regenerative optocoupler of each even-numbered and to the closing contact of the fourth group of the second switch, the opening contact of which is connected to the closing

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contact of the third group of the second switch and the second pin of the third photodetector of the regenerative optocoupler of each even-numbered disconnecting contact of the second group of the second switch are connected to the closing contact of the first group of the second switch and the second output of the third photoreceiver of the regenerative optocoupler of each odd-bit, switching contacts of the second and fourth groups of the second switch are connected to the first pins of the first and second additional photodetectors, the second pins of which Connected to the first and second power lines, respectively, the first additional photodetector is optically connected to the light source of the additional regenerative optocoupler, which is also optically connected to the third photodetector of the additional regenerative optocoupler, the second additional photodetector is optically connected to the light source of the optoelectronic switch, the second output of the photoreceiver of which connected to the second power bar, and the second output of the first resistor to the first power bar, to which the closing contact is connected rd switch, the changeover contact of which is connected to the second terminal of the first supplementary regenerative optocoupler photodetector.

The invention relates to a pulsed technique and can be used in various automation devices.

Known optoelectronic module containing regenerative optocouplers on transistors, photodetectors and a light source lj.

The disadvantages of this device are low reliability due to the variation of the switching times of the regenerative optocouplers and limited functionality, since there is no possibility of processing analog signals.

The closest to the proposed technical entity is an optoelectronic module containing in each discharge a regenerative optocoupler, common for all bits an additional regenerative optocoupler, an additional light source, an optoelectronic switch, switches, in each regenerative optocoupler a light source is connected between the first power bus and the collector of the transistor, the emitter of which is connected to the common bus, the base - to the first conclusions of the first, second and third photodetectors, in the J regenerative optocoupler of each bit second The first photodetector is connected to the first power supply bus; the light source in the first discharge is optically connected to the first photodetector of its discharge and to the second follower photodiode, in all bits except the first, the light source is optically coupled to the first photodetector of its own discharge, with the second photodetector of the subsequent discharge, and with the third photoreceiver of the previous discharge, in the optoelectronic switch, the light source is connected between the first power supply bus and the collector of the transistor, the emitter of which is connected to a common The base bus to the first terminals of the first resistor and photo optocoupler of the optoelectric switch; in the additional regenerative optocoupler the optical source is connected to the first photoreceiver, the second view of the third photoreceiver is connected to the second power supply bus, the photodetector of the additional regenerative optocoupler is optically connected with a light source of an additional regenerative optocoupler, which is also optically connected with the photodetector of an optoelectric switch, an additional source of Light is connected between the first power supply and about common bus and optically connected with the second photodetector additional regenerative optro 2. The disadvantages of the known device are low reliability of operation due to the scatter in the switching time of the regenerative optocouplers, which also leads to increased requirements for the duration of the clock pulses and, besides, limited functionality, since there is no possibility of processing analog signals. . I The aim of the invention is to increase the reliability of the operation by reducing the requirements for the duration of the clock pulses and expanding the functional capabilities by allowing the processing of both digital and analog signals. This goal is achieved by the fact that in an optoelectronic module containing a regenerative 814 optocoupler in each discharge, an additional regenerative optocoupler common to all discharges, an additional light source, an optoelectronic switch, and a light source are connected between the first power bus and the collector of the transistor, the emitter of which is connected to the common bus, the base - to the first conclusions of the first, second and third photodetectors, in the regenerative optocoupler of each discharge the second conclusion of the first photodiode The detector is connected to the first power bus, the light source is first optically coupled to the first photodetector of its own discharge and to the second photoreceiver. the next bit, in all bits, except for the first light source, is optically connected with the first photodetector of its bit, with the second photodetector of the next bit and with the third photoreceiver of the previous bit, the light source is connected between the first power bus and the collector of the transistor, the emitter of which is connected to the common bus, the base to the first pins of the ps pv resistor and photodetector of the optoelectronic switch, in the additional regenerative optocoupler the light source is optically connected to the first photoplate By the terminal, the second output of the third photodetector is connected to the second power supply bus, the third photodetector of the additional regenerative optocoupler is optically connected to the light source of the additional regenerative optocoupler, which is also optically connected to the photoreceiver of the optoelectronic switch, an additional light source is connected between the first power line and the common bus and optically associated with the second photodetector of an additional regenerative optocoupler, a pulse generator, a counting trigger, an analog switch are introduced; the first and second additional photodetectors, the second and third resistors, and in the case of a regenerative optocoupler of the fourth and fifth resistors, the first terminals of which are connected to the transistor base of the regenerative optometer, the second terminal of the fifth resistor is connected to the common bus, the second terminal of the fourth resistor is connected to the output of the analog switch and the first output of the second resistor, the second output of which is connected to the base of the transistor of the additional regenerative optocoupler and to the first input of the third resistor the second output of which o connected to the common bus second output of the second photodetector of the additional regenerative optocoupler connected to the disconnecting contact of the first switch, short-circuiting contact of which is connected to the control input of the analog key whose signal input is connected to the analog input of the device, switching contact of the first switch connected to the output of the pulse generator and to the counting the input of the counting trigger, the setup input of which is connected to the reset input, the direct output of the counting trigger is connected to the switch It contacts the first group of the second disconnect switch; the contact of the first group of which is connected to the second output of the second photodetector of the regenerative optocoupler of each odd bit and to the closing contact of the second group of the second switch; the inverted output of the counting trigger is connected to the switching contact of the third group of the second switch, the open contact of which is connected to the second output of the second photodetector of the regenerative optro for each even digit and the closing contact of the fourth group The second switch, the disconnecting contact of which is connected to the third-group third-group switching contact and to the second output of the third photodetector of the even-discharge regenerative optocoupler, the second contact of the second group of the second switch is connected to the closing contact of the first group of the second switch and to the second the output of the third photodetector of the regenerative optocoupler of each odd bit, the switching contacts of the second and fourth groups of the second switch is connected to the first bit The first and second additional photodetectors, the second terminals of which are connected to the first and second power buses, respectively, the first additional photodetector are optically connected to the light source of the additional regenerative optocoupler, which is also optically connected to the third photodetector of the additional regenerative optocoupler, the second additional photodetector is optically It is connected with the optoelectronic signal source, the second photodetector coagial pin is connected to the second power bus, and the second pin of the first th resistor to the first supply bus, which is connected to the normally open contact of the third switch, the changeover contact of which is connected to the second terminal of the first supplementary regenerative optocoupler photodetector. The drawing schematically shows the proposed device. An optoelectronic module containing 1 in each bit. 1, 1.2, 1.3 and 1.4 regenerative optocoupler, common for all bits additional regenerative optocoupler 2, additional light source 3, optoelectronic switch 4, switches, in each regenerative optocoupler 1.11 .4 and 2 light source 5 is connected between the first power bus 6 and the collector of transistor 7, the zmitter of which is connected to the common bus 8, the base is to the first terminals of the first, second and third photodetectors 9-11, in the regenerative optocoupler 1.1-1.4 of each bit the second output of the first photodetector 9 is connected to the first bus 6, power supply 5 lights in the lane The main discharge is optically connected with the first photodetector 9 of its discharge and with the second photodetector 10 of the subsequent discharge, in all bits except the first, the light source 5 is optically connected with the first photoreceiver 9 of its discharge, with the second photoreceiver 10 after-. with the third photodetector 11 of the previous discharge, in the optoelectronic switch 4, the light source 12 is connected between the first power bus 6 and the collector of the transistor 13, the emitter of which is connected to the common bus 8, the base to the first terminals of the first resistor 14 and the photodetector 15 of the optoelectronic switch 4, in the additional regenerative optocoupler 2, the light source 5 is optically connected to the first photoreceiver 9, the second output of the third photodetector 11 is connected to the second power bus 16, the third photodetector 1t is an additional 1119

A regenerative optocoupler 2 i is optically coupled to the light source 5 of an additional regenerative optocoupler 2, which is also optically coupled to the photodetector 15 of the opto-5 switch 4, an additional light source 3 is connected between the first power bus 6 and the common bus 8 and is optically connected with a second photodetector, Yu, an additional regenerative optocoupler 2, a 17 pulse generator, a counting trigger t8, an analog switch 19, the first and second additional photoreceivers 20 and 21, the second and third resistors tS 22 and 23, and each regener The optocoupler 1..i bits are the fourth and fifth resistors 24 and 25, the first terminals of which are connected to the base of transistor 7 of the regenerative optron 20, the second terminal of the fifth resistor 25 is connected to the common bus 8, the second terminal of the fourth resistor 24 is connected to the output 26 of the analog switch 19 and the first output of the second 25 resistor 22, the second output of which is connected to the base of the transistor 7 of the additional regenerative optocoupler 2 and to the first input of the third resistor 23, the second output of which under the 3Q switches to the common bus 8, the second output of the second photodetector 10 additional regenerative optocoupler 2 I connected to the break contact

27 of the first switch 28, the closure contact 29 of which is connected to the control input 30 of the analog switch 19, the signal input 31 of which is connected to the analog input 32 of the device, the switching contact 40 of contact 33 of the first switch 28 is connected to the input 34 of the pulse generator 17 and to the counting input 35 of the counting trigger 18, installation, input 36 of which is connected to the reset input 45 37, direct output 38 of the counting I

trigger 18 is connected to the switching contact 39 of the first step 40 of the second switch 41, open-. The first contact 42 of the first group 40 of which is 50 is connected to the second output of the second photodetector 10 of the regenerative optocoupler 1.1, 1.3 of each odd bit and to the closing contact 43 of the second group 44 of the switch 55, the inverse output 45 of the counting trigger 18 is connected to the switching contact 46 of the third group

47 of the second switch 41, the opening contact 48 of which is connected to the second output of the second photodetector 10 of the regenerative optocoupler 1.2, 1.4 of each even digit and to the closing contact 49 of the fourth group 50 of the second switch 41, the opening contact 51 of which is connected to the closing contact 52 of the third group 47 of the second switch 41 and the second output of the third photodetector 11 of the regenerative optocoupler 1.2, 1.4 of each even-numbered disconnecting contact .53 of the second group 44 of the second switch 41 is connected to the closing contact 54 of the first group 40 of the second switch 41 and the second output of the third photodetector 11 of the regenerative optocoupler 1.1, 1.3 of each odd digit, the contacts 55 and 56 of the second and fourth groups 44 and 50 of the second switch 41 are connected to the first terminals of the first and second additional photodetectors 20 and 21, the second corona leads are connected to the first and second power supply 6 and 16, respectively, the first additional photodetector 20 is optically connected to the light source 5 of the additional regenerative optocoupler 2, which is also optically and is connected to the third photodetector 11 of an additional regenerative optocoupler 2, the second additional photodetector 21 is optically connected to the optoelectronic source 12. key 4, the second output of the photodetector 15 of which is connected to the second power bus 16, and the second output of the first resistor 14 to the first power bus 6, to which the closing contact 57 of the third switch 58 is connected, the switching contact 59 of which is connected to the second output of the additional photoreceiver 9 regenerative optocoupler 2.

The optoelectronic module can be operated in digital and analogue modes.

Consider the operation of the device in. in digital mode.

For readiness of the optoelectronic module to write information to the bus and a positive and negative power supply voltage is applied to the 16, the even -18 trigger sets the zero state by applying

91

at its input 36 potendaal, respectively. units and the contacts 27 and 33 of the switch 28 are in the closed state.

In the Summation mode, switch 41 is set so that its contacts 39 and 42, 46 and 48, 53 and 55, 50 and 51 are closed, contacts 57 and 59 of switch 58 are open. From the output 34 of the generator 17, pulses of positive polarity are applied to the photodetector 10 of the optocoupler 2 through the contacts 33 and 27 of the switch. When applying a light flux to the second photodetector 10 of the optocoupler 1.1 and a pulse of positive polarity on the second pin of the photodisk | 0 optocoupler 2 and the counting input 35 of the trigger 18 to the excited state, the first optocoupler 1.1 and an additional regenerative optocoupler 2 switch, the optoelectronic switch 4 is activated The source 12 of whose light does not emit an optical signal, and the source of light 5 of an additional regenerative optocoupler 2 delivers the optics. This signal corresponds to a high positive potential on the combined outputs of the additional photodetectors 20 and 21. Moreover, if the duration of the pause between pulses is such that the additional regenerative optocoupler 2 did not have time to be zeroed, then when writing the next unit of information from the combined outputs of the additional photodetectors 20 and 21 also have a high level of positive potential. When a next pulse is applied at the forward output 38 of the trigger 18, there is a low level corresponding to a logic zero, and at the inverse output 45 a high level corresponding to the level of a logical unit. This enables the regenerative optocoupler 1.2 of the second bit to be triggered, and when the next pulse arrives, the output of the 38 counted trigger 18 is at a high level, and at the output 45 it is low, which makes it possible to trigger the optocoupler 1.3 of the third bit, etc. Optocouple zeroing 1.1, 1.2, etc. This does not occur, since when recording information into the module from the combined output of additional photodetectors 20 and 21, a high level of positive potential is recorded.

1918110

After the information is written to the module, the additional regenerative optocoupler 2 is zeroed, the optoelectronic switch 4 5 switches, and from its light source 12 comes

The optical signal or the second additional photodetector 21, and the Yervy additional photodetector 20, do not send an optical signal, which corresponds to the high potential of the photoreceivers 20 and 2t at the combined output of the photodetectors 20 and 2t, and the optocouplers of all bits of the module are zeroed by feeding to the base transistor 7 of the negative potential 7 through the photodetector 11, except for the last one, in which the unit of information was recorded, since there is no light flux on its third photo20 receiver 11 of this bit from optical to output of the next bit.,

In the Subtract mode, the nepBLOi switch 41 is set to

25 so that the contacts 39 and 54, 40 and 52, 43 and 55, 49 and 56 are closed, and the switch 58 is in the same state as in the Summation mode (its contacts 57 and 59 are closed). A positive pulse is detected at the output 34 of the generator 17. If the optocoupler 1.3 of the third discharge of the module is in an excited state, then during the loading of electrical pulses, regenerative optocouplers 1.2 and 1.1 of the second and first bits are sequentially excited. After the information is recorded, the module's bits are reset to zero in the same way as the Summation mode, except for the leftmost bit of those in which the unit of information was recorded.

Gakim way, when writing information to the module, it works in a single-normal code, and when the recording of information is completed, the code is converted into the corresponding one-position "

If the duration of the input pulses is € 3 the duration of the pause between the gs pulses ", then the module operates in the specified mode, if

 .App. Ap, about the time of zeroing of additional regenerative 5 optocoupler 2.

If f g Sobn..p4 module operates in a single-position code, and switching modes 11 Summation and Subtraction occurs in a similar way. In the Summation mode, when the luminous flux is applied to the second photodetector 10 of the optocoupler 1.3 of the third discharge, if the optocoupler 1.2 of the second discharge was in an excited state, and the next positive pulse at the generator output 17, the counting input 35 of the trigger 18, is detected At the output 38 of the trigger 18, a potential corresponding to the level of the logical unit appears, the optocoupler 1.3 of the third discharge goes to the excited state, and an additional regenerative optocoupler 2, and in the pause between pulses an additional regulative The optocoupler 2 has zeroed since. d, switching the optoelectric switch 4, therefore, from the combined output of the additional photodetectors 20 and 21, a high level of negative potential is removed and conditions are created for zeroing the second discharge optotron 1.2 In the Subtraction mode, if the third discharge modulator 1.3 is in an excited state, when the next pulse is applied, the optocoupler 1.2 of the second discharge is excited and the additional regenerative optocoupler 2, and in the pause between the pulses the additional regenerative optocoupler 2 is zeroed because .A ro switch ca optoelectronic ny key A thus combined with the findings of other photodetectors 20 and 21 is removed the high level and the negative potential are created conditions for zeroing 1.3 photocoupler third discharge. Consider the analog mode of the device. To operate the opto-electronic module in this mode, it is necessary to close the contacts 33 and 29 of the switch 29 and open the contacts 57 and 59 of the switch 58, and the contacts 40 and 47 are in an intermediate position (with contacts 42 and 48 of the switch 41, respectively, open and with contacts 54 and 52 - not closed). All the bits of the module, using a voltage divider, consisting of two resistors 24 and 25, are tuned 8112 to a certain threshold voltage Ufiop of driving the discharges in increasing order towards the higher bits. The additional regenerative optocoupler 2 is adjusted by variable resistors 22 and 23 to the threshold voltage of the youngest discharge, having the minimum threshold voltage. Contacts 55 and 56 of the switch 41 are installed so that they are closed with contacts 53 and 51, respectively. An analog signal is supplied to the input 31 of the analog switch 19 An analog switch is triggered only when a pulse 30 comes from the output 34 of the generator 17 to its control unit, then the output analog signal Ug U is output from the output 26 of the analog switch 19, which is fed to the second terminals of the resistors 24. Transition of an additional regenerative optocoupler 2 and those bits in which information will be presented in a single-normal code, as an additional regenerative optocoupler 2 locks the optoelectronic switch 4 and, next quently, the first photodetector 20 there is a further optical signal, and the second additional photodetector 21 - is absent. In connection with this, a high level of positive potential is present at the combined pins of the additional photodetectors 20 and 21. At the end of the pulse at the control input 30 of the analog switch 19, the signal from the output 26 of the switch 19 is removed, this embraces the additional regenerative optocoupler 2, the optoelectronic switch 4 is activated, with the source 12 of whose light the optical signal is fed to the second additional photodetector 21, which appears At the combined voltages, additional photodetectors 20 and 21 of a high level of negative potential, which flushes the excited optocouplers of all bits except the last, and the information is presented in the unit position th code corresponding to the present singly in normal code.

13p

When applying an analog signal.

V and. + And,

To the input 31 and upon the arrival of a pulse to the control input 30 of the analog switch 1, those bits are excited, in which U (ep wk

of the pulse at the control input 30 of the analog switch 19, the optocouplers of all the bits, except the most senior excited bit, are zeroed in view of the fact that the combined outputs of the additional photodetectors 20 and 21 are present.

. cue level of negative potential.

The technical and economic effect of the use of the invention lies in the fact that the reliability of the operation is improved, since the effects of time spread and regenerative optocouplers are eliminated, the requirements for 10 times the duration of the clock pulses are reduced, and the functionality is enhanced as the optoelectronic module provides the ability to process analog bass input signals fs remote control with digital inputs with needles.

Claims (1)

OPTOELECTRONIC MODULE containing a regenerative optocoupler in each category, an additional regenerative optocoupler common to all categories, an additional light source, an optoelectronic switch, switches, in each regenerative optocoupler a light source is connected between the first power bus and the transistor collector, the emitter of which is connected to the common bus, the base - to the first conclusions of the first, second and third photodetectors, in the regenerative optocoupler of each discharge, the second output of the first photodetector is connected to the first power bus, to light in the first discharge · optically coupled to the first photodetector his discharge and the second photodetector subsequent discharge, in all places, * except the first light source opti. It is closely connected with the first photodetector • of its discharge, with the second photodetector of the subsequent discharge j and with the third photodetector of the previous one! series, in the optoelectronic key, the light source is connected between the first power bus and the collector of the transistor, the emitter of which is connected to a common bus, the base is connected to the first terminals of the first resistor and photodetector optoelectronic switch, in an additional regenerative optocoupler the light source is optically connected to the first photodetector, the second the output of the third photodetector is connected to the second power bus, the third photodetector of the additional regenerative optocoupler is optically connected to the light source of the additional regenerative optocoupler, which is also optically coupled to the photodetector of the optoelectronic switch, an additional light source is connected between the first power bus and the common bus and is optically coupled to the second photodetector of the additional regenerative optocoupler, characterized in that, in order to increase the reliability of operation, expand functional capabilities, a pulse generator, a counting trigger, an analog switch, first and second additional photodetectors, a second and third resistors, and into each regenerative discharge optocoupler are introduced the fourth and fifth resistors, the first terminals of which are connected to the base of the transistors of the regenerative optocoupler, the second terminal of the fifth resistor is connected to the common bus, the second terminal of the fourth resistor is connected to the output of the analog key and the first terminal of the second resistor, the second terminal of which is connected to the base of the transistor of the additional regenerator 119181 active optocoupler and to the first terminal of the third resistor, the second terminal of which is connected to a common bus, the second terminal of the second photodetector of an additional regenerative optocoupler is connected to the opening contact of the first switch, the closing contact of which is connected to the control input of the analog switch, the signal input of which is connected to the analog input of the device, the switching contact of the first switch is connected to the output of the pulse generator and to the counting input of the counting trigger, the installation input of which is connected to the reset input, direct the output of the counting trigger is connected to the switching contact of the first group of the second switch, the NC contact of the first group of which is connected to the second the output of the second photodetector of the regenerative optocoupler of each odd discharge and to the make contact of the second group of the second switch, the inverse output of the counting trigger is connected to the switch contact of the third group of the second switch, the make contact of which is connected to the second output of the second photodetector of the regenerative optocoupler of each even discharge and to the make contact of the fourth group the second switch, the NC contact of which is connected to the NC of the third group of the second switch switch and to the second terminal of the third 'photodetector of a regenerative optocoupler of each even discharge, the opening contact of the second group of the second switch is connected to the making contact of the first group of the second switch and to the second terminal of the third photodetector of the regenerative optocoupler of each odd discharge, switching contacts • of the second and fourth groups of the second switch are connected to the first conclusions of the first and second additional photodetectors, the second conclusions of which are connected to the first and second power buses accordingly, the first additional photodetector is optically connected to the light source of the additional regenerative optocoupler, which is also optically connected to the third photodetector of the additional regenerative optocoupler, the second additional photodetector is optically connected to the light source of the optoelectronic switch, the second output of the photodetector of which is connected to the second power bus, and the second output of the first resistor - to the first power rail, to which is connected the make contact of the third switch, the switching contact to is connected to the second terminal of the first photodetector of an additional regenerative optocoupler.