SU947973A1 - Optronic module - Google Patents

Description

The invention relates to a pulse technique and can be used in various automation devices, including digital computers.

A conversion device is known that contains transistors, resistors, capacitors, diodes, and light sources. The disadvantage of the device is the complexity of implementation due to the non-uniform element base.

Also known is an optoelectronic module containing regenerative optocouplers with transistors, photodetectors and a G2 light source.

However, the known device is characterized by an insufficiently high speed and increased requirements to the pulse parameters of the input generator.

The purpose of the invention is to increase the speed and reduce the requirements for the pulse parameters of the input generator.

This goal is achieved by the fact that in an optoelectronic module, containing in each discharge a regenerative optocoupler, which is included, between the first bus power supply and the common

bus, and consisting of a light source, an amplifier, the first photodetector, which is connected between the amplifier input and the first power bus and optically connected to the light source, the second and third photodetectors, the common terminals of which are connected to the amplifier input, and the other terminals respectively to the first and

10 second electrical input busbars, the second photodetector is connected to the previous discharge light source, and the third photodetector is connected to the next light source, yes, a second power bus is introduced, a third electric input bus, an additional light source, an optoelectronic switch, the first and second Switches and additional re-20 generative .optron, in the collector circuit of the transistor of the amplifier of which the light source is included, the base of the transistor of the amplifier through the first photodetector is connected to the first ish25 not power, the third photoreceiver is cut to the second power supply bus; through the second photoreceiver, which is connected to an additional light source, the third electrical input

Claims (2)

30 bus, which is connected to the movable contact of the first switch, the first fixed contact of which is connected to the first electrical input bus and the first fixed contact of the second switch, and the second fixed contact to the second electrical input bus and the second fixed contact of the second switch regenerative optocoupler is optically coupled with its third photoreceiver and with the photoreceiver of the optoelectronic switch, the first terminals of the load resistor of the transistor and photo The receiver of which is connected to the second power supply, the second output of the photoelectric optoelectric switch is connected via a resistor to the common bus and directly to the transistor base of the optoelectronic key, the emitter is connected to the common bus, and the collector. - to the second output of the load resistor and to the moving one to the clock of the second switch, and the additional "light source is connected between the first inn power and the common bus. The drawing shows the structures on the scheme of the optoelectronic module. Each bit of the optoelectronic module contains a regenerative rptron connected to the first power supply bus 1, consisting of a source 2 connected, the first photoreceiver 3, a transistor 4 amplifier, the second photodetector 5, and the third photodetector 6, the combined outputs of these photodetectors are connected to the base of the transistor 4 of each regenerative optocoupler, the second photodetector 5 is optically connected to the source 2 of the previous light, the third photodetector b is connected to the source 2 of the next discharge light, and to the collector circuit of the transistor. 4 additional regenerative optocoupler 7 includes a source of 2 light, and the base of its transistor 4 is connected via the first photodetector 3 to the power supply bus 1 f or the second photodetector 5 to the third electrical input bus 8, which is connected to the movable contact 9 of the first switch 10, having the first fixed contact 11 and the second fixed contact 12; through the third photodetector b base of the transistor 4 of an additional regenerative opto optocoupler 7 is connected to the second power line 13, the light source 2 of the additional regenerative optometer 7 is optically connected with its third photodetector bis photoreceiver 14 of the optoelectric switch 15, and the combined outputs of its photoreceiver 14 and resistor 16 under connected to the base of transistor 17, and the second terminals, respectively, to the second power bus 13, where the load resistor 18 of the optoelectronic switch 15 is connected, and to the common 1generator, the collector of transistor 17 opto The electronic switch 15 is connected to another terminal of the load resistor 18 and to the movable contact 19 of the second switch 20, the first fixed contact 21 of which is connected to the first n fixed contact 11 of the first switch 10, and the second fixed contact 22 to the second fixed contact 12 of the switch 10, an additional source light 23 is connected to the second photodetector 5 of an additional regenerative optocoupler 7, the first and second electrical input buses are designated 24 and 25, and the common bus 26. The device works as follows. -. A power supply voltage is applied to the optoelectronic module for recording information on buses 1 and 13. In the Summing mode, the first switch 10 is shifted to the right position, with contacts 9 and 11 closed; and the second switch 20 is shifted to the left position, with contacts 19 and 22 being closed, and positive polarity pulses are applied to the electrical input bus 8. When applying a light flux to the second photodetector 5 (il) -ro discharge and a pulse of positive polarity on the electrical input bus 8, the (-1) -th discharge and an additional regenerative optocoupler 7 go into the excited state, the rptoelectric switch 15, s the electrical output of which removes a low level of negative potential. Moreover, if the duration of the pause between pulses is such that the additional regenerative optocoupler 7 did not have time to be zero, then when recording the next unit of information from the electrical output of the optoelectronic switch 15, a low level of negative potential is also removed. When applying the next pulses, the 1st, (1 + 1) -th, etc. bits, while resetting (i-l) -ro, i-th, etc. no discharges occur, since the low level of negative potential is also removed from the electrical output of the optoelectronic switch 15 when recording information into the module. After the information is written to the module, the additional regenerative optocoupler 7 is zeroed, the optoelectric switch 15 switches off, and a high level of negative potential is removed from its electrical output, while resetting all the bits of the module, except the last one, in which a unit of information was recorded. as there is no light flux to its third photodetector of this discharge from the optical output of the next discharge. In the Subtraction mode, the first switch 10 is shifted to the left position, contacts 9 and 125 are closed, and the second switch 20 is moved to the right position, contacts 19 and 21 are closed, and the electrical input bus 8 is supplied with positive polarity pulses. If the (| +1) -th module bit is in the excited state, then, when applying electric pulses, I sequentially excite from the i-th, (-1) -th, and so on. bits After the recording of the information is completed, all the bits of the module are reset, similar to the Summation mode, except for the last bit in which the information unit was recorded. Thus, when writing information to the module, it works in a single-normal code, and when the recording is completed, the information is converted into the corresponding 1; i-th unit-position code. If the duration of the input pulses is Cj, and the pause duration is uf, then the module operates in the specified mode, if the duration of the pause between pulses is less than the zeroing time of the additional regenerative optocoupler, tg, Cj; Gd5ts p, where f is the duration of the pause between pulses, tjjgj Q - zeroing time of the additional regenerative optocoupler. In a well-known module, the duration of the pause between the pulses should be maximum, because in the opposite case: e due to the variation of the zeroing times of the regenerative optocouplers when recording a unit of information in the i-bit, non-zeroing (il) -ro bit is possible and in the optoelectronic module there may be several excited regenerative optocouplers. If we assume that the optoelectronic module consists of n regenerative optocouplers, then the time spent 1 to record information in the unit position code in n regenerative optocouplers will be)) ./V.P..O.K ... where n is the duration of the input pulses; Wed about. - switching time optoele1 tronny key; - maximum zero reset time of the regenerative optocoupler. In the well-known module of time, Hflytjee for recording information in n regenerative optocouplers, will be +) .. Considering that. obn: A.R.o .. then the gain in speed when writing information in the n bits of the module compared to the known will be times. If an optoelectronic module, for example, consists of ten regenerative optocouplers, then the performance gain in writing information in 10 bits of the module compared to the known will be -, times., It-fo + sr If SaSw А-Р 0. The optoelectronic module functions in the unit-prediction code, and the commutation of the summation and subtraction rates is done in a similar way. In the Summation mode, when the luminous flux is applied to the second photodetector of the 5 (i + I) -ro discharge, if the i-th discharge was in the excited state, and the next positive-polarity impulse to the electrical one bus 8, the excited state passes (14-1) —and a bit and an additional regenerative optocoupler 7, and in the pause between pulses the additional regenerative optocoupler 7 is zeroed, since V. And p about. switching the optoelectronic switch 15, from whose electrical output a high level of negative potential is removed, and conditions are created for zeroing the i-ro discharge. In the Subtraction mode, if the (1 + 1) -s and the discharge of the module were in an excited state, then the ith discharge and the additional regenerative optocoupler 7 are excited when the next and the second is fed, and in the pause between the pulses the additional regenerative 7 is zeroed , because SiObN.A. (X switching the optoelectronic switch 157 from the electrical output of which a high level of negative potential is removed, and conditions are created for zeroing (f + l) -ro. Discharge. If 0, then to the electrical input bus 8 the potential of polo-polarity is given, with this switching mode summation and subtraction is performed similar manner. In D) to summation of the electrical output optocoupler 15 9nimaets low level negative potential. If-1; the positive polarity is given for the electrical input tm-8 during the time n-i, where n is the number of regenerative optocouplers and t; - regen response time -. then, the transition to the m and n regenerative optocouplers is excited to the excited state. The end of the recording of information into the module corresponds to the fact that the additional regenerative optocoupler 7 is zeroed, the optoelectronic switch 15 is switched, and a high level of negative potential is removed from its electrical output. Consequently, all efforts are made to zero all regenerative optocouplers of the module, except the last one, in which a unit of information was recorded. Suppose th (1) th modulus of the module is in an excited state. Then: in the Subtraction mode, the successively possible d5alots 1 -i, (-1) -and bits, etc. The end of the recording of information in the module corresponds to the fact that all the regenerative optocouplers of the module are zeroed, except for the last. Increasing the speed of the proposed optoelectronic module is connected with the fact that the duration of the pause between the input pulses can vary within О .A since during recording of a unit of information in the i- and module discharge the {-i-1) -th digit does not occur. , and resetting all the bits of the module, except the last one, in which the Information unit is recorded, takes place when the information is fixed and, therefore, the duration of the pause between input pulses does not need to be selected as the maximum. An optoelectronic module can be used in automation and computing devices as successive collectors, reversing counters and shift registers, as well as converters of the time interval to code. Claims of the invention: A photoelectric module containing in each discharge a regenerative optocoupler that is connected between the first power supply bus and a common bus, and consisting of a light source, an amplifier, the first photodetector, which is connected between the amplifier input and the first power supply and is optically connected to the source light, the second and third photodetectors, obgdie whose findings are connected to the input of the amplifier, and other conclusions, respectively, to the first and second electrical input tires, the second photodetector is connected to the light source the previous bit, aj, the third photodetector, with a light source of the subsequent bit, is due to the fact that, in order to increase speed and reduce requirements, to the parameters of the input generator pulses, a second power bus was inserted into it, a third electric input bus, an additional light source, optoelectronic switch, first and second switches, and an additional regenerative optocoupler, in the collector circuit of the amplifier transistor which includes a light source, the base of the amplifier transistor through the first photodetector Connected to the first power bus, via the third photodetector - to the second power bus, through the second photoreceiver, which is connected to an additional light source, to the third electric TRUNK bus, which is connected, to the moving contact of the first switch, the first fixed contact to which is connected to the first electrical input bus and with the first stationary contact of the second switch, and the second, fixed stationary contact - with the second electric input louse and with the second stationary contact of the second switch f This additional regenerative optocoupler is optically connected with its third photoreceiver and with an optical photoelectric switch, the first output load resistor of the transistor and photoelectric receiver are connected to the second power supply bus, the second output of the photoelectric switch of the optoelectronic switch is connected via a resistor to the common transistor and directly to the transistor network and the transistor base to the transistor network; the emitter of which is connected to the bus, and the collector is connected to the second output of the load resistor and the moving contact of the second switch, and dopol A powerful light source is connected between the first power bus and the common bus. Sources of information taken into account in the examination 1. Japan Patent No. 49-39860, cl. P 03 K 23/14, 1974. 2. USSR author's certificate ho application for application No. 2739229 / 18-21, cl. H 03 K 23/12, 10.21.79.