SU1170612A1 - Optronic module - Google Patents

Description

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

The aim of the invention is to expand the functionality for the 'ability to store information when it is read, reducing energy consumption, improving performance.

The drawing shows a schematic diagram of an optoelectronic module.

The module contains bits 1.1, 1,

2-1.N on regenerative optocouplers, 15 power supply bus 2, common bus 3, light emitter 4, first photodetector 5, transistor 6, second and third photodetectors 7 and 8, reset diode 9, first and second pins 10 and 11 of the first 20 key 12, the first and second pins 13 and 14 of the second switch 15, the limiting resistor 16, the additional light emitter 17, zero discharge 18, the first separating diode 19, the second separating diode 20, the fourth photodetector 21, the third, fourth

the second and fifth separation diodes 22, 23 and 24, the first element And 25 with the first, second inputs 25.1 and 25.2 and output

25.3, the second element And 26 with the first

and the second inputs 26.1, 26.2 and output,

26.3, the eighth element And 32 with the first and second inputs 32.1 and 32.2, output 32.3 and the third input 32.4, the ninth element And 33 with the first and second inputs 33.1 and 33.2, output 33.3 and the third input 33.4, the first counting trigger 34 with counting input 34.1, input 34.2 of resetting, direct and inverse outputs 34.3 and 34.4, respectively, second counting trigger 35 with counting input 35.1, input 35.2 of resetting, forward and inverse outputs 35.3 and 35.4, respectively, first short-trigger 36 with the first and second inputs 36.1 and 36.2, respectively, and direct output 36.3, W rear βίο-trigger 37 with the first and second inputs 37.1 and 37.2, respectively, direct and reverse outputs

37.3 and 37.4 respectively, first, second. . .-eighth inputs 38-45 devices.

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An optoelectronic module containing in each discharge 1.1, 1.2-1.Ν 18 a regenerative optocoupler consisting of a light emitter 4, a transistor 6, the first, second and third photodetectors-5,7 and 8, the first terminals of which are connected to the base of the transistor

6, the collector of the latter through the light emitter 4 is connected to the power supply bus 2, and the emitter is connected to the common bus 3, the first photodetector 5 is optically connected with the light emitter 4 of its own discharge, the second. , optically connected to it by the light emitter 4 of the previous discharge 18,

1.1, 1.2-1. (Ν-1), the third and fourth photodetectors 8 and 21 in all digits 18, 1.1, 1.2у1. (Ν-1), except the last 1., are optically connected to ^ 0 by light emitters of the subsequent discharge 1.1 , 1.2-1.Ν, the first conclusion is fourth. of the photodetector 21 is connected to

the base of the transistor 6 of its discharge, and the first account common for all discharges ·· 34, the first and second keys

12 and 15, entered the second counting

trigger 35, the first and second K9-triggers 36 and 37, nine elements And 25, 26-33, limiting resistor 16, 30

additional light emitter 17, and

in each digit there are four dividing diodes 19–22 and a diode 9 reset, in all bits 1.1, 1.2–1. (Ν — 1), except the last one 1.Ν, the fifth splitter diode 24, in all bits 1.1,

1,2-1.Ν the anode of the reset diode 9 is connected to the base of transistor 6, the cathode to the first contact 10 of the first switch 12, the second contact 11 of which is connected 40 to the common bus 3 and to the first contact

13 second key 15, second contact

14 which is connected to the power bus through a serial connection of the limiting resistor 16 and an additional 45 emitter 17, optically connected to the second photodetector

7 zero discharge 18, the cathode of the first separation diode 19 is connected to the second output of the second photodetector 50

7, the cathode of the second separation diode 20 of each discharge 18, 1.1, 1.21. (Ν-1), except the last 1.Ν - to the second conclusion of the fourth photoreception ^ · nick 21, the cathodes of the third and fourth 55 separation diodes 22 and 23 connected to the second output of the first photodetector 5, the anode of the fifth separating diode 24 is connected to the second output of the third photodetector 8, and the cathode to the first input 25.1 of the first element And 25, to the first input 26.1 of the second element And 26 and to the first input 38 of the device, the second input 26.2 of the second element And 26 is connected to the second input 39 of the device, the second input 25.2 of the first element AND 25 is connected to the third input 40 of the device ^ and to the first input 27.1 of the third element ¹ 27, the second input 27.2 of which is connected to the fourth input. 41 device- ^: rois.tva, output 26.3 of the second element AND 26 - to the anode of the third separation diode 22 of each discharge 18 1.1, 1.2-1.Ν, outputs 25.3 and 27.3 of the first and third elements And 25 and · 27 are connected to counting inputs 35 , 1 and 34.1 of the second and first counting triggers 35 and 34, inputs 35.2 and

34.2 of the initial state of which are connected to the fifth input 42 of the device, the outputs 28.3 and 29.3 of the fourth and fifth elements And 28 and 29 are connected to the anodes of the first separation diodes 19 of all odd and even digits 1.1, 1.3-1.Ν and 18,

1.2-1. (Ν-1) respectively, the outputs

30.3 and 31.3 of the sixth and seventh elements And 30 and 31 - to the anodes of the fourth separation diodes 23 all. odd and even digits 1.1,

1.3- 1. and 18, 1.2-1, (Ν-1) respectively, the outputs 32.3 and 33.3 of the eighth and ninth elements And 32 and 33 - to the anodes of the second cross-section diodes 20 of all odd and even digits 1.1,

1.3-1.Ν and 18, 1.2-1. (Ν-1) respectively, the direct output 36.3 of the first ^ -trigger 36 is connected to the first · inputs 30.1 and 31.1 of the sixth and seventh elements And 30 and 31, the first and second inputs 36.1 and 36.2 of the first? 5-flip-flop 36 - to the fifth and sixth inputs 42 and 43 of the device; direct output 37.3 of the second Kb-trigger 37 is connected to the first inputs 28.1 and

29.1 of the fourth and fifth elements 28 and 29 And, and its inverse output 37.4 to the first inputs 32.1 and 33.1 of the eighth and ninth elements And 32, 33, the first and second inputs 37.1 and 37.2 of the second 1? 5-flip-flop 37 are connected to the seventh and the eighth inputs 44. I am 45 devices, direct output 34.3 of the first counting trigger 34 - to the second inputs * 28.2 and 30.2 of the fourth and sixth

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elements And 28 and 30, inverse output

34.4 of the first counting trigger 34 is connected to the second inputs 29.2 and 31.2 of the fifth and seventh elements And 29 and 31, the direct output 35.3 of the second counting trigger 35 to the second input.

32.2 of the eighth element 32 And, the third input 32.4 of which is connected to the collector of zero transistor 6 and yes 18. And to the second input 33.2 of the ninth element And 33, the third input 33.4 of the latter is connected to the inverted output 35.4 of the second counting trigger 35. The first input 41 of the device first information input, input 40 · input of clock pulses, input 38 of the second information input, 'input

39 is the third information input, input 42 is the setup input, input 43 is the erase input, input 44 is the summing input (shift, right), input 45 is the subtraction input (left shift).

The device works as follows.

The information in the proposed module is represented by one excited time series, the sequence number of which is co. corresponds to the weight of the recorded figure, i.e., the device operates in a single-point code.

In preparing the module for recording information on the power bus 22, a positive voltage is supplied relative to ³ common bus 3. After that, the inputs 42 and 45 of the device, i.e. The inputs 36.1, 34.2, 35.2 and 37.2, respectively, of the first short-circuit trigger 36, the first counter trigger 34, the second counter trigger 35 and the second ϊ? 5 trigger 37 are fed a high level of positive voltage. Then, at the direct outputs 34.3, 35.3 of the counting triggers 34 and 35, a low voltage level appears, at the outputs 36.3 and

37.3 K5 -triggers 36 and 37, therefore, at the outputs 29.3 and 31.3 of the fifth and seventh elements And 29 and 31, a high voltage level appears, ⁵ and at the outputs of all other elements And low. In the next step, the contacts 10 and 11 of the first 12 are closed and all the discharges are reset to the initial state, after which the contacts 10 and 11 open. Then pins 13 and 14 of the second switch 15 are clamped and, consequently,

through the additional light emitter 17 and the limiting resistor 16 from the bus 2 to the bus 3 current flows, the light emitter 17 begins to radiate and an optical signal is present on the second photo sensor 7 of zero discharge 18. Due to the presence at output 29.3 of the fifth element I 29 of a high level, the transistor 6 of zero discharge 18 opens and the base current flows through the diode 19, the photodetector 7 and the base-emitter junction of the transistor 6 to the common bus 3, ie the collector current of transistor 6, i.e. current flows from the power supply bus 2 through the light emitter 4 and the collector-emitter junction of transistor 6 to the common bus 3. At the first photodetector 5 there is light from 2θ of the light emitter 4. Consequently, from output 31.3 of the seventh element I 35 through separation diode 23, first photoreceiver 5 and the transition base - emitter of transistor 6 to a common bus 3 te24 _{even current?} . those. Zero discharge 18 is in the excited state (positive feedback circuit is closed). After that, contacts 1.3 and 14 are opened and additional light 3 ° emitter 17 does not emit light. Zero digit 18 remains excited. nom condition due to the presence of the optical signal on the first photodetector 5 from the light emitter 4.

35 Information recording in this module can be done in the mode of changing the information in the direction of the higher digits (summation) and in the mode of changing the information in the direction of the younger digits (subtraction).

In the mode of changing information in the direction of the higher bits to the input 40 of the device, i.e. The combined inputs 25.1 and 27.1 of the elements And 25 and 27 are pulsed and received at input 39, i.e. To the second input 26.2 of the And 26 element is supplied "0", the voltage set by the measured time interval to the input 41 of the device, i.e. ⁵⁰ to the input 27.2 of the And 27 element and to the input 38 of the device, i.e. to the input 25.1 of the element And 25. They ₅ pulses from the outputs 27.3 and 25.3 are fed to the counting inputs 34.1 and 35.1 55 of the first counting trigger 34 and the second counting trigger 35, which are! change their state as many times as the pulses will go to their inputs.

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Suppose, at the first input 27.2, of the element 27 and at the input 25.1 of the element And 25, a time interval signal is given, which allocates five pulses to the input 40, i.e. on the combined inputs 25.1 and 27.1. With the arrival of the first pulse at the inputs 34.1 and 35.1 of the first 34 and second 35 counting triggers, a high level of ¹⁰ voltage appears at the direct outputs 34.3 and 35.3, and at the inverse outputs

34.4 and 35.4 - low respectively.

Therefore, at outputs 28.3 and

30.3 of the fourth and sixth elements And 28 and 30 there is a high '5 level of voltage, and at the outputs of the remaining elements And - low. Due to the presence of the optical signal at the second photodetector 7 of the first discharge 1.1 from the light emitter 4 of the numerical 20 of the left discharge 18, the first discharge 1.1 is excited and the zero discharge 18 is zeroed due to the fact that at outputs 29.3 and 31.3, elements 29 and 31

no high voltage level. With the 25th arrival of the second pulse, the second discharge of 1.2 is excited and the first 1.1 is reset, then the third 1.3 and so on, up to the fifth 1.5. At the end of the time interval, only the fifth digit 1.5 remains in the excited state 30.

In the mode of changing information in the direction of the lower digits to the input 45 _; devices, i.e. to input 37.2 of trigger 37, a high voltage level 35 is applied and at the inverse output

37.4 this trigger appears "1". ("high level), and the input 26.2 of the element I 26 is fed" 0 "(low level), which corresponds to" 0 "at 40 its output.

Suppose that the fifth digit 1.5 is in the excited state and it is necessary to change the information in the direction of the lower digits to two units. For this, it is necessary to apply the signal of the time interval c to the first and second inputs 27.2 and 25.1 of the elements 27 and 25. duration which allocates only 2 impulses. At the initial moment of 50 Burden at the output of 30.3 elements And 30 and the output 32.3 of element 32 is present. "1" due to the fact that zero discharge 18 is in the unexcited state and a high voltage level is present at the collector of transistor 55 6. With the arrival of the first pulse at the output 31.3 of the element AND 31 and the output 33.3 of the element AND 33, a “1” appears, and at the outputs of the remaining elements AND -I “0” a fourth discharge 1.4 is excited, due to the presence of an optical signal at the fourth photodetector 2) fourth discharge 1.4 from the light emitter 4 of the fifth discharge 1.5 and due to the presence of a high voltage level at the anodes of the diodes 20 and 23, and the fifth discharge 1.5 is reset due to the fact that there is no high level at the outputs 30.3 and 32.3 of the elements 30 and 32, With the arrival the second pulse triggers the third bit 1.3 and zeroes fourth I 1.4, Thus, the end of the time slot signal in the excited state is the third digit of 1.3, i.e. information has shifted in the direction of the younger categories by two units.

In the read mode, to the input 37.2 of the setup, to the zero state of the second 65 trigger 37, ”1” is applied and, accordingly, a logical zero appears at the direct output 37.3.

The input 27.2 of the element And 27 is * "0", the input 26.2 of the element And 26 "1", and the input 25.1 of the element And 25 is a time interval signal with a duration allocating Ν + 1 pulses, and the number Ν + 1 should be even so that the second countable trig * ger 35 at the end of the time interval returns to the state; in which he stayed before reading the information (· mation.

Let the excited state be the fifth digit 1.5, and high ^; the voltage level is present at the outputs 30.3 and 32.3 of the sixth and eighth elements 30 and 32, since the counting triggers 34 and 35 operate synchronously.

With the arrival of the first pulse, the second counting trigger 35 changes its state and at the output 33.3 of the ninth element And 33 a "1" appears, and at the output 32.3 of the eighth element And 33 "0". Due to the presence of light in the fourth photodetector 21 of the fourth discharge 1.4 from the light emitter 4 of the fifth discharge 1.5, the fourth discharge of 1.4 is excited, and the fifth discharge 1.5 remains in the excited state, as at the outputs 26.3 and 30.3 elements. Both 26 and 30 there is a high voltage level and a current flowing into the base of transistor 6 through 9

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The fourth photodetector is cut 21; it is equal to the sum of the currents through diodes 22 and 23. With the arrival of the second pulse, the third discharge 1.3 is excited, and the fourth and fifth discharges 1.4 and 1.5 also remain in the excited state. This happens until zero discharge 18 is energized. From the collector of the transistor b, the inputs 32.4 and 33.2 of the elements 32 and 33 receive a low voltage level, therefore, the outputs of these elements contain “0”, and the discharges are not zeroed by that output 26.3 of the element AND 26 is present at a high level applied to the anodes of the diodes 22. At the end of the signal of the time interval, the zero level enters the cathodes of the diodes 24,

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15

And due to the fact that on the third photo it’s 20 that the device has light, through the first 5 and third 8 photodetectors and the first, second, third, third and fourth digits 18, 1.1, 1.2, 1.3 and 1.4. diode 24 will flow .25 current. Bullet, first, second, third and fourth digits 18, 1.1 ,. 1.2,

1.3 and 1.4 are reset to zero, since the resistance of the third photo output device 8 and diode 24 shunts the resistance at the base-emitter transition of the open transistor. The fifth digit 1.5 remains in the excited state due to the fact that at its third photodetector 8 there is no optical signal from the light emitter 4 of the sixth discharge 1.6 and due to the fact that the output

30.3 of the sixth element And 30 there is a high voltage level.

Thus, the cycle during which the zero discharge is excited carries the information recorded in the module.

The table gives the corresponding combinations of input and output signals.

The recording mode in the table is not considered, since it is identical to the summation mode.

Technical and economic effect heals the expansion of functionality by storing information when reading it, reducing energy consumption, since information is encoded by one bit instead of two excited bits in the prototype, as well as improving performance by reducing the information shear time by shifting one information cell in one measure.

Modes,

So you

Information inputs

41 38 39 43 42 (36.1 44 45 of 1 2 3 4 5 N (27.2) (23.1 (26.2) (36.2) 34.2 and (37.1) (37.2) and 26.1) 35.2)

Summation

Subtraction

one

2

3

four

five

6

one

2

3

four

five

0

one

one

one

one

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about

one

one

about

about

about

one

one

one

one

about

about

one

one

about

about

about

about

about

about

about

about

about

about

about

about

about

about

about

about

about

about

about

about

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about

one

about

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about

about

about

about

about

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about

1 0 1 0 0 0 0 0 0

0 0 0 10 0 0 0

About About About FROM 0000

0 0 0 о о о о о о

0 0 0 000100

0 0 About 000100

0 1 About 000000

0 0 O 00 1000

0 0 .0 01.0000

0 O 0 0 1 0 0 0 0

0 0 About 010000

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Table continuation

Modes

So you.

Information inputs

41 38 39 43 42. (36.1 44 45 th — y 1 2. 3 4 5 L ¢ 27-, 2) (23.1 (26.2) (36.2) 34.2 and (37.0 (37.2) · and 26.1) 35.2) ‘

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20

thirty

4 o

50

6 o

(Ν + 1) About

(Ν + 2) About

Stira1. -ABOUT

niya

ABOUT

1 1 About

I 1 o

II o

1 10

11 o

1 1 o

O 1 o

0.0 1

0 0 0 0

About 0 0

Ltd

Ltd

About 0 0

Ltd

O .9 o

About 0 0

About 0 0

About 0 0 0 1 0 0

O O O 1 1 O ₍ 0

O 0 1 1 1 O 10

About 11110 0

ί

1 1 1 1 1 о | о

I

111110 0 1 1 1 1 1 о

About 0 0 0 1 0 0

About 0 0 0 0 0 0

1170612

Claims (1)

OPTOELECTRONIC MODULE, containing in each discharge a regenerative optocoupler consisting of a light emitter, a transistor, the first, second and third photodetectors, the first outputs of which are connected to the base of the transistor, the collector of the latter through the light emitter is connected to the power bus, and the emitter to the common bus, the first photodetector optically connected to the light emitter of its discharge, the second photodetector in all bits except zero, optically connected to the light emitter of the previous discharge, the third and fourth photodetectors in all bits poisons, except for the last, are optically connected to the supercurrent emitter of the subsequent discharge, the first output of the fourth photodynamic receiver is connected to the base of the transistor of its discharge, and the first counting trigger common to all the discharges, the first and a second key, characterized in that, in order to extend the functionality, reduce power consumption and increase speed, a second counting trigger, first and second 85 triggers, nine AND elements, limiting resistor, additional light emitter, and in each discharge — four isolation diodes and a reset diode — in all bits, except the last — the fifth isolation diode, in all bits, the anode of the diode reset is connected to the base of the transistor, the cathode t to the first pin of the first key, the second pin of which is connected to the common bus and to the first pin of the second key, the second pin of which is connected to the power bus through the serial connection of limiting resis Operations and additional light emitter, optically coupled to the second photodetector zero discharge, cathode of the first diode is connected to separating the second terminal of the second photodetector, the cathode of the second diode separating each digit except the last to the second terminal of the fourth photodetector, the cathodes of the third and fourth separating diodes connected to cheny ⁴ the second terminal of the first photodetector, the anode of the fifth separation diode is connected to the second output of the third photodetector, and the cathode in each discharge to the first input p The first element is And, to the first input of the second element And, and to the first input of the device + va, the second input of the second element And is connected to the second input of the device, the second input of the first element And connect to the third input of the device and to the first input of the third element And, the second input connected to the fourth * input device of the device, output is off $ and p „1170612 > 1170612 ' element And connected to the anode of the third separation diode of each discharge, the outputs of the first and third elements And connected to the counting inputs of the second and first counting triggers, the installation settings in the initial state of which are connected to the fifth input of the device, the outputs of the fourth and fifth elements And connected to the anodes of the revolutionary separation of the diodes of all odd and even digits, respectively, the outputs of the sixth and seventh elements AND connected to the anodes of the fourth dividing diodes of all odd and even digits correspond but, the outputs of the eighth and ninth AND gates are connected to the anodes of the second diodes separating the even and odd bits, respectively, a direct output of the first RS '.k -triggera connected first inputs of the sixth and seventh AND gates, first and second inputs of the first The short-circuit trigger is connected to the fifth and sixth inputs of the device, the direct output of the second ^ 5 trigger is connected to the first inputs of the fourth and fifth And elements, and its inverse output to the first inputs of the eighth and ninth And elements, the first and second inputs of the second P5 trigger connected to the seventh and eighth inputs of the device; the direct output of the first counting trigger is connected to the second inputs of the fourth and sixth elements; And the inverse output of the first. counting trigger is connected to the second inputs of the fifth and seventh elements; and the direct output of the second account The first trigger is connected to the second input of the eighth element And, the third input of which is connected to the collector of the zero-discharge transistor to the input of the ninth element And, the third input of the latter is connected to the inverse output of the second counting trigger. 41