SU1151954A1 - Optronic decimal adder - Google Patents

Abstract

An OPTOELECTRONIC DECIMATIC SUMMATOR containing two input units, bit cells, a pulse generator, and a pulse shaping unit, each bit cell containing an optoelectronic quantizing module, the first and second memory blocks, and a switch, the outputs of the first and second input units are connected to the corresponding inputs of the components of the corresponding bit cell; in each bit cell, the first input of the optoelectronic quantizing module is connected to the installation input of the discharge cell, which is connected to the bus of the adder installation to the initial state, the second input of the optoelectronic quantizing module is connected to the power input of the discharge cell, which is connected to the power bus of the adder, first and the second control inputs of the accumulator are connected respectively to the first and second control inputs of the discharge cells, and the pulse generator code is connected to the synchronization inputs of the discharge cells , the first output of the pulse shaping unit is the negative sign of the adder and is connected to the overflow enable input of the last bit cell of the adder, the second output of the pulse forming unit is connected to the overflow prohibition input of the last bit cell of the adder and the transfer receive input of the first adder cell, the first the input of the pulse shaping unit is connected to the output of the request for borrowing the last bit cell of the adder and the input of the request for issuing a loan to the first bit The second input of the pulse shaping unit is connected to the output of the correction 3 of the last bit cell of the adder, which is the output of the correction of the adder, the third input of the pulse shaping unit is connected to the bus of the adder, the initial state, the transfer receiving input of each bit cell , starting with the second one, connected to the output of the transfer unit of the previous bit cell, output of the control unit for receiving the transfer of each bit cell, starting with the second one, 00 connected to the control output of the transfer unit the previous bit cell, the 4th control output of the first bit cell borrowed is connected to the receive control terminal of the last bit cell whose overflow output is the overflow output of the adder, with each of the first and second inputs of the switch connected to the corresponding inputs the items of the bit cell, the third and fourth inputs of the switch are connected respectively

Description

Respectively with the first and second control inputs of the discharge cell, the fifth input of the switch is connected to the synchronization input of the discharge cell, the sixth input of the switch is connected to the receive input of the transfer of the discharge cell, the seventh input of the switch is connected to the input of the request for issuing a loan of the discharge cell, The first output of the switch of each bit cell, except the first one, is connected to the output of the transfer control of this bit cell, into the bit cell of the second switch output is connected to the control output of the bit cell. ma, the third output of the switch is connected to the first electrical input of the first memory block, the second electrical input of the first memory block of each bit cell, except the last one, is connected to the control output of the transfer of this bit cell, the second electrical input of the first memory block of the last bit The single cell is connected to the input of the overflow resolution of this bit cell, the output of the first memory block of each bit cell, except the last one, is connected to the output of the transfer of this bit cell, each bit cell In the fourth quarter, the output of the switch is connected to the first electrical input of the second memory block, the second electrical input of the second memory block of each bit cell, except the last one, is connected to the control input of receiving a bit of this bit cell, the output of the second memory block of each bit cell, In addition to the latter, it is connected to the output of the request for issuing a loan of this bit cell, in each bit cell the first and second optical outputs of the optoelectronic quantizing module are connected respectively to the optical inputs of the first About the second memory block, in the last bit cell the main output of the first memory block is connected to the overflow output of this bit cell, and the additional output - to the correction output of this bit cell, the third electrical input of the first memory block of the last bit cell connected to the input of the overflow prohibition of this bit cell, characterized in that, in order to

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speed and reliability by reducing the requirements for the pulse generator pulse parameters, a write control unit and a write unit are inserted into each bit cell, the third output of the switch is connected to the first input of the write control unit, and a quarter output of the switch is connected to the second input of the write control unit the output of which is connected to the first I-turn of the recording unit, the first control input of the adder is connected to the second input of the recording unit, the second control input of the adder is connected to the third input of the recording unit, the third output of the switch is connected to the fourth input of the recording unit, the fourth input of the switch, connected to the fifth input of the recording unit, the first output of the recording unit is connected to the third input of the optoelectronic quantizing module, the second output of the recording unit is connected to the fourth input of the optoelectronic quantizing module , the third input of the recording control unit is connected to the power bus of the adder, wherein the recording control unit contains an input light source, a regenerative optocoupler, an optoelectronic switch and an The OR, the first and second inputs of which are connected to the first and second inputs of the recording control unit, the output of the OR element is connected to the input of the regenerative optocoupler, which contains a transistor, a light source and three photoelectric receivers, an optoelectronic switch and load resistors, a light source is connected to the collector circuit of the transistor of the regenerative optocoupler, connected to the third input of the recording control unit, the base of the transistor of the regenerative optocoupler is connected via The first photodetector to the third input of the recording control unit, through the second photodetector to the input of the regenerative optocoupler, through the third photodetector to the zero potential terminal, one output of the input light source connected to the third input of the write control block, and the other to the zero potential bus, and the input source light is optically coupled to the second photoreceiver of the regenerative optocoupler, the light source of the regenerative optocoupler is optically coupled to its third photoreceiver and the photoreceiver of the optoelectronic switch, one the output of which is connected to the zero potential bus, and the other to the base of the transistor of the opto-electronic switch and, via a mode resistor, to the third input of the recording control unit, the collector of the transistor of the optoelectronic key is connected to the third input of the recording control unit, the output of the recording control unit is connected to the collector of the transistor optoelectronic key, while the recording unit contains four And four elements of the CM, and the inputs of the first, element And connected to the first, third and fourth inputs of the block records, the inputs of the first element OR are connected to the first and fourth inputs of the recording unit, and the output is connected to the first input of the second element AND, the second input of which is connected to the second input of the recording unit, the inputs of the second element OR are connected to the outputs of the first and second elements AND, and the output - with the first output of the recording unit, the inputs of the third element of RSHI are connected to the fifth and first inputs of the recording unit, and the output is connected to the first input of the third element And, the second input of which is connected to the third input of the recording unit, the inputs of the fourth element And they are connected to the fifth, first and second inputs of the recording unit, and the output is connected to the first input of the fourth OR element, the second input of which is connected to the input of the third element AND, and the output to the second output of the recording unit ..

one

The invention relates to computing and can be used in digital processing machines as the basis element of a processor.

The purpose of the invention is to increase the speed of the adder and increase reliability by reducing the requirements for the pulse generator pulse parameters.

FIG. i is a functional diagram of the three bits of the adder; Fig. 2 is a schematic diagram of a recording control unit; in fig. 3 is a functional block diagram of the record; in fig. 4 is a schematic diagram of an optoelectronic quantizing module.

The optoelectronic decimal adder contains the lowest 1, the oldest 2, and the most senior 3 bit cells, two addends 4 and 5, the impulse generator 6 and the impulse generator 7 (correction pulse and negative sign). Each cell of the cell contains a first second memory block 8 and 9, an optoelectronic quantizing module 10 and a switch 11, inputs

12 and 13 of which are the inputs 14 and 15 of the addendum of the discharge cell, the inputs 16 and 17 of the switch 11 are connected respectively to the control inputs 18 and 19 of the adder, the input 20 of the switch 11 is the synchronization input of the discharge cell and is connected to the output 21 of the generator 6 pulses, the input 22 of the switch 11 is connected to the input 23 of the transfer of the transfer of the discharge cell, the input 24 of the switch 11 is connected to the input 25 of the request for a higher loan of the discharge cell, the output 26 of the switch 11 is the output 27 of the transfer accept of the transfer of the discharge cell, the output 28 crossing Item 11 is the output 29 of the control of the discharge cell of the discharge cell, the output 30 of the switch 11 is connected to the input 31 of the recording unit 32 and to the input 33 of the memory 8, the input 34 and output 35 of which are the transfer control input 36 and the output 37 the transfer of the discharge cell and are connected respectively to the transfer control output 27 and the transfer reception entrance 23 of the adjacent highest bit cell, if the given discharge cell is not the highest. The output 38 of the switch 11 is connected to the input 39 of the block 32, to the input 40 of the memory block 9, the input 41 of the output 42 of which is, respectively, the transfer transfer control input 43 and the output of the loan request output 44 of the discharge cell and connected respectively to the output control output 29 the loan and the input 25 of the request for issuing a loan to the next highest bit of the bit. The optical outputs 45 and 46 of the optoelectronic quantizing module 10 are connected respectively to the optical inputs 47 and 48 of memory blocks 8 and 9. In the highest-order bit 3, the output 35 of memory block 8 is the output of the accumulator overflow, the output of output 49 is the correction of the adder and is connected to the input 50 of the unit 7. The first and third inputs 51 and 52 of the block 8 are permission and prohibition inputs 53 and 54, respectively The overflow of the discharge cell 3 and connected respectively to the outputs 55 and 56 of the block 7, the input 43 of the loan acceptance control of the discharge cell 3 is connected to the output of the control 28 of the discharge of the loan of the discharge cell 1, the output 44 of the request for the loan of the discharge cell 3 is connected to input 24 reception of the loan cell t and with input 57 of unit 7. Input 58 of unit 7 and input 59 of optoelectronic quantizing modules 10 are connected to the bus 60 to set the adder to the initial state, inputs 61 of module 10 are connected to bus 62 of the cjT-iMator power supply. The output 55 of block 7 is the output 63 of the negative character of the adder, the output 56 of the block 7 is connected to the transfer receiving input 22 of the bit cell 1, the outputs of the switch 11 and the output of the generator 6 pulses are connected to the inputs 64 and 65 of the recording control block 66, the output 67 of which connected to input 68 of block 32; recording; input 69 of block 32 is connected to control input 18 of the adder; input 70 of block 32 is connected to control input 19 of the adder; output 71 of block 32 is connected to input 72 of the optoelectronic quantizing module 10 / output 73 of block 32 connected to the input 74 of the optoelectronic kva The module 10, the power bus 62 is connected to the input 75 of the recording control unit 66. Block 66 contains inputs 64, 65, 75 and output 67, the element OR 76 with inputs 77 and 78, which are connected respectively to inputs 64 and 65, the output 79 of the element OR 76 is connected to the input 80 of the regenerative optocoupler 81, to the collector circuit of the transistor 82 of the regenerative The optocoupler 81 is connected to a light source 83, connected to the input 75, the base of transistor 82 is connected via a photodetector 84 to the input 75, through a photodetector 85 to the input 80 of the regenerative optocoupler 81, through the photodetector 86 to the zero potential bus, one output of the input light source 87 is connected to input 75 and the other to the bus well of the left potential, the input source 87 of the light being optically connected to the photodetector 85 of the regenerative optocoupler 81, the source 83 of the light of the regenerative optocoupler 81 is optically connected to the photoreceiver 86 and the photoreceiver 88 of the optoelectronic switch 89, one output of which is connected to the zero potential bus and the other to the base transistor 82 and through a mode resistor 90 to the input 75, the collector of the transistor 82 of the optoelectronic switch 89 through the load resistor 91 is connected to the input 75, and the output 67 of the block 66 is connected to the collector of the transistor 82 opto-electron key 89. Block 32 contains five inputs 31, 39, 68, 69 and 70, two outputs 71 and 73, and input 31 is connected to inputs 92 and 93 of the element AND 94 and the terminal OR 95, outputs 96 and 97 which are respectively connected to input 98 of element 99 and input 100 of element AND 101, input 39 connected to inputs 102 and 103 of element OR 104 and element AND 105, outputs 106 and 107 of which are respectively connected to input 108 of element AND 109 and input 110 of element OR 111 , the input 68 is connected to the inputs 112 and 113, respectively, of the element AND 94 and the element OR 104, the input 68 is connected to the inputs 114 and 115, respectively, of the element OR 95 and the element And 105 input 69 is connected respectively to input 116 of element AND 94 and input 117 of element AND 109, output 118 of which is connected to input 119 of element OR 111, input 70 is connected to input 120 of element And 105 and input 121 of element And 101, output 122 of which is connected to the input 123 of the element OR 99, the outputs 124 and 125, respectively, of the element OR 99 and the element OR 111 are the outputs 71 and 73 of the block 32.

Module 10 contains ten regenerative optocouplers 126-135, each of which contains a source of 136 light, photodetectors 137-139, amplifier 140, diode 141, optical output 142, optical inputs 143 and 144. The module 10 also includes an element HE 145 In this case, the optical output 142 of the subsequent regenerative optocoupler is connected to the optical input 144 of the previous regenerative optocoupler, the optical output 142 of which is connected to the optical input 143 of the subsequent regenerative optocoupler, and the optical output 142 of the continuous optocoupler 126 is zero discharged to the optical By the high input 144 of the ninth regenerative optocoupler 135, an optical output 142 of which is connected to the optical input 143 of a zero regenerative optocoupler 126; The optoelectronic quantizing module 10 has electrical inputs 61.72, 74, and 59; the input 59 for all regenerative optocouplers, except the zero 126, through the diode 141 is connected to the input of the amplifier 140; input 69 through the element HE 145 and diode 141 is connected to the input of amplifier 140 of the zero regenerative optocoupler 126, electrical input 61 is connected to the combined terminals of the light source 136 and the photodetector 137 of all regenerative optocouplers 126-135 module 10; electrical input 72 is connected to the combined pins of photodetectors 138 of all regenerative optocouplers 126-135 module 10, electrical input 74 is connected to the combined and pins of photoreceivers 139 of all regenerative optocouplers 126-135 module 10. Module 10 is equipped with optical outputs 45 and 46.

Optoelectronic dec; the adder works as follows.

At the initial moment of time, a negative reset pulse through the bus 60 for setting the adder to the initial state is fed to the input 58 of block 7, while the outputs 55 and 56 of block 7 are low potential. At the same time, a reset pulse is fed to the inputs, 59 opto-optical quantizers.

modules 10 and sets zero regenerative optocouplers 126 to one state, and the remaining regenerative optocouplers to zero state. This adder state corresponds to the initial zero state and indicates that it does not contain information.

Switch 11 performs the addendum transfer, transfer and loan control functions. When simultaneously applying a high potential to the input 16 and a high potential to the input 12 in the absence of signals at the inputs 13 and 17, the switch 11 passes pulses from the input 20 to the output 30, and to the output 38 - the low potential. At the output 67 of the recording control block 66, there is a high potential input to the input 68 b, rock 32. The input 31 of the block 32 receives pulses from the output 30 of the switch 11, and the input 39 of the block 32 of the recording receives a low potential from the output 38 of the switch 11. At the output 96 of the element AND 94, impulses are generated, arriving at the output 71 of the block 32 through the element OR 99. Since there is a high potential at the input 113 of the element OR 104, there is also a high potential at its output 106 which arrives at the input 108 of the element And 109, to the input 117 of which is high potential, and therefore, at the output 118 of the element And 109 also there is a high potential. Since the output 118 of the element AND 109 is connected to the input 119 of the element OR 111, a high potential appears at its output 125, the same potential exists at the output 73 connected to the output 125 of the element OR 111. This is true only during write operands to the adder.

When recording of operands to the adder is completed, a low potential occurs at the output 67 of the recording control block 66, which enters input 68 of block 32. Low potential is received at input 31 of block 32 when recording of any of the operands is completed, since input 31 is connected to output 30 of switch 11. All other inputs receive the same potentials. Since the low potentials are present at the inputs 31 and 68, connected respectively to the inputs 92 and 112 of the element And 94, there is also a low potential at its output 96, which arrives at the output 71 of block 32 through the element OR 99. Because at the inputs 102 and 113 of the element OR 104, respectively, connected to the inputs 39 and 68 of block 32, low potentials are also present, then at the output 106 of the element OR 104 there is also a low potential arriving at the output 73 of block 32 through the elements AND 109 and OR 111. At the same time, the recording of operands is prohibited in the adder. On the contrary, when a control pulse is applied to input 17 and high potential to input 13 of switch 11, pulses are fed to output 38, and low potential to output 30. With this output, there is a high potential at output 67 of recording control unit 66, which is fed to input 68 unit 32. The input 39 of unit 32 receives pulses from the output 38 of the switch 11, and the input 31 receives a low potential from the output 30 of the same switch 11. At the output 107 of the element I 105, pulses occur, which enter the output 73 of the unit 32 through the element OR 111. Since the input 114 of the element OR 95 when a high potential is lost, then at its output 97 will also be a high potential arriving at the input 100 of the element AND 101, to the input 121 of which post I, psd, II 1 Wi / Wl and nw 1 have a high potential, a) Consequently, The output 122 of the element AND 101 also has a high potential. Since the output 122 of the element AND 101 is connected to the input 123 of the element OR 9, a high potential appears at its output 124, the same potential exists at the output 71 associated with the output 124 of the element OR 99. This is true only during the recording of operands into the adder. When completing the recording of operands into the adder, at the output 67 of the recording control block 66, a low potential occurs at the input 68 of the block 32. At the input 39 of the block 32, when the recording of any of the operands is completed, the potential is low because the input 39 is connected to output 38 switch 11. So "as in the moves 39 and 68, connected respectively to the inputs 113 and 115 of the element And .105, there are low potentials, then 548 at its output 107 there is also a low potential that arrives at the output 73 of the block 32 through the element OR 111. Because the inputs 93 and 114 of the element OR 95, respectively, connected to the inputs 31 and 68 of block 32, low potentials are also present, then the output 97 of the element OR 95 also results in a low potential arriving at the output 71, block 32 through the elements AND 101 and OR 99. At the same time, the recording of operands is prohibited in the adder. The considered cases are intended accordingly for controlling the operation of the adder in the modes of addition and subtraction. If there are no signals at inputs 12, 13, 16 and 17, transfer and loan pulses are possible at inputs 22 and 24. In these cases, switch 11 outputs them to outputs 30 and 38, respectively. Unit 7 is designed to determine the sign of the result, as well as adjust the case of the addition of the first negative operand with the second positive large modulo operand. When a reset pulse is fed to its input 58 from the bus 60 of setting the adder to the initial state, there is no signal at the outputs 55 and 56 of block 7. When a pulse is applied to the input 57 at the output 55 of block 7, and accordingly, a high potential appears at the output 63 of the adder, meaning that the adder contains information with a negative sign. And if, after this moment, a pulse is applied to the input 50 of block 7, then a correction pulse with a duration equal to the duration of stabilized pulses appears at the output 56 of block 7, which is intended to correct the result, as well as set block 7 to stand. In the optoelectronic quantizing module 10, the zero regenerative optocoupler 126 is excited in the initial state. This state of the adder corresponds to the initial zero state and indicates that it does not contain information. Submission to the input 72 of the module 10 PULSES (when stopping the recording of any of the operands to the input 72 of the module 10 receives a low potential), and to the input of the 74 mod-ul 10 during the recording of any of the high potential operands 9 (upon stopping the recording of any of the operands to the input 74 module 10 is supplied low potential) corresponds to the mode of addition. The process of supplying control potentials is discussed in detail above. When a luminous flux is applied to the photodetector 138 of the first bit 12 and a pulse to the electric input 72 module to, the first bit 127 switches to the excited state. The input pulses enter the input 64 from the output 30 of the switch 11, and the input 65 from the output 38 of the switch 1 1 - low potential. Since the inputs 65 and 64 of the recording control block 66 are connected respectively to the inputs 77 and 78 of the SHSh 76 element, input pulses come from the output 79 of the OR 76 element to the electric input 80. When an input pulse is applied to the input 80, the photodetector 85 becomes illuminated, since it is connected to the input source 87 of light. The base current of the transistor 82 of the regenerative optocoupler 81 increases so much that it turns out to be in the open state and there is enough current through its light source 83 to illuminate it, and since there is a positive optical feedback between the light source 83 and the photoreceiver 84, the transistor 82 is kept open even after the input pulse has stopped. Since the regenerative optocoupler 81 of the control unit 6 is in the excited state, and its light source 83 is connected to the photodetector 88 of the optoelectronic switch 89, the key 89 is triggered and a high potential input to the input 67 of the block 66 is removed. The duration of the pause between the input pulses is chosen so that the regenerative optocoupler 81 of the block 66 does not have time to be turned around and when recording the next piece of information, the high potential is also removed from the collector of the transistor 82 of the key 89. When the next pulse arrives from the output 30 of the switch 11, the second 128, the third 129, and so on will be sequenced. regenerative optocouplers. At the same time, during the recording of information, module 10 (recording of any of 410 operands) at input 74 receives a high potential from output 73 of block 32 and when exciting (i + l) -ro discharge of module 10, resetting i-ro of discharge module 10 does not occur, since the optical output 142 (i-bl) -ro is connected to the optical input 144 of the i-th bit, and the combined potential of their photodetectors 139 receives a high potential that prohibits zeroing of the bits of the module 10. Upon completion of recording information to module 10 (low potentials appear at outputs 71 and 73 of block 32) regenerative optocoupler 81 blocks and the write control 66 is zeroed since the resistance of the photodetector 86 drops so much that it shunts the base-emitter junction of the transistor 82 of the optocoupler 81 and almost the entire base current flows through the photo-receiver 86 of the regenerative optocoupler 81, and therefore its transistor 82 is closed, its source is 83 light is not illuminated, the photodetector 88 of the key 89 will be unlit, then the transistor 82 of the key 89 is in the open state and a low potential is removed from its collector and, therefore, upon completion of recording information in m 10, a low potential appears at the output 67 of the recording control unit 66, passing through the block 32 to its output 73 (the output 71 of the block 32 also has a low potential - this follows from the described principle of operation of the block 32). i-ro bit optical signal enters the optical input (i-bl) -ro bit, and output 142 () -ro bit optical signal enters the optical input 144 of the i-th bit optical signal enters the optical input 144 i-ro bit This distribution of optical signals is valid for all bits where information1C1 is recorded, except for the last bit, where a unit of information is recorded. In the compilation mode, the optical signal is not fed to the optical input 144 of the last bit, where a unit of information is recorded; in the subtraction mode, the optical signal is not fed to the optical input 143 of the last bit, where the unit of information is recorded. Thus, at the completion of recording information in module 10, low 74 levels of potential are present at inputs 74, and optical inputs of all bits are stored at inputs 143 and 144, where information is recorded, except for the last bit, where information is recorded (only 14 enters the optical signal from the previous bit). Consequently, the photodetectors 138 and 139 are turned on in parallel for each bit, and if optical signals are received at both their inputs, their total resistance decreases so much that it shunts the base-emitter junction (if the amplifier 140 takes a transistor) and almost all the base current flows through the photodetectors 138 and 139, and all the regenerative optocouplers of module 10, except the last one, where the last pieces of information are recorded, are zeroed. The last regenerative optocoupler, where the last unit of information is recorded, is not zeroed, since no optical signal is received at its input 144 in the add mode (this is obvious, since the regenerative optocoupler following the last is not excited). a low potential enters, and pulses 11 are output from the output 38 of the switch 11, the process of moving information occurs in the opposite direction from right to left. At the same time, during the recording of information in the module 10, a high potential is present at the output 67 of the recording control unit 66, which prohibits zeroing with each tick of the previous bit. Moreover, during the recording of information, pulses arrive at output 73 of unit 32, and high potential at output 71. Promotion of information in the optoelectronic quantizing module tO occurs from right to left (note that in the summation mode from left to right), After the optocoupler 126 is triggered, if the pulses continue to be applied, the regenerative optocoupler 135 will operate and the information shift to the left continues. In this case, the output 73 receives pulses, and n input 72 - high potential (this is true only during the recording of information). Upon completion of recording information in module 10, all bits of it. Where was the information recorded. 5412 are zeroed, except for the last, where the last unit of information was recorded. In this case, the photoreceivers 138 and 139 of all bits, where the information is recorded, except the last bit, where the last unit of information is recorded, receives optical signals, and at inputs 72 and 74 low potentials are present. In the last discharge, the optical signal 138 does not receive an optical signal. As a result, all bits of the module, except the last one, where the last unit of information is recorded, are zeroed. The last bit remains in the excited state. To describe the operation of the adder, we consider two cases of the submission of terms — a term with a positive sign and a term with a negative sign. In the first case, the addendum is supplied from block 4 through the input 14 of the addendum of the discharge cell to the input 12 of the switch 11, and a high potential from the input 18 of the adder is supplied to its third input 16. At the same time, from the output 38 of the switch 11, through the block 32 to the input 74 of the module 10, a high potential is supplied (during information recording) and then a low potential; (when the recording of information is completed) From the output 30 of the switch 11 through the block 32 to the input 72 of the module 10 impulses are given (during the recording of information), and then a low potential (at the completion of recording information). According to the described operation of the optoelectronic quantum module 10, the information in this case is shifted from left to right and its value is determined during the recording of information the number of the excited regenerative optocoupler, and when the recording of information is completed, its value is determined by the position number of the excited regenerative optocoupler. When a transfer unit occurs at the optical output 45 of the optoelectronic quantum module 10, it is transmitted to the optical input 47 and is stored in memory block 8. After the termination of submission of the term as a time interval in the next highest bit cell, the low potential from its transfer control output 27 goes through the higher transfer control input 36

This bit cell to input 34 of memory block 8. In this case, a transfer unit with a duration, equal duration of pulses, cherz output 35 and transfer transfer output 37 enters input transfer reception 23 of the highest bit cell and results in an increase in information in its optoelectronic quantizing module 10 per unit. At the same time, memory block 8 is reset to ..

In the second case, the addendum is supplied from block 5 through the inlet 15 of the addendum of the discharge cell to the inlet of the switchgear 11, and a high potential from the inlet 19 of the adder is supplied to its inlet 17. In this case, from the output 30 of the switch 11, through the block 32, to the input 72, a high potential is applied (during information recording), and then a low potential (at the completion of information recording), and from the output. 38, the switch 11 at the input 74 when the block 32 is pulsed (during the recording of information), and then a low potential (when the recording of the information is completed).

The information in the optoelectronic quantizing module 10 in this case is shifted from right to left and its value is determined during the recording of information by the sequence number of the excited regenerative optocoupler, and when the recording of information is completed, its value is determined by the position of the excited regenerative optocoupler. When a loan unit occurs at the optical output 46 of the module 10, it is transmitted to the optical input 48 of the memory block 9 and is stored until the supply of the term is completed as a time interval in the next highest order. When this happens, the low potential from the output 28 of the switch 11 of the highest bit cell enters through the loan control output 29 via the loan bit control input 43 of the lower bit cell to input 41 of the memory block 9. In this case, the memory block 9 generates a request pulse for a loan with a duration equal to the pulse duration, which through the output 44 of the loan request arrives at input 2 of receiving the request for issuing a loan to the highest bit cell and from here this impulse goes through switch 11 to the input 74 module 10 and leads to a decrease in the information in it by one. When this happens, the memory block 9 is reset to zero. If a loan request is generated in the oldest bit cell 3, for example, in the case of adding and subtracting -1.8-3, + 21-61-21 + 61, - 28+ 15, -21-61, he

enters the input 25 of the youngest bit cell and reduces the information in its optoelectronic quantizing module 10 by one. This pulse is also fed to the input 57 of block 7, as a result of which, the output 55 of block 7, and accordingly, the output 63 of the adder has a high potential. If the potential is high after adding and subtracting the output 63 of the adder, then this indicates that in the adder the result is negative, Otherwise, for example, when adding -2l + 61, the adder contains the result in the forward code,

In the case of adding a negative number with a large positive number, for example, addition -21 + 61, the transfer unit from the output 49 of the memory block 8 of the oldest low-level cell 3 is fed to the input 50 of block 7, In this case, at the output 56 of block 7 a pulse with a duration equal to the duration of the pulses that goes to the input .23

the reception of the transfer of the smallest bit cell and leads to an increase in the information in its module by one. At the same time, this pulse is fed through the input 54 to the input 52 of the memory block 8 of the oldest bit cell 3 in order to prohibit the transmission of overflow of the adder. If after adding

neither + 999 + 1, from the output 55 of the block 7 through the input 53 of the oldest bit cell 3 to the input 51 of its memory unit, a low potential flows, then in this case the adder outputs the output 35 of the oldest bit cell 3 sigpal, which means overflow adder.

Thus, a distinctive feature of the proposed adder is that when writing information to a module. 10, it works in a single-normal code, and when the recording of information is completed, the

- 15 .

into the corresponding unit position code.

If the duration of the input pulses, for the adder to function in the specified mode, it is necessary that the duration of the pause between pulses be less than the zero time of the regenerative optocoupler 81 of the information recording control unit 66,

those. n the duration of the pause between the pulse. am, fj is the zeroing time of the regenerative optocoupler.

If ff 7 / fj, then the optoelectronic adder functions in a single-position code.

Consider how information is recorded in the optoelectronic quantizing module 10 in the addition mode. If the zero bit 126 in module 10 is in the excited state, then when the input pulse is applied from the output 30 of the switch 11, the first bit 127 and the regenerative optocoupler 81 of the recording control unit 66 are output to the excited state; the information is stored in module 10, and the regenerative optocoupler is zeroed in the pause between pulses, because i switches the optoelectronic switch 89, from the output of which low potential is applied to the output 67 of the block 66, while the zero discharge 1:26 of the module 10 is zeroed. Note that the addition process in this mode — T 7 / is similar to the addition mode of the known device.

A distinctive feature of this mode is that during the recording of information in module 10 and during the termination of recording, the adder operates in the unit position code

In the subtraction mode, if the (1 + 1) -th bit of the module 10 is in the excited state, then when the next pulse is applied, the i-th bit and the regenerative optocoupler 81 of the block 66 are excited, with output 67 of which you have. The high potential that permits the recording of information in the i-th bit of module 10, and during the pause between pulses, the regenerative optocoupler 81 of module 10 is zeroed because the TOSH switches the optic key 89, from the output of which to the input 67 of the block 66, a low potential is applied, while The (1 + 1) th bit of module 10 is zeroed

51954J6

If, in the information recording mode, the optoelectronic adder functions in a unit-parallel

code, and upon completion of the recording of information, is converted into the corresponding unit-position code.

Consider how information is recorded in module 10 in addition mode. If the zero bit 126 of module 10 is in an excited state, then when a high potential is applied during the time pT, where, 2 ... 9; f - response time

regenerative optocoupler, in the excitation state 5 goes to the regenerative optocoupler. The termination of the recording of information in module 10 corresponds to the fact that the regenerative optocoupler 81 is zero, the optoelectronic 20 key 89 is switched, and a low potential is removed from the output of block 66. At the same time, all the regenerative optocouplers of module 10 are zeroed, except for the last bit, in which 25 units of information are recorded.

Suppose that (1 + 1) -th bit d. module 10 is in an excited state. Then, in the subtraction mode, the i-th, 30 - (i-1) -th, and so on are sequentially excited. bits The end of the recording of information in module 10 corresponds to the fact that all the regenerative optocouplers of module E are zeroed, except the last one, in which the unit of information is recorded. 35 Thus, the increase in the speed of the proposed optoelectronic adder is related to the fact that the duration of the pause between pulses (input) can vary within the limits as when recording a unit of information in the i-th bit of the optoelectronic quantizing module does not reset (il) -ro bit , and resetting of all bits of module 5, except the last one, in which a unit of information was recorded, is carried out at recording information and, therefore. The duration of the pause between input pulses should not be 50 maximum. With

this condition, the OC ifCj5-optoelectronic adder functions during the recording of information in it in the unit code, and when 55 is completed, the information is converted into

the unit-position code corresponding to it, i.e., in this mode, functions in a unit normal-position code.

Claims (1)

A decoupled optoelectronic summator comprising two term input units, bit cells, a pulse generator and a pulse generator, each bit cell containing an optoelectronic quantizing module, a first and second memory blocks and a switch, while the outputs of the first and second term input blocks are connected to the corresponding inputs terms of the corresponding discharge cell; in each discharge cell, is the first input of the optoelectronic quantizing module connected to the installation input of the discharge cell, which is connected to the initial setting state of the adder _? the second input of the optoelectronic quantizing module is connected to the supply input of the discharge cell, which is connected to the power bus of the adder, the first and second control inputs of the adder are connected respectively to the first. and the second control inputs of the discharge cells, the output of the pulse generator is connected to the synchronization inputs of the discharge cells, the first output of the block pulse shaping is the output of the negative sign of the adder and is connected to the input resolution overflow of the last bit cell of the adder, the second output of the block The pulse input is connected to the overflow inhibit input of the last discharge adder cell and the transfer reception input of the first adder discharge cell, the first input of the pulse generating unit is connected to the loan request of the last adder discharge cell and the loan request input of the first adder discharge cell, the second input the pulse shaping unit is connected to the output of the correction of the last bit cell of the adder, which is the output of the correction of the adder, the third input of the block SU,.,. 1151954 G ”........ _ * pulse generation is connected to the installation bus of the adder; d is the initial state, the transfer reception input of each bit cell, starting from the second, [connected to the transfer output output of the previous bit cell, the transfer reception control output of each the bit cell, starting from the second one, is connected to the control input: transfer of the previous bit control output of the loan issuance of the first bit cell is connected to the loan acceptance control input of the last bit cell, the overflow output of which is the overflow output adder, while in each discharge cell the first and second> the inputs of the switch are connected to the corresponding inputs of the terms of the discharge cell, the third and fourth inputs of the switch are connected respectively to the first and second control inputs of the bit cell, the fifth input of the switch is connected to the synchronization input of the bit cell, the sixth input of the switch is connected to the input of the transfer reception of the bit cell, the seventh input of the switch connected to the input of the request for a loan of a bit cell, the first output of the switch of each bit cell, except the first, is connected to the control output by transferring this bit cell, in each bit cell, the second switch output is connected to the loan control output, the third switch output is connected to the first electrical input of the first memory unit, the second electrical input of the first memory unit of each bit cell, except the last, is connected to the control input by transferring this bit cell, the second electrical input of the first memory block of the last bit cell is connected to the overflow enable input of this bit cell, the output of the first memory block of each bit cell, except the last, is connected to the output of the transfer output of this bit cell, in each bit cell the fourth output of the switch is connected to the first electrical input of the second memory block, the second electrical input of the second memory block of each bit cell, except the last, is connected to the input of the loan receipt control of this bit cell, the output of the second memory block of each bit cell, except the last, is connected to the output of the loan request for this bit cell, in each bit th cell of the first and second optical outputs quantizing optoelectronic module are respectively connected to the optical inputs of said first and second memory blocks, the last bit cell of the main output of the first memory block is connected to the overflow outlet of the discharge cell, and pre-! additional output - with the correction output of this bit cell, the third electrical input of the first memory block of the last bit cell is connected to the overflow inhibit input of this bit cell, characterized in that, in order to increase speed and reliability by reducing the requirements for the parameters of the pulses of the pulse generator, a recording control unit and a recording unit are introduced to each bit cell, the third output of the switch connected to the first input of the recording control unit, and the fourth output of the switch The device is connected to the second input of the recording control unit, the output of which is connected to the first input of the recording unit, the first control input of the adder is connected to the second input of the recording unit, the second control input of the adder is connected to the third input of the recording unit, the third output of the switch is connected to the fourth input of the recording unit, the fourth input of the switch is connected to the fifth input of the recording unit, the first output of the recording unit is connected to the third input of the optoelectronic quantizing module, the second output of the recording unit is connected to the fourth input of the optoelectronic quantizing module, the third input of the recording control unit is connected to the adder power bus, while the recording control unit contains an input light source, a regenerative optocoupler, an optoelectronic switch and an OR element, the first and second inputs of which are connected respectively to the first and second inputs of the recording control unit , the output of the OR element is connected to the input of a regenerative optocoupler, which contains a transistor, a light source and three photodetectors, the optoelectronic switch contains a transistor, a photodetector, a mode and load resistors, a light source connected to the third input of the Recording control unit is included in the collector circuit of the regenerative optocoupler, the base of the transistor of the regenerative optocoupler is connected through the first photodetector to the third input of the recording control unit, through the second photodetector to the input of the regenerative optocoupler, through the third photodetector to the bus zero potential, one output of the input light source is connected to the third input of the recording control unit, and the other to the zero potential bus, and the input and Tocnik light optically coupled to the second photodetector regenerative photocoupler light source regonerativ1151954 Nogo is optically coupled to the optocoupler. with its third photodetector and photodetector photoelectric switch, one output of which is connected to the bus of zero potential, and the other to the base of the transistor of the optoelectronic key and through a mode resistor to the third input of the recording control unit, the collector of the transistor of the optoelectronic key through a load resistor is connected to the third input of the control unit recording, the output of the recording control unit is connected to the collector of the transistor of the optoelectronic switch, while the recording unit contains four AND elements and four OR elements, The inputs of the first, AND element are connected to the first, third and fourth inputs of the recording unit, the inputs of the first OR element are connected to the first and fourth inputs of the recording unit, and the output is connected to the first input of the second AND element, the second input of which is connected to the second input of the recording unit , the inputs of the second OR element are connected to the outputs of the first and second AND elements, and the output is with the first output of the recording unit, the inputs of the third OR element are connected to the fifth and first inputs of the recording unit, and the output is connected to the first input of the third AND element, second input One of which is connected to the third input of the recording unit, the inputs of the fourth AND element are connected to the fifth, first and second inputs of the recording unit, and the output to the first input of the fourth OR element, the second input of which is connected to the input of the third AND element, and the output to the second output recording unit.