SU1023654A1 - Voltage-to-code converter - Google Patents

Abstract

A VOLTAGE CONVERTER IN A CODE containing a voltage-to-time converter, the vysode of which is connected to the inputs of the delay unit and the reset pulse shaper, the discharge blocks of quantrons, in each of which the optical output of each previous quaitron is connected to the optical input of each subsequent quantron, differing in that, in order to increase the noise immunity and simplify the converter, the optoelectronic elements AND and OR, the first optical input of which connected to the optical output of the reset pulse generator, the second optical input is connected to the optical output of the optoelectronic element I, and the optical output connects to the optical reset inputs of quantrons, the optical controls of which are connected to the first optical input of the optoelectronic element I, the second optical input of which is connected to optical outputs of the last quantron, and vf the optical output with the first optical input of the optoelectronic element And the subsequent one. of the discharge unit .quantrons, with the first optical input of the optoelectronic element And the first discharge unit of the quantrons soy with the optical output of the delay unit. NO CO F cl “

Description

The invention relates to computing and can be used to construct analog-to-digital converters. A known voltage converter in the code contains a control unit NIN, the OUTPUT of which is connected to the inputs of the voltage converter in the time interval and with the code recorder, which are also connected to each other, the triggers are connected to the outputs of the And elements, which are connected to the outputs of the digital setting switches l, However, this device is characterized by insufficient speed, due to the limited switching speed of electronic circuits, a complex structure; Display of the A / D conversion result. The converter is known not directly to the code containing the voltage-to-time converter,. the output of which is decelerated by the delay unit is connected to the light emitter of the first bit line of quantrons, and through the shaper of reset pulses with isolating diodes of the discharge lines, which are connected to the resetting inputs of the quantrons, - with the optical input of the control photo of the element, the optical output of the previous quantron is connected to the optical input of the subsequent quantron, the optical output of the last quantron of the with the optical input of the photocell; all electrical modular inputs of quantrons and photocell 2. The disadvantage of this device is its low noise immunity due to the electrical connection of the input and output circuits, as well as the complexity of the circuit. The aim of the invention is to improve the noise immunity and simplify the device. The goal is achieved by the fact that a voltage converter containing a voltage converter in the time interval, the output of which is connected to the inputs of the delay unit and the reset pulse shaper, discharge blocks of quantrons, in each of which the optical output of each previous quantron is connected to the optical input each subsequent quantron, the optoelectronic elements AND and OR, the first optical input of which is connected to the optical output of the pulse former with a second optical input with an optical output of an optoelectronic element I, and an optical output with optical reset inputs of quantrons, the optical control inputs of which are connected to the first optical input of an optoelectronic element I, the second optical input of which is connected to the optical output of the last quantron, and the optical output - with the first optical input of the optoelectronic element I I of the subsequent discharge unit of quantrons, with the first optical input of the optoelectronic element I of the first discharge unit and the quantrons are connected to the optical output of the delay unit. The drawing shows a structural electrical circuit of the device. The device contains a voltage converter 1 into a time interval with an electrical input 2 and an electrical output 3, the discharge blocks 4 of quantum dots containing quantum dots 5, in which the optical outputs b are connected to the first single optical inputs 7 of the followings of the quantum dots 5, the reset impulse driver 8, having an electrical input 9 and an optical output 10, a delay unit 11, equipped with an electrical input 12 11 optical output 13, which with optical inputs 14 quantum dots 5 of the first discharge unit 4, an optoelectronic element IL And 15 having two optical inputs 16 and 17 and an optical output 18, associated with the optical input 19 of each of the quantrons 5 of the discharge units 4, the optoelectronic element And 20,. provided with two optical inputs 21 and 22, one of which is connected to the optical output 13 of the delay unit 11, and the second to the optical output 6 of the last quantron 5 of the first discharge unit 4 and the optical output 23, connected to the optical input 17 of the optoelectronic element OR 15, the optical inputs 14 of each of the quantrons 5 and the optical input 21 of the optoelectronic element AND 20 of the next bit block 4. In addition, the optical output 10 of the imaging unit 8 is connected to the first optical input 1 & optoelectronic element OR 15.

The voltage converter in the code works as follows.

The electrical input 2 of converter 1 is supplied with a voltage to be converted. The pulse from the output of the converter 1 is fed through the optical inputs of 14 quantum dots of the first bit of block 4 and through the optoelectron element OR 15 to the optical inputs 19 of all of the bit blocks 4. The quantrons 5 are set to zero. The delay time on the block il is chosen to be equal to or greater than the delay time on the driver 8 and on the optoelectronic element OR 15 When an optical pulse arrives, the duration of which corresponds to the voltage to be converted into a time interval to the optical inputs 14 of the first discharge unit 4, which comes from the optical output 13 of block 11, in transition to the excited state, the transition of the quantum dots of the first discharge unit 4. Moreover, any k8 antron, except the first, goes into the excited state, when two of its optical their inputs 7 and 14 simultaneously appear optical signals.

After all the quantrons 5 of the first bit unit 4 are switched to the excited state, the optoelectronic element I 20 is activated, from the optical output 23 of which the optical signal goes to the optical input 17 of the optoelectronic element OR 15, to the optical input 14 of all the quantrons 5 and to optoelectronic optical input 21

And 20 second-bit block-4. At the same time, the first quantron 5 of the second bit unit 4 enters the excited state, since the optical output 23 of the optoelectronic element I 20 is associated with the optical departure 14 of this quantron, and the quantrons 5 of the first bit unit 4 transition to the zero state, since the optical output 18 of the optoelectronic element OR 15 is connected to the zero optical input 20 of the first bit unit 4.

Similarly to the described process, the Bioro first discharge of the blizh 4 discharge, the excitation of the second quantron 5 of the second discharge block 4, and the explosion of the quantrons of the first discharge block 4 occur again.

Thus, there is a filling of the second third, etc. blocks 4.

This process occurs until the optical pulse disappears from the optical output 12 of the block 11, indicating the end of the voltage-to-code conversion.

The advantage of the conversion (the voltage detector in the code is its high noise immunity, which is achieved by the introduction of optical links between the units.

The simplification of the proposed device is due to the fact that it lacks a control element (nothing more than a modulator), switching and isolating diodes, and a second pulse shaper.

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Claims (1)

VOLTAGE CONVERTER IN THE CODE, containing a voltage converter in the time interval, the output of which is connected to the inputs of the delay unit and the reset pulse generator, the discharge blocks of quantrons, in each of which the optical output of each previous quitron is connected to the optical inputs of each of the following quitrons, characterized in that that, in order to increase the noise immunity and simplify the converter, optoelectronic elements AND and OR are introduced into each bit block of quantrons, the first optical input of which is connected nen with the optical output of the reset pulse generator, the second optical input with the optical output of the optoelectronic element And, and the optical output with the optical reset inputs of quantrons, the optical control inputs of which are connected to the first optical input of the optoelectronic element And, the second optical input of which is connected to the optical output the last quitron, and § the optical output — with the first optical input of the optoelectronic element AND the subsequent discharge block of quantrons, with the first optical, [optoelectronic input ronnogo of AND Vågå discharge unit quantrons union of the optical output of the Derzhko. lane for SU, 102365