SU1635252A1 - Bistable optoelectronic gate - Google Patents

Abstract

The invention relates to computing and pulse technology and can be used in optoelectronic automation devices. The aim of the invention is to simplify the optoelectronic bistable cell, as a result of which its speed is reduced and the power in the control circuits is reduced. The first photocoupler 1 is made in the form of a photodiode, and the second signal acceptor is made in the form of a bispin-photo- receiver, whose optical inputs are the R- and S-inputs of the cell, respectively. The feedback is carried out through one of the optical inputs of the bisin-photoelectric terminal with the optical output of the light emitter 3. 1 sludge. (L

Description

The invention relates to computing and pulse technology and can be used in optoelectronic automation devices.

The aim of the invention is to simplify the cell. The use of a bispan photodetector in the cell allows, in addition to the simplification, to increase the speed and reduce the power along the control circuits of the cell.

The cell diagram is shown in the drawing.

The cell contains the first photodetector 1 in the form of a photodiode, the second photodetector 2 in the form of a bispin photodetector having three electrical inputs (resistive, locking and controlling) and one optical input,

a light emitter 3, for example, an LED, and a load element 4, for example, a resistor. The drawing also shows electrical 5 and optical 6 cell outputs, R-input 7, S-input 8, power bus 9 and bus 10 of zero cell potential.

The cell works as follows.

In the initial state, the optical pulses on the optical R-input 7 and S-input 8 are absent, the ohmic contact of the bispan-photodetector 2 is connected to the power bus 10. Photodiode 1 is not illuminated and has a large resistance, with the result that the current through photodiode 1 is zero, which, in turn, leads to the fact that the Bispin-photodetector 2 is

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In the disconnected state, and at its output corresponding to the electrical output of the 5 cell, a slight voltage occurs corresponding to the state O. As a result of the fact that the voltage at the output of the bispin photodetector 2 is insignificant, there is no signal at the optical output 6 .

When an optical pulse is applied to the optical S-input 8 of a bistable cell, a Bispin photodetector 2 switches to state 1, since the optical signal power coming from the optical S-input 8 of the device is selected so as to ensure that the Bispine photodetector 2 turns on through it, the current and the formation at its output of a high voltage. Thus, at the electrical output 5 of the bistable cell, a high voltage 1 is set, causing the light emitter 3 to be active, the optical signals from the output of which are fed to the optical input of the bispan photodetector 2 and to the optical output 6 of the cells. to the optical S-input 8 of a bistable cell. should be sufficient for the optical feedback signal power of the light emitter 3 to exceed the optical signal power at the S-input 8 cells. In this case, if the signal at S-input 8 is turned off, the cell will go into storage mode 1 due to positive feedback.

To reset a bistable cell to the zero state, it is necessary to apply an optical signal to the optical R input 7 of the cell, which will illuminate the photodiode 1 and lead to an increase in the flow of current through it and the closing of the bispin photodetector 2 flowing and, at its output corresponding to the electrical output of the 5 cell, the voltage O is set. Since the LED 3 no longer emits optical signals, the positive feedback does not change the cell operation.

Mode when on the optical inputs

8 and 7 of the bistable cell simultaneously signals are given, it is prohibited.

Claims (1)

Invention Formula An optoelectronic bistable cell containing the first and second photodetectors, a light emitter and a load element, the first terminal of which is connected to the cell's zero potential bus, the optical input of the first photoreception is the R-input cell, OTJ. It is understood that, with the cell simplification circuit, the first photodetector is made in the form of a photodiode, the anode of which is connected to the zero potential bus of the cell, and the second photodetector - in the form of a bispin photodetector, the first output of which connected to the power bus cell, the second - to the cathode of the photodiode, and the third - to the first output of the light emitter, the second output of which is connected to the second output of the load element, The optical input of the bispan photodetector is connected to the optical output of the light emitter and is the S input of the cell, the first output and the optical output of the light emitter are respectively the electrical and optical outputs of the cell. ten