SU1298864A1 - Optronic bistable cell - Google Patents

Abstract

The invention relates to a pulse technique and can be used in various optoelectronic circuits of automation. The purpose of the invention is to simplify the device by reducing the number of circuit elements and expanding the scope of its application due to the possibility of operating when changing the polarity of the power supply and the source of alternating voltage. The device contains photodetectors 2, 3, input optoelectronic gates 4, 7, resistors 5, 8. To achieve this goal, new connections are introduced into the device. 1 il. c (O (L S;:: CO 00 00 o

Description

one

The invention relates to imguls technique and can be used in various optoelectronic circuits of automation.

The purpose of the invention is to simplify the device by reducing the number of circuit elements and expanding the scope of its application due to the possibility of working when the polarity of the power changes and from a source of alternating voltage.

The drawing shows a schematic diagram of the device.

The device contains a power bus 1 to which the first terminals of the first 2 and second 3 photodetectors and the first electrode of the first optoelectronic shutter 4 are connected, the second electrode of which is connected to the second output of the photoreceiver 2 directly and via a load resistor 5 to the common bus. The electrical output 6 is connected to the second output of the photodetector 2, the first output of the second optoelectric switch 7 is connected to the second output of the photoreceiver 3 and the first output of the second load resistor 8, the second output of which, together with the second electrode of the optoelectronic shutter 7, is connected to a common bus. The constant light emitter 9 is optically coupled to the gate entrance aperture. The output aperture of which, together with the optical S input 10, is optically coupled to the entrance aperture of the gate 7, the output aperture of which is optically connected to the photoreceiver 2 and is the optical output 11 of the bistable. cells, and the optical R-input 12 is optically coupled to the photodetector 3, with the second output of which is connected to the electrical input 13.

The device works in the following way.

In the initial state, the optical pulses at the optical inputs 10 and 12 are absent. After turning on the power supply of the bus 1, the voltage on the optoelectronic gate 4 is approximately equal to the voltage of the power due to the large dark resistance of the photoreceiver 2. The gate 4 is opaque to the radiation coming from the constant light source 9, and the electrical output 6 of the device is logical zero due to the fact that the dark resistance of the photodetector 2 is as high as 86/42

above the resistance of resistor 5. At the optical output 1I of the device, there is no snet, which indicates a zero state of the device, i.e.

the initial state, while the shutter 7 is open. When an optical pulse is applied to the optical R input 12, the resistance of the photodetector 3 decreases and a high potential is applied to the optoelectronic gate 7, which closes, which is equivalent to setting zero at the optical output 11, i.e. The initial state of the device, which corresponds to the storage of a logical zero, does not change.

If the optical signal is present at the optical S-input 10, and is not present at the optical R-input 12, then the resistance of the photoreceiver 3 becomes large again and the optoelectronic shutter 7 opens. The optical signal from S-input 10, passing through the open shutter 7, appears on the optical input of the photodetector 2 and on

the optical output 11. As the resistance of the photodetector 2 decreases in this case, the potential applied to the gate 4 also decreases and the gate 4 becomes transparent for

the passage of light from the constant light emitter 9. Now even after the signal disappears at the S-input 10, the light from the constant light emitter 9 passes through the optical gates

4 and 7, is fed to the photodetector 2, thereby maintaining the optical signal of the logical unit at the optical output 11. At the electrical output 6, the electric potential of the logical unit appears, since the light resistance of the photoreceiver 2 is significantly less than the resistance of the resistor 5. Thus the device after the optical pulse is applied to the S input is set to the second steady state, which corresponds to the storage of the logical unit.

In the presence of signals simultaneously

at the two optical inputs 10 and 12, the device is set to the zero state, i.e. on the optical 11 and electric 6 outputs, the logic zero signals.

the device is dominated by the R input, so it operates in the R-type trigger mode (there is also an electric R input 13).

Claims (1)

Invention Formula An optoelectrical bistable cell containing a constant light emitter, first and second optical optocouplers, the first and second photoreceivers, the first and second load resistors, the first electrode of the first optoelectronic gate and the first output of the first photodetector are connected to the power bus, the second electrode of the first optoelectronic the gate is connected to the second output of the first photodetector, to the first output of the first load resistor and to the electrical output of the bistable cell, the second output of the second photoreception the nickname is connected to the first pin of the second load resistor and to the first pin of the second optoelectronic gate, the second pin of which Editor V. Petrash Compiled by V. Shal gin Tehred A. Kravchuk Proofreader G. Reshetnik Order 896/57 Edition 902 Subscription VNIIPI USSR State Committee for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5 . Production and printing company, Uzhgorod, Projecto st., 4 connected to the common bus, the output aperture of the second optoelectronic shutter is optically connected with the first photodetector, the optical S-input is connected with the input aperture of the second optoelectronic shutter, so that. simplifying and expanding the field of application; the first output of the second photodetector is connected to the power bus; the second terminals of the first and second load resistors are connected to the common bus; the output of the constant light emitter is optically coupled to the input of the first optoelectronic gate, the output of which is optically coupled to the input aperture. the second optoelectronic shutter, the output aperture of which is the optical output of the bistable cell, the optical R input is optically coupled to the second photoreceiver.