SU1243037A1 - Optronic shift register - Google Patents

Abstract

The invention relates to computing and can be used in digital computing devices, in visual indication devices in moving text indicators or dynamic displays. The aim of the invention is to increase the reliability by eliminating the bipolarity of the control signals and reducing the number of optical links inside the bit cells. The optoelectronic shift register contains a driver LED, control buses, memory cells containing a load element, implemented as an LED, photo thyristors and LEDs, a power bus, and optical links. 1 hp f-ly, I ill. with i ate C

Description

The invention relates to computing and can be used in digital computing devices, in visual indication devices in moving text indicators or dynamic displays.

The aim of the invention is to increase the reliability of the optoelectronic moving register by eliminating

20

The NIN of the two polarities of the control signal is in the excited state, i.e. not catching and reducing the number of optical links inside the bit cells.

The diagram shows the scheme of the proposed device.

The device contains a master LED 1, the first 2 and second 3 control buses, memory cells 4 containing a load element 5, made in the form of a LED with an external optical output, the first 6 and the second 6 g photo thyristors, the first 7 /) and the second 72 LEDs, power supply bus 8, as well as optical links 9, with the cathodes of the first photo thyristors 6-g connected to the first control bus 2, the cathodes of the second photo thyristors 6 g are connected to the second control bus 3, the anode of the second photo thyristor 6 g. connected respectively to the cathode of the first LED 7 and the cathode of the second light of the diode 7, the anodes of which are connected together and through the load element 5 are connected to the power bus 8, in addition, the first photo thyristor 6-1 of the first cell 4 of the memory is connected by optical link 9 with driver LED 5, the first LEDs of the 7-j bit cells 4 are connected by optical links 9 with the second photo thyristors 6 g of the same cells 4 of the memory, and the second LEDs 7 g. The bit cells 4 are connected by optical links 9 with the first photo thyristors of 6 subsequent cells of the bit cells 4, respectively.

The device works as follows.

After powering the bus 8 and a high level of control potential, i.e. commensurate with the supply voltage, to the control bus 2, the first photothyristors 6 of all cells 4 of the memory are in the off state because the potential difference between the anodes of the indicator LEDs 5 and the cathodes of the first photothyristors 6 is not sufficient; of these photothyristors, the current being equal to the leakage current of the photothyristors and insufficient

emits light. At the moment of time, the control bus 2 has zero level of the inhibitory potential, i.e. a much lower voltage level, and the control bus 3 is at the low level of the control potential and the presence of a high level of voltage on the master LED 1, the optical signal from the excited driver; its LED 1 through the optical link 9 irradiates the first the photothyristor 6/1 of the first cell 4 of the memory, as a result of which the resistance of the first photothyristor 6/1 sharply decreases and it turns on. In the first step of memory 4, the LED 5 is on the circuit, the LED 7 / f is on, the first 6/1 photoirissor current flows, under the influence of which the LED 5 excites and emits a light flux to the external display. This means that the bit and the format in the form of a logical 1 field in the first cell 4, and the optical signal from the excited LED 7l through the optical link 9 irradiates the photothyristor 6g of the same, first cell 4, which causes a decrease in the resistance of the photothyristor i.e. Photo The thyristor is prepared but the current flowing through it is not sufficient to turn it on. In such a state, each cell can go for an arbitrarily long time,

At a short time from which the high level of the controlling potential to the control bus 2 and the left level of the controlling potential to the control bus 3 turns on the second photo thyristor 6g, and the first phototiristor 6 turns on, and earlier the photo thyristor 6g turns on ., because it was prepared, and the current is turned off, and the current is already flowing through the circuit LED 5, LED 7., the phototristor 6 2 of the first 4 clock memory 4, under the influence of which LED 5 continues to find in the excited state and the optical signal from LED 7 is first th

40

4.5

50

55

for excitations / LEDs, LEDs 5, as well as LEDs 7, with the result that the second photo thyristors of 6 g of each memory cell 4 are also switched off, since there is a large resistance due to the absence of optical signals from the LEDs 7 associated with optically coupled to them 9. Thus, none of the LEDs 5 is

five

0

in the excited state, i.e. not

about

emits light. At the time of submission to the control bus 2 of the zero level of the winding potential, i.e. a much lower supply voltage, and a control bus 3 - a high level of control potential and the presence of a low voltage level on the master LED 1, an optical signal from an excited driver; its LED 1 through optical communication 9 irradiates the first photo thyristor 6/1 the first cell 4 of the memory, as a result of which the resistance of the first photothyristor 6/1 decreases sharply and it turns on. In the first memory cell 4, the LED 5 is on the circuit, the first LED is 7 / f, the first photo thyristor 6/1 is flowing current, under the influence of which the LED 5 is energized and emits a light flux to the external indication. This means that the information bit as logical 1 was recorded in the first cell 4, and the optical signal from the excited LED 7 on the optical link 9 irradiates the photo thyristor 6g of the same, first cell 4, which causes a decrease in the resistance of the photo thyristor 6, i.e. . Photo Thyristor is prepared, but the current flowing through it is not enough to turn it on. In such a state, each of the cells can be indefinitely long,

At a moment, with the supply of a high level of control potential to control bus 2 and a zero level of control potential on control bus 3, the second photo thyristor 6g turns on, and the first photo thyristor 6 turns out, and the photo thyristor 6g turns on earlier, as it was prepared and then the previous one is turned off, and the current is already flowing through the circuit of LED 5, LED 7., the phototristor 6 2 of the first memory cell 4, under the influence of which LED 5 continues to be in an excited state, and the optical signal from led 7 first

0

.five

0

five

the memory cells 4 irradiates the first photothyristor 6 f of the second memory cell 4, preparing it for inclusion, thereby preparing this discharge cell for receiving information in the form of a logical 1 from the previous cell 4 but it is not turned on, since its high cathode is present level of potential. Subsequently, with the supply of a high potential level to the control bus 3, a zero potential to the control bus 2, the first photo thyristor b4 of the second cell 4 of the memory turns on, and as a result of this, the 1st current flows through the LED 5 of the second cell 4 of the memory, excites it and it emits a light flux to the external indication, the photothyristor 6g of the first memory cell 4 is turned off, and the photothyristor is the battery of the first cell 4 memory, depending on whether the optical signal from the driver LED 1 is on or not, turns on or remains off nnom state and the LED 5 or the first chey- ki continues to emit light flux, or radiation is stopped. Thus, the bit of information in the form of logical 1, previously recorded in the first cell 4, was shifted to the next cell 4, and the first bit of information in the form of logical 1 or O was recorded in the first cell 4 of the memory, depending on the state of the master LED 1. , The sequence of logical 1 and O can be any.

formula of invention

0 5 about 5

Claims (2)

1. An optoelectronic shift register containing a driver LED and optically coupled memory cells, each of which contains first and second LEDs, characterized in that, in order to increase the reliability of the register, the first and second photothyristors are inserted into each memory cell and the load cell, the cathodes of the first photothyristors of each memory cell are combined and are the first control bus; the cathodes of the second photothyristors of each memory cell are combined and are the second control bus; the anodes of the first and second photo cells the resistors in each memory cell are connected to the cathodes of the first and second LEDs, respectively, the anodes of which are combined and connected to the first electrode of the load cell, the second electrodes are combined and are the power bus, the first photo thyristor of the first memory cell is optically connected to the master LED, The first LED in each memory cell is optically coupled to the second photo thyristor. 2. A register according to claim 1, characterized in that, in order to provide an external indication with an increased light output efficiency, the load element is made in the form of a LED. /