SU1075848A1 - Optical memory - Google Patents

Abstract

OPTICAL STORAGE DEVICE, containing sequentially located and optically coupled, radiation source, beam addressing unit, beam forming unit, controlled transparency, beam focusing unit, information storage units, each of them is made in the form of consecutive and optically coupled collimation unit a controlled light switch optically coupled through a storage medium with a light coupler, and a beam focusing unit, an optical readout unit, a photoreceiver unit, and a block control, containing a clock generator, the first output of which is connected to the input of the first control signal generator, the output of which is connected to the radiation source, the second output of the clock generator is connected to the first input of the address buffer accumulator, the second input of which is connected to the first output of the input-output channel, output the address buffer accumulator is connected to the input of the second driver control signals, the output of which is connected to the beam addressing unit, the third output of the sync pulse generator The pulses are connected to the first input of the information buffer accumulator, the second input of which is connected to the second output of the I / O channel, the output of the information buffer storage device is connected to the input of the third control driver, the output of which is connected to the control transparency, the fourth output of the clock generator is connected to the first the input of the I / O channel, the second input of which is connected with the output of the buffer accumulator, the first input of which is connected with the fifth output of the generator of the sync pulse of the second The buffer storage unit is connected to the output of the photoreceiver unit, the sixth output of the clock generator is connected to the input of the fourth control signal generator, the output S of which is connected to the input of the photoreceiver unit, the seventh and eighths ccc) equalizing signals, the outputs of which 4 are connected respectively to the controllable light switches and information carriers of each of the information storage units characterized by That, in order to increase the reliability of the device, a controlled optical valve is inserted into each of the information storage units, the information carrier is made in the form of a two-dimensional photosensitive plate with rectangular holes, and the seventh control drivers are inserted into the control unit

Description

signals by the number of information storage units, the controlled light switch, if through rectangular holes in the photosensitive plate, is connected to the light coupler, the output of which is optically controlled through an optical controlled valve

connected to the input of the beam focusing unit, the ninth outputs of the clock generator are connected respectively to the inputs of the seventh control signal drivers, the outputs of which are connected to the corresponding controllable optical valves.

The invention relates to the field of computational tech- nique and can be used as a storage device when processing large amounts of information. An optical operational recording device is known, built on the basis of controllable multiplexers of images and information carriers that are reflective. The main disadvantage of this device is the relatively low storage capacity of the information. The closest technical solution is an optical memory access unit that contains Two lens regis. ra, controlled light switch, storage medium, light separator and control unit. The main disadvantage of this unit. - relative but low reliability. The purpose of the invention is to increase the reliability of the device. This is achieved in that an optical memory device containing successively located and optically coupled radiation source, beam addressing unit, beam forming unit, controlled transparency, beam focusing unit, information storage unit, each of which is sequentially arranged and optically (A coupled collimating node, controlled by a light switch, optically connected through a carrier-g formation with a light coupler, and a beam focusing unit, an optical reading unit, or a receiving unit and a control unit containing a clock generator, the first output of which is connected to the input of the first driver of control signals, the output of which is connected to the radiation source, the second output of the generator of clock pulses, is connected to the first input of the address buffer accumulator, the second input of which is connected to the first the output of the I / O channel, the output of the address buffer accumulator is connected to the input of the second driver of control signals, the output of which is connected to the beam addressing unit, the third output is a gene The sync pulse generator is connected to the first input of the information buffer accumulator, the second input of which is connected to the second output of the I / O channel, the output buffer of the information buffer terminal is connected to the input of the third control signal generator, the output of which is connected to the control transparency, the fourth output of the sync pulse generator is connected to the first input of the I / O channel, the second input of which is connected with the output of the buffer accumulator, the first input of which is connected with the fifth output of the synchroimpu generator The second input of the buffer accumulator is connected to the output of the photoreceiver unit, the sixth output of the sync pulse generator is connected to the input of the fourth control driver, the output of which is connected to the input of the photodetector unit, the seventh and eighth outputs of the sync pulse generator are connected to the rear of the fifth and sixth control formers. signals, the outputs of which are connected respectively to the control 1m of the light of one of the switches and information carriers of each of the information storage units, in each of information storage units, a controlled optical valve is inserted, the information carrier is made in the form of a 2D photosensitive plate with rectangular holes, and the seventh control signal generator is inserted into the control unit according to the number of information storage units, the controlled light switch through rectangular holes in the photosensitive plate is engaged with a light combiner, the output of which is optically connected via a controlled optical veitil, is connected to the input of a beam focusing node, and to the gene outputs The clock signals are connected respectively to the input of the seventh control signal drivers that have outputs connected to the corresponding controllable optical valves. The figure shows the optical storage device The optical storage device contains the radiation source 1, the beam addressing unit 2, the beamforming unit 3 that is controlled trans port 4, beam focusing unit 5 of information storage units 6, collimating node 7, controlled light switch 8, information carrier 9, light interconnect s 10 controlled by an optical isolator 11, a beam focusing unit 12, optical pickup unit 13, a light receiving unit 1-4 and a control unit 15. As a radiation source 1, for example, a laser can be used. As a beam addressing unit 2, for example, electro-optical, acousto-optic or liquid crystal deflectors can be used. The beam-forming unit 3 can consist, for example, of a telescopic system optically connected to a lens raster, and two objectives that are mutually in focal plane bones apart, with the first lens located in the rear focal plane of the lenticular screen. Managed transparency 4 is intended for amplitude modulation of a light beam passing through it and can be performed, for example, on the basis of liquid crystals with a matrix or individual addressing. The information on the banner 4 is displayed, for example, in a paraphase code. The beam focusing unit 5 can be made, for example, in the view of two lenses installed mutually in each other's focal planes. The information storage units 6 are intended to store information and consist, for example, of a collimating unit 7, a controllable light switch 8, an information carrier 9, a light coupler 10, a controllable optical wave 11 and a beam focusing unit 12. Collimating node 7 is made, for example, in the form of a lenticular raster. The controllable light switch 8 has k optical inputs, each of which has two optical outputs. For example, a birefringent crystal (for example, Iceland spar) can be used as a controlled light switch (for example, Iceland spar), in front of the entrance plane of which a light polarization switch is installed, which, for example, when voltage is applied, turns the plane of polarization of transmitted beams by 90, or, for example, the control polycubic system. . Media 9 information carried -. The reverse storage of information in the form of separate micro frames - pages of information, for example, in a paraphase code. The carriers 9 can be made, for example, on the basis of a photovoltaic crystal (for example, bismuth silicate /, or on any suitable medium that can record, read and erase information. The light coupler 10 has 2k optical inputs, each pair of which has one output. The light coupler 10 can be used, for example, a two-beam, refractive crystal (for example, Iceland spar) or a polycubic system. The controllable optical valve 11 serves to coordinate the operation of the successively located The information storage valve. The valve 11, for example, when fed to it, directly rotates the polarization plane of the transmitted beams by 90. It can be performed, for example, on the basis of electro-optical DC, CR or liquid crystal crystals. The photodetector unit 14 is intended for reading information represented in a paraphase code and can be made, for example, in the form of typesetting or integrated photodetector arrays. The control unit 15 ensures the operation of the memory devices in various modes. Block 15 may consist, for example, of a sync pulse generator 1; control signal generator 17, input-output channel 18; address buffer accumulator 19; shaper 20 control signals of information buffer accumulator 21; shaper 22-26 control signals; buffer accumulator 27. RAM works as follows. 1. In the recording mode information on the command generator. 16, the radiation source 1 is energized and the light beam from it is fed to the beam addressing unit. The site address of the carrier, on. which the microframe needs to be recorded, by the commands of the generator 16 comes from the input channel of the drive 18 to the drive 19, which, through the driver 20, supplies control voltages to block 2. According to the supplied code, block 2 sets the light beam to the position of the microframe recording . The light beam passes the beamforming unit 3 and at an angle corresponding to the address of the recording of the microframe on the carrier 9, illuminates the transparency 4. According to commands from the generator 16, the information to be recorded to the microframe comes from the input / output channel to the accumulator 21 and then to the driver 22, which supplies control voltage to a banner 4. According to the code provided. the transparency 4 modulates the passage of the light beam, and it is directed through the beam focusing unit 5 to the input of the block 6. The axes of the light beams at the output of the block 5 are parallel to the optical axis of the block 6. Thus, in the code of block 5 corresponding to the address of the media carrier 9, on which the micro-frame is to be recorded, a focused image of the code displayed on the transparency 4 appears. The beam transferring this image is collimated by the collimating node 7 of the first block 6. Suppose that the recording must be made in the second block block 6. Then the beam passes unimpeded through the channel through elements 8-11 (in the carrier 9, for example, there is a through hole), goes to the beam focusing unit 12, which focuses it and sends it to the input of the second unit 6. The synchro generator 16 outputs signals to drivers 23 and 24 that produce control voltages respectively for control light switch 8 and information carrier 9 (second block 6). According to the input signal from block 15, the controlled light KJ, the jogger 8 directs the input beam along the channel P to the section of the carrier 9 intended for recording the microframe. A page of information is recorded on the carrier 9. Upon completion of the recording of the microframe, the voltage from the carrier 9 at the command of unit 15, for example, is removed. Similarly, information is recorded in any block 6. 2. In the readout mode, all working cells of the banner 4 are switched to the light transmission mode. The illumination of the microframe intended for matching is carried out by the same optoelectronic system as in its recording. The beam passed the carrier 9, using a light coupler 10 and controlled. an optical valve 11, to which the generator 25 supplies a control voltage according to the signal of the generator 16, is directed to the channel of the third unit 6. The light beam passes all the other units 6 through the channel and passes through the optical reading unit 13 to the receiving unit 14. At block 14, on command from generator 16, driver 26 supplies control voltages, it reads information and sends signals from generator 16 to input-output channel 18. 3. When erasing information, the optoelectronic system of the device works in the same way and to the information recording. In this case, all the cells of the transparency 4, which correspond to the information to be erased, are transferred to the light transmission mode. The remaining cells are masked), and the carrier 9 is given a signal allowing the erasure by command of the unit 15.

The use of the proposed optical storage device in the composition of computer systems will allow more than 10 times increase in the volume and reliability of information processing.

Claims (1)

OPTICAL COMMISSION DEVICE, comprising sequentially located and optically coupled radiation source, beam addressing unit, beam forming unit, controlled transparency, beam focusing unit, information storage units, each of which is made in the form of sequentially located and optically connected collimating unit, controlled light switch, optically connected via an information carrier with a light combiner, and a beam focusing unit, an optical reading unit, a photodetecting unit and a control unit containing a clock generator, the first output of which is connected to the input of the first driver of the control signals, the output of which is connected to the radiation source, the second output of the clock generator is connected to the first input of the address buffer memory, the second input of which is connected to the first output of the input-output channel, output the address buffer drive is connected to the input of the second driver of control signals, the output of which is connected to the beam addressing unit, the third output of the clock generator is connected n to the first input of the information buffer drive, the second input of which is connected to the second output of the input-output channel, the output of the information buffer drive is connected to the input of the third driver of the control signals, the output of which is connected to the control transparency, the fourth output of the clock generator is connected to the first input of the input channel output, the second input of which is connected to the output of the buffer storage device, the first input of which is connected to the fifth output of the clock generator; the second input 'of the buffer storage device is connected to the output of the photodetector unit, the sixth output of the clock generator is connected to the input of the fourth driver of the control signals, the output of which is connected to the input of the photodetector unit, the seventh and eighth _(the outputs of the clock generator are connected to the inputs of the fifth and sixth drivers of the control signals, outputs which are connected respectively to controlled light switches and storage media of each of the information storage units, characterized in that, In order to increase the reliability of the device, a controlled optical valve is inserted into each of the information storage blocks, the storage medium is made in the form of a two-dimensional photosensitive plate with rectangular holes, and the seventh control signal conditioners are introduced into the control unit by the number of information storage blocks, and the controlled light switch through rectangular holes in the photosensitive the plate is connected to a light coupler, the output of which through a controlled optical valve is optically connected to the input home node beam focusing, the ninth clock generator outputs are respectively connected to the inputs of the seventh formers control signals, the outputs of which are connected to the respective controlled optical isolator.