SU1048491A1 - Optronic device for storing and displaying information - Google Patents

Abstract

1. (WELT-ELECTRONIC STORAGE AND DISPLAY OF INFORMATION DEVICE, containing an archiving drive on holographic microfiches, a reading unit and a writing unit that are connected via an interface unit to the control unit, a display and copying unit, the archive drive on holographic microfixes first and holographic microfiche through the first and the archive unit and the data copying and copying unit, and the archiving drive on the holographic microfixes is the first and the holographic microfiche files through the first and second archives and the data copying and copying unit. Mechanical transport units are connected, respectively, with a read unit and a write unit, so that, in order to increase the reliability and performance of the device, a buffer multichannel drive, an associative drive, a third, fourth and fifth mechanical transpdrtny blocks, the archive storage on holographic files through a third mechanical transport block connected to an associative accumulator connected to the interface block, and through a fourth mechanical transftor block connected to a buffer a multichannel storage device which, via the fifth mechanical transport unit, is connected to a data display and copy unit connected via an interface the unit to the control unit; the buffer multichannel drive is connected to the interface unit. 2. The device according to claim 1, characterized in that the display and copying unit of data contains a set of visualizers by the number of channels in the buffer multichannel storage device (P, each visualizer contains an input node, a processing node, a node, visualization and a data reading node from holographic microfiches, connected to the data processing unit connected to the input node and the visualization node, 3. The device according to paragraphs 1. and 2, about tl. 1. This is due to the fact that the associative accumulator contains a node utflavlenn, holographic storage, photo00 matrix parallel processor, co4; combined with a holographic drive with a parallel optical channel, the interface unit is connected to a holographic drive and a photomatrix parallel processor.

Description

The invention relates to computing technology and can be used for iqjH application data banks, information retrieval and information systems logical systems, automated control systems, archive computers, etc. It is known a static-electronic device; input unit (output unit), readout unit, search engines stored between each other central control unit. In this device, the search and main (archive) information is stored in the form of a hologram on a single Leschacchi medium. that connects the search unit and the readout unit Щ. The disadvantages of the system are the rapid wear of the tape with repeated access to the memory, the lack of autonomous operation of the search blocks Bf for reading the information and the long access time when the device is operated in the collective mode, due to sequential character search and read data. The closest to ii3o6p ' remno is an information processing device, contains an archiving drive on microfiches with means of sounding and cracking data connected to it, an interface unit connected through this recording unit, a reading unit and a control computer, and also means of sampling and microfiche transport between archival memory and reading unit G21, ff F1. Due to the centralized data fan in a single archive storage device and data retrieval by 1FO1 software in a computer, this device also receives a large memory access when the device is operating in the main shared mode. In addition, the operations of changing and correcting the data stored in the archive storage are also performed in the computer, which leads to a high computer load in cases where it is necessary to process the remaining amount of stored data for a limited period of time, therefore the control computer has the required amount of time. must have high speed and large memory. The purpose of the invention is to increase the reliability and performance of the device. The goal is achieved by the fact that the optical storage device for information storage and display, containing the archiving drive on the holographic microfiche, the 1CHitch block and the recording unit connected via the interface block to the control unit, the display and copying unit, data & m archiving drive on holographic microfiches through the first and second mechanical transport blocks are connected respectively to the reading unit and the writing unit, a buffer multi-channel drive, an associative one is introduced the third, fourth and fifth mechanical transport blocks, G5) and the archiving drive on holographic microfiches through the third mechanical transport block is connected with an associative accumulator; connected to the interface unit and through the fourth mechanical transport block to the buffer multichannel an accumulator which, via the fifth mechanical transport unit, is connected to the display and copying unit of data connected via the interface unit to the control unit, is a buffer multichannel storage unit connected yuchen to the interface unit. The display and copying unit contains nabs of visualizers on the number of cacals in a buffer multichannel accumulator, each visualizing unit containing an input unit, a data processing unit, a visualization unit and a data reading unit for holographic microfiches, & to the data processing unit connected to the input unit and the visualization unit The associative drive contains a control holographic nakolitel, a photomatrix parallel processor connected to a parallel optical holographic storage device, and the fertilizer node is connected to the holographic storage of a photomatrix parallel process. The drawing shows a block diagram of a bird-electronic device storing and displaying information. The device contains a block to control 1 associated with the interface block 2, the inputs and outputs of which are connected to the associative drives 3, the read lock 4, the record block 5, the display and copy data locks, to the archive 7 on the holographic microfiches, to the buffer multi-channel drive 8, archive

the drive is connected by transport mexai blocks 9-12, respectively, with an associated drive 3, a read block 4, a write block 5 and a buffer multichannel drive 8 containing L independent ones. TO/,

The accumulator 8 is connected by a transport mechanical unit 13 to a data display and copying unit 6 containing N identical display means O. Each of the data hardening means forming the data hardening and copying unit 6 contains an input unit 14, the output of which is connected to the input of the processing unit 15, Visualization 16, the input of the com- puter is connected, to the output of the 15data processing node, the readout node | 17 of 17 data from the holographic microfiches, connected to the input of the 15data processing node.

The associative accumulator 3 contains a control unit 18 connected to the holographic storage unit 19 and the computer-parallel parallel process H | y 20, which are connected to each other by a unidirectional data transmission channel.

The device works as follows.

In the data recording mode, the control signal I of the control unit 1 is transmitted to the initial coQTOsmHe via interface unit 2i.

Then, through the interface unit 2, information signals (for example, controlled transponder) are transmitted from recording unit 1 to recording unit 5, and then a hologram recording is transmitted to the control unit using the control signal of unit 1. After the hologram module is completely filled, the latter, with the transport mechanism 11, is transferred to the archive storage unit 7.. .

In the mode of reading data on a command coming from control unit 1 of interface unit 2 to read unit 4, a hologram module with necessary information is retrieved from archive storage device 7 using transport mechanical device 10 and then reads data from the hodogram module, for example, by addressing the laser beam to selected holograms and photoelectric

developing holograms of images of binary data pages and transferring them via interface unit 2 to block I.

In the associative search mode by a command from the control unit 1, which enters the associative drive 3 via the interface unit 2 from the archive drive 7, a transport module 9 extracts a hologram module containing descriptions (attributes) and addresses of the necessary subject section and is installed in a holographic storage device 19 ..

Under the influence of the control control signals 18, optical signals containing descriptions (features) of the desired data and their address data 1 are fed to the optical input of the photomatrix parallel processor 20, in which, according to the request signals coming through the node 18, electric signals are generated corresponding to the required information. Then, these signals, via the interface unit, are entered into a 4-unit readout unit in a display unit 6.

In the visualization mode, the signals from the I block of interface 1 to the input of node 14 are generated in the node 15; the node 15 generates the address signals that go to the bob, the node 17 of the data reading from the holographic microfiche. data of the required geographic module (microfiche) from the intermediate archive storage device 8 using the transport mechanical unit 13, which is carried out by signals from the archive storage device 7 by commands received from unit 1 through the command line ysny unit 2 schzichem fovanye Generators command unit 1 is performed based on the signals from node 15 originating in the unit 1 and through the interface unit 2.

After the holographic module is installed in the readout unit 17, the data is read out from the hologram of the hologram group (for example, by addressing the laser beam to the hologram and photoelectric shaping the reconstructed image). From the output of the readout node 17, information signals arrive at the input of the processing node 15, where, under the influence of control signals from node 1, information signals are processed and transmitted to the visualization node 16.

The introduction of new components and structural elements makes it possible to shorten the arrival time. to the information fund of the system and reduce the information load of the computer control unit, control unit, which ultimately ensures parallel simultaneous work of the user team

Claims (3)

1. OPTICAL-ELECTRONIC INFORMATION STORAGE AND DISPLAY DEVICE, comprising an archive storage device on holographic microfiches, a readout unit and a recording unit connected via an interface unit to a control unit, a data display and copying unit, the archived storage device on holographic microfiche through the first and the second mechanical transport blocks are connected, respectively, with the reading unit and the recording unit, which is connected with the fact that, in order to increase the reliability and performance of the device, a multichannel drive, an associative drive, third, fourth and fifth mechanical transport units, the holographic archive microprocessor drive through the third mechanical transport unit connected to an associative drive connected to the interface unit, and through the fourth mechanical transport unit connected to a multi-channel buffer drive, which through the fifth mechanical transport unit is connected to the data display and copy unit connected via the interface unit to the unit control, the buffer channel drive is connected to the interface unit. 2. The device according to π. 1, about t l and I am of the opinion that the display and copying unit for 'data contains' a set of visualizers according to the number of channels in the buffer multichannel drive, and each visualizer contains an input node, a data processing node, and a node. visualization and a node for reading data from holographic microfiche connected to the data processing node connected to the input node and the visualization node. ¹ 3. The device according to paragraphs. 1. and 2, characterized in that the associative storage device contains a control unit, a holographic storage device, a photomatrix parallel processor connected to the holographic storage device by a parallel optical channel, and the control unit is connected to a holographic storage device and a photomatrix parallel processor. ¹ s ί