SU701343A1 - Holographic memory - Google Patents

Abstract

1. HOLOGRAPHIC RECORDING-. A NAVIGATING DEVICE containing a coherent radiation source optically coupled through a first beam addressing unit to a first beam-splitting element, the first output of which is optically connected through successively arranged first beam forming unit, a randomizing mask, first controlled transparency, orifice plate, first beam focusing unit and a reversible information carrier with an optical readout unit, the second output of the first light-separating element is optically coupled through the first collimator, rotated the first prism and diffraction grating with a reversible carrier information. the first photodetector array and the control unit, the outputs of which are connected to the first beam addressing unit, the first controlled transparency, the reversible storage medium and the first photodetector matrix, characterized in that, in order to expand the functionality of the device by ensuring the operation in the associative mode of information sampling, A second beam-splitting element, a second beam-forming unit, / a second guided transparency, a second beam focusing unit and a second photo-receiving array, and The second beam-splitting element is optically coupled to the output of the optical readout unit, the first output of the second beam-splitting element is optically coupled to the first photodetector matrix, its second output is optically coupled through successively located second beamforming unit, the second controlled transparency beam and the second beam focusing unit the second photodetector matrix, the output of which is connected to the control unit, the outputs of which are connected to the second controllable transparency and the second beam-splitting element .. 2. A holographic memory device according to claim 1, characterized in that, in order to ensure simultaneous operation of the device in the write, read and erase information modes, a second coherent radiation source, a second beam addressing unit, a second collimator, a second diffraction - to the grid, the third beam focusing unit and the third photodetector array, the coherent radiation source being optically connected through a sequence; - the second beam addressing unit, the second collimator, the reversible information carrier mation and third beam focusing unit with a third photodetector matrix, yield office connected to the control unit, Yield which are connected to the second block o1dresatsii beam. • 3 (Aco oo

Description

The invention relates to the field of computer technology and can be used in systems for operational processing of large amounts of information. Holographic zalomiyakediye devices (memories) are known, containing a radiation source, an addressing system, a recording medium, an optical matrix of photodetectors forming a point source of spherical waves, illuminating the entire or significant area of the recording medium used for recording and reading both useful information and associative nakov and signs of the survey. The main disadvantage of these devices, which impedes their implementation, is the need to illuminate both when recording and when reading large areas of the recording medium. This leads to increased demands on the sensitivity of reverse recording media, photoreceivers and their characteristics, a sharp decrease in device performance and recording density, as well as the possibility of associative search for information pages only. A holographic memory 21 with recording, C4i and erasure is known. The information contains, a radiation source, an address system, forming optics, a controlled transparency, a photodetector matrix, a reversible recording medium and a control device. The disadvantage of this system is the possibility of address processing only. The purpose of the invention is to expand the functionality of the device by ensuring the work in the associative mode of retrieving information and ensuring the simultaneous operation of the device in the modes of writing, reading and erasing information. This goal is achieved in that a holographic memory device containing a coherent radiation source is optically coupled through a first beam addressing unit to a first beam-splitting element, the first output of which is optically connected through sequentially arranged first beam forming unit, a randomizing mask, and a first control transparency, diaphragm mask, the first beam focusing unit and the reversible data carrier with the optical unit reads vania, the second output of the first beam-splitting The element is optically coupled through the first collimator, the rotary prism and the first diffraction grating with a reversible information carrier, the first photodetector matrix and the control unit, the outputs of which are connected to the first beam addressing unit, the first controlled transparency, the reversible information carrier and the first photodetector matrix , a second beam-splitting element, a second beamforming unit, a second controllable transparency, a second focusing-beam unit and a second photodetector array, and the second light input the casing element is optically coupled to the output of the optical readout unit, the first output of the second beam-splitting element is optically coupled to the first photodetector matrix, its second output is optically connected through successively located second beamforming unit, the second controllable transparency and the second beam focusing unit to the second photodetector matrix, the output of which is connected to the control unit, the outputs of which are connected to the second controlled transparency and the second beam-splitting element. In addition, a second coherent radiation source, a second beam addressing unit, a second collimator, and a second diffraction radiation were introduced into the device ;. on the grille, the third focusing unit. the beam and the third photodetector array, the coherent radiation source being optically coupled through successively the second beam addressing unit, the second collimator, the reversible storage medium and the third beam focusing unit with the third photoreceiver matrix, the output of which is connected to the control unit whose outputs are connected to the second unit addressing beam. The drawing shows the optical layout of the proposed device. The device contains a source of coherent radiation 1, a beam addressing unit 2, which gives light beams at the write (ian) wavelength, read (I read) erase and erase) and provide as an arbitrary predetermined addressing of light beams when writing, reading and styling - injuries as well as simultaneous flashing of the entire address raster of light beams during associative processing of information (coherent radiation sources can be, for example, lasers, and electro-optical, for example, can be used as address systems system skanlazer); a beam-splitting element 3, which separates the address beams into the signal channel and the channel of the reference beam, as well as capable of switching the entire light beam only into the channel. the signal beam in the case of associative information processing or in the reference beam when read, collimator 4, turning prism 5 and diffraction grating 6, first beamforming unit 7; a random mask 8 that provides a uniform distribution of light across the field of the hologram; Managed transparency 9, which performs spatio-temporal modulation of a transmitted light beam in accordance with the code intended for recording information, or in accordance with a poll sign in an associative search for information, orifice plate 10, which fixes the position of the input information page. and defining hologram size on reversible storage medium 11; the carrier 11, for example, based on a photovoltaic crystal (e.g., bismuth silicate), on which information is stored in the form of separate hologram pages, for example, in a paraphase code (any suitable medium can be used for reading, reading and erasing the hologram beam focusing unit 12 and optical readout unit 13; photodetector arrays 14, 15 and 16. The matrix 14 registers the set useful information page, the matrix 15 determines the address of the page hologram on p When associating with a search page of information, the matrix 1 determines the address of associative selected words (word blocks). A beam-splitting element 17, for example, a beam splitting prism that is sensitive to the polarization plane or a translucent mirror, separates the optical design into the address (I) channel and associative reading the information page, in which the array of photodetectors 14 and the channel (II) of the associative word search (word block) in the page, in which the mirror 18 is located, is located, the second beamforming unit a 19, a second controllable transparency 20, a second beam focusing unit 21 and a second photocell receiving matrix 16. This element 17 either divides the bundle into two channels, or switches the whole light beam from one channel to another. Managed transparency 20 performs spatio-temporal modulation of the light beam in accordance with the code of the poll sign (word block). The control unit 22 controls writing, reading, erasing with address and associative information processing. In the address processing of information, the device operates as follows 1. In recording mode, radiation source 1 operates at a wavelength. On command from block 22, the light beam by block 2 is set to the position corresponding to the hologram address on the carrier on which; information should be recorded. With the aid of the beam-splitting element 3, the light beam is split into signal and reference beams. The reference beam of the optical system, consisting of a collimator 4, the diffraction grating 6 and the rotary prism 5, is directed to the carrier 11 in the place of the recording of the hologram. The controllable banner 9 displays the code of the recorded information received by the command from block 22 from any external source of information (for example, any type of memory, processor, etc.). The signal beam using beamforming unit 7 is expanded to the size of transparency 9 and then using beam focusing unit 12 illuminates the carrier section corresponding to the hologram address specified by block 2. The interference pattern of the signal and reference beams is the Fourier hologram of the image of the code displayed on the controllable transparency 9. 2. In the information reading mode, the source 1 is operating at the wavelength YassH. According to the command from block 22, the signal beam is blocked and the entire light beam is directed by element 3 a reference beam channel. The light beam illuminates the area of the carrier corresponding to the address of the readable hologram. The reconstructed image with the help of block 13 and the beam-splitting element 17 is directed to the array of photodetectors 14 and is read by it from the block 22. 3. In the hologram erase mode, the source 1 operates at a wavelength, the signal beam from block 22 is blocked, and the erasure is performed by the reference beam. When associative information processing device operates as follows. 1. In the mode of associative search for an information page, source 1 operates at a wavelength. the block 22 highlights the entire address raster of the light beams of block 2, for example, half-wave voltages are applied to all cells of the electro-optical system. Block 22 blocks the channel of the reference beam, and the entire light beam by element 3 is directed to the channel of the signal beam. In cells of a controlled transparency 9 intended for an associative hologram feature, unit 22 displays, for example, the reverse code of a poll feature, the remaining cells are masked. Since block 22 highlights all the address positions of block 2, the code of the interrogation attribute code of the page projects onto all the holograms - carrier pages 11. Angle (ji between any bundles of interrogation signs must be wounded in such a way that conditions (I (1) () .COS20, where I is the wavelength of light, t is the thickness of the reverse carrier, b is between the reference beam and the beams of the sampling pattern, and G is the refractive index. This means that each beam can restore the reference beam only when the condition of coincidence of its direction of falling the log with the direction If the directions of the interrogating light beams do not completely coincide with the Bragg angles for a certain hologram, “i.e., if the beams of the sign code of the interrogation do not match with the beams of the associative sign of the hologram during recording, then the reference beam will not be restored; Therefore, the location of the necessary information is determined by the absence of the image of the recovery reference beam in the cell (cell group) of the array of 15 photodetectors. The address of this photodetector (group of photodetectors) in the matrix. 1 corresponds to the desired hologram address on. the carrier. At the command of block 22, the device is transferred to the address reading mode at the found address described 2. In the associative word search mode (word block) in the information page, block 2 operates in the address read mode. At the command of unit 22 by the light-separating element 17, the installed light beam is directed to channel II. With the help of the second beam forming unit 19, all reconstructed associative features of words (word blocks) are designed and combined on a controllable transparency. 20. At transfer station 20, block 22 displays, for example, the reverse code of the word polling sign (word block). Optical multiplication of a poll tag by associative features of all words (word blocks) of one information page is performed. The resulting light distribution is projected by the second focusing unit of the beam 21 into the plane of the photodetector matrix 16. If one (or several) and associative feature codes of a word (block of words) sovoval with a code of the poll feature, then the total signal received from the corresponding photodetector (group of photodetectors) 16 will be zero. The address of this photodetector (group of photodetectors) corresponds to the desired address of the word (block of words) in the information page. Reading of the I-useful information is therefore possible for the address to be performed by the command of the block 22 by a 14-in. Array of photodetectors. the mode of reading the word (block of words) in the information page. 3. Recording information in the memory can be done in one of the following ways: by address, by sign, with step-by-step distribution, with sorting of information. 4. The erasing of the information page is performed only by the reference beam, while the block 22 blocks the signal beam. The information is erased by the command of the block 22 or by the address of the page, or by its associative feature, while the hologram to be erased is searched for when the device is operated in the associative search mode. A second coherent radiation source 23, a second beam addressing unit 24 at the second collimator 25, consisting of read beam forming lenses, and a differential grating 26 / providing the drop beams on the carrier 11 are used to provide information readout at a wavelength of 51 eep. at an angle of reading different from the angle of incidence of the reference beam when writing to Yaschit / -g.r. Erasure of information in this case can be carried out either by a reference beam or a readout beam. The device works as follows,. The writing and associative search of the page is carried out in the manner described above, and the reading, erasing and associative search of words (blocks of words) is carried out in the ways described below. When address reading or erasing is performed by a command from block 22, the light beam by block 24 is set to the position corresponding to the hologram address intended for reading or erasing. The light beam formed by the collimator 25 is directed by diffraction grating 26 to the hologram and either erases it or restores it, and the element 17 sends the reconstructed image to the photo receivers 14 and is read by it from a command from block 22. In an associative word search (block of words), the image from the selected hologram is directed by element 17 (in this case to element 17, for example, voltage is applied) to channel (II) of associative word search (word block). Work channel (II) described above. When used to read information from block 24, writing and reading can be done simultaneously.

Claims (2)

1. HOLOGRAPHIC REMEMBER-. A CURRENT DEVICE containing a coherent radiation source optically coupled through a first beam addressing unit to a first beam splitter element, the first output of which is optically coupled through sequentially arranged first beam forming unit, randomizing mask, first controllable transparency, iris mask, first beam focusing unit and reversible carrier information with an optical reading unit, the second output of the first beam splitting element is optically coupled through the first collimator, a rotary prism and the first diffraction grating with a reversible information carrier, the first photodetector and a control unit, the outputs of which are connected to the first beam addressing unit, the first controlled transparency, the reverse information carrier and the first photodetector, characterized in that, in order to expand the functionality of the device by ensuring operation in an associative mode of information sampling, a second beam splitting element, a second beam forming unit, are introduced into it ,? a second controlled transparency, a beam focusing unit and a second photodetector, the input of the second beam splitting element being optically coupled to the output of the optical reading unit, the first output of the second beam splitting element being optically coupled to the first photodetector, its second output being optically coupled through the second forming unit beam, a second controlled transparency and a second beam focusing unit with a second photodetector, the output of which is connected to the control unit, in the outputs of which are connected _ with the second controlled transparency -E and the second beam splitting element. 2. Holographic storage device pop. 1, characterized in that, in order to ensure simultaneous operation of the device in the modes of recording, reading and erasing information, a second coherent radiation source, a second beam addressing unit, a second collimator, and a second diffraction grating are introduced into it , a third beam focusing unit and a third photodetector matrix, wherein the coherent radiation source is optically coupled through sequentially arranged second beam addressing unit, a second collimator, a reversible storage medium and a third beam focusing unit with a third th photodetector matrix, the output of the office is connected to a control unit, the outputs of which are connected to the second beam addressing unit.