RU2092913C1 - Optical digital associative multiple-channel correlator - Google Patents

Abstract

FIELD: computer engineering. SUBSTANCE: device has first input buffer unit, unit of time multiplexers, unit of spectral multiplexers, optical splitting unit, unit of optical modulators, second input buffer unit, unit of optical joining, unit of spectral demultiplexers, unit of time demultiplexers, output recording unit. Device provides possibility of associative data search in different devices for large query parameters. EFFECT: increased speed, increased reliability, increased number of features to be processed in parallel, decreased size. 5 cl, 1 dwg

Description

 The invention relates to computer technology and can be used for associative information retrieval in its various devices, for example, storage devices (optoelectronic, electronic, magnetic), databases, processors.

 Closest to the proposed device is a multi-channel associative optical correlator for a storage device [1] comprising an optical multiplication unit, an optical modulator unit, an optical combining unit, a spectral demultiplexer unit and a spectral multiplexer unit, the outputs of which are optically coupled to the inputs of the optical multiplication unit of the same name, the outputs of which optically connected to the inputs of the same block of optical modulators, the outputs of each group of cells of which are optically They are connected to the inputs of the optical unit of the same name, the outputs of which are optically connected to the inputs of the unit of the spectral demultiplexers of the same name and the output recording unit, the output of which is the output of the correlator. The main disadvantages of this device are the relatively low performance and reliability.

 The technical result is to increase productivity, reliability and compactness, as well as simplifying the design of the correlator.

 This is achieved by the fact that into an optical digital associative multi-channel correlator containing an optical propagation unit, an optical modulator unit, an optical combining unit, a spectral demultiplexer unit, a photodetector unit and a spectral multiplexer unit, the outputs of which are optically coupled to the inputs of the optical modulator unit of the same name, the outputs of each group the cells of which are optically coupled to the inputs of the same name of the optical combining unit, the outputs of which are optically coupled to the inputs of the same name the spectral demultiplexers, and the output recording unit, the output of which is the output of the correlator, introduced the first and second input buffer blocks, a block of temporary multiplexers, a block of temporary demultiplexers, the input of the first input buffer block being the first input of the correlator, each group of outputs of the first input buffer block with the inputs of the same name in the corresponding multiplexer block of time multiplexers, the output of which is optically connected with the same input in the block of spectral mules of multiplexers, the second input of the block of optical modulators is connected to the output of the second input buffer block, the input of which is the second input of the correlator, the outputs of the block of spectral demultiplexers are optically connected with the same inputs of the block of temporary demultiplexers, each group of outputs of which is optically connected with the corresponding group of inputs of the output recording block.

 And also by the fact that the block of temporary multiplexers consists of optoelectronic multiplexers, each of which has electrical inputs and an optical output, and the optoelectronic multiplexers are combined into groups.

 And also by the fact that the block of temporary demultiplexers consists of optoelectronic demultiplexers, each of which has an optical input and electrical outputs, and the optoelectronic demultiplexers are combined into groups.

 And also the fact that the block of temporary multiplexers consists of optoelectronic multiplexers, each of which has optical inputs and optical output, moreover, the optoelectronic multiplexers are combined into groups, and the block of temporary demultiplexers consists of optoelectronic demultiplexers, each of which has an optical input and optical outputs, and optoelectronic demultiplexers are combined into groups.

 And also the fact that the first and second input buffer blocks are made in the form of electronic storage devices with optical outputs, and the output recording unit is made in the form of an electronic storage device with optical inputs.

 This set of essential features and the relationships between them allows you to get a device with more than 10-100 times greater speed, the number of simultaneously processed associative features and the characteristics of the survey, reliability, as well as smaller dimensions in comparison with the known devices and prototype.

The essence of the invention lies in the fact that due to the use of spectral and temporal compaction in the device, the requirements for all parameters of optoelectronic units are sharply reduced, including their dimension, which leads to the possibility of a practical increase in the amount of processed information, reliability, simplification of design, and performance ≈10 ¹³ opera / s.

 Thus, the proposed device has properties that are not inherent in known devices. This is due to a new set of essential features and new relationships outlined above.

 Comparison of the proposed device with the known indicates that it meets the criterion of "novelty", and the lack of analogues of the hallmarks of the proposed device according to the criterion of "inventive step".

 The drawing (a and b orthogonal projections) shows a functional diagram of an optical digital associative multi-channel correlator.

 The correlator contains a first input buffer block 1, a block of 2 time multiplexers, a block of 3 spectral multiplexers, a block of 4 optical multiplication, a block of 5 optical modulators, a second input buffer block of 6, a block of optical integration 7, a block of 8 spectral demultiplexers, and an output recording block 10.

 The first input buffer unit 1 is used to receive data (for example, associative features) from external devices, their layout and storage and can be performed, for example, in the form of electronic memory with electrical or optical outputs, depending on the execution of unit 2. In the second case bits of each group of signs are displayed by optical signals with the same wavelength different from the wavelengths of the optical signals, which display the remaining groups of signs in block 1.

 Block 2 time multiplexers is designed for temporary compression of the input channels. Block 2 can be made, for example, in the form of groups of optoelectronic multiplexers, each of which has either electrical inputs and an optical output, or optical inputs and outputs. In the first embodiment, the discharges of all the signs are displayed at the output of each group of multiplexers in the form of optical signals with the same wavelength different from the wavelengths of the optical signals on which the remaining groups of signs are displayed in block 2.

 Block 3 of the spectral multiplexers is designed to combine optical signals with different wavelengths into the corresponding single multi-wave (multi-color) optical signal and can be performed, for example, as a group of fiber optic or integrated optical combiners or as a group of waveguide lenses. Block 3 can also be made in the form of a hologram or from volumetric cylindrical lenses.

 The optical multiplication unit 4 is intended for propagating a multi-wave (multi-color) optical signal and can be performed, for example, as a group of fiber optic or integrated optical splitters, or as a group of waveguide lenses, or as a hologram.

 Block 5 of optical modulators is designed to display, for example, signs of interrogation, and can be performed, for example, in an integrated form based on an electro-optical crystal.

 The second input buffer unit 6 is used to receive data (for example, signs of interrogation) from external devices, their layout and storage and can be performed, for example, in the form of electronic memory.

 The optical combining unit 7 is intended for combining multiwave (multi-color) optical signals corresponding to different bits of each feature into a single multi-wave (multi-color) optical signal, each of which corresponds to a specific feature. Block 7 can be made, for example, in the form of a group of fiber-optic or integrally-optical combiners, or in the form of a group of integrated lenses, or in the form of a hologram or volumetric cylindrical lenses.

 Block 8 of spectral demultiplexers is designed to separate a multi-wave (multi-color) optical signal into its component single-wave (single-color) signals, and can be performed, for example, on the basis of a group of fused couplers from single-mode optical fibers or integrated optical fibers, or corrugated waveguide structures, or based on diffraction gratings or holograms.

 Block 9 temporary demultiplexers is designed for temporary decompression of the output channels. Block 9 can be performed, for example, in the form of groups of optoelectronic modules of demultiplexers, each of which has either an optical input and electrical outputs, or optical inputs and outputs.

 The output recording unit 10 serves to determine the coincidence of associative signs with the signs of farrowing their layout and storage and can be performed, for example, in the form of electronic memory or an integrated array of photodetectors coupled to electronic memory.

 Optical digital associative multi-channel correlator operates as follows.

Associative features of the data are fed, for example, to input 1 and through the first input buffer unit 1 are supplied to block 2 of time multiplexers, which temporarily compresses the signals displaying the signs. Block 2 transmits, with time division, every nth (where n = 1,2,3.N, and N is the number of multiplexers in the column of block 2) a group consisting of m (where m = 1,2,3, M, M the maximum number of inputs of each multiplexer of a block 2) associative features, each of which is present on a separate mth row of inputs of the nth row (line) of multiplexers per corresponding one nth row of their outputs nth row of outputs of block 2. Thus , each nth group of m associative features at the input of block 2 corresponds to one nth line of optical signals at its output. This line of signals displays on the nth output of block 2 all pth (where p = 1,2,3, S, S is the maximum number of bits in the mth characteristic of the nth group) bits of the nth group of signs on one and the same wavelength λ _n , different from the wavelengths at which the remaining (n-1) th groups of features are displayed.

These optical signals display associative features, for example, either in the Reed-Muller code, between the binary characters of which are represented in the direct paraphase code, the reference bits are located in the simple code [1] or in the Reed-Muller code, the binary characters of which are represented in the direct code Manchester followed by a reference signal in time. The reference signal in the latter case is formed, for example, when all the radiating elements of block 2, which display all the bits of each group of associative features, emit light, i.e. display "1" in simple code [1]
Input K receives K (where K = 1,2,3, Z, Z is the number of lines in block 5 of optical modulators) of the polling signs, for example, or in the Reed-Muller code, between the binary signs of which are represented in the inverse paraphase code, reference bits in a simple code [1] or in a Reed-Muller code, the binary signs of which are represented in the reverse Manchester code, with a time-separated reference signal. At the same time, each Kth polling attribute occupies, for example, the corresponding Kth row of block 5, and when a reference signal is supplied, each Kth row of block 5 remains open, for example, only one cell (the rest are closed), i.e. in each line of block 5, only one binary "1" is displayed, the remaining "0", all in simple code.

 Below we will describe the operation of the correlator in the case of using the second encoding method.

 Optical signals displaying the same p-discharges of all n-th groups of associative features are combined by the corresponding multiplexers of a block of 3 spectral multiplexers into single n-color optical signals. The optical propagation unit 4 multiplies these optical signals into K rows of identical beams, which are sent to all cells of the optical modulator unit 5, displaying the pth digits of all K polling attributes.

 Since optical signals displaying the same pth binary bits of all nm associative features at different wavelengths and during time compression, pass through all the cells of block 5 that display the corresponding pth bits of all K polling features, optical multiplication of all nm associative features for all K survey features, and the optical signals of the products are spectrally and temporally separated.

 Multicolor optical signals corresponding to all p bits of each Kth polling attribute are combined by the optical combining unit 7 into a single signal, which is supplied to the spectral demultiplexer unit 8. Block 8 directs each n-th spectral component of the multicolor optical signal to the corresponding input of block 9 of temporary demultiplexers, which directs each m-th time component of the signal to the corresponding nmKth input of the output recording block 10. Moreover, block 10 at its input with coordinates nmK registers an optical signal corresponding to the nmth associative feature and the Kth feature of the survey. The coordinates n, m and K of the input of block 10, on which the signal from the optical reference signal exceeds the signal from the optical signal of the main discharges, determine the nmth associative sign and the Kth sign of the survey, according to which a coincidence occurs. The address code of this nmKth input is also output to the correlator output. In this way, the address of the associative attribute in the array of associative attributes and the address of the interrogation attribute in the array of interrogation characteristics by which the match is determined are determined.

 Using the proposed optical digital associative multi-channel correlator will allow more than 10-100 times to increase productivity, reliability, the number of simultaneously processed features and the compactness of such devices.

Claims (4)

 1. An optical digital associative multi-channel correlator comprising an optical propagation unit, an optical modulator unit, an optical combining unit, a spectral demultiplexer unit and a spectral multiplexer unit, the outputs of which are optically coupled to the inputs of the optical multiplication unit, the outputs of which are optically coupled to the inputs of the same unit of optical modulators , the outputs of each group of cells of which are optically coupled to the inputs of the same unit of the optical association, the outputs of which o optically connected with the same inputs of the block of spectral demultiplexers, and an output recording unit, the output of which is the output of the correlator, characterized in that the first and second input buffer blocks, a block of temporary multiplexers, a block of temporary demultiplexers are introduced into the correlator, the input of the first input buffer block being the first input of the correlator, each group of outputs of the first input buffer block is associated with the same inputs of the corresponding multiplexer block of time multiplexes a ditch whose output is optically connected to the input of the block of spectral multiplexers, the second input of the block of optical modulators is connected to the output of the second input buffer block, the input of which is the second input of the correlator, the outputs of the block of spectral demultiplexers are optically connected to the same inputs of the block of temporary demultiplexers, each group of outputs of which optically connected to the corresponding group of inputs of the output recording unit.  2. The correlator according to claim 1, characterized in that the block of temporary multiplexers consists of optoelectronic multiplexers, each of which has electrical inputs and an optical output, and the optoelectronic multiplexers are combined into groups.  3. The correlator according to claim 1, characterized in that the block of temporary demultiplexers consists of optoelectronic demultiplexers, each of which has an optical input and electrical outputs, and the optoelectronic demultiplexers are combined into groups. 4. The correlator according to claim 1, characterized in that the block of temporary multiplexers consists of optoelectronic multiplexers, each of which has optical inputs and an optical output, wherein the optoelectronic multiplexers are combined into groups, and the block of temporary demultiplexers consists of optoelectronic demultiplexers, each of which has optical input and optical outputs, the optoelectronic demultiplexers being combined into groups
5. The correlator according to claim 1, characterized in that the first and second input buffer blocks are made in the form of electronic storage devices with optical outputs, and the output recording unit is made in the form of an electronic storage device with optical inputs.