RU2015580C1 - Optoelectronic logic unit for memorizing device - Google Patents

Abstract

FIELD: computer technology. SUBSTANCE: optoelectronic logic unit has multichannel unit with controlled radiation parameter, light-guide multiplexers and light-guide parametric demultiplexers according to number of channels, multichannel photodetecting unit and control unit. All the basic sixteen Boolean functions may be computed by optical methods. Speed of operation is improved in 100-1000 times as much. EFFECT: improved reliability; compactness. 1 tbl, 3 dwg

Description

 The invention relates to computer technology and can be used in conjunction with storage devices of various types (optoelectronic, electronic, etc.) for the logical processing of information.

 Known optoelectronic converter for optical storage device [1], containing a multi-channel emitting unit, beam forming units, polarizing light detectors, a collimating unit, optically controlled transparency, polarizing beam splitters, polarized controlled transparencies, beam offset unit, correction units, photodetector blocks, controlled switches , polarizing optical valve, reflectors and control unit. The main disadvantages of the converter are relatively low reliability due to the content of a large number of equipment, cumbersomeness, and the inability to calculate all sixteen basic logical Boolean functions.

 Closest to the proposed one is an optoelectronic logic unit for a storage device [2], containing n-channel (n = 1,2,3, ..., N) radiation unit, the controlled input of which is connected to the first output of the control unit, and a photodetector unit whose controlled input is connected to the second output of the control node, the input of which is connected to the output of the n-channel photodetector. The main disadvantages of this unit are relatively low speed and reliability.

 The aim of the invention is to increase the speed and reliability of the block.

 The goal is achieved by the fact that in the optoelectronic logic unit for a storage device containing a multi-channel radiation unit, the control input of which is connected to the first output of the control unit, and a photodetector unit, the control input of which is connected to the second output of the control unit, the input of which is connected to the output of the multi-channel photodetector , according to the number of channels, optical fiber multiplexers and optical fiber parametric demultiplexers are introduced, and the multi-channel radiation unit is made in the form of a multi-channel unit with control radiation parameter, each output of each paraphase emitter of a multichannel parametric emitting node is optically connected to the corresponding input of the corresponding fiber guide multiplexer, the output of which is connected to the input of the corresponding fiber guide parametric demultiplexer, each output of which is optically connected to the corresponding input of the corresponding paraphase photodetector of the multichannel photodetector.

 There are no technical solutions with a set of features similar to the set of distinctive features of the object of the invention. This set of essential features and the relationships between them allows you to get a device with 100-1000 times greater speed and reliability compared with known devices and prototype. Thus, the proposed block has properties that are not inherent in known devices. This is due to a new set of essential features and new relationships.

 In FIG. 1 is a functional diagram of an optical logic unit for a storage device that performs all 16 basic logical Boolean functions; figure 2 is a block diagram of a control node; figure 3 is an optical representation of 16 basic logical Boolean functions in node 1.

 The optoelectronic logic unit contains a multi-channel node 1 with a controlled radiation parameter, optical fiber multiplexers 2, optical fiber parametric demultiplexers 3, multi-channel photodetector 4 and control unit 5 (Fig. 2), which has two groups of inputs 6-1, 6-2 and three groups outputs 7-1. ..7-3 and contains an input-output channel 8, a buffer drive 9, drivers 10, 11 of the control signals, a buffer drive 12.

 A multi-channel unit 1 with a controlled radiation parameter is designed to enter the first page of operands into a logic unit in the form of optical signals (for example, converts input electrical signals to optical) and modulate their parameters (for example, polarization or wavelength) in accordance with the entered operands of the second page. The node 1 can be made, for example, in the form of a matrix of laser diodes with a modulated orientation of the plane of polarization of the output light beams or in the form of a matrix of laser diodes tunable according to the wavelength of the radiation.

 The light guide multiplexer 2 is designed to direct optical signals from each emitter of the pair constituting the paraphase emitter into a single channel. The multiplexer 2 can be made in the form of a fiber optic or integrated optical combiner.

 The fiber guide parametric demultiplexer 3 is designed to separate optical signals according to their parameters, for example, depending on the orientation of their plane of polarization or wavelength. The demultiplexer 3 can be made, for example, in the form of polarizing or spectral splitters, for example, based on alloy couplers of single-mode optical fibers or integrated optical fibers, or corrugated waveguide structures.

 The multi-channel photodetector assembly 4 serves to convert optical signals into electrical ones and can be performed, for example, in the form of an integrated photodetector array.

 The optical logical unit can perform any logical operation out of sixteen listed in the table.

) .Consider the operation of the optical logical unit on the example of the logical operation arrow Pierce (F ₈ =

)

 If the logic unit works in conjunction with an electronic device, then the electrical signals that display the first (A) and second (B) pages of the operands, via bus 6-1 through the input / output channel 8, go to the buffer drive 9. In this case, the Pierce arrow operation by a command coming from the input-output channel 8, the buffer drive 9 through the driver 10 of the control signals supplies, for example, voltage to the multi-channel node 1 with a controlled radiation parameter, which converts the electrical signals into optical ones the first page of operands A, for example, in direct paraphase code, and from the second page of operands B only zero paraphase characters are output. In addition, an auxiliary page (C), consisting only of paraphase units in all digits, is fed to node 1.

According to the electrical signals of page B and auxiliary page C, the parameters of the optical signals displaying page A are changed. For example, the plane of polarization of these signals is switched by 90 ^° or their wavelength is changed.

 The optical signal from each paraphase emitter of node 1 is sent through the corresponding multiplexer 2 to the corresponding demultiplexer 3, which, depending on whether the controlled radiation parameter has changed or not, directs the optical signal through its corresponding branch to the corresponding element of the corresponding paraphase photodetector of node 4.

 Thus, if the controlled parameter of the optical signal in node 1 changes, then the information displayed by it is inverted, otherwise the information does not change (is not inverted).

According to the signal from the input-output channel 8, the former 11 supplies the control voltage to the photodetector 4 and it reads the information corresponding to the logical operation of the pierce arrow (F ₈ ). This information from the node 4 enters the drive 12, from which the signal from channel 8 is output through it to other devices.

 The optical logic block shown in figure 1, can calculate all sixteen Boolean logic functions presented in the table. To do this, on its node 1 displays the information according to figure 3 depending on the calculated function (the shaded area changes the controlled parameter of the optical signal). Moreover, depending on which page of the operands (A or B) the signal controlling the parameters comes from, it has an index of 1 or 2, respectively (the signal of the auxiliary page has no index).

 Using the invention will allow 100-1000 times to increase the speed, reliability and compactness of such devices.

Claims (1)

 OPTO-ELECTRONIC LOGIC UNIT FOR THE REMEMBERING DEVICE, comprising a multi-channel radiation unit, the control input of which is connected to the first output of the control unit, and a multi-channel photodetector unit, the control input of which is connected to the second output of the control unit, the first input of which is connected to the output of the multi-channel photodetector unit, characterized in that, in order to increase the speed and reliability of the unit, optical guide multiplexers and optical guide parametric demultiplexes are introduced into it by the number of channels s, the multichannel radiation unit is made with a controlled radiation parameter, and the outputs of each paraphase emitter of the multichannel node with a controlled radiation parameter are optically connected to the inputs of the corresponding fiber guide multiplexer, the output of which is optically connected to the input of the corresponding fiber guide parametric demultiplexer, the outputs of which are optically connected to the inputs of the corresponding paraphase photodetector multichannel photodetector unit, the second input and the third output of the control unit are They are respectively input and output of the block.

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