RU2469368C1 - Multichannel integrated electro-optical conversion unit - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: multichannel integrated electro-optical conversion unit has a focal plane unit on which there are two rows of photosensitive CCD arrays arranged in checkered order and electrically connected to clock power cells mounted on two sides of a frame, cells for analogue-to-digital processing packaging video signals, whose inputs are connected to the register outputs of the photosensitive CCD arrays, and main and backup cells for controlling the unit. The main and backup cells for controlling the unit lie on opposite sides of the frame with mutual overlapping and are electrically connected in the central area of the frame.

EFFECT: cutting the length and number of inter-cell connections.

7 cl, 6 dwg

Description

The invention relates to optical-electronic systems for remote sensing of the underlying surface, in particular to airborne optical complexes for remote sensing of the Earth (RS) of spacecraft, and can be used in on-board remote sensing systems of the underlying surface.

Known multichannel block of optical-electronic conversion (OED) of the HiRISE device of the spacecraft for the study of the Martian surface, containing a focal plane assembly with two rows of charge-coupled photodetector arrays mounted on it in a checkerboard pattern, connected via wire harnesses and detachable connections to a separate electronic unit designed for clock power FPSS matrices, processing and packaging of video information [1].

The disadvantage of this multichannel optoelectronic conversion unit is that the clock power management functions of the FPGA matrices and digital processing and packaging of video information are performed by a separate electronic unit, which leads to an increase in the size and weight of the optoelectronic system.

A multi-channel optical-electronic conversion unit is known, comprising a focal plane assembly with staggered two rows of FPGA matrices electrically connected to clock power cells and analog-to-digital processing and pixel-by-pixel video compression cells installed on both sides of the main frame of the block, and with power control unit blocks installed on the main frame of the unit outside the limits of the photo zone of the unit, and power filter cells installed on the additional frame of the unit Nia cells and output transmitters, wherein the additional unit frame is mechanically coupled to the base frame unit and is its continuation, and all external connectors installed in the end part of the additional unit frame [2].

The disadvantage of this multichannel optoelectronic conversion unit is the incomplete processing of video information associated with the transfer of pixel-multiplexed streams of video information to secondary digital processing units, while most of the digital processing and packaging functions are performed outside the optoelectronic conversion unit, in video compression and compression units, and the multichannel optoelectronic conversion unit itself is not a functionally complete device of the system. This leads to a large number of inter-unit communication line transmitters, large block sizes and mass, a significant number of intercell and external connectors, in addition, the entire inter-cell and inter-block installation is made by wire harnesses, which leads to a large manufacturing complexity and large overall dimensions and mass of the blocks and the complex ERS onboard equipment as a whole.

The closest in technical essence to the present invention is, taken as a prototype, a multi-channel integrated optical-electronic conversion unit containing a focal plane assembly with two rows of FPSS arrays mounted on it in a checkerboard pattern, electrically connected to clock cells and analog-digital cells processing and packaging of video signals installed on both sides of the main frame of the unit, the main and backup control unit of the unit installed on the main frame of the unit beyond dimensions of the unit’s photozone and installed on the additional frame of the unit’s power supply filter cell, all intercell connections are made by wire harnesses, and the additional frame of the unit is mechanically connected to the main frame and is its continuation, and all external connectors are installed on the additional frame in its end part opposite to the unit of the photozone of the block and parallel to it [3].

This unit has large overall dimensions and weight, due to the presence of an additional frame detachable during adjustment of the unit with power supply filter cells and external connectors installed on it, as well as a significant length of wire bundles of intercellular communication lines due to the location of control cells on the main frame outside of the photo zone block, which leads to an increase in the number of intercellular connectors of the multichannel integrated block of optoelectronic conversion and a tween increase in the complexity of its manufacture, installation and adjustment of the unit.

The aim of the invention is to simplify the manufacturing technology of a multi-channel block of optical-electronic conversion, reducing the length of the intercellular communication lines in the block, reducing its mass, volume and increasing reliability.

This goal is achieved by the fact that in the well-known multichannel integrated optical-electronic conversion unit containing a focal plane assembly with two rows of FPSS arrays mounted on it in a checkerboard pattern, electrically connected to clock cells installed on both sides of the frame, analog-to-digital processing cells and packaging of video signals, the inputs of which are connected to the register outputs of the FPGA matrices, the main and backup control unit cells are located on opposite sides of the frame with mutual by interlocking and electrical connections in the central zone of the frame, intercellular communications are performed through pairs of connectors installed on the main and backup control units of the unit from the side of the frame, while one connector from the pair can be a plug, and the second outlet, electrical connections between control cells and clock cells power can be supplied through additionally entered pairs of intercell connectors installed on control cells and clock power cells, and electrical connections between clock cells power and analog-to-digital processing of video signals can be carried out through additionally entered pairs of intercell connectors installed on clock cells and analog-to-digital processing of video signals, all electrical connections between control cells and cells of analog-to-digital processing and packaging of video signals can be through pairs of connectors the corresponding clock power cells, and the external connections of the cells of the multichannel block of optoelectronic conversion can through connectors located on opposite side end surfaces of the block perpendicular to its frame, and the elements of the output information transmission lines can be made of fiber optic. In addition, the cells of the analog-to-digital processing and packaging of video signals can be combined into one cell with the clock power cells.

The application of the proposed multichannel integrated optical-electronic conversion unit allows to simplify its manufacturing technology, reduce the length of intercellular communication lines, reduce the mass and volume and increase the reliability of the multichannel optical-electronic conversion unit. In addition, combining the FPSS matrix clock power cell with the analog-to-digital video processing cell into one cell makes it possible to rationally use the focal plane of the optical system of the DZZ airborne complex, while retaining the functionality of the multi-channel integrated optical-electronic conversion unit.

The invention is illustrated by drawings.

Figure 1 shows the location of the node of the focal plane 1 with two rows of FPSS matrices 2 and 3 installed on it in a checkerboard pattern relative to frame 4 with the main 7 and backup 8 signal control and switching cells, clock power cells 5 and cells of analog-to-digital processing and packaging of video signals 6 of the proposed multichannel integrated optical-electronic conversion unit; figure 2 shows the location of the cells of the proposed multichannel integrated optical-electronic conversion unit on its frame; figure 3 is a structural diagram of the proposed multichannel integrated unit of optoelectronic conversion; figure 4 shows a variant of the layout of the multi-channel integrated optical-electronic conversion unit with combining the clock power cell and the cell for analog-to-digital processing and packaging of video signals into one cell, combining the cells of analog-to-digital processing of video signals with clock power cells; figure 5 shows a structural diagram of a multi-channel integrated block of optoelectronic conversion corresponding to the layout of figure 4; figure 6 shows the appearance of a multi-channel integrated optical-electronic conversion unit.

The numbers in figures 1–6 show the following elements of the multichannel integrated optical-electronic conversion unit: 1 - node of the focal plane; 2 - FPSS matrix of odd series; 3 - FPSS matrix of an even row; 4 - a frame of a multichannel integrated unit of optoelectronic conversion (OEP); 5 - cell clock power (TP); 6 - cell analog-to-digital processing and packaging of video signals (TOS - signal processing path); 7 - the main cell control and switching signals (UPRK-O); 8 - redundant cell control and switching signals (UPRK-R); 9 - the central zone of the block; 10 and 11 - intercellular pairs of connectors of the cells UPRK-O and UPRK-R; 12 - intercellular pairs of connectors of the cells UPRK-O and UPRK-R with cells TP; 13 - intercellular pairs of connectors of cells TP and TOS; 14 and 15 - lateral end surfaces of the OEP block; 16 - pairs of connectors of cells TP with matrices FPSS; 17 - pairs of connectors of TOC cells with FPGA matrices; 18 - power circuits (PIT.), 19 - control circuits (UPR.) And 20 - technological circuits (TECHN.) Of the UPRK-O cell with external connectors installed on the side end surface 14 of the multichannel integrated OEP block; 21 - power circuits (PIT.), 22 - control circuits (UPR.) And 23 - technological (TECHN.) Circuits of the UPRK-R cell with external connectors installed on the lateral end surface 15 of the multichannel integrated OEP block, respectively; 24 - power supply circuit of TP2 cells, 25 - power supply circuit of TP1 cells, 26 - power supply circuit of TP4 cells and 27 - power supply circuit of TP3 cells; 28 - the main circuit of the information transmission lines (LPI-O) and 29 - the backup circuit of the information transmission lines (LPI-R) of the TOC cells of the OEP block; 30 - a cell that combines the functions of cells TP and TOS (TP-TOS); 31 - power circuit of the combined cells TP-TOS; 32 - pairs of connectors of TP-TOS cells with FPSS matrices 2 and 33 - pairs of connectors of cells TP-TOS with FPSS matrices 3; 34 - protective glass FPSS matrices; 35 - casing of a multichannel integrated block of OEP.

As can be seen from the figures, the multichannel integrated optical-electronic conversion unit (see Fig. 1) contains a focal plane node 1 with two rows of FPSS matrices 2 and 3 mounted on it in a checkerboard pattern, electrically connected with 4 cells installed on both sides of the frame clock power 5 and cells of analog-digital processing and packaging of video signals 6, the main 7 and backup 8 cell control unit. In contrast to the prototype, the unit control cells are located on opposite sides of the frame, with their mutual overlap and electrical connections in the central zone of the frame 9. Moreover, the intercellular communications of the main and backup unit cells are made through pairs of connectors 10 and 11 installed on the side of the unit control cells the location of the frame, and in order to unify the cells of the UPRK-O and UPRK-R, one of the pair of connectors installed on each of the cells is a plug and the second outlet. Electrical connections between the control cells and the clock power cells are carried out through additionally introduced mezzanine connectors 12 mounted on the control cells and clock power cells. Electrical connections between the clock power cells 5 and the analog-to-digital video processing cells 6 are carried out through the additionally introduced intercell mezzanine connectors 13 installed on the clock power cells and the analog-to-digital video processing cells. Moreover, all the electrical connections between the control unit 7 and 8 and the cells of the analog-digital processing and packaging of the video signals 6 are carried out through the connectors 12 and 13 of their corresponding clock power cells 5. In this case, all external communications of the unit cells are made through the connectors located on opposite side end surfaces of the block 14 and 15, perpendicular to its frame 4.

Due to the described arrangement of control cells of unit 7 and 8 and their pairs of connectors 10 and 11, as well as the introduction of intercellular mezzanine connectors installed on TP and TOS cells, it became possible to completely eliminate wired intercell installation in multichannel integrated optical-electronic conversion units. This arrangement of control units of blocks 7 and 8, interconnected via pairs of connectors 10 and 11, made it possible to expand their functionality by using the control cells of block 7 and 8 in addition as cross-circuit boards for the mutual switching of all main and backup control circuits, clock power circuits in the block and other intercellular communication lines. In turn, on each of the control cells of the unit 7 and 8 installed on different sides of the frame 4, additional mezzanine connectors 12 are installed that directly connect them to each of the clock power cells 5 located on this side of the frame 4 of the multi-channel integrated optical-electronic conversion unit . At the same time, the cells of analog-digital processing and packaging of video signals 6 located above the clock power cells 5 are also connected through additional mezzanine connectors 13 with their corresponding clock power cells 5. This ensures the transmission of control signals transmitted from control and switching cells 7 and 8 through their corresponding clock power cells 5 to the cells of analog-to-digital processing and packaging of video signals 6 with minimal time delays. Thus, the arrangement of cells and communication circuits implemented in the blocks of optoelectronic conversion made it possible to realize the advantages claimed for the purpose of the invention. In order to unify the main 7 and standby 8 control unit cells, one of the pair of connectors 10 and 11 on each of control units 7 and 8 is a plug, and the second outlet. The installation of all the external connectors of the optoelectronic conversion unit on its opposite lateral end surfaces 14 and 15, perpendicular to its frame 4, reduces the length of the connections of the corresponding cells 7, 8, 5 and 6 with the external connectors of the block. In order to reduce the width of the focal plane of the block of the cell of analog-to-digital processing of video signals 6 and the clock power cells 5 can be combined into one cell TP-TOS 30 (see figure 4), which allows more rational use of the focal plane of the optical system of the onboard remote sensing system for by reducing the thickness of the multichannel integrated block of the OEP. At the same time, the total number of intercellular connections of the multichannel integrated unit of the OEP is significantly reduced, and the electrical connections of the TP-TOS cells with the FPSS matrices 2 and 3 are connected through connectors 32 and 33, respectively.

Information sources

1.http: //marsoweb.nas.nasa.gov/hirise

Imaging Mars at High Resolution. Grades 4-8 Teacher's Guide Written and developed by: Alexandra Davatzes and Virginia Gulick NASA Ames Research Center Mail Stop 239-20 Moffett Field, CA 94035.

2. Kuzmichev A.M. “Digital processing of video information in a system for receiving and converting an image of a spacecraft RS“ Resource-DK ”. The principles of building the subsystem of digital processing and packaging of video information ”// Transactions of NIIR: Sat. Art. - M .: NIIR. 2008. No2. - S.60-65.

3. Kuzmichev A.M., Zhevako VV, Rakhimyanov A.S. Improving the structure of building digital processing of video information in SPPI KA remote sensing. // V Scientific and Technical Conference “Earth Observation, Monitoring and Remote Sensing Systems”. - M.: MNTORES them. A.S. Popova. - 2008. - S.113-121.

Claims (7)

1. A multichannel integrated optical-electronic conversion unit containing a focal plane assembly with two rows of FPGAs mounted on it in a checkerboard pattern, electrically connected to clock power cells installed on both sides of the frame, analog-to-digital processing and video signal packaging cells, the inputs of which connected to the register outputs of the FPGA matrices, and the main and backup control unit cells, characterized in that the primary and backup control unit cells are located on opposite sides n frames with mutual overlap and electrical connections to the central frame area. 2. The multichannel integrated optical-electronic conversion unit according to claim 1, characterized in that the intercellular communications are made through pairs of connectors installed on the control units of the unit from the side of the frame, one connector of the pair being a plug and the other a socket. 3. The multi-channel integrated optical-electronic conversion unit according to claim 1, characterized in that the electrical connections between the control cells and the clock power cells are carried out through additionally entered pairs of intercell connectors installed on the control cells and clock power cells. 4. The multichannel integrated optical-electronic conversion unit according to claim 1, characterized in that the electrical connections between the clock power cells and the analog-to-digital video processing cells are carried out through additionally introduced pairs of intercell connectors installed on the clock power cells and the analog-digital processing cells video signals. 5. The multi-channel integrated optical-electronic conversion unit according to claim 1, characterized in that all the electrical connections between the control cells and the cells for analog-to-digital processing and packaging of video signals are carried out through pairs of connectors with their corresponding clock power cells. 6. The multichannel integrated optical-electronic conversion unit according to claim 1, characterized in that the external connections of the unit cells are made through connectors located from opposite side end surfaces of the unit perpendicular to its frame. 7. The multi-channel integrated optical-electronic conversion unit according to claim 3, characterized in that the analog-to-digital video processing cell is combined into one cell with a clock power cell.

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