RU2664788C1 - Optical-electronic target search and tracking system - Google Patents

Abstract

FIELD: instrument making.SUBSTANCE: invention relates to instrument making, for example, aircraft construction, in particular to the optoelectronic devices designed to search for visible and heat-emitting objects and their tracking in combination with the target indicator-range finder used to provide target designation to weapons and to solve the aiming tasks. Claimed opto-electronic target search and tracking system contains kinematically connected to the gyrostabilizer movable mirror, spectrum splitter, thermal-imaging and television channels forming the discrepancy signal between the system optical axis and the visible or IR target direction, transmitting and receiving laser channels. Terrain scanning in search for the target is carried out using the rotary mirror, which is controlled by the gyrostabilizer and can move in the horizontal and vertical planes. In the terrain survey mode, the rotary mirror is controlled by the operator through the electronic communication, conversion and control unit. With the automatic target tracking, the gyrostabilizer controls the movable mirror according to the signal generated by the electronic communication, conversion and control unit, which is generated as a result of processing information coming from the gyrostabilizer, thermal imaging, television channels and the laser ranging channel. Proportional to the rotary mirror current angles signals are transmitted to the electronic communication, conversion and control unit, which carries out the target search and tracking optic-electronic system communication with the weapons control system.EFFECT: expansion of functional capabilities.1 cl, 1 dwg

Description

The invention relates to instrumentation, for example, to the aircraft industry, in particular to optoelectronic devices designed to search for visible and heat-emitting objects and their accompaniment in combination with a target range finder, used to provide target designation for weapons and solve aiming problems.

Known optoelectronic search and target tracking system described in the patent of the Russian Federation for utility model No. 63520, IPC G01C 3/08, publ. January 10, 2008, containing a movable head mirror mounted on the base and equipped with two drives along two mutually perpendicular axes and angle sensors, an infrared direction finding channel containing a lens and a photodetector that generates a mismatch signal between the optical axis of the system and the direction to the target, an input element for inputting laser radiation from a transmitting laser channel, while the output of the photodetector and the outputs of the angular position sensors are connected to the corresponding input m of the computing-control unit, the corresponding control outputs of which are connected to the drivers of the head mirror and the control input of the transmitting laser channel, and between the head mirror and the lens at an angle to the optical axis there is a fixed flat mirror with an axial hole located along the laser radiation from the transmitting laser channel , the lens is made of two components, between which a diaphragm is installed in the focal plane of the first component along the radiation path, while the infrared DF th channel is simultaneously receiving a laser system channel. But this system has a low resolution. It allows you to determine only the presence or absence of a thermal spot of the target, but not to recognize the target in all details.

The closest is the system described in the patent of the Russian Federation No. 2155323, IPC G01C 3/08, publ. 2003, designed to search for heat-emitting objects. The device comprises a movable mirror with a control device interacting with angle sensors and movable mirror drives, a spectro-splitting filter, an IR channel made in the form of a direction-finding channel, generating a mismatch signal between the optical axis of the system and the direction to the target, as well as transmitting and receiving laser channels. The increase in resolution in this device is achieved by establishing in the direction-finding channel along the optical beam in front of the spherical mirror two corrective lenses and a scanning mirror between them. However, this device does not have sufficient resolution to recognize the image of the IR target and, in addition, this device cannot be used to work with targets in the visible range.

The objective of the invention is to increase manufacturability and expand the functionality of the device.

The technical result of the invention is to increase the functionality by adding a television channel, increasing the resolution of the channels, which allows to detect targets in the visible range and to recognize them in small details in a wide range of external factors, improving manufacturability by facilitating the assembly, adjustment and alignment of products , reducing the dimensions of the laser ranging and television channels due to their work through a single object in.

This is achieved by the fact that in the optical-electronic search and tracking system of a target containing a movable mirror, configured to move along two mutually perpendicular axes using a rotary mirror control device, a spectro splitter located behind the movable mirror, an IR channel generating an error signal between the optical the axis of the IR channel and the direction to the target located in the transmitted rays of the spectrometer and consisting along the beam of the IR lens with corrective lenses and an IR radiation receiver, and the laser transmitting and receiving channels are located in the reflected rays of the spectrometer, and the output of the laser receiving channel is connected to the processing unit of the ranging signal, which in turn is connected to the corresponding input of the control unit, the output of the IR radiation receiver and the outputs of the control device of the rotary mirror are connected to the control unit , the corresponding outputs of which are connected to the control device of the rotary mirror and to the input of the laser transmitting channel, in contrast to the known device is controlled a movable mirror is made in the form of a gyrostabilizer, the control unit is made in the form of an electronic communication, conversion and control unit, in the IR channel, the IR radiation detector is built on the basis of an array photodetector, the IR lens is made of a lens unit with a high degree of resolution, in which corrective lenses are made in in the form of a focusing and scattering lenses located along the beam behind the lens block and made with their drives, while the inputs of the drives are connected to the corresponding inputs of the electronic communication unit, converted control and the output of the laser transmitting channel is directly connected to the spectrometer, in addition, a television channel is added to the system, generating a mismatch signal between the optical axis of the television channel and the direction to the target located in the reflected rays of the spectrometer and made in the form of a high-resolution television a lens, a beam splitting prism and a photodetector made in the form of a matrix photodetector located in the transmitted rays of the beam splitting prism and in the reflected rays of the beam splitting prism there is a laser receiving channel, and the television lens is made common for both the television channel and the laser receiving channel, in addition, the output of the television matrix photodetector of the television channel is connected to the corresponding input of the electronic communication unit, conversion and control, and the electronic communication, conversion and control unit is made with an information input and output to the weapons control system.

The invention is illustrated in the drawing, where the figure shows a block diagram of an optoelectronic search and target tracking system. The system (see the figure) contains a protective glass 1, behind which there is a movable mirror 2, kinematically connected with a rotary mirror control device made in the form of a gyrostabilizer 3, built on the basis of a dynamically tuned gyroscope with a digital discharge and control circuit. Gyrostabilizer 3 is controlled by an electronic communication unit, conversion and control 4 and provides rotation of the mirror 2 along two mutually perpendicular axes, as well as stabilization of its position when exposed to external mechanical disturbances. The angular position of the movable mirror 2 is set remotely by the operator or automatically through the electronic communication, conversion and control unit 4. Information about the current angular position of the mobile mirror 2 is transmitted by the gyrostabilizer 3 to the electronic communication, conversion and control unit 4.

The block of mirrors 5 allows you to optimize the dimensions of the product and directs the reflected optical signal from the movable mirror 2 to a spectrometer made in the form of a spectrodividing plate 6. A spectrodividing plate 6, mounted at an angle to the optical axis of the IR channel, separates the optical signal from the spectra. Part of the optical signal that passed through the spectrodividing plate 6, enters the IR channel - thermal imaging channel 7, structurally made as a separate module. Another part of the optical signal reflected from the spectrodividing plate 6 and from the mirror 8, installed to reduce the size of the system, enters the television channel 9, combined with the laser ranging channel 10, consisting of a laser transmitting channel 11 and a laser receiving channel 12. Moreover, the laser transmitting channel 11 is directly connected through a mirror 8, a spectro-dividing plate 6, a block of mirrors 5 with a movable mirror 2, which reflects laser radiation through a protective glass 1 to the target. The television channel 9 is also structurally made as a separate module. The thermal imaging channel 7 contains, along the beam passing through the beam splitter plate 6, an IR lens, made in the direction of the beam in the form of a high-resolution thermal imaging lens 13, which includes a lens unit 14, a focusing lens 15, moved by a focusing drive 16, a scattering lens 17, installed with the possibility of throwing into a high-resolution thermal imaging lens 13 using a drive 18, as well as an infrared radiation detector made in the form of a thermal imaging photodetector, namely in the form of a matrix photodetector Nick 19. This embodiment of thermal imaging channel 7 can recognize the image of the target. The television channel 9 contains, along the path of the beam reflected from the spectrodividing plate 6, a high-resolution television lens 20, a beam-splitting prism 21, a beam-splitting face of which is installed at an angle to the optical axis of the high-resolution television lens 20, and a television photodetector in the form of a matrix photodetector 22 mounted in transmitted rays a beam-splitting prism 21. In the reflected rays of the beam-splitting prism 21 is a laser receiving channel 10, and the television lens 20 is a common lens for the laser receiving channel 10. The output of the laser receiving channel 10 through the processing unit of the ranging signal 23 is connected to the first input of the control unit, made in the form of an electronic communication unit, conversion and control 4, and the second input of the electronic communication unit, conversion and control 4 is connected to the output of the matrix photodetector 22. The first output of the electronic communication, conversion and control unit 4 is connected to the input of the laser transmitting channel 11.

The movable mirror 2 is kinematically connected with the gyrostabilizer 3, the outputs of which are associated with the third and fourth inputs, respectively, and the inputs, respectively, with the second and third outputs of the electronic unit for communication, conversion and control 4. The fourth and fifth outputs of the electronic unit for communication, conversion and control 4 are connected respectively with a focusing drive 16 of the focusing lens 15 and a drive 18 of the scattering lens 17, and the output of the matrix photodetector 19 is connected to the sixth input of the electronic unit for communication, conversion and control 4. In addition, the electronic communication, conversion and control unit 4 has a fifth information input and a sixth output to the weapon control system.

A movable mirror 2, a gyrostabilizer 3, a block of mirrors 5, a spectro-dividing plate 6, a mirror 8, a thermal imaging channel 7, and also a television channel 9, combined with a laser ranging 10 channel, are installed on a common base, while combining all the optical axes with the required accuracy channels of the optoelectronic search and target tracking system.

The device operates as follows:

In the search mode, viewing the target space is carried out remotely by the operator by turning the course and pitch of the moving mirror 2. In this case, the reflected optical signal from the mirror unit 5 and then passed through the spectrodividing plate 6 enters the thermal imaging channel 7, in which it sequentially passes through the thermal imaging lens 13 into the thermal a matrix photodetector 19, forming a thermal image of IR targets for transmission through an electronic communication unit, conversion and control 4 to the control system is armed iem. The high quality of the thermal imaging image is ensured by the high accuracy of the stabilization of the field of view by the gyrostabilizer 3, which controls the rotary mirror 2, the high characteristics of the thermal imaging lens 13 and the use of a matrix photodetector 19 in the thermal imaging channel. In addition, in the thermal imaging channel 7, the thermal imaging image is corrected with a focusing lens 15 using the drive 16, controlled from an electronic unit for communication, conversion and control 4 according to a special law that takes into account Changing environmental factors negatively affect the operation of the thermal imaging channel 7 and also takes into account the range to target. To adjust image quality, a scattering lens 17 is also intended, which is moved by the drive 18 on command from the electronic communication, conversion and control unit 4 and periodically briefly thrown into the optical path of the thermal imaging channel to improve the quality of the thermal imaging image. Another part of the optical signal reflected from the spectrodividing plate 6 and further from the mirror 8 through the television channel 9, in which it passes sequentially through the high-resolution television lens 20, the beam-splitting prism 21 and enters the television matrix photodetector 22, which forms a television image of targets for transmission via electronic communication unit, conversion and control 4 into an arms control system. The high quality of the television image is ensured by the high accuracy of the stabilization of the field of view by the gyrostabilizer 3, which controls the movable mirror 2, the high characteristics of the television lens 20 and the use of an array photodetector 22 in the television camera. The electronic communication, conversion and control unit 4 transmits mismatch signals between the optical axis to the weapon control system system and direction to the visible and infrared target, formed by television 9 and thermal 7 channels of the system.

In the mode of target designation and ranging, the transmitting laser channel 11 generates laser radiation, which is successively reflected from the mirror 8, the spectrodividing plate 6, the block of mirrors 5 and the moving mirror 2 is emitted into space. The laser signal reflected from the target through the protective glass 1 enters the movable mirror 2, reflected from which, as well as reflected successively from the mirror unit 5, the spectro-dividing plate 6 and the mirror 8, enters the high-resolution television lens 20. After passing through the television lens 20, the signal enters the beam-splitting a prism 21, inside which is reflected from the face and enters the laser receiving channel 10.

Thus, a technical result was achieved, namely, work was provided not only with infrared targets, but also with targets that can be detected only in the visible range, by achieving high resolution, the system allows not only to detect targets, but also to recognize them in small details. The laser ranging channel has a dual function - to measure the range to the target and as a laser illuminator. The use in the thermal imaging channel of focusing and scattering lenses, moved with the help of drives according to a given law, provides high quality thermal imaging images in a wide range of external influencing factors and at different ranges to the target, improving manufacturability is achieved by designing each of the channels in the form of structurally independent modules , which facilitates the process of assembly, adjustment and alignment of products. The reduction in the dimensions of the laser ranging channel is due to the combination with the television channel and the use of a common lens for these channels.

Claims (1)

An optoelectronic target search and tracking system comprising a movable mirror arranged to move along two mutually perpendicular axes using a rotary mirror control device, a spectro-splitter located behind the movable mirror, an IR channel generating an error signal between the optical axis of the IR channel and the direction to a target located in the passing rays of the spectrometer and consisting along the beam of an IR lens with corrective lenses and an IR radiation receiver, and laser transmitters and others the receiver channels are located in the reflected rays of the spectrometer, and the output of the laser receiving channel is connected to the processing unit of the ranging signal, which in turn is connected to the corresponding input of the control unit, the output of the IR radiation receiver and the outputs of the control device of the rotary mirror are connected to the control unit, the corresponding outputs of which are connected to the control device of the rotary mirror and to the input of the laser transmitting channel, characterized in that the control device of the moving mirror it is not possible in the form of a gyrostabilizer, the control unit is made in the form of an electronic communication, conversion and control unit, in the IR channel the IR radiation detector is built on the basis of a photodetector array, the IR lens is made of a lens unit with a high degree of resolution, in which the corrective lenses are made in the form of a focusing and scattering lenses located along the beam behind the lens block and made with their drives, while the inputs of the drives are connected to the corresponding inputs of the electronic unit of communication, conversion and control, and the output the laser transmitting channel is directly connected to the spectrometer, in addition, a television channel is added to the system, which generates a mismatch signal between the optical axis of the television channel and the direction to the target located in the reflected rays of the spectrometer and made along the beam in the form of a high-resolution television lens, a beam splitting prism, and photodetector made in the form of a matrix photodetector located in the transmitted rays of the beam-splitting prism, and in the reflected rays of light There is a laser receiving channel for the prism, and the television lens is common for both the television channel and the laser receiving channel, in addition, the output of the television matrix photodetector of the television channel is connected to the corresponding input of the electronic communication, conversion and control unit, and the electronic communication unit , conversion and control is performed with an information input and output to an arms control system.

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