RU2396573C2 - Electro-optical sighting system - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: electro-optical sighting system has a cowling, a scanning mirror with angle sensors and drives connected to the scanning mirror control unit, and a dichroic mirror, a heat source direction finding channel which includes an optical system with a photodetector connected to a video image processing unit, a laser channel with an optical system which includes a component which optically couples the transmitting and receiving laser channels fitted with an emitter and a photodetector respectively, connected to a laser digital processing unit, as well as a computer unit. Optical systems of the heat source direction finding and laser channels are made in form of two links and are fitted with deflectors, each connected to control units of their mirrors, connected to the control unit of the scanning mirror and the computer unit. The mirror of the deflector of the heat source direction finding channel is fitted in the interface plane of the exit pupil of the first link and the entrance pupil of the second link of its optical system. The mirror of the deflector of the laser channel is fitted in the plane of the exit pupil of the first link of its optical system.

EFFECT: increased amount of received information.

5 dwg

Description

The invention relates to the field of instrumentation, and more precisely, to optoelectronic devices, and is intended to search for objects by infrared radiation, to track detected objects, to obtain information used to aim various types of weapons and can be used in aviation, simulator and other technical fields .

The well-known target search and tracking system with a receiver of infrared radiation of the target and a laser range finder, described in US patent No. 3644043 from 02.22.72, class. 356-5. This system contains a movable mirror with drives and angle sensors mounted on mutually perpendicular axes, a heat direction finding channel, consisting of an optical system in the form of two spherical mirrors forming a telescope, and an IR receiver, a reflector and a laser channel, as well as a dichroic filter designed to separate IR energy from laser radiation.

The disadvantage of this system is the use of complex technological processes due to the impossibility of separate production and operation of channels, because The processing of the signal reflected from the target, consisting of IR and laser radiation, is carried out by common elements - focusing mirrors and a spectral filter.

Also known optical-electronic search and target tracking system according to the patent of the Russian Federation No. 2155323, G01C 3/08, G01B 11/26, F416G 3/06, published 27.08.00. This system contains a fairing, a scanning unit, including a movable mirror with azimuth and elevation drives and angle sensors, a spectro-splitting filter installed along the optical beam behind the movable mirror at an angle to the optical axis of the system, a direction finding (heat direction finding) channel that generates a mismatch signal between optical axis of the system and direction to the target, consisting of a receiving lens in the form of a spherical mirror, configured to compensate for the reversal of the image scanning ala modulator with functions, the lens and photodetector, a laser rangefinder, comprising an optical device optically coupled through prism laser transmitting and receiving channels, respectively provided with the emitter and the photodetector, and information-calculation unit.

The presence of a common movable scanning mirror allows you to optically combine the line of sight of all channels in the space of objects. The spectrum of the received radiation in the optical system of the product is divided into independent channels, providing a modular implementation of each of them. However, this device does not provide increased requirements for the characteristics of the fields of view and the volume issued in the viewing and tracking modes for the effective solution of survey and sighting tasks.

The closest set of essential features with the claimed invention is an aviation optical-electronic aiming system (see UA patent No. 65393, F41G 7/26, published March 15, 2004), which contains a cowl, a scanning mirror with electromechanical tracking drives, including a unit control of the scanning mirror, and the sensors of the angle of rotation of the scanning mirror in azimuth and elevation, a system of distribution mirrors (or, for example, a dichroic mirror), directing part of the energy flow to the survey-tracking teplopelengator minutes (teplopelengatsionny channel), and another portion to the laser channel consisting of receiving and transmitting parts. When making distribution mirrors in the form of a system, a mirror directing the energy flow into the heat direction finding channel is movable to correct for the non-parallelism of the optical axes of the heat direction finding and laser channels. In this case, the heat-detecting channel includes an optical system with a photodetector connected to a video processing unit connected to a computing unit and a scanning mirror control unit, and the laser channel with an optical system includes a component that optically mates the transmitting and receiving laser channels equipped with an emitter and a photodetector, respectively connected to a digital processing laser unit connected to the computing unit. In addition, the aviation optical-electronic aiming system in the form of an independent unit includes a helmet-mounted target designation and indication system, which determines, issues the angular coordinates of the line of sight in the coordinate system of the aircraft to the on-board information-measuring system, and forms sighting information in the pilot’s field of view.

The disadvantages of this technical solution include the fact that although the field of view is viewed in the field of view, and the coordinates of all detected targets are transmitted to the information management system, but when the system enters the tracking mode, tracking is carried out for only one purpose, and in this mode the field vision does not exceed several degrees. Range-finding in such devices is only possible in tracking mode, as there is no control over the line of sight of the laser range finder (laser channel) within the instantaneous field of the heat-direction finding channel.

It is obvious that in the overview mode with incomplete information about the targets (only coordinates without range) it is impossible to determine a more dangerous target for transmitting it for tracking.

The objective of the claimed device is the creation of an optoelectronic sighting system that provides a combination of a viewing mode and a dual-loop tracking mode, in which it is possible to obtain not only complete information (angular coordinates and range) about all targets in any field of view, but also achieve an increase in the range of ranging.

The technical result of such a device is expressed in increasing the amount of information received, detecting infrared objects from all targets, identifying the most dangerous (close) targets from a large field of view, pointing guided weapons at several targets at the same time, increasing the maximum distance to determine the distance to the object, and increasing reliability its definitions.

The indicated technical effect is achieved by the fact that in an optoelectronic sighting system comprising a cowl, a scanning mirror with angle sensors and actuators associated with a scanning mirror control unit, and a dichroic mirror, a heat direction finding channel, including an optical system with a photodetector and a unit associated with it video processing, a laser channel with an optical system, including a component that optically mates the transmitting and receiving laser channels, equipped respectively with an emitter and the receiving device connected to the digital processing unit, as well as the computing unit, the optical systems of the heat direction finding and laser channels are made in the form of two links and are equipped with a deflector, each of which is connected to the control unit for their mirrors connected to the control unit for the scanning mirror and the computing unit, the mirror of the deflector of the heat direction finding channel is installed in the plane of conjugation of the exit pupil of the first link and the entrance pupil of the second link of its optical system, and the mirrors A laser channel deflector is installed in the plane of the exit pupil of the first link of its optical system.

A causal relationship between the achieved technical result and the totality of essential features is due to the introduction of new structural elements, their location and relationship. Thanks to these signs, the scanning mirror and deflector mirrors are synchronized, in which:

- the scanning mirror forms the direction of the line of sight, making a circular or reciprocating movement (in the review mode);

- the mirror of the deflector of the heat direction finding channel shifts the line of sight in two mutually perpendicular directions with small deflection angles, compensating for both the image shift along the scanning direction and the image rotation synchronously with the scanning mirror turning around the Y axis, thereby ensuring the required exposure time;

- the mirror of the laser channel deflector compensates for a dynamic error exceeding the divergence of the laser rangefinder beam that occurs during tracking of the object by shifting the mirror of the laser channel deflector in the direction of the tracked object.

In addition, the low inertia of the deflector mirror allows it to be transferred for the purpose of sequentially bypassing and ranging several targets located in the field of view of the heat finder.

The essence of the proposed technical solution is illustrated by drawings:

figure 1 schematically depicts a functional diagram of the invention;

figure 2 presents an example 1 of the optical system of the heat direction finding channel;

figure 3 presents an example 2 of the optical system of the heat direction finding channel;

figure 4 shows an example 3 of the optical system of the laser channel;

in FIG. 5 shows an example 4 embodiment of an optical system of a laser channel.

Optoelectronic sighting system (figure 1) contains: fairing 1 - transparent for thermal and laser radiation, a scanning mirror 2, mounted in a biaxial gimbal, equipped with sensors for the rotation angles of the scanning mirror 2 in the azimuth and elevation planes 3-3 'and electromechanical tracking (azimuthal and elevation) drives 4-4 ', electrically connected to the control unit 5 by a scanning mirror 2, as well as a dichroic mirror 6, which operates on transmission and reflection, a heat direction finding channel 7, receiving and The transmitting laser channel 8 and the control unit 9 of the deflector mirrors of channels 7, 8, connected to the computing unit 10, which collects, processes, and issues information about all direction finding targets, controls the components of the device in all modes, connected to the control unit 5 by the scanning mirror 2.

The heat direction finding channel 7 consists of an optical system made of two links 11-12 (or 11 and 12-12 ', if the device will operate in a wide spectral range), between which is placed a mirror of the deflector 13, installed, for example, in an independent torsion suspension, which the magnetic coils are deployed, or in a biaxial gimbal with angle sensors 14-14 'and drives 15-15' connected to the control unit 9 of the deflector mirrors, a photodetector 16 (or 16-16 ') and a video processing unit 17, connected a control unit of a scanning mirror 5 and a computing unit 10. Furthermore, in the channel 7 includes teplopelengatsionnogo constructive element - spektrodelitelnoe mirror 18 (or mirror 18 and spektrodelitelnoe constructive mirror 18 ').

The receiving and transmitting laser channel 8 has two parts: a receiving and transmitting, which include an optical system made in the form of two links. Moreover, the first link (telescopic nozzle) 19 is common for the receiving and transmitting parts, the second link 20, which belongs to the receiving channel, is a focusing lens 20, in the focal plane of which a photodetector (FPU) 21 is installed. Focusing lens 20 paired with a telescopic nozzle 19 provides an equivalent focal length of the receiving channel ƒ _eq 'equal to:

where G is the increase in the telescopic nozzle 19;

- фокусное расстояние фокусирующего объектива (приемного объектива) 20.

- focal length of the focusing lens (receiving lens) 20.

The second link 22 of the transmission channel, made in the form of a telescopic nozzle mounted in front of the emitter 23, paired with a telescopic nozzle 19 provides a given divergence of the laser beam ψ _before in the space of objects emitted by the emitter 23, controlled by a digital processing unit 24 connected to the computing unit 10. ψ _pre = ψ _laser / Г ₁₉ · Г ₂₂ , where ψ _laser is the laser divergence, Г ₁₉ is the increase in the telescopic nozzle 19, and Г ₂₂ is the increase in the telescopic nozzle 22.

In addition to the first link 19, the following are common in the optical system of the transmitting and transmitting channel: an optical element 25 operating to reflect through the receiving channel and to pass the rays of the emitter 23 through its central hole, and a mirror of the deflector 26 of the laser channel with angle sensors 27-27 'and drives 28-28 ', connected to the control unit of the deflectors 9. This construction of the optical circuit allows you to almost perfectly synchronize the emitting and receiving beams (signals), which are combined on the scanning mirror of the deflector 26, which rotates hibernation at predetermined angles, thereby increasing the quality of range finding.

Figures 2 and 3 show examples of the optical system of the heat direction finding channel 7. The presence of two links in it is due to the fact that the deflector must have minimum overall dimensions at real values of the transfer coefficient M between the angular displacements of the mirror of the deflector 13 and the scanning mirror 2. keep in mind that a decrease in the overall dimensions of the mirror of the deflector 13 leads to an increase in the transmission coefficient M, and with an increase in the transmission coefficient M, the scanning speed increases, which is unacceptable, since a system becomes inoperable. Therefore, it is necessary to ensure the optimal ratio between the angular velocity characteristics of the mirror of the deflector 13 and its dimensions.

а второе звено 12 (или 12-12') - проекционный объектив с увеличением β_2зв.т. В этом случае эквивалентное фокусное расстояние всей оптической системы теплопеленгационного канала

равно:

=β_2зв.т., а коэффициент передачи М_{телеоб.т.} равенExample 1 (see Fig. 2) shows the optical system of the heat direction finding channel 7, where the first link 11 is a telephoto lens with a focal length

and the second link 12 (or 12-12 ') is a projection lens with an increase in β _2sv.t. In this case, the equivalent focal length of the entire optical system of the heat direction finding channel

equally:

= β _2t.s. , and the transmission coefficient M _teleob.t. is equal to

- расстояние от оси сканирующего зеркала дефлектора теплопеленгационного канала до фокуса первого звена теплопеленгационного канала

Where

- the distance from the axis of the scanning mirror of the deflector of the heat direction finding channel to the focus of the first link of the heat direction finding channel

тогда эквивалентное фокусное расстояние всей оптической системы пеленгационного канал

равноExample 2 (see Fig. 3) shows the optical system of the heat direction finding channel 7, where the first link 11 is made in the form of a telescope with an increase in G _{1 sound.t.} and the second 12 (12-12 ') - in the form of one or more focusing lenses (depending on the given spectral ranges) with the corresponding focal length

then the equivalent focal length of the entire optical system direction finding channel

equally

а коэффициент передачи М_{телескоп.т.}=Г_1зв.т.

and the transmission coefficient is M _telescope. = G _1z.t.

The design of the first link of the lens is determined by the tasks. A scheme with a telephoto lens is preferable to a scheme with a telescope in terms of dimensions and the number of optical elements, since the telescope must be made according to Kepler’s scheme, based on the minimum transverse overall dimensions of the telescope lenses. When the device operates in two spectral ranges (two FPUs and two independent second links), the first link is subject to the requirement of providing high optical correction in a wide spectral range, and with the available optical materials the first link in the form of a telephoto lens with traditional optical surfaces . Therefore, in this case, it is optimal to perform the first link in the form of a Kepler telescope, and its lack of transmission, due to the presence of a significant number of lenses, can be eliminated using an aspherical mirror as a telescope lens (see Fig. 3). The mirror does not have chromatic aberration, and the eyepiece having a small focal length, in the presence of available materials, allows for a high degree of chromatic correction in a wide spectral range.

In examples 3. 4 (see Fig.4, 5) shows the optical system of the receiving and transmitting laser channel 8, where the first link 19 is a telescopic nozzle, which serves to reduce the overall dimensions of the mirror of the deflector of the laser channel 26 and to match the transfer coefficient between the scanning mirror 2 and a deflector mirror 26.

Depending on the specified viewing angles, which should be provided by the mirror of the deflector 26, two variants of the telescopic nozzle 19 are possible.

At small viewing angles (~ 1 ° ÷ 2 °) in the space of objects, it is advisable to perform a telescopic nozzle according to the Galileo scheme (see figure 4). At viewing angles of more than 2 °, the telescopic nozzle should be performed according to the Kepler scheme (see Fig. 5), since at large viewing angles, the diameter of the first component of the first link 19 will sharply increase in the Galilean scheme, and when the diameter is limited, vignetting will increase sharply.

From the point of view of laser radiation, the Galilean scheme is preferable, because no focusing of laser radiation. In the Kepler’s scheme, an intermediate image (focusing of laser radiation) takes place, therefore, in such a scheme, it is necessary to provide protection of the space around the plane of the intermediate image (for example, some cuvette).

The claimed device operates as follows. In review mode, the inventive system using a scanning mirror 2 provides continuous viewing of a given space. The energy flow from objects emitting in the infrared wavelength range through the protective fairing 1, which prevents the influence of external factors on the internal parts of the device, enters the scanning mirror 2, reflecting from which, it enters the dichroic mirror 6, which separates it (energy stream) into beams required spectra. One of the energy beams enters the heat direction finding channel. Its radiation passes through the first link 11, made according to one of the schemes described above, behind which the mirror of the deflector 13 is placed. The mirror of the deflector 13 shifts the beam in two mutually perpendicular directions, compensating for the image shift synchronously with the movement of the scanning mirror 2 around the Y axis, and moves LP in the direction opposite to the direction of scanning, thereby providing the required exposure time. Reflected from the deflector 13, the radiation with the help of the optical element 18 (and 18 'in the multispectral scheme) enters the second optical link 12 (and 12'), which focus the energy flux in the plane of the sensitive areas of the FPU 16 (and 16 '). The signal from the FPU 16 (and 16 ') is transmitted to the processing unit of the video signal 17 for correction and filtering in order to select an object in the frame and determine its coordinates. The operation of the video processing unit 17 is synchronized by the commands of the control unit 5 (control unit of the line of sight) by the scanning mirror 2. From the processing unit of the video image 17, the coordinates of the detected object are transmitted to the computing unit 10, information about the current position of the line of sight from the unit is received in the same unit control the scanning mirror 5. Based on this information in the computing unit 10 determines the angular position of the detected object. The resulting coordinates are transmitted to an external central computing system (HCVS).

The operation of the mirror control unit of the deflectors 9 is synchronized with the control unit of the line of sight 5, which generates the necessary deflection angles of the deflector mirrors. Information about the development of these angles goes back to block 5.

As already mentioned, the optical system of the laser channel 8 provides the operation of the receiving and transmitting channels. In the transmitting channel, the optical system generates a beam with the required divergence of the laser radiation of the emitter 23, operating on commands from the digital processing unit 24, by the second optical link 22, which then passes through the central hole in the optical element 25, is reflected from the mirror of the two-coordinate deflector 26, which controls the target the axis of the laser locator when a target detects a target, passes through the first optical link 19, the dichroic mirror 6 and, reflected from the scanning mirror 2, exit t through the fairing 1 into the outer space. Next, the laser energy flux, reflected from the object and passing through the optical path: fairing 1 - scanning mirror 2 - optical link 19 - deflector 26, reflected from the optical element 25, is focused by the second optical link 20 in the plane of the sensitive areas of the photodetector 21.

When implementing the claimed invention, it is proposed:

- Scan the mirror from composite material Skeleton - D;

- use the DM 10 engine as an executive engine, the angle sensor - a BVTV-60-S30 type sensor;

- for the manufacture of optical elements, it is advisable to use K-8 glass for the laser channel, and ZnSe, ZnS, germanium and silicon for the heat channel;

- for registration of thermal radiation, for example, IR detectors from SOFRADIR can be used, and for a laser channel, for example, FPU Lazur.

Thus, the claimed product in comparison with the prototype:

- provides a larger field of view;

- allows you to get complete information (angular coordinates and range of all targets in a large field of view;

- allows you to identify the most dangerous of all objects in a large field of view;

- solves the problem of pointing guided weapons at several targets simultaneously;

- provides guidance of the sighting axis of the laser locator on the object during continuous viewing with a given accuracy;

- significantly increases the maximum ranging distance.

Claims (1)

Optoelectronic sighting system comprising a cowl, a scanning mirror with angle sensors and actuators associated with the control unit of the line of sight of the scanning mirror, a dichroic mirror, a heat-sensing channel, including an optical system with a photodetector and an associated video processing unit for correction and filtering the signals from the output of the photodetector with the subsequent selection of the object in the frame and determining its coordinates, a laser channel with an optical system, on a spinning component that optically matches the transmitting and receiving laser channels, respectively equipped with an emitter and a photodetector connected to a digital processing unit for generating commands for the emitter and a photodetector, also comprising a computing unit, characterized in that the optical systems of the heat-directional and laser channels are made in the form of two optical links and equipped with deflectors, each of which is connected to the control unit for their mirrors connected to the control line of sight of the scanning mirror and the computing unit, while the mirror of the deflector of the heat direction finding channel is installed in the plane of pairing of the exit pupil of the first optical link and the entrance pupil of the second optical link of its optical system, and the mirror of the deflector of the laser channel is installed in the plane of the exit pupil of the first optical link of its optical system, the operation of the control unit mirrors deflectors synchronized with the control unit of the line of sight of the scanning mirror a beam that generates the necessary deflection angles of the deflector mirrors, and information on the development of these angles is fed back to the control unit of the scanning line of sight of the scan mirror, while the dichroic mirror is designed to separate the energy flow between the heat direction finding and laser channels, the computing unit controls the control unit of the line of sight of the scanning mirror and, in addition, it is designed to determine the angular position of the detected object from information about the coordinates of the detected object and information about the current position of the line of sight of the scanning mirror, coming from the video processing unit and control unit the line of sight of the scanning mirror, respectively, in addition, the calculation unit performs the collection, treatment and delivery of information to the external system all zapelengovannyh purposes.

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