RU215688U1 - LASER ALL-DAY SCOUT DEVICE - Google Patents

Abstract

The utility model relates to wearable laser reconnaissance devices that provide detection and recognition of various types of objects in day-night conditions, determining their coordinates, processing and storing information about reconnoitered objects and promptly transmitting it to external devices. The objective of the utility model is to ensure all-day operation, expanding functional and operational capabilities. The all-day reconnaissance laser device is designed for individual equipment of military personnel of reconnaissance units, sniper groups of the Ground Forces. The essence of the utility model is to ensure the all-day operation of the device by shifting the working region of the spectrum to the short-wave infrared range and the technical solution of the optical system of the short-wave infrared day-night channel, matched with the matrix solid-state radiation receiver and the photodetector of the laser rangefinder channel, operating in the spectral region 0.9…1.8 µm, in which the average value of natural illumination on a moonless night is (1.5…2.0)⋅10 ^-7 W/cm ² ⋅µm, that is, two orders of magnitude higher than for range 0 .4…0.9 µm ((1.5…3.0)⋅10 ^-9 W/cm ² µm), atmospheric transparency is 1.3 times better, the contrast of the observed object is more stable and 1.5 times higher. In addition, masked objects are better detected in this spectral range compared to the range of 0.4…0.9 µm.

Description

The proposed utility model relates to wearable laser reconnaissance devices that provide detection and recognition of various types of objects in day-night conditions, determining their coordinates, processing and storing information about reconnoitered objects and promptly transferring it to external devices.

The laser all-day reconnaissance device (LVPR) is designed for individual equipment of military personnel of reconnaissance units, sniper groups of the Ground Forces.

Known portable laser reconnaissance devices for reconnaissance units of the Ground Forces. With the help of devices, the tasks of detecting, recognizing, determining the coordinates of various types of objects in day-night conditions, as well as processing and storing information about reconnoitered objects and its prompt transmission to external devices in digital and text form [1, 2 ].

The main component of the functional purpose of the device is the transceiver. The design of a portable laser reconnaissance device provides for the operation of the transceiver both by hand and when it is installed on an angle measuring platform and a tripod [1, 2].

The transceiver includes a daytime optical sight with variable magnification, a night sighting channel made on a 3rd generation image intensifier tube, a television system for day-night video surveillance and image control, a laser ranging channel that operates at a safe wavelength, an electronic compass, satellite radio navigation device, blocks for processing, storing and displaying information [4, 5].

The mass of a set of portable laser reconnaissance devices is 3 ... 5 kg, which does not meet the requirements for portable reconnaissance devices.

The closest in its technical essence to the claimed utility model is the LVPR model, which contains a laser ranging channel, consisting of transmitter and receiver channels, a common photodetector, the transmitter channel includes a pumping device, ignition and an emitter module operating at a wavelength of λ=1.54 µm optically coupled to the telescopic system; the receiver channel includes a receiving lens, a spectrum splitter assembly in the form of a prism block, which is an element for separating the receiving and sighting channels, a focusing system optically connected to the photodetector, a sighting channel including a common with the receiver channel, a receiving lens, a spectrum splitter assembly in the form of a prism block and a wrapping systems, an indicator for displaying information with a projection system for inserting into the eyepiece, an electronic unit that includes a control and information processing device, an electronic compass, a satellite radio navigation device, a control board, a voltage converter and a battery pack [3].

The disadvantages of the prototype are the possibility of using it for its intended purpose only in daytime conditions, the dependence of the work of the target sight on the transparency of the surface layer of the atmosphere, the receiving lens of the optical sighting and laser rangefinder channels is designed for an operating wavelength of 0.53 μm, which reduces the sensitivity of the photodetector, since the laser rangefinder channel operates at a wavelength of 1.54 μm. The objective of the utility model is to ensure all-day operation, expanding functional and operational capabilities.

The solution of the problem is proposed to be carried out using the LWPR, which, like the device selected as a prototype, contains a laser rangefinding channel consisting of transmitter and receiver channels, a common photodetector, a transmitter channel that includes a pumping device, ignition and an emitter module that functions at a wavelength of λ=1.54 μm, optically connected to the telescopic system, the receiver channel includes a receiving lens, a prismatic spectrum splitter unit, which is an element for separating the receiving and sighting channels, a focusing system optically connected to the photodetector, a sighting optical channel, including a receiving lens common with the receiver channel, a spectrum splitter assembly in the form of a prism block and an enveloping system, an information display indicator with a projection eyepiece insertion system, an electronic unit that includes a control and information processing device, an electronic compass, a satellite radio navigation device tristvo, control board, voltage converter and battery pack.

A feature of the proposed LVPR, which distinguishes its prototype, is that instead of a sighting optical channel, a short-wave infrared (CIR) day-night channel is introduced, containing receiving and matching lenses, which are designed for a working wavelength of 1.54 μm, a receiving lens, which is a common the receiver channel lens, on the same optical axis with it there is a matching lens, in the rear focal plane of which there is a solid-state radiation detector matrix with a sensitivity area of 0.9 ... 1.8 μm, which is electrically connected to the video processor, the first output of which is electrically connected to the memory device , the second with a micro-display that interfaces with the object space of the eyepiece. Between them there is a spectrum splitter assembly made according to the scheme of a plane-parallel plate with a multilayer film and optically connected to a positive collimating lens and a negative lens, which focuses the reflected laser radiation onto the photodetector of the receiver channel.

The essence of the utility model is to ensure the all-day operation of the device by shifting the working region of the spectrum to the short-wavelength IR range and the technical solution of the optical system of the CMC of the day-night channel, matched with the matrix solid-state radiation receiver and the photodetector of the laser rangefinder channel, operating in the spectrum region 0 .9…1.8 µm, in which the average value of natural illumination on a moonless night is (1.5…2.0)⋅10 ^-7 W/cm ² ⋅µm, that is, two orders of magnitude higher than for range 0, 4…0.9 µm ((1.5…3.0)⋅10 ^-9 W/cm ² µm), atmospheric transparency is 1.3 times better, the contrast of the observed object is more stable and 1.5 times higher. In addition, masked objects are better detected in this spectral range compared to the range of 0.4…0.9 µm. Thus, the solution of the task is provided.

The proposed LVPR is illustrated by the drawings shown in Fig. 1 and 2.

In FIG. 1 shows a functional diagram of the device, which includes a laser ranging channel 20, containing a telescopic system 1 for forming the radiation pattern of a laser emitter 2, a photodetector 3, pumping boards 5 and ignition 4, an electronic unit 22 containing a control and information processing device 6, with which electrically a radio navigation device 7 and an electronic compass 8 are connected, a short-wave infrared night channel consisting of a receiving lens 9 and a matching lens 11, a spectrum splitter assembly 10 is located between them, in the rear focal plane of the matching lens 11 there is a matrix solid-state radiation receiver 12, which is sensitive to short-wave IR region of the radiation spectrum (0.9 ... 1.8 μm), electrically connected to the video processor 13, the outputs of which are electrically connected to the memory device 16 and the microdisplay 14, which is optically connected to the eyepiece 15. The primary power sources are block a batteries 18 and voltage converter 17. Operation is controlled through the control board 19.

In FIG. 2 shows the optical scheme of the CFC of the day-night channel and the laser channel of the receiver. The optical scheme of the CMC of the day-night channel includes a receiving lens consisting of positive 23 and negative 24 lenses, a spectrum divider 25 made as a plane-parallel plate with a multilayer film, an aperture diagram 26, a matching lens consisting of two glued lenses 27, 28, negative 29 and positive 30 menisci, in the focal plane of which is installed a matrix solid-state radiation detector (TPI) 31, a four-component eyepiece 35 with a remote exit pupil, optically connected to the microdisplay.

The optical scheme of the laser channel of the receiver includes a receiving lens consisting of lenses 23, 24, a spectrum splitter 25, optically connected to positive 32 and negative 33 lenses, which are optically connected to the photodetector 34.

Laser all-day reconnaissance device operates as follows.

For the KIK of the day-night channel 21. Observing in the night channel, the operator studies the phono-target situation and searches for the target. The reflected IR radiation of objects of the background-target environment in the range of 0.9 ... 1.8 μm within the field of view of the day-night channel is received by the lens 9 (Fig. 1) lenses 23, 24 (Fig. 2) and is focused on the spectrum splitter 25, which is made in in the form of a plane-parallel plate. On its first surface, a multilayer film is formed that transmits the CIR radiation, is limited by the aperture diaphragm 26 and is transmitted to the matching lens 11 (lenses 27, 28, 29, 30), which focuses it on the matrix TPI 12. The plane of the sensitive elements of the matrix TPI 31 (Fig. 2) is aligned with the image space plane. Matrix TPI 31 converts the short-wave infrared radiation of the "background-target" space into an analog electrical signal, which is amplified to the nominal value by the video signal reading system. In the video processor 13 (Fig. 1), the video signal is digitized, processed to improve the quality, select the operating mode, formed into an image of the "object-background" space, which, depending on the selected mode, is transmitted to the microdisplay 14, recorded in the memory device 16 and formed in the form analog signal for transmission to an external device via agreed exchange channels. The "background-target" image, as well as service information (including date and time), scales, aiming mark are displayed on the microdisplay and are viewed through the eyepiece 15 at a large angle of view. The scheme for constructing the eyepiece 35 (Fig. 2) provides a given removal of the exit pupil for alignment with the operator's eye.

For the laser rangefinder channel 20. The operator turns on the aiming sign, which is displayed on the microdisplay, and combines it with the image of the target. After the operator presses the START button, the control and information processing device 6 generates an ON signal of the pump board 5, which, after the energy storage device enters the mode, generates a READY signal, after which the IGNITION signal for the ignition board 4 is generated in the control and information processing device 6. Radiation from a laser emitter 2 is fed to the input of the photodetector 3 to generate a START signal, which triggers the time interval meter of the control and information processing device 6 and is formed by the telescopic system 1 to obtain a given size of the radiation spot on the target. During the reverse passage, the radiation reflected from the target hits the receiving lens 9 (lenses 23, 24), which reflects the part of the spectrum corresponding to the working spectral range of the laser emitter of the rangefinder channel and is reflected from the spectrum splitter 10 (25), passes the positive lens 32 and is focused by the negative lens 33 on photodetector 34, which converts the energy of laser radiation into electrical energy to generate a STOP signal, which turns off the time interval meter in the control and information processing device 6 of the electronic unit 22, where the distance to the target is calculated. The control and information processing device 6 of the electronic block 22 is electrically connected to the radio navigation device 7 to determine the location coordinates and the electronic compass 8 to determine the azimuth angle. The software of the control and information processing device 6 of the electronic unit 22 implements algorithms for calculating spherical coordinates and outputting them in digital code to the microdisplay 14 and to an external device.

Thus, when the proposed LVPR is used for its intended purpose, the functional and operational capabilities are expanded, noise immunity is increased, which makes it possible to effectively perform tasks of reconnaissance of targets day and night.

A source of information

1. Bardachevsky, N.N. The use of laser rangefinders in military affairs / N.N. Bardachevsky, V.F. Litovchenko, D.V. Grishaev // [Electronic resource] / Title from the screen 20.01.22.

2. 1D13. Technical description and operating instructions. - Plant. - 54 p. EKVD.201212.000RE. - Valdai, 2014. - 24 p.

3. Product 1D36. Manual. - Plant. - 78 p.

4. Optical reconnaissance device. Patent 2324896.

5. Geikhman, I.L. Vision and security / I.L. Geikhman, V.G. Volkov // [Electronic resource]. - M.: News. - 2009. / Title from screen 20.10.21.

6. SWIR-camera: how to see the invisible [Electronic resource] / Name from the screen 20.0.21 // Access code: rostec.ru.

7. SWIR camera [Electronic resource] / Access code: http://rostec.ru/news/shvabe-uvelichil-razreshenie-i-prochnost-swir-kamery/.

Claims (1)

All-day reconnaissance laser device, containing a laser ranging channel, consisting of transmitter and receiver channels, a common photodetector, the transmitter channel includes a pumping device, ignition and an emitter module operating at a wavelength of λ = 1.54 μm, optically connected to the telescopic system, the channel The receiver includes a receiving lens, a spectrum splitter assembly in the form of a prism block, which is an element for separating the receiving and sighting channels, a focusing system optically connected to the photodetector, a sighting optical channel including a receiving lens common with the receiver channel, a spectrum splitter assembly in the form of a prism block and a wrapping systems, an indicator for displaying information with a projection system for inserting into the eyepiece, an electronic unit that includes a control and information processing device, an electronic compass, a satellite radio navigation device, a control board, a voltage converter and a battery pack that differs in We see that a short-wave infrared day-night channel has been introduced, containing receiving and matching lenses, which are designed for an operating wavelength of 1.54 μm, the receiving lens is a common lens of the receiver channel, a matching lens is located on the same optical axis with it, in the rear focal plane which is equipped with a matrix of a solid-state radiation receiver with a sensitivity area of 0.9 ... 1.8 μm, which is electrically connected to a video processor, the first output of which is electrically connected to a memory device, the second - to a microdisplay, which is associated with the eyepiece object space, between them there is a spectrum splitter unit , made according to the scheme of a plane-parallel plate with a multilayer film and optically connected to a positive collimating lens and a negative lens, which focuses the reflected laser radiation on the photodetector of the receiver channel.

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