RU194440U1 - Active-Pulse Television Night Vision with Daytime Television Channel - Google Patents

Abstract

The proposed device relates to the technique of optoelectronic observation and aiming devices. The technical result consists in providing observation in daytime conditions with the possibility of reducing the time the device switches from passive to active-pulse operation. An active-pulsed night-vision television device contains a pulsed laser illuminator comprising a pump unit connected to a pulsed laser semiconductor emitter, and a radiation forming lens focused on it, a gating unit consisting of a master pulse generator, the first output of which is connected to the pump unit, and the second the output through an adjustable delay unit is connected to a gate pulse generator, an observation unit consisting of sequentially mounted on an optical the axis of the night lens, a narrow-band filter, an electron-optical converter with a microchannel plate, to which the output of the gate pulse generator is connected, transfer optics, consisting of the first lens component focused on the screen of the electron-optical converter, and the second lens component focused on the device matrix with charge connection of a television camera connected to a television monitor. Additionally, the device contains a day channel, consisting of sequentially mounted on the optical axis: a day lens, a grid, a lens wrapping system containing the first and second lens blocks, between which a flat mirror is installed, the first lens block being focused on a grid installed in the rear focal plane of the day the lens, and the second lens unit is optically coupled through an additionally introduced cube-prism to the first lens component of the transfer optics. The screen of the electron-optical converter is optically coupled through a cube prism and an additionally introduced second transfer optics with an additionally introduced second television camera connected via an additionally introduced threshold device to the input of the master oscillator, the second transfer optics containing a third lens component focused on the screen of the electron-optical converter and its fourth lens component is focused on the CCD matrix of the second television camera. In front of the night lens, the first telescopic Galileo nozzle is installed with the possibility of its withdrawal from the rays, the second telescopic Galileo nozzle is installed in front of the day lens, with the possibility of its withdrawal from the rays. The housing of the first Galileo telescopic nozzle is kinematically connected with an additionally introduced electromechanical unit, to the input of which the first output of the master pulse generator is connected. 1 ill.

Description

The proposed device relates to the technique of optoelectronic observation and aiming devices.

Known active-pulse night vision device (AI NVD) (see Volkov VG, Gindin PD Technical vision. Innovations. M., Technosphere, 2014, 840 pp., P. 407, Fig. 4.4.1 ) This device is implemented in the form of AT PNV NNP-130 (see Geykhman I.L., Volkov V.G. Vision and Security. M, News, 2009, 840 pp., P. 292, Fig. 4.1.4a.). The device comprises a pulsed laser illuminator comprising a pump unit connected to a pulsed laser semiconductor emitter, onto which the radiation forming lens is focused, a gating unit consisting of a driving pulse generator, the first output of which is connected to the pump unit, and the second output is connected to the adjustable delay unit to a gating pulse shaper, an observation unit, consisting of a night lens, a narrow-band filter, e an electron-optical converter with a microchannel plate, and an ocular system. In this case, the output of the gate pulse generator is connected to the microchannel plate. The disadvantage of this device is the increased fatigue of the operator due to the need to observe the ocular system, the inability to remotely transmit the image and its duplication, the inability to digitally process the image in real time, the inability to observe in the daytime, the loss of time when switching the device from passive to active-pulse mode work.

The closest analogue of the proposed utility model is known, adopted for the prototype AI television (TV) NVD (see Volkov V.G., Gindin P.D. Technical vision. Innovations. M., Technosphere, 2014, 840 pp., P. 19 , Fig. 1.1.6). This device is implemented in the form of AI TV PNV of JSC NPO Geofizika-NV (see Active-Pulse Optical Television Camera with Long Range. Prospect of JSC NPO Geofizika-NV, RF, Moscow, 2018). The device comprises a pulsed laser illuminator comprising a pump unit connected to a pulsed laser semiconductor emitter, onto which the radiation forming lens is focused, a gating unit consisting of a driving pulse generator, the first output of which is connected to the pump unit, and the second output is connected to the adjustable delay unit to a gating pulse shaper, an observation unit, consisting of a night lens, a narrow-band filter, e an electron-optical converter with a microchannel plate, transfer optics containing the first and second lens components and a TV camera connected to a TV monitor. In this case, the output of the gate pulse generator is connected to the microchannel plate. In this device, due to the use of the TV channel, operator fatigue is reduced due to observation not through the ocular system, but from the TV monitor screen. Thanks to the TV channel, real-time digital image processing has become possible and, accordingly, its quality has been improved; remote image transmission and duplication are ensured. However, it is still impossible to observe in daylight conditions, and to lose time when switching the device from passive to active-pulse operation.

The objective of the proposed utility model is to provide daytime monitoring with the possibility of reducing the time the device switches from passive to active-pulse operation.

The indicated technical result is achieved due to the additional introduction of the daytime television channel and input of the television video signal to the threshold device, which, in the case of detecting the object of observation in the passive mode, switches the device from the passive mode to the active-pulse mode without operator intervention.

An active-pulsed night-vision television device containing a pulsed laser illuminator, comprising a pump unit connected to a pulsed laser semiconductor emitter, and a radiation forming lens focused thereon, a gating unit consisting of a driving pulse generator, the first output of which is connected to the pump unit, and the second output through the adjustable delay unit is connected to the gate pulse generator, the observation unit, consisting of sequentially mounted optical axis of the night lens, narrow-band filter, electron-optical converter with a microchannel plate, to which the output of the gate pulse generator, the transfer optics, consisting of the first lens component focused on the screen of the electron-optical converter, and the second lens component focused on the device matrix are connected charge-coupled (CCD) of a television camera connected to a television monitor, characterized in that it further comprises a daytime channel, consisting of therefore mounted on the optical axis of the day lens, the grid, the lens wrapping system comprising the first and second lens blocks, between which a flat mirror is mounted, the first lens block being focused on the grid mounted in the rear focal plane of the day lens, and the second lens block is optically paired through an additionally introduced cube-prism with the first lens component of the transfer optics, the screen of the electron-optical converter is optically coupled through the cube-prism and The second transfer optics with an additionally introduced second television camera connected via an additionally introduced threshold device to the input of the master oscillator, the second transfer optics containing a third lens component focused on the screen of the electron-optical converter, and its fourth lens component focused on the CCD of the second television cameras, in front of the night lens, the first Galilean telescopic nozzle is installed with the possibility of its withdrawal from the course of the rays, before the daylight injective second set Galilean telescopic nozzle, with its withdrawal from the ray path, wherein the first housing Galilean telescopic plant them kinematically connected with the electromechanical unit is further inserted, which is connected to the input of the first output of the driving pulse generator.

The block diagram of the proposed device is presented in the drawing of FIG. 1. An active-pulsed night-vision television device (AI TV PNV) contains a pulsed laser illuminator (ILO) 1. It consists of a pump unit 2, the output of which is connected to a pulsed laser semiconductor emitter (ILPI) 3. A radiation generating lens is focused on it ( OFI) 4. The device includes a gating unit 5. It contains a master pulse generator (ZGI) 6, the first output of which is connected to the input of the pump unit 2, and the second output is connected through an adjustable delay unit (BRZ) 7 to the gate driver pulses (FSI) 8. The device contains a monitoring unit 9. It consists of a first Galileo nozzle 10 sequentially mounted on the optical axis of the telescopic (TS) with the possibility of its output from the beam path, kinematically connected with the output of the electromechanical unit 11, to the input of which the first output is connected ZIG 6, night lens 12, narrow-band filter 13, electron-optical transducer (EOP) 14 with a microchannel plate (MCP) 15, cube prism 16 with a hypotenuse face 17, the first transfer optics 18 containing the first lens component 19 and the second lens component 20 of the television (TV) camera 21 connected to the TV monitor 22. In this case, the first lens component 19 is focused on the image intensifier tube 14, and the second lens component is focused on the CCD of the TV camera 21. The device contains a day channel 23, consisting of a Galileo nozzle 24 sequentially mounted on the optical axis of the second vehicle, with the possibility of its withdrawal from the rays, a day lens 25, a grid 26, a wrapping system 27, containing the first lens assembly 28 and the second lens assembly 29, between which is installed flat a mirror 30. In this case, the first lens assembly 28 is focused on the grid 26 located in the rear focal plane of the day lens 25, and the second lens assembly 29 is optically coupled through the hypotenuse face 17 of the cube prism 16 and through the first transfer optics 18 to the first TV camera 21. The screen of the image intensifier tube 14 is optically coupled through the hypotenuse face 17 of the cube-prism 16 and the second transfer optics 31 to the second TV camera 34. The third lens component 32 is focused on the screen of the image intensifier 14, and the fourth lens component 33 is focused on the CCD of the second TV camera 34. Her the output through the threshold device 35 is connected to the input of the ZGI 6.

The photocathode EOP 14 operates in the spectral region of 0.4-0.9 microns. A narrow-band filter transmits radiation at a wavelength of 0.85 microns, and ILPI 3 emits at this wavelength. The daytime channel operates in the spectral region of 0.38-0.78 microns, and the CCD arrays of the first 21 and second 34 TV cameras operate in the spectral region of 0.4-1.1 microns. The hypotenuse face 17 of the cube-prism 16 reflects 50% of the radiation in the spectral region of 0.38-0.78 μm and transmits 50% of the radiation in the same region of the spectrum.

The device operates as follows. When it functions during the daytime, sunlight, reflected from the object of observation and the background surrounding it, enters the daily lens 25 of the daytime channel 23. At the same time, the second vehicle nozzle Galileo 24 is removed from the course of the rays. The day lens 25 creates an inverted image of the object and background in its rear focal plane, which coincides with the first along the rays of the optical surface of the grid 26. It serves to sight the object and to roughly measure the distance to it. Next, the image is transferred using the wrapping system 27, its first 28 and second 29 lens assemblies, and also a flat mirror 30 to the rear focal plane of the second lens assembly 29. It is aligned with the front focal plane of the first lens component using the hypotenuse face 17 of the cube prism 16 19 of the first transfer optics 18. Its second lens component 20, focused on the CCD matrix of the first TV camera 21, creates an image of the object and background on this matrix. The TV camera 21 converts the image into a video signal. He enters the TV monitor 22, from the screen of which the operator observes the image. In this case, the operator searches and detects an object in a wide angle of the field of view, for example, 15 × 10 °. To recognize the object, the second TS Galileo nozzle 24 is introduced in front of the day lens 25 in the course of the rays of the day channel 23. It allows increasing the increase in the daily channel 23 by a factor equal to the increase in the second TS of the Galileo 24 nozzle, for example, Г = 5 ^х . Then, the range of the daytime channel will increase accordingly while reducing its angle of view. For example, if T = 5 ^x , then the angle of the field of view will be 3 × 2 °.

When operating at night in passive mode, the observation unit 9 is turned on. In this case, the Galileo nozzle 10 is removed from the path of rays using an electromechanical unit 11. Radiation from stars and the moon, which determines the level of natural night illumination (EHR), is reflected from the object and background and comes into night lens 12. In this case, the narrow-band filter 13 is removed from the path of the rays. The night lens 12 creates an image of the target and background on the photocathode of the image intensifier 14. It converts the image to visible and enhances it in brightness using the MCP 15. The image from the screen of the image intensifier 14 is transmitted through a cube prism 16 and the first transfer optics 18 to the CCD of the first TV camera 21. It converts the image into a video signal that enters the TV monitor 22. From its screen, the operator observes the image by searching for and detecting an object in a wide angle of view, for example, 15 × 10 °. At the same time, the image from the screen of the image intensifier tube 14 by reflection from the hypotenuse face 17 of the cube prism 16 and the second transfer optics 31 with its third lens component 32 and the fourth lens component 33 is transmitted to the CCD matrix of the second TV camera 34. It converts the image into a video signal that is received to the threshold device 35. If an object is detected, the video signal exceeds a certain threshold level of the threshold device 35. It is triggered and provides a corresponding signal to the input of the ZGI 6. In this case, the active-pulse (AI) mode is turned on operation. ZGI 6 from its first output gives a signal to the input of the electromechanical unit 11. It activates and installs the first TS nozzle Galileo 10 in the course of the rays of the observation unit 9, thereby increasing its increase in the number of times equal to the increase of the same nozzle 10, for example, G = 5 ^x to ensure recognition of an object detected in the passive mode of operation of the device. In this case, the angle of the field of view is reduced to 3 × 2 °, equal to the angle of illumination of the PLA.

1. At the same time, from the first output of ZGI 6, it feeds clock pulses to the input of the pump unit.

2. It creates at the output the corresponding pump current pulses, which are supplied to ILPI 3. In this case, ILPI 3 generates radiation pulses at a wavelength of 0.85 μm. The radiation of ILPI 3 is collimated using OFI 4, creating a spot of illumination on the object. The radiation pulses reflected from the object come to the input of the first TS nozzle 10, which transmits them to the input of the night lens 12. In this case, a narrow-band filter 13 with a working wavelength of 0.85 μm and a half-width of the spectrum equal to the half-width of the ILPI 3 spectrum is introduced into the beam . The photocathode of the image intensifier tube 14 creates a pulsed image of the object. Simultaneously with the supply of clock pulses from the first output of the ZGI 6 from its second output, clock pulses are fed to the input of the BRZ 7, in which the operator introduces a continuously adjustable delay. From the output of the BRZ 7, the signal is supplied to the FSI 8. It provides, until the radiation pulse arrives at the photocathode of the image intensifier tube 14, locking the MCP 15 with a constant bias voltage. At the time of the arrival of the radiation pulse to the photocathode, the image intensifier tube 14 of the FSI 8 unlocks the MCP 15 for a time equal to or slightly longer than the duration of the backlight radiation pulses. In this case, the image intensifier tube 14 converts the image to visible and enhances it in brightness using the MCP 15. The image of the object from the image intensifier screen 14 is transmitted using the first transfer optics 18 to the CCD matrix of the first TV camera 21, and then to the TV monitor 22 as it was described above. As soon as the delay between the moment of starting the pumping unit 2 and the moment of arrival of the backlight radiation pulse reflected from the object to the photocathode of the image intensifier tube 14 is equal to the time the radiation pulse travels from the device to the object and back, the operator will see the image and recognize it.

At present, a schematic diagram of the device has been developed and its layout has been completed.

Thus, due to the additional introduction of a daytime television channel and input of a television video signal to a threshold device, which, in the case of detecting an object of observation in passive mode, switches the device from passive mode to active-pulse mode without operator intervention, daytime monitoring is provided with the possibility of reducing the time the device switches from passive to active-pulse operation.

Claims (1)

An active-pulsed night-vision television device containing a pulsed laser illuminator, comprising a pump unit connected to a pulsed laser semiconductor emitter, and a radiation forming lens focused thereon, a gating unit consisting of a driving pulse generator, the first output of which is connected to the pump unit, and the second output through the adjustable delay unit is connected to the gate pulse generator, the observation unit, consisting of sequentially mounted optical axis of the night lens, narrow-band filter, electron-optical converter with a microchannel plate, to which the output of the gate pulse generator, the transfer optics, consisting of the first lens component focused on the screen of the electron-optical converter, and the second lens component focused on the device matrix are connected charge-coupled (CCD) of a television camera connected to a television monitor, characterized in that it further comprises a daytime channel, consisting of therefore mounted on the optical axis of the day lens, the grid, the lens wrapping system comprising the first and second lens blocks, between which a flat mirror is mounted, the first lens block being focused on the grid mounted in the rear focal plane of the day lens, and the second lens block is optically paired through an additionally introduced cube-prism with the first lens component of the transfer optics, the screen of the electron-optical converter is optically coupled through the cube-prism and The second transfer optics with an additionally introduced second television camera connected via an additionally introduced threshold device to the input of the master oscillator, the second transfer optics containing a third lens component focused on the screen of the electron-optical converter, and its fourth lens component focused on the CCD of the second television cameras, in front of the night lens, the first Galilean telescopic nozzle is installed with the possibility of its withdrawal from the course of the rays, before the daylight injective second set Galilean telescopic nozzle, with its withdrawal from the ray path, wherein the first housing Galilean telescopic plant them kinematically connected with the electromechanical unit is further inserted, which is connected to the input of the first output of the driving pulse generator.

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