RU50683U1 - DEVICE FOR DETECTION OF OPTICAL AND OPTICAL-ELECTRONIC Flickering OBJECTS - Google Patents

Abstract

The utility model relates to the field of location technology and can be used to detect and measure optical and optoelectronic devices: binoculars, telescopes, 6 cameras, video cameras, shooting optical sights, movie cameras, and any other devices equipped with optical lenses. The technical result of the utility model is to increase the detection efficiency of optoelectronic objects in a dynamic observation mode. The technical result is achieved by the fact that in the device for detecting optical and optoelectronic glare objects containing a radiation source and a receiving device, the detection device is structurally made in the form of a single module, the radiation source of which is implemented as a series of LEDs of continuous or pulsed radiation, placed on the surface of the module along (around the perimeter) of the receiving window (lens) for visual detection of the response of glare objects. A device for detecting optical and optoelectronic glare objects comprising a radiation source and a receiving device, the radiation source being implemented as a series of respectively emitting IR radiation diodes operating in pulsed or continuous modes or pulse-frequency lasers, and the receiving device is an optical system lens : photodetector or video camera, in addition, the receiving device is made in the form of two channels. The technical and economic effect of the utility model is achieved by the possibility of increasing the detection efficiency of optoelectronic objects in a dynamic observation mode.

Description

The utility model relates to the field of location technology and can be used to detect and measure optical and optoelectronic devices: binoculars, telescopes, cameras, video cameras, shooting optical sights, movie cameras, and any other devices equipped with optical lenses.

The specificity of detecting optical and optoelectronic objects is the specular (directional) nature of reflection, in which the beam divergence of the optical location systems before and after reflection is the same, and the specular reflection reflects the metallic luster of a metal surface that is clean without oxides, as well as bright glare when reflected from glass , in this case, the specular reflection coefficient has a value equal to:

R _i = (n-1) ² / (n + 1) ² ,

where R _i is the mirror reflection coefficient,

n is the refractive index of the surface material,

A known laser system for detecting optoelectronic objects (see application GB No. 2256554 IPC G 01 S 17/42, dated 09.12.92), containing

a pulse-frequency laser with a lens, an information display unit, the input of which is connected to the output of the memory unit.

Known laser marker PEQ-IA (see James International Defense Review, 1996, No. 2, pp.19-20) containing a night device, including a laser and a photosensitive receiver.

The device allows you to see at night, laser radiation directed at the target, which increases the likelihood of successful target designation.

A device for optical measurement of the distance to the object and its speed (see patent FR No. 2594959 IPC G 01 S 17/32, 08/28/87), containing a coherent light source, intended for radiation, means for frequency modulating the light of the source, for detecting frequency the shift between the light emanating from the source and the light reflected by the object, and means for focusing on the photodetector of the total signal from the volume resonator, the frequency of which displays the distance between the source and the object.

A device for detecting optical and optoelectronic devices (see patent RU No. 38408 IPC G 01 S 17/02, dated 10.06.04), containing a laser emitter with modulation of radiation of the order of 0.2-27 Hz, and optically matched with it a surveillance channel including an electron-optical converter with a receiving lens and means for observing the image on the screen of the electron-optical converter.

A known indicator of optical and optoelectronic glare objects (see patent RU No. 33443 IPC G 01 S 17/06, from 10.20.03) containing a radiation source with LED illuminator and a receiving device, as well as a beam splitter located on the optical axis between the source radiation and a glare object, the illuminator is capable of monochromatic radiation at several wavelengths and is installed in the focus of the collective lens, and the receiving device includes a coaxially located rotary mirror, optically coupled to the LED rer, and visual filter tube, wherein the optical axis of the source

radiation and the receiving device are oriented in parallel, the LEDs and the filter are two or three-color: red, green and red, green, blue.

A known indicator of optical and optoelectronic glare objects (see patent RU No. 36899 IPC G 01 S 17/06, dated 03/27/04) containing a illuminator and an image pickup unit installed in the housing with the ability to illuminate the object, display its image on the screen and storing the reproduced image, wherein the illuminator is a prefix to the image receiving unit and includes an LED unit configured to monochromatic radiation at several wavelengths (red, green and blue with the possibility of alternating activation), and the image receiving unit is made with a digital camera having a color liquid crystal screen.

The closest in technical essence is a laser detection system of optoelectronic devices for fixing the reflection of the reflected signal (see patent RU №2113717 IPC G 01 S 17/06, from 10.11.96), containing a pulse-frequency laser and photodetector, the output of which is sequential a threshold device for laser radiation intensity, a pulse counter of a frequency-pulse laser, an angular position sensor of a photodetector and a frequency-pulse laser, a coordinate determination unit and a signaling device are connected about, moreover, the lens of the photodetector is equipped with a narrow-band interference filter.

A disadvantage of the known technical solution is that the total area of the diffusion object substantially exceeds the aperture of the optical object illuminated by the laser beam, the signal level becomes comparable to the signal level reflected from the diffusion object, and when the threshold is set at a low level, the probability of false response due to the signal from diffusion object, when

setting the threshold at a high level increases the likelihood of missing a signal from an optical object, it is very difficult to operate and an overly expensive product.

The technical result of the utility model is to increase the detection efficiency of optoelectronic objects in a dynamic observation mode.

The technical result is achieved by the fact that in the device for detecting optical and optoelectronic glare objects containing a radiation source and a receiving device, the detection device is structurally made in the form of a single module, the radiation source of which is implemented as a series of LEDs of continuous or pulsed radiation, placed on the surface of the module along (around the perimeter) of the receiving window (lens) for visual detection of the response of glare objects.

A device for detecting optical and optoelectronic glare objects comprising a radiation source and a receiving device, the radiation source being implemented as a series of respectively emitting IR radiation diodes operating in pulsed or continuous modes or pulse-frequency lasers, and the receiving device is an optical system lens : photodetector or video camera, in addition, the receiving device is made in the form of two channels.

The essence of the proposed technical solution is the creation of a security system for a device for detecting optical and optoelectronic devices: binoculars, telescopes, cameras, video cameras, shooting optical sights, movie cameras, and any other devices equipped with optical lenses in the constructive implementation of it as a single module.

The use of a number of emitter elements located on the surface of the module along (around the perimeter) of the receiving window (lens) in the form of a circle,

a rectangle, a triangle, a square, a sector with LEDs, or IR emitting diodes operating in the regime of continuous or pulsed radiation or pulse-frequency lasers, with the angle of divergence between the axes of the receiving hole for visual observation or an optical system (photodetector or video camera) and backlight emitters it is minimal that a sufficiently large part of the reflected response enters the receiving hole. When using the backlight - emitters, several intersecting beams are formed around the hole, and the maximum illumination (the intersection of all beams) coincides with the axis of the receiving hole, i.e. the brightness of the reflected response in comparison with a simple (one) backlight increases several times, which greatly facilitates the task of detecting the reflected response, and the use of the second detection channel contributes to a significant increase in the level of detection of glare objects.

Comparison of the proposed solution with well-known technical solutions shows that it has a new set of essential features that can successfully achieve the goal.

Figure 1, 2 shows a device for detecting optical and optoelectronic glare objects, respectively, visual observation and through an optical display system (photodetector or video camera), figure 3 shows a two-channel device for detecting optical and optoelectronic glare objects.

A device for detecting optical and optoelectronic glare objects 1, containing a radiation source 2 and a receiving device 3, and structurally, the detection device is made in the form of a single module 4, the radiation source 2, having a number of LEDs 2 ¹ or emitting diodes IR 2 ² or frequency -pulse lasers 2 ³ (not shown) of continuous or pulsed radiation, placed on the surface of a single module 4 along the receiving window (lens) 5 for

visual detection of 3 ¹ or the lens of the optical system: a photodetector or video camera 3 ² , in addition, the receiving device is made in the form of two channels 6.

The device operates as follows.

The LED 2 ¹ (either an IR emitting diode 2 ² or a pulse-frequency laser 2 ³ ) generates irradiating radiation, which is sent to the zone of the alleged location of the optoelectronic glare objects 1, by turning in the hands of module 4, a sequential overview of the zone is performed (scanning), reflected radiation received observer's eye 3, ¹ or opto-electronic lens ^{2 March} (photodetector or camcorder), is analyzed eye either ¹ or 3 is detected in the receiving device 3, the output of which is formed a video signal propyl tional intensity of the reflected radiation.

The technical and economic effect of the utility model is achieved by the possibility of increasing the detection efficiency of optoelectronic objects in a dynamic observation mode.

Claims (3)

1. A device for detecting optical and optoelectronic glare objects, comprising a radiation source and a receiving device, characterized in that the design of the detection device is made in the form of a single module, the radiation source of which is implemented as a series of LEDs of continuous or pulsed radiation, located on the surface module along (around the perimeter) of the receiving window (lens) for visual detection of the response of glare objects. 2. A device for detecting optical and optoelectronic glare objects, comprising a radiation source and a receiving device, characterized in that the radiation source is implemented as a series of respectively emitting IR radiation diodes operating in pulsed or continuous modes or pulse-frequency lasers, and receiving the device is an optical system lens: a photodetector or a video camera. 3. A device for detecting optical and optoelectronic glare objects according to claims 1 and 2, characterized in that the receiving device is made in the form of two channels.