EA011843B1 - A device for detecting optical-electronic objects - Google Patents

Abstract

A device for detecting optical-electronic objects (variants) relates to optical-electronic devices and can be used, particularly to provide information security of service rooms of organizations, offices, companies and banking institutions. The technical result is in creating a portable device providing comfort of operation in detecting tiny optical-electronic objects, for example the systems of covert video surveillance (video recording), concealed in the details of the interior, premises, in clothes, personal things. The device contains an irradiating channel (IDC) 1, comprising a lens 2 and a visible light source 3, an observing unit (OU) made in the form of a spyglass 5, or in the form of a video camera 13 or a digital camera 17, a unit 22 for combination of the optical axes of IDC 1 and OU made in the form of a reflecting prism 23 with a reflecting face (RF) 24 mounted on the optical axes of the lens 2 and an objective of OU at an angle to them, and a non-transparent shutter 27 mounted on the optical axis of the objective of OU close to RF 24. Variants of the implementation of the device, OU are also disclosed.

Description

The invention relates to opto-electronic devices and can be used, in particular, as an indicator device to ensure the information security of office premises, offices of firms, banking institutions, etc.

A device for detecting optoelectronic objects, containing a radiating channel, including an optical radiation source, made in the form of a laser with radiation in the near infrared spectrum, a surveillance device, made in the form of a video camera, including an objective lens and a photo-receiving device, and an external monitor, whose input is electrically connected to photodetector output. The optical axis of the emitting channel through the beam-splitting device mounted in front of the lens of the video camera is aligned with its optical axis. The operation of the device is based on the irradiation of the beam of the radiating channel of the space where the optoelectronic object can be located, the formation of the image of the irradiated space around the object from the video camera reflected by the object on the photodetector of the video camera and the radiation spot identifying the object in the irradiated space. On the monitor, the operator observes the image of the irradiated space and the brightly lit spot of the detected optoelectronic object [1].

The disadvantage of the device are large dimensions and weight, due to the implementation of the surveillance device in the form of a video camera and an external monitor, as well as the need to work with the device with two hands, due to the same reasons.

The closest technical solution to the claimed is a device for detecting optoelectronic objects, containing a radiating channel, including a lens and a source of visible radiation, a surveillance device made in the form of a telescope including a lens and an eyepiece, a unit for combining the optical axes of the radiating channel and a lens of a monitoring device, made in as a reflective prism glued to the inner surface of the lens of the telescope, the reflective surface of the reflective prism mounted on optical axes of the objective of the telescope and the lens of the emitting channel at an angle to them. The operation of the device is based on irradiation with a beam of the radiating channel of the space where an optoelectronic object can be located, forming an image of the irradiated space around the object and the radiation spot from the object reflected by the telescope radiation identifying the object in the irradiated space on the operator's retina [2].

The disadvantage of this device is the presence of a luminous contour of the square in the center of the field of view when observing objects through a surveillance device, due to the presence of bubbles in the glass of a reflective prism and a high concentration of radiation emitting channel. This is due to diffraction scattering, reflection and refraction of radiation on these bubbles and a change in the direction of radiation of individual rays of the radiation beam of the radiating channel, which leads to the glow of the edges of the reflective prism.

The basis of the invention is the task of creating a portable device that provides detection of miniature objects, such as CCTV, disguised in the details of the interior, premises, clothing, personal belongings, and ensuring the comfort of its operation.

The invention according to the first embodiment consists in that an optoelectronic object detection device comprising a radiating channel including a lens and a source of visible radiation, a viewing device made in the form of a telescope including an objective and an eyepiece, and a unit for combining the optical axes of the radiating channel and objective a telescope made in the form of a reflective prism, the reflecting face of which is mounted on the optical axes of the objective and the lens of the radiating channel at an angle to them, unlike the prototype in The optical axis alignment unit of the emitting channel and the telescope lens is fitted with an opaque flap mounted on the lens axis near the reflecting face of the reflective prism, and the dimensions of the opaque damper are not smaller than the projection of the reflecting face onto the opaque flap.

A transparent plane-parallel plate is inserted into the device, mounted either in front of the lens or behind it, and the reflective prism is glued to the inserted plane-parallel plate on the side facing the eyepiece.

The invention according to the second embodiment consists in that an optoelectronic object detection device comprising a radiating channel including a lens and a source of visible or infrared radiation, a surveillance device made in the form of a video camera including a lens and a photoreceiver, and a monitor, and an optical alignment unit the axes of the radiating channel and the lens of the video camera, made in the form of a reflective prism, the reflecting face of which is mounted on the optical axes of the lens of the video camera and the lens radiating its channel at an angle to them, unlike the prototype, a transparent plane-parallel plate and an opaque damper are inserted into it, with a transparent plane-parallel plate mounted in front of the camera lens, a reflective prism is glued to its surface facing the lens, the opaque valve is mounted on the lens axis near the reflecting the faces of the reflective prism, and the dimensions of the opaque flap are not smaller than the projections of the reflecting facet onto the opaque flap.

In the device according to the second embodiment, the dimensions of the opaque flap in the projection on the entrance pupil

- 1 011843 lenses of the video camera are made not larger than half of its diameter.

According to the second variant, an eyepiece is inserted into the device, and the monitor is small-sized and installed in the plane of the eyepiece objects.

In the device according to the second variant, the radiation source is made in the form of a semiconductor laser with radiation in the near infrared spectrum, and the transparent plane-parallel plate is made in the form of a light filter with a transmission maximum in the range of the spectrum coinciding with the radiation spectrum of the semiconductor laser.

In the device according to the second variant, the radiating channel, the transparent plane-parallel plate, the reflective prism and the opaque flap are made in the form of a separate removable unit.

In the device according to the second variant, a power supply and a switch are inserted into a separate removable unit, the output of the power supply unit being connected via a switch to the input of the radiation source of the emitting channel.

According to the second variant, a two-color or three-color LED and a discharge level detection unit of the power supply unit, whose outputs are connected to a two-color or three-color LED, are entered into a separate removable unit, and the input is via a switch with a power supply unit.

The invention according to the third variant consists in that an optoelectronic object detection device comprising a radiating channel including a lens and a source of visible radiation, a surveillance device made in the form of a digital camera including a lens, a photo-receiving device, an image recording unit and a monitor, and a unit combining the optical axes of the radiating channel and the lens of a digital camera, made in the form of a reflective prism, the reflecting face of which is mounted on the optical axes of the lens a digital camera and a radiating channel lens at an angle to them, unlike the prototype, a transparent plane-parallel plate and an opaque valve are inserted into it, with a transparent plane-parallel plate installed in front of the lens of a digital camera, a reflective prism and an opaque valve are glued to its surface facing the lens mounted on the axis of the lens near the reflecting face of the reflective prism, and the dimensions of the opaque flap are made not smaller than the projection of the reflecting face onto the opaque flap.

In the device according to the third variant, the dimensions of the opaque flap in the projection on the entrance pupil of the lens of a digital camera are not larger than half of its diameter.

In the device according to the third variant, the radiating channel, the transparent plane-parallel plate, the reflective prism and the opaque flap are made in the form of a separate removable unit.

In the device according to the third variant, a power supply and a switch are inserted into a separate removable unit, with the output of the power supply unit being connected via a switch to the input of the radiation source of the emitting channel.

In the device according to the third variant, a two-color or three-color LED and a discharge level detection unit of the power supply unit, whose outputs are connected to a two-color or three-color LED, are entered into a separate removable unit, and the input is through a switch with a power supply unit.

Introduction to the device for detecting optoelectronic objects in the first embodiment of an opaque valve installed on the axis of the lens near the reflecting edge of the reflective prism, and making the dimensions of the opaque valve not smaller than the projection of the reflecting edge on the opaque damper, eliminates the lack of a prototype and observe in the visual tube of the visual tube an image of objects without parasitic illumination rays of the radiating channel, which provides a solution to the problem.

Introduction to the device for detecting optoelectronic objects in the first embodiment of a transparent plane-parallel plate, installed either in front of or behind the lens, and gluing the reflective prism to the inserted plane-parallel plate from the side facing the eyepiece, in addition to solving the task, allows you to simplify the assembly and alignment of the device.

The implementation of the device according to the second variant, unlike the device according to the first embodiment, of the observation device in the form of a video camera including a lens and a photoreceiver device and a monitor, and the execution of an optical radiation source with radiation in the near infrared region of the spectrum, in addition to solving the task, provides the possibility, unnoticed by others, to carry out, for example, remotely the process of detecting optoelectronic objects in the invisible near infrared region of the spectrum, which extends a functionality of the device.

Execution in the device according to the second variant, unlike the device in the first embodiment, the dimensions of an opaque flap projected on the entrance pupil of a video camera lens not larger than half of its diameter, in addition to solving the problem, ensures the comfort of viewing the image due to the absence of a “blind” dark spot in center of view.

Introduction to the device according to the second option, unlike the device according to the first option, an eyepiece, making the monitor small-sized and placing it in the plane of the eyepiece objects, in addition to solving the task, allows minimizing the device.

Execution in the device according to the second variant, in contrast to the device according to the first variant, is

- 2 011843 radiation points in the form of a semiconductor laser with radiation in the near-infrared spectrum and performing a transparent plane-parallel plate in the form of a light filter with a maximum transmittance in the spectrum that coincides with the radiation spectrum of a semiconductor laser, in addition to solving the problem, provides the ability to embed the device into various products, for example, in a stand for a calendar calendar, while a stranger flat parallel plate is perceived as usual mirror.

Execution in the device according to the second variant, unlike the device according to the first embodiment, radiating channel, transparent plane-parallel plate, reflective prism and opaque flap in the form of a separate removable unit, in addition to solving the set task, provides the opportunity to use household or professional video camera, which expands the functionality of the device.

Introduction to the device according to the second option, unlike the device according to the first option, is in a separate removable power supply and switch unit, and the output of the power supply unit through the switch is connected to the input of the radiation source of the emitting channel, in addition to solving the task, allows the device to function as a video camera camera and as a device for detecting optoelectronic objects, which expands the functionality of the device.

Introduction to the device according to the second variant, unlike the device according to the first variant, into a separate removable unit of a two- or three-color LED and a unit for determining the discharge level of a power supply unit whose outputs are connected to a two- or three-color LED, and the input is through a switch with a power supply unit In addition to solving the task, it allows you to change or charge the power supply in time, which expands the functionality of the device.

The implementation of the device in the third embodiment, in contrast to the device in the first embodiment, of a surveillance device in the form of a digital camera, in addition to solving the main task, allows documenting the process of detecting optoelectronic objects, which extends its functionality.

The invention is illustrated by the diagrams shown in FIG. 1-7. FIG. 1-6 depict functional diagrams of examples of the device in accordance with the first, second and third variants. FIG. 7 is a diagram of the location of the entrance pupil of the lens of the observation device and the opaque flap.

The device for detecting optoelectronic objects contains a radiating channel 1, which includes a lens 2, a source of 3 visible radiation. In the examples of execution in FIG. 2, 3, 5 and 6 to reduce the size of the radiating channel 1 contains a mirror 4. In the example of execution in FIG. 4, the source 3 is made in the form of a semiconductor laser with radiation in the near infrared region of the spectrum.

The device also contains a surveillance device, made in the examples of execution in FIG. 1-3 in the form of a telescope 5, which includes the lens 6 and the eyepiece. In the exemplary embodiment of FIG. 1 the telescope 5 is made according to the Galilean system, the eyepiece 7 of which is made with a negative focal length. In the examples of execution in FIG. 2 and 3, the telescope 5 is made according to the Kepler system and contains an eyepiece 8 with a positive focal length and an image-wrapping system 9, for example, a composite prism PK-0 °, including prisms 10 and 11, respectively, BU-45 ° and VkR-45 °. Eyepieces 7 and 8 are installed with the possibility of axial movement along the arrow "X". In the exemplary embodiment of FIG. 3, the telescope 5 contains a grid 12 with a mark, installed with the possibility of axial movement together with the eyepiece 8.

The surveillance device in the exemplary embodiment of FIG. 4 is made in the form of a video camera 13 comprising a lens 14 and a photoreceiver 15, and a monitor 16. In the exemplary embodiment of FIG. 5, the eyepiece 8 is inserted into the monitoring device, and the monitor 16 is small in size and located in the plane of the eyepiece objects 8.

In the exemplary embodiment of FIG. 6, the monitoring device is designed as a digital camera 17 including a lens 18, a photoreceiver 19, an image recording unit 20, and a monitor 21.

The device includes a unit 22 combining the optical axes of the radiating channel 1 and the lens of the observation device, made in the form of a reflective prism 23, the reflecting facet 24 of which is installed on the optical axes of the objective 6, 14 and 18 of the observation device and the lens 2 of the radiating channel 1 at an angle to them. In the examples of execution in FIG. 2, 3, 5 and 6, the first along the rays of the radiating channel 1 the refractive surface of the prism 23 is made in the form of a spherical surface 25.

In the examples of execution in FIG. 3, 4-6, the device comprises a transparent plane-parallel plate 26 installed in the example of embodiment of FIG. 3 either in front of lens 6 or behind it. In the examples of execution in FIG. 4-6 transparent plane-parallel plate 26 is installed in front of the lens, respectively, 14 and 18.

In the examples of execution in FIG. 1 and 2, the reflective prism 23 is glued to the inner surface of the lens 6, and in the examples of execution in FIG. 3, 4-6 - to the surface of a transparent plane-parallel

- 3 011843 plates 26 from the side facing, respectively, to the eyepiece 8, to the lens 14 and to the lens 18. In the example of embodiment of FIG. 4, the transparent lloscope plate 26 is made in the form of a light filter with a transmission maximum in the range of the spectrum coinciding with the emission spectrum of the source 3, made in the form of a semiconductor laser with radiation in the near infrared region of the spectrum.

The device contains an opaque shutter 27 mounted on the axis of the lens 6 (Fig. 1-3), the lens 14 (Fig. 4 and 5) and the lens 18 (Fig. 6) near the reflecting face 24 of the reflective prism 23. The dimensions of the shutter 27 are not smaller the projection of the reflective facet 24 on the opaque flap 27. Structurally, the flap 27 is made, for example, in the form of a curved U-shaped plate fixed on the non-working (side) faces of the prism 23.

In the examples of execution in FIG. 4-6, the dimensions of the opaque flap 27 projected onto the entrance pupil of the lens 14 and the lens 18 are not larger than half its diameter.

In the exemplary embodiment of FIG. 6 radiating channel 1, a transparent plane-parallel plate 26, a reflective prism 23 and an opaque damper 27 are made as a separate removable unit 28. Block 28 also contains a power supply unit 29, a switch 30, a two or three-color LED 31 and a discharge level detection unit 32 of unit 29 power, the outputs of which are connected to two-or three-color LED 31, and the input through the switch 30 with the block 29 power. The output of the power supply unit 29 through the switch 30 is connected to the input of the radiation source 3 of the radiating channel 1.

FIG. 7 pos. 33 shows the diameter of the entrance pupil of the lens 14 or 18, and pos. 34 - the size of the opaque flap 27.

FIG. 1 arrows show the course of the rays in the device when it is detected in the object plane, indicated by pos. 35, lens 6, 14 or 18 of an optoelectronic object, indicated by pos. 36

The operation of the device for detecting optoelectronic objects is as follows.

In the general case, after turning on the power supply of the device, the radiating channel 1 forms in the object plane 35 of the observation device the radiation field illuminated by the rays of the source 3, which is close in shape or coincides with the field of view of the observation device. In addition, in the device in FIG. 1 and 4, lens 2, and in the device of FIG. 2, 3 and 5, 6 — the lens 2, the mirror 4 and the spherical surface 25 of the prism 23 form a radiation beam of the source 3 converging near the reflecting surface 24 of the prism 23, which after reflection from the surface 24 leaves the device with a diverging beam symmetrical to the optical axis of the lens 6 , 14 and 18. If an optoelectronic object 36 (Fig. 1) enters the radiation field of a device, its optical system focuses on the photoreceiver of an object 36 the radiation beam of source 3 that enters it, which is reflected from the photodetector and symmetrically relative to Nia caught in his source 3 beam enters the telescope viewing device 5 (FIG. 1-3), a video camera 13 (Fig. 4, 5) and the digital camera 17 (FIG. 6). The operator observes the image of objects that have fallen into the field 35 of the viewpoint of the observation device, and a bright luminous spot identifying the detected optoelectronic object 36.

In the device of FIG. 1-3, the radiation of channel 1 reflected from the object 36 by the objective 6 of the telescope 5 and the eyepiece 7 or 8 is formed on the operator's eye retina to an image of a brightly lit spot. The change in the distance to the object of observation in the device in FIG. 1 and 2 is carried out by axial movement of the eyepiece 7 or 8, and in FIG. 3 - axial movement of the grid 12 together with the eyepiece 8. The diopter adjustment of the eyepiece 8 for the features of the operator in the device in FIG. 3 carry out the axial movement of the eyepiece 8 relative to the grid 12 to obtain a sharp image of its brand.

In the device of FIG. 4, 5, the radiation of channel 1 reflected from the object 36 by the lens 14 of the video camera 13 is formed on its photodetector device 15 into an image of a brightly lit spot. The operator observes the image on the monitor 16. Changing the distance to the object of observation is carried out by axial movement of the lens 14 manually or automatically according to the signal of the autofocus unit (not shown in Fig. 5, 6). The device of FIG. 4 can be embedded, for example, in a stand for a calendar calendar, mounted on the office table and directed to the entrance door, while a stranger-parallel plate 26 made by a light filter is perceived by a regular mirror by an outsider, and the cabinet owner can see brightly on the monitor 16 a luminous spot that identifies a microvideo camera disguised in the details of clothing or visitor’s things.

In the device of FIG. 6, the radiation reflected from the object 36 by the lens 18 of the digital camera 17 is formed on the photoreceiver 19 into an image of a brightly glowing spot. The operator observes the image on the monitor 21. Changing the distance to the object of observation is carried out by axial movement of the lens 18 automatically by the signal of the autofocus unit (not shown in Fig. 5). To register the image, the operator presses the shutter button of the digital camera 17, the signal from the photoreceiver 19 is fed to block 20, where electronic or magnetic image recording is performed. Disconnecting a separate removable unit 28, the operator can use the digital camera 17 for its intended purpose.

In the exemplary embodiment of FIG. 6 when the power is turned on by the switch 30 together with the radiation source 3, the block 32 and the LED 31 turn on. The block 32 determines the level of discharge of the block 29

- 4 011843 power supply and supplies an electrical signal to the corresponding input of the LED 31. Under normal power supply unit 29, LED 31, made for example two-color, glows in one color, for example green, when power supply unit 29 is discharged, close to inoperable, LED 31 glows in another color, such as red. In this case, the operator receives information that unit 29 needs to be charged or replaced.

Information sources:

1. Volkov V.G. Night vision devices for detecting glare elements. Special equipment, 2004, No. 2, p. 2-9, photo 4.

2. RF application for invention No. 2003137062/28, BIPM, No. 16, 2005, p. 829, 830.

Claims (14)

CLAIM 1. A device for detecting optoelectronic objects, containing a radiating channel including a lens and a source of visible radiation, a surveillance device made in the form of a telescope including an objective and an eyepiece, and a unit for combining the optical axes of the emitting channel and a lens of a telescope made in the form of a reflective prism, the reflecting face of which is mounted on the optical axes of the lens and the lens of the radiating channel at an angle to them, characterized in that in the block combining the optical axes of the radiating channel and lens ritelnoy pipe inserted opaque shutter, mounted on the axis of the lens near the reflecting prism reflective faces, wherein the dimensions are made opaque flap is not less reflecting face projection on the opaque flap. 2. The device according to claim 1, characterized in that a transparent plane-parallel plate is inserted into it, mounted either in front of or behind the lens, and the reflective prism is glued to the inserted plane-parallel plate from the side facing the eyepiece. 3. A device for detecting optoelectronic objects containing a radiating channel including a lens and a source of visible or infrared radiation, a surveillance device made in the form of a video camera including a lens, a photo-receiving device, and a monitor, and a unit for combining the optical axes of the radiating channel and a video camera lens made in as a reflective prism, the reflecting face of which is mounted on the optical axes of the lens of the video camera and the lens of the radiating channel at an angle to them, characterized in that a bright plane-parallel plate and an opaque valve, a transparent plane-parallel plate installed in front of the camera lens, a reflective prism glued to its surface facing the lens, an opaque valve mounted on the axis of the lens near the reflecting face of the reflective prism, and the dimensions of the opaque valve are made not smaller than the projection of the reflecting face on the opaque flap. 4. The device according to claim 3, characterized in that the dimensions of the opaque damper in the projection on the entrance pupil of the lens of the video camera are made not larger than half its diameter. 5. The device according to claim 3 or 4, characterized in that an eyepiece is inserted into it, and the monitor is made small-sized and installed in the plane of the eyepiece objects. 6. The device according to claim 3 or 4, characterized in that the radiation source is made in the form of a semiconductor laser with radiation in the near-infrared spectrum, and the transparent plane-parallel plate is made in the form of a light filter with a transmission maximum in the range of the spectrum coinciding with the emission spectrum of the semiconductor laser . 7. The device according to claim 3 or 4, characterized in that the radiating channel, the transparent plane-parallel plate, the reflective prism and the opaque flap are made in the form of a separate removable unit. 8. The device according to claim 7, characterized in that a power supply unit and a switch are inserted into a separate removable unit, the output of the power supply unit being connected via a switch to the input of the radiation source of the emitting channel. 9. The device according to claim 8, characterized in that a two- or three-color LED and a discharge level detection unit of the power supply unit are inserted into a separate removable unit, the outputs of which are connected to the two-color or three-color LED, and the input is through a switch with the power supply unit. 10. A device for detecting optoelectronic objects containing a radiating channel including a lens and a source of visible radiation, a surveillance device made in the form of a digital camera including a lens, a photo-receiving device, an image recording unit and a monitor, and a unit for combining the optical axes of the radiating channel and a digital camera lens , made in the form of a reflective prism, the reflecting face of which is mounted on the optical axes of a digital camera lens and a radiating channel lens at an angle to the bottom m, characterized in that it introduced a transparent plane-parallel plate and an opaque damper, with a transparent plane-parallel plate mounted in front of the lens of a digital camera, a reflective prism is glued to its surface facing the lens, and the dimensions of the opaque flap are - 5 011843 yen no smaller than the projection of the reflective face on the opaque flap. 11. The device according to claim 10, characterized in that the dimensions of the opaque damper in the projection on the entrance pupil of the lens of a digital camera are not larger than half its diameter. 12. The device according to claim 10 or 11, characterized in that the radiating channel, the transparent plane-parallel plate, the reflective prism and the opaque flap are made in the form of a separate removable unit. 13. The device according to claim 12, characterized in that a power supply and a switch are inserted into a separate removable unit, the output of the power supply unit being connected via a switch to the input of the radiation source of the emitting channel. 14. The device according to claim 13, characterized in that a two or three-color LED and a discharge level detection unit of the power supply unit are inserted into a separate removable unit, the outputs of which are connected to the two-color or three-color LED, and the input is through a switch with the power supply unit.