RU40680U1 - DEVICE FOR MONITORING A LASER DANGER, INSTALLED IN A PRODUCT WITH A TV SURVEILLANCE CHANNEL - Google Patents

Abstract

1. Device for monitoring a laser range finder mounted in an article with a television observation channel, comprising a fiber optic delay line with input and output ends, an input optical system with an input lens and an output optical system with an output lens, characterized in that the input and output lenses made mirror, in the input optical system introduced a block of variable radiation deflection, located in front of the input mirror lens, in the focus of which is set the first field diameter a ragma, followed by a first illuminator arranged to illuminate the first field diaphragm, a second field diaphragm and a second illuminator arranged to illuminate the second field diaphragm located in front of the output mirror lens, the output end of the fiber-optic delay line, was introduced into the output optical system located in the focal plane of the output mirror lens coaxially with the second field diaphragm. 2. The device according to claim 1, characterized in that the output mirror lens is made in the form of a spherical mirror with a Central hole and a flat mirror. The device according to claim 1, characterized in that a photodetector device that measures the power of radiation incident on the fiber optic delay line is inserted into the input optical system. The device according to claim 1, characterized in that a radiation attenuation unit located in front of the variable radiation deflection unit is inserted into the input optical system. The device according to claim 1, characterized in that a radiation diffuser is introduced into the input optical system, located

Description

The inventive utility model relates to measuring equipment, specifically to devices for the non-track control of the output parameters of the laser range finder installed in the product with a television observation channel.

A device for aligning a product with a television observation channel is known (Great Britain, invention, application No. 2165957, MKI ⁴ G 02 B 23/00, op. 23.04.86). The known device contains features that match the following features of the claimed utility model: a mirror lens, an element that creates radiation, a spectrometer. The disadvantages of the known device include:

- the device performs only one function - product alignment;

- lack of optical elements that allow you to adjust the direction of radiation;

- the absence of optical elements that allow you to adjust the power of the laser radiation in the receiving channel of the device.

The closest analogue to the claimed utility model is a device for monitoring a laser rangefinder (Germany, invention, application No. 3700962, MKI ⁴ G 01 S 7/48, published July 28, 88), which contains a number of features that coincide with the essential features of the claimed utility model: input optical system with input lens, fiber optic

a delay line with input and output ends and an output optical system with an output lens. The technical solution of the closest analogue has several disadvantages:

- control by one device of laser range finders with different radiation wavelengths is not ensured;

- it is intended only for non-track control of a laser range finder installed in a multi-channel product;

- there is no operational control and adjustment of the direction and power of radiation.

The task to which the claimed utility model is directed is to expand the functionality of the device and increase the usability.

The solution to this problem is achieved by the fact that the device for monitoring the laser range finder installed in the product with a television observation channel contains a fiber optic delay line with input and output ends, an input optical system with an input lens and an output optical system with an output lens.

The difference from a close analogue is that the input and output lenses are made mirrored. A variable radiation deflection unit, located in front of the input specular lens with the first field diaphragm in focus, and the first illuminator placed with the possibility of lighting the first field diaphragm, is introduced into the input optical system. A second field diaphragm and a second illuminator arranged to illuminate the second field diaphragm located in front of the output mirror lens are introduced into the output optical system. The output end of the fiber-optic delay line is located in the focal plane of the output mirror lens coaxially with the second

field diaphragm. The output mirror lens is made in the form of a spherical mirror with a central hole and a flat mirror. In addition, a photodetector is introduced into the input optical system, which measures the power of radiation incident on the fiber optic delay line, a radiation attenuation unit located in front of the variable radiation deflection unit, a radiation diffuser located between the first field diaphragm and the first illuminator, and an aperture diaphragm located in front of the radiation attenuation unit.

The drawing shows a diagram of the inventive device.

The device 1 is optically coupled to a transmitting 2 and a receiving 3 channels of a controlled laser rangefinder, as well as a television channel 4 of the product 5, in which they are located.

The receiving channel of the device contains an aperture diaphragm 6, a system 7 of radiation attenuators, a unit 8 of a variable radiation deflection. Block 8 variable radiation deflection is made in the form of two optical wedges. Behind the variable radiation deflection unit 8, there is an input mirror lens 9 made in the form of a spherical mirror, and behind it the first field diaphragm 10, the radiation diffuser 11, the first lamp 12 and then the input end 13. The radiation diffuser 11 is made in the form of milk glass. A photodetector device 14 is introduced into the receiving channel of the device, which measures the radiation power at the input end 13 of the fiber-optic delay line 15.

The transmitting channel of the device 1 contains the output end 16 of the fiber-optic delay line 15 located in the focal plane of the output mirror lens. The mirror lens is made in the form of a spherical mirror 17 with a Central hole and a flat mirror 18. Between the output end 16

a fiber optic delay line 15 and a spherical mirror 17 with a central hole are located spectrodivider 19, the second field diaphragm 20 and the second lamp 21.

The operation of the device is carried out in the following sequence.

At the beginning of work using the collimator check the parallelism of the axes of the device 1. Then check the parallelism of the axes of the product 5 and measure the range. To do this, install the device 1 so that the receive channel of the device 1 is located in front of the transmitting channel 2 of the laser rangefinder of the device 5. In this case, the transmitting channel of the device 1 is located opposite the television channel of the product 5, which is optically coupled to the receive channel 3 of the laser rangefinder. The television channel 4 is turned on. The second lamp 21 is turned on and, by means of a spectrometer 19, observing the image of the second field diaphragm 20 on the screen of the television channel 4 of the product 5, the electronic crosshair is aligned with the image center of the second field diaphragm 20. The transmitting 2 and receiving 3 channels of the laser range finder are turned on. The radiation from the transmitting channel 2 of the laser range finder of the product 5, passing through the aperture diaphragm 6, the attenuator system 7, the wedge assembly 8 and the input lens 9, the first field diaphragm 10 and the radiation diffuser 12, enters the input end 14 of the fiber optic delay line 15. Power radiation at the input end 14 is controlled by the signal of the photodetector 13. The delayed radiation pulse emerging from the output end 16 passes through the output lens formed by a spherical mirror 17 with a central hole and a flat stool 18 is directed into a receiving channel 3 of the laser rangefinder product 5, which provides a measure of the range, i.e., to control the laser rangefinder.

Thus, the use of a device with a combination of essential features of the claimed utility model will allow:

1. To ensure control of a laser rangefinder with different wavelengths of radiation and verification of the parallelism of the axes of the rangefinder channel and the target monitoring device of a multi-channel product (containing, for example, a television channel, a thermal imaging channel, etc.) through the use of mirror lenses.

2. To reduce the influence on the measurement of the range of errors due to the mismatch between the full-scale and non-path conditions for the propagation of laser radiation due to the preliminary alignment of the axes of the multi-channel product;

3. To improve the usability of the claimed device, due to the following:

- using the television channel of the product for monitoring and timely adjusting the direction of radiation in the inventive device;

- operational measurement of radiation power falling into the fiber optic delay line, due to the introduction of the inventive device photodetector;

- regulation of the radiation power entering the receiving channel of the product, due to the introduction of the radiation attenuation unit into the inventive device;

adjusting the direction of radiation due to the introduction into the inventive device of the unit variable deviation of radiation and the diffuser of radiation;

- reduce the likelihood of exposure to the receiving channel of the laser rangefinder, installed in the product, by radiation directed into the receiving channel of the device, due to the introduction of an aperture diaphragm.

Claims (6)

1. Device for monitoring a laser range finder mounted in an article with a television observation channel, comprising a fiber optic delay line with input and output ends, an input optical system with an input lens and an output optical system with an output lens, characterized in that the input and output lenses made mirror, in the input optical system introduced a block of variable radiation deflection, located in front of the input mirror lens, in the focus of which is set the first field diameter a ragma, followed by a first illuminator arranged to illuminate the first field diaphragm, a second field diaphragm and a second illuminator arranged to illuminate the second field diaphragm located in front of the output mirror lens, the output end of the fiber-optic delay line, is introduced into the output optical system located in the focal plane of the output mirror lens coaxially with the second field diaphragm. 2. The device according to claim 1, characterized in that the output mirror lens is made in the form of a spherical mirror with a Central hole and a flat mirror. 3. The device according to claim 1, characterized in that a photodetector device that measures the power of radiation incident on the fiber optic delay line is inserted into the input optical system. 4. The device according to claim 1, characterized in that the radiation attenuation unit located in front of the variable radiation deviation unit is introduced into the input optical system. 5. The device according to claim 1, characterized in that a radiation diffuser located between the first field diaphragm and the first illuminator is introduced into the input optical system. 6. The device according to claim 1 or 4, characterized in that an aperture diaphragm located in front of the radiation attenuation unit is introduced into the input optical system.