RU108841U1 - DEVICE FOR MONITORING AND ADJUSTING LASER RANGE AND SPEED METERS - Google Patents

Abstract

 1. A device for monitoring and aligning laser distance and speed meters, including a lens, a backlight system, a test object located in the focal plane of the lens, characterized in that it is configured to receive, process and transmit data to the user through a corresponding unit with a laser interface the meter, and further comprises a set of light filters installed between the test object and the backlight system, and a set of neutral filters, the test object being configured to input and output Yes, from the optical system and moving along the optical axis, a lens operating in the spectral range of the rangefinder channel and the television channels of the laser meter is mounted coaxially with these channels, and each neutral filter located between the lens and the laser meter overlaps the entrance pupils of the laser meter lenses and is placed at an angle to their optical axis. ! 2. A device for monitoring and aligning laser distance and speed meters according to claim 1, characterized in that a grid, a set of peace and a plate with a low reflection coefficient are used as a test object.

Description

The inventive utility model relates to measuring equipment and, in particular, to devices for monitoring laser distance and speed meters, and more specifically, to devices for aligning and verifying the operation of a mono-channel optical system containing at least a television observation channel and a laser rangefinder channel.

A device for aligning the optical axes of a multi-channel system is known (patent for a utility model of the Russian Federation No. 41867), comprising two transmitting channels with emitters operating in different spectral ranges, a conjugate prism, a receiving channel consisting of an off-axis specular parabola, aperture, and a movable mirror.

The disadvantage of this design is that the device only performs the adjustment of the channels of the controlled device.

A device for monitoring a laser range finder installed in an article with a television surveillance channel (patent for utility model RF No. 40680), comprising a fiber optic delay line with input and output ends, input and output optical systems with mirror lenses, a variable radiation rejection unit, located in front of the input mirror lens, in the focus of which the first field diaphragm is installed, a illuminator placed with the possibility of lighting the first field diaphragm.

The disadvantage of this analogue is that the device performs only a range measurement function.

The closest analogue to the claimed utility model is a device for monitoring a laser rangefinder (patent for the invention of the Russian Federation No. 2222792), including a sequential lens, test object, backlight system and an additional optical unit with two parallel channels, on the axis of which there are protective glasses in the form wedges, beam splitter and flat mirror.

However, this device does not allow to control the quality of the television channel, as well as to focus the television channel to the required distance.

The task that the claimed utility model solves is to expand the functionality of the device, as well as simplifying its design.

The solution to this problem is achieved by the fact that the inventive device for monitoring and aligning laser distance and speed meters, including a lens, a backlight system, a test object located in the focal plane of the lens, is configured to receive, process and transmit data to the user through a corresponding unit with an interface a laser meter, and further comprises a set of light filters and a set of neutral filters. Moreover, the test object is configured to input and output from the optical system and move along the optical axis. A lens operating in the spectral range of the rangefinder channel and the television channels of the meter is mounted coaxially with these channels, and each neutral filter located between the lens and the meter overlaps the entrance pupils of the meter’s lenses and is placed at an angle to their optical axis. As a test object, a grid, a set of the world and a plate with a low reflection coefficient are used.

In the inventive device, a new set of structural elements and the presence of connections between them allows you to expand the functionality of the device, namely, to adjust and check the required resolution limit of television channels, to focus the television channel at the required distance, and also to receive using the tested meter pulses of the rangefinder channel with subsequent by processing them in real time and transmitting to the user the relevant information about the alignment of the optical parallelism axes of the channel of the transmitter and receiver.

The essence of the proposed utility model is illustrated in the diagram below.

The achievement of the technical result is illustrated by the description of the operation of this device in alignment and verification of alignment of the optical axes of the rangefinder and television channels and adjustment and verification of the required resolution limit of television channels.

The device consists of a lens 1, operating in a wide range of wavelengths; a test object 2 mounted in the focal plane of the lens 1 and having the ability to move along the axis of the lens; set of light filters 3; a set of neutral optical filters 4 and illuminator 5. An adjustable and verified laser range and speed meter 6 comprises a rangefinder channel 7, including a transmitter channel 8 and an optical radiation receiver channel 9 that operate at a wavelength of λ ₁ , as well as television channels 10, structurally combined with a rangefinder channel and operating in the wavelength range from λ ₂ to λ ₃ . Moreover, the neutral optical filters 4 are installed in such a way that they overlap the entrance pupils of the rangefinder channel. All optical channels of the meter are connected to the data recording and processing unit with an interface 11, which has the ability to depict an electronic crosshair.

Alignment of the alignment of the axes of the television channels of the laser meter is as follows. A grid from the set of test object 2 is placed in the focal plane of the lens 1, then the grid is illuminated by the illuminator 5 and set by moving along the axis of the lens 1 according to the spectral range of the television channel and the focusing distance. Install the illuminator 5, a set of light filters 3 in accordance with the spectral range of the television channel. A set of filters is installed between the test object and the illuminator. Next, the center of the image of the crosshair of the grid is combined with the center of the electronic crosshair of the television channel by moving the video matrix, cube or spectrodivider of the television channel, using the corresponding shifts (not shown) for adjustment. To align all available television channels, repeat the same steps.

To check the alignment of the television channels, switching from one television channel to another is performed and the error in setting the alignment of the television channels relative to each other is evaluated. If necessary, the grid is adjusted at each transition from one television channel to another in accordance with the spectral range of these channels and the focusing distance. Using the grid as a test object allows you to quantify the error of alignment.

To set and check the required limit of resolution of television channels in the previously described scheme, replace the grid with the corresponding world from the set of test object 2. The world is moved along the axis of the lens 1 according to the spectral range of the television channel and the focus distance of the television channel. Observing the world through lens 1 and a television channel, focusing the channel lens sets the required resolution limit.

The introduction of the worlds makes it possible to evaluate the resolution redistribution of the channel, and the filter helps to increase the accuracy of determining resolution by highlighting the working spectral range of the television channel.

To align and check the alignment of the axes of the rangefinder and television channels, a set of neutral filters 4 is installed to reduce the optical radiation power of the transmitter channel 8 of meter 6, and each filter from the set must overlap the entrance pupils of the optical systems of the device 6 involved in the measurement. 6. A plate is installed in the focal plane of the lens 1 from a set of test object 2, respectively, wavelength λ ₁ , while the television channel operates in the range from λ ₂ to λ ₃ . Using the interface of the television channel during alignment, the image of the center of the spot of the transmitter is combined with the center of the electronic crosshair of the television channel using the adjustments of the channel of the transmitter 8, and when checking, the error in setting the axes is likewise evaluated.

To align and check the alignment of the axes of the transmitter and receiver of the rangefinder channel in the set of neutral filters 4, the filters are replaced with the corresponding ones. Moreover, the filters are installed in such a way that they overlap the entrance pupils of the transmitting and receiving optical systems of the rangefinder channel, and are at an angle to their optical axis in accordance with the size of the active area of the channel 9 receiver. Next, the meter measurement mode is activated, and the user receives processing with an interface 11 data processed in real time.

Since each optical filter covers the entrance pupils of the meter’s lenses, the error arising from superposition of alignment errors when radiation passes through the filter and vice versa is eliminated, and installing the filter at an angle to the optical axis of the lens avoids reflected glare from the filter, introducing an error into the alignment process and checks. Block 11 registers the pulses of the rangefinder channel with their subsequent processing in real time and transmitting to the user proportional information about the corresponding accuracy of alignment of the axes of the measuring channels.

Thus, the device allows you to align and check the required resolution limit of television channels, focus the television channel at the required distance, and also allows the meter to register the pulses of the rangefinder channel with their subsequent processing in real time and transmitting to the user proportional information about the corresponding accuracy of alignment of the axes of the channel axes transmitter and receiver.

In addition, the use of television channels in the meter’s electronic crosshair interface makes it possible to estimate the error in setting the alignment of the axes of the transmitter channel and television channels, as well as the error in setting the alignment of the axes of the television channels, which simplifies the design of the claimed device, since installation of additional elements is not required in this case.

Claims (2)

1. A device for monitoring and aligning laser distance and speed meters, including a lens, a backlight system, a test object located in the focal plane of the lens, characterized in that it is configured to receive, process and transmit data to the user through a corresponding unit with a laser interface the meter, and further comprises a set of light filters installed between the test object and the backlight system, and a set of neutral filters, the test object being configured to input and output Yes, from the optical system and moving along the optical axis, a lens operating in the spectral range of the rangefinder channel and the television channels of the laser meter is mounted coaxially with these channels, and each neutral filter located between the lens and the laser meter overlaps the entrance pupils of the laser meter lenses and is placed at an angle to their optical axis. 2. The device for monitoring and aligning laser distance and speed meters according to claim 1, characterized in that as a test object using a grid, a set of world and a plate with a low reflection coefficient.