RU81305U1 - STAND FOR SIMULATION OF PHONO-TARGET SITUATION - Google Patents

Abstract

The utility model relates to devices for optical testing of infrared systems, in particular, to stands for simulating a phono-target environment and can be used, for example, in testing homing heads. The essence of the utility model lies in the fact that the stand for simulating the phono-target environment, containing a background simulator collimator, consisting of an optically coupled radiation source, a test object, a flat mirror and a mirror lens, and a target simulator, in contrast to the prototype, additionally contains a collimator simulating false targets, a first beam splitter, a second beam splitter, a block of mirrors, an output mirror and a device for attaching the item to be tested, a collimator for simulating a target and a collimator for simulating false targets From an optically coupled radiation source, interchangeable test object, a wrapping system, a flat mirror and a mirror lens, a wrapping system is additionally introduced into the background simulation collimator, while the wrapping system of each collimator consists of a first lens, the plane of the best installation of which is aligned with the plane of the test object and the second lens, the plane of the best installation of which is combined with the focal plane of the mirror lens, while the wrapping systems of the collimator simulate the target and False target simulators are equipped with permanent spectral filters, all collimator wrap systems are equipped with replaceable filters, while the target simulator and background simulator are optically coupled to the first beam splitter, the second beam splitter and output mirror, the false target simulator is optically coupled to the mirror block, the second beam splitter and an output mirror, and the mirror unit consists of two mirrors that can swing in opposite directions, the output mirror has the possibility the oscillation capacity along two axes, and the device for mounting the product under test has the ability to tilt along two axes.

The stand may include a rectangular shutter made of an opaque material and having the ability to rotate around an axis perpendicular to the optical axis of the collimator, located at the output of at least one collimator. The stand may also contain an iris diaphragm of variable diameter, placed in at least one collimator. 1 Fig.

Description

The utility model relates to devices for optical testing of infrared systems, in particular, to stands for simulating a phono-target environment and can be used, for example, in testing homing heads.

The closest set of features to the proposed technical solution is a stand for simulating a phono-target environment [1], containing a background simulator collimator consisting of an optically coupled radiation source, a test object, a flat mirror and a mirror lens, and a target imitation collimator. The test object is made in the form of an opaque radiating transparency mask having a slot simulating a target. The radiation from a source simulating radiation from a target passes through a slot. One of the sides of the mask is made mirror-reflective and is irradiated with an additional emitter that simulates background radiation. The radiation transmitted through the mask (imitation of the target) and the radiation reflected from the mask (imitation of the background) are directed by a flat mirror onto a common mirror lens, and the mask is mounted in the focal plane of the mirror lens.

The disadvantage of this device is the lack of functionality, namely: it is not possible to simulate false targets, and, accordingly, the ability to simulate the scattering of false targets from the target and among themselves, it is not possible to isolate the working spectral range of collimators, it is not possible to quickly select spectral subbands inside operating spectral range, the ability to quickly adjust the radiation power is not provided, the ability to simulate different x positions and angular velocities of the target and false targets in the field of view of the item under test

and changes in the angular dimensions of the target and false targets, it is not possible to check the product for various inclinations with respect to incident radiation,

The objective of the utility model is to expand the functionality of the stand for a comprehensive study by providing a background-target environment that is closest to the real conditions.

The essence of the utility model lies in the fact that the stand for simulating the phono-target environment, containing a background simulator collimator, consisting of an optically coupled radiation source, a test object, a flat mirror and a mirror lens, and a target simulator, in contrast to the prototype, additionally contains a collimator simulating false targets, a first beam splitter, a second beam splitter, a block of mirrors, an output mirror and a device for attaching the item to be tested, a collimator for simulating a target and a collimator for simulating false targets From an optically coupled radiation source, interchangeable test object, a wrapping system, a flat mirror and a mirror lens, a wrapping system is additionally introduced into the background simulation collimator, while the wrapping system of each collimator consists of a first lens, the plane of the best installation of which is aligned with the plane of the test object , and the second lens, the plane of the best installation of which is combined with the focal plane of the mirror lens, the wrapping systems of the collimator simulating the target and collimato False target simulations are equipped with constant spectral filters, all collimator wrapping systems are equipped with replaceable filters, while the target simulation collimator and background simulation collimator are optically coupled to the first beam splitter, the second beam splitter and output mirror, the false target simulator is optically coupled to the mirror unit, the second beam splitter and an output mirror, the mirror unit consisting of two mirrors having the ability to swing in opposite directions, the output mirror has the ability to Chania on two axes, and a device for attaching scanned product has the ability of inclination in two axes.

The stand may include a rectangular shutter made of an opaque material and having the ability to rotate around an axis perpendicular to the optical axis of the collimator, located at the output of at least one collimator.

The stand may also contain an iris diaphragm of variable diameter, placed in at least one collimator.

The introduction of an additional collimator simulating false targets in the stand allows additionally to simulate false targets in the field of view of the item being tested to simulate a target and background.

The presence of a replaceable test object as part of a collimator simulating a target and a collimator simulating a false target allows you to change the simulation of the target and false targets, for example, change the angular dimensions.

The implementation of the wrapping system of each collimator so that it consists of a first lens, the plane of the best installation of which is aligned with the plane of the test object, and a second lens, the plane of the best installation of which is aligned with the focal plane of the mirror lens, provides a parallel path of rays between the first and second lenses of the wrapping system, which makes it possible to place interchangeable filters between the lenses of the reversing system, thereby providing the possibility of quick allocation of spec sweeping sub-bands within the working spectral range, as well as the possibility of operational stepwise adjustment of radiation power.

Equipping the wrapping systems of the target collimator and the false collimator with constant spectral filters makes it possible to isolate for these collimators a working spectral range that simulates the spectral composition of the radiation in which the corresponding systems of the product under test operate.

Optical connection of the target simulation collimator and the background simulation collimator with the first beam splitter, second beam splitter and output

With a mirror, it allows directing radiation simulating the target and background to the output mirror and then to the product under test.

The optical connection of the collimator simulating false targets with a block of mirrors, a second beam splitter and an output mirror allows you to send radiation simulating false targets to the output mirror and then to the product under test.

The execution of the block of mirrors consisting of two mirrors having the ability to swing in opposite directions, allows you to simulate two false targets, scattering from the target and among themselves.

The presence of the output mirror, which has the ability to swing along two axes, provides a simulation of various positions and angular velocities of the target and false targets in the field of view of the tested product.

The presence of a device for fastening the tested product, which makes it possible to slope the tested product in two axes, allows you to check the product for various inclinations with respect to incident radiation.

The presence at the output of at least one collimator of a rectangular curtain made of an opaque material and having the ability to rotate around an axis perpendicular to the optical axis of the collimator provides additional possibilities for smooth operational adjustment of radiation power.

The presence of a variable diameter iris diaphragm in at least one collimator provides additional possibilities for smooth operational adjustment of radiation power.

Thus, the stand provides additional opportunities for simulating false targets scattering from the target and between each other, operational stepwise and smooth adjustment of the radiation power of the target, false targets and background, highlighting the spectral working ranges of the target and false targets and narrower spectral subbands within the working ranges, by changing the angular position and angular velocity of the target and false

goals in the field of view of the inspected product, the possibility of various slopes of the inspected product, which proves the increase in the functional capabilities of the stand.

A diagram of a utility model is shown in the drawing.

A stand for simulating a phono-target environment includes a target simulation 1 collimator, background 2 simulation collimator, false targets simulation collimator 3, a first beam splitter 4, a second beam splitter 5, a mirror unit 6, an output mirror 7, and a device 8 for attaching a tested item. The target simulation collimator 1 and the false target simulation collimator 3 consist of optically coupled radiation source 9, a replaceable test object 10, a wraparound system 11, a flat mirror 12, and a mirror lens 13. The background simulation 2 collimator consists of optically coupled radiation source 9, a test object 14, a wrapping system 11, a flat mirror 12 and a mirror lens 13. In all collimators, the wrapping system 11 contains a first lens 15, the plane of the best installation of which is aligned with the plane of the interchangeable test object 10 il and a test of object 14 and a second lens 16, the plane of the best installation of which is aligned with the focal plane of the mirror lens 13, while the wrapping systems 11 of the collimator simulating target 1 and the collimator simulating false targets 3 are equipped with constant spectral filters 17, the wrapping systems 11 of all collimators are equipped with interchangeable filters 18. The collimator simulating the target 1 and the collimator simulating the background 2 are optically coupled to the first beam splitter 4, the second beam splitter 5 and the output mirror 7, the collimator simulating false targets 3 optical it is connected to the mirror block 6, the second beam splitter 5 and the output mirror 7. The mirror block 6 consists of two mirrors 19, 20, which can swing in opposite directions, the output mirror 7 has the ability to swing in two axes, and the device 8 for mounting the item under test has the ability to slope in two axes. At the output of at least one collimator, a rectangular shutter 21 made of

opaque material and having the ability to rotate around an axis perpendicular to the optical axis of the collimator, as well as in at least one collimator, an iris diaphragm 22 of variable diameter can be placed.

The described stand can be implemented as follows. An axial spherical mirror with the following characteristics is used as a mirror lens 13 of the collimator simulating target 1 and the collimator simulating false targets 3: light diameter of about 180 mm, relative aperture of about 1: 6, so the focal length will be about 1000 mm. An axial spherical mirror is mounted in a frame mounted on one end of a metal pipe of the corresponding diameter and length. At the other end of the pipe, a frame is fixed with a flat mirror 12 mounted in the focal plane of the axial spherical mirror at an angle of 45 ° to the optical axis. In the hole made in the cylindrical side of the pipe, the wrapping system 11 is fixed in the frame. The rim of the wrapping system 11 has a cut. Along the edges of the cut in the rim of the wrapping system 11, the first lens 15 and the second lens 16 are fixed. The plane of the best installation of the second lens 16 is aligned with the focal plane of the axial spherical mirror. The combination is provided by trimming the ring installed between the rim of the wrapping system 11 and the metal pipe. The plane of the best installation of the first lens 15 of the wrapping system 11 is aligned with the plane of the interchangeable test object 10. Each interchangeable test object 10 is installed in a separate hole along the edge of the rotary disk. The swivel disc is mounted on a stand. By moving the rack, we install a removable test object 10 in the plane of best installation of the first lens 15 of the wrapping system 11. When the disk is turned into the beam, the next interchangeable test object 10 is installed. As the interchangeable test object 10, diaphragms with a round hole having different angular angles can be used dimensions that mimic a target or a false target.

The collimator simulating target 1 and the collimator simulating false targets 3 simulate the spectral composition of the radiation in which the corresponding systems of the product under test operate. To do this, the wrapping systems of the target simulation collimator 1 and the false targets simulation collimator 3 are equipped with constant spectral filters 17 fixed in the frame of the wrapping system 11 between the first lens 15 and the second lens 16. The edge of the rotary disk enters the frame of the wrapping system 11, the holes of which are fixed replaceable filters 18, including spectral and neutral filters. When the disk is turned into the beam path, the necessary replaceable filter 18 is installed, thereby providing the possibility of operative allocation of spectral subbands within the working spectral range, as well as the possibility of operational stepwise adjustment of the radiation power.

Behind the disk with test objects 10, a radiation source 9 is located. For the collimator simulating target 1 and the collimator simulating a false target 3, radiation sources “MIKRON M360 Blackbody Calibration Source” from MIKRON Infrared, Inc. are used. USA In the parallel path of rays from the collimator simulating the target 1 and from the collimator of the false target 3, a rectangular shutter 21 is installed, made of an opaque material and having the ability to rotate around an axis perpendicular to the optical axis of the collimator. Shutter 21 provides additional features for smooth operational adjustment of radiation power. The electric motor rotates the shutter 21 about an axis through an angle of 90 °.

The design of the background simulation collimator 2 is similar to the design of the collimators 1, 3. As a mirror lens 13 of the background simulation collimator 2, a spherical mirror with a diameter of about 190 mm and a focal length of about 250 mm is used, respectively, the relative aperture is about 1: 1.6. In the background simulation collimator 2, as a test object 14, a constant aperture with a round hole is used, the angular value of which slightly exceeds the field of view of the test

products. Near the entrance pupil of the second lens 16 of the wrapping system 11 of the collimator simulating the background 2 is placed iris diaphragm 22 of variable diameter.

A radiation source 9, Model M316 Blackbody Calibration Source, manufactured by MIKRON Infrared, Inc., was used for the background simulation 2 collimator. USA

In the direction of the beam behind the first beam splitter 4, a second beam splitter 5 is located, then an output mirror 7 and a device 8 for attaching the item under test.

The collimator simulating a false target 3 is located towards the collimator simulating a target 1, but with an offset to accommodate the block of mirrors 6. The block of mirrors 6 is located along the beam behind the collimator simulating a false target 3. The block of mirrors 6 consists of two mirrors 19, 20, with the possibility of swing in opposite directions. The reversal of the mirrors 19, 20 in opposite directions occurs when a control voltage is applied to the electric motors. The speed adjustment of the mirrors 19, 20 is performed by the control voltage specified from external control signals. Further along the beam there is a second beam splitter 5, on which the parallel light beams from all collimators 1, 2, 3 of the stand are combined. After the second beam splitter 5, the radiation of the collimators 1, 2, 3 falls on the output mirror 7.

The output mirror 7 can carry out independent simultaneous swinging along two axes. Mirror 7 is installed in the housing. The rotation of the mirror 7 around the horizontal and vertical axis is carried out by electric motors, which is used as a torque sensor DM-10. The law of motion of the mirror 7 is set by external commands. The output mirror 7 directs the radiation of the collimators 1, 2, 3 to the entrance pupil of the tested product installed in the device 8 for mounting the tested product, with the possibility of bending in two axes.

The stand works as follows.

In the collimators 1, 3, the radiation of the source 9 falls on a replaceable test object 10 installed in the plane of best installation of the first lens 15 of the wrapping system 11. After the first lens 15, the radiation goes in a parallel beam, passes a constant spectral filter 17 and a replaceable filter 18. Constant spectral filter 17 allows you to select for the collimators 1, 3 the working spectral range, for example, 1.5 microns - 2.5 microns for the collimator simulating a false target 3, 3 microns - 5 microns for the collimator simulating the target 1. The replacement filter 18 provides the opportunity allocation of narrow spectral ranges within the working spectral range to determine the spectral characteristics of the tested product or stepwise changes in radiation intensity when determining the sensitivity of the tested product. An empty window in the disk with replaceable filters 18 acts as a neutral filter of zero density. The second lens 16 of the wrapping system 11 focuses the radiation beam onto a plane mirror 12 mounted at an angle of 45 ° to the optical axis, located in the focal plane of the mirror lens 13. The mirror lens 13 converts the radiation incident on it into parallel. The parallel beam of rays emerging from the collimator passes by a rectangular shutter 21. When turning, the shutter 21 overlaps part of the parallel beam of rays, providing smooth operational adjustment of the radiation power.

The simulation collimator 1 and the false target simulation collimator 3 create a radiation flux in a given spectral operating range that simulates the image of the target and false targets in the field of view of the tested product. In collimators 1, 3, it is possible to change the angular dimensions of an image simulating a target and false targets, the ability to change the radiation intensity or to isolate narrow spectral intervals within the working spectral range.

The background simulator collimator 2 works similarly to the above, the differences are that a circular diaphragm having an angular size exceeding the field of view of the product under test is selected as test object 14, replaceable filters 18 include only neutral filters of different densities, and near the output the pupil of the second lens 16 of the wrapping system 11 is placed iris diaphragm 22 of variable diameter. Thus, the background simulation collimator 2 creates a radiation flux that simulates the background, and the possibility of operational stepwise and smooth changes in the radiation intensity is provided.

The radiation of the collimator simulating the target 1 passes through the first beam splitter 4, the second beam splitter 5, is reflected from the output mirror 7 and falls on the entrance pupil of the tested product installed in the device 8 for mounting the tested product.

The radiation of the background simulator collimator 2 is reflected from the first beam splitter 4, and then goes the same as the radiation of the target simulator 1 collimator.

The radiation of the collimator simulating a false target 3 falls on a block of mirrors 6 is divided by a block of mirrors into two beams simulating radiation from two false targets. Further, the radiation is reflected from the second beam splitter 5, from the output mirror 7 and enters the entrance pupil of the tested product installed in the device 8 for mounting the tested product. When swinging in opposite directions of the mirrors 19, 20, the angle between the beams that simulate radiation from two false targets changes, and the false targets fly apart.

The output mirror 7, swinging along two axes, provides the ability to simulate the complex movement of the target and false targets in the field of view of the tested product.

The device 8 for mounting the test product provides the ability to tilt the test product in two axes.

Thus, the stand provides the possibility of forming in the field of view of the tested product:

   - images of the target in the working spectral range that simulates the spectral composition of the radiation, in which the corresponding systems of the product under test operate with the possibility of changing its angular dimensions, stepwise and smooth adjustment of the radiation power and the operational allocation of spectral sub-bands within the working spectral range;

- background radiation of a given spectral composition with the ability to adjust the radiation power;

- images of two false targets in the working spectral range simulating the spectral composition of the radiation, in which the corresponding systems of the product under test operate with the possibility of changing their angular dimensions, stepwise and smooth adjustment of the radiation power, quick selection of the spectral sub-bands within the working spectral range and with a variable expansion speed .

Depending on the task to be performed, it is possible to supply to the entrance pupil of the tested product all the radiation at the same time or only necessary, with imitation of motion or motionless, as well as the possibility of forming an image of the target and images of the false target in the spectral sub-bands within the working spectral range of the collimator. At the same time, the device for fastening the tested product allows you to carry out checks for different slopes of the tested product.

Information sources:

1. VV Tarasov, Yu.G. Yakushenkov Infrared systems of the “looking type”. Moscow, Logos, 2004, pp. 291-293 - prototype

Claims (3)

1. A stand for simulating a phono-target environment, comprising a background simulator collimator consisting of optically coupled radiation source, a test object, a flat mirror and a specular lens, and a target imitation collimator, characterized in that the stand further comprises a fake target collimator, the first a beam splitter, a second beam splitter, a block of mirrors, an output mirror and a device for mounting the product under test, a target simulation collimator and a false target simulation collimator consist of optically coupled radiation source , of a replaceable test object, a wrapping system, a flat mirror and a mirror lens, an wrapping system is additionally introduced into the background simulation collimator, while the wrapping system of each collimator consists of a first lens, the plane of the best installation of which is aligned with the plane of the test object, and a second lens, the plane of the best installation which is combined with the focal plane of the mirror lens, the wrapping systems of the collimator simulating a target and the collimator simulating a false target With spectral filters, the wrapping systems of all collimators are equipped with replaceable filters, while the target simulation collimator and the background simulation collimator are optically coupled to the first beam splitter, the second beam splitter and output mirror, the false target simulation collimator is optically coupled to the mirror block, the second beam splitter and output mirror, the mirror unit consists of two mirrors that can swing in opposite directions, the output mirror has the ability to swing in two axes, and the device for mounting The tested product has the ability to tilt in two axes. 2. The stand according to claim 1, characterized in that the output of at least one collimator has a rectangular shutter made of opaque material and having the ability to rotate around an axis perpendicular to the optical axis of the collimator. 3. The stand according to claim 1 or 2, characterized in that at least one collimator has an iris diaphragm of variable diameter.