RU2593258C1 - Two-degree dynamic target simulator - Google Patents

Abstract

FIELD: test equipment.

SUBSTANCE: invention relates to testing equipment and can be applied both to control over serviceability of aircraft direction-finding equipment, and simulation of complex target and background situation. Two-degree dynamic target simulator comprises vertical posts, fixed upper and lower bases, signal emitters with controlled irradiation intensity, which are arranged to move by azimuth, wherein at least one of signal emitters is installed with possibility of additional movement on elevation angle, and rotation unit with vertical rotation axis, mounted on upper base. Upper and lower ends of vertical posts are secured on fixed upper and lower bases, respectively. Lower base is provided with mounting hole, signal emitters are installed on attachment brackets, located on movable horizontal platform mounted below upper base and connected with rotation unit. Signal emitters are located at different heights between movable horizontal platform and lower base.

EFFECT: as result of expanded functionality of simulator, possibility of simulating more complex target situation is provided.

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Description

The invention relates to testing equipment and can be used to control the performance of aircraft direction finding equipment and simulate complex phono-target environment.

Known simulator of a moving target RU No. 2222034, IPC ⁷ G02B 26/00, 27/30, publ. 01/20/2004, made in the form of a collimator containing a lens, a test object illuminated by a backlight unit and located in the center of the picture plane coinciding with the focal plane of the lens, as well as a fixed and movable mirror. The swings of the movable mirror allow shifting the image of the test object, while the dimensions of the zone of the picture plane, the image of which is formed in the field of view of the tested product, will be twice the size of the linear field of view of the lens.

The main disadvantages of a moving target simulator are the simulation of only one moving target and the limited size of the simulation zone with only one plane, which does not allow creating a multi-purpose environment within the hemisphere when checking the operability of aircraft direction finding equipment.

Known simulator of a moving point RU No. 2057356, IPC ⁶ G02B 26/08, publ. 03/27/1996, comprising a monitor screen with a control device and a pulsed optical radiation source with a control unit, wherein the screen control device, made in the form of a deflection system with optical matching elements, is installed on the same optical axis as the screen and the optical radiation source. The monitor screen and the deflection system are located in the vacuum chamber, and the cooling source and the optical radiation source are located outside the vacuum chamber. The moving point simulator allows you to increase the contrast of the displayed information due to the possibility of imaging a moving point with a temperature of up to 300 K against a low-temperature background. However, the specified simulator of a moving point does not allow simulating more than one object, and the movement of the point is carried out within the monitor screen.

Closest to the claimed invention by technical nature is a two-stage dynamic target simulator RU No. 2273890, IPC G09B 9/00 (2006.01), G05B 23/00 (2006.01), F41G 7/20 (2006.01), publ. 04/10/2005, containing the upper and lower fixed bases, vertical struts, the upper ends of which are connected to each other and at the place of their connection, a vertical axis of rotation is fixed, which is included in the upper rotation unit mounted on the upper base. The lower ends of the uprights are fixed in the movable part of the lower rotation unit, the fixed part of which is mounted on the lower base. Vertical racks are made curved. The simulator contains signal emitters mounted on carriages moving along vertical struts. In addition, the simulator includes a radiation control unit, a rotation control unit, and a carriage moving unit. The movement of formed targets in azimuth is carried out by rotating vertical racks with carriages placed on them with signal emitters according to the law determined by the rotation control unit. The movement of the formed targets along the elevation angle is carried out by moving the carriages with signal emitters along the vertical racks using the carriage moving unit. Using the radiation control unit, a radiation signal is formed depending on the type of target, frequency range and power.

The main disadvantages of the prototype are the lack of testing for large products, as the test product is installed inside a two-stage dynamic simulator, and the lack of the ability to simulate dual targets.

The task to which the invention is directed is to expand the functionality of the simulator by testing large-sized devices and simulating a more complex target environment by forming both single and double targets (simulating twin missile launches).

The problem is solved in that in a two-stage dynamic target simulator containing vertical racks, fixed upper and lower bases, signal emitters with adjustable radiation intensity, installed with the possibility of movement in azimuth, while at least one of the signal emitters is installed with the possibility of additional movement along the corner of the place, and the rotation unit with a vertical axis of rotation mounted on the upper base, the upper and lower ends of the vertical racks are fixed on a fixed x the upper and lower bases, respectively, the lower base is made with a mounting hole, the signal emitters are mounted on mounting brackets located on a movable horizontal platform mounted under the upper base and connected to the rotation unit, while the signal emitters are located at different heights between the movable horizontal platform and bottom base.

And also the fact that in a two-stage dynamic target simulator, each signal emitter is made in the form of a lens collimator with a radiation source and a pinhole diaphragm.

And also because in the two-stage dynamic target simulator, the diaphragm of the lens collimator is made with two holes, and a matte diffusing plane-parallel plate is installed between the radiation source and the diaphragm.

In FIG. 1 shows a two-stage dynamic target simulator with a fairing of the tested product installed in its working area; on

FIG. 2 shows the design of a lens collimator made with a point diaphragm; in FIG. 3 shows the design of the lens collimator, the diaphragm of which is made with two holes.

A two-stage dynamic target simulator contains vertical racks 1, the upper and lower ends of which are fixed on a fixed upper base 2 and lower base 3, respectively, signal emitters 4 with adjustable radiation intensity, mounted for movement in azimuth, a rotation unit 5 with a vertical axis of rotation O, mounted on the upper base 2. The lower base 3 is made with a mounting hole 6. Signal emitters 4 are mounted on mounting brackets 7 located on the movable horizontal tal platform 8 mounted below the upper base 2 and connected to a rotation unit 5. The signal emitters 4 are arranged at different heights between the movable horizontal platform 8 and a lower base 3, wherein at least one of them is mounted for displacement on additional elevation.

The movement of the signal emitters 4 in azimuth is carried out using the drive 9 of the rotation unit 5 mounted on the upper base 2, and the additional movement along the elevation angle is carried out using the individual for each signal emitter 4 of the drive 10 of the elevation movement mounted, for example, on the mounting bracket 7 and consisting, for example, of an electric motor with a gearbox, a gear transmission, a balancing spring, bushings with bearings and a system of brackets (not shown in the drawing).

Drives 9 and 10, as well as signal emitters 4, are controlled by an electronic control device 11 containing three blocks — a control unit 12 of a drive 9 of a rotation unit 5, a control unit 13 of an angular displacement drive 10 and a control unit 14 of signal emitters 4, which is intended to be switched on on / off and adjusting the radiation intensity of the signal emitters 4.

For simplicity, the drawing shows the connection of the control units 13 and 14 of the electronic control unit 11 with only one emitter of signals 4 and one drive 10 angular movement.

For clarity, the fairing 15 of the tested device 16 is shown, installed in the working position when testing through the mounting hole 6.

The signal emitters 4 can be made in the form of lens collimators (Fig. 2), containing a sequentially mounted lens 17, a pinhole diaphragm 18, a radiation source 19, the input of which is connected to the output of the control unit 14. As a radiation source 19, a TRSh 1500 lamp can be used -2300. To simulate a more complex target environment, for example, to simulate a twin launch missiles, the diaphragm 18 can be made with two holes (Fig. 3), which can be located relative to each other, for example, at a distance of 10 angular minutes vertically or 30 angular minutes horizontally , which corresponds to a distance between them of 0.35 and 1 mm, while between the radiation source 19 and the diaphragm 18 is installed matte scattering plane-parallel plate 20, for example, of magnesium fluoride, necessary for uniform illumination of TIFA diaphragm 18.

Two-stage dynamic target simulator works as follows. During testing, the fairing 15 of the tested device 16 is installed in the working area of the simulator through the mounting hole 6 located on the lower base 3. The electronic control device 11 supplies power to the radiation sources 19 of the signal emitters 4, to the drive 9 of the rotation unit 5 and to the drive 10 of the angular movement emitters of signals 4. The electronic control device 11 through the control unit 12 allows you to control the speed of rotation of the drive 9 of the rotation unit 5, through the control unit 13 - speed moving the drive 10 angular movement of the signal emitters 4 and through the control unit 13 allows you to connect or disconnect the necessary signal emitters 4, increasing or decreasing the number of simulated objects, as well as adjust the currents of the radiation sources 19 in the range of 0.3-0.6 A, changing the energy light , for example, in the range from 3.94 × 10 ^-9 to 2.03 × 10 ^-7 W / cm ² for the possibility of simulating various types of targets.

The motion of the 4 targets generated by the emitters of the signals in azimuth is carried out by rotating the movable horizontal platform 8 using the rotation unit 5, for example, in the range of 0-340 °, and additional movement along the elevation angle is carried out by the elevator movement drive 10, for example, in the range of 0-60 °. The size of the mounting hole 6 is limited by the distance between the uprights 1 and the diameter of the movable horizontal platform 8.

The mounting brackets 7 allow you to install the emitters of the signals 4 at different heights between the movable horizontal platform 8 and the lower base 3, which ensures simulation of targets in the entire field of view of the tested device 16.

Performing a two-stage dynamic target simulator in accordance with the claimed features makes it possible to install the simulator on the body of the device under test, directly above its fairing, which allows to expand the simulator's functionality by testing large-sized products and simulating a more complex target environment by forming both single and double moving targets in the entire field of view of the device under test, thereby increasing the reliability of the control DF spine aviation equipment.

Claims (3)

1. A two-stage dynamic target simulator containing vertical racks, fixed upper and lower bases, signal emitters with adjustable radiation intensity, installed with the possibility of movement in azimuth, while at least one of the signal emitters is installed with the possibility of additional movement in elevation, and the node rotation with a vertical axis of rotation mounted on the upper base, characterized in that the upper and lower ends of the uprights are fixed on the fixed upper and lower bases, respectively, a lower base formed with a mounting hole, signal emitters installed on the mounting bracket disposed on the movable horizontal platform mounted below the upper base and connected to the rotation unit, wherein the signal emitters situated at different heights between the movable horizontal platform and lower base. 2. The two-stage dynamic target simulator according to claim 1, characterized in that each signal emitter is made in the form of a lens collimator with a radiation source and a pinhole diaphragm. 3. The two-stage dynamic target simulator according to claim 2, characterized in that the diaphragm of the lens collimator is made with two holes, and a matte diffusing plane-parallel plate is installed between the radiation source and the diaphragm.

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