RU2093852C1 - Gear simulating targets - Google Patents

Abstract

FIELD: SHF equipment, testing and checking of airborne radar stations, for instance, of aircraft interception and aiming radars. SUBSTANCE: gear simulating targets has echo-free chamber, reflector placed by one of face walls of echo-free chamber, radiator installed in focus of reflector and connected to output of simulator of echo signals of target, antenna of controlled object, for example, of airborne radar placed into hole in wall opposite to face wall of echo-free chamber and tested radar. characteristic feature of gear consists in manufacture of reflector in the form of truncated sphere-parabolic mirror which profile in horizontal planes resents arcs of circle and radiator or row of radiators for simultaneous emulation of several targets which are positioned on half-radius of arc of circle formed by focuses of parabolas. Each radiator is connected to its simulator of echo signal. Reflector is mounted in near zone of antenna of checked radar and is oriented with respect to this antenna so that its vertical axis passes through center of radar antenna. EFFECT: enhanced operational efficiency. 2 dwg

Description

 The invention relates to the field of microwave technology and can be used for testing and monitoring airborne radars, for example, aircraft interception and aiming radars.

 Known simulators of the target, working on the principle of relaying the radar probe signal: US patents N 3142059, 3216014, 3329953, 4517569 patent PNR N 54810, and.with. USSR N 196094, 1742984. Such simulators containing a transceiver antenna associated with a device simulating an echo signal of a target are, as a rule, passive and autonomous, i.e. not having electrical connections to the board.

 They receive the radar probe signal with their antenna, transform it in accordance with the specified characteristics of the real echo signal (create the necessary Doppler frequency shift, time delay, “calibrated” power and re-radiate this signal through the same antenna in the direction of the monitored radar.

 To radar mask the radar, to protect it from interference and environmental protection of the environment, the simulator or its antenna is usually installed in shielded rooms anechoic chambers (BEC), while the antenna of the object under test is inserted into the BEC through an opening in one of its walls.

These imitators have disadvantages:
1. The large size of the BEC, due to the need to install a simulator antenna in the far zone of the antenna of the monitored radar almost at a distance of more than 20 m from the control object.

 2. Difficulties in simulating several targets and their movement in space with given angular velocities.

 There is also known a device (prototype) for simulating targets (US patent N 4521780 class G 01 S 7/40), containing an anechoic chamber, a reflector located at one of the end walls of the BEC, made in the form of a segment of an ellipsoid, a radiating element having The microwave generator and the associated phased array of emitters, the center of which coincides with the first focus of the ellipsoid, and the receiving element of the tested homing object, for example, a guided missile with a passive homing head, located so that its center coincides with the second focus of the ellipsoid.

 The radiating element emits a number of independent rays, which, falling on different parts of the surface of the ellipsoid, are reflected from these areas and are received by the antenna of the test object. In this case, each reflected beam imitates the radiation coming from an individual target.

 The introduction of an elliptical reflector into the device made it relatively easy to solve the problem of simulating several targets and their movement in space at the same time, however, the first drawback, namely the large size of the BEC, continues to occur. Reducing the size of the BEC in this device to the size of the "near zone" of the antenna of the test object is unacceptable, because this will lead to a distortion of the plane wave front in the aperture of this antenna due to the focusing of the rays by the surface of the ellipsoid.

 In addition, the device can be used only for passive homing systems and cannot be used to control active systems, for example, airborne interception and aiming radars.

 The aim of the present invention is to reduce the size of the BEC, as well as providing the ability to control active homing systems, for example, airborne radars. This goal is achieved by the fact that in the device for simulating targets containing an anechoic chamber (BEC), a reflector located at one of the end walls of the BEC, an irradiator installed in the focus of the reflector and connected to the output of the target echo simulator, an antenna controlled by the onboard radar, inserted into the hole on the opposite end wall of the BEC, and controlled by the radar, the reflector is made in the form of a truncated spherical-parabolic mirror, the profile of which in horizontal planes is a circular arc, and in vertical parabolas, the foci of which are located at half the radius of the circular arc, and the irradiator or a number of irradiators while simulating several targets are located on the circular arc formed by the parabolic foci. In this case, each irradiator is connected to its own echo simulator, the reflector is installed in the near zone of the antenna of the monitored radar and is oriented relative to this antenna so that its vertical axis passes through the center of the radar antenna.

 In FIG. 1 shows a block diagram of a device, a top view; in FIG. 2 is a block diagram of the same device, side view.

 The device contains an anechoic chamber BEC-1, a reflector 2, an irradiator (s) 3, a simulator (s) of the ECHO signals of target 4, an antenna of a monitored airborne radar 5 and an airborne radar 6.

 Reflector 2 is located at one of the end walls in the near zone (Fresnel zone) of the onboard radar antenna 5, which is inserted into the hole on the other end wall of BEC 1.

 The reflector 2 is made in the form of a spherical-parabolic mirror, truncated below, the profile of which in horizontal planes is an arc of circles, and in vertical parabola. In this case, the parabolic foci are located at half the radius of the circular arc and the irradiator or a number of irradiators 3 (while simulating several targets at the same time) are located on the same arc formed by the parabolic foci, i.e. on the focal arc. Each of the irradiators 3 is a transceiver antenna CB4, for example, a horn antenna. The reflector 2 is oriented relative to the radar antenna 5 so that its vertical axis passes through the center of the radar antenna 5.

 Each irradiator 3 is associated with its own echo simulator 4. Echo simulators are known and are selected according to the type of monitored radar 6. For example, for Doppler continuous-wave radar simulators according to US Pat. N 3142.059, N 3216014, N 3 329953, N 4517569, for pulsed incoherent radar simulators according to a.s. USSR N 196094, for coherent pulsed radar of low duty cycle according to A. with. USSR N 1742984, etc.

The device operates as follows:
The electromagnetic wave of the probe signal of the radar 6 emitted by the antenna of the radar 5, falls on the spherical parabolic reflector 2. The signal reflected from the spherical parabolic reflector 2 is fed to the input of the irradiator 3.

 The signal received by the irradiator 3 is fed to a well-known echo signal simulator 4, which converts the radar probe signal 6 in such a way that its characteristics become close to the characteristics of the real target echo (i.e., it creates the necessary Doppler frequency shift, time delay, and normalized power etc.) and radiates it through the same irradiator 3 in the direction of the reflector 2. Reflector 2 transforms the spherical wave of the irradiator 3 into a quasi-plane wave and sends it in the direction of the radar antenna 5, thereby simulating an endlessly deleted target.

 Simulation of several targets with different azimuthal positions is provided by several of the same type of irradiators 3 located on the focal arc (see figure 1). The azimuthal movement of the target is created by moving the irradiator along the focal arc.

 Simulation of several targets with different positions on the "slope" is created by several irradiators 3, shifted vertically at different distances from the "focal arc". The movement of the target on the slope is due to the movement of the irradiator 3 vertically.

 Justification for the choice of shape and size of the reflector.

 It is known that to simulate an echo signal from an infinitely remote target, it is necessary to create a flat front E.M. in the aperture of the tested radar antenna. waves perpendicular to the direction of the target.

 This is achieved either by removing the point source of radiation (horn antenna of the simulator) in the far zone of the radar antenna, or by using collimating devices (large parabolic mirrors, lenses, etc.) that allow to obtain a plane wave in the aperture of the radar antenna when these devices are located in near zone antenna.

 In microwave measurement technique, collimators in the form of a truncated parabolic mirror with an irradiator in its focus are most common. Such collimators are usually used to take antenna patterns in the near Fresnel zone, which significantly reduces the size of the workplace, i.e. BEC.

 Truncation of the paraboloid mirror can significantly reduce the shadow effect of the irradiator and the reaction of the mirror to the irradiator due to the location of the irradiator outside the zone of the most intense field of the mirror (see figure 2).

где
F фокусное расстояние параболоида,
см. "Справочник по основам радиолокационной техники", Воениздат М. 1967 г.To simulate several targets, it is necessary to create a fan radiation pattern that has several portion rays, each of which simulates an infinitely distant target. A parabolic antenna creates a fan of portioned (independent) diagrams if there are several irradiators and they are out of focus at different distances. The shift ΔX of each independent feed from the focus of the parabolic mirror will shift the maximum of the radiation patterns by the angle Δθ. These quantities are related by the relation:

Where
F the focal length of the paraboloid,
see "Guide to the basics of radar technology", Military Publishing M. 1967

 However, when the irradiator moves out of focus, defocusing occurs, as a result of which the wavefront is distorted and the antenna gain decreases. This drawback of parabolic antennas limits the limits of simulating targets in the "angle" to almost angles of about 10 degrees.

 This disadvantage of parabolic antennas is eliminated in spherical antennas. A shallow spherical mirror acts almost like a parabolic mirror if the irradiator is located at half the radius of the sphere, and the direction of its maximum radiation is oriented along the radius, see the same "Guide to the basics of radar technology." However, spherical antennas have another drawback: in principle, the shadow influence of the irradiator cannot be avoided in them, since the beam reflected from the mirror always passes through the irradiator and the center of the sphere.

 For most radars, the magnitude of the viewing and tracking along the slope is much smaller than the size of the viewing and tracking along the azimuth. Therefore, to expand the target simulation zone in the horizontal (azimuthal) plane, it is advisable to use the spherical profile of the mirror, preserving the parabolic profile in the vertical plane to eliminate the shadow influence of the irradiator, that is, use a spherical-parabolic mirror as a reflector. Thus, the reflector should be made in the form of a truncated spherical-parabolic mirror, the profile of which in horizontal planes is an arc of a circle, and in vertical parabola. The foci of the parabolas should be located at half the radius of the circular arc. If we place the irradiators on this “focal arc”, then each irradiator will use his reflector mirror to create his own partial radiation pattern that simulates the target without restricting the limits of imitation in the horizontal plane.

 It should be noted that the disadvantage of spherical mirrors, in this case, a spherical profile in the horizontal plane, is a certain distortion of the plane of the wave front, depending on the ratio of the dimensions of the radar antenna to the dimensions of the spherical reflector, and therefore to the dimensions of the entire device.

где
Δα - отклонение фронта волны от идеальной плоскости в угловых единицах;
r радиус антенны РЛС;
R радиус сферы.The deviation of the wave front from the ideal plane in the aperture of the radar antenna, calculated according to the laws of geometric optics, is associated with the radii of the radar antenna and the sphere by the ratio:

Where
Δα is the deviation of the wave front from the ideal plane in angular units;
r radius of the radar antenna;
R is the radius of the sphere.

To simulate a plane wave front in the aperture of a radar antenna with an error not exceeding 0.5 ^o, these radii must satisfy the condition R≥4r or R≥2D, where D is the diameter of the radar antenna.

 This condition applies to spherical reflectors. However, it is also valid for shallow spherical parabolic mirrors.

 Thus, the distance between the reflector and the antenna of the controlled object must be such that the reflector is in the near zone of this antenna, while the specified distance should not be less than two of its diameters.

 The use of a reflector in the form of a truncated spherical parabolic mirror located in the near zone of the antenna of the controlled object compares the proposed device from the prototype, as it significantly reduces the size of the shielded BEC room and provides the ability to control active homing systems, for example, airborne radars.

 As a result, the use of this device will reduce material costs for the construction of BEC and ensure the monitoring of the health of airborne radars in the field immediately before their use.

 At the NGAZ Sokol plant, together with NIAT, an experimental model of a device for simulating targets made on the basis of a parabolic reflector was tested.

Based on the test results, a report was compiled on 12/14/92 with positive results, the main of which are as follows:
1. The device allows for the development and monitoring of airborne radars in small rooms, the dimensions of which are reduced by 5-6 times compared to existing BEC.

2. The device allows you to simulate simultaneously multiple targets in space and their movement in azimuth and inclination within approx. ± 10 ^o by moving the irradiator or irradiators of a parabolic mirror in its focal plane.

 Thus, it has been confirmed that several targets can be simulated using a single reflector located in the near Fresnel zone of an antenna of a controlled radar.

Claims (1)

 A device for simulating targets, containing an anechoic chamber (BEC), a reflector located at one of the end walls of the BEC, an irradiator installed in the focus of the reflector and connected to the output of the target echo simulator, an antenna of a controlled airborne radar station (radar) inserted into the hole on the opposite end wall of the BEC and a controlled radar, characterized in that the reflector is made in the form of a truncated spherical parabolic mirror, the profile of which in horizontal planes is a circular arc in vertical parabolas, the foci of which are located on half the radius of the circular arc, the irradiator or a series of irradiators while simulating several targets are located on the circular arc formed by parabolic foci, with each irradiator connected to its own echo simulator, the reflector is installed in the near area of the antenna of the radar being monitored and oriented relative to this antenna in such a way that its vertical axis passes through its center.

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