SU1810843A1 - Method of inspecting radio aerial - Google Patents

Description

The invention relates to radio engineering and can be used to obtain information about the quality of the shape of the surface of the reflector of the radio antenna, its radiation pattern and the direction of the axis of radio emission.

The aim of the invention is to improve the accuracy of monitoring the radio antenna by taking into account the deformations of the reflecting surface of the mirror.

This goal is achieved by improving the known method for monitoring a radio antenna, which includes illumination of flat optical reflectors (POTs), evenly located on the reflecting surface of the radio antenna mirror, by a flux of optical radiation from a source installed on the geometric axis of the radio antenna and rigidly connected to it and analysis of the distribution of radiation reflected from VET.

The improvement lies in. volume. that POOs are installed in the holes made in the mirror of the radio antenna, aligning their geometric centers with the reflection! pressing surface of the mirror. A focusing element is installed between each FET and the source of optical radiation. Then they unfold the POO at an angle

«) = 45 ° - 0.5 arctan Δ ι / Δ Yi.

where is the angle between the normal to the reflecting surface of the mirror and the normal to the POC in the plane; passing through the geometric axis of the radio antenna and the center of the 1st POO:

Δ Χι is the length of the perpendicular dropped from the center of the 1st POO onto the geometric axis of the radio antenna:

Δ Υι is the distance from the base of the 1st perpendicular to the source of optical radiation, measured towards the focus of the radio antenna.

In this position, the POT is fixed, and then three coordinates of the corresponding i-x images of the optical radiation source in the prefocal and / or extrafocal planes are determined, by which the quality of the radio antenna is judged.

1810843 A1

In two-mirror radio antenna systems on the secondary mirror, it is possible to install additional POTs tangentially to the reflecting surface, optically connected to the POT on the reflecting surface of the radio antenna mirror.

It is also possible to displace the source of optical radiation and all FETs before fixing from the reflecting surface to one side at equal distances in a direction parallel to the geometric axis of the radio antenna.

Figure 1 ... 3 shows possible versions of radio antennas with devices that implement the inventive method; figure 4 - geometric constructions to justify the angle of rotation of the normal to the surface of a flat optical reflector.

Figures 1-3 indicate: 1 - primary mirror of the radio antenna, 2 - secondary mirror of the radio antenna; 3 - geometric axis of the radio antenna; 4 - radio emission from an infinitely distant source located on the axis of the radio antenna, 5 - focus of the primary mirror of the radio antenna, 6 - focus of the radio antenna, 7 - source of optical radiation, 8 - flat optical reflectors, 9 - focusing elements. In addition, figure 4 indicated: 10 - normal to the radio reflecting surface of the antenna: 11 - angles of incidence and reflection of radio emission; 12 (1) and 12 (2) -normal of the surface of the optical reflector at two positions of the source 7 (1) and 7 (2); 13 - angles of incidence and reflection of radiation when the source of optical radiation is located in 7 (1): 14 - half of the angle between the directions to two positions of the radiation source 7 (1) and 7 (2) when viewed from the center of a flat optical reflector 8.

Figures 1 and 2 show radio antennas according to Newton's scheme with a parabaloid mirror 1. and in Fig.3 - according to the Gregory scheme with a parabaloidal mirror 1 and an ellipsoidal mirror 2. The geometric axes of radio antennas 3 are directed to an infinitely distant radio source, not shown in the figures ... Radio emission 4 is reflected from the surface of the radio antenna and is directed to the focus of the primary mirror 5, which coincides in the Newton scheme with the focus of the radio antenna 6. In the Gregory scheme, radio emission after the focus of the primary mirror 5 is reflected from the secondary mirror 2 and is directed to the focus 6 of the radio antenna. Light from the source of optical radiation 7 from the geometric axis of the antenna 3 by flat optical reflectors 8 is directed to the focus of the primary mirror 5 and the focus of the radio antenna 6. In this case, in the Gregory scheme, it is secondarily reflected from the flat optical reflector 8 mounted on the secondary mirror 2. Focusing elements 9 build an image of the source of optical radiation 7 in the focus of the radio antenna 6.

The radio antenna is monitored as follows.

Install the source of optical radiation 7 in the paraxial region of the geometric axis 3 of the radio antenna. In Figs. 1 and 3, the pre-mirror portions of the geometric axis are used, and in Fig. 2, the over-the-mirror portions of the geometric axis.

Flat optical reflectors 8. are installed in uniformly spaced along the aperture of the radio antenna holes, aligning the geometric centers of their surfaces with the radio reflecting surface 1 of the antenna. For the surface of the antenna 1 at the point corresponding to the center of the surface of the flat geometric reflector 8, the surface of the antenna 1 is taken in the absence of a hole. Without breaking the alignment, the flat optical reflector 8 is turned at an angle that ensures that the radiation from the light source 7 hits the focus of the radio antenna with the ideal surface of the mirror 1 (mirrors 1 and 2).

The justification of the mathematical expression given in the claimed method is conveniently carried out using the figure of Fig. 4. It has two parallel straight lines depicted by the lines of propagation of radio emission 4 and the geometric axis 3. We place the source of optical radiation at point 7 (1), which is the base of the perpendicular, released from the center of the flat optical reflector 8. We turn the reflector so that the radiation from m. 7 (1) went into focus 5. As follows from figure 4; (<13) + (<13) + (<11) + (<11) = = 90 °. And the angle between the normals 10 and 12 (1), equal to the sum of the angles (<11) and (<13), is 45 °. Move the source of optical radiation at point 7 (1) to point 7 (2) and turn the flat optical reflector from position 8 (1) to position 8 (2) so. so that the radiation again falls into focus 5. For this, it is necessary to turn the normal to the flat optical reflector from position 12 (1) to position 12 (2). those. by an angle (<14) equal to half the angle between the directions of two positions of the optical radiation source 7 (1) and 7 (2). The angle between the normal to the surface of the radio antenna 10 and the normal to the flat optical reflector will be the angle a, = 45 ° - (<14)

From triangle 7 (1): 8: 7 (2) it follows that

JgU * 14) 1 = (<14) + (<14) = arctan ΔΧι / Δ Yi and the sought angle 45 ° - 0.5 arctan ΔΧι / ΔΥι

The positive direction along the X axis is measured from the base of the perpendicular 7 (1) towards the focus 5 of the radio antenna.

After turning the flat optical reflectors, they are fixed, i.e. are fixed relative to the radio-reflecting surface of the antenna, ensuring that the angles a "remain unchanged.

The envelope surface passing through the centers of all flat optical reflectors 8. in this case coincides with the radio-reflecting surface of the antenna 1.

When the area of the radio-reflecting surface 1 is deformed in the area of the flat optical reflector 8, both radio beams and optical radiation deviate from focus at the same angles. '>

To concentrate optical radiation, a focusing element 9 with an optical axis is installed between each flat optical reflector 8 and the radiation source 7 on the line connecting the geometric center of the flat optical reflector 8 and the radiation source 7. Due to this installation, the direction of the axis of the discrete beam relative to the optical radiation 7 passing through the flat the optical reflector 8 is not changed by the focusing element 9. The focal lengths of the focusing elements 9 are chosen such that each focusing element 9 builds an image of the optical radiation source 7 in the focal plane of the radio antenna 6, i.e. so that the optical coupling of the optical radiation source and the focus of the radio antenna 5, 6 is carried out. To select the focal length, the segments are measured between the radiation sources 7 and the focus 5, 6 and between the focusing element 9 and the center of the flat optical reflector and using the previously measured segments ΔΧι ηΔΥι, are determined analytically focal length according to Newton's formula (fr = = Xi · Xi ¹ ). After completing these actions, three coordinates of the corresponding l-x images of the radiation source in the prefocal and / or extrafocal plane are determined. Further processing of measurements is carried out according to the Hartmann method. In this case, the position of the focus, the coordinates of the center of the focal plane, the displacement of the image of the optical radiation source relative to it, the parameters of the paraboloid best approaching the true surface of the mirror, and information about the local errors of the surface 5 of the mirror at the points of attachment of the flat optical reflectors are determined. In addition, using the coordinates of the centers of planar optical reflectors, the coordinates of the center of the focal plane and the working length of the radio emission, it is possible to analytically calculate the radio emission diagram for the antenna.Knowing the coordinates of radio emitters or inputs of radio receivers by the coordinates of the center of the focal plane, it is not difficult to determine the position of the radio axis of the antenna.

In two-mirror radio antenna systems, additional flat optical reflectors 8 (Fig. 3) can be installed on the secondary mirror 2 along tangents to the radio reflecting surface. They must be optically connected to the corresponding flat optical reflectors 8 on the radio reflecting πό25 surface of the primary mirror 1. This means that optical radiation, having passed from the source 7 through the focusing element 9 and the flat optical reflector 8 on the primary mirror 1, must be directed 30 through the focus of the primary mirror 5 (may be imaginary in the case of the Cassegrain scheme) onto the flat optical reflector 8 on the secondary mirror 2, and from there into the focus 6 of the radio antenna. There should also be built 35 image of the source of optical radiation 7.

It is also possible to displace (before fixing) all flat optical reflectors - 8 and the source of optical radiation 7 from 40 of the radio reflecting surface 1, 2 to one side at equal distances in a direction parallel to the geometric axis 3 of the radio antenna. In this case, flat optical reflectors are displaced parallel to themselves, i.e. without changing the angle This displacement allows you to either refuse to cut holes in the radio-reflecting surface 1, or close these holes with a radio-reflecting optically 50 transparent cover (metal mesh, glass with a transparent conductive coating, etc.). Naturally, in this case, the focus of the radio antenna and the optical model of the antenna 55 do not coincide by the offset value, which must be taken into account in the analytical processing of the measurement results.

Displacement is also possible in the direction perpendicular to the axis, but in this case, different planar optical reflectors appear in different positions relative to

Ί a very radio-shielding surface, which causes uneven gravitational and temperature deformations in magnitude and complicates the processing of measurement results.

Determination of the coordinates of images of an optical radiation source constructed by discrete streams can be performed using photographic, photoelectric and television devices. It is possible to carry out measurements at the time of operation of the radio antenna, for which a spectrum splitter is installed along the radiation path in front of the focus and one of the radiation is diverted to the side.

Thus, according to the described method, it is possible to control the radio antenna at any tilt of the antenna and any azimuths of radio emission, including the time of reception or transmission of radio emission.

Claims (3)

Claim 1. A method for monitoring a radio antenna, including illumination of flat optical reflectors (OPO), evenly located on the reflecting surface of the radio antenna mirror, by a stream of optical radiation from a source installed on the geometric axis of the radio antenna and rigidly connected to it, and analysis of the distribution of radiation, characterized in that, in order to improve the quality of control of the radio antenna by taking into account the deformations of the reflecting surface of the mirror, the POT is installed in the holes made in the mirror of the radio antenna, aligning their geometric centers with the reflecting surface of the mirror, a focusing element is installed between each POT and the source of optical radiation, the POT is turned at an angle = 45 ^{O <} 0.5 arctan. where eq is the angle between the normal to the reflecting surface of the mirror and the normal to the POT in the plane passing through the geometric axis of the radio antenna and the center of the 1st POT: Δ Υι is the length of the perpendicular dropped from the center of the i-ro POO to the geometric axis of the radio antenna; ΔΧι is the distance from the base of the Ι-th perpendicular to the optical radiation source, counted towards the focal point of the radio antenna, the POT is recorded, three coordinates of the corresponding i-x images of the optical radiation source, in the prefocal and / or extrafocal plane, are determined, by which the quality of the radio antenna is judged. 2. A method according to claim 1, characterized in that in two-mirror systems, radio antennas on the secondary mirror are equipped with additional POTs tangentially to the reflecting surface, optically connected to the POT on the reflecting surface of the radio antenna mirror. 3. The method according to PP. 1 and 2, with the fact that the source of optical radiation and all POTs before fixation are displaced from the reflecting surface in one direction at equal distances in a direction parallel to the geometric axis of the radio antenna, Phi 8 ί