RU2446524C1 - Multibeam double-reflector antenna for receiving signals from satellites on edge of visible geostationary orbit sector - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: disclosed is a multibeam double-reflector antenna, having a main reflector which is a cut of a portion of a surface formed by turning a parabola about an axis lying in the plane of the parabola and perpendicular to the focal axis of the parabola, an additional reflector which is a cut of a portion of a surface formed by turning a second-order line (ellipse or hyperbola), one of the two foci of which coincides with the focus of the parabola, about the same axis, and a line of radiators whose phase centres lie on the focus of the second-order line. Said portion of the main reflector is cut from a surface formed by turning a parabola about an axis inclined at an angle equal to the angle of inclination of serviced section of the geostationary orbit to the horizon line, to the normal to the plane passing through the point where the antenna is located and two points lying infinitely near to centre of the serviced section of the geostationary orbit such that the top and bottom edges of the reflector lie in parallel to said plane, and the edges of the additional reflector and the line of radiators are inclined to said plane.

EFFECT: high gain of the multibeam double-reflector antenna which is specifically meant to receive signals from satellites located on the edge of the visible section of the geostationary orbit, which does not need to be inclined to the earth's surface.

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Description

The invention relates to antennas and is intended for use as part of radio engineering satellite communications devices in the VHF and UHF bands.

Known designs of multi-beam mirror antennas that allow the formation of several deviated diagrams in a certain sector of angles (US Pat. 2380802, H01Q 19/19, 2336615, H01Q 15/00, 2181519, H01Q 19/18, 2342748, H01Q 19/10, US Pat. U.S. 4,786,910; H01Q 25/00).

Of the known designs, the closest in technical essence is the multi-beam antenna (MLA), described in Somov’s book “The fragmentation method for calculating the noise temperature of antennas” (2008, pp. 175-186), which is capable of receiving signals simultaneously from each of several artificial Earth satellites (AES) located in the geostationary orbit (GSO), through a partial diagram (beam). The antenna contains a spherical mirror formed by cutting from a reflector formed by rotating a parabola, an additional mirror forming by cutting from a reflector formed by rotating a second-order line (ellipse or hyperbola), one of the two foci of which coincides with the focus of the parabola, and an array of irradiators whose phase centers are located in the focus of the second-order line

One of the disadvantages of such an MDA design is the inconvenience of receiving signals from satellites located on the "edges" of the visible sector of the GSO, which is expressed in the fact that the antenna must be placed at an angle to the earth's surface.

The technical result consists in providing a high gain of a multi-beam two-mirror antenna, specially designed for receiving signals from "edge" satellites, which does not need to be installed obliquely to the earth's surface.

The specified technical result is achieved by the fact that a multi-beam two-mirror antenna is proposed containing a main mirror, which is a notch of a part of the surface from a surface formed by the rotation of a parabola around an axis lying in the plane of the parabola and perpendicular to the focal axis of the parabola, an additional mirror, which is a notch of a part of the surface from a surface formed by the rotation of a second-order line (ellipse or hyperbola), one of the two foci of which coincides with the focus of the parabola s, around the same axis, and a line of irradiators whose phase centers are in the focus of the second-order line, and the main mirror is cut out from the surface formed by the rotation of the parabola relative to the axis, inclined at an angle equal to the angle of inclination of the serviced portion of the geostationary orbit to the horizon line, to the normal to the plane passing through the antenna placement point and two points infinitely close to the center of the serviced portion of the geostationary orbit, so that the upper and lower edges of the mirror Position the said parallel plane, and the edge of mirror and placing additional irradiators line inclined to said plane.

In the Cartesian coordinate system, the surface of the main mirror of the MDA is described by the following formula:

where α is the angle of inclination to the horizon line of the served visible portion of the GSO; R ₃ is the radius of the circumference of the main mirror of the antenna; D _L - the size of the aperture of the antenna in the longitudinal plane; D _T - the size of the aperture of the antenna in the transverse plane; x, y, z - coordinates. The origin is the location of the “central” focus of the parabola, where the signal reflected from the main mirror of the MLA is focused from the satellite located in the middle of the served GSO sector.

In the same Cartesian coordinate system, the surface of an additional MDA mirror is described by the following formula:

where DC _L is the size of the aperture of the counterreflector in the longitudinal plane; DC _T - the aperture of the counterreflector in the transverse plane; e - eccentricity of the hyperbola; f _c is the focus of the hyperbola. The last condition indicates that only one of the two branches of the hyperbola is involved in the rotation.

The line of location of the phase centers of the MLA irradiators in the same Cartesian coordinate system is described by the formula

When aiming the irradiator at the served satellite, due to the nonlinearity of the visible portion of the GSO, the phosphor center of the irradiator will be slightly separated from the above line, which leads to a slight decrease in the antenna gain.

To explain the device of the proposed two-mirror MLA, FIG. 1 is used — an image of an antenna in a Cartesian coordinate system in three different projections, FIG. 2 — a parabola, a hyperbole and an axis of rotation, FIG. 3 — a visible portion of a GSO, FIG. 4 — a ray path in a geometrical optical representation. 5 is an arrangement of radiation patterns.

A two-mirror antenna contains a main mirror (reflector) 1, a line of irradiators whose phase centers are located on line 2 and an additional mirror (counter-reflector) 3 (Fig. 1).

The main mirror 1, used to form the field of the reflected wave with a flat phase front in the transmission mode or a quasispherical wave in the reception mode, is made in the form of a cut from the surface formed by the rotation of the parabola relative to an axis lying in the plane of the parabola and perpendicular to its focal axis (figure 2 ), inclined at an angle α to the normal to the plane passing through the antenna placement point and two infinitely close to the center of the served area (Fig. 3) of the geostationary orbit of the point. Moreover, the upper and lower edges of the main mirror are parallel to the specified plane. The angle α is equal to the angle of inclination of the serviced GSO section (Fig. 3) to the horizon line.

The counterreflector 3 can be formed by any of the known schemes of two-mirror antennas, which does not change the essence of the invention. In particular, if the counterreflector is made according to the classical Cassegrain scheme, then it is obtained by cutting from the surface formed by the rotation of the hyperbola relative to the same axis around which the parabola rotates when the main mirror is formed (figure 2). Moreover, the hyperbola lies in the same plane as the parabola, and one of the two foci of the hyperbola coincides with the focus of the parabola. At the same time, the edges of the counterreflector are inclined to the plane passing through the antenna placement point and two points infinitely close to the center of the served area of the geostationary orbit.

The line of irradiators, the phase centers of which are located on line 2 (Fig. 1), consists of irradiators, which can be used as horn, spiral, slot, and other single or group (cluster) emitters, which does not affect the essence of the proposed solution, but with a phase or "partial phase" center. Line 2, on which the phase centers of the two-mirror MLA irradiators are located, is located in the plane of rotation of the focal axis of the parabola and is part of a circle with radius r = R _З / 2 + 2f _c * e / (e-1) and centered on the axis of rotation. The plane of the line 2 is inclined to the horizon plane at an angle α.

The proposed antenna for transmission works as follows (figure 4). Each irradiator emits an electromagnetic field with a spherical phase front within the aperture of the counterreflector and a phase center that coincides with one of the foci of the hyperbola. The geometrical optical rays of these fields are reflected at the corresponding points of the counterreflector and form a new spherical wave, but with a phase center that coincides with another focus. In turn, the geo-optical rays reflected from the counterreflector fall on the main mirror, where they are again reflected, forming waves with a flat phase front. The location and orientation of the irradiators relative to the main mirror are determined by the location of the served satellites on the GSO.

In the reception mode, the proposed antenna operates as follows (figure 4). Geometrical optical rays of partial radiation patterns arriving at the main mirror in the form of waves with a flat phase front are reflected from the main mirror, concentrating in the focus of the main mirror, which coincides with one of the foci of the hyperbola. Then the rays reflected from the main mirror are again reflected from the counterreflector, concentrating already in another focus of the hyperbola, where the phase center of the irradiator is established.

The present invention allows to form a set of partial radiation patterns, an example of which is shown in figure 5. In the figure, the abscissa shows the angles in radians, and the ordinate shows the level of the radiation pattern in dB.

The present invention allows to receive signals from satellites located on the edge of the visible portion of the GSO, without the need to tilt the antenna to the horizon.

Various modifications of the invention are possible, which does not change the essence of the structure under consideration, i.e. The solution claimed in the invention is common for two-mirror antennas forming a multi-beam pattern.

BIBLIOGRAPHIC DATA

1. Somov A.M., Babintsev A.V. Multipath Mirror Antenna for Satellite Communication Systems // Transactions of NIIR. - 2010. - No. 1. - S. 35-42.

2. Eisenberg G.Z., Yampolsky V.G., Tereshin O.N. VHF antennas. Part 1. - M .: Communication, 1977.-382 p.

3. Eisenberg G.Z., Yampolsky V.G., Tereshin O.N. VHF antennas. Part 2. - M.: Communication, 1977 .-- 288 p.

4. Somov A.M. Fragmentation method for calculating the noise temperature of antennas. - M .: Hot line - telecom, 2008. - S.175-186.

Claims (1)

A multi-beam two-mirror antenna containing a main mirror, which is a notch of a part of the surface from a surface formed by the rotation of a parabola around an axis lying in the plane of the parabola and perpendicular to the focal axis of the parabola, an additional mirror, which is a notch of a part of the surface from a surface formed by the rotation of a second-order line (an ellipse or a hyperbola), one of the two foci of which coincides with the focus of the parabola, around the same axis, and a line of irradiators whose phase centers are focus lines of the second order, characterized in that the cutout of the main mirror is carried out from the surface formed by the rotation of the parabola relative to the axis, inclined at an angle equal to the angle of inclination of the serviced portion of the geostationary orbit to the horizon, to the normal to the plane passing through the antenna location and two points infinitely close to the center of the serviced area of the geostationary orbit, so that the upper and lower edges of the mirror are parallel to the specified plane, and the edge and an additional mirror and the line of placement of the irradiators are inclined to the specified plane.

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