RU2620875C1 - Multibeam band dish antenna - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: multi-beam band dual-reflector antenna consists of a irradiators system located on arc of a circle, a primary reflector mirror which has a form of parabola in the plane orthogonal to the plane of circular arc, and an auxiliary subdish, in form of coaxial to parabola ellipse, concaved towards the reflector; the cross sections of all above in the plane of the irradiators arc are circumferences, concentric with the irradiators arc and having a larger and smaller radius, respectively, compared with it. The irradiators circumferences arc passes through the focus of ellipse, which is close to the reflector. At the same time, additional irradiators are placed on the irradiators arc passing through the focus of the ellipse remote from the reflector.

EFFECT: increase the efficiency of antenna while simultaneously receiving two frequency bands.

2 dwg

Description

The invention is intended for use as part of radio engineering devices for television, broadcasting and radio communications through artificial Earth satellites (AES) located in the geostationary orbit (GSO) of the centimeter and millimeter wave ranges, operating simultaneously in several frequency ranges.

Multibeam two-mirror toroidal parabolic antennas are known, consisting of a main (large) mirror (reflector) in the form of a part of a parabolic torus, an auxiliary (small) mirror (counterreflector) in the form of an elliptical torus, coaxial to the reflector, and a system of irradiators located on an arc of a circle. Such antennas make it possible to form a fan radiation pattern (LH) for simultaneous radio communication with several satellites in the GSO. The disadvantages of such an antenna include its reduced efficiency while simultaneously receiving several ranges per irradiator, caused by the loss of electromagnetic energy in the device combining frequency ranges.

The invention relates to the field of radio engineering and is intended for use as terrestrial antennas of satellite communication systems with microwave transmitters in the geostationary orbit (GSO) for simultaneous operation with several satellite communications, each of which operates simultaneously in multiple frequency ranges.

The technical result of the invention is the creation of a multi-beam band reflector antenna of increased efficiency. The antenna consists of a system of irradiators located on an arc of a circle, a main reflector mirror having in the plane orthogonal to the plane of a circular arc, a parabola shape, and an auxiliary counterreflector mirror, in the form of an ellipse coaxial parabola, concave towards the reflector, whose sections are in the arc plane of irradiators is a circle concentric to the arc of the irradiators and having a larger and smaller radius respectively, the arc of the irradiator circles passes through the focus of the ellipse, approximately at the same time, one or more irradiators are additionally installed on the irradiator arc passing through the focus of the ellipse remote from the reflector.

The invention is intended for use as part of the radio systems of earth stations of satellite communications for satellites in geostationary orbit. It can be used for transmission and reception of television, broadcasting and radio communications in the VHF, UHF and microwave ranges.

Known two-axis axisymmetric antennas with a reflector in the form of a paraboloid, a counterreflector in the form of part of an ellipsoid, one of the foci of which coincides with the focus of the paraboloid, and the second is the irradiator (Gregory scheme) [1]. The disadvantage of this antenna is the formation of a single radiation pattern.

Known [2, 3] are multi-beam two-mirror toroidal-parabolic antennas for operation in a wide sector of satellite placement in the geostationary orbit (GSO), consisting of a reflector in the form of a parabolic torus, a counter-reflector and a system of irradiators located on an arc of a circle. These antennas make it possible to form a fan radiation pattern (DD) for simultaneous radio communication with several satellites in a geostationary orbit. The disadvantages of such an antenna include a significant decrease in its efficiency, caused by phase distortions of the field in one of the aperture planes of the main mirror, close to quadratic, due to the difference in the shape of the reflector in this plane from the parabolic.

The technical result of the invention is to increase the efficiency of a mirror antenna while maintaining a fan radiation pattern in two or more frequency ranges.

For this, a multi-beam two-mirror antenna is proposed, consisting of a system of irradiators located on an arc of a circle, a main reflector mirror having a circular arc plane, orthogonal to the plane, a parabola shape, and an auxiliary counterreflector mirror, in the form of a coaxial ellipse parabola, concave to the side reflectors whose sections in the plane of the irradiator arc are circles concentric to the irradiator arc and having a larger and smaller radius, respectively, d ha circles irradiators passes through the focus of the ellipse that approximates the reflector, wherein the further set one or more illuminators irradiators arc passing through kontrreflektora focus remote from the reflector.

The invention is illustrated by drawings, in which:

FIG. 1 - multi-beam band mirror antenna, side view;

FIG. 2 - multi-beam band mirror antenna, view from the side of the reflector, where:

- reflector - 1;

- counterreflector - 2;

- primary irradiators - 3;

- arc of a circle of placement of secondary irradiators - 4;

- additional secondary irradiators - 5;

- directional radiation - 6;

- the focal axis of the parabola is 7;

- arc of a circle of placement of primary irradiators - 8;

- a fan of partial antenna patterns - 9.

The Gregory band multipath mirror antenna with a reflector 1 in the form of a parabolic torus with a counterreflector 2 in the form of an elliptical torus (Fig. 1) with matching focal axes forming the parabola and ellipse contains a primary irradiator 3 and the like in the focal points of the ellipse closest to the top of the reflector one.

When connected to a primary irradiator 3 and the like, placed on a circular arc of the primary irradiators 8, of a high-frequency generator, the primary irradiator 3 emits an electromagnetic field, including towards the upper and lower edges of the counter-reflector 2, which in the geometrical optical sense can be considered in the form of rays. Reflected from the upper and lower edges of the counterreflector 2, both rays, like all others, intersect at the focus of the ellipse, remote from the reflector, coinciding with the location of the focus of the parabola.

Due to the property of the cross section in the form of an ellipse, the distance from the focus of the placement of the primary irradiator 3 to any point on the surface of the ellipse and then after the reflection of the field of the primary irradiator 3 to the second focus coinciding with the focus of the parabola, the rays of the field of the primary irradiator 3 form a spherical wave after passing through the second focus.

The primary irradiators 3 are located in the focus of the ellipse; therefore, due to passage through the focus, parabolas after reflection from the counterreflector 2 are formed in the plane of the drawing of FIG. 1 directional radiation 6, parallel to the focal axis of the parabola 7.

At the same time, in the plane of the drawing of FIG. 2 they form a fan of partial antenna patterns 9.

Due to the placement of additional secondary irradiators 5 on the arc of the circumference of the secondary irradiators 4, passing through the focus of the ellipse of the counterreflector 2, the same fan of partial radiation patterns of the antenna 9 is formed in the plane of the arc of the circumference of the secondary irradiators 4, as from the primary irradiators 3, and each the partial diagram is directed to its satellite. Since primary irradiators 3 are primary and additional secondary irradiators 5 can lie on radii common to the distribution circles of secondary irradiators 4 and the circumference of the placement of primary irradiators 8, the rays of the fan of the partial radiation patterns of the antenna 9 from the primary irradiators 3 and additional secondary irradiators 5 coincide in direction.

Additional secondary irradiators 5 are located at half the radius of the arc of the circumference of the secondary irradiators 4, which is equal to twice the focal length of the parabola of the reflector 1, and in addition, are located in the focus of the parabola. This leads to the creation of a fan of partial radiation patterns of the antenna 9 in the plane of the arc of the circumference of the secondary irradiators 4, concentric with the arc of the circumference of the primary irradiators 8 and the circles forming the parabolic and elliptic tori. When placing the primary irradiators 3 and additional secondary irradiators 5 on the same radius of the circular arc of the secondary irradiators 4 and the circular arc of the primary irradiators 8, the directions of the partial diagrams from such irradiators coincide and are directed to the same satellite. This can be used to simultaneously receive from this satellite two different frequency ranges - one ranges to primary irradiators 3, and other ranges to additional secondary irradiators 5.

For simultaneous operation in two ranges in known antennas, an irradiator common to these ranges is used in combination with a device for separating frequency ranges, introducing additional high-frequency losses and reducing the gain and noise temperature of the antenna.

In the proposed antenna, the separation of frequency ranges is carried out by the method of spatial separation into two feeds, one of which is primary 3, the other secondary secondary 5, which increases its efficiency.

LITERATURE

1. Eisenberg G.Z., Yampolsky V.G., Tereshin O.N. VHF antennas. / Ed. G.Z. Eisenberg: In the 2nd part of Part 2 - M., Communication, 1977 .-- 288 pp., Ill.

2. Somov A.M. Fragmentation method for calculating the noise temperature of antennas. - M., Hot line - Telecom, 2009, p. 168-170.

3. Frolov O.P., Wald V.P. Mirror antennas for satellite earth stations. - M .: Hot line - Telecom, 2008 .-- 496 p.

Claims (1)

A multi-beam two-mirror antenna, consisting of a system of irradiators located on an arc of a circle, a main reflector mirror having in the plane, an orthogonal plane of a circular arc, a parabola shape, and an auxiliary counter-reflector mirror, in the form of an ellipse coaxial parabola, concave towards the reflector, section which in the plane of the irradiator arc is a circle concentric to the irradiator arc and having a larger and smaller radius, respectively, the arc of circles irradiate The oil passes through the focus of the ellipse close to the reflector, characterized in that one or more irradiators are additionally installed on the arc of the irradiators passing through the focus of the ellipse remote from the reflector.

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