FR2577074A1 - Multireflector antenna with conformed beam - Google Patents

Abstract

The field of the invention is that of antennas intended for the coverage, from a satellite, of a terrestrial region with prescribed contours. The problem resolved consists in conforming the beam of the antenna whilst carrying out communications on two orthogonal polarisations. To do this, the antenna according to the invention is composed of a main reflector A and of at least one auxiliary reflector B, the active surfaces of both reflectors being deformed so as to correspond to the terrestrial region with prescribed contours, whilst satisfying the Mizugutch condition for the elimination of crossed polarisation. The invention finds a preferred application in the coverage of Europe from a geostationary satellite.

Description

Multi-reflective shaped beam antenna ",
The invention relates to an antenna, in particular intended for covering, from a satellite, a terrestrial region with prescribed contours, with two well decoupled orthogonal polarizations.

 We know that the use of two orthogonal polarizations makes it possible to double the communication capacity of a satellite, on the condition that a very good insulation is obtained between the two polarized signals.

 On the other hand, we also know that the creation of antennas with a conformed beam, making it possible to cover specific demarcated terrestrial areas, namely generally a given country or group of countries, constitutes a current important concern for the realization of the new generation of communication satellites. The increase in traffic and the limitations of the available frequency bands in fact lead to the use of complex antennas, whose beams with prescribed contours, or with very low side lobes, are compatible with frequency reuse.

 The solution developed by the present invention relates to an antenna comprising a main reflector with a single offset primary source, cooperating with one or more auxiliary reflectors.

 Antennas with multi-grid reflector and multiple source are already known, making it possible to obtain an emission of two orthogonally polarized signals (USSN patent 665,933 ASE). As can be seen in FIG. 1, this document describes a type of antennas comprising a system 1 reflector with two offset grids 2,3, one reflecting a polarization, and the other orthogonal polarization. These two grids 2, 3 are portions of paraboloids, at the foci of which two multisource systems 4, 5 are placed, emitting the polarization corresponding to the grid 2, 3 with which they respectively operate.

 The very low level of cross polarization is ensured by the use of grids, and the contour of the radiation diagram is controlled by multisource systems 4,5, In addition, the advantage of these antennas is that the two polarizations can radiate different beams.

 However, these antennas are of a relatively complex and expensive construction, in particular because of the bigrille reflectors, and of multiple primary sources.

 The multisource solution requires complex, heavy and expensive distributors. Finally, the performance of these antennas is affected by the losses appearing in the distributors and at the level of the reflectors.

 There are also known antennas of the type with a single reflector 10 with offset source 13, and whose surface is shaped (FIG. 2). The radiation pattern of these antennas is shaped by the fact that the active surface 11 of the reflector 10 is deformed relative to a parabolic starting surface 12, so as to concentrate the rays reflected in the desired angular range. The two polarized signals are transmitted by the single primary source 13 is provided by an orthomode coupler 14.

In order to obtain a very low level of crossed polarization with such an antenna, there are two solutions
- We can first use a bigrille reflector with shaped surfaces and two sources each corresponding to a polarization. However, this solution brings back to the bigrille multisource system described above, of which it has most of the drawbacks even if the complexity of the primary sources is reduced.

 - One can also significantly distance the source 13 from the reflector 10, so as to obtain a high ratio between this distance and the diameter of the reflector. This solution makes it possible to limit the cross polarization induced by the reflector, but never to cancel it completely.

In addition, such a solution crowds a large footprint
We finally know the device described by Xizugutch in AP-S International Symposium 1976, Amherst, gauss, 11-15
Oct. 1976, p.25. As shown in Figure 3, the antenna is provided with a main parabolic reflector 20, cooperating with a second asymmetric reflector 21,22, ensuring the elimination of cross polarization. One of the solutions described consists in using a Gregory antenna with an ellipsoidal secondary reflector 21 (FIG. 3a) or a Cassegrain antenna with a hyperboiodal secondary reflector (FIG. 3b). Elimination of cross depolarization is obtained by choosing and arranging the reflectors and the primary source 23 according to very specific conditions.

 However, this configuration does not make it possible to conform the reflected beam, in order to achieve coverage of a well-defined terrestrial region.

Consequently, the objective of the invention is to provide an antenna with offset source, which can cover from a satellite a well delimited terrestrial region, with two orthogonal polarizations well decoupled while remedying the drawbacks mentioned above:
To this end, the antenna according to the invention is characterized in that it consists of a substantially paraboloidal main reflector, illuminated by a single offset source, in that said main reflector cooperates with at least one auxiliary reflector of elimination of cross polarization, and in that the surface of said main reflector is deformed with respect to its base parabdold to conform the radiated beam to said terrestrial region with prescribed contours.

The two essential characteristics sought are therefore achieved by this type of antenna
- the deformation of the base dish ensures the shape of the radiated beam;
- the presence of one or more auxiliary reflectors eliminates the cross polarization. In this regard, and according to a preferred embodiment, the auxiliary reflector is chosen and positioned with respect to the main reflector so as to verify the Mizugutch condition.

 In total, the design and structure of the antenna according to the invention makes it possible to obtain very good polarization purity, and better optimization of the radiation diagram than the solutions of the known art.

 They are also presented in the form of a compact configuration using only simple elements.

Other characteristics and advantages of the invention will appear on reading the following description and the appended drawings, in which
- the first three figures represent the prior art already mentioned:
* Figures la and lb show a known multisource bigrille antenna with a shaped beam, in front view and in profile respectively;
* Figure 2 shows a known single source reflector antenna
* Figures 3a and 3b show known antennas with offset source, comprising a secondary reflector for eliminating cross polarization; and
- Figure 4 shows an embodiment of the beam multi-reflector antenna shaped according to the invention.

 In an antenna with offset source, the primary source is off center with respect to the main reflector, which results in an eccentric illumination and therefore a cross polarization of the radiation with two orthogonal polarizations reflected by this reflector.

 On the other hand, the fact that the primary source is unique, resulting in the production of a shaped secondary beam can only result from the way in which the reflector is produced; in this case, it is the deformation which it is subjected to, relative to its base surface, which makes it possible to obtain the selective coverage of a terrestrial region with prescribed contours.

 In this respect, the antenna according to the invention differs notably from the device described above and represented in FIG. 1, the radiation diagram of which is composed from the multiplicity of sources selectively oriented in the direction of a paraboloid bigrille reflector system. not deformed.

The embodiment of the antenna according to the invention, as shown in FIG. 4, comprises a main reflector A, associated with an auxiliary reflector B, and a single source C,
The reflectors A, B and the source C are arranged so that the source C directly illuminates the auxiliary reflector B; the auxiliary reflector B then reflects the beam received from the source C towards the main reflector. The resulting beam finally covers the desired terrestrial area.

dans laquelle e représente l'excentricité du réflecteur auxiliaire.The cooperation of the two main reflectors A and auxiliary B, therefore clearly distinguishes the antenna according to the invention from the single reflector system described above and represented in FIG. 2. The two reflectors are positioned so that their interaction compensates for the effect system offset, and more particularly the offset effect which would appear on the beam reflected by the main reflector A, if it were directly illuminated by the source C, which would correspond to the unfavorable case where one would not use auxiliary reflector B. In practice, it has been shown that cross polarization is eliminated when the values are chosen: of the angle {appearing between the axis 41 of the source C and the axis 42 of the auxiliary reflector B, of the angle appearing between each of the axes 43.42 of the two main reflectors
A and secondary B respectively, and of the eccentricity of the base surface of the auxiliary reflector B, so that they verify the condition of Mizugutch. This geometric relationship is expressed by the following equation

in which e represents the eccentricity of the auxiliary reflector.

 This relation can be applied as well to the case where the auxiliary reflector is ellipsordal (Grégo antenna), as to the case where this auxiliary reflector B is hyperboloidal (Cassegrain antenna).

 In the case where several auxiliary reflectors B are used, the relation therefore involves additional parameters, but the identical condition is that the system offset effect must be compensated for by the interaction of successive reflections, and that consequently the radiation induced in cross polarization is canceled or very weakened.

 If the coupling of two reflectors is necessary to preserve the independence of the two orthogonal polarizations emitted by the source C, we have seen about the system proposed by Mizugutch that this arrangement is not sufficient as such to conform the reflected beam .

 In order to cover a terrestrial area with prescribed contours, the paraboloidal base surface 44 of the main reflector A has therefore been deformed, so as to obtain a final surface 45 concentrating the rays reflected in the desired angular domain or domains, and with the desired radiation densities.

 One possible method, and known in the prior art, of forming the surface of the reflector, to adapt the contour of the radiated beam to that of the region to be covered, consists in optimizing, by an algorithm of "minimax" type, the phase in the opening of the reflector, depending on the amplitude of illumination, and the desired phase law on the opening. The shape of the surface 45 of the reflector A is obtained by screening of rays between the source, the desired surface 45 and the opening.

This method does not lead to a significant increase in cross polarization.

 On the contrary, while it is used here on a basic multi-reflector system, ensuring compensation for the induced cross polarization, this method guarantees to obtain superior performance for the shape of the beam and its polarization purity.

 It is also possible to also deform the auxiliary reflector (s) in addition to the main reflector A to contribute to the objective of shaping the resulting beam, while preserving the purity of polarization.

In this case the auxiliary reflector B can be deformed with respect to a starting surface 46, for example hyperboloidal or ellipsoidal. The shaping of the surfaces of the two main reflectors A and auxiliary B is then carried out in an interactive and iterative manner until the obtaining of the perforations: rare ances. The adjusted shape of the final surface 47 of the reflector B makes it possible in particular to refine the polarization purity and therefore to optimize the performance of the antenna according to the invention.

 This faculty thus constitutes an additional degree of freedom for the development of the antenna.

 The single source C used is typically a conventional circular source, for example of the corrugated horn type 48, having good polarization purity performances. It can be fitted with an orthomode coupler 49.

Finally, it should be noted that the auxiliary reflector
B has a generally circular or elliptical surface, in particular if no other auxiliary reflector is used. This makes it possible to use one or more simple primary horns (conical corrugated horn, for example). It is also possible to envisage an elliptical auxiliary reflector in the case of a system with two reflectors.

 It is therefore noted that the design of the multi-reflector antenna with a shaped beam according to the invention makes it possible to cover with two orthogonal polarization signals, a delimited earth zone, by using a main reflector with offset source. There is therefore on the one hand the intrinsic advantage of offset source systems, which make it possible to avoid the obstruction of secondary radiation by the assembly formed of the sources and the auxiliary reflectors, and on the other hand we compensate for quite satisfallte depolarization induced by this system.

 As a preferential application, the antenna according to the invention can make it possible to cover the EurDEe from a geostationary satellite, with a minimum gain of 28 dB in double linear polarization, with a level of crossed polarization lower than - 34 dB. The diameter of the antenna opening must not exceed 1.1 meters.

If we compare the device used according to the invention with the known devices, the qualities of the first appear clearly
- If lton uses a bigrille reflector system, of the type shown in Figure 1, it is necessary to mount two sets of five offset rectangular sources, each with a waveguide distributor. Problems arise then in the manufacture of grid reflectors, their thermal insulation, as well as those linked to the complexity of the non-identical primary sources, and of their distributors.

In addition, the total mass of the two primary source systems is significant.

 Another solution, corresponding to the device shown in FIG. 2, consists in using a single reflector lit by a conventional corrugated horn with double polarization provided with an orthomode coupler. The surface of the reflector is formed so as to concentrate the rays reflected in the coverage area. However, in order to limit the level of cross-polarization to the value specified above, the source-reflector distance must typically be two meters or more, c which leads to significant congestion, and risks requiring the use of a tower to support the primary source.

 In the case of using the antenna according to the invention, the main reflector has an opening comparable to the opening of the previous systems. The surface is shaped to concentrate the rays reflected in the angular range and with the desired relative intensity. The auxiliary reflector B is a circular portion of hyperboid whose axis orientation and eccentricity are such that the induced cross polarization is canceled after reflection on the main reflector A. The primary source C is a corrugated horn 48 of circular section equipped with an orthomode coupler 49.

Claims (7)

 10) Antenna especially intended for coverage from a satellite of a terrestrial region with prescribed contours, with two well decoupled orthogonal polarizations,  characterized in that it consists of a main reflector (A) substantially paraboloSdal, illuminated by a single offset source (C),  in that said main reflector (A) cooperates with at least one auxiliary reflector (B) for eliminating cross polarization, and  in that the surface (45) of said main reflector (A) is deformed with respect to its base paraboloid (44), to conform the radiated beam to said terrestrial region with prescribed contours.  20) Antenna according to claim 1, characterized in that the auxiliary reflector (B) has an active surface (44J 'chosen from the family of hyperboloids and ellipsoudes.  30) Antenna according to claim 1, characterized in that the auxiliary reflector (B) is circular.  40) Antenna according to claim 2, characterized in that the values are chosen: of the angle K between the axis (41) of the source (C) and the axis (42) of the auxiliary reflector (B), the angle between each of the axes (A3,42) of the two main (A) and secondary (B) reflectors respectively, and of the eccentricity of the active surface of the secondary reflector (B), so that they verify the condition from Mizugutch.  50) Antenna according to claim 1, characterized in that the auxiliary reflector (B) has an active surface (47) deformed, relative to its base surface (46), in a manner adapted to the deformations undergone by the main reflector (A )  6) Antenna according to claim 1, characterized in that the source <C) is a corrugated horn (48) of circular section.  70) Antenna according to claim 6, characterized in that the source (C) is equipped with an orthomode coupler.  80) Application of the antenna according to any one of claims 1 to 7, for the coverage of Europe from a geostationary satellite with a minimum gain of 28 dB in double linear polarization, with a level of polarization cross less than - 34 dB, in which the diameter of the opening of the main reflector (A) is less than or equal to 1.1 meters, its surface (45) being shaped, the auxiliary reflector (B) being a circular portion d hyperbolorde whose axis orientation (42) and eccentricity verify the condition of Mizugutch, and the primary source (C) being a corrugated horn (48) of circular section equipped with an orthomode coupler (49).  90) A method of manufacturing an antenna according to any one of claims 1 to 7, characterized in that  - The active surface of the main reflector A is first deformed as a function of the contours of the terrestrial area to be covered;  - the active surface of the auxiliary reflector B is then deformed as a function of the modified surface of the main reflector A, in order to eliminate cross polarization  - the shape of the active surface of the main reflector A and of the auxiliary reflector is then again rectified B interactively and iteratively until the required performance is obtained.