FR2596208A1 - Two-frequency antenna with independent steerable beams - Google Patents

Abstract

The field of the invention is that of antennas on board telecommunications satellites. The problem posed consists in producing a two-frequency antenna with independent steerable beams, which is compact, accurate, reliable and aberration-free. The objective is achieved with the aid of a main reflector 11 illuminated by two adjacent sources 12, 13 placed in its focal region and operating at distinct frequencies, the said main reflector cooperating with a set of two overlaid secondary reflectors 14, 16, the first of which is dichroic so as to be transparent to the signals emitted by one of the said sources 13 and the orientation of at least one of the said secondary reflectors being variable with respect to the main reflector. The invention finds a preferred application in the tracking of 2 independent telecommunications satellites in low orbit, from a geostationary relay satellite equipped with the said antenna.

Description

"Dual frequency antenna with independent orientable beams".

 The invention relates to an antenna capable of transmitting or receiving two separate beams, of different frequencies, with the possibility of orientation of these beams independently of one another.

 There is a great interest in this type of antenna, in on-board use in telecommunications satellites, because it constitutes a compact combination of two conventional monofrequency antennas, with great flexibility of use due to the independence of the bundles. A preferential application of such an antenna with independent beams consists in placing it on a geostationary relay satellite retransmitting signals coming from two satellites circulating on lower orbits.

 In the field of dual-frequency antennas, we already know the groupings of radiating sources in networks. Such antennas are constituted by a set of elementary sources supplied by separate channels. In camnar, independently dant each of the elements so that it operates either at a first frequency or at a second frequency alternately, one can obtain a dual frequency antenna. The orientation of the beams can, for its part, be carried out by varying the relative phases of the sources, which supposes the existence of a large number of elements. This type of network antenna is therefore all the more bulky when it is desired to obtain a greater pointing finesse, which is not suitable for applications on board satellites.

 In the case of the use of radiating elements in network on the same radiating aperture, and each operating at two distinct frequencies, each of the radiations can be independently controlled using a frequency duplexer. But we also find here a great complexity in the case where a slow repointing of the beams is required.

 Another known dual-frequency array antenna device is presented in FIG. 6. This type of antenna comprises two source networks 1, 2, cooperating with a dichromatic sub-reflector 3 ensuring the separation of the signals of different frequency for each of the sources. .

 These networks feed a system of two confocal parabolic reflectors 4-5. The first reflector encountered 4 is used on its convex parabolic surface so that the beams reflected towards the main reflector 5 widen to form an enlarged image of the source gratings.

A detailed description of this system can be found in C.Dragone and MJ Gans,
Bell System Technical Journal 58, N 2. (February 79).

This known dual-frequency antenna is hardly compatible with the constraints of putting satellites into orbit, due to its complexity and its size. In addition, he suffers from aberration.

 Consequently, the object of the invention is to provide a dual-frequency antenna with independent orientable beams which overcomes the drawbacks noted above of existing systems.

 A first object of the invention is therefore to provide a compact dual-frequency antenna, made up of a small number of elements.

 A second object of the invention is to produce such an antenna which is of reliable operation, in particular because it consists only of a small number of elements, arranged in a slightly complex assembly, which limits the risk of adjustment.

 An additional object of the invention is to provide a dual-frequency antenna, the beams of which can each be pointed independently with very high precision. This flexibility of operation of the antenna according to the invention allows in particular the pursuit of two transmitting stations / u̲ receiving terrestrial and / or satellite with a relatively large scanning angular field depending on the constructive characteristics of each embodiment.

 The pointing accuracy obtained with the dual-frequency antenna according to the invention is accompanied by an almost absence of aberration, because the number of sub-reflectors and deflection mirrors is limited to the minimum.

 These objects are achieved using a dual-frequency antenna, of the type consisting of a main reflector illuminated by at least two adjacent sources placed in its focal area, and operating at separate frequencies, characterized in that said main reflector cooperates with a set of two superimposed secondary reflectors, the first secondary reflector facing the main reflector is dichrolic so as to be transparent for the signals emitted by one of said sources, and in that the orientation of at least one of said secondary reflectors is variable compared to the main reflector.

In a preferred embodiment
of the invention, the two secondary reflectors are
orientable independently of each other, so
to produce two reflected beams with independent scanning
while.

As we will see below, this prin
basic principle of the invention can be applied in
many embodiments. Some of these
embodiments as well as other features
ques and advantages will appear on reading the
following description of some devices given to
non-limiting illustration title and drawings
annexed in which
- Fig.1 shows an antenna
dual frequency according to the invention, with offset sources,
with two inductive orientable secondary reflectors
hanging from each other.

- Fig.2 shows a mode of
realization of the invention of the Cassegrain type;
- Fig.3 shows a mode of
realization of the invention with enlarging optics
- Fig.4 shows a mode of
compact embodiment of the invention, with offset source;
- Fig.5 shows a mode of use of the invention on an oeplovaole satellesee ceiling
- Fig.6 shows a device antenna antenna of the prior art, discussed in advance; wing.

 FIG. 1 represents an embodiment of the invention of the type with two sources 12, 13, offset with respect to the portion of paraboloid 11 forming the main reflector.

 The two sources 12, 13 are located adjacent to the focal plane of the reflector 11, and directed so that the signals which they emit are first reflected on said reflector 11 before being returned to two orientable secondary reflectors 14 , 16.

 The reflector 14 is a double reflector, which reflects the signal 18 coming from the source 12, but is transparent to the signal 19 coming from the source 13.

 On the other hand, the secondary reflector 16 can be a conventional reflector, its function consisting simply in returning the signals which reach it, in this case the signal 19 coming from the source 13.

 Each of the two secondary reflectors 14,16 is orientable thanks to a pulling mechanism 15,17 respectively. Each of these mechanisms has the function of modifying in a precise and controllable way the angle under which the reflectors are connected 14,16 receive the signals 18,19 emitted by the sources, or even the signals received from space or ground stations. Advantageously, these mechanisms 15, 17 are linear motors, or stepper motors precisely driving the secondary receivers in rotation, combined or not with a translational movement.

 In other possible embodiments of the invention, only one of the two secondary reflectors 14,16 is orientable. Of course, one can also consider the configuration according to which the two secondary reflectors 14, 16 are mounted on a common mobile base (not shown) making it possible to modify the orientation thereof without modifying their relative position, one with respect to the other. An optional mechanism mounted between the common base and one of the secondary reflectors then makes it possible, if necessary, to obtain independence of orientation between the two reflectors 14, 16.

 Finally, in certain cases where the embodiment of the means for orienting the secondary reflectors as shown in FIG. 1 poses constructive problems which are difficult to overcome because of the overhang, it is entirely possible to equip each reflector secondary of a complementary orientation mechanism at the opposite end. In this case the variation in orientation of the reflectors results from the combination of the action of each of the mechanisms located at each end.

 The operation of the dual-frequency antenna of FIG. 1, in transmission mode, is therefore as follows: each of the sources 12, 13 emits a signal at a different frequency. The two spherical waves from the two sources are transformed into portions of equiphase waves 18, 19 by the concave reflector 11.

These two planar portions 11 then meet the dichromatic secondary reflector 14. This reflector 14 returns one of the two frequencies. For this purpose, the dichroSque reflector can operate as a low pass or high pass frequency filter. The second signal is reflected by the second secondary reflector 16. The aiming of the resultant beams 20, 21 is a function of the orientation, independently controlled, of the two secondary reflectors 14, 16.

 As can be seen in Figure 1, the secondary reflectors 14 and 16 are oriented so as to direct the resulting radiation 20,2i in the half space located on the source side with respect to a vertical plane passing substantially through the main reflector 11 as shown.

 FIG. 2 represents another embodiment of the dual-frequency antenna according to the invention in which the two sources 12, 13 illuminating the parabolic reflector 1 are located in the central zone of the surface of the set of secondary reflectors 14, 16.

This arrangement of the sources recalls the design of the Cassegrain antennas with the first reflector 11 encountered by the signals coming from the sources being a concave parabolic receiver, and the final receiver being constituted by the set of secondary secondary reflectors 14,16. This configuration of FIG. 2 has the advantage of being very compact, and allows in particular the production of an antenna as shown in FIG. 4.

 It will be noted that the principle of the invention is not limited to the geometry of the reflector 11 on the one hand, and of the secondary reflectors 14,16 on the other hand as shown in FIG. 1 and 2. The objective of obtaining a resulting wave equiphase at the output of the antenna, can be produced for example by means of a planar reflector 11, and a set of secondary parabolic reflectors 14, 16, or any other suitable combination of the shape of the reflectors 11, 14.16.

 FIG. 3 represents a third possible embodiment of the dual-frequency antenna according to the invention, making it possible to obtain an enlarged outlet opening. The configuration consists of two sources 32,33 facing a first auxiliary parabolic reflector 31, returning the signals from the sources to a set of planar secondary reflectors34,36.

 The two resulting beams 40,41 are then portions of equiphase waves as obtained using the antenna configuration of FIG. 1.

At the exit from this "first stage", two confocal reflectors 42, 43 are placed, arranged so that the two beams 40, 41 come into incidence on the convex part of the first confocal reflector 42, to be returned to the concave part of the second confocal reflector 43, in order to obtain the resultant beams 44.45 emitted on an enlarged opening.

 It can be seen that the directional independence of the two beams is always ensured, in this configuration, by the variable orientation of each of the two planar reflectors 34, 36 of which the first reflector 34 is dichroic.

FIG. 4 represents the original adaptation of the principle of the dual-frequency antenna with independent orientable beams according to the invention to the embodiment protected by French utility certificate no. 82 13 213 of 28 07 1982, in the name of the same applicant, and concerning a 1 antenna of the type
CASSEGRAIN with eccentric primary source ". In this advantageous embodiment, the sources 52, 53 are located at the level of the planar reflectors 54, 56 having an elliptical contour, so as to emit signals towards the reflector 51 having the form of a portion of parabolord. The two planar reflectors 54,56, with variable orientation, are supported by at least one of their ends on the planar support 55, to which they are connected by articulation. The planar support 55 can itself be mounted on the flat surface 58 by means of mechanical dispositij 57 for fixing, and for adjusting the inclination of the antenna.

 A support in cylinder trunk 59, made of a material permeable to electromagnetic radiation, ensures the rigidity of the assembly, and justifies the cutting of each of the plan reflectors 54 56 according to a substantially elliptical contour. Shielding of the antenna structure can be achieved by applying a metallic coating to appropriate areas of the support 59, and the antenna structure thus produced can be filled with a foam transparent to electromagnetic radiation to improve the rigidity, preventing the penetration of moisture.

 This embodiment lends itself perfectly to the mass production of the dual-frequency antenna with independent orientable beams according to the invention.

 Finally, a last embodiment of the invention is shown in FIG. 5. This embodiment corresponds more particularly to the integration of the antenna according to the invention on a satellite platform. In this case, the antenna is deployable, from a launch position in which all of the reflectors are inscribed inside the cap (dotted representation).

The type of launching cap shown here is that which belongs to a SPELDA type 10 double launching device from the European Space Agency. When the satellite has been placed in orbit, the antenna is then easily deployed (shown in solid lines). The sources 62, 63 are mounted on the body of the satellite so that the signals which they emit are reflected by the parabolic portion of the reflector 61, in order to form the resulting signals 70, 71 via the set of planar secondary reflectors 64, 66 independently adjustable.

 This embodiment is perfectly suited to the application of the invention in a relay satellite, placed in geostationary orbit, and communicating simultaneously with several distinct users at two different frequencies, for example between 2025 and 2300 MHZ on the one hand, and between 25.25 and 27 GHz on the other hand. In the embodiment of FIG. 5, and the fact that the SPELDA is substantially symmetrical with respect to its vertical central axis, four antennas of the type shown can be deployed there independently of each other, which corresponds to the possibilities of communication with eight independent orbital or ground stations.

 As an indication, it has been calculated that a sweep on lO e of solid half-angle makes it possible to pursue satisfactorily 2 independent satellites in low orbit from an antenna according to the invention placed in geostationary orbit.

 Of course, other embodiments and configuration of the dual-frequency antenna with independent orientable beams can be envisaged, without departing from the scope of the invention. It is in particular possible to use for example a small additional auxiliary reflector shaped in order to increase the illumination efficiency of the antenna, the main reflector itself being shaped for this purpose.

 The antenna according to the invention therefore constitutes a very efficient embodiment of a dual-frequency system with independent orientable beams, having the qualities of compactness, simplicity of implementation, and operating precision required for space applications.

Claims (3)

 10. Dual-frequency antenna of the type consisting of a main reflector (11,31,51,61), illuminated by at least two adjacent sources (12,13; 32,33; 52,53; 62,63) placed in its area focal and operating at separate frequencies,  characterized in that said main reflector cooperates with a set of two superposed secondary reflectors (14,16; 34,36; 54,56; 64,66) of which the first (14,34,54,64) secondary reflector facing said main reflector (11,31,51,61) is di chronic so as to be transparent for the signals emitted by one of said sources (13,33,53,63),  and in that the orientation of at least one of said secondary reflectors is variable with respect to the main reflector.  20. Dual-frequency antenna according to claim 1, characterized in that the means for orienting said secondary reflectors are constituted by drive mechanisms (15, 17) located at at least one of their ends.  30. Dual-frequency antenna according to claim 1 characterized in that the relative position of the sources and the main and secondary reflectors is determined so that the signals from the sources first meet the main reflector and then the set of secondary reflectors  40. Dual-frequency antenna according to claim 1, characterized in that the main reflector consists of a portion of concave paraboloSde and cooperates with a set of two planar secondary reflectors.  5. Antenna according to claim 1, characterized in that the main reflector 11 consists of a portion of an offset dish, said sources (12,13) being offset with respect to said main reflector (11j, and in that the orientable secondary reflectors ( 14,16) are arranged so as to direct the final emission radiation into the half space situated on the source side (12,13) relative to the main reflector (113.  6. Antenna according to claim 1, characterized in that the adjacent sources (12,13) are arranged in the central region of the surface of the set of secondary reflectors (14,16, in the manner of a Cassegrain antenna.  Antenna according to claim 1, characterized in that it comprises an additional system of two confocal parabolic reflectors (42,43) for enlarging the exit opening.