FR2952759A1 - Reflector focal network and antenna for use in satellite to cover chosen geographical area of geostationary orbit, has sub-reflector misaligning and/or deforming beam from selected sources to produce spot near area - Google Patents

Abstract

The antenna has a control unit (50) selecting some of elementary sources adapted to cover a chosen geographical area, from a set of elementary sources (40) that are constituted of radiant elements e.g. slits. A main reflector (20) and an electrically/mechanically reconfigurable sub-reflector (30) are arranged one with respect to another to reflect one or a set of signals issued from/intended to the sources. The sub-reflector misaligns and/or deforms the beam from the selected sources to produce a spot near the area, to reduce constraints related to misalignment at level of the sub-reflector.

Description

GENERAL TECHNICAL FIELD The invention relates to reflector antennas embedded on satellites and intended to transmit and / or receive electromagnetic waves over a reconfigurable coverage area in flight.

STATE OF THE ART Reflector antennas are a very common technical solution for covering a selected geographical area from a geostationary orbit. These antennas are generally used to obtain a high directivity Io, given the dimensions of the reflectors which are generally greater than ten wavelengths. Figure 1 illustrates a reflector antenna of known type. Such an antenna comprises an elementary source 10, a main reflector 20 and a subreflector 30. A parabolic-type reflector antenna naturally produces a beam pointing in the main axis of the antenna and characterized by iso-level curves. projected concentric and quasi-circular. By forming the surface of the reflector (s), it is possible to produce a misalignment of the beam with respect to the main axis of the antenna and / or to modify the shape of the iso-level curves in order to better correspond to a geographical area. chosen. For some satellite applications such as communications, for example, the need for coverage may vary during the life of the satellite. It appears essential for the next generations of satellites to be able to offer a reconfiguration capability in flight of the coverage areas, thus requiring a reconfiguration of the beam produced by the antenna. By beam formation or reconfiguration is meant the possibility of producing misalignment and / or deformation of projected iso-level curves. To ensure this reconfiguration of the beam while limiting the number of controls, a widespread solution is to use a sub-reflector 30 reconfigurable mechanically (flexible surface associated with actuators for example) or electrically (reflector array consisting of a set of cells to phase shifters for example). To cover the selected geographical zone, in transmission mode, the electromagnetic signal is emitted by the source 10 in the direction of the subreflector 30. The emitted wave is said to be spherical because the electromagnetic signal is equispaced on a spherical surface. By its mechanically or electrically reconfigured shape, the subreflector introduces an amplitude and / or phase deformation of the wave which, after reflection on Io, the main reflector 20 will produce a formed beam. As known per se, these reflector antennas make it possible to produce spots with a relatively high directivity (typically of the order of 40 dB for satellite telecommunications applications when a main reflector of a hundred wavelength diameter is projected is used) over a selected geographical area. Several reconfigurable reflector antenna solutions are known. A first solution consists in the use of an electrically reconfigurable sub-reflector reflector network type. Such a solution is described in S. Xu et al. in "Subreflectarrays for reflector surface distortion compensation", IEEE Trans. Antennas and Propagation, Vol. 57, No. 2, February 2009. This configuration consists of a parabolic-shaped main reflector and a plane sub-reflector, the source is placed at the image point with respect to the sub-reflector of the focal point of the main reflector according to the principle illustrated in FIG. 1. The main reflector is thus dimensioned as in the case of a single reflector antenna and the subreflector has a function in initial plane mirror mode. The advantage of this configuration is that in its initial form, this solution is naturally broadband since all the cells of the reflector array 30 are in the same phase state. On the other hand, as the spot deforms and especially is depointed, the disparity of the phase states on all the cells tends to reduce the bandwidth of the antenna. Indeed, the cells are usually sized to produce a phase dynamic covering 2n radians, the phase value correcting the electric path difference between the real surface and the surface to be synthesized being adjusted to a given frequency to within 2n (usually the dimensioning is performed at the center frequency over a specified frequency band). As we move away from the sizing frequency, a natural phenomenon of phase dispersion taking into account the different cell states leads to a degradation Io directivity performance. A second solution consists in the use of a mechanically reconfigurable subreflector. Such a solution is for example described in P.J. B. Claricoats, "Reconfigurable mesh reflector antennas" A review ", IEE Colloquium on Reflector Antennas for the 90's", is 1992, for the case of a simple reflector antenna configuration. The disadvantage of this solution is to have a lower directivity (of the order of 30 dB) for a reasonable size of the reconfigurable surface. In addition, the electromagnetic energy emitted by the source must be focused by this same surface which supposes a global form of parabolic type. By using this concept of mechanically reconfigurable reflector in the case of a two-reflector solution whose sub-reflector is a plane mirror as shown in Figure 1, it is possible to substantially simplify the mechanical aspects of this antenna. Moreover, the potential in terms of reconfiguration is delimited by the mechanical deformation dynamics authorized by the actuators used. In addition, a problem common to the two solutions presented above is that to cover the selected geographical area it is appropriate to apply a sometimes significant deformation to the sub-reflector, often all the more important that the misalignment is strong, which implies strong constraints on the latter and tends to reduce the bandwidth of the antenna or to impose actuators with a larger race.

PRESENTATION OF THE INVENTION The invention overcomes the aforementioned drawbacks and in particular makes it possible to reduce the stresses applied to the sub-reflector. According to a first aspect, the invention relates to a reflector antenna and focal array for covering a selected geographical area comprising: a main reflector comprising a parabolic or quasi-parabolic reflective surface; a subreflector comprising a reflective surface of planar initial shape; an array of at least two elementary sources arranged and positioned to transmit and / or receive electromagnetic waves, the array being placed in the focal plane of the main reflector; source control means for selecting among the elementary sources, the elementary source (s) adapted (s) to achieve the chosen coverage; in which the main reflector and the sub-reflector are arranged one with respect to the other so as to reflect one or more signal (s) coming from the source network and / or intended for the network of sources, the subreflector being further adapted to detach and / or deform the beam from or intended for the selected element (s) element (s) to produce a spot close to the chosen coverage, thereby reducing the constraints related to misalignment at the subreflector. The implementation of a source network associated with a sub-reflector makes it possible to distribute the constraints appropriately between the source network (placed in the focal plane of the main parabolic reflector) and the subreflector. Relative deformations are therefore well reduced. Other aspects of the antenna according to the first aspect of the invention are as follows: the control means are adapted to control the amplitude and / or the phase of each elementary source by means of amplitude / phase laws applied on their accesses such that a source or several sources emit a chosen radiation pattern constituting a beam pointing in a preferred direction specific to the source (s) selected; the network comprises seven elementary sources, six sources being arranged regularly around a central source; the main reflector describes a parabolic surface and the source array is arranged so that the central source is at the image point, relative to the initial plane surface of the subreflector, of the focal point of the parabolic surface. the sub-reflector is mechanically configurable by the combination of a flexible surface and mechanical actuators the sub-reflector is electrically configurable by the use of a reflective network structure consisting of cells with several phase states allowing to modify the wavefront of the electromagnetic signal. Each source consists of a radiating element selected from the following group: circular horn, rectangular horn, printed element, a slot, a helix. According to a second aspect, the invention relates to a satellite comprising a reflector array antenna according to the first aspect of the invention. PRESENTATION OF THE FIGURES Other features and advantages of the invention will become apparent from the description which follows, which is purely illustrative and nonlimiting, and should be read with reference to the accompanying drawings, in which, in addition to FIG. 2 illustrates a reflector antenna according to the invention; FIG. 3 illustrates a focal network implemented in a reflector antenna according to the invention; FIG. 4 illustrates spots produced by a reflector antenna 30 according to the invention; FIG. 5 illustrates the relative deformation as a function of the distance at the center of the sub-reflector of the antenna according to the invention compared to a conventional reflector antenna; FIG. 6 illustrates the obtaining of the coverage of France by means of a reflector antenna according to the invention by the association of the signals coming from three sources; FIG. 7 illustrates the relative deformation as a function of the distance at the center of the sub-reflector of the antenna according to the invention for a case at a source and for a case with three sources; FIG. 8 illustrates a block diagram of a switching matrix of a focal network of a reflector antenna according to the invention; FIG. 9 illustrates a block diagram of a variable power divider that can be used to power a focal network of a reflector antenna according to the invention; Figure 10 illustrates a block diagram of an orthogonal matrix focal array; FIG. 11 illustrates a block diagram of an 8x8 hybrid matrix that can be used to power a focal array of a reflector antenna according to the invention; FIG. 12 illustrates a block diagram of a generalized orthogonal matrix that can be used to power a focal network of a reflector antenna according to the invention.

DETAILED DESCRIPTION OF THE INVENTION Antenna Description FIG. 2 illustrates a reflector array antenna for coverage of a selected geographic area. This antenna comprises an array of elementary sources 40, a main reflector 30, a subreflector 20 and control means 50 for selecting among the elementary sources 40, the elementary source (s) adapted (s) ) to achieve the chosen coverage. Each source consists of a radiating element chosen from the following group: circular horn, rectangular horn, printed element, a slot, a helix. In this antenna, the main reflector 30 and the subreflector 20 are arranged relative to each other so as to reflect the signal / signals from the source network (when the antenna operates in transmission) and / or intended for the source network (when the antenna 10 operates in reception). The subreflector 20 is adapted to detach and / or deform each beam of a selected elemental source so as to form a spot corresponding to the selected coverage. The main reflector 30 and the subreflector 20 each comprise a reflective surface (not shown). The subreflector 30 is reconfigurable mechanically (solution based on mechanical actuators for example) or electrically (reflector network type solution for example). FIG. 3 illustrates a view in the focal plane of a reflector array with seven sources distributed in a triangular mesh. As already mentioned, the antenna comprises control means 50 for selecting from among the elementary sources, the elementary source (s) adapted (s) to achieve the chosen coverage. These control means consist in particular of an amplitude control network making it possible to select the most suitable source or sources that correspond to the coverage chosen. The chosen coverage is achieved by the formation of a spot. Figure 4 illustrates the set of spots that can produce the focal network of Figure 3. This is the image of this network.

By selecting the source or sources forming a spot as close as possible to the chosen coverage, it is possible to reduce the constraints on the subreflector.

To achieve the coverage chosen, there are two cases.

First case: A single source makes it possible to achieve the chosen coverage (for example the Iberian Peninsula as illustrated in Figure 4). In this case only one source will be selected: it is the one of which the spot produces, with a sub -reflector in initial configuration (flat shape), is the closest to the selected geographical area to cover. The deformation of the subreflector is then optimized to point more precisely the spot formed on the area to be covered. The subreflector also makes it possible to adjust the shape of the spot to the selected area to be covered. FIG. 5 illustrates the relative deformation of the subreflector obtained with the antenna of FIG. 2 compared with a reference solution (that is to say a solution without a source network) for the case of an Iberian cover. This is expressed in wavelengths for a reflector antenna configuration characterized by: ù a projected diameter of the main reflector of one hundred wavelengths; a focal length associated with the parabolic surface of the main reflector of one hundred wavelengths; a clearance of the reflector with respect to the focal axis of fifty wavelengths; a circular sub-reflector whose diameter is twenty four wavelengths; a focal network characterized by a pitch of four wavelengths.

As this deformation is expressed in wavelengths, it can be interpreted directly in terms of mechanical deformation.

To interpret this deformation in terms of necessary phase shift, in the case of an electrically reconfigurable subreflector, it suffices to consider that a wavelength is equivalent to 2n radians. It is noted that the average relative deformation as a function of the distance at the center of the sub-reflector is reduced over the entire sub-reflector and this, very significantly on the central part. As a result, by imposing constraints on the mechanical displacement dynamics or on the phase dispersion, which would ultimately only concern the peripheral part of the subreflector, it is possible to significantly reduce the deformation required for highly detuned spots.

Second case: Several sources are associated to achieve the chosen coverage (eg France as illustrated in Figure 4) In this case, we will select the source or sources forming the spots is best suited to achieve the chosen coverage. When we restrict ourselves in this case to a single source, we find the previous case. For example, referring to Figure 4, for the coverage of France, we will select the sources that can form the three spots around France and then applying a deformation on the under-reflector we will detach the beams in order to achieve the coverage of France. This solution is more favorable than detaching a single beam to achieve the coverage of France. Figure 6 illustrates the coverage of France by pointing out the three beams producing the three spots surrounding France. Figure 7 illustrates the results in terms of relative deformation of the subreflector in the case with a source and in the case with three sources. The use of the three sources allows in this case a significant reduction of the deformations relative to the level of the sub-reflector on almost the entire surface. Only the edge has a large deformation but it could be truncated given the low electric field levels at the periphery of the sub-reflector. It should be noted that the performances in the case one source were obtained with the central source. But very similar performances would have been obtained with the other sources, the coverage chosen being in this particular case equidistant from the three potentially usable spots.

Control of the network of elementary sources I o Several embodiments can be envisaged for the control of the network of elementary sources according to the desired operating mode (one or more sources). The simplest is to use a matrix of switches. FIG. 8 illustrates the block diagram of a switch matrix with two states (allowing one port to be selected from the two output ports in transmit mode, respectively to input in receive mode) in the case of a network to seven sources. Six C1-C6 switches are required to select one of seven S1-S7 sources. Depending on the technologies used, which will strongly depend on the power levels required in transmission, switches with more than two states may also be used to reduce the number of components required to access all the sources of the focal network. Sizing of the switch matrix can also be done to allow the simultaneous use of multiple sources by interleaving switches and dividers and / or power combiners. Two other embodiments also allow for possibly a combination of sources, which provides increased primary beam pointing flexibility by power distribution on one or more sources.

The first is to realize the source network according to the principle of the matrix of switches, but replacing each switch by a variable power divider. Figure 9 illustrates the principle of operation of this component.

This component is the cascading of two hybrid couplers and a phase shifter. The power distribution is controlled by the phase delay O introduced by the phase shifter, one of the outputs having a power level at 0 0 cos 2 2 ~ and the other at sin 2 2. This component can even be used as a switch if the two-phase phase shifter is restricted to {0; z}. The second embodiment allowing an amplitude distribution on one or more sources is a generalization of the variable power divider. Figure 10 illustrates such an embodiment. This is obtained by associating a section 121 of balanced power division, a section 122 of variable phase shifters (one less than the number of sources because only the relative phases are important for the proper functioning of this structure) and a section of orthogonal matrix type 123 (this matrix can be made according to the principle of a simplified Butler matrix, a Nolen matrix or a combination of both depending on the number of ports required). The power division section 121 consists of a cascade of dividers with two or more output ports, depending on the technology used. This section can also possibly be replaced by an orthogonal matrix. This section 121 must ensure a balanced distribution on all the outputs of the available input power (conversely, in receive mode, this section must ensure a balanced combination of all inputs).

The technology adopted for the phase shifters 122 will depend on the position of the amplification stage. This will consist of power amplifiers (transmit) or low-noise amplifiers (receive) that can be positioned between the phase shifter section and the orthogonal matrix or between the phase shifters and the power division section. One could also consider a centralized amplification, if the technologies of phase-shifters and associated performances (in particular in losses and heat dissipation) allow it. For the orthogonal matrix 123, the chosen solution will strongly depend on the number of ports required. This matrix can be made by a simplified Butler matrix or hybrid matrix as described by S. Egami and M. Kawai in "An adaptive multiple beam system concept", IEEE Journal on Selected Areas in Communications, Vol. SAC-5, No. 4, May 1987, pp. 630-636.

An example of a hybrid matrix 8x8 is illustrated in FIG. 11. More generally, a matrix having 2n inputs consists of n hybrid coupler layers c each having 2n-1 couplers, the layers being interconnected to ensure a balanced and parallel distribution. energy input to all outputs.

The disadvantage of these matrices in their generic form is that the number of ports is necessarily a power of two, a constraint imposed by the use of the hybrid coupler as the basic component. If it is desired to have a number of ports not constrained by this condition, a Nolen matrix, described by N. J. G. Fonseca in "Printed S-band 4x4 Nolen matrix for multiple beam antenna applications" IEEE Trans. on Antennas and propagation, Vol. 57, Issue 6, June 2009, pp. 1673-1678. The schematic diagram of a Nolen matrix is shown in Figure 12.

These matrices are characterized by a series supply, which makes it possible to fix the number of ports more freely. This matrix consists of a set of supply lines (horizontal lines in the figure, inputs al-aM) and a set of output lines (vertical lines in the figure, outputs b, -bN), the crossings being made by directional couplers c. Each node of the matrix may also include a phase shifter to provide the orthogonal character. On the other hand, depending on the chosen technology, these matrices may have a higher complexity (more components, limited component reuse) than the modified Butler matrix equivalent or hybrid matrix when the number of ports is a power lo of two. Thus, for relatively large matrices, it is preferable to use a combination of these two matrices, the Nolen matrix being able to serve as a sub-block in a generalized hybrid matrix. This combination makes it possible to remove the constraint on the number of ports while maintaining a reduced number of components. 15

Claims (8)

REVENDICATIONS1. A reflector antenna and a reflector focal array for covering a selected geographical area comprising: - a main reflector comprising a parabolic or quasi-parabolic reflective surface; a subreflector comprising a reflective surface of planar initial shape; an array of at least two elementary sources arranged and positioned to emit and / or receive electromagnetic waves, the array being placed in the focal plane of the main reflector; source control means making it possible to select from the elementary sources the elementary source (s) adapted to achieve the chosen coverage; in which the main reflector and the subreflector are arranged relative to one another so as to reflect one or more signal / signals coming from the source network and / or intended for the source network the subreflector being further adapted to detach and / or deform the beam from or destined for the selected elemental source (s) to produce a spot close to the selected coverage, thereby reducing constraints related to misalignment at the subreflector. 25 An antenna according to claim 1 wherein the control means is adapted to control the amplitude and / or phase of each elemental source by means of amplitude / phase laws applied on their accesses so that one or more sources Sources emit a selected radiation pattern constituting a beam pointing in a preferred direction specific to the selected source (s). 3. Antenna according to one of claims 1 to 2, wherein the network comprises seven elementary sources, six sources being arranged regularly around a central source. 4. Antenna according to one of claims 1 to 3 wherein the main reflector describes a parabolic surface and the source array is arranged so that the central source is at the image point, relative to the initial planar surface of the subreflector , from the focal point of the parabolic surface. i0 5. Antenna according to one of claims 1 to 4 wherein the subreflector is mechanically configurable by the combination of a flexible surface and mechanical actuators 15 6. Antenna according to one of claims 1 to 4 wherein the sub-reflector is electrically configurable by the use of a reflective array type structure consisting of multi-phase state cells for changing the wavefront of the electromagnetic signal. 20 7. Antenna according to one of claims 1 to 6 wherein each source consists of a radiating element selected from the following group: circular horn, rectangular horn, printed element, a slot, a helix. 25 8. Satellite comprising an antenna according to one of claims 1 to 7.