EP0417679A1 - Multiple beam antenna, steerable by low switching rate - Google Patents

Multiple beam antenna, steerable by low switching rate Download PDF

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Publication number
EP0417679A1
EP0417679A1 EP90117354A EP90117354A EP0417679A1 EP 0417679 A1 EP0417679 A1 EP 0417679A1 EP 90117354 A EP90117354 A EP 90117354A EP 90117354 A EP90117354 A EP 90117354A EP 0417679 A1 EP0417679 A1 EP 0417679A1
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European Patent Office
Prior art keywords
antenna
reflector
network
generalized
outputs
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EP90117354A
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German (de)
French (fr)
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EP0417679B1 (en
Inventor
Trevor C/O Sospi Jones
Antoine C/O Sospi Roederer
Régis Lenormand
Gérard Raguenet
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Alcatel Espace Industries SA
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Alcatel Espace Industries SA
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q25/00Antennas or antenna systems providing at least two radiating patterns
    • H01Q25/007Antennas or antenna systems providing at least two radiating patterns using two or more primary active elements in the focal region of a focusing device
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q3/00Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system
    • H01Q3/26Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system varying the relative phase or relative amplitude of energisation between two or more active radiating elements; varying the distribution of energy across a radiating aperture
    • H01Q3/2658Phased-array fed focussing structure
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q3/00Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system
    • H01Q3/26Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system varying the relative phase or relative amplitude of energisation between two or more active radiating elements; varying the distribution of energy across a radiating aperture
    • H01Q3/30Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system varying the relative phase or relative amplitude of energisation between two or more active radiating elements; varying the distribution of energy across a radiating aperture varying the relative phase between the radiating elements of an array
    • H01Q3/34Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system varying the relative phase or relative amplitude of energisation between two or more active radiating elements; varying the distribution of energy across a radiating aperture varying the relative phase between the radiating elements of an array by electrical means
    • H01Q3/40Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system varying the relative phase or relative amplitude of energisation between two or more active radiating elements; varying the distribution of energy across a radiating aperture varying the relative phase between the radiating elements of an array by electrical means with phasing matrix

Definitions

  • the invention relates to a multibeam antenna orientable by low level switching.
  • a work entitled "space telecommunications" of the technical and scientific collection of telecommunications in particular in its volume I pages 92 to 94 and pages 259 to 261 describes on the one hand the fact of grouping several antennas, fed simultaneously by the same transmitter with the interposition of power dividers and phase shifters, the radiation characteristics of this group depending both on the diagram of each antenna and on the distribution of powers in amplitude and phase. This property is used to obtain a diagram which could not be obtained with a single radiating source. If, in addition, the characteristics of the power dividers and phase shifters are modified by electronic means, it is possible to obtain an almost instantaneous modification of the diagram.
  • the simplest grouping of radiating sources is the network, in which all the sources are identical and are deduced from each other by any translation. One can thus realize rectilinear or planar networks.
  • the illumination system of the reflector is generally off-center with respect to the latter so as to avoid any blockage of the radiating opening and to facilitate installation on the platform in the case of a spatial application.
  • the main reflector is for example a paraboloid.
  • the mobile beams are in fact the combination of elementary beams, obtained by placing a set of sources of illumination in the vicinity of the focal point, each source corresponding to an elementary beam.
  • the illumination is not geometrically perfect and there are phase aberrations which slightly degrade the radiation performance, therefore decreases in gain compared to the values achievable at home. These degradations are all the more important that you move away from the focal point and that the curvature of the reflector is large. Reflectors must therefore be made as "flat” as possible, that is to say with a focal distance to high aperture diameter ratio. This leads to structures of large dimensions which pose problems of precision and mechanical strength.
  • the configuration of these large antennas must also take into account several system aspects: - satellite volume limitation, linked to the need for an antenna to transmit and receive simultaneously; - compatibility of an easy mechanical arrangement on the platform, and on the launcher before and during operation; - good thermal control; - possible multiplicity of missions and users.
  • the object of the invention is to provide a low-level switching orientable antenna which makes it possible to solve these various problems which can operate with very good overall efficiency of the antenna + amplifier subsystem regardless of the number of users; number may be small, for example less than five.
  • the invention proposes for this purpose a multibeam antenna orientable by low level switching comprising a reflector focusing energy, a network of elementary sources, located in the focal zone of the reflector so as to carry out the synthesis of the electromagnetic field in this focal zone and electronics comprising an amplification stage with m inputs and m outputs, characterized in that the coverage area is produced by m spots, each corresponding to a defined number of active elementary sources, and in that the electronics comprise at least a low level switch enabling an input to be connected to one of the f outputs.
  • the invention Compared to mechanical solutions, the invention has the advantage of not requiring movement of the source or the reflector. It allows the use of weak focal lengths (antenna compact), and to provide several simultaneous connections.
  • the advantages compared to a direct radiation network solution are as follows: - The performance of the antenna is not directly linked to the total size of the network; - The installation is not necessarily on the earth face of the satellite.
  • the proposed solution Compared to an imaging network solution with a single reflector, the proposed solution has the following advantages: - the overall dimension of the network is reduced; - the antenna efficiency is improved.
  • the antenna of the invention shown in FIG. 1, comprises an eccentric parabolic reflector 10 supplied by a planar network 11 of sources located in the vicinity of the focal point F of the reflector, the network 12 representing the network of virtual sources, corresponding to this network 11.
  • FIG. 2 gives an example of several amplitude distributions during displacements in two directions OX and OY at the level of the network 11 of sources.
  • the diameters of the disks carried in FIG. 2 represent the amplitude of the signal received by the various sources of the network.
  • the antenna directivity performance is defined by the level of coverage of the spots.
  • the antenna of the invention is provided for a number m of spots, a determined number of radiating elements or sources corresponding to each spot; all the radiating elements, corresponding to a given spot operating non-simultaneously.
  • An embodiment of electronics of such an antenna according to the invention comprises: . a switch, or "switch", low level C1 making it possible to connect the input E to one of the groups of radiating elements corresponding to a spot SPi; . an amplification stage 16 with m inputs and m outputs comprising a first and a second generalized couplers 17 and 18 arranged on either side of m amplifiers 19 arranged in parallel; m filters 20 being arranged at the output of these amplifiers 19.
  • the amplification stage 16 comprises a first and a second generalized couplers 17 and 18 respectively formed from a combination of couplers hybrids 21 on either side of amplifiers 19, respectively associated with a filter 20, so that each input of the first coupler 17 is distributed over all the amplifiers 19 and therefore over all the outputs of the hybrid couplers of the first generalized coupler 18.
  • the amplifiers 19 thus have a constant input power and can thus operate at their nominal capacity.
  • a signal applied to the first input for example, spring amplified on the first output. So if a signal is applied to one of the inputs of rank i for example, to the corresponding output (of rank i) the signal will be amplified by all the amplifiers and no other output will receive a signal: Indeed a signal injected into the one of the input gates of a generalized coupler is divided into n components of equal amplitude, at the level of the n outputs, if and only if, no signal being coherent to it, is injected at another input.
  • the inputs can be split using at least one second switch Ci, the combination of the signals being effected on each input Ei of the amplification stage 16, by means of couplers known from the skilled in the art and not shown.
  • the coverage to be produced has been divided into m zones.
  • a group of sources from the primary network of the antenna radiates a beam SPi.
  • each of the sources contributes to the radiation of a single beam SPi.
  • the level of overlap between beams, defined at the border of the zones, is subject to the optimization of the excitation coefficients of the sources.
  • the antenna thus defined corresponds to a given coverage, m independent access. It follows that an amplifier stage, including generalized couplers with m inputs / outputs makes it possible to use the m amplifiers 19 optimally (constant input load) whatever the spot SPi considered.
  • a signal is radiated in any direction of coverage by the addressing of said input signal from the amplification stage 16 which corresponds to the area containing this direction.
  • the m amplifiers 19 are dimensioned to obtain the radiated power required.
  • the extension to multi-user operation (p users) is achieved by grouping by coupling p connection circuits Ci.
  • This grouping is done using low level techniques.
  • the amplifiers are dimensioned as a function of the sum of the powers to be radiated.

Abstract

The invention relates to a multiple beam antenna which can be steered by low-level switching comprising a network (11) of elementary sources, an energy-focusing reflector (10), the network (11) being situated in the focal region of the reflector, in such a way as to produce the synthesising of the electromagnetic field in this focal region, and the region of coverage being produced by m spots, each spot corresponding to a definite number of active elementary sources. Application in particular to the field of space telecommunications. <IMAGE>

Description

L'invention se rapporte à une antenne multifaisceaux orientable par commutation bas niveau.The invention relates to a multibeam antenna orientable by low level switching.

Un ouvrage intitulé "télécommunications spatiales" de la collection technique et scientifique des télécommunications notamment dans son tome I pages 92 à 94 et pages 259 à 261 (Masson, 1982) décrit d'une part le fait de grouper plusieurs antennes, alimentées simultanément par le même émetteur avec interposition de diviseurs de puissances et de déphaseurs, les caractéristiques de rayonnement de ce groupement dépendant à la fois du diagramme de chaque antenne et de la répartition des puissances en amplitude et phase. Cette propriété est mise à profit pour obtenir un diagramme qui ne pourrait pas être obtenu avec une seule source rayonnante. Si, en outre, on modifie les caractéristiques des diviseurs de puissance et des déphaseurs par des moyens électroniques, on peut obtenir une modification quasi-instantanée du diagramme. Le groupement le plus simple de sources rayonnantes est le réseau, dans lequel toutes les sources sont identiques et se déduisent l'une de l'autre par une translation quelconque. On peut réaliser ainsi des réseaux rectilignes ou plans.A work entitled "space telecommunications" of the technical and scientific collection of telecommunications in particular in its volume I pages 92 to 94 and pages 259 to 261 (Masson, 1982) describes on the one hand the fact of grouping several antennas, fed simultaneously by the same transmitter with the interposition of power dividers and phase shifters, the radiation characteristics of this group depending both on the diagram of each antenna and on the distribution of powers in amplitude and phase. This property is used to obtain a diagram which could not be obtained with a single radiating source. If, in addition, the characteristics of the power dividers and phase shifters are modified by electronic means, it is possible to obtain an almost instantaneous modification of the diagram. The simplest grouping of radiating sources is the network, in which all the sources are identical and are deduced from each other by any translation. One can thus realize rectilinear or planar networks.

Ce document décrit, d'autre part, l'utilisation d'antennes à réflecteur pour la génération de plusieurs faisceaux mobiles qui présentent l'avantage d'une faible masse liée à l'utilisation d'étages amplificateurs optimisés. Le système d'illumination du réflecteur est en général, décentré par rapport à celui-ci de façon à éviter tout blocage de l'ouverture rayonnante et faciliter l'implantation sur la plateforme dans le cas d'une application spatiale. Le réflecteur principal est par exemple un paraboloïde. Les faisceaux mobiles sont en fait la combinaison de faisceaux élementaires, obtenus en plaçant un ensemble de sources d'illumination au voisinage du foyer, chaque source correspondant à un faisceau élémentaire.This document describes, on the other hand, the use of reflector antennas for the generation of several mobile beams which have the advantage of a low mass linked to the use of optimized amplifier stages. The illumination system of the reflector is generally off-center with respect to the latter so as to avoid any blockage of the radiating opening and to facilitate installation on the platform in the case of a spatial application. The main reflector is for example a paraboloid. The mobile beams are in fact the combination of elementary beams, obtained by placing a set of sources of illumination in the vicinity of the focal point, each source corresponding to an elementary beam.

Du fait que l'on ne peut pas les placer exactement au foyer, l'illumination n'est pas géométriquement parfaite et il se produit des aberrations de phase qui dégradent quelque peu les performances de rayonnement, donc des baisses de gain par rapport aux valeurs réalisables au foyer. Ces dégradations sont d'autant plus importantes que l'on s'écarte du foyer et que la courbure du réflecteur est importante. On doit donc réaliser des réflecteurs aussi "plats" que possible, c'est-à-dire avec un rapport distance focale à diamètre d'ouverture élevé. Ceci conduit à des structures de dimensions importantes qui posent des problèmes de précision et de tenue mécanique.Because they cannot be placed exactly at the focal point, the illumination is not geometrically perfect and there are phase aberrations which slightly degrade the radiation performance, therefore decreases in gain compared to the values achievable at home. These degradations are all the more important that you move away from the focal point and that the curvature of the reflector is large. Reflectors must therefore be made as "flat" as possible, that is to say with a focal distance to high aperture diameter ratio. This leads to structures of large dimensions which pose problems of precision and mechanical strength.

Les applications spatiales, qui nécessitent une déflexion électronique de l'onde rayonnante sur un large champ de vue, conduisent à des déviations angulaires de plusieurs largeurs de pinceau. En conséquence la possibilité de contrôler précisément la forme du diagramme de l'antenne est essentielle.Space applications, which require an electronic deflection of the radiating wave over a wide field of view, lead to angular deviations of several brush widths. Consequently, the possibility of precisely controlling the shape of the antenna diagram is essential.

La configuration de ces grandes antennes doit aussi tenir compte de plusieurs aspects système :
- limitation en volume du satellite, liée à la nécessité pour une antenne de transmettre et de recevoir simultanément ;
- compatibilité d'un agencement mécanique aisé sur la plate-forme, et sur le lanceur avant et pendant le fonctionnement ;
- bon contrôle thermique ;
- multiplicité éventuelle des missions et des utilisateurs.The configuration of these large antennas must also take into account several system aspects:
- satellite volume limitation, linked to the need for an antenna to transmit and receive simultaneously;
- compatibility of an easy mechanical arrangement on the platform, and on the launcher before and during operation;
- good thermal control;
- possible multiplicity of missions and users.

L'objet de l'invention est de réaliser une antenne orientable à commutation bas niveau permettant de résoudre ces différents problèmes qui puisse fonctionner avec une très bonne efficacité globale du sous système antenne + amplificateurs quel que soit le nombre d'utilisateurs ; nombre pouvant être faible, par exemple inférieur à cinq.The object of the invention is to provide a low-level switching orientable antenna which makes it possible to solve these various problems which can operate with very good overall efficiency of the antenna + amplifier subsystem regardless of the number of users; number may be small, for example less than five.

L'invention propose à cet effet une antenne multifaisceaux orientable par commutation bas niveau comprenant un réflecteur focalisant l'énergie, un réseau de sources élémentaires, situé dans la zone focale du réflecteur de manière à réaliser la synthèse du champ électromagnétique dans cette zone focale et une électronique comprenant un étage d'amplification à m entrées et m sorties, caractérisée en ce que la zone de couverture est réalisée par m spots, correspondant chacun à un nombre défini de sources élémentaires actives, et en ce que l'électronique comporte au moins un commutateur bas niveau permettant de relier une entrée à l'une des f sorties.The invention proposes for this purpose a multibeam antenna orientable by low level switching comprising a reflector focusing energy, a network of elementary sources, located in the focal zone of the reflector so as to carry out the synthesis of the electromagnetic field in this focal zone and electronics comprising an amplification stage with m inputs and m outputs, characterized in that the coverage area is produced by m spots, each corresponding to a defined number of active elementary sources, and in that the electronics comprise at least a low level switch enabling an input to be connected to one of the f outputs.

Par rapport aux solutions mécaniques, l'invention présente l'avantage de ne pas nécessiter de mouvements de la source ou du réflecteur. Elle permet d'utiliser des focales faibles (antenne compacte), et d'assurer plusieurs liaisons simultanées.Compared to mechanical solutions, the invention has the advantage of not requiring movement of the source or the reflector. It allows the use of weak focal lengths (antenna compact), and to provide several simultaneous connections.

Les avantages par rapport à une solution réseau à rayonnement direct sont les suivants :
- La performance de l'antenne n'est pas liée directement à la dimension totale du réseau ;
- L'implantation n'est pas obligatoirement sur la face terre du satellite.The advantages compared to a direct radiation network solution are as follows:
- The performance of the antenna is not directly linked to the total size of the network;
- The installation is not necessarily on the earth face of the satellite.

Par rapport à une solution réseau imageur à simple réflecteur, la solution proposée présente les avantages suivants :
- la dimension hors tout de réseau est réduite ;
- l'efficacité antenne est améliorée.Compared to an imaging network solution with a single reflector, the proposed solution has the following advantages:
- the overall dimension of the network is reduced;
- the antenna efficiency is improved.

Enfin, si on compare la solution proposée à une solution réseau imageur à double réflecteur, la compacité de l'antenne de l'invention est clairement mise en évidence.Finally, if we compare the proposed solution to an imaging network solution with double reflector, the compactness of the antenna of the invention is clearly highlighted.

Les caractéristiques et avantages de l'invention ressortiront d'ailleurs de la description qui va suivre, à titre d'exemple non limitatif, en référence aux figures annexées sur lesquelles :

  • - la figure 1 illustre schématiquement l'antenne à balayage selon l'invention ;
  • - la figure 2 illustre le fonctionnement de l'antenne selon l'invention ;
  • - la figure 3 illustre une première réalisation de l'électronique de l'antenne selon l'invention ;
  • - la figure 4 illustre un étage de l'électronique telle que représentée à la figure 3 ;
  • - la figure 5 illustre une seconde réalisation d'une électronique de l'antenne selon l'invention.
The characteristics and advantages of the invention will become apparent from the description which follows, by way of nonlimiting example, with reference to the appended figures in which:
  • - Figure 1 schematically illustrates the scanning antenna according to the invention;
  • - Figure 2 illustrates the operation of the antenna according to the invention;
  • - Figure 3 illustrates a first embodiment of the antenna electronics according to the invention;
  • - Figure 4 illustrates a stage of electronics as shown in Figure 3;
  • - Figure 5 illustrates a second embodiment of an antenna electronics according to the invention.

L'antenne de l'invention, représentée à la figure 1, comprend un réflecteur parabolique 10 excentré alimenté par un réseau plan 11 de sources situé au voisinage du foyer F du réflecteur, le réseau 12 représentant le réseau de sources virtuelles, correspondant à ce réseau 11.The antenna of the invention, shown in FIG. 1, comprises an eccentric parabolic reflector 10 supplied by a planar network 11 of sources located in the vicinity of the focal point F of the reflector, the network 12 representing the network of virtual sources, corresponding to this network 11.

La figure 2 donne un exemple de plusieurs répartitions en amplitude lors de déplacements selon deux directions OX et OY au niveau du réseau 11 de sources.FIG. 2 gives an example of several amplitude distributions during displacements in two directions OX and OY at the level of the network 11 of sources.

Les diamètres des disques portés sur la figure 2 représentent l'amplitude du signal reçu par les différentes sources du réseau.The diameters of the disks carried in FIG. 2 represent the amplitude of the signal received by the various sources of the network.

L'efficacité pour capter ces différentes répartitions d'énergie, lorsque le capteur a une loi de répartition fixe, ne peut être optimale. Il en est de même pour la répartition en phase.The efficiency for capturing these different energy distributions, when the sensor has a fixed distribution law, cannot be optimal. The same is true for phase distribution.

Ainsi si l'on déplace fictivement une source par rapport au foyer du réflecteur on dégrade le rendement de l'antenne.Thus if one fictitiously displaces a source with respect to the focus of the reflector one degrades the efficiency of the antenna.

Lorsque la couverture spécifiée est réalisée en utilisant plusieurs spots, la performance de directivité antenne est définie par le niveau de recouvrement des spots.When the specified coverage is achieved using multiple spots, the antenna directivity performance is defined by the level of coverage of the spots.

Ainsi l'antenne de l'invention est prévue pour un nombre m de spots, un nombre déterminé d'éléments rayonnants ou sources correspondant à chaque spot ; tous les éléments rayonnants, correspondant à un spot donné fonctionnant de manière non simultanée. Une réalisation d'une électronique d'une telle antenne selon l'invention, telle que représenté à la figure 3, comporte :
. un commutateur, ou "switch", bas niveau C1 permettant de relier l'entrée E à un des groupes d'éléments rayonnants correspondant à un spot SPi ;
. un étage d'amplification 16 à m entrées et m sorties comprenant un premier et un second coupleurs généralisés 17 et 18 disposés de part et d'autre de m amplificateurs 19 disposés en parallèle ; m filtres 20 étant disposés en sortie de ces amplificateurs 19.Thus, the antenna of the invention is provided for a number m of spots, a determined number of radiating elements or sources corresponding to each spot; all the radiating elements, corresponding to a given spot operating non-simultaneously. An embodiment of electronics of such an antenna according to the invention, as shown in FIG. 3, comprises:
. a switch, or "switch", low level C1 making it possible to connect the input E to one of the groups of radiating elements corresponding to a spot SPi;
. an amplification stage 16 with m inputs and m outputs comprising a first and a second generalized couplers 17 and 18 arranged on either side of m amplifiers 19 arranged in parallel; m filters 20 being arranged at the output of these amplifiers 19.

Comme représenté à la figure 4, dans un exemple de réalisation à 16 entrées et 16 sorties (m=16), l'étage d'amplification 16 comprend un premier et un second coupleurs généralisés 17 et 18 respectivement formés d'une association de coupleurs hybrides 21 de part et d'autre d'amplificateurs 19, associés respectivement à un filtre 20, de telle façon que chaque entrée du premier coupleur 17 soit répartie sur tous les amplificateurs 19 et donc sur toutes les sorties des coupleurs hybrides du premier coupleur généralisé 18. Les amplificateurs 19 ont ainsi une puissance d'entrée constante et peuvent ainsi fonctionner à leur capacité nominale.As shown in FIG. 4, in an exemplary embodiment with 16 inputs and 16 outputs (m = 16), the amplification stage 16 comprises a first and a second generalized couplers 17 and 18 respectively formed from a combination of couplers hybrids 21 on either side of amplifiers 19, respectively associated with a filter 20, so that each input of the first coupler 17 is distributed over all the amplifiers 19 and therefore over all the outputs of the hybrid couplers of the first generalized coupler 18. The amplifiers 19 thus have a constant input power and can thus operate at their nominal capacity.

Dans cet étage d'amplification 16 un signal appliqué à la première entrée, par exemple, ressort amplifié sur la première sortie. Ainsi si un signal est appliqué à l'une des entrées de rang i par exemple, à la sortie correspondante (de rang i) le signal sera amplifié par tous les amplificateurs et aucune autre sortie ne recevra de signal : En effet un signal injecté à l'une des portes d'entrée d'un coupleur généralisé est divisé en n composantes d'amplitude égales, au niveau des n sorties, si et seulement si, aucun signal lui étant cohérent, est injecté à une autre entrée.In this amplification stage 16 a signal applied to the first input, for example, spring amplified on the first output. So if a signal is applied to one of the inputs of rank i for example, to the corresponding output (of rank i) the signal will be amplified by all the amplifiers and no other output will receive a signal: Indeed a signal injected into the one of the input gates of a generalized coupler is divided into n components of equal amplitude, at the level of the n outputs, if and only if, no signal being coherent to it, is injected at another input.

Ainsi on adresse une source, ou un groupe de sources correspondant à un spot, en partant de l'entrée E : Il y a donc routage d'énergie entre les deux. A un spot correspond l'entrée E à un moment déterminé : on réalise donc une désignation successive des différents spots SP1 à SPn.Thus we address a source, or a group of sources corresponding to a spot, starting from the input E: There is therefore energy routing between the two. A spot corresponds to the input E at a determined time: a successive designation of the different spots SP1 to SPn is therefore carried out.

Dans le cas de plusieurs utilisateurs on peut dédoubler les entrées en utilisant au moins un second commutateur Ci, la combinaison des signaux s'effectuant sur chaque entrée Ei de l'étage d'amplification 16, par l'intermédiaire de coupleurs connus de l'homme de l'art et non représentés.In the case of several users, the inputs can be split using at least one second switch Ci, the combination of the signals being effected on each input Ei of the amplification stage 16, by means of couplers known from the skilled in the art and not shown.

Ainsi dans l'antenne selon l'invention la couverture à réaliser a été divisée en m zones. Pour chacune des m zones, un groupement de sources du réseau primaire de l'antenne, rayonne un faisceau SPi. Par principe chacune des sources contribue au rayonnement d'un seul faisceau SPi. Le niveau de recouvrement entre faisceaux, défini à la frontière des zones, fait l'objet de l'optimisation des coefficients d'excitation des sources.Thus in the antenna according to the invention the coverage to be produced has been divided into m zones. For each of the m zones, a group of sources from the primary network of the antenna radiates a beam SPi. In principle, each of the sources contributes to the radiation of a single beam SPi. The level of overlap between beams, defined at the border of the zones, is subject to the optimization of the excitation coefficients of the sources.

Dans la pratique, ces coefficients définis en amplitude et en phase sont réalisés par un répartiteur fixe Ri.In practice, these coefficients defined in amplitude and in phase are produced by a fixed distributor Ri.

L'antenne ainsi définie fait correspondre à une couverture donnée, m accès indépendants. Il s'en suit qu'un étage amplificateur, incluant des coupleurs généralisés à m entrées/sorties permet d'utiliser les m amplificateurs 19 de manière optimale (charge d'entrée constante) quel que soit le spot SPi considéré.The antenna thus defined corresponds to a given coverage, m independent access. It follows that an amplifier stage, including generalized couplers with m inputs / outputs makes it possible to use the m amplifiers 19 optimally (constant input load) whatever the spot SPi considered.

Ainsi un signal est rayonné dans une direction quelconque de la couverture par l'adressage dudit signal d'entrée de l'étage d'amplification 16 qui correspond à la zone contenant cette direction.Thus a signal is radiated in any direction of coverage by the addressing of said input signal from the amplification stage 16 which corresponds to the area containing this direction.

Les m amplificateurs 19 sont dimensionnés pour obtenir la puissance rayonnée requise. L'extension à un fonctionnement multi-utilisateurs (p utilisateurs) est réalisé grâce à un regroupement par couplage de p circuits de connexions Ci.The m amplifiers 19 are dimensioned to obtain the radiated power required. The extension to multi-user operation (p users) is achieved by grouping by coupling p connection circuits Ci.

Ce regroupement se fait en utilisant des techniques bas niveau. Dans ce cas les amplificateurs sont dimensionnés en fonction de la somme des puissances à rayonner.This grouping is done using low level techniques. In this case the amplifiers are dimensioned as a function of the sum of the powers to be radiated.

Il est bien entendu que la présente invention n'a été décrite et représentée qu'à titre d'exemple préférentiel et que l'on pourra remplacer ses éléments constitutifs par des éléments équivalents sans, pour autant, sortir du cadre de l'invention.It is understood that the present invention has only been described and shown as a preferred example and that its constituent elements can be replaced by equivalent elements without, however, departing from the scope of the invention.

Claims (3)

1/ Antenne multifaisceaux orientable par commutation bas niveau comprenant un réflecteur (10) focalisant l'énergie, un réseau (11) de sources élémentaires, situé dans la zone focale du réflecteur de manière à réaliser la synthèse du champ électromagnétique dans cette zone focale et une électronique comprenant un étage d'amplification (16) à m entrées et m sorties, caractérisée en ce que la zone de couverture est réalisée par m spots, correspondant chacun à un nombre défini de sources élémentaires actives, et en ce que l'électronique comporte au moins un commutateur bas niveau (Ci) permettant de relier une entrée (Ei) à l'une des f sorties.1 / Multibeam antenna orientable by low level switching comprising a reflector (10) focusing energy, a network (11) of elementary sources, located in the focal zone of the reflector so as to synthesize the electromagnetic field in this focal zone and electronics comprising an amplification stage (16) with m inputs and m outputs, characterized in that the coverage area is produced by m spots, each corresponding to a defined number of active elementary sources, and in that the electronics comprises at least one low level switch (Ci) making it possible to connect an input (Ei) to one of the f outputs. 2/ Antenne selon la revendication 1, caractérisée en ce que l'étage d'amplification (16) comprend un premier et un second coupleurs généralisés (17 et 18) disposés de part et d'autre de m amplificateurs (19) en parallèle, un filtre (20) étant associé en série à chaque amplificateur (19).2 / antenna according to claim 1, characterized in that the amplification stage (16) comprises first and second generalized couplers (17 and 18) arranged on either side of m amplifiers (19) in parallel, a filter (20) being associated in series with each amplifier (19). 3/ Antenne selon la revendication 2, caractérisée en ce que le premier et le second coupleurs généralisés (17 et 18) sont respectivement formés d'une association de coupleurs hybrides (21) de telle façon que chaque entrée du premier coupleur (17) soit répartie sur tous les amplificateurs (19) et donc sur toutes les sorties des coupleurs hybrides du premier coupleur généralisé (17), le second coupleur généralisé (18) ayant une structure inverse de celle du premier.3 / antenna according to claim 2, characterized in that the first and the second generalized couplers (17 and 18) are respectively formed of a combination of hybrid couplers (21) so that each input of the first coupler (17) is distributed over all the amplifiers (19) and therefore over all the outputs of the hybrid couplers of the first generalized coupler (17), the second generalized coupler (18) having a structure opposite to that of the first.
EP19900117354 1989-09-13 1990-09-10 Multiple beam antenna, steerable by low switching rate Expired - Lifetime EP0417679B1 (en)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
FR8911967A FR2651927B1 (en) 1989-09-13 1989-09-13 LOW LEVEL SWITCHING MULTI-BEAM ANTENNA.
FR8911967 1989-09-13

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EP0417679A1 true EP0417679A1 (en) 1991-03-20
EP0417679B1 EP0417679B1 (en) 1994-11-02

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EP19900117354 Expired - Lifetime EP0417679B1 (en) 1989-09-13 1990-09-10 Multiple beam antenna, steerable by low switching rate

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EP (1) EP0417679B1 (en)
JP (1) JPH03110905A (en)
CA (1) CA2025154A1 (en)
DE (1) DE69013831T2 (en)
FR (1) FR2651927B1 (en)

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
FR2811480B1 (en) * 2000-07-06 2006-09-08 Cit Alcatel TELECOMMUNICATION ANTENNA INTENDED TO COVER A LARGE GROUND ZONE

Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3740756A (en) * 1971-03-26 1973-06-19 Marconi Co Ltd Switching system for plural antennas connected to plural inputs
FR2570883A1 (en) * 1984-09-25 1986-03-28 Nippon Telegraph & Telephone POWER AMPLIFICATION DEVICE
GB2209629A (en) * 1987-09-09 1989-05-17 Era Patents Ltd Networks for antenna arrays
EP0333166A1 (en) * 1988-03-18 1989-09-20 Alcatel Espace Electronically reconformable transmitting antenna
EP0340429A1 (en) * 1988-03-18 1989-11-08 Alcatel Espace Electronically scanned antenna

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3740756A (en) * 1971-03-26 1973-06-19 Marconi Co Ltd Switching system for plural antennas connected to plural inputs
FR2570883A1 (en) * 1984-09-25 1986-03-28 Nippon Telegraph & Telephone POWER AMPLIFICATION DEVICE
GB2209629A (en) * 1987-09-09 1989-05-17 Era Patents Ltd Networks for antenna arrays
EP0333166A1 (en) * 1988-03-18 1989-09-20 Alcatel Espace Electronically reconformable transmitting antenna
EP0340429A1 (en) * 1988-03-18 1989-11-08 Alcatel Espace Electronically scanned antenna

Non-Patent Citations (2)

* Cited by examiner, † Cited by third party
Title
IEEE INTERNATIONAL CONFERENCE ON COMMUNICATIONS 1985 vol. 3, 23 juin 1985, CHICAGO,ILLINOIS pages 1299 - 1305; S.V.PAREKH et.al.: "Active Antennas For Satellite Communications" *
INTERNATIONAL SYMPOSIUM DIGEST ANTENNAS AND PROPAGATION vol. II, 06 juin 1988, Syracuse,NY pages 506 - 509; R.Lenormand et.al.: "A Versatile Array Fed Reflector Antenna for Satellite Communications Part B - Transmission" *

Also Published As

Publication number Publication date
EP0417679B1 (en) 1994-11-02
DE69013831D1 (en) 1994-12-08
FR2651927A1 (en) 1991-03-15
FR2651927B1 (en) 1991-12-13
JPH03110905A (en) 1991-05-10
DE69013831T2 (en) 1995-03-23
CA2025154A1 (en) 1991-03-14

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