EP3675278A1 - Multibeam antenna with adjustable pointing - Google Patents

Abstract

The present invention relates to an adjustable pointing multibeam antenna (10) comprising a single reflection device (12) and a plurality of radiating sources arranged opposite the reflection device (12) and capable of transmitting and / or receiving radioelectric signals. , the reflection device (12) defining a center, a focal plane and a focal point located in this focal plane. The antenna (10) is characterized in that at least one of the radiating sources, known as the mobile source, is movable substantially independently of the or each other radiating source in a scanning surface to adjust the pointing of the antenna (10), the scanning surface coinciding with the tangent plane or being tangent thereto at the focus.

Description

The present invention relates to a multibeam antenna with adjustable pointing.

The invention is particularly applicable for reflector antennas in the space field and in particular to satellite missions requiring independent repointing of radioelectric beams. Mention will be made in particular of the so-called "gateway" antennas on geostationary satellites.

These antennas generally target several points on the earth's surface, the positions of which can change during the satellite's mission independently of one another. In this case, it is necessary to repoint, that is to say to redirect, the antenna beam corresponding to the point whose position has changed. It may also be a new position of the satellite which in this case requires repointing of the points targeted on earth.

To do this, it is known in the prior art to use different repointing methods chosen according to the type of antenna used.

In particular, in order to repoint a passive antenna with a reflector, it is possible either to make the body of the antenna move entirely or to move only the reflector (s) within the limit of the evolution of the performance of radioelectric signals. In both cases, the reorientation therefore takes place mechanically.

It is thus clear that in order to be able to carry out a mechanical reorientation for each target point independently of the other points, it is necessary to provide a radiating source and one or more reflectors for each target point.

It is therefore understandable that this generates significant bulk on the outer surface of the satellite and considerably increases its mass.

In the case of active antennas, repointing can be obtained more easily.

Unlike passive antennas, the radiating sources of active antennas form a network and are associated with a system for distributing radioelectric signals in amplitude and / or in phase between these sources and with a system for controlling this distribution in according to predetermined laws.

Active antennas thus make it possible to carry out so-called "electronic" repointing, that is to say without mechanical action exerted on the antenna.

The active antennas therefore give great flexibility in reorienting the beams associated with different targeted points. This flexibility implies in return a high complexity of these antennas, an increase in mass, consumption and dissipation, which are critical on satellites.

The object of the present invention is to propose a multibeam antenna making it possible to repoint its beams independently while being compact, relatively light and of simple structure.

To this end, the subject of the invention is a multi-beam antenna with adjustable pointing comprising a single reflection device and a plurality of radiating sources arranged opposite the reflection device and capable of transmitting and / or receiving radioelectric signals, the device reflection defining a center, a focal plane and a focus located in this focal plane;
the antenna being characterized in that at least one of the radiating sources, said mobile source, is mobile substantially independently of the or each other radiating source in a scanning surface to adjust the pointing of the antenna, the surface scanning plane coinciding with or tangent to the focal plane.

• la source mobile est mobile dans la surface de balayage selon au moins deux degrés de liberté ;
• chacun des deux degrés de liberté comprend la rotation autour d'un axe, l'un des axes étant dit axe primaire de rotation et l'autre, axe secondaire de rotation ;
• l'axe primaire de rotation et l'axe secondaire de rotation sont perpendiculaires au plan focal, la surface de balayage coïncidant alors avec le plan focal ; ou
• l'axe primaire de rotation est perpendiculaire au plan focal et passe par le foyer du dispositif de réflexion, et l'axe secondaire de rotation est incliné par rapport à ce plan focal de sorte qu'en toute position, la source mobile est orientée vers le centre du dispositif de réflexion, la surface de balayage étant alors tangente au plan focal au foyer ; ou
• l'axe primaire de rotation est situé hors du foyer, et l'axe primaire de rotation et l'axe secondaire de rotation sont inclinés par rapport au plan focal de sorte qu'en toute position, la source mobile est orientée vers le centre du dispositif de réflexion, la surface de balayage étant alors tangente au plan focal au foyer ;
• l'axe primaire de rotation est fixe en translation ;
• l'antenne comporte plusieurs sources mobiles analogues à ladite source mobile ;
• les axes primaires de rotation des sources mobiles sont disposés symétriquement autour du foyer ;
• l'antenne comprend en outre pour le ou chaque source mobile, un support fixé sur une embase et comprenant un avant-bras rotatif autour de l'axe primaire de rotation de la source mobile correspondante et un bras rotatif autour de l'axe secondaire de rotation de la source mobile correspondante et définissant une extrémité de fixation de cette source mobile ;
• le ou chaque support comprend en outre au moins un moteur pas à pas apte à entrainer en rotation l'avant-bras ou le bras de ce support autour de l'axe correspondant ;
• le ou chaque support comprend en outre au moins un joint tournant raccordant l'avant-bras à l'embase ou le bras à l'avant-bras de ce support, le joint tournant étant apte à transmettre des signaux radioélectriques et/ou du courant électrique entre ces éléments ;
• le ou chaque joint tournant comprend au moins un canal de transmission des signaux radioélectriques, le canal de transmission étant délimité par une pluralité de plots espacés entre eux ;
• le bras du ou de chaque support est rotatif dans une surface de rotation, dite surface de rotation supérieure, et au moins une partie de l'avant-bras de ce support est rotatif dans un plan de rotation, dit plan de rotation inférieur, ce plan de rotation inférieur étant parallèle au plan focal et cette surface de rotation supérieure étant comprise entre le plan focal et ce plan de rotation inférieur ;
• lorsqu'elle comprend plusieurs sources mobiles, les plans de rotation inférieurs des avant-bras d'au moins deux supports coïncident entre eux ;
• elle comprend plusieurs sources mobiles, la surface de rotation supérieure et le plan de rotation inférieur du bras et de l'avant-bras d'au moins un support sont compris entre la surface de balayage et la surface de rotation supérieure et le plan de rotation inférieur du bras et de l'avant-bras d'au moins un autre support ;
• lorsqu'elle comprend plusieurs sources mobiles, la surface de rotation supérieure du bras d'au moins un support est comprise dans le plan de rotation inférieur de l'avant-bras d'au moins un autre support ; et
• le dispositif de réflexion est mobile.

According to other advantageous aspects of the invention, the antenna comprises one or more of the following characteristics, taken in isolation or in any technically possible combination:

• the mobile source is mobile in the scanning surface according to at least two degrees of freedom;
• each of the two degrees of freedom comprises rotation about an axis, one of the axes being said primary axis of rotation and the other, secondary axis of rotation;
• the primary axis of rotation and the secondary axis of rotation are perpendicular to the focal plane, the scanning surface then coinciding with the focal plane; or
• the primary axis of rotation is perpendicular to the focal plane and passes through the focal point of the reflection device, and the secondary axis of rotation is inclined relative to this focal plane so that in any position, the mobile source is oriented towards the center of the reflection device, the scanning surface then being tangent to the focal plane at the focal point; or
• the primary axis of rotation is located outside the focus, and the primary axis of rotation and the secondary axis of rotation are inclined relative to the focal plane so that in any position, the mobile source is oriented towards the center of the reflection device, the scanning surface then being tangent to the focal plane at the focal point;
• the primary axis of rotation is fixed in translation;
• the antenna comprises several mobile sources similar to said mobile source;
• the primary axes of rotation of the mobile sources are arranged symmetrically around the focal point;
• the antenna further comprises for the or each mobile source, a support fixed on a base and comprising a rotary forearm around the primary axis of rotation of the corresponding mobile source and a rotary arm around the secondary axis of rotation of the corresponding mobile source and defining an attachment end of this mobile source;
• the or each support further comprises at least one stepping motor capable of rotating the forearm or the arm of this support around the corresponding axis;
• the or each support further comprises at least one rotary joint connecting the forearm to the base or the arm to the forearm of this support, the rotary joint being capable of transmitting radioelectric signals and / or current electric between these elements;
• the or each rotating joint comprises at least one channel for transmitting the radio signals, the transmission channel being delimited by a plurality of studs spaced apart from each other;
• the arm of or each support is rotatable in a rotation surface, called the upper rotation surface, and at least part of the forearm of this support is rotatable in a rotation plane, called the lower rotation plane, this lower plane of rotation being parallel to the focal plane and this upper surface of rotation being between the focal plane and this lower plane of rotation;
• when it comprises several mobile sources, the lower planes of rotation of the forearms of at least two supports coincide with each other;
• it comprises several mobile sources, the upper rotation surface and the lower rotation plane of the arm and forearm of at least one support are between the scanning surface and the upper rotation surface and the rotation plane lower arm and forearm of at least one other support;
• when it comprises several mobile sources, the upper rotation surface of the arm of at least one support is included in the lower rotation plane of the forearm of at least one other support; and
• the reflection device is mobile.

• [Fig. 1] la figure 1 est une vue schématique en perspective d'une antenne multifaisceaux selon un premier mode de réalisation de l'invention, l'antenne comprenant notamment une pluralité d'assemblages mobiles ;
• [Fig. 2] la figure 2 est une vue schématique en perspective de l'un des assemblages mobiles de la figure 1 selon un premier exemple de réalisation de celui-ci ;
• [Fig. 3] la figure 3 est une vue schématique de côté de l'assemblage mobile de la figure 2 dans une position différente de celle de la figure 2 ;
• [Fig. 4] la figure 4 est une vue schématique de côté de différentes positions de l'un des assemblages mobiles de la figure 1 selon un deuxième exemple de réalisation de celui-ci ;
• [Fig. 5] la figure 5 est une vue schématique d'une variante de réalisation de l'un des assemblages mobiles de la figure 1 selon le deuxième exemple de réalisation ;
• [Fig. 6] [Fig. 7] les figures 6 et 7 sont des vues schématiques d'autres variantes de réalisation de l'un des assemblages mobiles de la figure 1 selon le deuxième exemple de réalisation ;
• [Fig. 8] [Fig. 9] les figures 8 et 9 sont des vues schématiques en perspective de différentes positions respectives des assemblages mobiles de la figure 1 ; et
• [Fig. 10] la figure 10 est une vue schématique en perspective d'une pluralité d'assemblages mobiles selon un deuxième mode de réalisation de l'invention.

These characteristics and advantages of the invention will appear on reading the description which follows, given solely by way of nonlimiting example, and made with reference to the appended drawings, in which:

• [ Fig. 1 ] the figure 1 is a schematic perspective view of a multibeam antenna according to a first embodiment of the invention, the antenna comprising in particular a plurality of mobile assemblies;
• [ Fig. 2 ] the figure 2 is a schematic perspective view of one of the mobile assemblies of the figure 1 according to a first exemplary embodiment thereof;
• [ Fig. 3 ] the figure 3 is a schematic side view of the movable assembly of the figure 2 in a different position than the figure 2 ;
• [ Fig. 4 ] the figure 4 is a schematic side view of different positions of one of the movable assemblies of the figure 1 according to a second exemplary embodiment thereof;
• [ Fig. 5 ] the figure 5 is a schematic view of an alternative embodiment of one of the mobile assemblies of the figure 1 according to the second exemplary embodiment;
• [ Fig. 6 ] [ Fig. 7 ] the figures 6 and 7 are schematic views of other alternative embodiments of one of the mobile assemblies of the figure 1 according to the second exemplary embodiment;
• [ Fig. 8 ] [ Fig. 9 ] the figures 8 and 9 are schematic perspective views of different respective positions of the movable assemblies of the figure 1 ; and
• [ Fig. 10 ] the figure 10 is a schematic perspective view of a plurality of movable assemblies according to a second embodiment of the invention.

The antenna 10 of the figure 1 is a multi-beam antenna with adjustable pointing.

According to an exemplary embodiment of the invention, this antenna 10 is on board a satellite and more particularly, is mounted on an external surface of the latter oriented for example towards the Earth.

The satellite is for example a geostationary satellite performing a telecommunication mission and requiring so-called "gateway" antennas. In a manner known per se, such a mission must allow the antenna 10 of the satellite to exchange radioelectric signals with several antennas arranged on the ground.

The positions as well as the number of these ground antennas are likely to change over time, throughout the mission of the satellite.

The antenna 10 makes it possible to repoint its beams independently of one another to follow these evolutions on the ground, as will be explained below.

With reference to the figure 1 , the antenna 10 comprises a single reflection device 12, a plurality of mobile assemblies 14A to 14D, a base 16, a processing module 18 and a control module 20.

The reflection device 12 has a reflector of any known shape or several reflectors, preferably two, also of known shapes.

Thus, according to an exemplary embodiment, the reflection device 12 has a single reflector of the centered or simple offset type.

According to another exemplary embodiment, the reflection device 12 has two reflectors and is for example of the SFOCA (from the English “Side Fed Offset Cassegrain Antenna”), Gregorian, Cassegrain, splash plate, etc. type.

Also in a manner known per se, the reflection device 12 defines by its geometry a center on its surface and a focal point located outside this surface. This reflection device 12 further defines a focal plane corresponding to the plane containing the focal point and perpendicular to the line connecting the focal point and the center.

The mobile assemblies 14A to 14D are for example four in number and make it possible to send and / or receive beams of radioelectric signals originating from different points aimed at the ground or intended for these points.

In the event of a change in the positions of these points and / or in their number, modifications of the positions of the mobile assemblies 14A to 14D make it possible to reorient the antenna 10, as will be explained in detail below.

The base 16 makes it possible to fix the reflection device 12 and the mobile assemblies 14A to 14D to the structure of the satellite and is thus presented in any form suitable for doing so.

So, in the example illustrated on the figure 1 , the base 16 is in the form of a plurality of fixing lugs, each lug being adapted to fix one of the mobile assemblies 14A to 14D or the reflection device 12 to the structure of the satellite.

These fixing lugs are therefore arranged as a function of the corresponding structure of the satellite. On the figure 1 , the structure comprises two perpendicular surfaces so that at least some of the fixing lugs are fixed on one of these surfaces and some others on the other surface.

Furthermore, the fixing lugs of the mobile assemblies 14A to 14D include transmission means necessary in order to transmit radio signals and electric current between these assemblies 14A to 14D and the processing module 18 and the control module 20.

The processing module 18 makes it possible to acquire radioelectric signals received by the mobile assemblies 14A to 14D and / or to generate radioelectric signals intended to be emitted by these assemblies.

To this end, the processing module 18 includes electronic components such as amplifiers, a distributor, etc. These components are known per se and will not be described in detail.

The control module 20 makes it possible to modify the positions of the mobile assemblies in order to redirect the antenna beams 10 as a function of the points targeted. To do this, the control module 20 is able to control the position of each of the mobile assemblies 14A to 14D and to modify it independently of the other assemblies by transmitting, for example, a command adapted to this assembly.

The control module 20 is for example at least partially in the form of a programmable logic circuit or in the form of software. In the latter case, it is implemented by a suitable processor.

According to the first embodiment of the antenna 10, the movable assemblies 14A to 14D are substantially identical.

Thus, subsequently, only the movable assembly 14A will be explained in detail with reference to figures 2 to 4 .

In particular, figures 2 and 3 illustrate such a mobile assembly 14A according to a first exemplary embodiment thereof.

With reference to the figure 2 , the mobile assembly 14A comprises a radiating source 22 and a support 24 fixing this source 22 in a mobile manner to the base 16.

The radiating source 22 is for example in the form of a horn for transmitting and / or receiving radioelectric signals elongated along a source axis C.

This source axis C is oriented towards the reflection device 12 and in the first embodiment of the assembly 14A, is perpendicular to the focal plane PF in any position of this assembly 14A.

Furthermore, in the first embodiment of the assembly 14A, the support 24 allows the radiating source 22 to move in a scanning surface coinciding with the focal plane of the reflection device 12.

This focal plane is visible on the figure 3 and denoted by the reference "PF" on this figure 3 .

In particular, the support 24 allows the radiating source 22 to move in the focal plane PF according to two degrees of freedom comprising in the example of the figure 2 two rotations around the parallel axes which are perpendicular to the focal plane PF.

One of these axes is called the primary axis of rotation X ₁ and the other is said to be the secondary axis of rotation X ₂ . In addition, the primary axis of rotation X ₁ is fixed in translation relative to the base 16.

To ensure the displacement of the radiating source 22 in the focal plane PF according to two degrees of freedom, the support 24 comprises a forearm 26 rotatable relative to the primary axis of rotation X ₁ in a plane of rotation, called the plane of lower rotation PI, and an arm 28 rotatable relative to the secondary axis of rotation X ₂ in a rotation surface, called the upper rotation surface SS.

As can be seen on the figure 3 , the upper rotation surface SS is arranged between the focal plane PF and the lower rotation plane PI.

Furthermore, in the first embodiment of the assembly 14A, this upper rotation surface SS has a plane.

The forearm 26 is of elongated shape and thus has two ends. One of these ends is rotatably fixed around the primary axis of rotation X ₁ on a stator 30 in rigid connection with the base 16. The other end is rotatably fixed around the secondary axis of rotation X ₂ on arm 28.

Similarly, the arm 28 is of elongated shape and thus has two ends. One of these ends is fixed in a rotary manner around the secondary axis of rotation X ₂ to the forearm 26 and the other receives in a fixed way the radiating source 22.

The longitudinal expanses of the arm 28 and the forearm 26 are for example substantially identical as can be seen on the figure 3 . According to another exemplary embodiment, these ranges are different and are adapted as a function of the arrangement of the other mobile assemblies to ensure greater scanning of the scanning surface.

To implement the rotation around the axes X ₁ and X ₂ , the support 24 advantageously comprises two motors, one being integrated in the junction between the forearm 26 and the stator 30 and the other in the junction between the arm 28 and the forearm 26.

These motors have, for example, stepper type motors which can be controlled by the control module 20. In this case, the commands transmitted by the control module 20 to the assembly 14A correspond to electric currents of suitable voltage.

The control module 20 is thus able to supply these motors in an appropriate manner via means for transmitting electric current, integrated in the stator 30 and the forearm 26.

To ensure the junction of these means between the stator 30 and the forearm 26, these transmission means have flexible cables in this junction or then comprise an electrical rotating joint making it possible to avoid cable transmission between these components.

To ensure the transmission of the radio signals between the radiating source 22 and the processing module 18, the support 24 comprises means for transmitting the radio signals. These means comprise for example waveguides integrated in the arm 28 and the forearm 26 as well as two radiofrequency rotating joints. One of these radiofrequency rotating joints is integrated in the junction between the arm 28 and the forearm 26 and the other in the junction between the forearm 26 and the stator 30.

Advantageously, each of these radiofrequency rotating joints has a “groove gap” type rotating joint, that is to say a rotating joint comprising at least one channel for transmitting radioelectric signals which is delimited by studs spaced apart according to a predetermined distance.

More advantageously, each of the rotary joints used for the transmission of the radio signals or at least the rotary joint integrated in the junction between the arm 28 and the forearm 26 is configured to allow rotation around the axis corresponding to 360 °. .

A movable assembly 14A according to a second embodiment is illustrated in detail on the figure 4 in its different positions A) to D).

The movable assembly 14A according to this exemplary embodiment is substantially similar to that described above.

Unlike the assembly 14A described above, in the mobile assembly according to this second embodiment, the secondary axis of rotation X ₂ is inclined relative to the primary axis of rotation X ₁ , the primary axis of rotation X ₁ located at the focal point of the reflection device and always remaining perpendicular to the focal plane PF.

The angle of inclination of the secondary axis of rotation X ₂ is chosen so that in any position of the assembly 14A, the radiating source 22 is oriented towards the center of the reflection device 12. In other words, this angle is chosen so that the source axis C is oriented towards the center of the reflection device 12.

Thus, according to this exemplary embodiment, the radiating source 22 is movable in a scanning surface tangent to the focal plane at the focus. This scanning surface therefore has a convex surface extending on one side of the focal plane close to the latter, between the reflection device 12 and this focal plane.

In the example of realization of the figure 4 , the angle of inclination of the secondary axis of rotation X ₂ is substantially equal to 4.5 °. This value depends on the geometry of the antenna.

By the way, in the example of this figure 4 , to form an inclination of the secondary axis of rotation X ₂ , the adjacent ends of the forearm 26 and of the arm 28 are bent at the same angle.

Thus, in this case, at least part of the forearm 26 comprising the rotary end around the primary axis of rotation remains rotary in the lower plane of rotation PI as described previously, then the upper surface of rotation is different from a plane and corresponds to a conical surface.

The upper rotation surface SS is between the scanning surface and the lower rotation plane PI. This then allows the arm 28 to rotate independently of the forearm 26.

On the figure 4 , in position A), the arm 28 and the forearm 26 extend in the same direction and the source axis C coincide with the primary axis of rotation X ₁ .

In positions B) and C), the arm 28 and the forearm 26 extend in perpendicular directions.

Thus, in position B), the source axis C is inclined relative to the primary axis of rotation X ₁ in the plane of the figure and relative to the secondary axis of rotation X ₂ in a plane perpendicular to the plan of the figure.

In position C), the source axis C is inclined relative to the primary axis of rotation X ₁ in the plane of the figure and the primary axis of rotation X ₁ is inclined relative to the secondary axis of rotation X ₂ in the plane perpendicular to the plane of the figure.

In position D), the arm 28 and the forearm 26 both extend in the plane of the figure and the source axis C and the secondary axis of rotation X ₂ are therefore inclined relative to the primary axis of rotation X ₁ in this plane, the angle of inclination of the source axis C being twice the angle of inclination of the secondary axis of rotation X ₂ .

A variant of the second embodiment of the movable assembly 14A is illustrated on the figure 5 . In this variant, the primary axis of rotation X ₁ of the forearm 26 is close to the focus F and therefore does not pass through this focus.

Thus, in this alternative embodiment, the primary axis of rotation X ₁ is inclined to aim at the center of the reflector 12. The arrangement of the arm 28 relative to the forearm 26 remains as has been described in relation to the figure 4 .

This variant is particularly advantageous when the primary axis of rotation X ₁ of each of the mobile assemblies 14A to 14D is arranged close to the focal point, as will be explained below.

On the figure 5 , the two movable assemblies 14A and 14B are visible. According to this figure, it is clear that the scanning surface described by the sources of these assemblies 14A and 14B has part of a sphere. By the way, in the example of this figure 5 , the arm 28 of each of the assemblies 14A, 14B has a length less than that of the corresponding forearm 26 and only the end of the forearm 26 adjacent to the arm 28 is bent. In this case, at least in one position, the arm 28 extends along the bent part of the forearm 26. The arm 28 is therefore rotatable in a plane intersecting the plane of rotation of the forearm 26.

Of course, this variant arrangement of the arm and the forearm remains applicable to the embodiment of the figure 4 , that is to say when the primary axis of rotation passes through the hearth.

More generally and advantageously with respect to the performance of the antenna, each of the assemblies 14A to 14D is constructed so that whatever its position and its axes of rotation, the axis of the source targets the center of the device. reflection.

Thus, whatever the position of the arms, the axis of each source targets the center of the reflection device 12.

In general, it is possible in this way to have N mobile assemblies similar to the mobile assemblies 14A and 14B of the figure 5 , so that their radiating sources target the center of the reflection device and advantageously describes the same scanning surface having part of a sphere.

Thus, according to other variants of the second embodiment of the mobile assembly 14A illustrated on the figures 6 and 7 , the primary axis of rotation X ₁ of this assembly 14A as well as similar assemblies 14B to 14D is arranged far from the focus F.

In this case, each of these assemblies 14A to 14D and in particular their axes X ₁ and X ₂ are configured so that the corresponding source axes aim at the center or a point close to the center of the reflection device. The sources are then mobile on a part of a sphere as described above.

This makes it possible to offset the focal point F of the reflection device 12 so as to have a scanning surface centered on the focal point as illustrated in the figures 6 and 7 .

Indeed, these figures 6 and 7 show a possible arrangement of the movable assemblies 14A to 14D on the base 16 with an eccentric focus. The circle T represents for example on the figures 6 and 7 the image of the earth seen from the focus of the reflection device. It is thus understood that the eccentricity of the focus F advantageously makes it possible to be able to sweep the whole of the earth.

Another possible arrangement of the movable assemblies 14A to 14D on the base 16 is illustrated on the figures 8 and 9 .

In particular, these figures illustrate an arrangement of these assemblies 14A to 14D according to the first exemplary embodiment of each of them but can also be applied to assemblies according to the second exemplary embodiment.

Thus, according to these figures, the movable assemblies 14A to 14D are arranged symmetrically around the focal point F of the reflection device 12. Furthermore, advantageously, the primary axes of rotation X ₁ of these assemblies are arranged as close as possible to this focal point and target the center of the thinking device.

In addition, these assemblies 14A to 14D are arranged so that the lower rotation planes PI of their forearm 26 coincide with one another. In other words, in this type of arrangement, the arm 28 of each assembly 14A to 14D is located above the forearm 26 of each assembly 14A to 14D. This then makes it possible to facilitate the respective displacements of the corresponding radiating sources 22 in order to scan a greater part of the scanning surface.

The figure 8 illustrates the initial positions of these mobile assemblies 14A to 14D during, for example, the launch of the satellite.

The figure 9 illustrates the operational positions of these assemblies. These positions can be changed during the satellite mission. It is therefore understood that the present invention has a number of advantages.

In particular, the invention provides an antenna comprising mobile radiating sources in the focal plane or close to it. The invention makes it possible to modify the positions of these radiating sources independently of one another, thereby modifying the pointing of the antenna mechanically.

This avoids the use of complex and heavy electronic components of active antennas implementing electronic pointing.

This also makes it possible to use a single reflection device, which makes it possible to considerably reduce the weight and size of the antenna in the case of passive antennas implementing mechanical pointing.

The antenna according to the invention therefore makes it possible to implement flexible pointing without adding heavy and complex components.

A multibeam antenna according to a second embodiment will now be described with reference to the figure 10 .

This antenna according to the second embodiment is substantially similar to the antenna 10 described above with the exception of the mobile assemblies.

In particular, the antenna according to the second embodiment comprises four mobile assemblies 114A to 114D, at least one of which differs from the other assemblies.

So in the example of the figure 10 , the assemblies 114B to 114D are identical to the assemblies 14B to 14D described above and are therefore identical to each other.

On the other hand, the assembly 114A differs from each of these assemblies by an end 129 of the arm 128 carrying the radiating source 122.

According to this second embodiment, this end has an elongated shape of extent equal for example to the sum of the transverse expanses of the arm and the forearm, for example of the assembly 114B.

Thus, when the movable assemblies 114A to 114D are arranged for example symmetrically around the hearth, the arm 128 and the forearm 126 of the assembly 114A are arranged below the arm and the forearm of each other mobile assembly 114B to 114D.

In other words, in this case, the upper rotation surfaces SS and the lower rotation planes PI of the supports of the assemblies 114B to 114D are between the scanning surface and the upper rotation surface SS and the lower rotation plane PI of the support of the mobile assembly 114A.

In other words, in this case, the arm and forearm of the support of the mobile assembly 114A are arranged below the arms and forearms of the other mobile assemblies 114B to 114D.

It is also possible to arrange these assemblies 114A to 114D so that the upper rotation surface of the arm 128 of at least one support is included in the lower rotation plane PI of the forearm 126 of at least one other medium.

In this case, the arm 128 of at least one support is disposed at the level of the forearm 126 of at least one other support.

This allows more space to move these different assemblies.

Of course, other modes and examples of embodiments are also possible.

It is for example possible to make the reflection device 12 mobile at least according to a degree of freedom. This will make the pointing of the antenna according to the first or the second embodiment even more flexible.

It is also possible to mount at least one radiating source in a stationary manner, for example at the focal point of the antenna, and to arrange the other radiating sources mobile, for example around this stationary source.

It is also possible not to limit the number of degrees of freedom, it is therefore possible to have mobile assemblies with 1 to N axis (s) of rotation.

Claims (16)

Multibeam antenna (10) with adjustable pointing comprising a single reflection device (12) and a plurality of radiating sources (22; 122) arranged opposite the reflection device (12) and capable of transmitting and / or receiving radioelectric signals , the reflection device (12) defining a center, a focal plane (PF) and a focus located in this focal plane (PF);
the antenna (10) being characterized in that at least one of the radiating sources (22; 122), called the mobile source, is movable substantially independently of the or each other radiating source (22) in a scanning surface to adjust the pointing of the antenna (10), the scanning surface coinciding with the tangent plane (PF) or being tangent thereto at the focus. An antenna (10) according to claim 1, wherein the movable source (22; 122) is movable in the scanning surface according to at least two degrees of freedom. Antenna (10) according to claim 2, in which each of the two degrees of freedom comprises rotation about an axis, one of the axes being said primary axis of rotation (X ₁ ) and the other, secondary axis of rotation (X ₂ ). Antenna (10) according to claim 3, in which: - the primary axis of rotation (X ₁ ) and the secondary axis of rotation (X ₂ ) are perpendicular to the focal plane (PF), the scanning surface then coinciding with the focal plane; or - the primary axis of rotation (X ₁ ) is perpendicular to the focal plane (PF) and passes through the focal point of the reflection device (12), and the secondary axis of rotation (X ₂ ) is inclined relative to this plane focal (PF) so that in any position, the mobile source (22; 122) is oriented towards the center of the reflection device (12), the scanning surface then being tangent to the focal plane (PF) at the focus; or - the primary axis of rotation (X ₁ ) is located outside the focal point, and the primary axis of rotation (X ₁ ) and the secondary axis of rotation (X ₂ ) are inclined relative to the focal plane (PF) of so that in any position, the mobile source (22; 122) is oriented towards the center of the reflection device (12), the scanning surface then being tangent to the focal plane (PF) at the focal point. Antenna (10) according to claim 3 or 4, in which the primary axis of rotation (X ₁ ) is fixed in translation. Antenna (10) according to any one of claims 3 to 5, comprising several mobile sources (22; 122) analogous to said mobile source (22; 122). Antenna (10) according to claim 6, in which the primary axes of rotation (X ₁ ) of the mobile sources are arranged symmetrically around the focal point. Antenna (10) according to any of claims 3 to 7, further comprising for the or each movable source (22; 122), a support (24) fixed on a base (16) and comprising a forearm (26 ; 126) rotatable around the primary axis of rotation (X ₁ ) of the corresponding mobile source (22; 122) and an arm (28; 128) rotatable around the secondary axis of rotation (X ₂ ) of the source mobile (22; 122) corresponding and defining a fixing end of this mobile source (22; 122). Antenna (10) according to claim 8, in which the or each support (24) further comprises at least one stepping motor capable of driving the forearm (26; 126) or the arm (28; 128) in rotation. ) of this support (24) around the corresponding axis (X ₁ , X ₂ ). Antenna (10) according to claim 8 or 9, in which the or each support (24) further comprises at least one rotary joint connecting the forearm (26; 126) to the base (16) or the arm ( 28; 128) to the forearm (26; 126) of this support (24), the rotating joint being able to transmit radioelectric signals and / or electric current between these elements. An antenna (10) according to claim 10, in which the or each rotary joint comprises at least one channel for transmitting radioelectric signals, the transmission channel being delimited by a plurality of studs spaced apart from each other. Antenna (10) according to any one of claims 8 to 11, in which the arm (28; 128) of the or each support (24) is rotatable in a rotation surface, called the upper rotation surface (SS), and at least part of the forearm (26; 126) of this support (24) is rotatable in a plane of rotation, called lower rotation plane (PI), this lower rotation plane (PI) being parallel to the focal plane (PF) and this upper rotation surface (SS) being between the focal plane (PF) and this lower rotation plane (PI) ). Antenna (10) according to claim 12, wherein when it comprises several mobile sources (22; 122), the lower planes of rotation (PI) of the forearms of at least two supports (24) coincide with each other. Antenna (10) according to claim 12 or 13, wherein when it comprises several mobile sources (122), the upper rotation surface (SS) and the lower rotation plane (PI) of the arm (128) and of the forearm (126) of at least one support (24) is included between the scanning surface and the upper rotation surface (SS) and the lower rotation plane (PI) of the arm (128) and the front -arm (126) of at least one other support (24). Antenna (10) according to claim 12 or 13, wherein when it comprises several mobile sources (122), the upper rotation surface (SS) of the arm (128) of at least one support (24) is included in the lower plane of rotation (PI) of the forearm (126) of at least one other support (24). An antenna (10) according to any one of the preceding claims, in which the reflection device (12) is movable.

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