EP1226626A1 - Printed antenna with an enlarged bandwidth and a low level of cross polarisation, and corresponding antenna network - Google Patents

Abstract

The invention relates to a printed antenna, comprising the following: a substrate plate; a metal deposit which is situated on the surface of said substrate plate and defines a resonating patch (2); and a supply means (3) for supplying said resonating patch. According to the invention, the antenna also comprises at least one stub (141 to 144) which extends from a point of minimum voltage (9A, 9B) of said resonating patch. The invention also relates to an antenna network comprising at least two printed antennae of the type described.

Description

 Printed antenna with broad bandwidth and low level of cross polarization, and corresponding antenna array.

The field of the invention is that of antennas made in impnmated technology. It is recalled that this technology makes it possible to obtain light, compact and inexpensive printed antennas if mass produced. They are now found in all types of applications (satellite television reception, telecommunications, portable radars, ...). They can be used alone or in networks. More specifically, the inv ention relates to an improvement to conventional impinnated antennas.

Traditionally, a waterproof antenna includes in particular: a substrate (or dielectric) plate; a metal deposit, located on one face of the substrate plate and defining a resonant patch (or "patch"). Generally, the resonant patch is of square or circular shape, and its dimensions are of the order of half a wavelength. ; a feed mov, making it possible to feed the resonant patch, by contact (line or coaxial probe) or by coupling (line or slot cut out in a ground plane).

If such a conventional printed antenna offers several advantages (lightness, compactness and low cost), it nevertheless also has some drawbacks.

First of all, the bandwidth of such a conventional aerial antenna is not wide enough (in general a few% at ROS (Stationary Wave Ratio) less than 2. It should be remembered that this percentage is obtained by dn ision of the bandwidth by the central frequency of this band. A known solution for increasing the bandwidth consists in increasing the thickness of the substrate plate. Unfortunately, this solution generates parasitic radiation which makes it unusable in practice. Indeed, the ideal operation corresponds to the excitation of a particular mode (generally a fundamental mode), but when the thickness of the substrate becomes important compared to the wavelength (approx iron 0.1. λ, with ec λ the length operating wave), then other modes (generally higher modes) are inadvertently excited, called parasitic modes. Interference waves are also excited which reduce the efficiency of the antenna.

Furthermore, such a conventional printed antenna generates a level of cross polarization that is too high. This level reflects the capacity of the antenna, when it operates according to a first polarization (main component, for example horizontal), to reject a second polarization (crossed component, for example vertical). Ideally, the level of cross polarization is zero.

The current antenna networks, owing to the fact that they are obtained by juxtaposition of a plurality of conventional printed antennas (known as sources), have the same disadvantages as those mentioned above (bandwidth too narrow and neither water of polarization crossed too much Student).

Such an array of antennas can be used either to maximize the radiation pattern in a predetermined principal direction (for example the normal Oz to the plane (Ox, O \) containing the array of antennas), or to generate a radiation pattern deviated from this predetermined pnncipale direction. The second case corresponds in particular, but not exclusively, to obtaining a radiation diagram of the "cosecanted", making it possible to vary the transmission (and / or reception) power of the network as a function of at least one angular parameter. This angular parameter is for example the angle θ between the axis Oz and the direction deviated from the radiation diagram, and / or the angle φ between the axis Ox and the projection in the plane (Ox, O) of the direction devoid of the delight diagram.

Currently, the implementation of an antenna array in the aforementioned second case (localized radiation diagram) requires the use of additional means making it possible to play on the phase and the amplitude of each of the elementary antennas. Now these m o \ ens additional are complex and expensive.

The invention particularly aims to overcome these various drawbacks of the state of the art.

More specifically, one of the objectives of the present invention is to provide a printed antenna having a broad bandwidth and a low level of cross-polansation. The invention also aims to provide such an impnmated antenna which has a manufacturing cost substantially equal to that of a conventional printed antenna.

Another objective of the invention is to provide such a printed antenna having dimensions close to those of a conventional printed antenna.

A complementary objective of the invention is to provide an array of antennas from a plurality of such impinnated antennas.

Another objective of the invention is to provide such an array of impinnated antennas making it possible to obtain a localized radiation pattern without additional means (making it possible to play on the phase and the amplitude) complex and expensive.

These various objectives, as well as others which will appear subsequently, are achieved according to the intention with the aid of a waterproof antenna, of the type comprising: a substrate plate, a metal deposit, located on one face of said substrate plate and defining a resonant patch, a supply means for supplying said resonant patch, and further comprising: at least one reactance arm extending from a cold point of said resonant patch. The impnmée antenna of the invention therefore differs from that of the prior art in that, from one or more cold points of the resonant patch, extend one or more reactance arms. Each "reactance arm" (or stub, or

"mustache") can be either in the plane containing the resonant patch, or in an inclined plane relative to the latter. The second case (arms in an inclined plane) includes in particular, but not exclusively, the reactance arms extending upwards, of the monopoly type, and the reactance arms extending downwards, of t pe coaxial lines .

It is clear that all or only part of the cold spots can be affected. It is also clear that each cold point concerned can constitute a starting point for one or more reactance arms. It is recalled that a cold point, for a given mode, is a point on the resonant patch where the current is maximum and where the voltage is zero. The reactance arms make it possible to suppress, by short-circuiting them, unwanted modes (or parasitic modes), and by the same to improve markedly: the level of cross polarization, by increasing the useful ra onement, according to the main polarization , compared to the parasitic ravaison, according to the cross polansation. bandwidth, by reducing reactance at certain frequencies. In other words, we minimize the v anation of reactive energy

In a first advantageous embodiment of the antenna impregnated according to the invention, said feed moven does not substantially feed said wedge "resonant pad", said resonant pad having this milk a single fundamental mode. Said cold point from which extends said at least one reactance arm is a cold point for said single fundamental mode.

Thus, in this first embodiment of the antenna according to the invention, the unwanted modes which are eliminated are the superior modes. In a second advantageous embodiment of the impnmated antenna according to the invention, said supply means supplies substantially "in the corner" said resonant patch, said resonant patch therefore having at least two fundamental modes. Said cold point from which extends said at least one reactance arm is a cold point for the superposition of said at least two fundamental modes.

Thus, in this second embodiment of the antenna according to the invention, the unwanted modes which are eliminated are the superior modes.

In a third advantageous embodiment of the impinnated antenna according to the invention, said supply means supplies substantially "in the corner" said resonant patch, said resonant patch therefore having at least two fundamental modes. Said cold point from which extends said at least one reactance arm is a cold point for one of said fundamental modes.

Thus, in this third embodiment of the antenna according to the invention, the unwanted modes which are suppressed are on the one hand the other fundamental mode (a cold spot of one of the two fundamental modes being a on the other) and on the other hand the superior modes. Antagonously, said at least one reactance arm is formed in said metallic deposit. In this way, the reactance arms are very simple to produce and do not generate any additional cost compared to the resonant pellet alone.

Advantageously, said at least one reactance arm is a section of line formed in said metallic deposit and extending towards the extender of said resonant pad.

According to a vanante av antageuse, said at least one reactance arm is a section of slot formed in said metallic deposit and extending towards the interior of said resonant pad. With this v anante, we still gain in compactness since the reactance arms do not extend towards the outside of the pellet. In this case, the size of the impnmated antenna according to the invention is the same as that of a conventional impnmated antenna.

Preferably, said power supply mo belongs to the group comprising: direct attack lines; - direct attack probes; contactless coupling lines; contactless coupling lines cooperating with slots. This list is by no means exhaustive.

Preferably, in order to obtain a predetermined operation of said impnmated antenna, the design of said antenna is played on at least one parameter belonging to the group comprising: the length of each reactance arm; the width of each reactor arm; the geometric shape of each reactor arm; - the position of each reactance arm; the number of cold points from which at least one reactance arm extends; the number of reactance arms extending from each cold point. Thus, there are many possible strategies for controlling the overall reactance introduced by all of the reactance arms. Advantageously, said at least one reactance arm has a length substantially equal to λ / 4, with λ the operating wavelength. In this way, the reactance arm constitutes an open circuit stub close to a quarter wave.

Antagonally, said at least one reactance arm has at least one elbow. The elbows allow the reactance arms to stay as close as possible to the resonant pad. The antenna is therefore more compact.

In a particular embodiment of the invention, said resonant patch has at least two cold spots, said antenna comprises at least a first pair of reactance arms. The reactance arms of said at least one first pair of reactance arms have substantially one met with respect to a first axis, passing through said at least two cold spots.

This first circuit between pairs of reactance arms makes it possible to reduce the quantity of parasites, and therefore to improve the performance of the antenna.

Advantageously, said resonant patch has at least two cold spots. Said antenna includes at least a second pair of reactance arms. The reactance arms of said at least a second pair of reactance arms have substantially a shape relative to a second axis, forming an axis of symmetry for said resonant pad and passing through a point of excitation of said resonant pad by said mo in power. The combination of two symmetries between pairs of reactance arms, along two distinct axes, makes it possible to further improve the performance of the antenna.

The invention also relates to an antenna array comprising at least two impinnated antennas as mentioned above.

In a first advantageous embodiment of the array of impinnated antennas according to the invention, each of said antennas comprises a same set of at least one reactance arm, so as to maximize radiation of said array of antennas in a predetermined main direction .

Advantageously, said array comprises at least a first pair of antennas and at least a second pair of antennas. The antenna reactance arms of said at least one first pair of antennas have between them substantially symmetry with respect to a third axis, forming a vertical axis for said array of antennas and passing through a feed point of said antenna array. The antenna reactance arms of said at least one second pair of antennas have substantially one axis between them relative to a fourth axis, forming a mete axis for said antenna array, perpendicular to said third axis and passing through said point. supplying said antenna array.

Thus, if we assume that the network is in a plane (Ox, Ov), the predetermined main direction is the axis Oz, and the third and fourth axes are for example respectively the axes Ox and O (or inversely the axes O \ and Ox).

This double svmétne between reactance arms of antenna pairs makes it possible to reduce the quantity of parasites, and therefore to improve the performance of the antenna array. It is advisable to distinguish these sv metπes, within the antenna array, between reactance arms of pairs of antennas, and the aforementioned svmétnes, within the antenna used alone, between pairs of reactance arms. Indeed, the axes of sv metne concerned are not the same in both cases (some are specific to the antenna, while others are specific to the antenna array).

In a second embodiment with an advantage of the array of printed antennas according to the invention, at least two of said antennas each comprise a distinct set of at least one reactance arm, so as to induce counting of the alignment of said array of antennas with respect to a predetermined main direction. Thus, by appropriately choosing the reactance arms, it is possible to identify the radiation pattern of the antenna array. By "predetermined main direction" is meant here the direction that the direction diagram would take if there were no depointing. If we assume again that the network is in a plane (Ox, Oy), the predetermined main direction, with respect to which the depointing takes place, is the axis Oz. Unlike the conventional solution discussed above, the invention allows such defocusing to be carried out without any additional means (neither phase shifter nor amplifier)

Advantageously, said array comprises at least a first pair of antennas. The reactance arms of the antennas of said at least one first pair of antennas do not have between them a svmetne with respect to a third axis, forming an axis of sv metne for said antenna array and passing through a point supplying said antenna array. In this way, said deflection takes place around said third axis. Thus, the depointing is carried out for example around the axis Ox (or Ov).

In an avagage way, said array comprises at least a second pair of antennas. The reactance arms of the antennas of said at least one second pair of antennas do not have between them a sv metne with respect to a fourth axis, forming an axis of s metne for said array of antennas, perpendicular to said third axis and passing through said feed point of said antenna array In this way, said depointing is also carried out around said fourth axis. Thus, the depointing is carried out for example around the axis O (or Ox).

Other characteristics and advantages of the invention will appear on reading the following description of a preferred embodiment of the invention, given by way of non-limiting example, and of the accompanying drawings, in which: Figure 1 (prior art) shows a perspective view of a first known impnmated antenna, with a "non-corner"feed; FIG. 2 (prior art) illustrates the distribution of the electric field around the patch of the first known antenna of FIG. 1. FIG. 3 (prior art) presents a top view of a second known impnmated antenna, with a "corner" power supply, - FIGS. 4A, 4B and 4C (prior art) each illustrate the distribution of the electric field around of the patch of the second known antenna of FIG. 3, respectively for a first fundamental mode (fιg.4A), a second fundamental mode (fιg.4B) and the superposition of the first and second fundamental modes (fιg.4C); - Each of Figures 5 to 12 shows a top view of a separate embodiment of a printed antenna according to the present invention; and FIG. 13 presents a perspective view of a particular embodiment of an array of impnmated antennas according to the present invention. For the sake of simplification, identical elements in different figures retain the same reference numeral. In order to explain the concept of cold spot of an impnmated antenna, we first present, in relation to FIGS. 1 to 4, two examples of impnmated antennas according to the prior art.

The first known impinnated antenna (cf. FIGS. 1 and 2) conventionally comprises: a substrate plate 1; a metal deposit, located on the upper face of the substrate plate 1 and defining a resonant patch 2 of rectangular shape (length a and width b); a supply line (microstrip line) 3, supplying the resonant patch 2 by direct contact. The width b of the patch 2 is much greater than the width of the supply line 3; a ground plane 4, located on the lower face of the substrate plate 1.

For this first known antenna, the excitation point 6 of the patch is not in the corner. Consequently, the pastille presents a unique fundamental mode. The dimensions of the patch are of the order of half a wavelength. This results in a non-uniform distribution of the electric field under and around the resonant pad 2.

FIG. 2 illustrates an example of such a non-uniform distribution, for a mode

TM0,1. The two cold spots 5A, 5B of this mode appear clearly in the figure. The second known impnmated antenna (cf. fιg.3 and 4) differs from the first only in that the excitation point 7 of the patch 3 is here in the corner. Consequently, the patch has two fundamental modes: mode 0.1 and mode 1.0. In fact, each of the two sides of the patch to which the excitation point belongs is associated with a distinct fundamental mode. The global non-uniform distribution (cf. fιg.4C) is obtained by summing the non-uniform distributions of the two fundamental modes (cf. fιg.4A and 4B). For each fundamental mode, the patch has two distinct cold points: 7A, 7B (cf. fιg.4A) and 8A. 8B (cf. fιg.4B). In addition, for the superposition of the two fundamental modes, the patch also has two distinct cold points: 9A, 9B (cf. fιg.4C). We now present, in relation to FIGS. 5 to 12, several particular embodiments of a waterproof antenna according to the present invention. We recall that the general principle of the invention consists in adding, at least one cold point of the patch 2, at least one reactance arm. This reactance arm (s) makes it possible to reduce the level of cross-polansation and increase the bandwidth of the antenna.

In the first embodiment, illustrated in FIG. 5. the resonant patch is not supplied at the corner (the antenna is therefore of the same TV as the first known antenna, presented above in relation to FIGS. 1 and 2). On the contrary, in the second to eighth embodiments, illustrated in FIGS. 6 to 12 respectively, the resonant patch is supplied at a corner (the antenna is therefore of the same type as the second known antenna, presented above in relation with ec Figures 3 and 4). In the first embodiment (cf. fιg.5), two 10 _t reactor arms, 10- and

10 ₃ , 10 ₄ extend from each cold point 5A, 5B for the single fundamental mode. Each reactance arm is a section of line formed in the metallic deposit and which extends towards the outside of the pellet. Each reactance arm has a length substantially equal to λ / 4, with λ the operating wavelength. For the sake of compactness, each arm has an elbow 11.

The reactance arms have between them two types of s metne: a first s metne with respect to a first axis 12 passing through the two cold points 5A, 5B (and forming an axis of line for the pellet). Thus, we can distinguish two first pairs of reactance arms (10 _{l 5} 10 ₂ ), (10 ₃ , 10 ₄ ) for each of which this first svmétne exists; a second svmétne with respect to a second axis 13 forming an axis of symmetry for the patch and passing through the excitation point 6 of the patch. Thus, we can distinguish two second pairs of reactance arms (10 _j , 10 ₃ ), (10 ₂ , 10 ₄ ) for each of which this second svmétne exists.

In the second embodiment (cf. fιg.6), two reactance arms 14 ,, 14, and

14 ₃ , 14 ₄ extend from each cold point 9A, 9B for the superposition of the two fundamental modes. The first and second axes of svmétne are here referenced 15 and

16 respectively. The other characteristics are unchanged compared to the first embodiment described above. In the third embodiment (cf. fιg.7), two reactance arms 17 „17 ₂ and 17 ₃ , 17 ₄ extend from each cold point 7A, 7B for the first fundamental mode (mode 0, 1 )

In the fourth embodiment (cf. fιg.8), two reactance arms 18 _l5 18 ₂ and 18 ₃ , 18 ₄ extend from each cold point 8A, 8B for the second fundamental mode (mode 1.0 ).

The fifth embodiment (cf. fιg.9) is an extension of the second embodiment, in which the reactance arms have a greater width.

The sixth embodiment (cf. fιg.10) is a variant of the second embodiment, in which the reactance arms do not have a bend.

The seventh embodiment (cf. fig. L l) is a variant of the second embodiment, in which the reactance arms do not have an elbow and are split.

The eighth embodiment (cf. fig. 12) is a variant of the second embodiment, in which the reactance arms 19 _! at 19 ₄ are sections of slot formed in the metal deposit and extending towards the interior of the resonant pad 2.

It is clear that numerous other embodiments of the antenna impregnated according to the present invention can be envisaged. We can in particular pre oir: other forms of reactance arm; - other forms of pellets (square, round, ...); other tv feed pes. One can in particular replace the line with direct attack by a probe (for example coaxial) with direct attack, a line with coupling without contact, a line with coupling without contact cooperating with a slot, ..., - etc.

In general, in order to obtain a predetermined operation of the printed antenna according to the invention, one can play during the design of this antenna on various parameters, such as in particular: the length and / or the width and / or the geometric shape of each reactor arm, the number of cold points from which at least one reactor arm extends, the number of reactor arms extending from each cold point, etc. We now present, in relation to FIG. 13, a particular embodiment of an array of impinnated antennas according to the present invention.

In this particular embodiment, the network comprises four printed antennas 20 _d to 20 ₄ . Each is supplied at the corner. Each comprises a bent reactance arm 21 _t to 21 ₄ , of length L1 to L4 respectively, which extends from a cold point for one of its two fundamental modes (cf. the fourth embodiment, presented above in relation to Figure 8)

It is assumed that the supply point of the network corresponds to the center 0 of the coordinate system (O, Ox, Oy). It is assumed that, in a conventional manner (and independently of the reactance arms), the pellets of the network have between them a double svmétne with respect to the axes Ox and Oy. Generally, the main direction 22 of ra nement of the network passes by O and is defined by the angle pair (θ, φ), with θ the angle between the axis Oz and the main direction of alignment 22, and φ the angle between the axis Ox and the projection 23 in the plane (Ox, Oy) of the main direction of alignment 22. One can distinguish several cases according to the possible event (s) that present between them the reactance arms of the impnmated antennas of the network. We can in particular distinguish the following four cases if Ll = L2 = L3 = L4 (double s metπe with respect to the axes Ox and Ov). there is no deflection, the ra nement of the network is carried out in a pnncipale direction merged with the axis Oz (that is to say θ = 0 ° mod π), if Ll = L3, L2 = L4 and Ll ≠ L2 (svmétne compared to the axis O): it goes a simple depointing, compared to the axis Ox but not compared to the axis Oy (i.e. φ = 90 ° mod π and θ ≠ 0 ° mod π); if Ll = L2, L3 = L4 and Ll ≠ L3 (s metne compared to the axis Ox): there is a simple depointing, compared to the axis Ov but not compared to the axis

Ox (i.e. φ = 0 ° mod π and θ ≠ 0 ° mod π); if Ll ≠ L2 ≠ L3 (no s mete): it has a double depointing, compared to the axis Ov and compared to the axis Ox (that is to say φ ≠ 0 ° mod π. φ ≠ 90 ° mod π and θ ≠ 0 ° mod π). It is clear that many other embodiments of the array of antennas impnmed according to the present invention can be used. We can in particular provide for: a higher number of antennas impnmed within the network; - a higher number of reactance arms per impnmated antenna (one or more arms from one or more cold points of each antenna); reactance arms extending not in the plane containing the resonant pellet but in an inclined plane relative thereto; - other tv pes of impnmated antennas with reactance arms according to the invention

(such as in particular, but not exclusively, the eight embodiments described above, in relation to FIGS. 5 to 12); etc.

Claims

1. A waterproof antenna, of the t pe comprising: a substrate plate (1), a metallic deposit, situated on a lace of said substrate plate and defining a resonant patch (2), a supply means (3), allowing to feed said resonant pellet, characterized in that it further comprises: at least one reactance arm (10 _x to 10 ₄ ; 14 _! to 14, 17, to 17 ₄ ; 18 _[ to 18, 19ι to 19 ₄ , 21 ₁ to 21) extending from a cold point (5A, 5B; 7A, 7B,

8A, 8B, 9A, 9B) of said resonant patch so as to increase the bandwidth and the level of cross polarization of said antenna.

2. Antenna printed according to claim 1. characterized in that said supply means (3) does not substantially supply said wedge "resonant pad" (2), said resonant pad therefore having a single fundamental mode, and in that said cold point (5A, 5B) from which extends said at least one reactance arm is a cold point for said single fundamental mode.

3. Antenna printed according to claim 1. characterized in that said supply means (3) supplies substantially "in the corner" said resonant patch (2), said resonant patch therefore having at least two fundamental modes, and in that said cold point (9A, 9B) from which extends said at least one reactance arm is a cold point for the superposition of said at least two fundamental modes.

4. Antenna printed according to claim 1, characterized in that said means

(3) the supply feeds substantially "in the corner" said resonant pad (2), said resonant pad thereby having at least two fundamental modes, and in that said cold spot (7A, 7B; 8A. 8B) from which extends said at least one reactance arm is a cold spot for one of said fundamental modes.

5. An impnmated antenna according to any one of claims 1 to 4, characterized in that said at least one reactance arm is formed in said metallic deposit.

6. Antenna impnmée according to rev endication 5, characterized in that said at least one reactance arm is a line section (10, to 10 ₄ ; 14, to 14; 17, to 17; 18, to 18 ₄ ; 21 , to 21 ₄ ) formed in said metallic deposit and extending towards the exteneur of said resonant pad.

7. Antenna printed according to claim 5, characterized in that said at least one reactance arm is a section of slot (19, to 19 ₄ ) formed in said metallic deposit and extending towards the interior of said resonant pad .

8. An impnmated antenna according to any one of claims 1 to 7, characterized in that said supply means belongs to the group comprising - - direct attack lines (3), direct attack probes, coupling lines without touching ; contactless coupling lines cooperating with slots.

9. An antenna impnmée according to any one of claims 1 to 8, caracténsee in that, in order to obtain a predetermined operation of said impnmée antenna, one plays during the design of said antenna on at least one parameter belonging to the group comprising : the length of each reactance arm; the width of each reactor arm; - the geometric shape of each reactor arm, the position of each reactor arm; the number of cold points from which at least one reactance arm extends; the number of reactance arms extending from each cold point.

10. An impnmated antenna according to any one of claims 1 to 9, characterized in that said at least one reactance arm has a length substantially equal to λ / 4, with λ the operating wavelength.

11. Impnmée antenna according to any one of claims 1 to 10, characterized in that said at least one reactance arm has at least one elbow (11).

12. A printed antenna according to any one of claims 1 to 11, characterized in that said resonant patch has at least two cold spots, in that said antenna comprises at least a first pair of reactance arms, and in that the reactance arms of said at least one first pair of reactance arms have substantially a direction relative to a first axis, passing through said at minus two cold spots.

13. An antenna impnmée according to any one of re endications 1 to 12, characterized in that said resonant patch has at least two cold spots, in that said antenna comprises at least a second pair of reactance arms, and in that the reactance arms of said at least a second pair of reactance arms have substantially one axis relative to a second axis, forming an axis of axis for said resonant pad and passing through an excitation point of said resonant pad by said means 'food.

14. Antenna network, characterized in that it comprises at least two waterproof antennas according to any one of claims 1 to 13.

15. antenna array according to claim 14. characterized in that each of said antennas comprises a same set of at least one reactance arm, so as to maximize radiation from said antenna array in a predetermined main direction.

16. antenna array according to claim 15, characterized in that it comprises at least a first pair of antennas and at least a second pair of antennas, in that the antenna reactance arms of said at least one first pair of antennas have substantially a svmétne between them with respect to a third axis, forming a svmétne axis for said antenna array and passing through a feed point of said antenna array, and in that the reactance arms antennas of said at least a second pair of antennas have substantially one svmétne between them with respect to a fourth axis, forming an axis of svmétne for said antenna array, perpendicular to said third axis and passing through said feed point of said array antennas.

17. Antenna array according to claim 14, characterized in that at least two of said antennas each comprise a distinct set of at least one reactance arm, so as to induce a shift in the alignment of said antenna array with respect to a predetermined main direction

18. Antenna network as claimed in claim 17, characterized in that it comprises at least a first pair of antennas, and in that the antenna reactance arms of said at least one first pair of antennas do not have not between them a sv metne with respect to a third axis, forming an axis of sv metne for said antenna array and passing through a feed point of said antenna array, so that said depointing takes place around said third axis 19. Antenna network according to re endication 18 characterized in that it comprises at least a second pair of antennas, and in that the antenna reactance arms of said at least one second pair of antennas do not have between them a sv metne with respect to a fourth axis, forming an axis of sv metne for said antenna array, perpendicular to said third axis and passing through said feed point of said antenna array, so that said depointing takes place égaleme nt around said fourth axis.