EP4304012A1 - Improved elementary antenna of the slot fed radiating plane type and active antenna array - Google Patents

Abstract

This elementary antenna 1 comprises: two cross-shaped slots 32, 33 defining four half-slots; for each half-slot, excitation ribbons 41, 42, the first ribbon 41 being connected to a first via 61 and the second ribbon 42 being connected to a second via 62; an integrated circuit 70 carrying a plurality of ports; for each half-slot, ribbon supply tracks, the first track 51 circulating from a first port 71 to the first via 61 and the second track 52 circulating from a second port 72 to the second via 62, the first and second ports being two successive ports of the integrated circuit, differentially connected to a transmission/reception voice by first and second power lines located inside the integrated circuit, the lines and tracks circulating so that there is no crossover in their respective routings.

Description

The present invention relates to an elementary antenna of the “radiating plane fed by slots” type for an active array antenna.

An active array antenna, in particular with electronic scanning (AESA - “Active Electronically Scanned Array” in English), is a mosaic of a plurality of identical elementary antennas.

For active array antennas, there is a need to be able to emit a signal with high peak power.

If it is the electronic transmission chain upstream of the active antenna which prepares this high power signal, this requires summation of amplifiers with low efficiencies and additional losses at the end of amplification, this is i.e. when returns are most crucial. In addition, this high power signal must then be conveyed to the radiating element of each elementary antenna, which leads to additional losses and constraints for conveying high power signals.

Another alternative consists of preparing this power signal in each elementary antenna by combining several reduced power signals applied to the input of the elementary antenna.

The power combination in the elementary antenna is carried out by two pairs of feed points (the number of feed points being four).

For example as illustrated in the figure 1 , the applicant company produces an active network antenna, an elementary antenna 101 of which is of the radiating plane type fed by slots. The radiating element here is a metallic plane (“patch” in English) or a combination of metallic planes, arranged on a front face of the elementary antenna, and which is excited by a pair of slots: first and second slots, 132 and 133, orthogonal to each other so as to form a cross pattern.

Each slot is excited by a pair of strips (or “stripline” in English), 142 and 146 for the first slot 132 and 144 and 148 for the second slot 133, which overlap the slot at two excitation points arranged symmetrically from either side of the geometric center of the elementary antenna.

For supplying the ribbons, an integrated circuit 170 is placed on a rear face of the elementary antenna. The integrated circuit has as many power ports 172, 174, 176, and 178 as there are ribbons to be powered.

Electrical tracks 152, 154, 156 and 158 connect each port of the integrated circuit 170 to the end of the associated ribbon (through vias 162, 164, 166 and 168).

To be able to properly excite the main mode TE10 of a slot, the two excitation ribbons of this slot should be supplied in phase opposition, that is to say in differential.

Thus, inside the integrated circuit 170, two opposite ports are connected at the output of the same transmission/reception channel by two power lines. Thus, ports 172 and 176 are differentially supplied from channel 182 by lines 192 and 196 and ports 174 and 178 are differentially supplied from channel 183 by lines 194 and 198.

We see that it is then necessary to cross the power lines within the integrated circuit (crossing 184 on the figure 1 ) or the supply tracks.

Routing inside or outside the integrated circuit is therefore not optimal and causes losses and imbalances between the ribbons and consequently in the operation of the elementary antenna.

Furthermore, the reproducibility of the routing from one elementary antenna to another is difficult to achieve, so that there is a significant dispersion of the characteristics of the elementary antennas constituting an antenna. The properties of the antenna are therefore degraded.

The aim of the present invention is to provide a solution to this problem.

For this, the subject of the invention is an elementary antenna of the radiating plane type fed by slots for an active network antenna, characterized in that, the radiating plane being arranged on a front face of the elementary antenna, the elementary antenna comprises: a ground plane carrying first and second slots, orthogonal to each other so as to form a cross pattern defining four half-slots; for each half-slot, a pair of ribbons making it possible to excite the half-slot, a first ribbon of the pair of ribbons being connected by one of its ends to a first via associated with the first ribbon and overlapping the half-slot from a first side towards a second side of the half-slot, a second ribbon of the pair of ribbons being connected by one of its ends to a second via associated with the second ribbon and overlapping the half-slot from the second side towards the first side of the half -slit, the first and second ribbons of the pair of ribbons circulating without crossing; an integrated circuit arranged on a rear face of the elementary antenna, an outline of the integrated circuit carrying a plurality of ports; for each half-slot, a pair of power tracks of the pair of ribbons making it possible to excite the half-slot, a first track of the pair of power tracks circulating from a first port of the integrated circuit to the first via, a second track of the pair of power tracks circulating from a second port of the integrated circuit to the second via, the first and second ports being two successive ports along the contour of the integrated circuit, which are connected in differential to a transmission/reception voice of the elementary antenna by first and second power lines located inside the integrated circuit, the lines and tracks circulating so that There is no crossover in the routing of either lines inside the circuit board or tracks outside the circuit board.

• le circuit intégré est un circuit intégré monolithique hyperfréquence,
• les vias sont disposés en périphérie de l'antenne élémentaire à proximité de ses bords et, pour chaque demi-fente, les premier et second vias de connexion de la paire de rubans permettant d'exciter la demi-fente sont deux vias successifs le long de la périphérie de l'antenne élémentaire,
• pour chaque demi-fente, les premier et second rubans d'une paire de rubans permettant d'exciter la demi-fente présentent une longueur identique,
• pour chaque demi-fente, les premier et second rubans d'une paire de rubans permettant d'exciter la demi-fente circulent en parallèle l'un de l'autre,
• pour chaque demi-fente, les premier et second rubans d'une paire de rubans permettant d'exciter la demi-fente sont espacés d'une distance permettant un isolement électrique des premier et second rubans tout en excitant la demi-fente en deux points d'excitation proches pour considérer que la demi-fente comme excitée localement,
• un ruban croise une demi-fente orthogonalement,
• les première et seconde pistes de la paire de pistes d'alimentation associée à une demi-fente ont la même longueur ; et
• l'antenne élémentaire est symétrique par rotation de 90° autour d'un axe normal au plan rayonnant.

According to particular embodiments, the elementary antenna comprises one or more of the following characteristics, taken individually or in all technically possible combinations:

• the integrated circuit is a monolithic microwave integrated circuit,
• the vias are arranged on the periphery of the elementary antenna near its edges and, for each half-slot, the first and second connection vias of the pair of ribbons making it possible to excite the half-slot are two successive vias along from the periphery of the elementary antenna,
• for each half-slot, the first and second ribbons of a pair of ribbons making it possible to excite the half-slot have an identical length,
• for each half-slot, the first and second ribbons of a pair of ribbons making it possible to excite the half-slot circulate in parallel to each other,
• for each half-slot, the first and second ribbons of a pair of ribbons making it possible to excite the half-slot are spaced a distance allowing electrical isolation of the first and second ribbons while exciting the half-slot at two points close excitations to consider that the half-slit as locally excited,
• a ribbon crosses a half-slit orthogonally,
• the first and second tracks of the pair of power tracks associated with a half-slot have the same length; And
• the elementary antenna is symmetrical by rotation of 90° around an axis normal to the radiating plane.

The invention also relates to an array antenna comprising a plurality of active antennas identical to the previous active antenna.

• [Fig 1] La figure 1 est une représentation schématique en vue de dessous d'une antenne élémentaire selon l'état de la technique ;
• [Fig 2] La figure 2 est une représentation en coupe transversale d'un mode de réalisation préféré d'une antenne élémentaire selon l'invention ;
• [Fig 3] La figure 3 est une représentation en vue de dessous de l'antenne élémentaire de la figure 2 ; et,
• [Fig 4] La figure 4 est une représentation électrique des moyens d'alimentation de l'antenne élémentaire de la figure 2.

The invention and its advantages will be better understood on reading the detailed description which follows of a particular embodiment, given solely by way of illustrative and non-limiting example, this description being made with reference to the accompanying drawings on which :

• [ Figure 1 ] There figure 1 is a schematic representation seen from below of an elementary antenna according to the state of the art;
• [ Figure 2 ] There figure 2 is a cross-sectional representation of a preferred embodiment of an elementary antenna according to the invention;
• [ Figure 3 ] There Figure 3 is a bottom view representation of the elementary antenna of the figure 2 ; And,
• [ Figure 4 ] There figure 4 is an electrical representation of the means of supplying the elementary antenna of the figure 2 .

An active array antenna, in particular with electronic scanning, is a mosaic made up of a plurality of identical elementary antennas.

The present invention relates to the case of an active network antenna whose elementary antennas are of the “slot-fed patch” type. A patch is a metallic plane printed on a substrate. The radiating element of the elementary antenna is constituted by at least one patch.

There figure 2 is a cross section of a preferred embodiment of an elementary antenna 1 according to the invention.

• un premier substrat 10, qui est le substrat dit « antennaire », sur une surface supérieure duquel est gravé un premier patch 11. Cette surface supérieure constitue la face avant de l'antenne élémentaire.
• un second substrat 20, sur une surface supérieure duquel est gravé un second patch 21.
• un troisième substrat 30, dont une surface supérieure porte un plan de masse supérieur 31, qui est muni de fentes.
• un quatrième substrat 40, dont une surface supérieure porte une pluralité de rubans pour exciter les fentes.
• un cinquième substrat 50, dont une surface inférieure porte à la fois le circuit intégré 70 et les pistes d'alimentation des rubans. Une piste est connectée à un port du circuit intégré 70 d'une part, et à un via, d'autre part. Le via traverse les cinquième et quatrième substrats pour relier la piste au ruban associé. Il y a donc une piste par ruban. La surface supérieure du substrat 50, orientée vers le ou les patch(s) comporte un plan de masse inférieur 49 dans lequel sont gravées des épargnes (ou trous) afin de réaliser la connexion par via précédemment mentionnée.

The elementary antenna 1 comprises four substrates, stacked on top of each other along a Z axis, called “vertical”:

• a first substrate 10, which is the so-called “antennary” substrate, on an upper surface of which a first patch 11 is etched. This upper surface constitutes the front face of the elementary antenna.
• a second substrate 20, on an upper surface of which a second patch 21 is etched.
• a third substrate 30, an upper surface of which carries an upper ground plane 31, which is provided with slots.
• a fourth substrate 40, an upper surface of which carries a plurality of ribbons for exciting the slots.
• a fifth substrate 50, a lower surface of which carries both the integrated circuit 70 and the ribbon supply tracks. A track is connected to a port of the integrated circuit 70 on the one hand, and to a via on the other hand. The via passes through the fifth and fourth substrates to connect the track to the associated ribbon. So there is one track per ribbon. The upper surface of the substrate 50, oriented towards the patch(s), comprises a lower ground plane 49 in which savings (or holes) are etched in order to make the previously mentioned via connection.

The different substrates are associated with each other, for example by means of a suitable glue: an interface layer between the first and second substrates bears the reference 12 on the figure 2 ; an interface layer between the second and third substrates bears the reference 23 on the figure 2 ; an interface layer between the third and fourth substrates bears the reference 34 on the figure 2 ; and an interface layer between the fourth and fifth substrates bears the reference 45 on the figure 2 .

There Figure 3 is a bottom view of the elementary antenna 1 of the figure 2 , that is to say along a plane transverse to the Z axis. This transverse plane is defined by axes 31 and the slots with which it is provided, as well as the different excitation ribbons of the slots.

The elementary antenna 1 is preferably square in shape. It has a central symmetry with respect to its center O, but above all a symmetry by rotation of 90° around the center O. Alternatively, the elementary antenna can take other shapes, in particular rectangular or circular.

Two slots 32 and 33 are provided in the ground plane 31. These slots are oblong.

In the embodiment shown, they are rectangular, but as a variant they could have ends so that a slot has a "dog bone", "dumbbell" shape, or other...

Each slot has a reduced width compared to its length, the latter being slightly less than that on the side of the elementary antenna.

The slots are arranged so that the major axis of the first slot 32 coincides with the Y axis and that of the second slot 33 coincides with the X axis.

The two slots therefore intersect at right angles at the geometric center O of the elementary antenna 1, so as to form a cross pattern.

This cross pattern can be seen as composed of four half-slots, respectively a first positive half-slot corresponding to the part of the first slot 32 above the X axis, a first negative half-slot corresponding to the part of the first slot 32 below the axis slot 33 to the left of the Y axis on the Figure 3 .

In what follows, unless otherwise stated, the elementary antenna is described in detail as it relates to a particular half-slot, in this case the first upper half-slot.

The half-slot is excited by a pair of ribbons. This pair of ribbons comprises a first ribbon 41 and a second ribbon 42 which do not overlap.

In the present embodiment, a ribbon is made up of a plurality of rectilinear portions. The first ribbon 41 thus comprises a proximal portion 411, an intermediate portion 412, and a distal portion 413. The second ribbon 42 thus comprises a proximal portion 421, an intermediate portion 422, and a distal portion 423.

The proximal portion of a ribbon is connected to a first via associated with the ribbon, respectively a first via 61 for the first ribbon 41 and a second via 62 for the second ribbon 42. The vias are here arranged on the periphery of the antenna at proximity to its edges.

The first ribbon 41 circulates for example from the via 61 (located to the left of the axis overlaps the half-slot perpendicular to the X axis of the half-slot and its distal portion makes an angle of +45° relative to the X axis of the half-slot.

Similarly, the second ribbon 42 circulates from the via 62 (located to the right of the axis X) so that its proximal portion makes an angle of +45° relative to the axis intermediate portion overlaps the half-slot perpendicular to the axis

Other paths are possible for the ribbons: rectilinear portions making other angles in relation to the X axis (respectively the Y axis), curvilinear portions, etc.

The first ribbon 41 preferably crosses the half-slot orthogonally at a first excitation point. This first crossing is made by crossing the half-slot from left to right.

The second ribbon 42 crosses the half-slot orthogonally at a second excitation point, further away from the center O than the first excitation point. A distance d separates the first and second excitation points along the axis X. This distance is reduced as much as possible, while maintaining an electrical insulation interval between the ribbons.

The distance d is minimal so that the excitation of the half-slit by the pair of ribbons takes place essentially locally, that is to say that we can consider that the application of a first electric field d excitation at the first excitation point and a second excitation electric field at the second excitation point, is equivalent to the application of an excitation electric field (resulting from the sum of the first and second excitation electric field) at a midpoint between the first and second excitation points.

This second crossing is carried out by crossing the half-slot from right to left. The head-to-tail configuration of this particular embodiment requires, all things being equal, that the electric potential A- to which the second ribbon 42 is carried is phase shifted by 180° with respect to the electric potential A+ to which the first ribbon 41 is carried, so that the electric fields generated are in phase to properly excite the first slot.

The first and second ribbons run parallel to each other. Preferably, we try to maintain a constant offset between the first and second ribbons 41 and 42 for reasons of coupling between the ribbons of the same pair of ribbons.

Each ribbon continues beyond the half-slot so as to optimize the impedance matching (“stub” in English). We try to give the two ribbons the same length so that they have the same impedance. For this, the proximal portion of the second ribbon, a priori shorter in the embodiment of the figures, can be extended for example by a meander at the level of the connection to the second via. Alternatively, a phase shift can be introduced between the signals delivered to each port of the integrated circuit, this phase shift being able to be achieved either by adding a length of line upstream of said port or directly by a phase shifter integrated into the integrated circuit.

A similar description could be made for the pair of ribbons 43, 44 for excitation of the second positive half-slot (associated vias 63 and 64 and supply potentials D+ and D-), for the pair of ribbons 45, 46 d excitation of the first negative half-slot (associated vias 65 and 66 and potentials B+ and B-), for the pair of ribbons 47, 48 for excitation of the second negative half-slot (associated vias 67 and 68 and potentials C+ etc-).

The ribbon supply means must apply voltages adapted in phase so that the elementary antenna emits a polarized wave.

The table below indicates the phase control for the elementary antenna to transmit at different polarizations. [TABLE 1] A+ HAS- B+ B- C+ VS- D+ D- Polarization (relative to the X axis) 0° 180° 0° 180° 0° 180° 0° 180° 45° 0° 180° 0° 180° 180° 0° 180° 0° -45° 0° 180° 0° 180° 90° 270° 90° 270° Right circular 0° 180° 0° 180° 270° 90° 270° 90° Left circular 0° 180° 0° 180° OFF OFF OFF OFF Horizontal OFF OFF OFF OFF 0° 180° 0° 180° Vertical

It should be noted that a slot is excited symmetrically with respect to the center O by two pairs of ribbons so as to operate in the TE10 mode.

The means for supplying the pairs of ribbons comprise an integrated circuit 70 and supply tracks circulating on the rear face of the elementary antenna.

Circuit 70 is for example a monolithic microwave integrated circuit - MMIC (“Monolithic Microwave Integrated Circuit”).

It is, for example, parallelepiped in shape. For example, it still has a square contour in the transverse plane XY.

It is located in the center O of the rear face of the elementary antenna so that its sides are parallel to the sides of the elementary antenna.

Each of the four sides of the circuit has two ports (or connection pins), referenced 71 to 78 on the Figure 3 . Circuit 70 therefore has eight output ports in total.

A power trace electrically connects a port of the circuit to a via associated with a ribbon.

Thus, with the pair of ribbons 41 and 42 exciting the first positive half-slot is associated a pair of supply tracks 51 and 52. The first ribbon 41 is supplied by a first dedicated track 51 through the via 61, while the second ribbon 42 is supplied by a second dedicated track 42 through the via 62.

The first and second tracks 51 and 52 are connected to ports of circuit 70 located on the same side of integrated circuit 70, in this case ports 71 and 72 on the side of circuit 70 oriented towards vias 61 and 62.

Note that the vias are here arranged on the periphery of the elementary antenna near its edges. The first and second vias 61 and 62 are successive vias along the periphery of the antenna.

The first track 51 has for example the shape of an “L”, with an axial section 511, which circulates parallel to the axis a lateral section 511 which circulates transversely to the axis which circulates transversely to the X axis to join the second via 62.

The first and second vias 61 and 62 pass through the fifth and fourth substrates, 50 and 40, to electrically connect an associated track and ribbon. Each via passes through the ground plane provided on the upper surface of the fifth substrate at the level of a savings provided in this ground plane.

The impedances seen by each port 71 and 72 must be as close as possible to each other.

A similar description could be made for the supply of the pair of ribbons 43 and 44 from the ports 73 and 74 by the supply tracks 53 and 54 respectively, for the supply of the pair of ribbons 45 and 46 from the ports 75 and 76 by the feed tracks 55 and 56 respectively, and for feeding the pair of ribbons 47 and 48 from the ports 77 and 78 by the feed tracks 57 and 58 respectively.

There figure 4 is an electrical representation illustrating the routing inside and outside of the integrated circuit 70.

A pair of ports for supplying a pair of ribbons, such as the pair 71 and 72 for supplying the pair of ribbons of the first positive half-slot, is supplied in differential at the output of a channel. transmission/reception 81 (represented schematically on the figure 4 ), by a first line 91 connected to the first port 71 and a second line 92 connected to the second port 72.

Similarly, the pair of ports 73 and 74 for supplying the pair of ribbons of the second positive half-slot are differentially supplied at the output of a transmission/reception channel 83 by a first line 93 connected to the first port 73 and a second line 94 connected to the second port 74.

In a similar manner, the pair of ports 75 and 76 for supplying the pair of ribbons of the first lower half-slot are differentially supplied at the output of a transmission/reception channel 85 by a first line 95 connected to the first port 75 and a second line 96 connected to the second port 76.

In a similar manner, the pair of ports 77 and 78 for supplying the pair of ribbons of the second negative half-slot are differentially supplied at the output of a transmission/reception channel 87 by a first line 97 connected to the first port 77 and a second line 98 connected to the second port 78.

Those skilled in the art will note in this figure that the routing is now devoid of any crossing whether between lines 91 to 97 inside the integrated circuit 70, or between tracks 51 to 58 outside the circuit. integrated 70.

Routing is thus greatly reduced. This simplifies the production of the printed circuit and the stacking of its constituent layers.

In addition, greater manufacturing precision of the elementary antennas is obtained, which has a positive impact on the overall operation of the active array antenna integrating such radiating elements.

The present invention has the advantage of presenting four pairs of excitation points of the slots, or eight excitation points. This therefore doubles the power emitted compared to the configuration of the figure 1 .

This makes it possible, during transmission, to combine the powers of eight elementary signals in order to generate a signal of higher power.

This allows the incident power to be distributed over a larger number of receiving voices in reception. The power level applied to the input of the low noise amplifier - LNA of the electronic chain of the receiving voice is therefore reduced, so that this component is not saturated and can operate in an optimal linear range.

The present invention makes it possible to improve efficiency by minimizing losses.

Thanks to the summation in the elementary antenna, the printed circuit no longer uses as much combiner. This helps reduce heat dissipation within the integrated circuit and reduces the size of the printed circuit.

It allows programmable polarization.

The present invention finds applications in the field of radars, jammers, radiocommunications, remote energy transfer, or even data links.

Claims (10)

Elementary antenna (1) of the slot-fed radiating plane type for an active array antenna, characterized in that , the radiating plane (11) being arranged on a front face of the elementary antenna, the elementary antenna comprises: - a ground plane carrying first and second slots (32, 33), orthogonal to each other so as to form a cross pattern defining four half-slots; - for each half-slot, a pair of ribbons (41, 42) making it possible to excite the half-slot, a first ribbon (41) of the pair of ribbons being connected by one of its ends to a first via (61) associated with the first ribbon and overlapping the half slot from a first side towards a second side of the half slot, a second ribbon (42) of the pair of ribbons being connected by one of its ends to a second via (62) associated with the second ribbon and overlapping the half slit from the second side towards the first side of the half slit, the first and second ribbons of the pair of ribbons circulating without crossing each other; - an integrated circuit (70) arranged on a rear face of the elementary antenna, an outline of the integrated circuit carrying a plurality of ports; - for each half-slot, a pair of supply tracks of the pair of ribbons making it possible to excite the half-slot, a first track (51) of the pair of supply tracks circulating from a first port (71) of the integrated circuit to the first via (61), a second track (52) of the pair of power tracks circulating from a second port (72) of the integrated circuit to the second via (62), the first and second ports being two successive ports along the contour of the integrated circuit, which are differentially connected to a transmission/reception voice (81) of the elementary antenna by first and second power lines (91, 92) located at inside the integrated circuit, the lines and tracks flowing so that there is no crossover in the routing of either the lines inside the integrated circuit or the tracks outside the integrated circuit. Elementary antenna (1) according to claim 1, in which the integrated circuit (70) is a monolithic microwave integrated circuit. Elementary antenna (1) according to any one of the preceding claims, in which the vias are arranged on the periphery of the elementary antenna near its edges and, for each half-slot, the first and second vias (61, 62) connecting the pair of ribbons making it possible to excite the half-slot are two successive vias along the periphery of the elementary antenna. Elementary antenna (1) according to any one of the preceding claims, in which, for each half-slot, the first and second ribbons of a pair of ribbons making it possible to excite the half-slot have an identical length. Elementary antenna (1) according to any one of the preceding claims, in which, for each half-slot, the first and second ribbons of a pair of ribbons making it possible to excite the half-slot circulate in parallel to one of the 'other. Elementary antenna (1) according to any one of the preceding claims, in which, for each half-slot, the first and second ribbons of a pair of ribbons making it possible to excite the half-slot are spaced apart by a distance allowing a electrical insulation of the first and second ribbons while exciting the half-slot at two nearby excitation points to consider the half-slot as locally excited. Elementary antenna (1) according to any one of the preceding claims, in which a ribbon crosses a half-slot orthogonally. Elementary antenna (1) according to any one of the preceding claims, in which the first and second tracks of the pair of feed tracks associated with a half-slot have the same length. Elementary antenna (1) according to any one of the preceding claims, symmetrical by rotation of 90° around an axis (Z) normal to the radiating plane. Active array antenna comprising a plurality of elementary antennas, characterized in that each elementary antenna conforms to any one of claims 1 to 9.

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