FR2808128A1 - Mobile telephone cross polarisation monolithic antenna having radiating element base reflector mounted and having folded foot upper element/feed line connected - Google Patents

Abstract

The monolithic cross polarised antenna has a rectangular reflector (2) with radiating elements (11) and feed system (20). The feed circuit has two line conductors connecting two elements. Each conductor element has a folded foot (17) connected between the upper element and the feed lines.

Description

The present invention relates to a cross-polarized monolithic antenna for cellular telephony in particular.

Document FR-A-2 766 626 discloses a cross-polarized antenna having dipoles mounted on a reflector, being orthogonal two-by-two and thereby defining at least one cross-polarizing radiating cell. This antenna preferably comprises a plurality of cross-polarizing radiating cells, which are identical to each other and arranged on the same alignment along the reflector.

In this known antenna, the two conductive elements of each of the dipoles are identical. They have the shape of a Vé and are mounted back to, the bases Vés being in opposite. Each of them has a leg secured to the reflector and provided with two end lateral arms opposite the reflector. It is advantageously made of a single piece in the form of a properly cut plate and then folded into Ve.

In this same known antenna, two dipoles are arranged orthogonally to each other having the two conductive elements one of them interposed between the two conductive elements of the other dipole, to define one of the cells Cross-polarized radiators which form a compact and robust radiating module.

This known antenna also comprises a system for feeding its cross-polarizing radiating cells. This power system is dual for feeding the two cell dipoles from two external sources of energy. It is constituted analogously regardless of the dipole of each of the cells. It comprises a first section of coaxial cable connected to a coaxial connector for connection to one of the sources, second sections of coaxial cable each connected to one of the dipoles of the cells, a power divider coupling the first section to the second sections of coaxial cable. turns out that such a power system induces losses and can generate unwanted intermodulation products, which are due essentially to the many welded connections that this power system has, especially for its connection to the dipoles.

The object of the present invention is to minimize the disadvantages and to simplify the power supply system of a compact cross-polarized cell antenna as mentioned above, and consequently to simplify the overall structure of the antenna by considerably reducing its cost. .

It relates to a cross-polarized monolithic antenna, comprising a substantially rectangular reflector, radiating cells mounted aligned on said reflector each formed by two orthogonal dipoles, and a supply system connecting the two dipoles of said radiating cells to two sources of radiation. external energy, each of the dipoles comprising two flat conductive elements folded in V, arranged back to back and each having a central branch of folding fixed to the reflector by a first end portion of said branch and two terminal lateral arms protruding from each other on a second end portion of said branch, the two conductive elements of one of the dipoles of each of the cells being each disposed between those of the other dipole of the same cell, characterized in that said supply circuit comprises two lines conductive power plates, mounted opposite said reflector and connected to one and the other of said sources respectively, and in that only one of the first two conductive elements of each of said dipoles comprises a folded conductive tab, having a first end secured to the second end portion of the central branch of said first conductive element, extending inside the Ve and substantially along the central branch of the second conductive element of the dipole and having a second end connected to one of said supply lines. Advantageously, this antenna also has one of the following characteristics: - said flat conductive lines are situated on a so-called rear face of said reflector, said cells being mounted on a so-called front face of said reflector, - the integral tabs of the first conductive elements two dipoles of the same radiating cell intersect, without contact with each other, in a front part of the cell and have the same orientations as the one and the other of the crossed polarizations of the cell, - the tab is an integral part of said first conductive element, - the tab is integral with the front end of the central branch of said first conductive element and extends inside the Ve facing the central branch of the second conductive element of the dipole, - the tab is secured of an intermediate portion of the second end portion of the central branch of said first element, is constituted by an axial cutting portion of said central branch, completely detached from it, and extends along the split axial portion of the central branch of the second conductive element of the dipole, - each of the conductive lines have bifurcations in T with two lateral branches welded to the legs of the two first dipole elements of two consecutive cells on said reflector, respectively, - each of said conductive lines has a central extension, conductive line connection to one of the external sources.

The features and advantages of the present invention will emerge from an embodiment illustrated by way of preferred but nonlimiting example in the accompanying drawings. In these drawings - Figure 1 is a front view of an antenna according to the invention - Figure 2 is a top view of a radiating cell of the antenna Figure 1, - Figures 3 and 4 are two perspective views of two first conductive elements of one and the other of the dipoles of each of the radiating cells, - Figure 5 is a front view of one of the dipoles of each of the radiating cells, - Figure 6 is a rear view of the antenna, - Figures 7 and 8 show an alternative embodiment of the first two conductive elements Figures 3 and 4, - Figure 9 shows the second conductive element to be associated with the first element of Figure 7 for constitute one of the dipoles of the radiating cells, - Figure 10 shows dipoles according to this variant.

Referring to FIG. 1, it can be seen that the antenna comprises a plurality of identical cross-polarized radiating cells which are mounted axially aligned on a reflector 2. These cells are four in number in the illustrated example but their number could be different. The reflector 2 is plane with two longitudinal rebounds 3 and 4 folded at 90 on the same side as the radiating cells 1.

With reference to FIG. 2, it can be seen that each radiating cell 1 comprises two orthogonal dipoles 11 and 12. Each of the dipoles is formed by a pair of conductive elements 1 <B> IA </ B> and 1 1 B or 12A and 12B having the shape of a Vee, whose Vés are mounted back to back at a short distance from each other. one of the other. The two main polarization components of the fed dipoles, which are the two orthogonally crossed polarizations 5 and 6 and in phase with each other of the elements of the same dipole, are illustrated in phantom. It has also been shown on one of the conductive elements, the secondary polarization components 7A and 7B, which are orthogonal to the main polarization of the dipole and are in phase opposition with each other and therefore cancel themselves directly. . Furthermore, the polarities of dipole elements for their radiofrequency wave radiation in a broad band diagram have been denoted by + and polarities from the electrical energy supplied by two external sources, not shown.

The orientation in FIG. 1 of the radiating cells 1 on the reflector 2 is advantageously chosen so that the crossed polarizations 5 and 6 are not horizontal or vertical, in order to optimize the transmission characteristics of the dipoles. These crossed polarizations are substantially + and - 45 with respect to the longitudinal axis of the reflector corresponding to the vertical.

Referring to Figures 2 to 5, it appears that the conductive elements of the dipoles are advantageously constituted by properly cut plates folded Vee.

Each of these conductive elements has the same, as referenced in Figure 3 for the element 12A, a central branch 13 folded longitudinally and two lateral end arms 14 and 5, projecting on one of the end portions before said plugged. At least one tooth 16 is provided on the other end of the branch for mounting the conductive element reflector. The central branch has in this embodiment two longitudinal folds thus dividing it into a flat axial portion 13A, constituting axial flattened, and two fins such as 13B folded on the same side along the flat. Alternatively, it may have only one axial line of folding.

Only one of the two conductive elements of the same dipole, such as the element 12A of the dipole 12 and the element 11A of the dipole 1, further comprises a lug 1 or 17 'which leaves the front end slightly indented of the central branch 13, or 13 'corresponding to the element <B> 11 </ B> A. This tab is centered on the end of the branch and is folded to extend facing and along the branch central, being outside the VE defines this element 12A or 1 1 This tab is received inside the Vee that defines the other element 12B of the dipole 12 or 11 B of the dipole 11, where it extends the long and facing the central branch of this other element as shown in Figure 2 or 5. This tab is an integral part of the conductive element or alternatively is rappportee and soldered in front end of its central branch.

With reference to FIGS. 3 and 4, it will be noted that the two conductive elements 12A and 1 differ from each other only by their notch before 13C or 13'C leaves the tab 17 or 17 '. These two notches although shallow have different depths from each other. They thus allow tabs 17 and 17 'to intersect in the front part of the radiating cell, as shown in FIG. 2, but without contact with each other.

length of the central branch and the two arms of the different conductive elements is equal to one quarter of the wavelength of the energy radiated by each dipole. The different parts of the conductive elements of each of the dipoles constitute a balancing assembly for their supply of electrical energy from two unrepresented external sources, to which the dipoles are coupled as described below.

mounting teeth 16 provided on the conductive elements are received in the reflector 2 and welded thereto, each by a weld point such as 18 in Figures 5 and 6. The end of the tab 17 or 17 ', provided only one of the two conductive elements of each dipole, is received through the reflector, but remains isolated therefrom and is connected by a weld point 19 to a supply circuit 20 of the dipoles.

This supply circuit 20 is advantageously made at the rear of the reflector 2, as can be seen in FIGS. 5 and 6. As a variant, it can be produced at the front of the reflector, but is then associated with additional elements of the reflector. decoupling between its different parts connected to the dipoles of the radiating cells.

It is constituted symmetrically with respect to the longitudinal axis of the reflector 2, being at a small defined distance from the reflector. It thus comprises two feed lines 21 and 22, each coupled to one of the two external sources not shown. These two lines are parallel to the alignment of the radiating cells and located on either side of the direction of this alignment. Each of them has two T-shaped bifurcations which are provided, for example at both ends of this line. Thus, while referring at the same time to FIG. 1 or 2, it is understood that the two lateral branches 23 and one of the two bifurcations and those similar to the other bifucartion on the line 21 are each connected to the conductive element The two branches of the bifurcations on the line 22 are connected to the conductive elements 12A of the dipoles 1 of the cells. The other conductive elements 1 1 B and 12B of the dipoles 11 and 1 2 are in turn electrically connected to the reflector 2, grounded to the two external sources of energy.

A connection extension 25 is provided on the middle part of each of the supply lines such as 21. This extension serves for the direct connection of one of the external sources in the middle of this line 21. As a variant it is used for the connecting, via a coaxial cable section, the power supply line to a coaxial connector mounted at one end of the reflector and connected to one of the sources. The energy from the external sources is thus distributed in a suitable manner on the different dipoles 11 and 2, the amplitude and phase weightings being obtained by variations of the parameters of the power system, namely the distance of the lines and 22 and their bifurcations relative to the reflector 2 and the length and width of these lines and bifurcations.

lines are flat electrical conductors of the same nature as the reflector and the conductive elements of the dipoles 11 and 1 in particular aluminum or aluminum alloy. They are held opposite the required distance from the reflector by insulating spacers, not shown, which are provided between them and the reflector.

To complete the description of the antenna according to the invention, there is shown in Figure b the solder points 18 of the ends of the central branches of the various conductive elements of the dipoles and the soldering points 19 of the additional legs provided on two of the four conductive elements of each radiating cell. Figure 2 shows the holes 29 for passage of the tabs 17 and 17 'through the reflector, without contact between these tabs and the reflector.

Finally, it is specified that unrepresented insulating shims may advantageously be provided between each of the lugs, such as 17 and 17 ', and the central branch of the conductive element which receives the lug.

Similarly, one or more insulating shims not shown are advantageously provided between the integral tab of the conductive element 1 1 A and that integral with the conductive element 12A, which intersect one below the other but without electrical contact. between them at the front each cell 1 (figure). The portions of these tabs which intersect at the front of the cell are oriented according to the crossed polarizations 5 and 6.

Advantages of the monolithic antenna structure, by integrating the dipole supply system and thus eliminating many solder points, stand out directly from the description of this preferred embodiment. These benefits include improved ruggedness, power system losses and minimized intermodulation undesirable products, and significantly reduced cost of the antenna.

In the variant embodiment given in FIGS. 7 and 8, with respect to FIGS. 3 and 4, the first two conductive elements respectively of the two dipoles of the same radiating cell are designated by 32A and 31A. Their only differences with respect to the conductive elements 12A and 11A of the figures and 4 are specified below.

In this variant, the front end of the central branch 33 or 33 'is indented. By against an axial slot 38 or 38 'provided in this central branch, and extends from an intermediate portion of its front end portion to its rear end, the width of the initial flat between the two fins 33B or 33'B . The tab or 37 'of each of the conductive elements is constituted by the axial cutting portion of the slot, without its detachment from the front portion 33 or only remaining from the initial flat, and by folding twice of this axial cutting portion. This leg thus extends outside the V and facing the conductive element which it is integral.

These figures 7 and 8 show that the folding point closest to the central branch is at a slightly different level on two legs 37 and 37 '. This allows the crossing of these tabs, without contact in the front part of the radiating cell.

FIG. 9 shows the second conductive element 32B associated with the conductive element 32A of FIG. 7 to then form dipoles 32 noted and illustrated in FIG. 10. It emerges that this second element 32B is similar to the conductive element 32A. except that it has no tab 37 of it. In particular, its central branch has a slot 38B extending over almost its entire length, to receive the tab 37 without contact between this tab and the conductive element 32B.

As a non-illustrated variant indicated with respect to FIG. 9, instead of the aforementioned slot 38B, a simple light can be provided in an intermediate portion of the front part of the flat part of the central branch, for the insertion through this light of the tab 37 of the element 32A of Figure 7 inside the Vee of the conductive element 32B thus modified. This tab 37 then remains without contact with this conductive element that receives it.

When the dipole 32 of FIG. 10 is mounted on the reflector and then fed, as has been described above for the dipoles 11 and 12 with reference to FIGS. 2, 5 and 6, the tab 37 is at + polarity. one of the two external sources to thereby give this polarity + to the conductive element 32A, while the conductive element 32B is at the polarity - given by the reflector grounded external sources. By this tab 37 located in or almost in the slot 38B, this results in a coplanar or quasi-coplanar radio-electric power supply mode of the two conductive elements of this dipole 32.

Comparatively, the feeding mode of the two elements of each of the preceding dipoles 11 and 12, such as the resulting dipole, the variant suggested with reference to FIG. 9, is of the microstrip type, with an air dielectric layer of thickness defined between the conductive parts which have + and - polarities and are opposite each other.

The advantage of the variant embodiment described with regard to FIGS. 7 and 10 is that the radiating cells thus obtained are lighter and less expensive since the tab of one of the two conductive elements of each dipole essentially comes from the cutting of its central branch and that the other element is itself split.

Claims (1)

 CLAIMS. Cross-polarized monolithic antenna, having a substantially rectangular reflector (2), radiating cells (1 mounts aligned on said reflector and each formed by two orthogonal dipoles <B> (11 </ B>; 12,32)) and a system power supply unit (20) connecting the two dipoles of said radiating cells to two external power sources each of the dipoles comprising two V-folded flat conductive elements (11A, B; 12A,; 31A, B; 32A, B) arranged in the back each having a central folding limb (13, 33) fixed to the reflector by a first end portion of said limb and two end lateral arms (13, 14) protruding on either side of a second enderminated portion of said branch, the two conductive elements of one of the dipoles of each of the cells being each disposed between those of the other dipole the same cell, characterized in that said supply circuit (20) comp two flat feeder conductor lines (21, 22), mounted facing said reflector (2) and connected to one and the other of said sources respectively, and in that only one first (11A, 12A, 31A); , 32A) of the two conductive elements of each of said dipoles comprises a folded conductive tab (17, 37), having a first end secured to a second end portion of the central branch (13, 33) of said first conductive element, extending to the the interior of the Ve and substantially the I of the central branch of the second conductive element <B> (11 </ B> B, 12B, 32B) of the dipole and having a second end connected to one of said supply lines (21 , 22). 2. Antenna according to claim 1, characterized in that said flat conductive lines (21, 22) are located opposite a rear face of said reflector (2), said cells being mounted on a so-called front face of said reflector. 3. Antenna according to claim 2, characterized in that the lugs (17, 17 ', 37, 37') integral with the first conductive elements of the two dipoles the same radiating cell (1), intersect, without contact between them, in a front part of the cell and have the same orientations as the one and the other of the crossed polarizations (5, 6) of the cell. 4. Antenna according to claim 3, characterized in that the cross polarizations are substantially + and - 45 relative to the vertical respectively. 5. Antenna according to one of claims 1 to 4, characterized in that said tabs (17) pass through said reflector (2) without contact therewith, each by a hole (29) in the reflector, and are each welded on one of said flat conductive lines (21, 22). 6. Antenna according to one of claims 1 to 5, characterized in that the tab 7; 37) is integral with said first conductive element (11A; 32A). 7. Antenna according to one of claims 1 to 6, characterized in that the central branch of each conductive element has at least one terminal tooth (16) on said first end portion thereof, which is engaged in said reflector and is welded to it. 8. Antenna according to one of claims 1 to 6, characterized in that each of said conductive lines have bifurcations T, each has two lateral branches (23, 24) welded to the legs of the first two elements of two consecutive cell dipoles on said reflector, respectively. 9. Antenna according to claim 8, characterized in that each of said conductive lines (21, 22) has a central extension (25) for connecting the conductive line to one of the external sources. 10. Antenna according to claim 1, characterized in that the lug (17) is integral with a front end of the central branch (13) of said first conductive element (1 <B> IA; </ B> 12A). Antenna according to claim 1, characterized in that the central branch (33) of each of said first and second conductive elements (32A-32B) has an axial slot (38, 38B), extending between a rear end and an intermediate portion of said second end portion thereof. 2. Antenna according to claim 11, characterized in that the lug (37) of said first conductive element (32A) is integral with said intermediate portion of said second end portion of the central branch (33) of that and consists of an axial cutting portion of said slot (38) in said branch. 13. Antenna according to one of claims 10 to 12, characterized in that the central branch (13, 33) of each of said first and second conductive elements has an axial flat and two lateral fins folded on the same side of the flat.