FR2963168A1 - PRINTED ANTENNA WITH OPTICALLY TRANSPARENT DIRECT RADIATION OF PREFERENCE - Google Patents

Abstract

The invention relates to a printed antenna comprising: a ground plane (10) consisting of at least one conductive deposit (100); a radiation plane (30) disposed above the ground plane (10), the radiation plane comprising a radiating element (31, 32, 33); characterized in that the radiation plane is constituted by at least one conductive deposit (300) and in that the radiating element is constituted by discontinuities (31, 32, 33) formed in the conductive deposit (300), the discontinuities drawing an annular slot (33) and two brackets (31, 32) flanking said slot (33).

Description

GENERAL TECHNICAL FIELD The invention relates to the field of telecommunications and particularly that of antennas printed for mobile cellular networks.

And the invention more particularly relates to a printed antenna and in particular an optically transparent printed antenna whose ground plane is constituted by an optically transparent conductive deposit, preferably in the form of a grid. The invention is particularly applicable in the context of UMTS 2000 telecommunications (in English, "Universal Mobile Telecommunication Standard 2000").

STATE OF THE ART A printed antenna usually comprises a ground plane, is a radiation plane comprising one or more radiating elements and a dielectric substrate (for example air) interposed between the ground plane and the radiation plane. The radiating element ("patch") usually consists of a conductive square surface printed on the radiation plane and fed by a microstrip line printed on the radiation plane. or on another plane disposed between the ground plane and the radiation plane. However, the use of a square radiating element does not make it possible to adjust the antenna radiation pattern sufficiently for the intended applications.

PRESENTATION OF THE INVENTION An object of the invention is to improve the performance of printed antennas of known type. For this purpose, according to a first aspect, the invention relates to a printed antenna comprising: a ground plane constituted by at least one conductive deposit; a radiation plane disposed above the ground plane, the radiation plane comprising a radiating element; characterized in that the radiation plane is constituted by at least one conductive deposit and in that the radiating element is constituted by discontinuities formed in the conductive deposit, the discontinuities forming an annular slot and two brackets flanking said slot. The antenna of the invention makes it possible, because of the structure of the radiating element, to have a wider band of adaptation frequencies and of the radiation patterns in the horizontal and vertical planes which are tighter with respect to an antenna. classic patch. In addition, the conductive deposit may be such that the antenna is optically transparent. Other aspects of the antenna according to the first aspect of the invention are as follows: it further comprises a feed plane disposed above the ground plane, the feed plane comprising a feed line ; the radiating element is disposed above the feed line, the annular slot and the two brackets being concentric; the supply line is constituted by at least one conductive deposit of a first constant width on a first portion of the line, a second constant width on a second portion of the line, the second portion being in the extension of the first part, and a third constant width on a third part of the line, the third part being in the extension of the second part and is vis-à-vis the radiating element; the junction between the third part and the second part is centered on the portion of the annular slot crossing said junction; the annular slot of the radiating element is connected at two points of the third part of the supply line, each point being respectively disposed at the intersections between the supply line and the annular slot; the annular slot of the radiating element is of generally rectangular shape; the conductive deposition of the ground plane and / or the radiation plane and / or the feed plane is a conductive mesh such that the plane containing said mesh is optically transparent; the sizing of the conductive mesh, where appropriate: o the ground plane varies locally according to the electromagnetic activity of the radiating element placed opposite; and / or the radiation plane locally varies according to its electromagnetic activity; and / or o the feed plane varies locally depending on the electromagnetic activity of the feed line; the ground plane and / or the power plane and / or the radiation plane rest on a transparent or flexible transparent substrate (s), plane (s) ) or curve (s) to fit a conformal surface, the substrate (s) being preferably made of glass; each plane is separated by a dielectric substrate, the dielectric substrate is a gas, preferably air; The discontinuities are formed by removing the conductive deposit so as to draw the parentheses and the annular slots. According to a second aspect, the invention relates to an antenna array comprising a plurality of antennas according to the first aspect of the invention.

In the antenna array according to the second aspect of the invention, the antennas are arranged, on a panel, relative to one another according to at least one tree structure.

PRESENTATION OF THE FIGURES Other features and advantages of the invention will become apparent from the description which follows, which is purely illustrative and not limiting and should be read with reference to the appended figures in which: FIG. 1 illustrates a three-dimensional view of the antenna of the invention; Figure 2 illustrates a side view of the antenna of the invention; FIG. 3 illustrates a view from above of the antenna of the invention; FIG. 4 illustrates a view from above of the radiation plane of the antenna of the invention; FIG. 5 illustrates a top view of the antenna supply plane of the invention; FIG. 6 illustrates a view from above FIG. 7 illustrates a detailed view of the radiating element of the radiation plane of the antenna of the invention; FIGS. 8a, 8b and 8c illustrate the adjustment of the misalignment of the antenna of the invention; FIG. 9 illustrates a diagram of an antenna array comprising several antennas of the invention; Figures 10a and 10b respectively show a top view and a three-dimensional view of a conventional "patch" antenna as known; Figures 11a and 11b illustrate antenna performance of the invention compared to that of a conventional so-called "patch" antenna as known; Figures 12a and 12b illustrate the progressive misalignment of the main lobe of the radiation pattern of the antenna of the invention; Figure 13 illustrates a tri-sectoral arrangement of several antennas of the invention mounted on a base station. In all the figures, similar elements bear identical reference numerals.

DETAILED DESCRIPTION OF THE INVENTION Reference is made hereinafter to FIGS. 1 to 13. By the following description, by "optically transparent" material, is meant a material that is transparent in at least a portion of the field of visible light. allowing at least about 30% of this light to pass, and preferably more than 60% of the light.

General description of the antenna The printed antenna comprises a ground plane 10 consisting of a conductive deposit 100, a radiation plane 30 disposed above the ground plane 10, the radiation plane 30 comprising a radiating element 31, 32 33. It further comprises a feed plane 20 interposed between the ground plane 10 and the radiation plane 30. The feed plane 20 comprises a feed line 21. Each plane 10, 20, 30 is for example a glass substrate with a thickness of between 1 and 5 mm, typically 1.1 mm in size between 300 × 300 and 500 × 500 mm 2, typically 400 × 400 mm 2. The antenna also comprises a dielectric substrate 3 disposed between the ground plane 10 and the feed plane 20 on the one hand and between the feed plane 20 and the radiation plane 30 on the other hand.

The dielectric substrate 3 is, for example, a gas (neutral: nitrogen, argon, etc.), preferably air or a material with low magneto-dielectric constants. The dielectric substrate 3 is, for example, of thickness between 4 and 12 mm, typically 8 mm. Each plane 10, 20, 30 comprises a conductive deposit 100, 200, 300 which according to the plane 10, 20, 30 to which it relates, describes or not a pattern, the assembly consisting of the planes 10, 20, 30 allowing get an antennal function. In order to supply the antenna, a plate 23 comprising a coaxial plug 213 is connected to the supply line 21, this plate 23 also makes it possible to bond the ground and radiation planes 30 to one another. Conductive deposits 100, 200, 300 are advantageously positioned on the upper surface of the ground plane 10 and the feed plane 20 and on the lower surface of the radiation plane 30 so that the deposit 200 of the feed plane 20 and the deposition 300 of the radiation plane 300 are separated by the dielectric substrate 3. In addition, the deposition 100 of the ground plane 10 and the deposition 200 of the feed plane 20 are in turn separated by the thickness of the substrate comprising the 3. Other superpositions are conceivable, in particular the arrangement of the conductive deposits of the ground plane 10 and / or the radiation plane 30 respectively on the lower surface of the plane. n of mass 10 and / or on the upper surface of the radiation plane 30.

Ground plane The ground plane 10 is completely covered with a conductive deposit 100 without or with discontinuities. It is specified that discontinuity is understood to mean a localized or non-localized removal of the material constituting the conductive deposit.

Power Plan The power plan 20 includes a conductive deposit which forms the feed line 21 of the antenna. It is noted that beyond the feed line 21, there is no conductive deposit. More specifically, the supply line 21 is constituted by at least one conductive deposit of a first constant width on a first portion 210 of the line 21, a second constant width on a second portion 211 of the line 21 the second part being in the extension of the first part 210, and a third constant width on a third part 212 of the line 21, the third part being in the extension of the second part 211 and is facing -vis the radiating element. Preferably, the width of the third portion 212 is greater than the width of the second portion 211. In addition, it is possible to adjust the misalignment of the radiation pattern of the antenna by modifying the relative position of the radiating element. along the second and third portions 211, 212 (see below). It is recalled that the misalignment of an antenna for UMTS cellular networks is generally used in the vertical plane of the radiation patterns.

Radiation plane The radiation plane 30 is constituted by a conductive deposit 300. The radiating element consists of discontinuities 31, 32, 33 formed in the conductive material 300, the discontinuities forming an annular slot 33 and two brackets 31, 32 flanking said slot 33. This annular slot structure, in association with the two brackets 32, 33, allows for a wider frequency band adaptation 30 and radiation patterns in the horizontal and vertical planes further tightened by compared to a conventional patch antenna.

Adjustment of the adaptation band is achieved by controlling several parameters, such as, for example, the opening size of the brackets 31 and 32; the spacing between the brackets 31, 32 and the slot 33. In addition, the angular aperture of the half-power horizontal radiation pattern can be controlled by weighting the amplitude of the signal feeding the two points of the annular slot . In addition, the angular misalignment of the main lobe of the horizontal radiation pattern is controlled by the weighting of the phase of the signal supplying the two points of the annular slot. It should be noted that by a simple homothety of the dimensions of the antenna, it is possible to optimize its operation in lower or higher frequency bands. We give here, without limitation, optimized dimensions (see Figure 7) of the antenna including the pattern drawn on the radiation plan for the antenna operates around 2 GHz. The annular slot 33 here takes a simplified square shape with a slot width of 7.5 mm and 58 mm on the outer side, the tips of the rectangular slot being bevelled at 45 ° to a depth corresponding to the width of the slot. The two brackets are two slits 6 mm in width and 86.6 mm in length, in the bevelled form of the annular slot to form 90 ° segments of 10 mm in length. They are spaced from each other also 86.6 mm outside, centered around the annular slot and disposed on one side and the other of the axis of the feed line 212. This line 25 has a length of 55 mm and a width of 27 mm. In the case illustrated in FIGS. 7 and 8b, the annular slot consists of four parts: a lower left part 334, a lower right part 333, a left upper part 331 and a right upper part 332.

The annular slot 33 is centered on an orthonormal reference X, Y taken in the radiation plane. Each portion 331, 332, 333, 334 schematically corresponds to a quadrant of the X, Y mark. Advantageously, as mentioned above, the radiating element 33 can relatively be moved relative to the line 21 to change the misalignment of the radiation pattern of the antenna. FIGS. 8a, 8b and 8c illustrate the positioning of the radiating element with respect to the feed line 21. To clarify this positioning, we consider the point A of junction between the third 212 and second 211 parts as well as in the case where the radiating element is of square shape, the center of symmetry B of the lower right part which is above the second part 211 of the supply line 21 of the antenna. The modification of the misalignment of the antenna is obtained by shifting the point B with respect to the point A along a line which passes through the points A and B, which line is also a longitudinal axis of symmetry of the third part 212.

Conductive Deposits Conductive deposits 100, 200, 300 may be formed in any conductive material, for example copper deposition. The conductive deposits 100, 200, 300 may be optically transparent or not. Indeed, in order to make more discreet or to integrate a printed antenna within glazed surfaces (for example window), an optically transparent antenna is preferred. The optically transparent printed antenna is obtained by using, for the ground, radiation and power planes, transparent dielectric substrates of the glass or plexiglass type.

The optically transparent conductive deposit is, for example, indium oxide doped with tin ITO or with silver-doped tin oxide AgHT deposited on a plastic film (for example a polyester film). To improve the transparency of the optically transparent printed antenna, the conductive deposits can be replaced by a conductive mesh. The mesh used has a number of parameters that influence optical transparency. Note that the sizing of the conductive mesh 100 of the ground plane 10 may vary locally depending on the electromagnetic activity of the radiating element 31, 32, 33. For this purpose, reference may be made to the patent application FR 10/50392. , "An optically transparent printed antenna with a mesh ground plane". As for the ground plane 10, it is also possible to adjust the dimensioning of the mesh of the radiation plane 30 as a function of its local electromagnetic activity. Thus, near the annular slot 33, parentheses slots 31, 32 and above the feed line 21, the mesh is tightened and elsewhere the mesh is released to gain optical transparency without degrading performance radio signals from the antenna. Similarly, the mesh of the feed line 21 will be narrower to ensure its feeding function, the mesh tightening being maximum close to the coaxial plug 213 (sheet or metal layer without any recess). In addition, the meshes of the radiation plane 300 and the ground plane 100 will be gradually released and / or assigned discontinuities in the vicinity of the edges of the antenna to limit the radiation of the rear face (see on this subject the request for patent FR 10/50392). It is specified that the conductive mesh is for example made of iron, nickel, chromium, titanium, tantalum, molybdenum, tin, indium, zinc, tungsten, platinum, manganese, magnesium, lead, preferably silver, copper, gold or aluminum. or metal alloy chosen according to the electrical conductivity. It typically takes the form of a grid whose ratio between the size of the openings of the mesh and the width of the tracks of the mesh defines the level of optical transparency of the ground plane, the feed line of the feed plane and the radiation plan. Of course, it is not limited to the use of a mesh grid, other forms are of course possible (see also FR 10/50392). Here it is specified that the dimensioning of the mesh is characterized by its pitch (or its periodicity), by the width and thickness of the conductive tracks (or by the opening made in the pitch). The conductive deposit can be obtained by various means. The conductive deposit may thus consist of a metallic foil (foil) or of a conductive thin layer deposited on an inorganic transparent substrate (silica, glass, sapphire, etc.) or organic (plexiglass, polymethylpentene, polycarbonate, polyethylene terephthalate, BCB, ...). It should be noted that the use of low loss flexible polymer substrates facilitates the transfer of the antenna onto or into the appropriate supports (window, window, vehicle windshield, etc.). The conductive deposit can be made physically (PVD), for example by spraying, evaporation under vacuum, laser ablation, etc. or by other means, for example chemical deposition (silver plating, copper plating, gilding, aluminide, tin plating, nickel plating, etc.), by screen printing, by electrolytic deposition, by chemical vapor deposition (CVD, PECVD, OMCVD , etc.), etc. The openings of the conductive mesh in the sheet or metal film can be made by standard photolithography from a photomask or mask transferred by laser writing on a reserve and the associated chemical etching, or by tampongraphy followed by etching chemical, or by ion etching through a mask.

The mesh can also be directly produced by screen printing through a screen (in English, "screen printing"), by jet printing of a conductive ink (and annealing associated), by electroforming, by direct writing via decomposition under laser beam of an organometallic, etc.

Of course, we are not limited to the embodiments described here, but we can consider any variant within the scope of the art and particularly the combination of different embodiments described above.

Antenna network By associating several elementary antennas of the type described above, it is possible to constitute a UMTS antenna network, also called UMTS panel. Figure 9 illustrates an example of such a panel. The panel consists of several printed antennas 1 are arranged in one or more trees 51. The panel of Figure 9 comprises sixteen printed antennas 1 arranged on two trees 51 of four levels arranged relative to each other so that the printed antennas are directed towards the center of the panel 50. In this panel 50, for each antenna of the panel, the second portion 211 of the feed line 21 is inclined at 45 ° with respect to the first portion 210 of the line 21, the first portion 210 of the supply line 21 being perpendicular to a longitudinal axis of symmetry of the panel 50. Such an arrangement allows the formation of an array of linear antennas having a main polarization at 45 ° . It is noted that it is possible to create polarization diversity with the association of another network having a main polarization oriented at -45 ° arranged in the same plane and decoupled thanks to a variation in the mesh size as described in FIG. FR application 10/050392.

In this way, we obtain two linear arrays (+ 45 ° and -45 °) forming a polarization diversity panel antenna each powered by a connector 52. Other types of association of elementary antennas of the type described herein text are possible for the purpose of obtaining antenna arrays with specific radiation patterns and for the use of telecommunication systems.

Performance Comparison with a Printed Patch-type Antenna The advantages of a printed antenna as described above (hereinafter ring-slot antenna) compared with a known conventional patch-type antenna are compared here. This conventional "patch" antenna includes a square radiator 90 also derived from the printed technology and often serving as a reference (see Figures 10a and 10b). The square patch 90 is fed by a microstrip line 91. These two elements positioned on a substrate 94 under which there is a ground plane 93. Before describing the performance in detail, it can be noted that thanks to its original geometry, the Annular slot antenna makes it possible to obtain two major properties for its use in panel antennas for cellular networks: a wide bandwidth covering the entire UMTS frequency band (1900-2170 MHz), characterized by a low coefficient of reflection, that is to say less than -10 dB in the whole band; an increased directivity, characterized by an angular aperture of the half-power horizontal radiation diagram close to 65 °. In FIG. 11a, the adaptation levels in dB (S ') as a function of the operating frequency are represented ( GHz).

As known, a radiating element is commonly considered to be adapted to a bandwidth when its reflection coefficient (S ') is less than -10 dB in the whole band and around its central frequency.

The conventional patch is adapted between 1.99 GHz and 2.015 GHz (see curve 102), so its band is 25 MHz, or 1.25% bandwidth. The structure presented here is highly resonant. The annular slot antenna is, in turn, adapted between 1.85 GHz and 2.20 GHz (see curve 101), its band is therefore 350 MHz, or 17.3 0/0 of bandwidth. Thus, as can be seen, the annular slot antenna has an enlarged band, which is achieved through the optimized conjugation of the slot and brackets. The annular slot antenna therefore has the advantage of having a frequency band that is much larger than the conventional patch antenna. FIG. 11b shows the radiation patterns of the conventional patch antenna and the ring slot antenna. It is known that the directivity of an antenna is given by the angular aperture in the desired plane. We are interested here in the horizontal plane, that of the surface coverage of a base station for cellular networks, on which are positioned the antenna-panels in tri-sectoral arrangement. A tri-sectoral arrangement is shown in FIG. 13. This arrangement uses sources having mid-power (-3 dB) apertures at about 65 ° (or about 120 ° -10 dB). To compare the antenna radiation patterns and in particular the angular aperture, we compare the openings corresponding to the levels at -3 dB. FIG. 11b shows the radiation patterns 30 of the conventional patch antenna (curve 112) and the annular slot antenna (curve 111) for an operating frequency at 2 GHz.

It can be seen that the opening at -3 dB is 86 ° for the radiating patch and only 64 ° for the annular slot antenna. Here again, the advantages of the annular slot antenna with respect to the conventional patch antenna have been shown.

Thus, this new structure makes it possible to offer a directivity stronger and in accordance with the needs of the tri-sectoral panel antennas by tightening the opening of the radiation pattern and to operate on a higher frequency band of work, especially in the whole area. UMTS band 1900 - 2170 MHz. i0 Angular Deflection FIG. 12a illustrates the H-plane antenna radiation pattern for three positions of point A with respect to point B and with an operating frequency of 2.17 GHz in the UMTS band. It is noted that the antenna has an identical radiation in the plane E. FIG. 12b illustrates the different positions P1, P2, P3 of the point A relative to the point B in an X, Y coordinate system centered on the radiating element. Point B has the coordinates X = Y = 17.86 mm in the X, Y coordinate as shown in Figure 8b. The position P1 of the point A corresponds to the coordinates X = Y = 20.86 mm, the position P2 of the point A corresponds to the coordinates X = Y = 17.86 mm and the position P3 of the point A corresponds to the coordinates X = Y = 14 , 86 mm. With reference to FIG. 12a, it can be seen that the positioning of the point A at the position P1 (the line is set back relative to the radiating structure) corresponds to a direction of the main lobe in the axis of the radiating source. When point A is under point B (position P2 in FIG. 12b), a misalignment of about 8 ° with respect to position P3 is observed.

When the supply line enters the radiating structure, point A at position P3, the same phenomenon of misalignment of about 16 ° of the main lobe with respect to position P1 is observed. As can be seen, with these different arrangements, it is possible to have a control of the misalignment of the main lobe of the radiation pattern of the transparent radiating source.

Claims (15)

REVENDICATIONS1. A printed antenna comprising: - a ground plane (10) consisting of at least one conductive deposit (100); - a radiation plane (30) disposed above the ground plane (10), the radiation plane comprising a radiating element (31, 32, 33); characterized in that the radiation plane is constituted by at least one conductive deposition (300) and in that the radiating element is constituted by discontinuities (31, 32, 33) formed in the conductive deposit (300), discontinuities forming an annular slot (33) and two brackets (31, 32) flanking said slot (33). 15 2. An antenna according to claim 1 further comprising a feed plane (20) disposed above the ground plane, the feed plane comprising a feed line (21). 3. Antenna according to claim 2 wherein the radiating element 20 is disposed above the feed line, the annular slot (33) and the two brackets (31, 32) being concentric. 4. Antenna according to one of claims 1 to 3 wherein the feed line (21) is constituted by at least one conductive deposit of a first constant width on a first portion (210) of the line (21). a second constant width on a second portion (211) of the line (21), the second portion being an extension of the first portion (210), and a third constant width on a third portion (212) of the line (21), the third portion being in the extension of the second portion (211) and is vis-à-vis the radiating element. 5. Antenna according to claim 4 wherein the junction between the third portion (212) and the second portion (211) is centered on the portion of the annular slot (33) crossing said junction. 6. Antenna according to one of claims 1 to 5 wherein the annular slot of the radiating element is connected at two points of the third portion (212) of the feed line (21), each point being respectively disposed at intersections between the feed line and the annular slot. i0 7. Antenna according to one of claims 1 to 6 wherein the annular slot of the radiating element is generally substantially rectangular shape. 15 8. Antenna according to one of claims 1 to 7 wherein the conductive deposition of the ground plane and / or the radiation plane and / or the power plane is a conductive mesh such that the plane containing said mesh is optically transparent . 20 9. Antenna according to claim 8 wherein the dimensioning of the conductive mesh, where appropriate: - the ground plane varies locally according to the electromagnetic activity of the radiating element placed vis-à-vis; and / or - the radiation plan locally varies according to its electromagnetic activity; and / or - the feed plan varies locally according to the electromagnetic activity of the feed line. 10. Antenna according to one of claims 1 to 9 wherein the ground plane and / or the power plane and / or the radiation plane rests (s) on a (the) substrate (s) transparent (s) ) Rigid (s) or flexible (s), plane (s) or curve (s) to fit a conformal surface, the (s) substrate (s) being preferably glass. 11. Antenna according to one of the preceding claims wherein each plane is separated by a dielectric substrate. Antenna according to claim 11 wherein the dielectric substrate is a gas, preferably air. io 13. Antenna according to one of the preceding claims wherein the discontinuities are formed by removing the conductive deposit so as to draw the parentheses and the annular slots. Antenna array comprising a plurality of antennas according to one of the preceding claims. 15. Antenna array according to claim 14 wherein the antennas are arranged on a panel, relative to each other in at least one tree. 20