ES2523347T3 - Multi-layer antenna configuration - Google Patents

Abstract

Multilayer antenna of planar construction type, including a patch antenna A, preferably excluding an inverted F antenna, with several surfaces and/or layers arranged with or without lateral offset relative to each other along an axis in the direction axial (Z), with the following characteristics: - an electrically conductive ground surface (3) is provided, - a conductive radiating surface (7) is provided, arranged offset in the direction of the axis in the axial direction (Z) with respect to to the ground surface (3) and preferably running parallel thereto, - a dielectric support (5) is provided, arranged between the ground surface (3) and the radiating surface (7), at least along of part of the height and/or a partial area, possibly close to the air, - the radiating surface (7) is electrically connected to an electrically conductive supply line (9), - on the side of the radiating surface radiation (7) opposite to a dielectric support device (19) is provided on the ground surface (3), - on the face of the dielectric support device (19) opposite the radiation surface (7), an electrically conductive parasitic patch configuration (13) is provided - the support device (13) has a thickness or height (17) less than the thickness or height (114) of the parasitic patch configuration (13), - the parasitic patch configuration (13) is box-shaped or similar to a box and/or includes, at least by segments, elevations, edge, rib or wall segments (53b) that go around and extend transversely from a base or central segment (53") of the parasitic patch configuration ( 13), precisely moving away from the radiation surface (7), characterized by the following additional features: - above the base or central segment (53") of the parasitic patch configuration (13) another patch antenna (B) is provided with a di support (105) and a radiating surface (107), the radiating surface (107) being provided on the upper face (105a) of the dielectric support (105) opposite the base or central segment (53"), and - the another patch antenna (B) has a ground surface (103) lying on the lower face (105b) of its dielectric support (105) and is inserted at least in part in the parasitic patch configuration (13) shaped like a box or box-like or box-like or box-like parasitic patch configuration (13) is configured as an electrically conductive surface (253d) on the underside (105b) and at least in partial areas on the edge that goes around or on the outer surfaces (105d) of the dielectric support (105) of the other patch antenna (B), - for the patch antenna (A) a connection with a feed line (9) is provided that leads to the surface of radiation (7) of the patch antenna (A) and a ground connection that is connected to the ground surface (3) of the patch antenna (A), - for the other patch antenna (A) another connection is provided with another feed line (109) leading to the radiation surface (107) of the another patch antenna (B) and another ground connection that is also connected to the ground surface (3) of the patch antenna (A).

Description

DESCRIPTION

Multi-layer antenna configuration.

The invention relates to a configuration of multilayer antennas in particular according to the planar constructive type, 5 according to the preamble of claim 1.

A multi-layer type antenna has been disclosed by DE 10 2006 027 694 B3.

The multilayer antenna known by this prior publication of the planar constructive type includes an electrically conductive mass surface 10, a conductive radiation surface (arranged at a certain distance parallel to the mass surface), as well as a dielectric support, provided between the mass surface and radiation surface as a sandwich. A support device is provided above the radiation surface, on which an electrically conductive patch element is positioned. The support device for the patch element has a thickness or height less than the thickness or height of the patch element. fifteen

The patch element itself can be configured as a volume body, that is, as a solid material. It is also possible that the patch element is composed of a metal plate or a metal plate, provided for example by cutting or stamping ribs, edges or the like that go around and run away from the dielectric support. twenty

Such an antenna is especially suitable as an antenna for motor vehicles, for example also for SDARS services. In addition, one such patch antenna may be arranged next to other antenna transmitters for other services on a common socket configuration.

 25

Such a configuration of antennas with several antennas, which are found under a common bell, is known for example from EP 1 616 367 B1.

According to the previous publication cited above, a multifunction antenna is known, which has a socket, on which four different antennas are disposed, decayed from one another in the longitudinal direction and covered by a bell covering all the antennas. This is just an example of an antenna configuration in which four different antennas are used. But in many cases, on the contrary, antenna configurations are also needed, which require, for example, only a set of antennas for the SDARS service and, for example, another patch antenna to find out the location, that is, an antenna that is often also referred to as an antenna. GPS, regardless of what principle they are based on and / or which operator makes such 35 systems available (the so-called GPS location system, the Galileo system, etc.) is known.

An improved patch antenna and superior to previous antennas, in particular to receive SDARS or comparable services via satellite and / or in parallel thereto also services emitted by land, has been disclosed by DE 10 2006 027 694 B3 type creator cited at the beginning. 40

The configurations of patch antennas with several radiation surfaces arranged one above the other are also known. In this regard, a patch surface is usually arranged on the other, in each case interposing a substrate. Thus, antennas working in different frequency bands can also be made. Such antenna configurations are to be considered known, for example by documents DE 10 2004 035 064 45 A1, US 7,253,770 B2, US 6,850,191 B1 or by prior publication Pigaglio, O.; Raveu, N .; Pascal, O., ”Design of multi-frequency band Circularly Polarized Stacked Microstrip patch Antenna” (ICE International Symposium Antennas and Propagation Society, 5-11 July 2008) , DOI 10.1109 / APS.2008.4619109, being arranged for example in the "Stacked Patch Antenna" last cited one above the other several plate-shaped substrate planes with 50 conductive patch surfaces configured thereon.

From US 2008/0218418 A1, for example, a configuration of carcass-shaped antennas with a conductive outer housing, internally filled with substrate and provided on the upper face of a parasitic patch, has been known. An actively operated patch surface 55 housed in the substrate is provided under this parasitic patch, and may be configured between this active patch and the parasitic patch provided on the upper face of the substrate, if necessary, another interleaved patch surface.

That the configurations of antennas with an active patch and a parasitic patch found above are basically known, also in connection with the connection of a so-called "Horn" (horn), results for example from the other 60 previous publication Nasimuddin; Esselle, K.P .; Verma, A.K .; "Wideband High-Gain Circularly Polarized Stacked Microstrip Antennas With an Optimized C-Type Feed and a Short Horn." Feb. 2008, vol. 56, No. 2,578-581.

Regardless of these known executions, it can and should be noted, however, that from document DE 10 2006 027 694 B3, creator of type and already mentioned at the beginning, a patch antenna (patch) basically improved and superior to previous antennas is known, in particular to receive SDARS or similar services via satellite and / or in parallel thereon also services issued by land.

 5

If such a patch antenna must be used, for example, with another patch antenna provided for the GPS service, then it is basically a structure such as that which can be seen in Figure 1 in schematic representation in vertical section.

Figure 1 shows an antenna with a socket S indicated only schematically in Figure 1, located below 10 and usually electrically conductive, which is covered by a bell H permeable to electromagnetic radiation, with which the antennas are protected found inside the bell H.

In schematic sectional representation there is shown an improved multilayer antenna A, which has a structure known for example by document DE 10 2006 027 694 B3 cited at the beginning, corresponding to document WO 2007/144104 A1.

Additionally, a second antenna B, which is a usual patch antenna, is provided in the antenna configuration simplified in Figure 1 in horizontal vertical section, usually when mounted on a vehicle in the front in the direction of travel. which includes a surface of mass M located below 20 and vertically spaced thereon an active patch surface R and intercalated a dielectric substrate D. This patch antenna is fed, as is known, by a power line L, which leads to through a hole from below through the surface of mass M and the substrate D to the patch surface R and there it is connected to the patch surface R. The substrate D is preferably composed here of ceramic, a substance with a high dielectric constant . 25

It is now the task of the present invention to improve such a configuration of antennas, where appropriate as a basic type using other antennas for other services (for example mobile phone services in various frequency ranges, etc.).

 30

The task is solved within the framework of the invention according to the characteristics indicated in claim 1. Advantageous configurations of the invention are indicated in the dependent claims.

In the context of the invention, a surprising solution is achieved, in which an antenna configuration comparable to the antenna configuration of Figure 1 is achieved, but of a much more compact structure than that of Example 35 of Figure 1.

Within the framework of the solution corresponding to the invention it is proposed that in the antenna a conductive patch element (passive or parasitic) disposed above the radiation surface of a first or primary patch antenna and distanced from it, that at least by segments it is provided with an edge or wall that goes around 40 and running away from the radiation surface of the antenna A, the additional patch antenna B shown in figure 1 is placed.

In other words, the second or secondary additional patch antenna is set, provided for example for GPS services, on the parasitic patch element configured in the form of a box or similar to a box, arranged with respect to the first mentioned antenna A above the corresponding radiation surface.

The other patch antenna can be inserted in a part of the height in this box-shaped patch element or similar to a box. It can protrude from its upper part beyond the edge that goes around the box-shaped patch element or similar to a first antenna box. fifty

But it is also possible that the edge that goes around, at least in segments, of the parasitic patch element of the first patch antenna ends above the surface of the other patch antenna, thus introducing the additional patch antenna completely into the receptacle of the element patch endowed with an edge that goes around or segments of the edge that go around. 55

The other patch antenna provided in particular for GPS services can then be supported and / or fixed, interposing an insulating layer, on the parasitic patch element in the form of a box or similar to a box of the first patch antenna.

It is also possible that the other patch antenna, provided in particular for GPS services, is not provided with a surface of its own mass, but that the substrate is directly supported on the parasitic patch element in the form of a box or similar to a box of the first patch antenna, whereby the parasitic patch element of the first patch antenna at the same time also constitutes the ground surface of the other patch antenna.

Finally, it has been verified within the framework of the invention that the parasitic patch element, configured by at least 65 segments with a border that goes around or a wall that goes around, can be configured on the part

bottom and / or next to the edge parts that go around the other patch antenna. In this way, the aforementioned patch element in the form of a box or similar to a box is not provided at all as a separate component, that is, it is not fully or partially provided as a separate component, but the corresponding electrically conductive segments of the so-called patch element form of box or similar to a box are configured totally or partially as metallic layers on the corresponding segments of the other antenna 5 patch.

In this case, the parasitic patch element of the primary antenna can be formed totally or partially by a metallic layer on the lower part and / or on the side walls that go around the other patch antenna. These steps can be carried out already during the manufacture of the other patch antenna, precisely similar to 10 during the manufacture of the patch antenna itself, when a surface is applied on the substrate of such a patch antenna, lying in the direction of emission electrically conductive patch and on the opposite part an electrically conductive mass surface in the form of metallizations on the upper and lower faces of the patch antenna substrate. In this case, the parasitic additional patch element in the form of a box or similar to a box provided according to the prior art above a radiation surface of a patch antenna 15, as a physically autonomous element, would be deleted.

The aforementioned metallizations on the patch antenna, on its lower face and / or on one or several of the lateral surfaces that go around, do not have to be completely made around, but may have interruptions in the perimeter direction, for example they may have different height in the corner areas, 20 even being able to be galvanically separated from the ground surface below or from the parasitic patch element located below. The aforementioned metallizations on the side surfaces can even reach the top of the other patch antenna, but they must be there galvanically separated from the antenna patch actively fed from the other antenna.

 25

The particular conformation of the other patch antenna, that is, above all the conformation of the substrate, of the lower mass surface, which at the same time can also be the surface of the parasitic patch element of the first patch antenna, as well as of the active patch surface provided on the emitter / receiver side, it does not necessarily have to be square or rectangular. This surface can be configured as a polygon of n sides and even have other different conformations in a regular way with angles. Finally, the side walls of the substrate of the additional patch antenna and / or the side walls or side surfaces there provided at least by segments and extending away from the first patch antenna, necessarily parallel to the direction, must not be configured. axial of the patch antenna (that is, perpendicular to the various mass and / or patch surfaces), but may have rounded edges, angled edges, etc. In this regard there are no limitations. 35

With respect to the solution described based on Figure 1 and already known by the state of the art, a clear reduction of the space requirements for the combination of antennas corresponding to the invention can be achieved within the framework of the invention. The small overall size is important especially in antenna systems for the roof of vehicles, which have a critical design, in which due to the design indications prescribed by the vehicle manufacturer for the configuration of the outer envelope of the antenna, usually only a small space is available.

In this regard it is even more surprising that the electrical characteristics of the corresponding antenna for motor vehicles, already good in themselves, according to the document DE 10 2006 027 694 B3 already known not only continue to be maintained, but can even be improved and this despite having reduced the necessary construction space. This is not evident, since another antenna is inserted in the intended patch element. This is also all the more surprising because this antenna system must be suitable to receive SDARS services and the corresponding antenna designs to receive these services must be evaluated very critically since the antennas do not have the corresponding good reception characteristics desired. fifty

The characteristics of the upper GPS antenna are not negatively influenced in the context of the invention. This is also surprising. Furthermore, in the context of the invention, the upper GPS antenna can also be configured larger, that is, even as large as the SDARS patch surface below. This is another essential difference from the state of the art, since here always the upper patch antenna 55 was and always had to be smaller than the lower one. By increasing the GPS patch antenna, a clear improvement in the reception of this service is also ensured. In the context of the invention, a preferred embodiment is even possible in which the upper patch antenna and / or the upper dielectric support is larger than the SDARS patch below. This ultimately results in even an improvement in the characteristics of the SDARS patch. 60

In addition, a complete antenna with two patch transmitters can be made within the framework of the invention, which are completely assembled in a previous stage and then can be mounted as a unit on an antenna chassis or on a socket antenna This has clear advantages over the manufacturing sequence when a traditional antenna configuration is generated according to the state of the art (as described based on Figure 1).

The invention will be described in more detail below on the basis of drawings. In this regard they show in detail:

Figure 1: a schematic representation in section through an antenna such as that which can be mounted in particular on the roof of a motor vehicle, using a first patch antenna known from the prior art and another patch antenna seated next to the previous for other services;

Figure 2: a sectional representation through an antenna configuration corresponding to the invention using a first (primary) and a second (secondary) patch antenna;

 10

Figure 3: a schematic plan view on the exemplary embodiment of Figure 2 further representing the essential components of the first patch antenna that are under an upper patch element (parasite);

Figure 4: a schematic spatial representation of the configuration of patch antennas 15 corresponding to the invention with both individual patch antennas;

Figure 5: a representation corresponding to that of Figure 4, but without the second patch antenna;

Figure 6: a sectional representation comparable to the sectional representation of Figure 2 relative to a different exemplary embodiment;

Figure 7: another sectional representation comparable to the representations of Figures 2 or 6 relating to a different exemplary embodiment;

 25

Figure 8: a spatial representation of the antenna configuration corresponding to the invention with both patch antennas relative to the antenna shown in Figure 7 in vertical section;

Figure 9: another modification related to the configuration of patch antennas corresponding to the invention represented spatially in Figure 8; 30

figure 10: another modification with respect to figure 9 in spatial representation;

Figure 11: an example of a multilayer antenna of planar constructive type, in which it is basically shown that an antenna is also possible in which metallic layers 35 are provided on the dielectric support, which by means of a separation segment are separated from a metallized layer configured in the lower part of the dielectric support;

Figure 12: another different execution in particular from the example of execution shown in Figure 8 in spatial representation; 40

Figure 13: another example of different execution in section representation to show different sections of the substrate for the other patch antenna;

Figure 14: a particular example of execution different from those of Figure 4 and / or Figure 8, in which the parasitic patch configuration is configured in part as a box or similar to a box and partly layers are configured metallized (electrically conductive) for example in the perimeter and / or side walls of the other patch antenna; Y

Figure 15: another example of a different embodiment, in which the electrically conductive patch element in the shape of a box or similar to a box has been removed for example in two opposite areas of the corners, even when the other patch antenna protrudes in these areas of the corners beyond the parasitic patch element.

Next, we will first refer to the exemplary embodiment of Figures 2 to 5, in which a patch antenna is shown that has surfaces and layers arranged one above the other along an axis in the axial direction Z. One such patch element It is basically known from document DE 10 2006 027 694 B3, to the content whose publication we refer to in its entirety. Of course, no additional patch antenna is known to the patch element known from DE 10 2006 027 694 B3.

 60

In the schematic sectional representation of Figure 2 it can be seen that the patch antenna A presents in its so-called bottom or assembly part 1 an electrically conductive ground surface 3. A dielectric support 5 is arranged on the surface of mass 3 or with lateral offset thereon, which usually has an outer perimeter 5 'in plan view corresponding to the outer perimeter 3' of the mass surface 3. This dielectric support 5 it may nevertheless have larger or smaller dimensions and / or be provided with an outer perimeter 65 'different from the outer perimeter 3' of the mass surface 3. In general it may be the outer perimeter 3 '

of the surface of mass a polygon of n sides and / or even be provided with curved segments or be configured curved, even when this is unusual.

The dielectric support 5 with its upper face 5a and its lower face 5b has a sufficient height or thickness, which is generally a multiple of the mass surface thickness 3. Contrary to the mass surface 3, which is more or less 5 It is composed only of a two-dimensional surface, therefore dielectric support 5 is dimensioned as a three-dimensional body with sufficient height and thickness.

Unlike the dielectric body 5, a dielectric of another type or a dielectric structure of another type may also be provided, also using air or with an air layer next to another dielectric body. When air is used as a dielectric, the corresponding support equipment must of course be provided, for example, with pillars, bolts, columns, etc., in order to be able to support and hold the other parts of the patch antenna that are located above and which will be described continuation.

On the upper face 5a opposite the lower face 5b, an electrically conductive radiation surface 7 7 is configured, which again can approximately be understood as a two-dimensional surface. This radiation surface 7 is electrically powered and activated through a power line 9, which preferably runs in the transverse direction, in particular perpendicular to the radiation surface 7 from below through the socket (chassis) S, the surface of mass 3 and through the dielectric support 5 in the corresponding hole or the corresponding channel 5c. twenty

From a connection point 11 generally located below, to which a coaxial cable not shown in more detail can be connected, the inner conductor of the coaxial cable not shown is connected with the power line 9 electrogalvanically and therefore with the surface of radiation 7. The outer conductor of the coaxial cable not shown is electrogalvanically connected to the ground surface 3 below. Instead of the connected coaxial line, a micro tape line can also be used and connected accordingly.

In the exemplary embodiment of Figure 2 et seq., A patch antenna having a dielectric 5 and a square planar shape is described. This shape or the corresponding perimeter or contour line 5 ’may however also have a different shape than the square and generally have a polygonal shape with n sides. Even when it is unusual, curved outer limits may even be provided.

The radiation surface 7 that sits on the dielectric 5 can have the same perimeter or contour line 7 ’as the dielectric 5 below. In the exemplary embodiment shown, the basic shape of the contour line 5 'of the dielectric 5 is also adapted and configured squarely, but it has two flat corners 7 ”opposite (only shown in the plan view of Figure 3) , formed practically eliminating a right triangle of equal sides. Therefore, in general, the contour line 7 ’can also represent a contour line or polygonal perimeter of n sides or even be provided with an outer boundary 7’ curve. 40

The aforementioned mass surface 3, as well as the radiation surface 7, is partly referred to as a "two-dimensional" surface, since its thickness is so small that it cannot be called "body with volume". The thickness of the mass surface 3 and the radiation surface 7 is usually below 1 mm, that is, generally below 0.5 mm, in particular below 0.25 mm, 0, 20 mm, 0.10 45 mm.

The patch antenna described so far can be composed, for example, of a commercial patch antenna, preferably a so-called ceramic patch antenna with a dielectric support layer 5 of a ceramic material. According to the more detailed description it turns out that by going beyond the patch antenna described up to 50 now, a patch antenna is also configured in the form of a stacked patch antenna A, in which above the upper radiation surface 7 ( preferably perpendicular to the radiation surface 7 at a certain distance from the same one laid parallel to each other) a parasitic patch element 13 is additionally provided. This parasitic patch element 13 is configured such that it presents contrary to said mass surface 3 and the surface of radiation 7, a three-dimensional structure, that is, of greater height or thickness than surface 55 of mass 3 or radiation surface 7.

Preferably a support equipment 19 (in particular a dielectric support equipment) with a thickness or height 17 is used by which the parasitic patch element 13 is held and supported. This dielectric support equipment 19 is preferably composed of a layer of adhesion or mounting 19 ', which for example can be configured as the so-called adhesion and mounting layer 19' with adhesion on both sides. For this, adhesive tapes can be used that glue on both sides customary in the trade or adhesive foam tapes on both sides, adhesive pads or the like, which have the corresponding thickness indicated above. This opens up the simple possibility of fixing and mounting said patch element 13 on top of a commercially available patch antenna, in particular of a commercially available ceramic patch antenna. 65

The stacked patch antenna A thus described is positioned on a chassis S indicated in figure 2 only as a line, that is, on a socket that is also complementaryly indicated with reference 20. This socket can be for example the base chassis 20 for an antenna of a motor vehicle, on which the antenna corresponding to the invention can be housed, if necessary together with other antennas for other services. The stacked patch antenna A corresponding to the invention can be used for example in particular as an antenna for receiving satellite or terrestrial signals 5, for example from the so-called SDARS service. However, there are no limitations for use also for other services.

The patch element 13 may be composed, for example, of an electrically conductive metal body, open upwards, in the form of a box with the corresponding longitudinal and transverse extension and with a sufficient height 10.

As can be seen in the spatial representation of Figures 4 and 5, this patch element 13 may have a rectangular or square structure with the corresponding contour 53 ’, without being limited to this conformation. Figure 4 shows in this regard the upper patch element 13 in plan view with rectangular or square shape 15, including the edges or walls that go around, which will be discussed below. In the plan view of Figure 3 it is indicated that the parasitic patch element can also have a different conformation, for example a polygonal shape with n sides. In this regard, it is shown in FIG. 3 that the patch element 13 can be provided, for example, in two opposite angles of flattening 13 ", which for example are adjacent to the flattening 7" of the corresponding emitting surface 7 which is located above 20 to patch antenna A.

In the exemplary embodiment shown, the patch element 13 has a longitudinal extension and a transverse tension that on the one hand is greater than the longitudinal and transverse extension of the radiation surface 7 and / or on the other hand is also greater than the longitudinal extension and cross section of the dielectric support 5 and / or of the mass surface 3 below.

As can be seen in the figures, it includes the parasitic patch element that sits on the support device 19 or is fixed thereto, configured as a box open upwards, a base or central surface 53 ", which in the exemplary embodiment shown is provided with an edge that goes around or a rib that goes around 53d (in general therefore the corresponding over lift 53d), which rises from the plane of the base surface 53 "also parallel to the mass surface transversely, in particular perpendicularly. Such a patch element 13 can be manufactured, for example, by cutting and bending from an electrically conductive metal sheet, the ribs that go around 53d can be joined at the corners of each other electrogalvanically for example by welding (recesses can also be provided in the segment 35). central 53 ”, in which we will not go into more detail below).

Above this secondary patch element 13 is - as shown in the other figures - a second patch antenna B. The dimensioning of the second patch antenna B is in terms of its length and width such that its dimensions are for example at less slightly less than the free internal longitudinal and transverse extension 40 between the ribs 53d that go around the parasitic patch element 13. This precisely opens up the possibility that the patch antenna B can be introduced to a different extent in the interior space 53a of the patch element 13 In other words, the lowest level arrives, that is, the delimitation plane 101 lower than the interior space 53a of the parasitic patch element 13, that is, below the upper delimitation plane 53c, predetermined by the upper edge that goes around the nerves, edges or outer walls 53d of patch 45 parasite.

The second patch antenna B also includes a substrate (dielectric body) 105 with an upper face 105a and a lower face 105b, being configured lying in the direction of transmission / reception (ie, opposite the patch antenna A) the active radiation surface 107 of the second or secondary patch antenna B as an electrically conductive surface 50 on the upper face 105a of the substrate 105 and the corresponding second mass surface 103 of the second patch antenna B provided facing the patch antenna A ( that is, on the lower face 105b).

In the drawings it can be seen that transversely and in particular perpendicular to the surfaces of patch emitters (that is, in the axial direction Z of the complete antenna configuration) another channel or another hole 105c is provided. This channel runs through the chassis 20, through the first or primary patch antenna A (that is, through its mass surface, the dielectric body and the radiation surface lying above), through the support device 19 which follows next, as well as the parasitic patch element 13, through a support layer which, if necessary, follows for the second patch antenna B, as well as through the second mass surface 103 belonging to the antenna patch B and through the dielectric support 105 to the second radiation surface 107 lying above, that is, the second radiation surface 107 of the second patch B antenna.

In the lower part of the chassis 20 there is a coaxial connection, whereby the radiation surface 107 is fed through a power line 109 that runs in the channel. The outer conductor of a line of

The coaxial connection is galvanically connected to the connection with the ground surface 3. Also in this exemplary embodiment, a micro-tape (microstrip) connection line can naturally be provided instead of a coaxial connection line.

In the exemplary embodiments described so far, the height 115 of the second patch antenna B (including a support surface and / or fixing and / or adhesive layer 111, where appropriate, is located on the lower side of the dough surface 103 contiguous to the upper side of the parasitic patch element 13) is greater than the height 117, that is, greater than the edges 53d that go around the parasitic patch element 13. The patch element can nevertheless also be as tall as the edges 53d that go around the parasitic patch element 13.

 10

Figure 6 shows that the edges 53d that go around the parasitic patch element 13 can be even higher than the height of the second patch antenna B, whereby the second patch antenna B is completely inserted into the interior space 53a of the parasitic patch element 13. Otherwise, it shows Figure 6, contrary to Figure 2, that the longitudinal and transverse extension of the other patch antenna B that runs towards the Z axis is larger dimensioned and can fill the interior space of the element parasite patch 13, at least almost 15 completely.

In the sectioned representation of Figure 7 it is shown that the parasitic patch element 13 (which serves to form the beam of the patch antenna A) is now directly connected with the second patch antenna B. The upper patch element 13, belonging to the antenna First or primary patch A, for example, may be composed of a metallic layer 20 253, formed directly on the surface of the second patch B antenna. The application of this metallic layer can already be carried out during the manufacture of the second patch antenna B, similarly to the corresponding application of the patch surface or the mass surface or the metallization on the upper and lower part of the second antenna B during its manufacture. Thus, the parasitic patch element 13 no longer exists as a physically autonomous element, but is a fixed integral part of the second patch antenna B. 25

In Figures 7 and 8 it can be seen that even the separated lower mass surface 103 of the second patch antenna B has been renounced, whereby the metallized layer 253 on the lower side 105b of the dielectric support 105 as layer 253d replaces the mass surface 103 of the second patch antenna B and / or constitutes the same and at the same time this metallic layer 253 also constitutes the parasitic patch element 13. In this exemplary embodiment the metallic layer 253 is configured, at least in a part of the height, also on the edges 105d that go around, that is, on the outer surfaces 105d of the second patch antenna B and there cover the dielectric support 105. In this regard the lower layer 253b configured next to the dielectric support 105 of the second antenna patch B on the lower side 105b, is galvanically joined, totally or at least by segments, with the metallized layers 253d provided at least part of the height in the sup outer perimeter surfaces. 35

In the representation of Figure 9 it can be seen that the metallizations 253 configured on the outer sides 105d of the second dielectric support 105, that is, in the peripheral direction in the second patch antenna B, do not always have to have the same height. It can be seen that, for example, the metallized layer 253d configured on one of the edges that goes around 105d has recesses 253 ', whereby a metallized layer 40 is left with a lower height and on the contrary on the outer side 105d than in Figure 9 is located on the right on the dielectric support 105 a metallic layer 253d is configured, which reaches the upper side 105a of the substrate 105.

In the variant of Figure 10 it is shown that the metallized layer 253d that goes around does not have to be completely configured around it, but that the different metallized layers 253d may have interruptions 253 "at the edges 105d that go around the dielectric support 5 , configured up to the level of the lower side 105b in the dielectric support 105. These interruptions or recesses 253 "are provided in the variant of Figure 10 in the areas of the substrate corners.

 fifty

Based on Figure 11, it will basically be shown, unlike the other examples, that a planar constructive type antenna can also be made such that the metallized layers 253d configured around in the dielectric support 105 are separated even from the metallized layer 253b configured on the lower side 105a of the dielectric support 105 by means of a separation segment 253e, that is, in this exemplary embodiment they are galvanically separated. In the area of the corners of the substrate, the 55 metallized layers 253d are galvanically joined in this exemplary embodiment.

In the exemplary embodiment of Figure 12 it can be seen that the metallized layers 253 extend not only along the bottom side 105b and the surrounding edge or outer surfaces 105d, but even starting from the outer edge 105d to a certain extent on the upper face 105a of the dielectric support 105, from 60 then at a certain distance from the upper radiation surface 107 of the second patch antenna B, whereby here results a galvanic separation between the radiation surface 107 provided on the upper face 105a of the substrate 105 and metallizations 253. In the embodiment shown, the electrically conductive layer 253a configured on the upper face 105a of the substrate 105 is electroplated with the electrically conductive layers 105d on the outer perimeter of the substrate 105. 65

The sectional representation of Figure 13 shows that neither the dielectric support 105 of the second patch antenna B has to have a rectangular shape (perpendicular to the different radiation surfaces) necessarily, but bevels can be configured 305 on the upper and lower sides or curved elements in the substrate 105. The correspondingly applied metallic layers 253 are configured following the corresponding outer perimeter of the substrate. 5

To complete the picture, let us also mention that the dielectric support 5, the ground surface 3 located below it and the radiation surface 7 that is located in front of the ground surface of the first patch antenna A, as well as the dielectric support 105 of the second patch antenna B and the mass surface 103, if necessary, as well as the corresponding radiation surface 107, 10 do not necessarily have to have a square or rectangular configuration, but with a general polygon character of n sides or may even be provided with curved edge surfaces. In the exemplary embodiments shown, in particular in Figure 3, it can be seen that for example the radiation surface 7 is provided in two areas of the diagonally opposite corners of flattening 7 "(therefore configured in the first patch antenna A) and on the contrary the corresponding flattening 107 "configured in two zones of the 15 correspondingly diagonally opposite corners may also be configured with respect to the surface of the radiator 107 in the second patch antenna B. These two flattening 107" of the second patch antenna B are set at 90 ° with respect to the flattening 107 "of the first patch antenna A. Also even unlike figures 2 and 4, the parasitic patch element can be provided, for example, facing flat" 13 "(as shown in the figure 3). The dielectric supports 5 and / or 20 105 may also be configured with irregular outer perimeters, in particular facing flattening, avoiding the corresponding areas of the corners.

Next we will refer further to another example of execution according to Figure 14, which ultimately reproduces an example of execution that can be described as a combination of the example of execution of Figure 4 25 and that corresponding to Figure 11.

This is so because in the exemplary embodiment of Figure 14 it can be seen that a superior parasitic patch configuration 13 is provided, similar to that described based on Figure 4 and the other exemplary embodiments. However, it also has the other patch antenna B on its outer walls that go around, that is, on its outer perimeter surfaces 105d, metallized segments, that is, metallizations 253d, which extend in this example of execution only by one part of the height (but they can also be configured for the entire height of the other patch antenna B). In the exemplary embodiment shown, the metallizations 253d are extended by a height that exactly in lateral view protrudes at least a part of the height beyond the edge that goes around 13 'of the upper patch configuration 13, but also ends below. This metallization 253d can also present segments of different height throughout the perimeter surface, with interruptions, partly with joints with a metallization configured on the lower side of the other patch B antenna, etc. Nor are there any major limitations here.

Figure 15 shows that, for example, the parasitic patch configuration 13 of which we are talking about can be provided in two areas with opposite corners of flattening, recesses or so-called absences 13 ", as already shown in Figure 3. in plan view and in figure 15 in a three-dimensional reproduction. In other words, in this exemplary embodiment, the edges that go around, the walls or ribs 53d in this area of the corners are also interrupted with the flattening 13 ", the other patch B antenna that is in this element being able to protrude outwards. parasitic patch 13 in the form of a box or similar to a box in these 45 zones of the corners beyond the areas of the openings 13a thus obtained between two segments of the adjacent edge 53d, whereby the edge 105d that goes around is visible the other patch antenna B.

Claims (13)

1. Planar constructive multilayer antenna, which includes a patch antenna (patch) A, preferably excluding an inverted antenna F, with several surfaces and / or layers arranged with or without lateral offset between each other along an axis in axial direction (Z), with the following characteristics: 5 - an electrically conductive mass surface (3) is provided, - a conductive radiation surface (7) is provided, arranged offset in the direction of the axis in the axial direction (Z) with respect to the mass surface (3) and preferably running parallel to it, 10 - a dielectric support (5) is provided, arranged between the mass surface (3) and the radiation surface (7), at least along a part of the height and / or a partial area, if necessary together in the air, - the radiation surface (7) is electrically connected with an electrically conductive power line (9), - a dielectric support device (19) is provided on the face of the radiation surface (7) opposite the mass surface (3), - an electrically conductive patch configuration (13) is provided on the face of the dielectric support device (19) opposite the radiation surface (7), - the support device (13) has a thickness or height (17) less than the thickness or height (114) of the parasitic patch configuration (13), 20 - the parasitic patch configuration (13) is configured as a box or similar to a box and / or includes, at least by segments, over elevations, edge, nerve or wall segments (53b) that go around and extend transversely from a base or central segment (53 ”) of the parasitic patch configuration (13), precisely moving away from the radiation surface (7), characterized by the following additional features: 25 - above the base or central segment (53 ”) of the parasitic patch configuration (13) another patch antenna (B) with a dielectric support (105) and a radiation surface (107) is provided, the surface of which is provided radiation (107) on the upper face (105a) of the dielectric support (105) opposite the base or central segment (53 "), and - the other patch antenna (B) has a mass surface (103) lying on the underside (105b) of its dielectric support (105) and is introduced at least in part in the parasitic patch configuration (13) configured with box shape or similar to a box or the parasitic patch configuration (13) configured as a box or similar to a box is configured as an electrically conductive surface (253d) on the underside (105b) and at least in partial areas in the edge that goes around or on the outer surfaces (105d) of the dielectric support (105) of the other patch antenna (B), 35 - for the patch antenna (A) a connection with a power line (9) is provided that leads to the radiation surface (7) of the patch antenna (A) and a ground connection that is connected to the ground surface (3) of the patch antenna (A), - for the other patch antenna (A) another connection is provided with another power line (109) that leads to the radiation surface (107) of the other patch antenna (B) and another ground connection that is also connected 40 with the ground surface (3) of the patch antenna (A). 2. Antenna according to claim 1, characterized in that the parasitic patch configuration (13) includes elevations, edges and / or ribs (53b) that run transversely away from the base or central segment (53 "), whose height (117) corresponds to 45 to the height (115) of the another patch antenna (B) or is larger. 3. Antenna according to claim 1, characterized in that the parasitic patch configuration (13) includes over-elevations, edges, nerves and / or walls (53b) and / or electrically conductive surfaces (253b) that run transversely away from the base or central segment (53 "), whose height ( 117) corresponds to the height (115) of the other patch antenna (B) or is smaller. 4. Antenna according to one of claims 1 to 3, characterized in that a support layer (111) is provided between the ground surface (103) of the other patch antenna (B) and the core or central segment (53 ") of the parasitic configuration (13), preferably of non-conductive material, in particular in the form of an adhesive layer on both sides. 5. Antenna according to one of claims 1 to 4, characterized in that the dielectric support (105) of the other patch antenna (B) is arranged with its lower face 60 (105b) directly on the upper face of the base or central segment (53 ") of the parasitic patch configuration (13). 6. Antenna according to one of claims 1 to 5, characterized in that the longitudinal extension and / or the transverse extension of the other patch antenna (B) has 65 parallel to the base or central segment (53 ") of the parasitic patch configuration (13) a dimension smaller than the free internal dimension in the longitudinal and transverse direction between the elevations, edges, nerves and / or electrically conductive surfaces (53b) of the parasitic patch configuration (13). 7. Antenna according to one of claims 1 to 6, characterized in that the base or central segment (53 ”) of the parasitic patch configuration (13) is provided as an electrically conductive or metallization layer (253b) directly on the underside of the dielectric support (105) of the other patch antenna (B) ). 8. Antenna according to one of claims 1 to 7, characterized in that the raised, edged, ribs and / or walls (53b) of the parasitic patch configuration 10 (13) are configured as electrically conductive surfaces or metallizations (253d) on the outer surfaces (105d) in the dielectric support (105) of the other patch antenna (B). 9. Antenna according to claim 8, characterized in that the electrically conductive layers or metallizations (253d) configured in the 15 outer perimeter surfaces (105d) of the dielectric support (105) of the other patch antenna (B), extend for a part of the height or for their total height.  10. Antenna according to one of claims 1 to 9, characterized in that on the surface (105a) of the dielectric support (105) of the other patch antenna (B) 20 are provided, separated from the radiation surface (107) provided on the upper face (105a), electrically conductive surfaces or metallizations ( 253a), which are preferably galvanically bonded with electrically conductive surfaces or metallizations (253d) configured on the outer walls (105d) of the dielectric support (105).  25 11. Antenna according to one of claims 1 to 10, characterized in that the radiation surface (7) of the patch antenna (A), the radiation surface (107) of the other patch antenna (B) and / or the dielectric support (105) of the other patch antenna (B), they have flattening (7 ”, 107”, 53 ”) facing each other.  30 12. Antenna according to one of claims 1 to 11, characterized in that the metallization (253d) configured at least in partial areas of the edge or outer surfaces (105) of the other patch antenna (B), when viewed laterally parallel to the mass surface (3), exceeds the edges or edges (13 ') leaving the surface of mass (3) of the parasitic patch configuration (13) shaped like a box or similar to a box. 35 13. Antenna according to one of claims 1 to 12, characterized in that the parasitic patch configuration (13) in the form of a box or similar to a box is provided with a recess (13a) in one or preferably in at least two areas of the opposite corners, presenting in these areas of the corners the edges that a recess or absence (13a) goes around (53d), the corners of the other patch antenna (B) protruding freely in this area.