FR2918803A1 - Parasitic monopole antenna system i.e. tactical air navigation antenna system, for use in e.g. drone, has conducting rim formed on surface of dielectric layer and electrically connecting one end of one hole with end of another hole - Google Patents

Abstract

The system (30) has conducting holes (33, 34-1-34-3) formed in a dielectric material layer i.e. support matrix (32), where the holes form a metamaterial. The hole (33) forms a part of a central monopole of a folded monopole. The holes (34-1-34-3) are arranged around the hole (33), where each hole (34-1-34-3) has an end that is electrically connected to a ground plane (31) and forms a part of parasitic wires of the folded monopole. A conducting rim (35) is formed on a surface of the dielectric layer and electrically connects another end of the hole (34-1-34-3) with an end of the hole (33).

Description

Antenna system comprising a folded monopole with parasitic multi-strands.

  FIELD OF THE INVENTION The field of the invention is that of antennas, preferably in the range of microwaves (300 MHz to 300 GHz).

  More specifically, the invention relates to an antenna system comprising a ground plane and a folded monopole. The invention has many applications, and especially, but not exclusively, those in which, within the antennal system, the folded monopole is surrounded by nearby parasitic monopoles, each of which may be short circuited or open circuit, to allow the realization of a directional beam in the direction defined by the central monopole axis-parasitic monopole short-circuited. Each parasitic monopole is open or short-circuited for example by means of a suitably polarized PIN diode (or any other active component capable of performing this switching function). This makes it possible to obtain an orientable beam over an angular sector of 360, which corresponds, for example, to a demand expressed for the systems of beacons embedded in tanker aircraft (example of TACAN antennas). The invention is also applicable in the case where the antenna system, comprising the folded monopole (possibly surrounded by parasitic monopoles), is immersed in an artificial metallo dielectric material. Artificial materials combine a dielectric matrix (typically a polymer foam) and metal islands distributed in the dielectric matrix. They are called metamaterials when the metal islands are small in size relative to the wavelength of the signal propagating in the system. They are called photonic crystals or photonic bandgap materials (BIP materials) when the metal islands are distributed periodically or pseudoperiodically, with dimensions comparable to the wavelength of the signal propagating in the system. The notions of metamaterials and BIP materials are discussed for example in the article Metamaterials: evolution or revolution? (17th International Conference Optical Hertzian and dielectric, 3-4 September 2003, D. Lippens) (see in particular paragraph II). The dielectric and magnetic behavior of these artificial materials depends on the dilution and the type of metal islands distributed in the host environment. For metamaterials, it is thus possible to obtain negative effective dielectric constants, negative permeabilities, and consequently quite unusual propagation phenomena such as opposite phase and group velocities, inverted doppler effects, a refractive index. Negative, ... For BIP materials, signal transmission in the periodic or quasi-periodic medium is selectively frequency-selective and thus enables frequency filtering functions, or also allows for spatial filtering. The connections between the different metal islands obviously provide a significant modification of the filtering properties and this can be used to control the properties of the material. This type of connection between metal islands can be implemented by means of active components, for example PIN diodes. In this case, when the PIN diodes are polarized, the set of connected islands then forms a single larger conductive pattern, whose electromagnetic response is naturally very different. 2. Technological background According to the current technique, antennal systems comprising a ground plane and a monopole, simple or folded, are made based on metal structures (solid metal rods) which for reasons of mechanical maintenance are carried out with thicknesses of thick metal (of the order of mm or more). In fact, the necessary thicknesses, which are of the order of skin thickness (a few tens of microns in the VHF-UHF frequency bands), are not sufficient mechanically to produce rigid antennas. More specifically, with the current technique, a folded monopole is made by a folded metal rod, in three parts (cf below), a first end is fed (for example by a coaxial cable) and a second end is electrically connected. to the mass. The folded monopole is U-shaped and comprises the following three parts: a first rectilinear part, called central monopole, which extends from the first end of the metal rod to an intermediate folding part; the intermediate folding part; and a second rectilinear part, called parasitic strand, which extends from the intermediate folding part to the second end of the metal rod. In the above-mentioned particular application where the antenna system comprises parasitic monopoles arranged around the monopole (single or folded), then with the current technique these parasitic monopoles are also made with metal rods. FIG. 1 shows an example of such a known antennal system, comprising a ground plane referenced 1, a central (simple) monopole referenced 2 and parasitic monopoles referenced 31 to 3g. FIG. 2 illustrates a view from above of the antenna system of FIG. 1, as well as the radiation diagram 4 obtained in the case where one of the parasitic monopoles (that referenced 34) is short-circuited, the others being in open circuit . Of course, each parasitic monopole can play the same role, and the beam detaches in the corresponding direction.

  The aforementioned current technique of producing an antenna system comprising a ground plane and a folded monopole has several disadvantages. Firstly, it is not easy mechanically to manufacture such antenna systems, since it is necessary to assemble metal elements of different shapes: three-part form (central and parasitic monopole) for the conventional folded monopole, and rectilinear shape (in one part) for parasitic monopoles, if there are any. Moreover, the central monopole and the parasitic strand, which are the two rectilinear parts of the folded monopole, are metal elements whose positioning relative to each other is decisive for the operation of the folded monopole. If it is desired to use the antennal system in an environment where it undergoes strong vibrations, the folded monopole structure must be reinforced (for example by using larger diameter metal rods to provide greater rigidity), in order to avoid or reduce the relative displacements of the central monopole with respect to the parasitic strand. Similarly, in the case where the antennal system comprises a folded monopole surrounded by parasitic monopoles, the relative displacements between these elements should be avoided or reduced. Indeed, they are close to each other and the coupling phenomena are crucial for the operation of the antenna system, namely in particular the directivity of the rotating beam, the weak rear radiation and the bandwidth. However, as it is realized today, with monopoles which are metallic elements, this type of antennal system is naturally sensitive to the vibrations and this naturally has an impact on the whole of the performances and on the reliability of the antenna system . It should be emphasized that the requirements on the antenna radiation characteristics, their performance and associated complexity have become more important today. This often leads to stricter specifications or demands. This is particularly true for certain embedded antennas (aircraft, drones ...) which must have high performance despite being in a difficult environment (vibrations, thermal shocks, obstacles of carrier structures ...). Yet another disadvantage of the above-mentioned current technique is that the conventional folded monopole (comprising a central monopole and a single parasitic strand) makes it possible to obtain a maximum bandwidth (by the very structure of this conventional folded monopole) that one would like to be able to pass. Also by its structure, comprising a single parasitic strand, the conventional folded monopole does not have good symmetry of revolution.

  Another disadvantage of the aforementioned current technique is that it does not easily immerse a folded monopole (possibly surrounded by parasitic monopoles) in an artificial material (metamaterial or BIP material). 3. Objectives of the invention The invention, in at least one embodiment, is intended in particular to overcome these various disadvantages of the state of the art. More specifically, in at least one embodiment of the invention, one objective is to provide an antenna system comprising a ground plane and a folded monopole, which is simpler to manufacture and less expensive than known antennal systems of the same type. .

  At least one embodiment of the invention also aims to provide such an antenna system to avoid or reduce the relative displacements between them of the constituent elements of the folded monopole (that is to say, as detailed below). after, the relative displacements of the central monopole with respect to the parasitic strands). Another objective of at least one embodiment of the invention is to provide such an antenna system allowing, in the case where it comprises a folded monopole surrounded by parasitic monopoles, to avoid or reduce any relative displacement between these elements. A complementary objective of at least one embodiment of the invention is to provide such an antenna system comprising a folded monopole offering a greater maximum bandwidth than that of the conventional folded monopole.

  Another objective of at least one embodiment of the invention is to provide such an antenna system having a good symmetry of revolution of the radiation pattern. Another objective of at least one embodiment of the invention is to provide such an antenna system for easily immersing a folded monopole (possibly surrounded by parasitic monopoles) in an artificial material (metamaterial or BIP material). 4. DESCRIPTION OF THE INVENTION In a particular embodiment, there is provided an antenna system comprising a ground plane and a folded monopole. This antenna system comprises: a layer of dielectric material; a first conducting hole, made in said layer of dielectric material and coated with a conductive material, said first conducting hole forming at least part of a central monopole included in said folded monopole; a plurality of second conductive holes, disposed around said first hole, made in said layer of dielectric material and coated with a conductive material, a first end of each of said second conductive holes being electrically connected to ground, each of said second conductive holes forming at least a portion of a parasitic strand included in said folded monopole; and a conductive collar formed on one side of said dielectric material layer and electrically connecting a second end of each of said second conductive holes with an end of said first conductive hole. The general principle of the invention is therefore to use a technology of the dielectric matrix type (typically a foam) with metallized holes, such as that widely developed by Advanten, to realize in a simple and inexpensive way an antennal system comprising a monopole folded having several strands. We benefit from all the advantages of this technology, such as: - lightness of antenna systems; - reduction of the amount of metal needed; - Possibility of 2D antennal systems (planar) or 3D (surface curves, multiplans ..), which offers new possibilities in terms of antenna design; improvement of efficiency of planar type antennas (loss of surface wave loss given the small value of the dielectric constant); simultaneously the possibility of increasing the thicknesses of the planar structures (without increasing the losses by surface waves) and thus increasing the bandwidths;

  Furthermore, it should be noted that in the French patent application FR 2 867 617, filed by the company Advanten, it is also proposed to use foam technology with metallized holes, in particular to make a monopole antenna immersed in a network. 3D transverse dipoles (see Figure 14). However, this French patent application is a simple general technological background since it does not address in any way, and therefore does not disclose, the realization of a folded monopole antenna with several strands parasitic. Because the central monopole and stray strands are formed as conductive holes within the support matrix (dielectric material layer), this matrix maintains these elements in perfectly determined positions relative to each other. In other words, the effects of the vibrations are reduced, which results in a suppression or a reduction of the relative displacements between the constituent elements of the folded monopole, and thus a suppression or reduction of the coupling fluctuation effect between these elements and a lack of modification of the impedances. Because the folded monopole comprises at least two stray strands, it offers a greater bandwidth and better symmetry of radiation pattern revolution than the conventional single strand folded monopole. Advantageously, said antenna system comprises at least three second conductive holes. Thus, the more we increase the number of parasitic strand folded strands, the better the performance of the antennal system (bandwidth, rotation symmetry of the radiation pattern). Advantageously, said first conductive hole is surmounted by a metallized plug to which it is electrically connected, said metallized plug forming part of said central monopole. Said conductive flange is in electrical contact with said plug instead of said end of the first conductive hole. In this case, the central monopole includes the first conductive hole and the metallized plug.

  Advantageously, the antenna system comprises a plurality of third conductive holes, arranged around said first and second conductive holes, made in said layer of dielectric material and coated with a conductive material, each of said third conductive holes forming at least a portion of a parasite monopole disposed around said folded monopole.

  Since, like the central monopole and the parasitic strands, the parasitic monopoles are made in the form of conductive holes in the support matrix (layer of dielectric material), this matrix maintains these elements in perfectly determined positions, one by one. compared to others. In other words, the effects of the vibrations are reduced, which results in a suppression or a reduction of the relative displacements between the central monopole, the parasitic strands and the parasitic monopoles, and thus a suppression or a reduction of the effect fluctuation of coupling between these elements and a lack of modification of the impedances. In a particular embodiment, the antenna system comprises: active components, making it possible to connect or not an end of each of the third conductive holes to ground; and means for controlling said active components. Advantageously, the antenna system comprises fourth conductive holes, made in said layer of dielectric material and coated with a conductive material, said fourth conductive holes being of small relevant dimensions with respect to a wavelength of a signal propagating in the layer of dielectric material, the layer of dielectric material and the fourth conductive holes together forming a metamaterial. Thus, the folded monopole (possibly surrounded by parasitic monopoles) is easily immersed in a metamaterial.

  According to an advantageous variant, the antenna system comprises fourth conductive holes, made in said layer of dielectric material and coated with a conductive material, said fourth conductive holes being of relevant dimensions comparable to a wavelength of a propagating signal. in the layer of dielectric material and being distributed periodically or pseudo-periodically, the layer of dielectric material and the fourth conductive holes together forming a photonic bandgap material. Thus, the folded monopole (possibly surrounded by parasitic monopoles) is easily immersed in a BIP material. In a particular embodiment, the antenna system is an antenna system intended to be embedded on a platform which in operation undergoes vibrations. As indicated above, the technique of the invention makes it possible to reduce the effects of the vibrations, which results in a suppression or a reduction of the relative displacements between the elements (central monopole, parasitic strands and possibly parasitic monopoles). It is therefore perfectly suited to the realization of antenna systems intended to be embedded on platforms such as, but not limited to, aircraft, drones, trains, etc. 5. List of Figures Other features and advantages of embodiments of the invention will appear on reading the following description, given by way of indicative and nonlimiting example (not all embodiments of the invention are not limited to the features and advantages of the embodiments described hereinafter), and the accompanying drawings, in which: - Figure 1 shows a perspective view of an example of antenna system according to the prior art; FIG. 2 illustrates a view from above of the antenna system of the prior art shown in FIG. 1, as well as the radiation pattern obtained in the case where one of the parasitic monopoles is short-circuited, the others being in circuit. open; - Figure 3 shows a perspective view of an antenna system according to a particular embodiment of the invention; and FIG. 4 shows a plan view of an antenna system according to an alternative embodiment of the invention. 6. DETAILED DESCRIPTION FIGS. 1 and 2 relate to the prior art and have already been discussed above. FIG. 3 shows an antenna system 30 according to a particular embodiment of the invention, comprising a folded monopole around which a plurality of parasitic monopoles, each of which may be short-circuited or in an open circuit, are arranged. , to allow the realization of a directional beam. More precisely, this antenna system 30 comprises: a ground plane 31; a layer of dielectric material (also called support matrix thereafter) 32. This support matrix is for example made by superposition of dielectric material slices or by association of elementary blocks of dielectric material. The association between slices or elementary blocks is done for example by a set of tenons / mortises or collage. The connections between different parts of the same metallized hole (distributed over several slices or elementary blocks) are for example cylindrical pins made of copper of the same diameter as the cylindrical portions of the metallized hole they connect; - A first conductive hole 33, made in the support matrix 32 and coated with a conductive material. In this example, the first conductive hole is frustoconical in its lower part and cylindrical in its upper part. The core of a supply coaxial (not shown) is for example welded inside the frustoconical metal hole. In the case where the support matrix is made by superposition of dielectric material slices (cf discussion above), the frustoconical portion 33a of the first conductive hole is for example made in the lowest wafer, and the cylindrical portion 33b in the or the slices above. Optionally, the cylindrical portion 33b of the first conductive hole is replaced or supplemented by an additional metallized plug, to obtain the optimal size of the central monopole. The contact between the metal of the plug and the metal of the frustoconical metallized hole ensures the necessary electrical continuity. Alternatively, an electrical connection using a conductive adhesive or a weld on the upper periphery allows better contact. The first conductive hole 33 (optionally supplemented by a plug) forms the central monopole of the folded monopole; second conductive holes (three in this example) 341 to 343, arranged around the first hole 33. They are made in the support matrix 32 and coated with a conductive material. Each has a first end electrically connected to the ground 31. Each second conductive hole forms (alone or possibly supplemented by a metal plug (not shown)) a parasitic strand of the folded monopole; a conductive flange 35 made on one face of the support matrix 32. It electrically connects a second end of each of the second conducting holes 341 to 343 with one end of the first conducting hole (or with the plug if the first conducting hole is surmounted by a cap). Thus, the first conductive hole, the second conductive holes and the conductive flange together form a folded multi-strand monopole (three parasitic strands in this example); third conductive holes 36, arranged around the first conductive hole 33 and the second conducting holes 341 to 343 (that is to say around the folded monopole). They are made in the support matrix 32 and coated with a conductive material. They form a plurality of parasitic monopoles arranged around the folded monopole (see detailed discussion below); active components 37 (for example a PIN diode for each third hole 36), making it possible to connect or not an end of each of the third conductive holes 36 to ground 31; and - means (not shown) for controlling the active components 37. In the example of FIG. 3, there are twelve parasitic monopoles 36 arranged, in a ring 50, around the folded monopole 33 and 341 to 343. It is It is clear that many other configurations can be envisaged. For example, and as illustrated in FIG. 4, the parasitic monopoles may be arranged, around the folded monopole, along several rings (in the example of FIG. 4, two rings 40, 41 each comprising eight parasitic monopoles 381 to 38g, and 391 to 398 respectively). It is possible to have either the same number of parasitic monopoles on each ring, or a different number from one ring to the next. In the case where the crowns comprise the same number of parasitic monopoles, it is possible to provide an alignment of the parasitic monopoles of the different crowns. In this case, the aligned parasitic monopoles will be short-circuited simultaneously, so that there is a cooperative effect of these parasitic monopoles for the realization of a directional beam in the alignment direction (i.e. say the direction defined by the central monopole axis - aligned parasitic monopoles). Thus, in the example of FIG. 4, the parasitic monopoles referenced 381 and 391 are aligned with the central monopole 33, the parasitic monopoles referenced 382 and 392 are aligned with the central monopole 33, ... and so on. The antennal system 30 described above is for example intended to be embedded on a platform (aircraft, drone ...) which in operation undergoes vibrations. The manufacture of this antenna system 30 comprises for example the following steps: - preparation of a block of foam forming a dielectric matrix, for example by machining in parallelepiped form; - drilling holes in the foam block; - Soaking at least a portion of the foam block in a plating bath for depositing the metal on the surface of the holes and at least a portion of the outer surface of the foam block; final cutting of the foam block to remove or partially leave the deposited metal on a part of the outer surface of the foam block, or possibly burn them.

  The soaking step is for example carried out according to the technique described in the French patent application FR 2 780 319, published on December 31, 1999, entitled Foam coating process for the manufacture of antenna elements and of which the text is inserted here by reference. According to one variant, the dipping step corresponds to a conductive resin deposition. Other variants can of course be considered. It is clear that many other embodiments of the invention can be envisaged. In particular, it is possible to immerse the folded monopole (and the parasitic monopoles, if any) in an artificial material. It suffices for that to achieve additional conductive holes (and having special characteristics) in the support matrix. Thus, in the case of an artificial material of the metamaterial type, the antenna system comprises additional conductive holes (not shown) made in the support matrix 32 and coated with a conductive material. They are of low relevant dimensions with respect to a wavelength of a signal propagating in the support matrix.

  In the case of an artificial material of BIP material type, the antenna system comprises additional conductive holes (not shown), made in the support matrix 32 and coated with a conductive material. They are of relevant dimensions comparable to a wavelength of a signal propagating in the support matrix and distributed periodically or pseudo-periodically.

Claims (8)

  Antenna system (30) comprising a ground plane (31) and a folded monopole, characterized in that it comprises: - a layer of dielectric material (32); a first conducting hole (33) made in said layer of dielectric material and coated with a conductive material, said first conducting hole forming at least a portion of a central monopole included in said folded monopole; a plurality of second conductive holes (341 to 343), arranged around said first hole, made in said layer of dielectric material and coated with a conductive material, a first end of each of said second conducting holes being electrically connected to ground, each of said second conductive holes forming at least a portion of a parasitic strand included in said folded monopole; and - a conductive flange (35), made on one side of said layer of dielectric material and electrically connecting a second end of each of said second conductive holes with an end of said first conductive hole.   2. Antenna system according to claim 1, characterized in that it comprises at least three second conductive holes (341 to 343).   3. antennal system according to any one of claims 1 and 2, characterized in that said first conductive hole is surmounted by a metallized plug (33b) to which it is electrically connected, said metallized plug forming part of said central monopole, and that said conductive flange is in electrical contact with said plug instead of said end of the first conductive hole.   4. Antenna system according to any one of claims 1 to 3, characterized in that it comprises a plurality of third conductive holes (36; 38, 388, 391 to 398), arranged around said first and second conductive holes, formed in said layer of dielectric material and coated with a conductive material, each of said third conductive holes forming at least a portion of a parasitic monopole disposed around said folded monopole. 15 2918803   5. Antenna system according to claim 4, characterized in that it comprises - active components (37), for connecting or not one end of each of the third conductive holes to ground; and means for controlling said active components. 5   6. antennal system according to any one of claims 1 to 5, characterized in that it comprises fourth conductive holes, made in said layer of dielectric material and coated with a conductive material, said fourth conductive holes being of relevant dimensions low with respect to a wavelength of a signal propagating in the layer of dielectric material, the layer of dielectric material and the fourth conductive holes together forming a metamaterial.   7. Antenna system according to any one of claims 1 to 5, characterized in that it comprises fourth conductive holes, made in said layer of dielectric material and coated with a conductive material, said fourth conductive holes being of relevant dimensions comparable to a wavelength of a signal propagating in the layer of dielectric material and being distributed periodically or pseudo-periodically, the layer of dielectric material and the fourth conductive holes together forming a photonic bandgap material.   8. antennal system according to any one of claims 1 to 7, characterized in that it is an antenna system intended to be embedded on a platform 20 which in operation undergoes vibration.