FR3082059A1 - ELECTROMAGNETIC ANTENNA SUITABLE FOR OPERATION IN A FREQUENCY BAND - Google Patents

Abstract

The invention relates to an electromagnetic antenna adapted to operate in a frequency band, comprising at least one conductive radiating element (4), characterized in that said radiating element (4) is based on conductive ferrofluid, said ferrofluid comprising colloidal suspensions of ferromagnetic nanoparticles in an ionic solvent.

Description

Electromagnetic antenna adapted to operate in a frequency band

The present invention relates to an electromagnetic antenna adapted to operate in a given frequency band.

The invention is in the field of radio frequency or microwave communications, and finds a particular application in the field of shipborne communications.

In known manner, an antenna is an electric electromagnetic transducer, the performance of which is calculated theoretically as a function of its physical characteristics, using the Maxwell equations. An antenna includes in particular one or more radiating elements, which are conventionally solid conductors, made of metal or another conductor. The antenna operating characteristics are studied in the design phase and include in particular an operating frequency band, antenna gain and antenna diagram.

In general, a compromise must be found between frequency adaptation and radiation.

For example, there are known antennas adapted to operate in a wide frequency band and having isotropic or directional radiation. Such antennas generally have a low antenna gain.

There are also known antennas adapted to operate in a narrow frequency band around a resonant frequency, the gain of which is chosen to be maximum, with a predetermined radiation pattern.

In traditional antennas, once the antenna structure has been chosen, the antenna operating characteristics are fixed and the antenna performance results.

The invention relates in particular to antennas adapted to operate in the frequency domains used in communications, which are the VHF domain (for “Very High Frequency” in English), the UHF domain (for “Ultra High Frequency” in English) typically ranging from 30 MHz to 3 GHz. The object of the invention is to remedy the drawbacks of the prior art, by proposing electromagnetic antennas adapted to operate in a given frequency band, and of which at least one operating characteristic is configurable.

To this end, the invention provides an electromagnetic antenna adapted to operate in a frequency band, comprising at least one conductive radiating element. In this antenna, the radiating element is based on conductive ferrofluid, said ferrofluid comprising colloidal suspensions of ferromagnetic nanoparticles in an ionic solvent.

Advantageously, the use of a radiating element comprising a ferrofluid comprising colloidal suspensions of ferromagnetic nanoparticles makes it possible to produce an antenna with variable geometry without modifying the radiating element or elements. Indeed, such a ferrofluid has electrical conduction properties and includes a magnetic charge, which makes it possible to spatially move the ferrofluid as a function of an applied magnetic field.

The electromagnetic antenna according to the invention may also have one or more of the characteristics below, taken independently or in any technically acceptable combination.

The antenna further comprises at least one magnet adapted to be placed at a given distance from said radiating element and at a given spatial position to form a magnetic field acting on said conductive ferrofluid, said magnetic field making it possible to spatially configure said conductive ferrofluid and to modify at least one operating characteristic of the antenna.

The distance and the spatial position are obtained as a function of said at least one selected antenna operating characteristic.

According to a variant, the antenna comprises two containers of conductive ferrofluid, aligned in a predetermined direction, each container having a connection to an electric generator, and two magnets of the same size placed facing each other in said predetermined direction, forming a elementary dipole.

According to a variant, the antenna comprises a panel of electromagnets adapted to be positioned vis-à-vis the radiating element or elements, said electromagnets being activated or deactivated individually by a control circuit so as to modify at least one characteristic antenna operation.

The operating characteristic includes an operating frequency band, an angle and / or direction of radiation, a radiation pattern, an antenna gain.

According to a variant, the antenna comprises a plurality of said radiating elements spatially arranged according to a predetermined topology.

Ferromagnetic nanoparticles are obtained from an iron oxide.

Iron oxide is a magnetite or maghemite.

According to another aspect, the invention relates to a carrier or a platform comprising at least one wall in which is inserted at least one antenna as briefly described above.

Other characteristics and advantages of the invention will emerge from the description which is given below, for information and in no way limitative, with reference to the appended figures, among which:

- Figure 1 is a schematic representation of an elementary antenna according to a first embodiment of the invention;

- Figure 2 schematically illustrates embodiments of network antennas according to the invention;

- Figure 3 schematically illustrates a first variant form of radiating element according to one embodiment of the invention;

- Figure 4 schematically illustrates a second form variant according to an embodiment of the invention;

FIG. 5 schematically illustrates a second embodiment of an antenna according to the invention comprising a block of electromagnets.

FIG. 1 schematically illustrates an elementary antenna 2 according to an embodiment of the invention and makes it possible to explain the operating principle of such an antenna.

The electromagnetic antenna 2 shown diagrammatically in FIG. 1 is a dipole which performs the function of an electrical-electromagnetic transducer.

The antenna 2 comprises a radiating element 4, formed in the illustrated example of two containers 6 and 8 filled with a conductive ferrofluidic liquid, also called conductive ferrofluid. Each container 6, 8 is adapted to be electrically connected to a generator 10 which supplies an electrical signal adapted to be transformed into an emitted radio frequency signal.

The antenna 2 also comprises two magnets 12, 14, positioned opposite in the example illustrated, and symmetrically with respect to the containers 6, 8 of ferrofluid.

The shape of the containers 6, 8 is variable, and chosen according to a targeted application.

For example, according to one variant, a container 6, 8 is tubular, and according to another variant the or each container has a plate shape of dimensions chosen according to the application.

The containers have any shape inside which the ferrofluid is positioned according to geometric shapes determined by the magnet (s).

According to a variant illustrated schematically in FIG. 3, the ferrofluids of the containers 6 ′, 8 ′ take, under the action of the magnets, a triangular section shape, for example isosceles triangles placed in opposition, that is to say whose vertices joining the equal sides are placed opposite.

According to another variant illustrated schematically in Figure 4, the antenna comprises two radiating elements, placed according to a regular grid, comprising four containers references 6a, 6b, 6c, 6d. In this case, the antenna has four input connections.

Preferably, each container is made of glass. It is understood that this example is not limiting, other materials being usable.

Each magnet is placed at a given distance d from the corresponding container, the distance d being calculated to obtain a given antenna operating characteristic.

Indeed, the magnets 12, 14 form a magnetic field H, lines of these magnetic fields being schematically illustrated in the example by dashed lines.

The ferrofluidic material used to form the radiating antenna element has the property of deforming as a function of the direction of the field lines of the applied magnetic field.

Preferably, the magnets 12, 14 are chosen to generate a quasi-stationary magnetic field on the scale of the signal to be transmitted.

In the presence of the magnets 12, 14, the excitation of the antenna 2 by an electrical signal of given frequency, supplied by the generator 10, makes it possible to generate an electric field E, represented diagrammatically in FIG. 1.

Thus, the antenna 2 functions as a VHF or UHF electromagnetic antenna depending on the frequency chosen.

In ferrofluid, the magnetic field and the electric field are substantially collinear and therefore have a weak interaction.

Outside the ferrofluid, the magnetic and electric fields are coupled, their interaction defining a pointing direction of the antenna. Thus, the pointing direction of the antenna depends in particular on the shape of the magnetic field applied. The positioning of the magnet (s) makes it possible to control the shape and intensity of the applied magnetic field, and therefore the pointing direction of the antenna as well as other operating characteristics of the antenna, which are therefore configurable.

For example, in the embodiment illustrated in FIG. 1, a directive antenna is obtained which is suitable for transmitting or receiving radiofrequency signals in a direction parallel to the axis Z shown.

Advantageously, the ferrofluid used comprises colloidal suspensions of ferromagnetic nanoparticles in a solvent, which is preferably an ionic liquid.

Generally the ferrofluids are produced on the basis of organic solvents, therefore non-polar (non-conductors) of which there are several examples ENIM for 1-ethyl-3methylimidazolium, BNIM, etc.) in the literature.

Conversely, ionic liquids are also called "liquid salts". Indeed, these are ionic complexes (binary, even tertiary), just like table salt NaCI, generally in the liquid state at temperature and atmospheric pressure. The purely ionic nature of this type of liquid gives it very specific properties, such as being conductive for the production of a ferrofluid.

Preferably, the ferromagnetic nanoparticles are particles of an iron oxide, in particular magnetite or maghemite.

The loading rate of ferromagnetic nanoparticles has an effect on the viscosity of the ferrofluid liquid. Preferably, the charge rate of nanoparticles is between 1 to 10%.

Preferably, the ferromagnetic nanoparticles have dimensions of the order of a nanometer.

It is clear from the above description that the use of radiating elements based on ferrofluid with colloidal suspensions of ferromagnetic nanoparticles, in particular in an ionic liquid, makes it possible to obtain antennas whose operating characteristics are configurable a posteriori depending on the shape and intensity of the magnetic field applied.

In particular, the spatial displacement of the ferrofluid under the action of the magnetic field makes it possible to modify the spatial geometry of the antenna, and therefore its operating diagram, the angle and the pointing direction.

An antenna thus obtained is qualified as an antenna with variable or agile geometry.

Variable geometry is understood here to mean geometry which varies during use. Indeed, it is possible to vary the magnetic field applied over time by moving the applied magnet (s), and therefore to vary over time the operating diagram, the angle and the pointing direction of l 'antenna.

The term “agile geometry” is understood here to mean a geometry which is chosen according to an application of the antenna, and which is then frozen during the application. Thus, from the same radiating elements, different antenna geometries are obtained in an agile manner thanks to a fixed positioning of the magnets for a given application, but modifiable between two applications.

The modification of the magnetic field applied is notably modified by the number or the power of the magnets, and the spatial position of each of the magnets relative to the ferrofluid containers forming the radiating element of the antenna.

In one embodiment, illustrated diagrammatically in FIG. 2, provision is made to associate several elementary antennas 2 according to a predetermined topology to configure various operating characteristics of the antenna.

An elementary antenna 2 has a variable central operating frequency, included in a given operating frequency band.

A plurality of elementary antennas 2 can be associated according to a first network arrangement 20 making it possible to obtain a network antenna operating in transmission at a frequency F1, or according to a second network arrangement 22, comprising a second network of antennas 24 adapted to operate in transmission at frequency F1 and an antenna 26 adapted to operate in reception at frequency F2.

The frequencies F1 and F2 are different, chosen according to the intended application 15.

Alternatively, the magnets used are electromagnets, and the antennas are controlled depending on the activation or non-activation of each of the electromagnets.

Of course, many variations in terms of network layout and topology are possible.

FIG. 5 schematically illustrates a second embodiment of an antenna according to the invention, in which the antenna 50 comprises a plane 28 comprising one or more radiating elements 40, for example arranged in an array, having a chosen shape. For example, the radiating elements 40 have a triangular shape as described above with reference to FIG. 3. The antenna 50 also includes a source 34 of electrical signal adapted to be transformed into radiofrequency signal emitted.

The antenna 50 further comprises a slab or block 30 of electromagnets 32, intended to be placed opposite the plane 28 of the radiating elements for the antenna to operate.

For example, the electromagnets 32 are arranged according to a regular grid, and each electromagnet 32 can be activated individually.

For example, the electromagnets 32 are of the same size and the same power.

The antenna 50 also includes an electrical circuit 36, shown diagrammatically in FIG. 5, for controlling the electromagnets.

Depending on the subset of electromagnets activated or not, it is possible to control the antenna geometry, and therefore to vary the operating diagram, the angle and the pointing direction of the antenna.

This second embodiment makes it possible to obtain an antenna with agile or variable geometry.

In a particular advantageous embodiment, it is envisaged to integrate elementary antennas 2 as described above in a wall of a platform, for example a ship, in order to achieve a functionality of communication antenna integrated directly into the platform.

Of course, the application of the invention is not limited to ships, and is more generally applied in other communication systems on board mobile platforms or not. In particular, the invention applies to mobile platforms (vehicles) but also fixed platforms.

Advantageously, for a ship, the communication function is integrated directly into a wall, which reduces the bulk due to the traditional antennas carried by masts or yards.

Advantageously, the invention makes it possible to produce antennas whose operating characteristics, including the operating frequency band, the antenna gain, pointing angle / direction, radiation pattern, are adjustable as a function of an applied magnetic field. on the radiating element.

Claims (10)

1. -An electromagnetic antenna adapted to operate in a frequency band, comprising at least one conductive radiating element, characterized in that said radiating element (4, 40) is based on conductive ferrofluid, said conductive ferrofluid comprising colloidal suspensions of nanoparticles ferromagnetic in an ionic solvent. 2, - Antenna according to claim 1, further comprising at least one magnet (12, 14, 32) adapted to be placed at a given distance from said radiating element and at a given spatial position to form a magnetic field (H) acting on said conductive ferrofluid, said magnetic field making it possible to spatially configure said conductive ferrofluid and to modify at least one operating characteristic of the antenna. 3, - Antenna according to claim 2, wherein said distance and said spatial position are obtained as a function of said at least one selected antenna operating characteristic. 4, - Antenna according to any one of claims 2 or 3, comprising two containers (6, 8) of conductive ferrofluid, aligned in a predetermined direction, each container comprising a connection to an electric generator (10), and two magnets ( 12, 14) of the same size placed facing each other in said predetermined direction, forming an elementary dipole. 5. - Antenna according to claim 1, comprising a panel (30) of electromagnets (32) adapted to be positioned opposite the radiating element or elements (40), said electromagnets (32) being individually activatable or deactivable by a servo circuit (36) so as to modify at least one antenna operating characteristic. 6. - Antenna according to one of claims 2 to 5, in which said operating characteristic comprises an operating frequency band, an angle and / or a direction of radiation, a radiation diagram, an antenna gain. 7, - Antenna according to one of claims 1 to 6, comprising a plurality of said radiating elements spatially arranged according to a predetermined topology. 8, - Antenna according to one of claims 1 to 7, in which the ferromagnetic nanoparticles 5 are obtained from an iron oxide. 9, - An antenna according to claim 8, wherein said iron oxide is a magnetite or a maghemite. 10 10.- Platform comprising at least one wall in which is inserted at least one antenna according to one of claims 1 to 9.