CA2800952A1 - Very thin linear orthogonal dual-polarised wide band compact antenna operating in v/uhf bands - Google Patents

Abstract

An antenna (2) for transmitting / receiving electromagnetic waves, of the type comprising two dipoles (16A, 16B) orthogonal to each other, each dipole (16A, 16B) comprising two radiating elements (4), a metal plate (8) , and an absorbent structure (6). The radiating elements (4) are all substantially planar, the two dipoles (16A, 16B) being substantially included in the same plane (P), and the absorbent structure (6) is interposed between the metal plate (8) and the dipoles ( 16A, 16B) and is arranged in contact with the metal plate (8).

Description

Broadband compact antenna with very small thickness and double polarizations Orthogonal Linear Functions Operating in V / UHF Bands The invention relates to a compact broadband antenna with very small thickness and with orthogonal linear double polarizations operating in the V / UHF bands.
More particularly, the invention relates to a transmitting / receiving antenna electromagnetic waves, of the type comprising:
two orthogonal dipoles between them, each dipole comprising two radiating elements, a metal plate, and an absorbent structure.
The invention is in the field of antennas and antenna systems compact broadband. These systems are dedicated to applications of reception and emission of electromagnetic waves in a very wide frequency band.
By For example, the compact antenna according to the invention is intended to operate in the VHF bands and UHF, that is to say at frequencies between 30 MHz and 3 GHz, and more particularly at frequencies between 30 MHz and 500 MHz.
Such antennas are used for various purposes, for example in the field of of the radiocommunications, and are intended in particular to be incorporated in a machine, whether ground, airborne or naval.
Therefore, these antennas are subject to many constraints.
Thus, they must for example:
= have a small footprint, = present visual discretion or SER, for Equivalent Surface Radar, weak, = have high radio performance such as ROS, for Stationary Wave Ratio, low, strong gain, etc., = be adapted to emit and receive electromagnetic waves whatever their polarization (linear polarization, a polarization circular and elliptical polarization), and = have unidirectional radio coverage.
Finally, they must respect the road gauge of land vehicles and not degrade the aerodynamics of airborne vehicles to which they are integrated and present independent radio performances vis-à-vis them.
In addition, these antennas must have a very thin thickness to be arranged either directly on one of the surfaces of a machine or in a cavity provided for

2 this effect in said machine, for example so that they are flush with a surface he includes.
For example, the document A Novel Compact Dual-Linear Polarized UWB Antenna for VHF / UHF applications describes a compact broadband antenna of the type supra. The radiating elements of the antenna are curved and have meanders of way to increase the electrical lengths of the antenna and thus optimize the performances radio frequencies. In addition, the metal platinum of the antenna is disposed on a disk made of a ferrite material. She is at a distance radiating elements so that it reflects electromagnetic waves issued or received by the antenna at high frequencies.
However, this solution does not give complete satisfaction.
First, this antenna does not allow use from 30 MHz with an acceptable ROS.
Secondly, because of the curved shape of the radiating elements, the antenna constitutes a prominent protruding protrusion of the craft when it is arranged on a surface of it, or imposes to oversize the cavity in which it is arranged, which is particularly penalizing on some machines.
Third, given the design of the antenna, the performance the low frequencies of this antenna must vary in function of the machine on which it is arranged and these will be particularly impacted in the where this antenna is arranged in a metal cavity.
The object of the invention is therefore to solve these problems.
For this purpose, the invention relates to an antenna of the aforementioned type characterized in this that the radiating elements are all substantially plane, the two dipoles being substantially included in the same plane, and in that the absorbent structure is interposed between the metal plate and the dipoles and is arranged at platinum contact metallic.
According to other aspects of the invention, the compact broadband antenna comprises one or more of the following characteristics, taken alone or according to all) technically possible combination (s):
each radiating element has a general shape of disk sector;
said plane is at a distance d from the absorbent structure between 1 mm and 2 mm;
it comprises an impedance matching circuit realized in technology printed;

3 the metal plate comprises a soleplate, the adaptation circuit impedance being arranged in said sole;
- It also includes a radome protection.
the absorbent structure has a generally cylindrical shape;
the height of the absorbent structure is between 20 mm and 21 mm, and is advantageously 20 mm, and its diameter is between 330 mm and 334 mm , and is advantageously 330 mm;
the dipoles and the absorbent structure are integrally included in a cylinder of diameter substantially equal to 330 mm and substantially equal to 22 mm;
- the electromagnetic waves that it is able to transmit and receive have of the frequencies in the whole frequency range 30 MHz to 500 MHz, and advantageously throughout the frequency range 30 MHz to 700 MHz;
- it is suitable for emitting and receiving electromagnetic waves with any polarization among a linear polarization, a polarization circular or an elliptical polarization, each dipole being respectively clean to emission / reception of electromagnetic waves with polarization linear horizontal for one of the dipoles and vertical linear for the other dipole.
In addition, the invention relates to a land-based, airborne or naval machine of the type comprising:
a flat surface and / or a cavity, an antenna as described above and arranged on said surface and or in said cavity.
According to other aspects of the invention, the machine comprises one or more of the characteristics, taken alone or in any combination (s) technically possible:
the flat surface and / or the cavity are made from a material metallic.
The invention will be better understood with the aid of the description which follows, given only by way of example and with reference to the accompanying drawings on which :
- Figure 1 is a perspective view of a compact broadband antenna according to a first embodiment of the invention;
- Figure 2 is a sectional view of the antenna of Figure 1 according to the plan II;
FIG. 3 is a representation curve of the stationary wave ratio of one of the two dipoles of a compact broadband antenna according to the invention in frequency function in MHz;

4 - Figure 4 is a curve of representation of the insulation between the two dipoles a compact broadband antenna according to the invention according to the frequency in MHz;
FIG. 5 is a representation curve of the gain of one of the two dipoles a compact broadband antenna according to the invention according to the frequency in MHz;
FIG. 6 is radiation diagrams according to the azimuthal plane of one of the two dipoles of a compact broadband antenna according to the invention for of the frequencies of 30 MHz, 50 MHz, 100 MHz, 300 MHz and 500 MHz respectively;
- Figure 7 is a side view of a compact broadband antenna according to a second embodiment of the invention;
- Figure 8 is a side view of a compact broadband antenna according to the invention comprising a protective radome; and - Figure 9 is a schematic representation of the antenna of Figure 8 arranged in a cavity formed in a machine;
In all that follows, the lower and upper expressions are used with reference to the figures and not in a limiting manner.
The antenna according to the invention is intended to transmit and receive waves electromagnetic fields whose frequencies are preferentially included in all the frequency range 30 MHz to 500 MHz. Advantageously, it is intended to transmit and receive electromagnetic waves whose frequencies are included in all the frequency range 30 MHz - 700 MHz.
With reference to FIGS. 1 and 2, the antenna 2 comprises radiating elements 4, an absorbent structure 6 and a metal plate 8. In addition, it includes means 10 for adapting impedance and supplying the radiating elements 4.
The radiating elements 4 are specific to the transmission and reception of wave electromagnetic.
For this purpose, the radiating elements 4 are made from a material electrically conductive.
In the example of FIG. 1, the radiating elements 4 are made of printed technology known to those skilled in the art.
The antenna 2 thus comprises four radiating elements 4 substantially plane and of triangular general shape, and more precisely each sector-shaped of disk. Each radiating element 4 thus has a rounded edge 12 and a Mountain peak opposite 14 to said rounded edge 12. Each radiating element 4 has an angle opening has at its summit 14 whose value is worth substantially 45.

This value of the opening angle a makes it possible to optimize the performances of impedance and gain of antenna 2 over the bandwidth covered, while in minimizing its bulk.
The radiating elements 4 are substantially inscribed in a circle C of center

5 0, the rounded edge 12 of each radiating element belonging substantially to said circle C. In addition, the opposite peaks 14 at these rounded edges all point to sensibly to point O.
The radiating elements 4 are all substantially included in the same plane P
and have substantially the same dimensions.
The radiating elements 4 are divided into two dipoles 16A, 16B comprising each two radiating elements 4 diametrically opposed. Each dipole 16A, is symmetrical with respect to said point 0 and has an axis of symmetry 17A, 17B included in the plane P, passing through 0 and coincident with the bisector of the angle at summit 14 of each of its radiating elements 4.
Each of the two dipoles 16A, 16B is suitable for transmission and reception wave electromagnetic fields with vertical linear polarization for the one and horizontal for the other. The emission and reception of electromagnetic waves a any polarization (linear polarization, circular polarization or polarization elliptic) are then obtained by combining the two polarizations linear of analogue way by adding for example a coupling function, either by treatment digital, this being known to those skilled in the art.
For this purpose, the two dipoles 16A, 16B are orthogonal, that is to say that their axes of symmetry 17A, 17B are orthogonal. In addition, each radiating element 4 of a 16A dipole adapted for transmission / reception of linear polarization waves data is then arranged between the two radiating elements 4 of the dipole 16B adapted for the emission / reception of electromagnetic waves of linear polarization complementary, as shown in Figure 1.
With reference to FIGS. 1 and 2, the preferred radiation direction of the antenna 2 corresponds to an axis AA 'perpendicular to the plane P of the elements radiant 4 and passing through point 0.
Still with reference to FIG. 1, the dipoles 16A, 16B are substantially registered in Circle C.

6 The diameter of the circle C is equal to a fraction of the length of a wave electromagnetic, that is to say that the diameter is equal to / 1 / n, where 2 is the length wave and n is a strictly positive number.
For an ideal low-bandwidth antenna centered around a length wave 2, n is typically chosen to be 2.
The dimensioning of the dipoles of this antenna is then determined as a rule overall by the ratio 2 / independently of the resulting bulk.
However, the congestion and bandwidth constraints to which the antenna is meant to answer translate into a significant gap with this case of Fig.
In the embodiment considered, the diameter of the circle C is taken substantially equal to 330 mm, n being then approximately between 30 and 1,8 respectively for electromagnetic waves with a frequency of 30 MHz at 500 MHz.
The geometry of the dipoles 16A, 16B has the effect of minimizing the volume occupying them, while having a transmission and reception capacity wave electromagnetic waves of any polarization from a single antenna 2.
The absorbent structure 6 is able to improve the level of adaptation impedance of the antenna 2 and to increase its directivity by absorbing a part of rear radiation dipoles 16A, 16B of the antenna 2, that is to say the influence emitted in the opposite direction to its preferred radiation direction. She is by therefore, to optimize the gain of antenna 2, particularly low frequencies of its frequency band, for example at frequencies between 30 MHz and 200 MHz. In addition, it is suitable for minimizing congestion in diameter and in thickness of the antenna 2.
For this purpose, the absorbent structure 6 is interposed between the elements radiant 4 and the metal plate 8. It is then both located near the items 4 and in contact with the metal plate 8. In addition, it comprises a assembly of tiles made from a ferrite material known from the man of job.
The absorbent structure 6 has a generally cylindrical shape of axis AA ' and of diameter substantially equal to the diameter of the circle C circumscribing the dipoles 16A, 16B, and more particularly between 330 mm and 334 mm.
In the example of FIGS. 1 and 2, it has a substantially equal diameter at 330 mm.

7 Moreover, the absorbent structure 6 has a height substantially between 20 mm and 21 mm, and advantageously substantially equal to 20 mm.
This value is a good compromise between performance ROS radio and gain between low and high frequencies, the resulting bulk of the antenna 2, and the related absorption properties to the features of complex permittivity and complex permeability of the material of the absorbent structure 6.
The arrangement of the absorbent structure 6 near the elements radiating 4 and in contact with the metal plate 8 can significantly reduce the influence of the gear on which the antenna 2 is integrated on the radio performances at low frequencies, especially in the case where the antenna 2 is arranged in a cavity metallic.
Absorbent structure 6 is delimited vertically by a surface higher 18 substantially flat and a lower surface 21 both parallel to the P. Ledit plan plane P is then located at a distance d from said upper surface 18 between 1 mm and 2 mm. In addition, the lower surface 21 is disposed in contact with the platinum metallic 8.
This low value of the distance da for effect of self-adapting the antenna 2 via the means 10 of adaptation and feeding, and consequently to generate a decrease of the value of the Stationary Wave Report of antenna 2 particularly at low frequencies of its frequency band, for example at frequencies between 30 MHz and 200 MHz.
The circle C and the absorbent structure 6 both have the same axis of revolution A-A '. In the embodiment of Figure 1, the dipoles 16A, 16B and said structure absorbent 6 are thus included in a cylinder of axis AA 'of diameter sensibly equal to 330 mm and height substantially equal to 22 mm.
When the antenna 2 is arranged in a cavity, this allows in particular to minimize the dimensions of said cavity, as will be seen later.
Absorbent structure 6 is adapted for the passage of means 10 impedance and power supply. For this purpose, the absorbent structure 6 delimits an orifice of passage 19 for the passage of the impedance matching means 10 and supply, as we will see later. This orifice has a general shape cylindrical axis AA 'and of small diameter in front of the diameter of the absorbent structure 6.
The metal plate 8 provides the ground plane functions as well as interface mechanical and electrical between the antenna 2 and the structure on which the antenna 2 is intended to be integrated.

8 The metal plate 8 is able to provide a mass reference to different antennas 2 and is able to optimize the directivity of the antenna 2 in contributing to the reduction of the back radiation of the latter.
In addition, the metal plate 8 is adapted to be arranged in contact with a plane surface of a machine to which the antenna 2 is intended to be integrated.
For this purpose, the metal plate 8 is made from a material electrically driver known to those skilled in the art.
In addition, it has a general disc shape AA 'axis and is arranged in contact with the absorbent structure 6.
In the example of FIGS. 1 and 2, the metal plate 8 presents a diameter of 350 mm and thus delimits a projection 20 of generally annular shape extending radially with respect to the absorbent structure 6 and having a width I
substantially equal to 10 mm.
The metal plate 8 has an upper surface 22 and a area lower 23.
The upper surface 22 is substantially flat and arranged in contact with the lower surface 21 of the absorbent structure 6. It is furthermore parallel to the plane P
radiating elements 4. Said surface 22 is then at a distance from said plane P equals at a fraction of the length of an electromagnetic wave, i.e.
the distance is equal to 11 / n where it is the wavelength and m is a strictly positive.
For an ideal low-bandwidth antenna centered around a length wave 2, m is typically chosen equal to 4 considering that the space between the radiating elements and the reflective plane of the ideal antenna is filled with air and therefore permittivity and permeability equal to 1. The distance of the turntable metallic to dipoles is then determined by the ratio 2 / inde 'of the congestion resulting.

However, the congestion and bandwidth constraints to which the antenna according to the invention responds result in a significant gap with this case of Fig.
Thus, in the embodiment of Figures 1 and 2, the distance of the platinum metal 8 in the plane P is taken substantially equal to 22 mm, m being then understood approximately between 450 and 27 for electromagnetic waves from frequency from 30 MHz to 500 MHz respectively.
The impedance matching and power supply means 10 are suitable for ensure impedance matching and feeding dipoles 16A, 16B of antenna 2 as well as to balance the currents flowing in the radiating elements 4.

9 For this purpose, these means 10 comprise two connectors 24, two impedance transformers 26 and electrical contacts 28 connecting the items radiators 4 to transformers 26. In addition, these means 10 include contacts 30, 32 connecting 24 connectors and transformers impedance 26, the reference electrical contacts 32 being ground contacts.
The connectors 24 are adapted to provide the electrical interface between the antenna 2 and a device (not shown) for transmission and / or reception which is associated.
The connectors 24 are arranged through the metal plate 8 next to the passage opening 19 of the absorbent structure 6.
In known manner, such connectors 24 are intended to be engaged with coaxial cables (not shown), and then have a core 34 and a mass 36 complementary to those of the coaxial cables to which they are connected.
In the embodiment of Figure 2, the core 34 of each connector 24 is connected to an asymmetrical channel 40 that includes each transformer impedance 26 via an electrical contact 30 located in the passage opening 19. The mass 36 of each connector 24 is connected to a ground track 42 of each transformer 26 via a electrical contact 32 also located in the passage opening 19. The mass 36 of each connector 24 is in electrical continuity with the metal plate 8 via a electrical contact 31 arranged in contact with the lower surface 23 of the platinum metallic 8.
Such electrical contacts 30, 31, 32 are well known to those skilled in the art and will not be described here.
In known manner, an impedance transformer 26 is adapted to maximize the power transfer between the dipoles 16A, 16B of the antenna 2 and the device transmission and / or reception to which the antenna 2 is associated.
At each dipole 16A, 16B is associated an impedance transformer 26.
As illustrated in FIG. 2, each impedance transformer 26 is agency in the passage opening 19 and comprises two symmetrical channels 38 connected each to one of the radiating elements 4 of the corresponding dipole 16 via a contact electrical 28, as well as an asymmetric channel 40 and a ground channel 42, as described below.
above.
The electrical contacts 28 are also arranged in the passage opening 19.
They are well known to those skilled in the art and will not be described here.
In the antenna 2 according to the invention, the geometry, the dimensions, the properties and the relative arrangement of the radiating elements 4, of the absorbent structure 6 and the metal plate 8 allow to:

(i) minimize the overall size of the antenna 2, in particular by very reduced thickness. The antenna 2 has very small dimensions in front of wavelengths of the electromagnetic waves that it is clean to emit and to receive.
In addition, the flatness of the radiating elements 4 and the geometries and dimensions of the The absorbent structure 6 and the metal plate 8 make it possible to minimize the volume occupied by antenna 2, (ii) maximize the reduction of the back radiation of the antenna 2. This is got by absorption of the back radiation of the dipoles 16A, 16B through the structure absorbent 6. The plating of the absorbent structure 6 on the plate 8 allows in addition

10 to attenuate the currents on the metal plate 8 generated by the back radiation dipoles 16A, 16B and which, if not attenuated, would re-radiate and interfere with the radiation in the preferred direction of the antenna 2.
The arrangement of the absorbent structure 6 near the elements radiating 4 dipoles 16A, 16B reduces the influence of neighboring objects on the radio performance. The antenna 2 thus presents performances optimized radio (Impedance, ROS, radiation, directivity and gain) and an maximized independence from its environment.
These characteristics (i) and (ii) combined make the antenna 2 suitable for minimize the volume of protruding protrusion that it constitutes compared to the machine when it is embedded in a surface of it, and to minimize the dimensions of a cavity intended to receive the antenna 2, said cavity being for example made from of a metallic material.
With reference to FIGS. 1 and 2, during operation of the antenna 2, the radiating elements 4 are powered by the transmitting / receiving device associated to the antenna via the impedance matching and power supply means.
The dipoles 16A, 16B emit and receive electromagnetic waves having any polarization among a linear polarization, circular and elliptical and having frequencies within the frequency band of the antenna 2.
These waves are then emitted and received preferentially according to the direction AA 'emission of antenna 2.
With reference to Figure 3, the ROS of antenna 2 is less than 2.35 for 1 for a nominal impedance of 50 Ohms over the 30 MHz to 500 MHz frequency range, that is, it has a very good impedance match on its Band frequency.

11 Referring to Figure 4, which is a representative curve of decoupling enter the two dipoles 16A, 16B as a function of the frequency, it can be seen that insulation between the two dipoles 16A, 16B is greater than 30 dB over the frequency band of the antenna 2.
With reference to Figure 5, it can be seen that the gain obtained on one of the dipoles is greater than ¨8 dBi over the frequency range 200 MHz to 500 MHz, greater than -5 dBi on the frequency range 230 MHz ¨ 470 MHz. In addition, this gain is worth ¨ 35 dBi at 30 MHz, -17 dBi at 100 MHz, and -12 dBi at 150 MHz.
Finally, with reference to Figure 6, the antenna 2 has a cover quasi-unidirectional radio frequency on its frequency band.
Referring to Figure 7, in a second embodiment of the invention, the impedance matching and power supply means 10 are integrated in a circuit impedance matching 44, with the exception of electrical contacts 28 connecting the dipoles 16A, 16B to said impedance matching circuit 44 and connectors 24.
This circuit 44 is made in printed technology known to those skilled in the art and is then disposed in a sole plate 46 that comprises the metal plate 8.
In practice, the sole 46 comprises a cavity 461 dedicated for this purpose and which is Accessible via a removable metal cover 462.
The metal plate 8 then defines four passage orifices 48 of shape cylindrical, located opposite the passage opening 19 of the structure absorbent 6.
The passage orifices 48 are angularly spaced 900 of each of the other and are each intended for the passage of an electrical contact 28.
The electrical contacts 28 are then arranged in the passage orifices 48 to connect the dipoles 16A, 16B and the circuit 44.
The sole 46 has a generally cylindrical shape of axis AA 'and of diameter less than or equal to the diameter of the metal plate 8 and comprises a lower surface 50.
The connectors 24 are then attached to the impedance matching circuit 44 in the sole 46 so as to project from the lower surface 50, as shown in FIG.
Figure 7.
The electrical contacts 31 provide electrical continuity between the mass 36 of each connector 24 and the removable metal cover 462.
With reference to FIG. 8, the antenna 2 also comprises a clean radome 52 to protect said antenna 2 and to allow the passage of radiation electromagnetic transmitted and received by the antenna 2.

12 For this purpose, the radome 52 has a generally cylindrical shape and is realized at from a material known to those skilled in the art, of the epoxy glass type, polyamide, or still peek, etc.
The radome 52 is delimited radially by a side wall 54 having a thickness less than or equal to the width I of the projection 20 and vertically by a wall transverse 56 discoidal shape.
The radome 52 is thus adapted to be fixed on the projection 20 in a position of protection illustrated in Figure 8 and in which its axis is coincident with the axis A-A '.
The radome 52 delimits a cylindrical cavity 58 of complementary dimensions to the dimensions of the cylinder in which are included the dipoles 16A, 16B and the structure absorbent 6.
In practice, the dimensions of the cavity 58 are increased by distances E
and e 'ranging from a millimeter to a few millimeters, and corresponding to One day existing respectively between the dipoles 16A, 16B and the transverse wall 56 and between absorbent structure 6 and the side wall 54 of the radome 52 in the position protection of it.
In the example of FIG. 8, this cavity 58 thus has a diameter of 330+ 2.e 'mm approximately and a height of 22 + e mm approximately.
Still in the example of Figure 8 which illustrates the antenna 2 according to the second embodiment, the side wall 54 is fixed on the projection 20 by means of fixation (not shown) so that the dipoles 16A, 16B and the structure absorbent 6 are integrally included in the cavity 58, as illustrated in FIG. 8.
As illustrated in FIG. 8, the antenna 2 provided with its radome 52 is range in a cylinder of axis AA 'and of diameter substantially equal to 350 mm.
With reference to FIG. 9, the antenna 2 provided with its radome 52 is suitable for to be arranged on a flat surface 60 of a cylindrical cavity 62 provided for this effect in a machine 64, the metal plate 8 being in contact with said surface 60.
In the example of Figure 9, which represents an antenna 2 according to the second embodiment of the invention, it is then the lower surface 50 of the sole 46 of the metal plate 8 which is in contact with the flat surface 60.
The cylindrical cavity 62 has a diameter substantially equal to the diameter of the antenna 2 and a height substantially equal to the height of the radome 52 to which is added the height of the metal plate 8.
Preferably, said surface 60 and said cylindrical cavity 62 are carried out from a metallic material.

13 In the surface 60 is formed an opening 66 for the connection via the connectors 24 means 10 for impedance matching and power supply at device transmission / reception (not shown) of the antenna 2 associated with it.

Claims (13)

1. Antenna (2) for transmitting / receiving electromagnetic waves, of the type comprising:
two dipoles (16A, 16B) orthogonal to each other, each dipole (16A, 16B) comprising two radiating elements (4), a metal plate (8), and an absorbent structure (6), characterized in that the radiating elements (4) are all substantially plans the two dipoles (16A, 16B) being substantially comprised in the same plane (P), and in that the absorbent structure (6) is interposed between the metal plate (8) and the dipoles (16A, 16B) and is arranged in contact with the metal plate (8). 2. Antenna (2) according to claim 1, characterized in that each element radiating (4) has a general form of disk sector. 3. Antenna (2) according to claim 1 or 2, characterized in that said plan (P) is at a distance d from the absorbent structure (6) of between 1 mm and 2 mm mm. 4. Antenna (2) according to any one of the preceding claims, characterized in that it comprises an impedance matching circuit (44) made in printed technology. 5. Antenna (2) according to claim 4, characterized in that the platinum metal (8) comprises a sole (46), the impedance matching circuit (44) being arranged in said sole (46). 6. Antenna (2) according to any one of the preceding claims, characterized in that it also comprises a radome (52) protection. 7. Antenna (2) according to any one of the preceding claims, characterized in that the absorbent structure (6) has a general shape cylindrical. 8. Antenna according to claim 7, characterized in that the height of the absorbent structure (6) is between 20 mm and 21 mm, and advantageously 20 mm, and its diameter is between 330 mm and 334 mm, and is advantageously 330 mm 9. Antenna (2) according to any one of the preceding claims, characterized in that the dipoles (16A, 16B) and the absorbent structure (6) are integrally contained in a cylinder of diameter substantially equal to 330 mm and of height substantially equal to 22 mm. 10. Antenna (2) according to any one of the preceding claims, characterized in that the electromagnetic waves that it is specific to to issue and receive frequencies in the entire 30 MHz frequency range ¨ 500 MHz, and advantageously throughout the frequency range 30 MHz to 700 MHz. 11. Antenna (2) according to any one of the preceding claims, characterized in that it is adapted to transmit and receive waves electromagnetic having any polarization among a linear polarization, a polarization circular or an elliptical polarization, each dipole (16A, 16B) being respectively specific to the emission / reception of electromagnetic waves with a polarization horizontal linear for one of the dipoles (16B) and vertical linear for the other dipole (16A). 12.- A machine (64) on land, airborne or naval, of the type comprising:
a flat surface (60) and / or a cavity (62), an antenna (2) according to any one of the preceding claims and arranged on said surface (60) and / or said cavity (62). 13.- machine (64) according to claim 12, characterized in that the surface plane (60) and / or the cavity (62) are made from a metallic material.