EP1291974A1 - High efficient and high power antenna system - Google Patents

Abstract

The antenna system is made of identical radiating structures. Each structure is connected to a feed impedance adaptor. A processor (15) with control logic (Cm) is adapted to match to the master radiating structure and a logic structure (Cs) transfers the matching parameter to the slave radiating structure.

Description

The present invention relates to an antennal system having a plurality of radiating elements or structures arranged in parallel to each other, each structure being in connection with a power supply and impedance matching device.

It applies, for example, to radiocommunication using the frequency range between 1.5 and 30 MHz.

It also relates to a small antennal system operating particularly in the HF band (high frequency or in Anglo-Saxon High frequency) covering frequencies from 1.5 to 30 MHz, and intended to be installed for example on land vehicles to ensure ionospheric reflection radio links of the NVIS type (abbreviation of Near Vertical Skywave Incidence).

It works with radio communication systems at frequency evasion (Hopping Frequency in Anglo-Saxon terms).

Radiocommunication systems using the range of frequencies covering 1.5 to 30 MHz and intended to be installed on vehicles usually involve antennae composed essentially of a radiating structure, a device for feeding the radiating structure and a device impedance matching, usually referred to as ATU (Antenna Tuning Unit). The expression "radiating element" or "radiating structure" designates the same element.

A typical example of such an antennal system is given in the figure 1. The radiating structure 1, of monopole type, is constituted in this example by a vertical whip fixed by one of its ends 7 on a vehicle 2 via an E penetrate base, also ensuring a role of feeding device 6 by connecting the end 7 of the whip 1 to impedance matching and feeding device 3. The whip is thus connected to a transceiver 5 via the set of power supply and impedance matching 3 comprising a device impedance matching 4.

• Un ensemble d'éléments capacitifs 41 et un ensemble d'éléments inductifs 42 qui peuvent être connectés entre eux et ajustés en valeurs par l'intermédiaire de commutateurs 43 pour constituer un réseau d'adaptation d'impédance de type LC. Ce réseau LC est capable de transformer l'impédance complexe de la structure rayonnante 1 afin de présenter à l'entrée du poste émetteur/récepteur 5 (E/R) une impédance fixée selon le fonctionnement souhaitée, par exemple une valeur voisine de 50 ohms, à la fréquence de travail, réalisant de ce fait l'accord du système antennaire,
• Un processeur 44 pourvu d'un algorithme AL variant en fonction des concepteurs. Les fonctions principales de cet algorithme consistent notamment à dialoguer avec le poste émetteur-récepteur 5 afin de connaítre la fréquence instantanée de travail, à assurer la commande des commutateurs 43 et à gérer, en particulier, la phase d'accord pendant laquelle l'algorithme fait varier, par exemple par itérations successives, les valeurs des éléments capacitifs et celles des éléments inductifs pour les faire converger vers les valeurs conduisant à l'accord.

This impedance matching device 4 has a known structure described in FIG. 2 and comprising, for example:

• A set of capacitive elements 41 and a set of inductive elements 42 which can be connected to each other and adjusted in values via switches 43 to form an LC type impedance matching network. This LC network is capable of transforming the complex impedance of the radiating structure 1 in order to present at the input of the transceiver station 5 (E / R) an impedance set according to the desired operation, for example a value close to 50 ohms , at the working frequency, thereby realizing the tuning of the antennal system,
• A processor 44 provided with an algorithm AL varying according to the designers. The main functions of this algorithm consist in particular in dialoguing with the transceiver station 5 in order to know the instantaneous working frequency, to control the switches 43 and to manage, in particular, the tuning phase during which the algorithm varies, for example by successive iterations, the values of the capacitive elements and those of the inductive elements to make them converge towards the values leading to the agreement.

The synoptic of operation of such an antennal system is given in Figure 3.

For links to be provided on short and on average distances (typically of the order of 0 to 500 km) from a radiocommunication system installed on a mobile vehicle, the structure radiating the most suitable is a loop-type radiating structure. Examples of such structures are described for example in patents US 4,893,131, FR 2 553 586 and FR 2 785 094. FIGS. 4 and 5 schematize such a structure.

A filiform conductive element 1 is curved on the top of a vehicle 2. This element is powered at one end 8 by a power supply device 6 consisting of a wide impedance transformer strip 10 and a connecting cable 11 (FIG. 5). The other end 7 of this radiating element is connected to the ground by a variable capacity 12 of pre-tuning to generate the radiating surface S of the antennal structure loop type. The radio frequency power provided by the station transmitter / receiver 5 is transmitted to the supply device 6 through a impedance matching device which is, in this embodiment, integrated with the variable capacity 12 pre-agreement in the same housing 13. This integration makes it possible to control the variable capacity by means of the AL algorithm.

Other power supply and adaptation configurations impedance can be used.

The antenna systems according to the prior art, although effective, however, have limitations in their operation.

• de réduire fortement le rendement des systèmes antennaires, parfois de manière importante,
• de générer des tensions élevées et de forts courants dans tous les éléments constitutifs du système antennaire. Cet aspect limite la puissance admissible de ces systèmes antennaires pour véhicule aux alentours d'une centaine de Watts et nécessite de séparer le dispositif d'alimentation 6 de la capacité de préaccord ce qui représente un inconvénient pour l'intégration de l'antenne sur son véhicule porteur.
• n'étant pas capables de supporter des puissances RF (Radio fréquence) élevées, en particulier celles des postes émetteurs/récepteurs utilisés sur des véhicules pouvant délivrer plusieurs centaines de Watts voire le kilowatt, ils ne peuvent pas faire fonctionner les éléments réactifs tels que les éléments capacitifs 41, 12 ou inductifs 42, à des taux de charge très élevés au détriment de la fiabilité et ne sont pas adaptés pour mettre en oeuvre des composants de commutation 43 de forte puissance dont le temps de commutation est trop lent pour suivre tous les rythmes d'évasion de fréquence offerts par les émetteurs/récepteurs.

For example, their use on vehicles, in particular on moving vehicles, requires limiting or restricting the dimensions of the radiating structures. This results in particular:

• greatly reduce the performance of antennal systems, sometimes significantly,
• to generate high voltages and strong currents in all the constituent elements of the antennal system. This aspect limits the allowable power of these antennal systems for vehicles around a hundred watts and requires the separation of the feed device 6 of the pre-tuning capacity which represents a drawback for the integration of the antenna on its carrier vehicle.
• not being able to withstand high RF (Radio Frequency) powers, especially those of transceivers used on vehicles that can deliver several hundred Watts or even a kilowatt, they can not operate reactive elements such as capacitive elements 41, 12 or inductive 42, at very high load rates to the detriment of reliability and are not adapted to implement switching components 43 of high power whose switching time is too slow to track all frequency evasion rhythms offered by transmitters / receivers.

• au moins un processeur équipé d'une logique de commande Cm adaptée à réaliser l'accord de la structure rayonnante « maítre », à faire varier au moins une des valeurs d'au moins un paramètre donnant l'accord pour les faire converger vers les valeurs donnant l'accord, et
• une logique Cs adaptée à transférer les paramètres correspondant à l'accord de la structure rayonnante « maítre » vers la ou les structures rayonnantes « esclave ».

The invention relates to an antenna system consisting of (N + 1) substantially identical radiating structures with N greater than or equal to 1, said (N + 1) structures are arranged parallel to each other, each radiating structure is connected to a device power supply and impedance matching characterized in that it comprises

• at least one processor equipped with a control logic Cm adapted to achieve the agreement of the radiating structure "master", to vary at least one of the values of at least one parameter giving the agreement to converge them to the values giving the agreement, and
• a logic Cs adapted to transfer the parameters corresponding to the tuning of the "master" radiating structure to the "slave" radiating structure or structures.

A radiating structure is for example in connection with a processor equipped with control logic Cm (radiating structure having a function of master) or Cs (radiating structure having a function slave).

The feeders can be selected to provide Frequency Radio Frequencies substantially equal in phase with the majority or all (N + 1) radiating structures.

The system is for example used in the frequency range between 1.5 and 30 MHz.

• associer à une structure rayonnante une fonction de maítre, et aux autres structures rayonnantes une fonction « d'esclave »,
• transmettre les paramètres d'accord de la structure rayonnante maítre vers les structures rayonnantes esclaves
• faire varier au moins une des valeurs d'au moins un des paramètres pour les faire converger et obtenir l'accord.

The invention also relates to a method for tuning an antenna system comprising (N + 1) substantially identical radiating structures, with N greater than or equal to 1, comprising at least one step where each of the radiating structures arranged in parallel to each other are fed and adapted in impedance for a given operating frequency value, characterized in that it comprises at least the following steps:

• to associate with a radiating structure a function of master, and with the other radiating structures a function of "slave",
• transmit the tuning parameters of the radiant master structure to the radiating slave structures
• varying at least one of the values of at least one of the parameters to make them converge and obtain agreement.

a) initialiser les paramètres d'accord pour la structure rayonnante « maítre »,

b) transmettre les paramètres d'accord aux autres structures rayonnantes,

c) déterminer la valeur d'impédance Z_mesurée en sortie de la structure rayonnante « maítre » et comparer ladite valeur à une valeur spécifiée Z_fixée,

d) tant que ladite valeur déterminée est différente de la valeur spécifiée déterminer les valeurs des paramètres permettant l'accord pour la structure rayonnante maítre,

e) faire varier au moins un des paramètres d'accord de la structure rayonnante maítre, et réitérer les étapes c à d.

The method comprises for example the following steps:

a) initialize the tuning parameters for the radiating structure "master",

b) transmit the tuning parameters to the other radiating structures,

c) determining the impedance value Z _measured at the output of the "master" radiating structure and comparing said value with a specified value Z _fixed ,

d) as long as said determined value is different from the specified value determining the values of the parameters allowing agreement for the master radiating structure,

e) varying at least one of the tuning parameters of the master radiating structure, and repeating steps c to d.

• II assure un débit de données numériques (en bits/secondes) de plus en plus élevé en radiocommunication dans la bande HF (High Frequency),
• II peut supporter des puissances radiofréquence des postes émetteurs-récepteurs, pouvant aller de plusieurs centaines de watts voire le kilowatt,
• Il augmente le rendement en accroissant la résistance de rayonnement du système rayonnant, tout en restant dans un encombrement compatible avec un véhicule terrestre,
• II limite les tensions et les courants développés dans les éléments réactifs et permet de ce fait le regroupement sur une seule extrémité de la capacité de préaccord et du dispositif d'alimentation même pour une forte puissance émise,
• II autorise l'utilisation de composants de commutation de faible puissance et en conséquence est donc rapide et fiable contrairement aux systèmes de l'art antérieur qui doivent faire fonctionner les éléments réactifs, capacitifs ou inductifs à des taux de charge très élevés au détriment de la fiabilité et doivent mettre en oeuvre des composants de commutation de forte puissance dont le temps de commutation est trop lent pour suivre tous les rythmes d'évasion de fréquences offerts par les émetteurs-récepteurs.

The antenna system according to the invention has the following advantages:

• It ensures a digital data rate (in bits / second) of higher and higher radiocommunication in the High Frequency (HF) band,
• It can support radiofrequency power of transceivers, ranging from several hundred watts to the kilowatt,
• It increases the efficiency by increasing the radiation resistance of the radiating system, while remaining in a space compatible with a land vehicle,
• It limits the voltages and the currents developed in the reactive elements and thus makes it possible to group on one end only the pre-tuning capacitance and the supply device even for a high emitted power,
• It allows the use of low power switching components and therefore is fast and reliable unlike prior art systems which must operate the reactive, capacitive or inductive elements at very high load rates to the detriment of the reliability and must implement high power switching components whose switching time is too slow to follow all the frequency evasion rates offered by the transceivers.

• Les figures 1, 2 et 3 un système antennaire HF selon l'art antérieur, le détail d'une ATU et le synoptique du système,
• Les figures 4 et 5 un exemple de système d'antenne de type boucle,
• La figure 6 un synoptique du système antennaire selon l'invention et la figure 7 un organigramme détaillant les étapes principales du procédé,
• Les figures 8 et 9 un exemple d'installation du système antennaire sur un véhicule et un détail de l'ensemble d'alimentation et d'adaptation d'impédance,
• Les figures 10 et 11 une autre variante de réalisation à base de monopoles,
• La figure 12 un exemple de système antennaire pour installation sur un mât-support.

Other features and advantages of the invention will appear better on reading the description which follows given by way of illustration and in no way limiting with respect to the appended figures which represent:

• FIGS. 1, 2 and 3 an antenna system HF according to the prior art, the detail of an ATU and the synoptic of the system,
• FIGS. 4 and 5 an example of a loop antenna system,
• FIG. 6 a block diagram of the antennal system according to the invention and FIG. 7 a flowchart detailing the main steps of the method,
• FIGS. 8 and 9 an example of installation of the antennal system on a vehicle and a detail of the power supply and impedance matching assembly,
• Figures 10 and 11 another embodiment based on monopolies,
• Figure 12 an example of antennal system for installation on a support mast.

• Un émetteur-récepteur 5 relié à un diviseur de puissance 9 de rapport N+1 égal au nombre d'éléments rayonnants utilisés,
• N+1 ensembles R₁, R₂, ...Ri,.., R_n, R_n+1 comportant chacun au moins un élément rayonnant 1₁, 1₂, ...1_i,..,1_n,1_n+1 associé à un ensemble d'alimentation et d'adaptation d'impédance respectivement 3₁, 3₂, 3i,..., 3_n, 3_n+1, chaque ensemble Ri est en liaison avec le diviseur de puissance 9 au moyen d'un câble 90₁, 90₂, ... 90_i,.., 90_n, 90_n+1,
• Les N+1 éléments rayonnants 1_i sont implantés en parallèle, un de ces éléments jouant le rôle de maítre et les N autres éléments un rôle d'esclave, (sur la figure 6, c'est l'élément 1₁ qui joue ce rôle),
• Un dispositif Z (Zmètre) de mesure de l'impédance en sortie de l'élément rayonnant 1₁ désigné comme maítre,
• Pour l'élément maítre, un processeur 15 équipé d'une logique de commande Cm ayant notamment pour fonction de réaliser l'accord d'une façon active durant la phase d'accord. La logique de commande Cm permet notamment de gérer la phase d'accord du système antennaire en faisant varier, les valeurs des éléments variables de l'ensemble d'alimentation et d'adaptation, tels que les éléments capacitifs 41, les éléments inductifs 42, la capacité variable 12 pour les faire converger vers les valeurs qui donnent l'accord,
• Pour chacun des N éléments rayonnants ayant un rôle d'esclave dans une configuration de fonctionnement donné du système antennaire, un processeur 15 équipé d'une logique de commande Cs ayant notamment pour fonction de recopier à tout moment et donc pendant toute la phase d'accord, l'état de l'équipement maítre, notamment les paramètres d'accord, tels que les valeurs des éléments variables 41₁, 41₂, ..vers respectivement les éléments variables 41_i, 42_i, .....des ensembles d'alimentation et d'adaptation dits « esclaves ».
     Avantageusement, la résistance de rayonnement de l'ensemble des N+1 éléments rayonnants par rapport à celle d'un seul élément rayonnant se trouve multipliée approximativement par N+1 et il en est de même pour le rendement du système antennaire. Les équipements d'alimentation et d'adaptation ne supportent alors qu'une (N+1)ième partie de la puissance RF totale délivrée par l'émetteur-récepteur.
     Dans le cas particulier d'un système antennaire fonctionnant sur une fréquence fixe unique, il est possible de fixer manuellement les valeurs des capacités et des inductances pour obtenir l'accord souhaitée et de fait les logiques de commande par processeur ne sont plus nécessaires.

The following description is given by way of nonlimiting example for an antenna system intended to be used in the HF frequency range from 1.5 to 30 MHz and installed on a vehicle.
Referring to the block diagram of FIG. 6, the antennal system according to the invention comprises:

• A transceiver 5 connected to a power divider 9 of ratio N + 1 equal to the number of radiating elements used,
• N + 1 sets R ₁ , R ₂ ,... Ri, .., R _n , R _{n + 1} each comprising at least one radiating element 1 ₁ , 1 ₂ , ... 1 _i , .., 1 _n , 1 _{n + 1} associated with a power supply and impedance matching respectively 3 ₁ , 3 ₂ , 3i, ..., 3 _n , 3 _{n + 1} , each set Ri is in connection with the power divider 9 by means of a cable 90 ₁ , 90 ₂ , ... 90 _i , .., 90 _n , 90 _{n + 1} ,
• The N + 1 radiating elements 1 _i are implanted in parallel, one of these elements acting as a master and the other N elements as slave, (in FIG. 6, it is the element 1 ₁ which plays this role. role),
• A device Z (Z meter) for measuring the impedance at the output of the radiator element 1 ₁ designated as a master,
• For the master element, a processor 15 equipped with a control logic Cm whose particular function is to achieve the agreement in an active manner during the tuning phase. The control logic Cm makes it possible in particular to manage the tuning phase of the antenna system by varying the values of the variable elements of the supply and adaptation assembly, such as the capacitive elements 41, the inductive elements 42, the variable capacity 12 to converge them to the values that give the agreement,
• For each of the N radiating elements having a slave role in a given operating configuration of the antennal system, a processor 15 equipped with a control logic Cs having in particular the function of copying at any time and therefore during the entire phase of accord, the state of the master equipment, including the tuning parameters, such as the values of the variable elements 41 ₁ , 41 ₂ , ..vers respectively variable elements 41 _i , 42 _i , ..... so-called "slave" power and adaptation assemblies.
  Advantageously, the radiation resistance of the set of N + 1 radiating elements relative to that of a single radiating element is multiplied approximately by N + 1 and the same is true for the efficiency of the antennal system. The power supply and adaptation equipment then supports only one (N + 1) th part of the total RF power delivered by the transceiver.
  In the particular case of an antennal system operating on a single fixed frequency, it is possible to manually set the values of the capacitors and inductances to obtain the desired agreement and in fact the logic of control by processor are no longer necessary.

a) désigner un des éléments rayonnants comme « maítre »,

b) initialiser les paramètres d'accord de la structure rayonnante « maítre » en fonction de la fréquence de fonctionnement du système antennaire,

c) communiquer les paramètres d'accord, par exemple les valeurs des capacités et des inductances du circuit d'adaptation à tous les circuits d'adaptation des éléments rayonnants « esclaves », la logique de commande Cs permet une recopie des valeurs du maítre vers les esclaves,

d) déterminer, par exemple par mesure, la valeur d'impédance en sortie de l'élément rayonnant maítre », et
comparer la valeur mesurée Z_mesurée à une valeur souhaitée Z_fixée, cette dernière est choisie par exemple selon les conditions de fonctionnement du système antennaire, de façon à obtenir l'accord souhaité,

e) tant que Z_mesurée est différente ou sensiblement différente de la valeur Z_fixée, déterminer les valeurs des paramètres permettant l'accord pour la structure rayonnante maítre,

f) faire varier au moins une des valeurs des éléments variables pour les faire converger vers les valeurs qui donnent l'accord et réitérer les étapes e) à d). La tolérance est par exemple fixée à une valeur de TOS inférieure ou égale à 1,5.

FIG. 7 represents, in flowchart form, an example of steps implemented during the method in the particular case where the system is provided with a control logic:

a) designate one of the radiating elements as "master",

b) initializing the tuning parameters of the "master" radiating structure according to the operating frequency of the antennal system,

c) communicating the tuning parameters, for example the values of the capacitors and the inductances of the matching circuit to all the matching circuits of the "slave" radiating elements, the control logic Cs makes it possible to copy the values of the master to the slaves,

d) determining, for example by measurement, the impedance value at the output of the radiating element ", and
comparing the measured value Z _measured with a desired value Z _fixed , the latter is chosen for example according to the operating conditions of the antenna system, so as to obtain the desired agreement,

e) as long as Z _measured is different or substantially different from the _fixed Z value, determining the values of the parameters allowing agreement for the master radiating structure,

f) varying at least one of the values of the variable elements to converge them to the values that give the agreement and reiterate the steps e) to d). The tolerance is for example set at a value of TOS less than or equal to 1.5.

The variation of the values is carried out for example iteratively according to algorithms known to those skilled in the art.
The information is transferred from the radiating structure "master" to the structures "slaves" for example by modulating them at a frequency different from the working frequency and using the cables 90i.
They can also be transferred by any other means known to those skilled in the art.

FIG. 8 represents an exemplary embodiment of an antenna system according to the invention comprising two radiating elements installed on a vehicle and connected directly to the mass of the latter.
A first filamentary radiating element 1 ₁ has one of its ends 8 ₁ connected directly to the mass of the vehicle 2. The other end 7 ₁ is connected through a feedthrough E ₁ to the input terminal 30 ₁ of the power supply and impedance matching 3 ₁ . An example of details of this assembly is shown in Figure 9. It comprises for example a pre-agreement of variable capacitor 20 whose one terminal is the input terminal 30 ₁ get series with the primary of a wide elevator band transformer impedance 21, an ATU connected to the secondary of the transformer 21 and a control logic Cm which allows this set to function as a master. It is the same for the second filiform element 1 ₂ disposed in parallel to the first element 1 ₁ , at a distance of the order of 0.5 m so that these radiating elements do not touch under the effect of the movement of the vehicle. Similarly, the ends 8 ₂ and 7 ₂ are respectively connected to the vehicle earth and to the input terminal 30 ₂ of the second supply assembly and impedance matching February _3. This second set being regarded as slave with respect to the first set, it is equipped with a control logic Cs, allowing, in particular, the copying at any moment, in particular during the tuning phase, the state of the first together or master.
The information exchanged between the different assemblies is effected by means of a bus known to a person skilled in the art or else a connecting cable, for example the coaxial cables 31 ₁ and 31 ₂ connecting the power supply and adaptation assemblies. impedance 3 ₁ and 3 ₂ to the power divider 9. These two cables connected to two separate outputs 90 ₁ and 90 ₂ of the power divider have the same length or substantially the same length to allow the arrival of the signals at the same time on the radiating elements. The RF powers transmitted to the radiating elements 1 ₁ and 1 ₂ are therefore identical in amplitude and in phase or at least the most similar possible.

Figures 10 and 11 correspond to an alternative embodiment where the radiating elements 1 ₁ , 1 ₂ are of monopole type. In this case the supply and impedance assemblies are directly connected to the ATU 4. Only one end 7 ₁ , 7 ₂ of the radiating element is connected to the antenna system via the base E ₁ , E ₂ . Figure 11 shows a single element for simplification concerns.

FIG. 12 shows a variant embodiment in which a dipole antenna is installed on a support mast M. For voltage and current levels generated in the constituent elements of the antenna identical to those corresponding to a dipole antenna equipped with an ATU unique, this embodiment allows to transmit twice as much RF power. It consists of two monopole type 1 ₁ and 1 ₂ radiating structures installed in a substantially collinear manner head to tail at the top of the support mast and horizontally. The ends 7 ₁ and 7 ₂ of the radiating structures are respectively connected to the two sets of power supply and impedance matching 3 ₁ and 3 ₂ which function respectively as a master and as a slave. The two coaxial cords 31 ₁ and 31 ₂ of the same electrical length connect the two supply and impedance matching assemblies to the outputs of a hybrid power divider 0-180 °, 9 '. The two outputs 90 ' ₁ and 90' ₂ are in phase opposition.

Claims (12)

Antenna system composed of (N + 1) substantially identical radiating structures with N greater than or equal to 1, said (N + 1) structures are arranged parallel to each other, each radiating structure is connected to a feeding device and impedance matching characterized in that it comprises at least one processor (15) equipped with a control logic Cm adapted to achieve the agreement of the radiating structure "master", to vary at least one of the values of at least one parameter giving the agreement to make them converge towards the values giving the agreement, and a logic Cs adapted to transfer the parameters corresponding to the tuning of the "master" radiating structure to the "slave" radiating structure or structures. Antenna system according to claim 1 characterized in that the power supply devices are selected to provide substantially equal Radio Frequency frequencies in phase with the majority or all of the (N + 1) radiating structures. Antenna system according to claim 2 characterized in that it comprises at least: a first set (R ₁ ) consisting of a radiating structure (1 ₁ ), a power supply and impedance matching assembly (3 ₁ ) having a control logic (Cm) allowing it to operate in master to manage the tuning phase of the antenna system by varying, the values of the variable elements such as the capacitive elements (41 ₁ ), the inductive elements (42 ₁ ), the variable capacitance (12 ₁ ) to converge them to the values that give the agreement. N additional sets (R ₂ ...., R _{n + 1} ) substantially identical first set and placed parallel thereto, having a control logic (Cs) power supply and impedance matching sets (3 _i , 3 _i ... 3 _{n + 1} ) adapted to operate as a slave by copying at any time the state of the variable elements (41 ₁ ), (42 ₁ ), (12 ₁ ) ... of the master to respectively the elements variables (41 _i ), (42 _i ), (12 _i ) ... power supply and impedance matching assemblies (3 _i ), a power divider (9) from 1 input to N + 1 outputs (90 ₁ ) ... (90 _{n + 1} ) connected to the N + 1 power supply and impedance matching units (3 ₁ . ..3 _{n + 1} ). Antenna system according to claim 2 characterized in that : the radiating structures (1 ₁ ) ... (1 _{n + 1} ) are of loop type made from a filamentary conducting element, one of whose ends (8 ₁ ) ... (8 _{n + 1} ) is connected to the mass and whose other end (7 ₁ ) ... (7 _{n + 1} ) is connected to the input (30 ₁ ) ... (30 _{n + 1} ) of a supply and adaptation assembly impedance (3 ₁ ) ... (3 _{n + 1} ) and in that the power supply and impedance matching (3 ₁ ) ... (3 _{n + 1} ) assemblies consist of less: a wide-band impedance-boosting transformer (21), a pre-tuned variable capacitance (20) arranged in series with the impedance-boosting wideband transformer primary (21) and whose free terminal constitutes the input (30 ₁ ) ... (30 _{n + 1} ), an ATU (4) connected to the secondary of the transformer (21). Antenna system according to claim 2 characterized in that the radiating structures (1 ₁ ) ... (1 _{n + 1} ) are of monopole type made from a filiform conductive element, one of whose ends is left free and whose another end (7 ₁ ) ... (7 _{n + 1} ) is connected to the input (30 ₁ ) ... (30 _{n + 1} ) of a power supply and impedance matching assembly (3 ₁ ) ... (3 _{n + 1} ). Antenna system according to one of Claims 1 and 2, characterized in that it comprises at least: a first set (R ₁ ) consisting of a radiating structure (1 ₁ ), a power supply and impedance matching assembly (3 ₁ ) having a control logic (Cm) allowing it to operate in master to manage the tuning phase of the antenna system by varying, the values of the variable elements such as the capacitive elements (41 ₁ ), the inductive elements (42 ₁ ), the variable capacitance (12 ₁ ) to converge them to the values that give the agreement. an additional set (R ₂ ), identical to the first set (R ₁ ) and placed head to tail with this first set (R ₁ ), but whose control logic (Cs) of the power supply and adaptation set impedance (3 ₂ ) operates this one as a slave by copying at any time during the tuning phase the state of the variable elements (41 ₁ ), (42 ₁ ), (12 ₁ ) ... of the master to respectively the variable elements (41 ₂ ), (42 ₂ ), (12 ₂ ) ... of this slave assembly (3 ₂ ), a hybrid power divider (9 ') with an input and two outputs (90' ₁ ) (90 ' ₂ ) in phase opposition connected to the 2 power supply and impedance matching (3 ₁ ) and (3) ₂ ). Antenna system according to claim 6, characterized in that the radiating structures (1 ₁ ) and (1 ₂ ) are monopoles. Use of the system according to one of claims 1 to 7 in the frequency range from 1.5 to 30 MHz. A method for tuning an antenna system having substantially identical radiating structures (N + 1), with N greater than or equal to 1, comprising at least one step where each of the radiating structures arranged in parallel with each other is energized and impedance matched for an given operating frequency value characterized in that it comprises at least the following steps: to associate with a radiating structure a function of master, and with the other radiating structures a function of "slave", transmit the tuning parameters of the master radiating structure to the radiating slave structures, varying at least one of the values of at least one of the parameters to make them converge and obtain agreement. Process according to Claim 9, characterized in that it comprises at least the following steps: f) initializing the tuning parameters for the radiating structure "master", g) transmitting the tuning parameters to the other radiating structures, h) determining the impedance value Z _measured at the output of the "master" radiating structure and comparing said value with a specified value Z _fixed , i) as long as said determined value is different from the specified value determining the values of the parameters allowing agreement for the master radiating structure, j) varying at least one of the tuning parameters of the master radiant structure, and repeating steps c to d. Method according to one of Claims 9 and 10, characterized in that the parameters are transmitted by modulating the information at a frequency value different from that of the system operation. Method according to one of Claims 9 to 11, characterized in that the operating frequency range is chosen in the range 1.5 to 30 MHz.

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