EP0961344A1 - Device for radiocommunication and a slot loop antenna - Google Patents

Abstract

The lower auxilliary layer conductor structure (4) is decoupled from the resonant structure for all signals near resonance thus avoding capacitive coupling.

Description

The present invention relates, in general, to the devices for radiocommunication, in particular portable radiotelephones, and it relates more particularly to the antennas which can be included in such devices.

Such an antenna is advantageously produced according to a technique planar which applies both to the realization of lines transmitting signals and that of antennas coupling between such lines and radiated waves. It is formed by etching a conductive layer deposited on the upper surface of a dielectric substrate.

A device according to this invention more specifically includes an antenna planar with a resonant slit in the form of a loop. Such an antenna comprises a patch consisting of a fraction of said conductive layer. Said slot separates this patch from a conductive pad constituted by a another fraction of the same conductive layer. This beach constitutes a mass of the antenna. It almost completely surrounds this patch so that the resonant slit forms an open loop around the patch.

The antennas produced according to this technique constitute structures resonant capable of being the seat of standing electromagnetic waves. It is through these standing waves that the antenna ensures its function which is to carry out a coupling with electromagnetic waves radiated into space. Various forms can be taken by these waves stationary and correspond respectively to various modes of resonance of these structures. Each resonance mode can be described as resulting from the superposition of two waves propagating in two opposite directions on the same path and reflecting alternately at both ends of this path. This path is defined by the constituent elements of the antenna. He will be hereinafter called "resonance path". It follows the length of the slit in the form of loop in the case of the normal resonance mode of the antennas previously mentioned. But it can also be straight, for example in the case of other resonance modes of these antennas or in that of other antennas. In in all cases the resonant frequency is inversely proportional for each mode at the time during which a traveling wave considered above traverses said resonance path.

Several resonance modes can be established on the same path of resonance and then appear several resonance frequencies corresponding respectively to these modes. Such a mode can be defined by a number which will be called hereinafter "number of waves" and which is the number of wavelengths of a wave whose frequency is equal to the frequency of resonance corresponding to this mode, this number of wavelengths being the one contained in the length of this path. For each journey of resonance the resonance frequency is therefore proportional to this number. This number is typically close to a small integer or a fraction whose denominator is two or four. The expression "resonance mode" will sometimes be replaced below by the term "resonance".

The coupling of an antenna to a signal processing device is to say a transmitter or a receiver, is provided through a set connection which typically includes a connection line external to this antenna and connecting the latter to this member. One end of this line forms a coupling device which is included in this antenna.

In the case of a transmitting antenna with a resonant structure, respective functions of the coupling device, the connection line and the antenna are as follows: the function of the connection line is to carry a radio frequency or microwave signal from the transmitter to the antenna terminals. Throughout such a line the signal is propagates in the form of a traveling wave without undergoing, at least in principle, significant modification of its characteristics.

The function of the coupling device is to transform the signal supplied by the connection line so that this signal excites a resonance of the antenna, that is to say that the energy of the progressive wave carrying this signal is transferred to a useful standing wave established in the antenna with characteristics defined by the latter. The effectiveness of a such transfer is linked to an impedance adaptation which is to be carried out between the connection line and resonant structure. This adaptation is generally imperfect, i.e. the coupling device reflects a part of the energy towards the connection line which gives birth in the latter to a parasitic standing wave. The amplitude of this wave parasite defines a standing wave rate. This rate varies depending on the frequency and the diagram of this variation defines the bandwidth (s) of the antenna.

As for the antenna, it transfers the energy of the useful standing wave to a wave radiated in space. The signal supplied by the transmitter thus undergoes a first transformation to pass from the shape of a progressive wave to that of a standing wave, then a second transformation which gives it the shape of a radiated wave. In the case of a receiving antenna the signal takes the same forms in the same organs but it takes them in reverse order.

In the case of a planar antenna with resonant slit in the form of open loop, the coupling device typically has the form of a coplanar line formed in the same conductive layer than the antenna. This line has a conductor main connecting to the pad and surrounded by two ground conductors connecting to the antenna ground on either side of the opening of the loop.

With reference to the case of transmitting antennas, all of connection of an antenna is often referred to as constituting a line power supply to this antenna.

The present invention relates to the production of various types of apparatus. These devices include portable radiotelephones, radio stations, basis for these, automobiles and airplanes or air missiles. In the case of automobiles and especially in that of planes or missiles whose outer surface has a curved profile to obtain a low aerodynamic drag, the antenna included in such a device can be conformed to this profile so as not to show drag annoying additional aerodynamics. However, it remains desirable that antenna transmitting or receiving lobes are directed towards the outside of the device. In the case of a portable radiotelephone it is more particularly desirable to limit the radiation power which is intercepted by the body of the user of the device when it is used in emission.

This is why an asymmetrical spatial distribution has been sought. for the transmit power and reception sensitivity of such antennas. For this purpose, auxiliary conductive layers have been associated with numerous known planar antennas having resonant slots in loop form. Such a layer is typically formed on the surface bottom of the antenna substrate. It then has the effect that the waves emitted by the antenna are directed in the solid angle extending above the plane of the antenna.

A first such known antenna is described in the document of U.S. Patent 4,063,246 (Greiser). It has a shaped tablet rectangular. It has a resonant, loop-shaped slot that surrounds this pastille. This slot is the seat of a resonance mode established according to its length and corresponding to a number of waves which is approximately the number one. The auxiliary conductive layer of this antenna constitutes a lower ground as it is connected through the substrate to ground upper located in the plane of the patch. Coupling with waves radiated is made from the resonant slit. This slot is then said "radiative". The mass of the antenna extends over a significant width from the resonant slit. This type of antenna is usually designated under the name "coplanar antenna".

• la nécessité de prévoir des moyens de connexion entre la masse inférieure et la masse supérieure complique la réalisation.
• Les dimensions de l'antenne sont supérieures à des valeurs souhaitées dans certains des cas d'application indiqués ci-dessus.

This first known antenna has the following disadvantages in particular:

• the need to provide connection means between the lower mass and the upper mass complicates the implementation.
• The dimensions of the antenna are greater than desired values in some of the application cases indicated above.

To lower the dimensions of such an antenna a second antenna known differs from the previous one by the use of a resonance mode different. It is described in an article: Microwave and Optical Technology Letters / vol 6, N ° 5, April 1993, page 292-294, A COMPACT SLOT LOOP ANTENNA, M. Cal, P.S. Kooi, and M.S. Leong. In this second antenna known the number of waves of the resonance mode used is approximately 1/2, i.e. the perimeter of the patch extends over half a wavelength of the wave of this mode, this mode can be called "half-wave resonance". The radiative zone is then mainly constituted by the outer edges of the upper mass surrounding the patch and the width of this upper mass must therefore be limited. The choice of this width makes it possible to adjust the impedance presented by the antenna for the connection assembly. The lower mass layer is advantageously more extensive than the upper mass to avoid the appearance important side lobes in the spatial distribution of emission-reception. This type of antenna is called internationally in English "slot loop antenna" for "loop slot antenna".

This second known antenna has in particular a drawback which may be common to it with the first known antenna and which is that only a fraction of the power injected into the antenna is useful in certain cases, that is, only this fraction is transferred in these cases to the resonance half wave desired. Another fraction of this injected power can be a parasitic fraction which is transferred to parasitic resonance modes. While said half-wave resonance is established on a path constituted by the loop slot with electric field lines extending between the patch and the upper mass, these parasitic modes are the modes which are called in English "parallel plate modes" for "parallel plate modes". They are characterized in particular by electric field lines extending across the substrate enters on the one hand the upper conductive layer including the patch and the upper mass, and on the other hand the lower mass. Their journeys from resonance are further different from that of the half-wave resonance desired. The existence of this parasitic fraction causes a decrease in the useful power which is emitted by the antenna at the desired frequency. otherwise interactions may appear between the various modes of resonance. They may cause unpredictable changes in the frequency of half-wave resonance desired.

The size of said parasitic power fraction depends on the various propagation speeds of the various waves giving respectively birth to the various modes of resonance. It is known that these speeds depend on the dielectric constants of the materials in which these waves spread. This is why, in order to avoid a loss of power and / or a change in frequency caused by parasitic resonances, a third and fourth known antennas differ from previous ones by the use of several materials with different dielectric constants.

This third known antenna is described in an article: ELECTRONICS LETTERS, vol.32, n ° 18, 29th August 1996, P. 1633-1635 Forma et al. "Compact Oscillating slot loop antenna with conductor backing". Besides its dielectric substrate used to carry the conductive layer upper and lower mass, it has another dielectric layer which covers the upper conductive layer and which has a constant higher dielectric than that of this substrate. This other dielectric layer is added for two purposes: one is to slow down the useful traveling waves which propagate along the loop gap a short distance above and below the antenna plan. The other aim is not to slow down the waves which propagate throughout the thickness of the substrate and which can give rise parasitic modes. The effect of the difference in speeds thus created is favor the desired half-wave resonance.

The fourth known antenna is described in an article: IEEE TRANSACTIONS ON ANTENNAS AND PROPAGATION, Vol.43 n ° 10, October 1995, p. 1143-1148, Liu et al. "Radiation of Printed Antennas with a Coplanar Waveguide Feed ". The purpose of using two dielectric layers is to same as in the third known antenna except that the two layers of different dielectric constants are both interposed between the layer upper conductor and lower mass. That is, the substrate is then composite.

These third and fourth known antennas have in particular the disadvantage that the need to use two dielectric layers made up of different materials complicates the realization of the antenna.

• permettre de réaliser économiquement un dispositif de radiocommunication compact et efficace, et plus particulièrement un terminal mobile limitant la puissance de rayonnement susceptible d'être absorbée par le corps d'un utilisateur de ce terminal,
• permettre pour cela de réaliser une antenne à fente en boucle efficace ayant un angle solide d'émission-réception limité,
• au moins limiter l'amplitude de modes de résonance parasites qui sont susceptibles de s'établir dans une telle antenne,
• permettre un ajustement facile et précis d'une fréquence de résonance de cette antenne, et
• limiter les dimensions de cette antenne.

The present invention has in particular the following aims:

• allow a compact and efficient radiocommunication device to be produced economically, and more particularly a mobile terminal limiting the radiation power capable of being absorbed by the body of a user of this terminal,
• allow for this to produce an antenna with an efficient loop slot having a limited solid transmit-receive angle,
• at least limit the amplitude of parasitic resonance modes which are likely to be established in such an antenna,
• allow easy and precise adjustment of a resonant frequency of this antenna, and
• limit the dimensions of this antenna.

• une structure résonante définissant une fréquence de résonance utile de cette antenne, cette structure s'étendant dans une surface constituant un plan d'antenne, et
• une couche conductrice auxiliaire s'étendant en regard de ladite structure résonante dans une surface s'étendant à distance dudit plan d'antenne,

   ledit dispositif de radiocommunication comportant encore un organe de traitement de signal pour traiter lesdits signaux électriques ,
   ledit dispositif de radiocommunication étant caractérisé par le fait que ladite couche conductrice auxiliaire est découplée de ladite structure résonante et du dit organe de traitement de signal au moins pour tout signal ayant une fréquence radio proche de ladite fréquence de résonance utile.And for these purposes it has in particular for object a radiocommunication device comprising a loop slot antenna capable of coupling electrical signals to radiated electromagnetic waves, this antenna comprising:

• a resonant structure defining a useful resonant frequency of this antenna, this structure extending in a surface constituting an antenna plane, and
• an auxiliary conductive layer extending opposite said resonant structure in a surface extending at a distance from said antenna plane,

said radiocommunication device further comprising a signal processing member for processing said electrical signals,
said radiocommunication device being characterized in that said auxiliary conductive layer is decoupled from said resonant structure and from said signal processing member at least for any signal having a radio frequency close to said useful resonant frequency.

• un substrat diélectrique ayant une surface inférieure et une surface supérieure
• une couche conductrice auxiliaire s'étendant sur ladite surface inférieure du substrat et ayant une aire sur cette surface inférieure, et
• une couche conductrice supérieure s'étendant sur ladite surface supérieure du substrat et formant :
• une pastille, ladite couche conductrice auxiliaire étant isolée de cette pastille, et
• une masse d'antenne entourant ladite pastille tout en étant séparée de cette pastille par une fente, cette fente constituant une fente résonante, cette pastille, cette fente et cette masse constituant une structure résonante, cette structure ayant une aire sur ladite surface supérieure du substrat, cette aire étant sensiblement incluse dans ladite aire de la couche conductrice auxiliaire,

   ladite antenne à fente en boucle étant caractérisée par le fait que ladite couche conductrice auxiliaire est isolée en outre de ladite masse d'antenne de manière à constituer un réflecteur d'ondes pour des ondes électromagnétiques rayonnées émises ou reçues par ladite structure résonante.The present invention also relates to a loop slot antenna comprising:

• a dielectric substrate having a lower surface and an upper surface
• an auxiliary conductive layer extending over said lower surface of the substrate and having an area on this lower surface, and
• an upper conductive layer extending over said upper surface of the substrate and forming:
• a pad, said auxiliary conductive layer being isolated from this pad, and
• an antenna mass surrounding said patch while being separated from this patch by a slot, this slot constituting a resonant slot, this patch, this slot and this mass constituting a resonant structure, this structure having an area on said upper surface of the substrate , this area being substantially included in said area of the auxiliary conductive layer,

said loop slot antenna being characterized in that said auxiliary conductive layer is further isolated from said antenna mass so as to constitute a wave reflector for radiated electromagnetic waves emitted or received by said resonant structure.

Various aspects of the present invention will be better understood with the help of the description below and the attached schematic figures. When a same element is represented on several of these figures it is designated by the same reference numbers and / or letters.

Figure 1 shows a view of a radiocommunication device produced according to this invention, an antenna of this device being seen in perspective.

FIG. 2 represents a top view of the antenna of the device of the figure 1.

FIG. 3 represents a view of the same antenna in section through a vertical plane III-III of figure 2.

FIG. 4 represents a diagram of the variation of a coefficient of reflection expressed in decibels and measured at the input of this same antenna, in function of the frequency of a signal feeding this antenna, this frequency being expressed in MHz.

• Un substrat diélectrique 2 présentant deux surfaces principales mutuellement opposées. Ces deux surfaces principales constituent respectivement une surface inférieure et une surface supérieure. Elles s'étendent selon des directions horizontales définies dans cette antenne et plus précisément selon une direction longitudinale DL et selon une direction verticale DT, ces deux directions étant représentées à la figure 2. La forme de ce substrat est typiquement celle d'une feuille plane rectangulaire de composition et d'épaisseur uniformes. Mais cela n'est nullement une obligation. En particulier les dites surfaces peuvent être incurvées et la nature et l'épaisseur du substrat peuvent varier.
• Une couche conductrice inférieure 4 s'étendant par exemple sur une fraction de cette surface inférieure du substrat et constituant la couche conductrice auxiliaire précédemment mentionnée. Cette couche a une surface supérieure au contact du substrat et une surface inférieure opposée à cette surface supérieure.
• Une première fraction d'une couche conductrice supérieure s'étend sur cette surface supérieure au dessus de la couche 4 et constitue une pastille 6 du type désigné internationalement par le mot anglais patch. Cette pastille a une longueur et une largeur s'étendant selon la direction longitudinale DL et la direction transversale DT, respectivement, et sa périphérie est constituée par quatre bords s'étendant deux à deux sensiblement selon ces deux directions. Quoique les mots longueur et largeur s'appliquent usuellement aux deux dimensions mutuellement perpendiculaires d'un objet rectangulaire, la longueur étant plus grande que la largeur, il doit être compris que la pastille 6 peut s'écarter de la forme d'un tel rectangle sans sortir du cadre de cette invention. Plus particulièrement les directions DL et DT peuvent former un angle différent de 90 degrés, les bords de cette pastille peuvent ne pas être rectilignes et ne pas être séparés par des sommets anguleux et la forme de la pastille peut aussi être circulaire ou elliptique. L'un des bords de la pastille représentée s'étend selon la direction transversale DT et constitue un bord arrière 50. Un bord avant 52 est opposé à ce bord arrière. Deux bords latéraux 54 et 56 joignent ce bord arrière à ce bord avant. La longueur cumulée de ces quatre côtés constitue un périmètre P de la pastille.
• Une deuxième fraction de ladite couche conductrice supérieure entoure la pastille 6. Elle constitue une masse d'antenne 8. Elle est séparée de cette pastille par une fente constituant une fente résonante 10. Elle s'étend sur une distance limitée à partir de cette fente. Ledit substrat, cette pastille et cette masse d'antenne définissent des vitesses de propagation pour des ondes électromagnétiques se propageant dans cette antenne le long de cette fente. La largeur de la fente résonante est typiquement uniforme. Mais cela n'est pas nécessaire. Dans le cas où elle est uniforme et où il en est de même des caractéristiques du substrat et du milieu ambiant au dessus du substrat, la vitesse de propagation d'une onde est constante le long de la fente résonante. Cette vitesse dépend alors seulement de la fréquence de cette onde. La pastille et la masse d'antenne constituent ladite structure résonante. Cette masse présente typiquement la forme d'un ruban dont la largeur est par exemple constante. Un tel ruban constitue un ruban de masse. Sa largeur est limitée pour que le couplage de l'antenne à des ondes rayonnées puisse se faire à partir d'un bord externe de ce ruban.

In accordance with FIGS. 1, 2 and 3 and in a manner known per se, a loop slot antenna according to the present invention firstly comprises a resonant structure which itself comprises the following elements:

• A dielectric substrate 2 having two mutually opposite main surfaces. These two main surfaces respectively constitute a lower surface and an upper surface. They extend in horizontal directions defined in this antenna and more precisely in a longitudinal direction DL and in a vertical direction DT, these two directions being shown in Figure 2. The shape of this substrate is typically that of a flat sheet rectangular with uniform composition and thickness. But this is by no means an obligation. In particular, said surfaces can be curved and the nature and thickness of the substrate can vary.
• A lower conductive layer 4 extending for example over a fraction of this lower surface of the substrate and constituting the previously mentioned auxiliary conductive layer. This layer has an upper surface in contact with the substrate and a lower surface opposite this upper surface.
• A first fraction of an upper conductive layer extends over this upper surface above the layer 4 and constitutes a patch 6 of the type designated internationally by the English word patch. This patch has a length and a width extending in the longitudinal direction DL and the transverse direction DT, respectively, and its periphery is constituted by four edges extending two by two substantially in these two directions. Although the words length and width usually apply to the two mutually perpendicular dimensions of a rectangular object, the length being greater than the width, it should be understood that the patch 6 can deviate from the shape of such a rectangle without departing from the scope of this invention. More particularly, the directions DL and DT may form an angle other than 90 degrees, the edges of this patch may not be straight and may not be separated by angular vertices and the shape of the patch may also be circular or elliptical. One of the edges of the patch shown extends in the transverse direction DT and constitutes a rear edge 50. A front edge 52 is opposite this rear edge. Two lateral edges 54 and 56 join this rear edge to this front edge. The cumulative length of these four sides constitutes a perimeter P of the patch.
• A second fraction of said upper conductive layer surrounds the patch 6. It constitutes an antenna mass 8. It is separated from this patch by a slot constituting a resonant slot 10. It extends over a limited distance from this slot . Said substrate, this patch and this antenna mass define propagation speeds for electromagnetic waves propagating in this antenna along this slot. The width of the resonant slot is typically uniform. But it is not necessary. In the case where it is uniform and the same applies to the characteristics of the substrate and of the ambient medium above the substrate, the speed of propagation of a wave is constant along the resonant slit. This speed then only depends on the frequency of this wave. The patch and the antenna mass constitute said resonant structure. This mass typically has the form of a ribbon whose width is for example constant. Such a ribbon constitutes a mass ribbon. Its width is limited so that the antenna can be coupled to radiated waves from an external edge of this strip.

The antenna further includes a coupling device. As known in this type of antenna, this device has the form of a line of coplanar type transmission. On the one hand it has a main conductor consisting of a longitudinal coupling tape 18 extending over the surface top of the substrate. This ribbon is connected to the patch 6 in the middle of said rear edge 50. This device also comprises a ground conductor 20 consisting of a third and a fourth fraction of the conductive layer upper, these two fractions being located on either side of the ribbon 18. The electric field lines of the traveling waves guided by this line of transmission are established through two longitudinal slots separating this ribbon of these two fractions.

Within the framework of a radiocommunication device, this coupling constitutes all or part of a connection assembly which connects the resonant structure of the antenna to a said signal processing member. In the device given as an example, this assembly also includes a line connection which is external to the antenna.

In FIG. 1, such an external connection line to the antenna has been symbolically represented in the form of two conducting wires 28 and 30. These two wires respectively connect the coupling tape 18 and the ground conductor 20 to a signal terminal 14 and to a ground terminal 16 of the signal processor 12. But it should be understood that such a line would in practice be preferably carried out in the form of a line coplanar, a microstrip line or a coaxial line.

The signal processor 12 is adapted to operate at predetermined operating frequencies that are at least close to the useful resonant frequency of the antenna, i.e. which are included in a bandwidth centered on this resonant frequency. He can be composite and then have an element permanently tuned to each of these operating frequencies. It can also include a tunable element on the various operating frequencies. This resonant frequency F is such that the product PxF of this frequency by the said perimeter P of the patch is close to half V / 2 of a speed of mean propagation V of an electromagnetic wave having this frequency and propagating in this antenna along said resonant slot. That is to say that this frequency is that of a so-called half-wave resonance.

According to the present invention said conductive layer auxiliary is decoupled from said structure resonant and said signal processor at least for any signal having a said radio frequency, the said operating frequencies constituting in particular such frequencies. This decoupling allows this layer to reflect the said radiated electromagnetic waves without altering substantially said useful resonant frequency defined by this structure of so that this layer constitutes a wave reflector 4. This function of wave reflector is different from that of the mass layers that extend on the lower surface of the substrate of known loop slot antennas. This invention takes advantage of the fact that when such a layer of mass lower of known antennas allows the development of parasitic modes of the type of parallel plates, this is because this layer is connected to the antenna mass formed by the upper conductive layer.

Preferably the area which is occupied by the wave reflector on the bottom surface of the substrate includes that occupied by the structure resonant on the upper surface of the substrate. It can be beneficial in some application cases where the area of the reflector extends beyond the area of the resonant structure to very strongly limit the emission of parasitic waves radiated to the areas below the plane of the antenna. He can be advantageous in other cases to make these two areas substantially coincide to make a more compact antenna while limiting enough the emission of such parasitic waves.

Preferably said area which is occupied by the wave reflector excludes the one occupied by said coupling device on the upper surface of the substrate. This arrangement prevents a spurious coupling between the resonant structure and the wave reflector through the coupling.

• ladite pastille,
• ladite masse d'antenne,
• ladite borne de signal de l'organe de traitement de signal,
• ladite borne de masse de cet organe,
• ledit conducteur principal de l'ensemble de raccordement, et
• le dit conducteur de masse de cet ensemble.

Preferably, an electrical insulation is produced between on the one hand said wave reflector and on the other hand:

• said pellet,
• said antenna mass,
• said signal terminal of the signal processing member,
• said earth terminal of this organ,
• said main conductor of the connection assembly, and
• said ground conductor of this set.

Such insulation is ensured both against direct current and with respect to alternating currents. It helps to limit the risk of pairings parasites. Means for achieving it are constituted inter alia by the substrate 2 and by a separating layer 22 which will be described below.

Preferably the radio communication device further comprises a spacing means for maintaining a decoupling distance predetermined between said wave reflector 4 and an object approaching this reflector on the side of said lower surface of this reflector.

Preferably said spacing means is constituted by a layer electrically insulating separator 22 fixed to said lower surface of this reflector 4, this layer having a thickness constituting said distance of decoupling.

Preferably said separating layer 22 is made of a material having a relative permittivity less than 2 and preferably still close to unity. In the context of this invention the thickness of this layer must indeed be chosen sufficiently large and its dielectric constant represented by its relative permittivity must be chosen small enough to avoid or less limit parasitic capacitive coupling between the reflector and all component or conductor subjected to variations in electrical potential at a called radio frequency. Such coupling is to be feared in the event that this component or conductor can come into contact with this separating layer. Of such components or conductors are included in particular in the Signal processing. This is why, preferably still, and with the aim of compactness, said separating layer 22 is interposed between said reflector of waves 4 and said signal processing member 12. It is for example constituted by an organic polymer having the form of a rigid foam, or by a massive material of very small dielectric constant.

• un microphone 24 pour moduler un signal électrique émis par ledit organe de traitement de signal 12 vers ladite antenne à fente en boucle 1, et
• un écouteur 26 pour fournir un signal sonore représentatif d'une modulation d'un signal électrique reçu par ledit organe de traitement de signal en provenance de ladite antenne.

The radiocommunication device according to the invention can in particular constitute a mobile terminal for a radiotelephony network. It then further comprises at least:

• a microphone 24 for modulating an electrical signal emitted by said signal processing member 12 towards said loop slot antenna 1, and
• an earpiece 26 for supplying a sound signal representative of a modulation of an electrical signal received by said signal processing unit from said antenna.

In this case, preferably said wave reflector 4 is interposed between said resonant structure 6, 8, 10 of the antenna and at least said listener. It is known that a fraction of the radiation emitted by the antenna of such a terminal can be intercepted by the head of a user of this terminal. This position of wave reflector allows at least to limit such a fraction. More generally the wave reflector is interposed, as is the layer separator, between this resonant structure and the rest of a radiocommunication.

• fréquence de résonance F=1 180 MHz,
• impédance d'entrée : 50 Ohms,
• composition du substrat : résine époxy ayant une permittivité relative e_r égale à 4,3 et un facteur de dissipation tg d égal à 0,03,
• épaisseur du substrat : 2 mm,
• épaisseur de la couche séparatrice : 8 mm
• composition des couches conductrices : cuivre,
• épaisseur de ces couches : 17 microns,
• longueur du substrat : 42 mm,
• largeur du substrat : 50 mm,
• longueur de la pastille : 26 mm,
• largeur de la pastille : 33 mm,
• longueur du réflecteur d'ondes et de la couche séparatrice : 40 mm,
• largeur de la fente résonante : 0,8 mm,
• largeur du ruban de masse : 5 mm,
• largeur du ruban de couplage : 5 mm,
• largeur des fentes situées des deux côtés de ce ruban : 0,8 mm.

In the context of a particular embodiment of an antenna according to this invention, various arrangements, compositions and values will be indicated below. The lengths and widths are indicated respectively in the longitudinal directions DL and transverse DT. The antenna is symmetrical with respect to an axis A. The substrate is rectangular and it has four edges which are a rear edge, a front edge and two lateral edges and which are respectively opposite the edges of the same names of the patch. The edges of the upper conductive layer coincide with those of the substrate. The wave reflector and the separating layer have front and side edges which coincide with those of the substrate. But it is not the same with their front edges.

• resonant frequency F = 1180 MHz,
• input impedance: 50 Ohms,
• composition of the substrate: epoxy resin having a relative permittivity e _r equal to 4.3 and a dissipation factor tg d equal to 0.03,
• substrate thickness: 2 mm,
• thickness of the separating layer: 8 mm
• composition of conductive layers: copper,
• thickness of these layers: 17 microns,
• substrate length: 42 mm,
• substrate width: 50 mm,
• length of the patch: 26 mm,
• pad width: 33 mm,
• length of the wave reflector and the separating layer: 40 mm,
• width of the resonant slot: 0.8 mm,
• width of the mass ribbon: 5 mm,
• width of the coupling tape: 5 mm,
• width of the slots on both sides of this tape: 0.8 mm.

The diagram in Figure 4 was drawn from measurements made on the antenna whose encrypted characteristics have been indicated above. On this figure the 0 dB level corresponds to the upper horizontal reference line. The difference between two horizontal tracking lines represents 10 dB. The extreme frequencies of the scale shown are 700 and 2000 MHz. The peak of resonance presented by the diagram corresponds to the resonance frequency useful F previously indicated.

Claims (13)

Radiocommunication device, this device comprising a loop slot antenna (1) capable of coupling electrical signals to radiated electromagnetic waves, this antenna comprising: a resonant structure defining a useful resonant frequency of this antenna, this structure extending in a surface constituting an antenna plane, and an auxiliary conductive layer extending opposite said resonant structure in a surface extending at a distance from said antenna plane, said radiocommunication device further comprising a signal processing member (12) for processing said electrical signals,
said radiocommunication device being characterized in that said auxiliary conductive layer is decoupled from said resonant structure and from said signal processing member at least for any signal having a radio frequency close to said useful resonant frequency. Radiocommunication device according to claim 1, this device comprising: a dielectric substrate (2) having a lower surface and an upper surface, said auxiliary conductive layer, this layer having an area on said lower surface of the substrate and constituting a wave reflector (4), this reflector having an upper surface in contact with said substrate and a lower surface opposite this upper surface, and an upper conductive layer extending over said upper surface of the substrate and forming: a patch (6) having a perimeter (P), an antenna mass (8) surrounding said patch while being separated from this patch by a slot, this slot constituting a resonant slot (10), this mass extending over a limited distance from this slot, this patch, this slot and this antenna mass constituting said resonant structure, this structure having an area on said upper surface of the substrate, this area being included in said area of the wave reflector, this structure defining propagation speeds for electromagnetic waves of this antenna propagating along this slot, and a coupling device, this coupling device having the form of a coplanar line having an area on said upper surface of the substrate, this coupling device comprising: a coupling tape (18) connecting to said pad, and a ground conductor (20) connecting to said antenna ground and extending on both sides of said coupling strip while being separated from this strip by a slot on each said side of this strip, said signal processing member (12) having a signal terminal (14) and a ground terminal (16) and being tuned to transmit and / or receive an electrical signal in the vicinity of said useful resonant frequency (F) of l antenna, the product (PxF) of this useful resonance frequency by said perimeter (P) of the patch being close to half (V / 2) of an average propagation speed (V) of a said electromagnetic wave having this frequency and propagating along said resonant slit,
said radiocommunication device being characterized in that said area of the wave reflector (4) excludes said area of the coupling device. Radiocommunication device according to claim 2, this device comprising a connection assembly, this assembly comprising: a main conductor including said coupling strip (18) and connecting said signal terminal (14) of the signal processing member (12) to said pad (6) at least for any signal having a said radio frequency, and a ground conductor including said ground conductor (20) of the coupling device and connecting said ground terminal (16) of the signal processing member to said ground of the antenna at least for any signal having a said radio frequency , said radiocommunication device being characterized by the fact that it comprises electrical isolation means (2, 22) between on the one hand said wave reflector (4) and on the other hand: said pellet (6), said antenna mass (8), said signal terminal of the signal processing member, said earth terminal of this organ, said main conductor of the connection assembly, and said ground conductor of this assembly. Radiocommunication device according to claim 2, this device being characterized in that it further comprises a means spacer (22) to maintain a predetermined decoupling distance between said wave reflector (4) and an object approaching this reflector of the side of said lower surface of this reflector. Radiocommunication device according to claim 4, this device being characterized in that said decoupling distance is between 5 mm and 10 mm. Radiocommunication device according to claim 4, this device being characterized in that said spacing means is constituted by an electrically insulating separating layer (22) fixed on said surface lower of this reflector (4), this layer having a thickness constituting said decoupling distance. Radiocommunication device according to claim 6, this device characterized in that said separating layer (22) is made of a material having a relative permittivity less than 2. Radiocommunication device according to claim 6, this device characterized in that said separating layer (22) is interposed between said wave reflector (4) and said radiation processing member signal (12). Radiocommunication device according to claim 6, this device constituting a mobile terminal for a radiotelephony network and further comprising: a microphone (24) for modulating an electrical signal emitted by said signal processing member (12) towards said loop slot antenna (1), and an earpiece (26) for providing a sound signal representative of a modulation of an electrical signal received by said signal processing unit from said antenna, said wave reflector (4) being interposed between said resonant structure (6, 8, 10) of the antenna and at least said listener. Loop slot antenna, this antenna comprising: a dielectric substrate (2) having a lower surface and an upper surface an auxiliary conductive layer extending over said lower surface of the substrate and having an area on this lower surface, and an upper conductive layer extending over said upper surface of the substrate and forming: a patch (6), said auxiliary conductive layer being isolated from this patch, and an antenna mass (8) surrounding said patch while being separated from this patch by a slot, this slot constituting a resonant slot (10), this patch, this slot and this mass constituting a resonant structure, this structure having an area on said upper surface of the substrate, this area being substantially included in said area of the auxiliary conductive layer, said loop slot antenna being characterized in that said auxiliary conductive layer (4) is further isolated from said antenna mass so as to constitute a wave reflector for radiated electromagnetic waves emitted or received by said resonant structure . Loop slot antenna according to claim 10, this antenna further comprising a coupling device formed by said upper conductive layer, this coupling device having the shape of a coplanar line having an area on said upper surface of the substrate, this device coupling comprising: a coupling tape (18) connecting to said pad, and a ground conductor (20) connecting to said antenna ground and extending on both sides of said coupling strip while being separated from this strip by a slot on each said side of this strip, said loop slot antenna being characterized in that said area of the wave reflector (4) excludes said area of the coupling device. Loop slot antenna according to claim 10, said antenna being characterized in that said wave reflector (4) carries a layer electrically insulating separator (22) on one side of this reflector opposite said substrate (2). Loop slot antenna according to claim 12, said antenna being characterized in that said separating layer (22) has a thickness between 5 and 10mm.

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