FR2916087A1 - MINIATURIZED PROPELLER ANTENNA FOR CONSUMER USE - Google Patents

Abstract

The present invention relates to the realization of miniaturized antennas, directives or not, used in particular in a context of consumer applications, which are weakly sensitive to their environment of use.

Description

MINIATURIZED ANTENNA FOR CONSUMER USE

  The present invention relates to the production of families of antennas, directives or not, of size adapted to general public uses, and presenting new characteristics of low sensitivity compared to a general public use (proximity of the hand or the head , proximity of drivers in particular). They are particularly useful in particular in a context of remote control and telecommunications for the general public, identification without contact (RFID according to conventional terminology), and as television antennas that is to say in aspects of dimensions, weight and cost (cost direct cost but also cost of integration into a system) are as much or more important than the pure technical performance. Devices for the general public using radio communications (eg point-to-point transmission of video images) or which are remotely controlled are becoming more numerous, and these devices use various frequency bands, ranging from 27 Megahertz (Mhz) up to 2.4 Gigahertz (Ghz) and beyond. Non-contact identification techniques frequently use the 13.56 MHz frequency band, and television uses frequencies ranging from more than 100 MHz to almost 1 Ghz. The principles of the invention apply to a frequency range which includes frequencies from 10 MHz to several GHz. When these devices present in the same place are numerous, it is advantageous to have a directional radio link that either helps the user to select the device he wants to control, or improve the quality of a link point-to-point radio.

  In the context of a general public use, it is advantageous to have directional antennas that have all of the following characteristics: a) technical performance in terms of directivity and gain 5 adapted to the application considered b) dimensions and cost as low as possible; c) very easy to use in the usual electronic environment for such devices, particularly low sensitivity to the environment, and in particular proximity to the user or other devices Technical examples, for example conductors such as metal masses or batteries. It will be appreciated that: a) the requirements described above are different from those for professional use, in which on the contrary the maximum technical performance is required; size can relate to the antenna itself as well as to the dimensions of the ground plane associated with it 20 c) when the distance e between the transmitter and the receiver is weak, the absolute gain of the antennas used is not necessarily an essential point d) the bandwidth allowed by the antenna is often an important element for the applications; in particular, the ISM frequency bands, ie the industrial, scientific and medical frequency bands for which a prior license is not required, often impose bandwidths of the order of a few percent ( this is particularly the case for the 2.4 Ghz frequency band, whose bandwidth is about 3.4%). A main aim of the present invention is to favor consumer applications, and in particular applications mentioned above, by providing antennas that can be integrated into small and low-cost consumer electronic devices, such as, for example, remotes or wireless communication networks, user terminals for contactless identification or television antennas, and which allow a use as simple as possible within the framework of these applications. Another main object of the invention is to use the possibilities of reducing the size of the antennas allowed by the invention to make antennas of as small a size as possible, the notion of size of the antenna including the minimum size of the antenna. ground plane that is necessary for proper operation of the antenna.

  In the field of antennas, mention may be made of the following references: Reference 1. The book Antennas for all applications by John D. Kraus and Ronald J. Marhefka, which in particular describes in detail various types of antennas, including antennas helix, and as well as many techniques of calculation relating to antennas Reference 2. The article of IEEE Transactions on antennas and Propagation Vol 39 N June 6, 1991 Study of an internally matched helical beam antenna This document describes the general principle as well as the setting detailed implementation of a helical antenna whose dimensions are reduced thanks to slow wave techniques, these techniques being implemented with respect to surfaces and by means of inductances and distributed capacitors whose value is calculated explicitly to from said surfaces. This principle is therefore inapplicable to antennas without facing surfaces that are significant and determinable. Furthermore, the internal operation of the antenna is not detailed since it refers to a helix in axial mode, while the propagation time calculations inside the antenna show significant differences with respect to a conventional helical antenna operating in axial mode. Reference 3. The Spiro Helical Antenna which is the PhD Thesis of Idine Ghoreishian at the Virginia Polytechnic Institute and State University and is available via the Internet at http://scholar.lib.vt.edu/theses/available / etd-120899-112725 / which indicates that the access to the document is without restriction and gives access to the document by downloading This document describes the general principle as well as the detailed implementation of a helical antenna operating in axial mode whose dimensions are reduced by replacing the wired conductor of a conventional propeller with a primary propeller; the limitations of this technique are also mentioned in this document, namely a very high impedance and having a significant reactive component. Reference 4. The Radioengineering article Volume 10 No4, December 2001 entitled Solenoid above ground plane - Equivalent circuit This document describes a solenoid modeling valid for frequencies from 45 Mhz to more than 10 Ghz and validates it from measurements concrete. The equivalent circuit resulting from the modeling notably comprises capacitors between each turn of the solenoid. This document is limited to a simple modeling of the solenoid. Reference 5. This article describes the influence of the size of the ground plane of a working helical antenna. in axial mode: when the ground plane has an important dimension, the antenna radiates in a direction opposite to the ground plane, when the ground plane has a reduced dimension or does not exist, the axis of radiation is in the direction of the mass plan, that is to say of opposite direction compared to the previous case. No possibility of miniaturization is mentioned in this document. Reference 6. The Internet page 6.6 Piece-wise uniformly electrically linear dielectrics (http://web.mit.edu./6.013 book / www / chapter6 / 6.6.html) which describes the behavior of electric field lines at the boundary between two media of different dielectric constants, and in particular why the electric field lines diverge by passing to a lower dielectric constant medium. These references, and in particular Reference 1, themselves contain other references which may be useful for the present invention. Compared to the previous solutions, the present invention provides the following advantages: a) High insensitivity with respect to the immediate environment (electrical conductors and user's body in particular) b) Small dimensions of both the antenna and the associated ground plane c) Ease of obtaining antennas with purely real impedance d) Ease of managing resonance frequencies e) High simplicity and low manufacturing cost f) Ease of use in usual technical environments for consumer devices As will be seen below, and in particular in the section Experimental observations, antennas according to the invention have particularly advantageous characteristics. Furthermore, the antennas according to the invention which are made with insulated wire can not be made with all categories of insulated wire.

  PRESENTATION OF THE FIGURES Other features and advantages of the invention will become apparent from the following description, given by way of non-limiting example, with reference to the appended figures in which: FIG. 1 shows an example of an elementary cell antenna according to the invention, and Figure 2 an example of an electric field inside this mesh. Figure 3 shows a detail of the electric field inside the mesh in a configuration according to the invention, and Figure 4 shows the same detail in a different configuration of the invention. Figures 5 to 11 show different examples of elemental meshes according to the invention.

  Figure 12 shows a detail of the electric field for the elementary mesh of Figure 5. Figures 13 to 16 show antenna structures that are variants of the invention.

  DETAILED DESCRIPTION OF THE INVENTION In the various figures, the same references have been retained to designate identical or similar elements.

  A) EXPERIMENTAL OBSERVATIONS The observations below relate to concrete examples of antennas having particular and advantageous characteristics for a general public use, which can be realized simply and economically. A.1) A 2.4 Ghz directive antenna, associated with a minimum ground plane There is currently no antenna for a 2.4 Ghz frequency which has all of the following characteristics: - a strong directivity - small dimensions including before the ground plane (dimensions of the order of a few millimeters to be able to be included in a mobile phone) very low sensitivity with respect to its close environment, and in particular low sensitivity with respect to proximity The present invention has made it possible to make such an antenna. A.2) A real impedance antenna at 13.56 Mhz, insensitive or adapted to its environment There is currently no miniaturized antenna 30 operating at 13.56 MHz which is not disturbed by a close metallic environment , especially with regard to the possibility of keeping a real impedance while the near metallic environment varies. The present invention has made it possible to produce such an antenna.

  B) AN EXAMPLE OF ANTENNA ACCORDING TO THE INVENTION FIGS. 1 and 2 describe an example of an elementary radiating antenna mesh (ARA) according to the invention. For this example, the case of a cylindrical helix wound with contiguous turns with insulated wire was chosen. It will be shown later that various other means of implementing the invention are possible. This antenna comprises a succession of elementary cells, as described by FIGS. 1 and 2.

  Figure 1 illustrates the physical arrangement of the elements of an elementary mesh of such an antenna: a) (EMC) is the electromagnetic field to which the antenna is subjected (if it is in reception) or that it generates (if it is in transmission), the antenna providing a variable electrical signal (SEL) if it is in reception or being subjected to a variable electrical signal (SEL) if it is in emission b) (CO) is a conducting wire of which (P1X) and (P2X) are two consecutive portions, and (P1X) and (P2X) are respectively first and second consecutive portions of the conductor (CO), of substantially similar geometric shapes, arranged: - alternately and in sequence along the path 30 of the electromagnetic field (EMC) associated with the electrical signal (SEL) variable, - in a preferred direction (DIP) d) (ISX) is a dielectric constant insulator significantly greater than that of the ambient medium (MIA) of the antenna radiative (ARA), the ambient environment being typically air for general public use e) it can be assumed without loss of generality that the electric field lines are arranged from the left to the right of the

  For Figure 1, but also for all the radiating antennas (ARA) according to the invention: aa) The portions (P1X) and (P2X) are of substantially similar geometric shapes, and arranged in a preferred direction (DIP), which means in the context of the invention that, substantially: - one passes continuously and gradually between the geometric shapes of portions (P1X) and (P2X) consecutive - the geometric shapes of portions (P1X) and (P2X) consecutive are parallel bb) A substantially cylindrical spirally wound helical (CO) conductor satisfies condition aa) cc) A substantially conical spiral wound continuous conductor (CO) satisfies condition aa) dd) In examples bb) and cc) the axis of the cylinder or cone may be a straight line or a regular curve ee) A continuous conductor (CO) coiled in planar spiral or on a substantially regular surface satisfies condition aa) ff) Conductive non-continuous conductor (CO) consisting of straight, parallel and adjacent dimensions satisfies condition aa) gg) A non-continuous conductor (CO) consisting of parallel elements of similar shapes and sizes satisfies condition aa) hh) The electrical signal (SEL) and the electromagnetic field (EMC) are by definition variable in time in the case of a radiating antenna; in the general case, therefore, the portions (P1X) and (P2X) are not at the same electrical potential, and electric field lines therefore exist between these portions For Figure 2, but also for all the radiating antennas (ARA) according to the invention: ii) in general, at each point in the space, the electric field E, the magnetic field B and the vector representing the electromagnetic wave are linked by the Maxwell equations kk) consequently, the conditions imposed on the electric field existing between the portions (P1X) and (P2X) by an element (ECX) acting on the electromagnetic coupling between the first portion (P1X) and the second portion (P2X) of such a pair successive portions impose constraints on the entire electromagnetic field received or generated by the radiating antenna (ARA) 11) in the context of the present invention, the constraints on the electric field: - relate to the said field close, ie inside and in the vicinity of the antenna - come from phenomena of refraction or reflection of the electric field lines due to the interfaces 30 existing between the various elements that make up each element (ECX) and the ambient environment (MIA) mm) it will also be noted that there are electric field lines that are not impacted by the preceding mechanism, and that are those that are substantially perpendicular to the axis that joins the centers of the portions (P1X) and (P2X) the antenna can radiate and the preceding mechanism has no direct or automatic consequence on the far field or the radiation pattern

  Figure 2 illustrates the interactions between the portions (P1X) and (P2X): a) (P1X) and (P2X) are the two consecutive portions of the radiating antenna (ARA) arranged as in Figure 1 b) the insulator (ISX) due to its significantly higher dielectric constant than that of the ambient medium (MIA) of the radiating antenna (ARA) locally influences the interface between the insulator (ISX) and the ambient medium (MIA) the lines of the field electrical connection (CEX) connecting the first portion (P1X) to the second portion (P2X) c) the insulation (ISX) therefore acts in this case as an element (ECX) acting on the electromagnetic coupling between the first portion (P1X) and the second portion (P2X) of the pair Figure 3 details the coupling mechanism between the portions (P1X) and (P2X) shown in Figures 1 and 2; in this figure: a) (P1X) and (P2X) are two consecutive portions, and the preferential direction (DIP) is the direction on which the portions (P1X) and (P2X) b) are aligned (ISX) is an insulator of a dielectric constant significantly greater than that of the ambient medium (MIA) and whose thickness is at least comparable to the diameter of the first portion (P1X) and the second portion (P2X) of the pair of successive portions; in the context of the figure, and more generally in the context of the invention, typically the ambient medium (MIA) is air c) when the ambient medium is air a dielectric constant significantly greater than that of the ambient environment (MIA) of 2 or 3 is enough; this means that the insulation (ISX) may be a common plastic material such as in particular PVC or Teflon (trademark); a higher dielectric constant can also be used, and for example, be obtained by using a common plastic material loaded with materials of higher dielectric constant, such as for example titanium dioxide d) as stated above, insulator (ISX) therefore acts in this case as an element (ECX) acting on the electromagnetic coupling between the first portion (P1X) and the second portion (P2X) of the pair e) (LEA), (LEB) and (LEC) ) are a three-element cutting of a line of the electric field (CEX) connecting the first portion (P1X) to the second portion (P2X) f) between these three elements of electric field line, there are two interfaces between the insulation (ISX) and the environment (MIA) g) the element (LEA) corresponds to the portion of the electric field line extending from the conductor of the portion (P1X) and located inside the insulation (ISX) ); the element (LEB) corresponds to the part of the electrical field line located in the environment (MIA); the portion (LEC) corresponds to the portion of the electric field line arriving at the conductor of the portion (P2X) and located inside the insulator (ISX) h) the outer surface of the insulator (ISX) which covers both portions (P1X) and (P2X) is assumed substantially regular; as a result, tangent and normal straight lines to the outer surface of the (ISX) insulation substantially existing at any point on this outer surface i) (Ni) is the line normal to the point where the electric field line leaves the insulation ( ISX) starting from the portion (P1X) and (N2) is the line normal to the point where the electric field line enters the insulator (P1X) while moving towards (P2X) j) Reference 6 indicates that the lines of electric field diverging by passing to a lower dielectric constant medium and converging by passing to a higher dielectric constant medium k) in the general case, there is a potential difference between the portions (P1X) and (P2X), and therefore electric field lines between these portions (P1X) and (P2X), assumed here, without loss of generality, going from the portion (P1X) to the portion (P2X) 1) is recalled that a line of electric field arriving on or leaving a perfect driver has Pass or leave the driver normally to this driver; in the case of a metallic conductor, a line of electric field arriving on or leaving this conductor arrives or leaves the conductor in a substantially normal manner to this conductor m) the electric field line (LEA) is thus directed from the left to the right towards the portion (P1X) and arrives under oblique incidence at the point where the electric field line leaves the insulator (ISX); at the point of intersection between the normal (Ni) and the outer surface of the insulator (ISX) of the portion (P1X), the electric field line diverges and therefore reorients to the right n) at the point of intersection between the normal (N2) and the outer surface of the insulator (ISX) of the portion (P2X), the electric field line converges; it reorients itself once again to the right o) the electric field has thus been reoriented twice 10 times to the right, and towards the preferential direction (DIP) p), it is therefore found that phenomena of guiding the electric field lines between the portions (P1X) and (P2X) exist and are generated by the existing interfaces 15 between: - on the one hand the elements that make up the elements (ECX) acting on the electromagnetic coupling between the two successive portions (P1X) and (P2X) the ambient environment (MIA) or other elements composing these elements (ECX) on the other hand

  The preceding elements refer mainly to considerations of the angles and shapes of the trajectories of electric field line lines; in particular, there is no reference to any particular frequency. Such a reorientation of the electric field lines is not automatic and does not exist in all cases. FIG. 4 indicates a case in which such a reorientation does not occur: in this figure, the insulator (ISX) has a thickness substantially smaller than the diameter of the first portion (P1X) and the second portion ( P2X) of the pair of successive portions -the electric field line element (LEA) leaves the conductor portion (P1X) substantially normal to that conductor; in this case, due to this small thickness, this field line element (LEA) is weakly reoriented towards the portion (P2X) and arrives substantially normal to the outer surface of the insulator (ISX) - so there is little difference between the case of Figure 4 on the one hand and a case in which the insulator (ISX) would be absent on the other hand Experimentally, we note that the use of conventional enamelled wire for the realization of the portions (P1X) and (P2X), that is to say with a thickness of insulator weak compared to the diameter of the conducting wire, does not allow to observe the phenomena observed with the antennas according to the invention However , it is important to note that if the thickness of the insulation (ISX) is important in absolute value, and in particular greater than 0.5 mm for the thickness existing between the outer surface of the conductor (CO) and the outer surface of insulation (ISX), phenomena such as they are described in Figure 3 can be observed, even if the relative thickness of the insulation (ISX) is low compared to that of the driver (CO).

  C) PRINCIPLES OF OPERATION OF THE INVENTION C.1) The elementary mesh of the antennas according to the invention C.1.1) An example of elementary mesh according to the invention The section B) An example of an antenna according to the invention above described a possible elementary mesh for a radiating antenna (ARA) according to the invention, described in Figures 1 to 4.

  C.1.2) Other examples of elemental mesh FIGS. 5 to 11 describe other examples of elementary cells for a radiating antenna (ARA) according to the invention.

  In all these figures, the preferential direction (DIP) joins the centers of the conductors of the portions (P1X) and P2X) and the remarks aa) to mm) inclusive of section B). An example of an antenna according to the invention above apply.

  Figures 5 to 8 describe elementary mesh variants using an insulator (ISX) and refraction phenomena of the electric field lines at the interfaces between the insulator (ISX) and the ambient medium (MIA).

  In all these figures, the insulator (ISX) covers the two portions (P1X) and (P2X) along a substantially regular surface with an insulation thickness (ISX) at least comparable to the diameter of the first portion (P1X) and of the second portion (P2X) of the pair of successive portions. Figure 12 summarizes, similarly to Figure 3, the path of an electric field line between the portions (P1X) and (P2X). It will be noted that, as in FIG. 3, at each interface between the insulator (ISX) and the ambient medium (MIA), the electric field line is concentrated in the vicinity of the preferential direction (DIP) and reoriented towards the latter. It will also be noted that this guide and concentration mechanism can be performed even if the distance between the successive portions (P1X) and (P2X) is greater than that indicated in the figure, and that the electric field line successively passes several once through the narrow part of the insulation (ISX). Figure 8 indicates that the section of the conductors of the portions (P1X) and (P2X) is not necessarily of circular section, and that many forms are possible for this section.

  FIGS. 9 to 11 describe variants of elementary cells using at least one element (ECX) acting on the electromagnetic coupling between the first portion (P1X) and the second portion (P2X) of the pair comprising a conductor (COX) of comparable dimensions to the diameter of the two portions (P1X) and (P2X) and at their distance which. is located in the vicinity of the two successive portions (P1X) and (P2X) -use the reflection of the electric field lines between the conductor (COX) to redirect the electric field lines connecting the first portion (P1X) to the second portion (P2X) ) substantially towards the preferential direction (DIP) and guide them in this preferential direction (DIP) In these elementary meshes, the phenomenon of guiding and concentrating the electric field lines is carried out at least partly by using the reflection of the field lines electrical: the conductor (COX), for example without an electrical connection to another conductor or a voltage source, receives the electric field lines from the portions (P1X) and is the starting point for new electric field lines pointing to (P2X), and the conductor dimension (COX) along the preferential direction (DIP) ensures this concentration and guiding phenomenon.

  C.1.3) The particular case of a continuous conductor Several variants described in section D) Some examples of variants, and in particular the variants described in Figures 13 to 15 show that the conductor (CO) of the portions (P1X) and ( P2X) can be a continuous driver. C.1.4) The particular case with discontinuous portions of conductor The variant described in section D) Some examples of variants according to Figure 16 shows that the conductor (CO) of portions (P1X) and (P2X) is formed by sections unconnected conductor.

  C.2) The electrical characteristics of the antennas according to the invention for: The antennas with continuous conductor C.2.1) The characteristic impedance of the structure formed by the conductor and his environment When the conductor (CO) of the portions (P1X) and (P2X) is a continuous conductor, and the at least one element (ECX) acting on the electromagnetic coupling between the first portion (P1X) and the second portion (P2X) of the pair comprises an insulator (ISX), then the first portions (P1X) and the second conductor portions (P2X) in combination with insulators (ISX) of dielectric constant significantly greater than that of the ambient medium (MIA) of the radiating antenna (ARA) form a transmission line having an impedance substantially constant distribution (ZDX) along the first portions (P1X) and second portions (P2X) of the conductor. This will be the case especially if the geometric dimensions of the portions (P1X) and (P2X) are close, their distances are close, and the insulator (ISX) has a thickness and a dielectric constant substantially constant. C.2.2) Favorable cases for the management of this characteristic impedance An advantageous case for the performance of the radiating antenna (ARA) is observed when the substantially constant distributed impedance (ZDX) has a value which is close to that of the medium. ambient (377 ohms for air).

  C.2.3) The influence of the antenna environment on this characteristic impedance The proximity of conductive elements such as metallic masses, other types of conductors (such as batteries) in the environment of use (EVU) of the antenna influences the impedance of the radiating antenna (ARA). In particular, it is observed experimentally that when the substantially constant distributed impedance (ZDX) is greater than that of the ambient medium (377 ohms for air), the proximity of metallic elements reduces this impedance, and consequently improves the performance of the the antenna. This result is particularly advantageous when the radiating antenna (ARA) is to be used in an environment with large metal masses. C.2.4) A substantially aperiodic structure and the management of resonance frequencies It has already been noticed that the mechanisms represented in FIG. 3 do not involve any particular frequency. When the impedance of the radiating antenna (ARA) is close to that of the ambient medium (377 ohms for air), when the conductor (CO) is a continuous conductor, and the conductor thickness (CO) of the portions (P1X) and (P2X) is close to the distance separating these two conductors (or alternatively that the thickness of the conductor (CO) is close to half the distance separating the centers of these conductors (CO) from the portions (P1X) ) and (P2X)), it is observed that the structure obtained does not, as such, have its own resonance frequency, and is therefore substantially aperiodic.

  However, resonance frequencies for radiating antennas (ARA) according to the invention may exist, and are related to the total length of the conductor (CO) associated with the portions (P1X) and (P2X) if the conductor (CO) is continuous, or the length of the various elements of the conductor (CO) associated with the portions (P1X) and (P2X) if the conductor (CO) is discontinuous. When the conductor (CO) is continuous, however, a first resonance frequency can typically be obtained by adjusting the total length of the conductor (CO), and it is observed that the variation of the wavelength of the resonant frequency is related to significantly linearly to the length of the conductor (CO). For example, for a helical antenna, a resonance frequency can be adjusted by simply varying the number of turns of the helix (this number of turns can be fractional such as 3.25 turns).

  It is typically observed that other resonant frequencies exist for such an antenna, and that these frequencies are often close to the harmonics of the first resonant frequency.

  C.2.5) The use of stray conductors One or more conductors not electrically connected to the portions (P1X) and (P2X) may be used in the radiating antennas (ARA) according to the invention. These conductors are called stray conductors (COP), with particular reference to helical antennas, in which the main conductor are added conductors of comparable shape and size that improve the performance of the antenna. In particular, it is possible to introduce more than one parasitic conductor (COP), each having a specific length. When the conductor (CO) is continuous, the stray conductor (s) may have a length which may be close to or different from the length of the conductor (CO). In the context of the present invention, and in particular for helical antennas, these parasitic conductors (COP) may have a specific resonant frequency, and this resonant frequency is generally related to the length of these conductors, and can be close to or different from the frequency of the conductor (s) (CO) The use of such parasitic conductors is particularly advantageous in the case of antennas according to the invention which have a helical configuration, but are not not limited to such configurations.

  A stray conductor (COP) does not need to be made with an insulated wire with an insulation (ISX) of dimension comparable to that of the conductor (CO). A classic enamelled wire with a thin insulation is enough.

  It will be noted that a parasitic conductor (COP) may behave as a conductor (COX) shown in Figures 9 to 11.

  D) SOME EXAMPLES OF VARIANTS Dl) 2.4 Ghz helical directional antenna D.1.1) The basic antenna A 2.4 Ghz helical radiating antenna (ARA) has been realized in the form of a cylindrical helix approximately 4 turns in diameter 4 mm, made with a 0.4 mm diameter wire surrounded by a PVC insulator (ISX) with a thickness of 0.2 mm, the wire having an outside diameter total of 0.8 mm.

  The inside of the propeller can be empty, include insulators or even conductors. The antenna may also have a slightly conical shape. Figure 13 shows such an antenna. The most advantageous points of this radiating antenna (ARA) are the following: - small dimensions - extremely high radiation intensity on the axis (AX) of this antenna 30 - operation substantially identical with mass planes of very different sizes, including ground plane whose outer diameter is comparable to that of the antenna (less than 1 cm). - very insensitive to its immediate environment of use (EVU), especially with respect to the present conductor or human body parts such as hand - ease of tuning the resonance frequency by setting the total conductor length (CO) - ease of obtaining several resonance frequencies by introducing stray conductors (see below) D.1.2) Antenna with stray conductors Stray conductors (COP) made especially using bare wire or conventional enamelled wire of diameter less than or equal to 0.4 mm may be added to the previous antenna. They make it possible in particular to increase the resonance at the working frequency if their own resonance frequency is close to that of the conductor (CO) or to introduce new resonance frequencies if their own resonance frequency is different from that of the conductor ( CO), for example having resonance frequencies at the frequencies of 2.4 Ghz and 5.9 Ghz. D.2) A spiral antenna for Rfid at 13.56 Mhz D.2.1) The spiral antenna Figures 14 and 15 describe spiral antennas that can be used in the context of non-contact identification transmissions (Rfid according to classical terminology). ) at 13.56 MHz. The antenna of Figure 14 is a spiral with a diameter of about 1.3 cm and a ring width (outer diameter - inside diameter) of about 3 mm, wound on a plane insulating support with a wire wire 0.1 mm in diameter surrounded by 0.05 mm thick Teflon (Trade Mark) insulation (ISX), the wire having a total outside diameter of 0.2 mm.

  Figure 15 shows the form that can have such an antenna to be included in a GSM mobile phone card (SIM card). The most advantageous points of this radiating antenna (ARA) are the following: - small dimensions, and therefore integrable in a SIM card including in the thickness of such a card - operation substantially identical with mass plans of very large sizes different, including with very small size ground plane very great adaptation to its immediate environment of use (EVU), especially with respect to the present of conductor or human body parts such as hand-impedance actual antenna when the resonance frequency of the antenna is far from the working frequency In particular, it is found that the impedance of such an antenna decreases when metal elements such as conductors or batteries are brought to a very close distance (of the order of a few millimeters) from the antenna. The drop in impedance improves the performance of the antenna in transmission, which is a particularly advantageous result. D.2.2) Loop antenna Figure 15 shows a second conductor (BO) at the output of the antenna. With this second conductor, it is possible to operate the antenna in magnetic loop mode, which may be advantageous when it is desired to charge the antenna with a variable impedance, as is the case in Rfid transmissions. D.3) A television antenna of reduced length Figure 16 shows an antenna conventionally called a Yagi antenna, commonly used as a receiving antenna for television broadcasts. In this antenna, the conductor (CO) is discontinuous and the portions (P1X) and the portions (P2X) arranged alternately and in sequence the log of the path of the electromagnetic field are the following of the directing elements, the receiver dipole and the reflector. In Yagi antennas, these elements may be straight segments or have other shapes, but they have similar shapes and sizes. Figure 12 shows how the techniques of the present invention can be applied to Yagi antennas: Figure 12 is a side view showing two successive elements of the Yagi antenna, for example two successive directors, a director and the receiver dipole , Or the receiver dipole and the reflector. These elements are covered with a significant thickness of insulation, for example an insulating thickness comparable to their diameter, and the refraction mechanisms of the electric field lines force a significant portion of the electric field lines existing between the portions (P1X). and (P2X) to transit for a substantial portion of their path inside the insulator (ISX). Under these conditions, they travel an electrical distance that is greater than the physical distance they travel, which reduces the distance between the portions (P1X) and (P2X) compared to what it would be in an antenna A classical Yagi in which electric field lines pass only through the air. This mechanism allows a reduction in the distance between the portions (P1X) and (P2X), but does not allow the reduction of the dimensions and in particular the length of the portions (P1X) and (P2X). For the reduction of these lengths, other techniques are usable, such as the use of helically wound son.

  E) THE CONCENTRATED OBSERVED BENEFITS The preceding examples have shown radiant (ARA) according to the invention advantageous characteristics as follows: - Insensitivity or adaptation to the immediate environment, whether it is conductors (metals, batteries) or in relation to the human body - Weak dimensions both the antenna and the associated ground plane - Ease of obtaining antennas with a purely real impedance - Ease of managing the resonant frequencies - Very simple and low manufacturing cost that the antennas had

  compared to - (as a result of the previous points) Ease of use in the usual technical environments for consumer devices

Claims (31)

  A radiant antenna (ARA) comprising: a) first portions (P1X) and second conductor portions (P2X) of substantially similar geometric shapes arranged alternately and in sequence along the path of the electromagnetic field (EMC) ) associated with the corresponding electrical signal (SEL), and in a preferred direction (DIP), b) for each pair of first portions (P1X) and second portions (P2X) at least one element (ECX) acting on the coupling electromagnetic between the first portion (P1X) and the second portion (P2X) of said pair, characterized in that said element (ECX) acting on the electromagnetic coupling between the first portion (P1X) and the second portion (P2X) of the pair has a nature and is arranged to concentrate in the vicinity of the preferential direction (DIP) and guide towards this preferential direction a substantial part (CEY) of the electromagnetic field (CE X) existing between the two successive portions (P1X) and (P2X), by means of guiding phenomena of the electric field lines, said guide phenomena being generated by the interfaces existing between: - on the one hand the elements that make up the elements (ECX) acting on the electromagnetic coupling between the two successive portions (P1X) and (P2X) - the ambient medium (MIA) or other elements composing these elements (ECX) on the other hand.   2. Antenna radiator (ARA) according to claim 1 characterized in that the at least one element (ECX) acting on the electromagnetic coupling between the first portion (P1X) and the second portion (P2X) of the pair comprises an insulator (ISX) a dielectric constant significantly greater than that of the ambient medium (MIA) of the radiating antenna (ARA) which: - covers the two portions (P1X) and (P2X) according to a substantially regular surface with an insulation thickness (ISX) at least comparable to the diameter of the first portion (P1X) and the second portion (P2X) of the pair of successive portions - uses the refraction of the existing electric field lines at the interfaces between the insulator (ISX) on the one hand and the ambient medium (MIA) on the other hand to reorient the electric field lines connecting the first portion (P1X) to the second portion (P2X) substantially to the preferential direction (DIP) and guide them according to this preferential direction (DIP)   3. Antenna radiator (ARA) according to claim 1 characterized in that the at least one element (ECX) acting on the electromagnetic coupling between the first portion (P1X) and the second portion (P2X) of the pair comprises a conductor ( COX) of dimensions comparable to the diameter of the two portions (P1X) and (P2X) and at their distance which: is located in the vicinity of the two successive portions (P1X) and (P2X) -use the reflection of the electric field lines between the conductor (COX) for redirecting the electric field lines connecting the first portion (P1X) to the second portion (P2X) substantially in the preferred direction (DIP) and guide them in this preferred direction (DIP)   4. Antenna radiator (ARA) according to any one of the preceding claims wherein the first portions (P1X) and the second portions (P2X) conductor form a continuous conductor   5. Antenna radiator (ARA) according to any one of the preceding claims wherein the first portions (P1X) and the second portions (P2X) of conductor are electrically unconnected   6. Antenna radiator (ARA) according to claims 1,2 and 4 wherein the first portions (P1X) and the second portions (P2X) conductor in combination with the insulators (ISX) of dielectric constant significantly greater than that of the ambient environment (MIA) of the radiating antenna (ARA) form a transmission line having a substantially constant distributed impedance (ZDX) along the first portions (P1X) and second portions (P2X) of the conductor   A radiant antenna (ARA) according to claim 6 wherein the substantially constant distributed impedance (ZDX) along the first portions (P1X) and second conductor portions (P2X) is comparable to that of the ambient medium (MIA) of the radiating antenna (ARA) in its conditions of use   8. Antenna radiator (ARA) according to claim 6 wherein the substantially constant distributed impedance (ZDX) along the first portions (P1X) and second conductor portions (P2X) is made closer to that of the ambient medium (MIA). ) of the radiating antenna by the use environment (EVU) of the antenna   9. Antenna radiator (ARA) according to claim 4 wherein the first portions (P1X) and the secondportions (P2X) conductor form a helical continuous conductor   10. Antenna radiator (ARA) according to claim 4 wherein the first portions (P1X) and the second portions (P2X) conductor form a continuous helical conductor of cylindrical shape   11. Antenna radiator (ARA) according to claim 4 wherein the first portions (P1X) and the second portions (P2X) of conductor form a conically shaped conical helical conductor 10   12. Antenna radiator (ARA) according to claim 4 wherein the first portions (P1X) and the second portions (P2X) conductor form a spiral continuous conductor 15   13. A radiating antenna (ARA) according to claim 4 wherein the first portions (P1X) and the second conductor portions (P2X) form a continuous conductor whose shape and diameter are substantially constant along the first portions (P1X) and second driver portions (P2X)   14. Antenna radiator (ARA) according to claims 2 and 13 wherein the following dimensions are similar: - half the distance between two first 25 portions (P1X) and second portions (P2X) successive - the diameter of the first portions (P1X) ) and second portions (P2X) of conductor   15. Antenna radiator (ARA) according to claims 2 and 13 wherein the first of the two following dimensions is greater than the second: - half the distance between two first portions (P1X) and second portions (P2X) successive- diameter of first portions (P1X) and second portions (P2X) of conductor   16. Antenna radiator (ARA) according to claims 7 and 14 wherein the structure formed by the first portions (P1X), the second portions (P2X) conductor and the elements (ECX) acting on the electromagnetic coupling between the first portion ( P1X) and the second portion (P2X) form a substantially aperiodic structure   17. Antenna radiator (ARA) according to claim 5 wherein the first portions (P1X) and the second portions (P2X) conductor form a Yagi type antenna   18. Antenna radiator (ARA) according to claim 1 in a helix having a very low sensitivity relative to its environment and a very low intensity intensity in the direction of its axis (AX) characterized in that it comprises at least one conductor wound with contiguous turns with insulated wire, with a conductor whose diameter is significantly smaller than the total external diameter of the wire, and that the length of this conductor is adjusted so that the radiating antenna (ARA) is in resonance at its frequency of job   19. Antenna radiator (ARA) propeller according to claim 18 characterized in that it also comprises another conductor configured spurious helix   20. helical radiating antenna (ARA) according to claim 18 characterized in that the conductor configured spurious helix has a resonant frequency close to that of the wound conductor contiguous turns with insulated wire   21. helical radiating antenna (ARA) according to claim 18 characterized in that the parasitic helix-shaped conductor has a resonant frequency different from that of the wound conductor contiguous turns with insulated wire   22. Antenna radiator (ARA) propeller according to claims 18 to 20 characterized in that the geometric dimensions of the at least one conductor are adapted to have a resonance frequency close to 2.4 Ghz   23. Antenna radiator (ARA) helical according to claims 18 to 22 characterized in that the geometric dimensions of the at least one conductor are adapted to have at least two resonant frequencies   24. Antenna radiator (ARA) according to claim 1 spiral having a very low sensitivity relative to its environment characterized in that it comprises at least one wound conductor with contiguous turns with insulated wire, with a conductor whose diameter is significantly less than the total outer diameter of the wire, with turns of diameters significantly identical, and substantially included in the same plane   Spiral radiating antenna (ARA) having a very low sensitivity to its environment according to claim 24, characterized in that the resonant frequency of the spiral is significantly close to the working frequency.   26. Spiral Antenna (ARA) spiral possessing. a very low sensitivity to its environment according to claim 24, characterized in that the resonance frequency of the spiral is significantly far from the working frequency   Spiral radiating antenna (ARA) having a very low sensitivity with respect to its environment according to claim 24, characterized in that it can also operate as a loop antenna   28. Antenna radiator (ARA) according to any one of the preceding claims, wherein portions (P3X) of conductors are added to the first portions (P1X) and the second portions (P2X) conductor, and not electrically connected to those to constitute parasitic conductors.   29. Antenna radiator (ARA) obtained by arranging a plurality of elementary antennas (AEL) in an antenna array, fed from a common point, characterized in that at least one elementary antenna (AEL) is a radiating antenna (ARA) according to any one of the preceding claims.   30. Antenna radiator (ARA) according to claim (29) obtained by arranging the antenna elements (AEL) antenna array substantially parallel.   31. Antenna radiator (ARA) according to claim (29) obtained by arranging the elementary antennas (AEL) antenna array along axes substantially concurrent in a common point.