FR2843835A1 - Portable radiotelephone antenna, has conductive surface parallel and placed at distance from radiating unit and provided with slot facing radiating unit, and conductive connection between surface and radiating unit - Google Patents

Abstract

The antenna has an antenna feed connected to a radiating unit (50) that is in a form of a plate. A conductive surface (66) is parallel and placed at a distance from the radiating unit. The surface is provided with a slot (68) facing the radiating unit and a conductive connection is provided between the surface and the radiating unit. The shape of the slot is identical to the shape of the radiating unit.

Description

i The present invention relates to a low volume antenna intended

  to be used in particular but not exclusively in

a portable radiotelephone.

  In portable radiotelephones, the use of helix-shaped antennas is known, which is most often mounted outside the radiotelephone case. These antennas may have a relatively small dimension but they are arranged outside the housing to be associated with a ground plane which is arranged

  inside the radiotelephone case.

  We know that the trend in the production of radiotelephones is to remove any external antenna to have it inside the housing. The trend is also to reduce the dimensions of the radiotelephone or at least to integrate it into the radiotelephone for

  a given external dimension of a larger number of components.

  It follows that it is advantageous for the design of a radiotelephone to have an internal antenna and dimensions

relatively small.

  To satisfy the first condition, it has been proposed to use plate antennas of the PiFa type or similar in radiotelephones. 20 These plate antennas which consist essentially of a plane of

  ground and by a radiating plate, more generally a radiant element parallel to the ground plane, also comprise a short-circuit connection between the radiant element and the ground plane as well as a 50 Q antenna feed most often performed at using a microstrip line or a printed circuit.

  In the frequency range used for radiotelephones and in particular for the frequency range corresponding to GSM which is of the order of 920 MHz, the minimum distance between the radiant element and the ground plane is of the order of 7 to 10 mm, at least when the dielectric disposed between the radiant element and the ground plane is air. This thickness of the order of 7 to 10 mm is considered to be too great for the production of radiotelephones. However, it can be seen that, if the aim is to reduce the thickness of the PiFa antenna in order to bring it for example to less than 5 mm, the bandwidth of this antenna is considerably reduced, which makes it practically unusable. Known plate antennas therefore do not respond

  more to the second condition set out above.

  An object of the present invention is to provide an antenna which can be used in particular in a portable radiotelephone which has a very small volume and a reduced thickness. To achieve this object according to the invention, the small volume antenna comprises a radiant element, said radiant element being constituted by means forming a coil having an axis, said coil being connected to an antenna conductor, and it comprises 10 in addition to a conductive element parallel to the axis of said coil which comprises means forming a slot arranged opposite said

coil means.

  It is understood that, according to the invention, the antenna is constituted by means forming a coil whose axis is parallel to a conductive element which is provided with a slot or an arrangement similar to a

  slot, opposite the means forming the coil.

  As will be explained later in more detail, this antenna arrangement, the volume of which is very small and the thickness of which is less than 5 mm nevertheless makes it possible, in particular in the range of frequencies corresponding to the GSM system, to obtain not only sufficient bandwidth, but much greater than that obtained with conventional antennas, this bandwidth for this range of

  frequencies up to 100 to 120 MHz, and sufficient gain.

  According to a preferred embodiment, the coil means are constituted by a conductive wire in the form of a helical coil. The tests carried out show that this coil can have a reduced diameter, of the order, for example, of 3 mm, and the distance between the slit conductive element and the axis of this coil can also be very reduced, by around 1.7 to 2 mm. An antenna is thus obtained,

  the overall thickness is less than 4 mm.

  The coil element may be a coil in the sense

  usual term, that is to say a helix formed from a conducting wire. The coil element can also be a "pilot" coil 35 formed by metallizations on an insulating support.

  The conductive element can be a conductive surface. In this case, this surface can be formed by the ground plane of the antenna and the slot is closed and has substantially a rectangular shape corresponding to the apparent outline of the coil. This surface can also be a conductive plate. In the latter case, the slot is open, that is to say it opens into the periphery of the conductive surface. The conductive element can also be a smear conductive element. In this case, it is folded back to present two substantially parallel elongated portions 10 defining between them the equivalent of a slot. Other characteristics and advantages of the invention

  It will appear better on reading the following description of several embodiments of the invention given by way of nonlimiting examples. The description refers to the appended figures, in which:

  - Figure 1A is a vertical sectional view of a first embodiment of the antenna according to the invention; - Figure 1B is a top view of the antenna shown in Figure 1A; - Figure 2 is a view of a first alternative embodiment of the antenna of Figure 1A; Figure 3 is a partial view of the antenna showing an alternative embodiment of the helical coil; FIG. 4A is a view in vertical section of a second embodiment of the antenna according to the invention; - Figure 4B is a detail view showing the particular shape of "flat" coils used; - Figures 5A and 5B show a second alternative embodiment of the antenna in vertical section and in top view; - Figure 6 is a vertical sectional view of a third alternative embodiment of the invention; and - Figures 7A and 7B are views respectively in elevation and from above of an antenna comprising a second embodiment

of the conductive element.

  Referring first to Figures 1A and 1B, we will describe

  a first preferred embodiment of the antenna according to the invention.

  The antenna consists essentially of a ground plane consisting of an electrically conductive material which is for example mounted or deposited on an insulating support 12. As shown better in FIG. 1B in the ground plane 10, a slot 14, the shape of which will be described in more detail later. The antenna also comprises a radiant element constituted by a helicofdale coil 16 whose axis XX 'is parallel to the ground plane 10. One of the ends 16a of the coil 16 is connected to the antenna supply 18 constituted for example by a coaxial cable 20 whose central conductor 20a is 10 electrically connected to the end 16a of the coil and whose shield b is connected to the ground plane 10. The coil 16 has a length L and a

diameter d.

  FIG. 1B shows in more detail the particular shape of the slot 14 produced in the ground plane 10. This slot 14 has the shape of a rectangle circumscribed around the external contour of the coil 16. In other words, the slot rectangular 14 has a length I which is substantially equal to the length L of the coil and a width 1 'substantially equal to the diameter d of the coil 16. This slot is closed, that is to say, it does not

  not lead into the periphery of the ground plane.

  In a particular embodiment, the coil 16 has a diameter d equal to 3 mm and the distance h between the ground plane 10 and the axis

  X-X 'of the coil 16 is equal to 1.72 mm.

  Indeed, to obtain a given impedance for the antenna, typically 50 Q2, the distance h between the coil, the ground plane and the diameter d of this coil are linked by the following formula ZO 138 Logio (4h Zo = - Lboglo / - / 4th d) In this formula, úr = 1 for air and ZO is equal to 50 Q. Furthermore, in this embodiment, the length L of the coil is equal to 20 mm. The dimensions of the slot 14 are therefore

mm by 3 mm.

  The tests carried out with the antenna as it has just been defined previously have shown that one obtained for the frequency range corresponding to the GSM system, that is to say for a central frequency of the order of 920 MHz, a bandwidth that goes from

at 120 MHz.

  Such bandwidth is not only widely

  acceptable for making a portable radiotelephone, but it is approximately twice as much as that obtained with antennas, for example antennas of the PiFa type.

  It should be emphasized that the total thickness of the antenna is reduced since, in the example considered, this thickness is less than 3.5 mm and that the construction of the antenna is also relatively simple, in particular because of the rectangular shape of the slot 14 to be produced

in the ground plane.

  In Figure 2, there is shown a first alternative embodiment of the first embodiment in which the supply of the coil 16 by the antenna cable 20 is different. Indeed, the axial conductor 15 of the cable 20a is connected to a current point 22 of the coil 16 while the end 16a of this coil is connected to the ground plane 10. This gives a "shunt" attack on the antenna which allows the realization

  an impedance corresponding to a selfic component.

  FIG. 3 shows an alternative embodiment of the coil 16 which then bears the reference 30. This coil comprises a

  first portion 32 whose turns have a first pitch Pl and a second portion 34 whose turns have a pitch P2 different from Pl.

  Furthermore, the helical antenna has a constant diameter d. Tests carried out with this type of helical coils have shown that the antenna effectively operates in two or three frequency bands defined by the judicious choice of the steps P1 and P2 of the two

  portions of the helical coil.

  Referring now to Figures 4A and 4B, we will describe a second alternative embodiment of the antenna. In this alternative embodiment, there is a ground plane 40 which is provided with a closed slot 42 and with a radiant element 44 constituted by a flat coil 44 shown in FIG. 4B. The flat coil 44 is formed by a zigzag shape of a flat conductive element 46. The end 46a of the flat antenna 44 is connected to the antenna conductor 48 formed by the coaxial cable 50. More precisely 46a is connected to the driver

central 50a of the cable 50.

  The tests carried out with this second embodiment of the antenna also give satisfactory results while being less than those obtained with the first embodiment of this antenna. Referring to Figures 5A and 5B, we will describe a second embodiment of the antenna. This second mode is essentially distinguished from the first by the fact that the conductive surface in which the slot is formed is not the ground plane of the antenna but

a conductive plate.

  In these figures, there is shown the coil 16 which can be

  identical to those shown in FIGS. 1A and 3. The antenna also comprises a conductive plate 50 which is parallel to the axis XX 'of the coil 16. The distance h between the axis of the coil and the plate is the same as in Figure 1A. This plate is not electrically connected to any other component of the antenna.

  The plate 50 is provided with a slot 52 whose contour corresponds to the shape of the coil. This outline 54 may have the general shape of a rectangle with two short sides in the form of semicircles 54a and 54b. It has been demonstrated that in this embodiment, for the antenna to have an acceptable gain, it is necessary for the slot 52 to open out by an extension 56 in the periphery 50a of the plate 50. The plate may have a length Ll equal to 35 mm and a width equal to 9 mm, the coil having the dimensions already mentioned in connection with FIGS. 1A and 1B. The antenna therefore has very small dimensions. The end 16a of the coil is connected to the central conductor 60 of the coaxial supply cable 62. The plate 50 is electrically insulated

conductor 60.

  This antenna can be mounted on a printed circuit 64 of a portable radiotelephone or of any other device with internal antenna. The shield 62a of the cable 62 is connected to a suitable ground of the printed circuit. With this second embodiment, we obtain the same

  performance than with the first embodiment. With a coil 16 with two separate steps, the antenna can operate in the GSM and DCS frequency band.

  In FIG. 6, another embodiment of

  the antenna according to the invention. According to this embodiment, there is the coil 16 and the conductive plate 50 with its open slot 52.

  The end 16a of the coil 16 is connected to the conductive plate 50 while the axial conductor 60 of the antenna cable is connected to an intermediate point 16b of the coil 16.

  FIGS. 7A and 7B show an embodiment of the antenna in which the conductive element is not constituted by a conductive surface but by a conductive wire element 70. The wire element 10 preferably has a diameter at less than 2.5mm. It comprises two substantially rectilinear portions 72 and 74 substantially parallel

between them.

  The first ends 72a, 74a of the straight portions are connected together by a curved portion 76. The second end 72b of the portion 72 is electrically connected to the shielding

  coaxial cable 62, while the second end 74b of the portion 74 is free. This wire element 70 thus defines the equivalent of a slot 76. The two portions 72 and 74 of the wire element 70 are substantially coplanar and arranged in a plane parallel to the axis XX ′ of the coil 16.

Claims (11)

  1. A small volume antenna comprising a radiant element, characterized in that said radiant element consists of means 5 forming a coil having an axis, said coil means being connected to an antenna conductor, and in that it further comprises a conductive element parallel to the axis of the coil means which comprises slot means arranged opposite said coil means.   2. Antenna according to claim 1, characterized in that said coil means consist of a conductive wire in helical coil shape.   3. An antenna according to claim 2, characterized in that said conductive element is a conductive surface and in that said slot means are constituted by a slot made in said conductive surface.   4. Antenna according to claim 3, characterized in that   said conductive surface is the ground plane of the antenna.   5. An antenna according to claim 3, characterized in that said conductive surface is a conductive plate and in that said   slot opens into the periphery of said plate.   6. An antenna according to any one of claims 4 and 5,   characterized in that said slot has a rectangular shape one side of which has a length substantially equal to the diameter of the coil and the other side of which has a width substantially equal to that of the coil.   7. An antenna according to any one of claims 4 to 6,   characterized in that said antenna conductor is connected to a end of the coil.   8. Antenna according to claim 4, characterized in that one of the ends of the coil is electrically connected to the ground plane and in that the antenna conductor is connected to a point coil current.   9. An antenna according to claim 2, characterized in that said conductive element is a wire element folded over to form two main parts substantially parallel to each other, each main part having a first end connected to the first end of the other main part, the slit means being constituted by   the space limited by the two main parts.   10. Antenna according to claim 9, characterized in that said two main parts of the wire element are arranged substantially in the same plane parallel to the axis of the coil.   11. An antenna according to any one of claims 2 to 10,   characterized in that said helical coil comprises a first portion having a first pitch and a second portion   presenting a second step distinct from the first.