FR2963487A1 - PARABOLIC REFLECTOR ANTENNA - Google Patents

Abstract

An antenna (30) has a parabolic reflector (31), provided with a skirt (32), which cooperates with a means (35) for transmitting incident radiation towards the reflector (31). The antenna (30) includes means for decreasing the distribution current appearing on the edge of the antenna (30). These means (34) are arranged on the front or side outer surface of the peripheral rim of the antenna (30). These means are preferably traps (34) in even number and arranged symmetrically. Preferably the angle formed by the sector of a trap (34) is of the order of 60 °. Each trap (34) has the shape of at least one conductive surface groove, the depth P and the width E are of the same order of magnitude, of the order of a fraction of the wavelength of the radiation. incident.

Description

The present invention relates to a parabolic reflector telecommunication antenna, used in particular for mobile communication networks.

These antennas operate indifferently in transmitter mode or in receiver mode, corresponding to two opposite directions of RF wave propagation. It should be noted that all the reasonings apply to the antennas as well in reception as in emission. In particular, the invention relates to a microwave antenna with a parabolic reflector. The invention applies both to dual reflector antennas and antennas having only one reflector. A conventional radiating aperture antenna comprises a reflector having a concavity, for example having the form of a paraboloid of revolution about the axis of symmetry of the antenna, and a feeding device located along the axis of the antenna. symmetry of the antenna transmitting the electromagnetic waves emitted or received by the antenna. The end of the radiofrequency waveguide is at the focus of the reflector. The waveguide is inserted into an orifice on the axis of the reflector, and its end is bent 180 ° to face the reflector. The maximum half-angle of radiation at the folded end of the waveguide to illuminate the reflector is small, of the order of 70 °. The distance between the reflector and the end of the waveguide must therefore be large enough to illuminate the entire surface of the reflector. In these parabolic reflector antennas, the value of the diameter D is determined by the central working frequency of the antenna. The lower the working frequency of the antenna (for example 7.1 GHz or 10 GHz) and the greater the diameter of the reflector is important at equivalent antenna gain: it is then necessary that the end of the waveguide is very far from the reflector to illuminate it well (emission mode), and the antenna becomes more cumbersome as the working frequency is low. For the shallow reflector antennas ("shallow reflector" in English), the F / D ratio is of the order of 0.36. In this report, F is the focal length of the reflector (distance between the top of the reflector and its focus) and D is the diameter of the reflector. These antennas have spillover losses which are high and reduce the front-to-back ratio of the antenna. In addition, wave diffraction appears from the peripheral edge of the antenna and increases the field at the rear of the parabolic reflector. Overflow losses, expressed in dB, lead to environmental pollution by RF waves and must be limited to levels defined by standards. In order to limit lateral radiation in particular, a usual solution is to attach to the periphery of the primary reflector a skirt ("shroud" in English which has the shape of a cylinder, of diameter close to that of the primary reflector and of suitable height In addition to the resulting bulk, this known solution has the disadvantage of the cost of the material of the skirt, as well as the cost of assembling this skirt on the inside. the reflector.

With similar performance of the radiation pattern, a parabolic antenna with a low F / D value of less than or equal to 0.25, for example around 0.17 ("deep dish" in English), has a more absorbent skirt. short than the shallow reflector antenna. Nevertheless, the field on the edge of the antenna is higher in the case of a deep dish antenna. Due to the very short height of the skirt, the field level on the edge of the antenna is close to the field level at the end of the parabolic reflector (about 2 dB at 3 dB gap). In the case of a shallow reflector antenna, the difference is higher and about 10 dB. Distribution currents may appear on the edge of the antenna and disturb the forward / backward ratio of the radiation pattern by the appearance of wave diffraction on the peripheral edge of the antenna. The values of the radiation pattern exceed the maximum values allowed by the ETSI class 3 mask. The object of the present invention is to propose a parabolic reflector microwave antenna in which the diffraction of the waves appearing on the outer peripheral edge of the antenna has been substantially reduced. The invention also aims to provide a parabolic reflector antenna whose front / rear ratio is improved.

The invention also aims to provide a parabolic reflector antenna requiring a skirt of lesser height. The object of the present invention is an antenna comprising a parabolic reflector, provided with a skirt, cooperating with a means for emitting incident radiation in the direction of the reflector. The antenna comprises means for reducing the distribution current appearing on the edge of the antenna, these means being arranged on the front or side outer surface of the peripheral rim of the antenna. Preferably, the means for reducing the distribution current are composed of even-numbered traps arranged symmetrically.

When the traps do not cover the entire circumference of the antenna, the angle formed by the sector of a trap is preferably of the order of 60 °. More preferably each trap has a shape adapted to the rounding of the peripheral edge of the antenna. According to a particular embodiment, each trap has the shape of at least one conductive surface groove. In particular the groove is formed of a material which may be a metal or a metallized plastic. According to a preferred embodiment, the groove has dimensions of the order of a fraction of the wavelength of the incident radiation. Preferably, the groove has a depth of the same order of magnitude as its width, and more preferably the width and depth are equal. The groove may have a section selected from a flat-bottom U-shaped section, a U-shaped section with a rounded bottom, and a V-shaped section. Its side walls may be straight or inclined. The present invention reduces the height of the skirt attached to the parabolic reflector, which provides a cost advantage and significant size. The invention can be used in applications such as, for example, the production of terrestrial antennas for receiving a radiofrequency signal emitted by a satellite or the link between two terrestrial antennas, and more generally in any application concerning radiofrequency links. point-to-point in the frequency band from 7 GHz to 40 GHz.

Other features and advantages of the present invention will appear on reading the following description of an embodiment, given of course by way of illustration and not limitation, and in the accompanying drawing in which - - Figure 1 shows schematically the path of the radiation received by the parabolic reflector, - Figure 2 shows in schematic section a parabolic reflector antenna provided with a high skirt according to the prior art, - Figure 3 shows a parabolic reflector antenna provided with traps according to a embodiment of the invention; FIG. 4 is a diagrammatic section of a parabolic reflector antenna according to one embodiment of the invention; FIG. 5 is a detailed view of the traps according to a first embodiment; of the invention, - Figure 6 is a detailed view of the traps according to a second embodiment of the invention, - Figures 7a to 7c show different section of go FIGS. 8a and 8b compare the radiation patterns in the horizontal plane of an antenna of the prior art and an antenna provided with a trap according to one embodiment of the invention; in FIGS. 6a and 6b, the intensity of the radiation J in dB is given on the ordinate, and on the abscissa the emission / reception angle R in degrees. In these figures, the identical elements bear the same reference numbers. FIG. 1 is a diagram showing a reflector 1, in the form of a parabola bow, disposed facing a waveguide 2 which emits incident radiation 3 towards the reflector 1. Most of the incident radiation 3 is reflected on the reflector 1 and forms the radiation emitted 4 by the antenna. However, part of the incident radiation 3 is returned in a divergent direction, and causes overflow losses 5. In addition, another part of the incident radiation 3 reaches the edges of the reflector 1, where a diffraction 6 occurs, which increases the field to the rear of the parabolic reflector 1 and contributes to deteriorate the forward / backward ratio. An antenna, shown in section in FIG. 2, usually comprises a parabolic reflector 1 provided with a skirt 7, forming a cylindrical wall, internally lined with an absorbent material 8 and closed by a radome 9. The incident radiation 3 coming from the The waveguide 2 is reflected by the reflector 1 in the form of emitted radiation 4. The radiation 10 which projects beyond the reflector 1 is absorbed by the absorbent material 8 of the skirt 7. The characteristic of the radiation pattern of an antenna The horn-shaped waveguide ("horn") is determined by the mode of transmission of the horn waveguide, which is generally the dominant mode or TEI1 mode. Since the dominant mode TE 'is asymmetric about the central axis of the horn, the horn antenna radiation pattern is disadvantageously asymmetrical around the central axis. When using a horn-shaped waveguide with a parabolic reflector, the asymmetric radiation characteristic leads to a reduction of the antenna radiation efficiency and a deterioration of the cross-polarization waves. In a first embodiment of the invention illustrated in Figures 3 to 5, the antenna 30 comprises a reflector 31 surmounted by a skirt 32 closed by a radome 33 plane. In this case, the diameter D of the reflector 31 of the antenna 30 is of the order of 2ft (0.6096 m), and the operating frequency range is between 7 GHz and 14 GHz. One way to reduce the diffraction of the waves appearing on the outer peripheral edge of the antenna is to suppress the current, in particular using quarter-wave traps. These traps have the shape of grooves with dimensions close to a quarter of the wavelength considered. The outer surface of the skirt 32 carries, in lateral position, wave traps 34 with a conductive surface, which may be metallic or made of metallized plastic. As shown in FIG. 5, these traps 34 are preferably in the form of grooves whose depth P and the gap E of the walls of the groove depend on the wavelength of the incident RF signal emitted by the waveguide. 35. Preferably, the dimensions E and P of the traps 34 are of the order of 215 to 8 GHz, in this case 8 mm. In this case the traps 34 are in the form of two contiguous parallel grooves with vertical walls. For low frequency operation; it is preferable to use at least two traps 34. The traps are placed in symmetrical position: they are therefore even in number. These traps 34 may be placed on only part of the peripheral rim of the antenna, for example diametrically opposite as shown in Figure 3, or on the entire circumference of the antenna. When the traps do not cover the entire circumference of the antenna, the angle formed by the sector of a trap is of the order of 60 °. For example, for an antenna having a diameter of about 65 cm, this represents a length of about 35 cm for each trap. The shape of the trap must therefore adapt to the rounding of the peripheral edge of the antenna as shown in FIG. 3. The purpose of the traps 34 is to reduce or even eliminate the distribution current 36 on the edge of the antenna. antenna 30 to reduce diffraction. The principle of their operation is based on the fact that they produce a phase shift of a part of the wave which is then placed in phase opposition with the main wave and is canceled out. A second embodiment of the invention is shown in FIG.

The antenna 40 comprises a reflector 41 surmounted by a skirt 42 closed by a radome 43. The inner surface of the skirt 42 is coated with an absorbent material 44. The outer surface of the skirt 42 carries, in the frontal position, In this case the traps 45 have the shape of a single groove. The angle formed by the sector of a trap is of the order of 60 °, when the traps do not cover the entire circumference of the antenna. For example, for an antenna having a diameter of about 65 cm, this represents a length of about 35 cm for each trap. It is therefore necessary that the shape of the trap adopts the roundness of the edge of the antenna. According to a particular embodiment, the traps 45 can be fixed on the edge forming the circumference of the radome 43. Of course, traps can be placed both in the lateral position and in the front position on the antenna. The number of traps is not limited. The section of the groove may have a varied shape, for example a U-shaped section with a flat bottom as shown in Figures 4 to 6, a U-shaped section with a rounded bottom 50 as in Figure 7a or a section in V-shaped 51 as in Figure 7b. The side walls flanking the groove may be straight as shown in Figures 4 to 6, or inclined 52 as in Figure 7c. FIGS. 8a and 8b, which illustrates the diagrams of the radiation of an antenna, will now be considered. In these two figures, the continuous line 60 of reference represents the standard profile corresponding to the model class 3 ETSI.

In FIG. 6a relating to an antenna of the prior art, the side lobes 61 exceed the ETSI standard. In comparison, the side lobes 62 of an antenna provided with traps according to one embodiment of the invention are very clearly reduced. This shows that the traps are an effective means of reducing the diffraction of the waves appearing on the outer peripheral edge of an antenna. Of course, the present invention is not limited to the described embodiments, but it is capable of many variants accessible to those skilled in the art without departing from the spirit of the invention. In particular, without departing from the scope of the invention, it will be possible to modify the nature and structure of the traps.

Claims (1)

REVENDICATIONS1. Antenna according to claim 1, wherein the CLAIMS1. Antenna according to claim 1, wherein the means for decreasing the distribution current are composed of even-numbered traps (34, 45) arranged symmetrically. Antenna according to claim 2, wherein each trap has a shape adapted to the rounding of the peripheral edge of the antenna. Antenna according to one of claims 2 and 3, wherein the angle formed by the sector of a trap (34, 45) is of the order of 60 °. Antenna according to one of claims 2 to 4, wherein each trap (34, 45) has the shape of at least one conductive surface groove. Antenna according to claim 5, wherein the groove is metallic or metallized plastic. Antenna according to claim 5, wherein the groove has dimensions of the order of a fraction of the wavelength of the incident radiation (3). Antenna according to claim 5, wherein the groove has a depth P of the same order of magnitude as its width E. Antenna according to one of claims 5 to 8, wherein the groove has a section selected from a U-shaped section. flat-bottomed, a U-shaped section with a rounded bottom and a V-shaped section. Antenna according to one of claims 5 to 8, wherein the groove has straight or inclined side walls. Antenna comprising a parabolic reflector (31), provided with a skirt (32), cooperating with an emission means (35) for incident radiation towards the reflector (31), characterized in that it comprises means (34) for decreasing the distribution current appearing on the edge of the antenna (30), these means (34) being arranged on the front or side outer surface of the peripheral rim of the antenna (30) .2. 3. 4. 5. 6. 7. 8. 9. 10.