DE69006372T2 - Antenna system for receiving direct broadcast transmission satellites. - Google Patents

Abstract

The antenna system consists of a parabolic reflector (1) associated with source means (2, 3), the reflector being positioned and held by means of a support foot formed from a hollow tubular body (7) fixed at its upper part to the rear central zone of the reflector and hinged at its lower part on a base about a horizontal axis (XX) in order to define the elevation of the antenna. The base comprises a part (24) which is movable in rotation in order to define the azimuth of the antenna. The tubular body (7) of the support foot has a sufficient cross-section to contain all the circuits associated with the antenna. Application, in particular to satellite reception, of which the radiated powers are greater than 50 dBW. <IMAGE>

Description

The invention relates to the field of reception of direct broadcast TV satellites and in particular to a receiving antenna system.

In the field of reception of direct broadcasting satellites, in particular for the DBS satellites (Direct Broadcasting Satellite) such as TDF 1, TV SAT, OLYMPUS, BSD, etc., various types of well-known antennas can be used:

A first known type of antenna uses a paraboloid of revolution with a source located at the focal point of this paraboloid. The antenna is accessed either directly at the focal point of the parabola by accessing the source or at the rear of the antenna via a cable bridge which creates the connection between the source and the rear of the antenna. The antenna is mounted on a support whose dimensions are determined depending on the size of the parabola, this support allowing the azimuth and El angle alignment in the direction of the satellite to be received.

The disadvantage of this type of antenna is that the shadow cast by the source, its support and its support arms covers part of the reflector, which results in a reduction in performance. In addition, the use of a waveguide for access at the rear of the antenna allows protection of the low noise converter (LNB), but it causes a transmission loss which is translated into a reduction in the antenna gain and an increase in the antenna's noise temperature. In addition, this type of antenna is expensive, particularly because of the number of mechanical parts that must be used to create the antenna structure and enable its orientation. The latest developments in this type of antenna have made it possible to obtain low-noise, small-sized transducers thanks to GaAs FET transistors, which can be placed directly behind the source at the focal point of the paraboloid, thus reducing transmission losses. However, this further increases the shadowing of the reflector, especially for antennas with a small diameter. In addition, the electronics are then even more directly subject to climatic conditions, particularly temperature variations, and induced vibrations.

Another known type of antenna uses an eccentric parabolic reflector. This type of antenna is commonly called an "offset" antenna. This is an antenna whose reflector is formed by a region of a paraboloid of revolution, the source offset from the central axis of this paraboloid casting no shadow on the opening. To do this, the reflector is obtained by cutting a paraboloid with a cylinder of diameter D centered on an axis parallel to the focal axis of the paraboloid. The source is then placed at the focal point F of the paraboloid and aimed at the center of the paraboloid region. Access to the antenna is generally via a source access, with the low-noise transducer then placed directly behind the source and in front of the reflector.

The main advantage of this "offset" structure is to increase the performance of the antenna by reducing the coverage effect of the source; in addition, the antenna is not very sensitive to climatic conditions, and the antenna aimed at the satellite is practically vertical by virtue of its structure. However, this second type of antenna also has major disadvantages: the realization of this type of reflector, which is not rotationally symmetrical, is difficult and only to a limited extent suitable for manufacture by flat stamping or drawing. In addition, the radiation characteristics of the antenna are not rotationally symmetrical, and the degree of ellipticity of an antenna of this type used with circular polarization is higher than that of an antenna using a reflector in the shape of a paraboloid of revolution. In addition, the transducer is placed in front of the reflector with low noise and is therefore subject to climatic conditions (in particular temperature). Finally, since the elevation angle reference plane is not easily defined, it is not easy to align the antenna in the direction of the satellite to be received.

Another problem of direct reception satellite antennas concerns their fixing. This must be sufficiently stable to withstand the effects of the weather, it must also be versatile to be suitable for different conditions (fixing on a roof, a balcony, etc.) and it must allow the antenna to be easily aligned. A solution currently used and known for example from document JP-A-60 75 130 is to fix the antenna to the top of a tubular mast. This solution forms the starting point for the antenna according to the invention. However, instead of providing a support allowing the orientation of the reflector with respect to the mast, the reflector of the antenna according to the invention is fixed, while the orientation of the mast is varied in order to align the antenna. This construction is necessary for the supply system of the antenna according to the invention.

The invention relates to a compact antenna system intended to capture the signals transmitted by a satellite and incorporating the low-noise converter amplifier to amplify the signals received by the antenna and convert them into the required band, this antenna being intended to incorporate all or part of the electronic functions required for the compatibility with the reception of television images, while having a very reasonable cost and being very easy to align. These characteristics are achieved thanks to a greatly reduced number of elements for the implementation

- the El angle setting,

- the azimuth setting,

- protection and integration of electronics

- and the fastening

receive.

According to the invention, an antenna system for reception of direct broadcast satellites is characterized in that it comprises a parabolic reflector, the rear central part of which is fixed by a fixing part to a hollow tubular body of a support base, a tube with the same central axis as the reflector passing through the reflector, the fixing part and the tubular body of the support base, which contains the source and forms a protection and a centering means for the source in the reflector, the tubular body of the support base being hinged at its base to a horizontal axis carried by a base and connected to locking means which determine the elevation angle of the antenna, the base being movable about a vertical axis in order to determine the azimuth angle of the antenna, all the circuits of the antenna system and their means for electrical supply being fixed inside the tubular body of the support base.

The invention will be better understood and further features will become apparent with the help of the following description and with reference to the accompanying figures.

Fig. 1 is a cross-sectional diagram of a first embodiment of the antenna system according to the invention.

Fig. 2 is a second embodiment of the antenna system according to the invention.

In the following description, the embodiments described in detail are specifically adapted to the reception of satellites transmitting in the band from 11.7 to 12.5 GHz with right-hand or left-hand circular polarization. However, the antenna can be modified to be suitable for a different frequency band or for other types of polarization.

The antenna system according to the invention consists mainly of an antenna whose reflector has a diameter adapted to the power received from the satellite and from its source, a support leg ensuring the geometry of the antenna and at the same time ensuring its adjustment for alignment with the satellite, and electronic circuits essentially formed by the low-noise converter amplifier and possibly supplemented by other circuits. Figure 1 shows by way of example the embodiment of the antenna system according to the invention for reception from the TDF 1 satellite, which radiates at a power of 63 dBW: the reflector 1 of the antenna is a parabolic reflector with a diameter of 0.33 meters. The system can be adapted without modification to larger diameters up to 0.7 meters for powers emitted by other, smaller satellites, for example ASTRA, which radiates at a power of 52 dBW.

The reflector 1 is a paraboloid of revolution whose focal length to diameter ratio is 0.3, which gives a focal length of 97 mm for a diameter of 0.33 m. The paraboloid's opening angle is 161º. This reflector is made of 1.5 mm thick aluminum and is obtained by roll forming for small quantities or by drawing for larger quantities. The tolerance on the reflector profile leads to a mean square deviation of 0.5 mm with respect to the theoretical profile, which results in a gain loss of the order of 0.28 dB at a center frequency of F = 12.1 GHz. This reflector 1 is directly attached to the support by its central part, as explained below.

The source allows the reception of circularly polarized signals in the frequency band from 11.7 to 12.5 GHz. This source is formed by a semi-rigid coaxial cable 2 with PTFE dielectric in a copper tube on which a radiator 3 is mounted that exploits the radiation properties of surface waves: this radiator has the shape of a helix or any other source that allows the electronics to be moved to the rear of the antenna reflector. In the optimized embodiment shown, the radiator is a helix whose turns are formed by winding around a Cylinders with a diameter of 6 mm with a pitch of 12 mm, the angle of inclination of the turns being 30º. The attenuation introduced by the semi-rigid coaxial cable is of the order of 1.5 dB per metre when used in the 12 GHz band, which leads to a reduction in gain of the order of 0.2 dB for the antenna described. Due to the structure of the source with respect to the reflector, the losses caused by the source covering the reflector are limited to 0.01 dB. This source (coaxial cable surrounded by the helical radiator) is mounted in a polypropylene tube 4 with the same central axis as the reflector, which it crosses at its centre; this tube, closed at its radiator end by a protective cap 5, forms the antenna dome and ensures sealing against surface water. The measured losses of the antenna dome are 0.2 dB at the useful frequencies. At the rear of the reflector, the tube 4 is held in position by a centering part 6 which is fixed on the one hand to the rear of the reflector and on the other hand to a hollow tube 7 which forms the body of the support foot. In this way, the rigidity of the supply line is ensured.

The source is thus centered in the tube 4 and is held in position by the part 6 centered in the rear part of the reflector, which in turn is held by means of a screw to the body 7 of the support foot. In this way, the centering and longitudinal positioning of the source with respect to the reflector is achieved.

The dimensions of the body 7 of the support foot are such that the reflector can be replaced by simply removing the screws securing the latter to the part 6, while the diameter of the reflectors can be varied as above.

The support foot has three functions:

- Ensure the geometry of the antenna as mentioned above;

- Housing and protecting the electronics necessary for processing the signals received from the satellite;

- Enables quick alignment of the antenna even by a layperson.

The entire source, supply and converter head 10 is attached via a part 8 in the support foot 7.

The transducer head connected to the body of the support leg is protected against surface water by means of a cover 9 which protects it against the effects of the weather, this cover closing the upper part of the tube 7 forming the body of the support leg. At the opposite end, the tube forming the support leg 2 is not closed, allowing air to circulate which, thanks to this opening in the lower part, prevents condensation.

The receiver connection at the output of the support leg is made via a cable 20 which is connected to the transducer head 10 and passes through an opening formed in the lower part of the body 7 of the support leg.

The entire reflector, source and converter head is compact and contains all the elements necessary to receive the satellite signals.

In order to enable the antenna to be aligned quickly even by a layman, the assembly described above is held to a base by two screws 15 which are connected to a vertical tube 11, so that the antenna can be tilted around a horizontal axis XX.

The base is made up of two mechanical parts:

- a fixed part 21, for example in the shape of a cross, fixed horizontally (or vertically) by means of screws arranged in the holes 22 in its arms. On this fixed part there is arranged a spirit level 23 which allows the perfect definition of a horizontal or vertical plane and therefore the obtaining of a reference plane for defining the elevation angle of the antenna;

- a mobile part 24 from which the tube 11 protrudes and which is centered in the direction of rotation on the fixed part and is held to the latter by two screws 25. These screws slide into the recesses of the mobile part. The locking of these two screws ensures the fixation of the azimuth axis of the antenna, after the rotation of the rotating part 24 with respect to the fixed part has enabled the azimuth axis to be defined. In order to pre-position the antenna in the direction of the satellite, a magnetic needle and possibly a directional scale are attached to this mobile part.

The tube 11 of this movable part carries the body 7 of the foot, which can pivot about the axis defined by the two screws 15, shown in Fig. 1 in the partial section AA. The elevation angle adjustment of the antenna is carried out by adjusting a screw 26 in a maximum sector defined by a movable stop 17. while the blocking and fixation after adjustment are accomplished by locking the screw 15 and the movable stop.

All the parts of this support are made of aluminium, and all the shapes chosen are simple shapes that can be obtained by moulding or drawing for very large series, thus minimising manufacturing costs. To simplify the alignment of the antenna, the positioning marks used to adjust the elevation and azimuth axes contain graduations and possibly an indication of the satellites being targeted.

For certain applications, the assembly of the mobile part 24 and the fixed part 21 of the support can be replaced by the single cylindrical tube 11, which can be inserted directly into a standard tube usually used as a support for radio reception antennas. Figure 2 shows an embodiment of an antenna according to the invention, simplified in this way, intended to be inserted directly into a standard tube. The same reference numerals indicate the same elements as in Figure 1.

The essential difference is that the base of the support tube 11 is inserted directly into a standard tube 50 external to the antenna system. Of course, in this case the horizontal part of the support base is omitted, and the reference axis is given directly by the standard tube, which is positioned vertically thereto. In this figure, the parabolic reflector 1 with a diameter of 0.33 m is also shown in solid lines and a reflector 1' with a different diameter of, for example, 0.7 m is shown in broken lines. Likewise, to illustrate the adjustment of the orientation of the antenna, the support tube 7 is shown in three different positions, one in solid lines and the other two in broken lines, to show the possible angular deflection of the system.

The invention is not limited to the embodiments described and shown. In particular, in the figures, the source is shown as a simple helix with a free end. This type of source is perfectly suited to the circular polarization emissions of a satellite such as TDF 1. Of course, this nature is not limiting, since the source can be adapted to the type of polarization of the satellite emissions. Thus, while the polarization for the emissions from the TDF 1 satellite is circular, the polarization for the emissions received from the ASTRA satellite is horizontal or vertical. Similarly, certain satellites transmit with two circular polarizations, namely right-hand and right-hand polarizations. Left polarization. The corresponding sources are adapted to receive these different polarization types.

The tube 4 forming the antenna dome may be made of a material other than polypropylene, provided that this material does not generate losses.

The structure obtained in this way for the antenna system is particularly compact and very easy to install: all the sealing is carried out in the factory, and no special precautions are required during installation.

Claims (7)

1. Antenna system for receiving direct broadcast satellites, comprising a parabolic reflector (1), the rear central part of which is fixed to a hollow tubular body (7) of a support leg via a fixing part (6), characterized in that a tube (4) with the same central axis as the reflector passes through the reflector (1), the fixing part (6) and the tubular body of the support leg, which tube contains the source (2, 3) and forms a protection and a centering means for the source in the reflector, the tubular body (7) of the support leg being hinged at its base to a horizontal axis (XX) supported by a base and connected to locking means (26) which determine the elevation angle of the antenna, the base being rotatable about a vertical axis to determine the azimuth angle of the antenna, all the circuits of the antenna system and their means for electrical supply being located inside of the tubular body of the support foot. 2. Antenna system according to claim 1, characterized in that the base of the support leg is a tube (11) designed to be easily inserted into a standard tube with a vertical axis (50) which is usually used for radio reception antennas. 3. Antenna system according to claim 1, characterized in that the base of the support foot is formed from two parts: - a first part (21) intended to be fixed to a horizontal or vertical support, - a second part (24) rotatable about a vertical axis with respect to the first in order to determine the azimuth angle of the antenna. 4. Antenna system according to claim 3, characterized in that the fixed part (21) of the base of the support leg is provided with a spirit level defining a reference plane with respect to which the setting of the elevation angle is precisely obtained. 5. Antenna system according to claim 4, characterized in that on the rotatable part (24) of the base and on the tubular body of the support foot (7) scale divisions are provided in order to mark the azimuth and elevation axes of the antenna during its installation. 6. Antenna system according to claim 1, characterized in that the tubular body of the support foot is tightly closed in its part closest to the reflector, and is open in its part furthest from the reflector. 7. Antenna system according to claim 1, characterized in that for the reception of a satellite emitting circularly polarized waves, the source is formed by a helical radiator (3) connected to a coaxial cable (2), this assembly being centered in the cylindrical tube (4) made of a material which does not generate any losses.