DE4102846A1 - Planar microwave aerial for satellite TV reception - has single feed mains radiation element structure in individual aerial housing - Google Patents

Abstract

The planar microwave aerial consists of feed mains-radiation element-structure in strip conductor technique, mass surfaces which enclose the feed mains, and radiation windows in the mass surfaces in which the radiation elements affect the wave conversion from and to free space. A unit for high frequency connection of a converter to the feed mains is arranged in an enclosed and mechanically supporting housing. The grid-type radiation windows distributed over the aerial surface are segregated in several sectors into an equal number of groups. Each radiation window has two radiation elements (14,15), which within a sector are connected to each of two separate part feed mains. Each of the two part feed mains of a sector connects all radiation elements (14,15) for a polarisation component to the wave to be converted. USE/ADVANTAGE - For 11-12 GHz band. Using triplate arrangement, high frequency signals of each type of polarisation can be received.

Description

The invention relates to a planar antenna according to the upper handle of the claim as z. B. for television reception via Satellite, in the 11 and 12 GHz range, is used.

In the known planar antennas, the RF coupling and Line structures designed so that with a module of food network / radiator surface / ground surfaces (triplates) each only Waves of a polarization type are coupled in or out can, e.g. B. horizontal or vertical or circular-right turning or turning left.

The type of polarization depends on the cross section of the radiators window, of the arrangement and configuration of the radiator elements and from their connection to the dining network. Examples übli Versions are in EP application 8 61 10 153, EP application 8 74 01 252 and DE-OS 37 06 051 and in the contribution Ephan, N., and other: flat antenna for circular polarization (magazine Funkschau, issue 18/1990, page 58 ff).

To receive with more than one type of polarization, you arrange in one antenna, one behind the other in the direction of action, two triplate Modules (e.g. GB patent application 21 95 832, DE-OS 39 17 138, EP application 8 74 01 252).

The radiator windows of both triplates must be coaxial; between A ground surface is sufficient for the two carrier foils. So will it is possible to use signals with both linear or circular To receive polarizations within a frequency band. A Receive waves with linear and circular polarization is with such a structure because of the lack of orthogona technically not feasible.  

Another option for receiving in two at the same time Types of polarization are indicated in EP application 8 74 01 252 tet: two triplates with different or against each other rotated feed network / spotlight structure side by side, on ge common or separate carrier film. It's about the same thing like placing two planar antennas next to each other, only that the housing costs are reduced and an antenna saves bracket.

The increased effort involved in side by side as well Series connection of the triplates is unavoidable, is probably the main disadvantage of all previous solutions of planar antennas for more than one type of polarization.

In addition, there are Pro with the series connection problems with reception performance and quality: the carriers The film of the outer triplate has a dampening effect on that of the subsequent one switched triplate signal portion to be decoupled, and when arranged of a reflection surface behind the triplates - for which it can only give an optimal distance to a carrier film - compromises must be made, d. H. the reception condition conditions in both or in one of both types of polarization additionally worsen.

Both principles still have in common that on the essential advantage of the planar antennas - the small size or the extremely flat design - part of it has to be dispensed with. This would be particularly important if you put the antenna in Wanted to set up the room - just like in this case Lineup z. B. of two antennas for each type of polarization would hardly be represented.  

To date, planar antennas for theories so far have been used in retail not possible to offer two types of polarization, so that you have two for each frequency band of satellite television If you wanted antennas, you wanted the entire range of programs Use individual antennas.

The invention has for its object to a planar antenna develop in which with a triplate arrangement, d. H. without increased effort compared to the known special antenna, RF signals of any type of polarization can be received.

This object is achieved with the in the characterizing Part of the main claim resolved characteristics.

Embodiments of the invention are described in the subclaims mentally stated.

The two radiator elements arranged at right angles to each other in the spotlight windows, not each other, but each are directly connected to the central entry point men the incident signal of any polarization each linear field component corresponding to its angular position. The means that the pair of radiator elements, if available, couples two orthogonal linear field components.

At the entry point, which is designed as a waveguide the two field components - here summed up from the two parts dining networks - taking into account their mutual Reassembled phase position and thus the signal in the correct polarization reconstructed.

The antenna according to the invention is suitable - in conjunction with the respective converter - without any design changes Adjustments and adjustments for sending and receiving in all Polari sations types, also with elliptical polarization.  

Compensation of the Polarisa is also not required tion angle (by rotating the antenna in the surface axis), as with the conventional planar antennas at least in the Edge areas of the illumination zones must be made.

The new antenna corresponds in terms of manufacturing costs and outer contours of any known planar antenna for a single type of polarization. It is also the Para Bolspiegel antenna equivalent. The principle according to the invention can be the basis for the development of broadband satellite Planar antennas are used with which - as today riding the parabolic mirror antennas - remote-controlled, e.g. B. via converters with polarization converters, Reception in frequency ranges with linear and with circular Polarization is possible.

The invention is illustrated below with the aid of an embodiment explained in more detail. In the accompanying drawing shows

Fig. 1 carrier film with feed network to the antenna element groups,

Fig. 2 emitter group with connection of the emitter elements.

Fig. 1 shows schematically a complete base film for a planar antenna according to the invention with the conductor track structure. The radiator windows in the ground area above are thinly drawn out and thus only hinted at.

With 1 the feed point is designated, cut a waveguide section, in which the coupling ends 2 and 3 each two connecting lines 4 and 5 protrude, which lead to the connection points 6 and 7 for the partial feed networks of the radiator sectors 8 . The partial feed networks are each connected in pairs to the connecting line for a field component.

From the connection points 6 and 7 , which are arranged in this embodiment example at the corner points of the sectors, distribution lines 9 and 10 go to the radiator groups 11th This image is repeated in a similar manner for the individual radiator group 11 , which is shown in FIG. 2 (in two variants). Connections 12 and 13 lead to the radiator elements 14 and 15 from two diametrical corner points. The distribution lines and the connections form two partial feed networks within the sector, the conductor tracks of which penetrate each other like a comb, but do not intersect at any point. This creates a separate path 14-12-9-6-4-2 or 15-13-10-7-5-3 for the two polarization components in the entry point 1 .

These paths are in contrast to the dining networks in the State-of-the-art solutions of different lengths. However, since each individual track length as a multiple of the mean Ren operating wavelength is executed, the field compo of each radiator element in phase with the feed point, and the total signal from the component sums is in phase and thus built up in the input polarization.

Another effect is the different attenuation compared to the known solutions on the unevenly long tracks - some lower and some higher. However, calculations and measurements have shown that the mean path length of all radiator elements 14 and 15 to the coupling ends 2 and 3 in the solution according to the invention is actually the same as the dimension resulting in the solutions of the prior art and that the mean damping and thus the total damping the dining network speaks ent the usual value in the solution according to the invention.

The structure of the conductor tracks within the sectors and within the radiator groups is the same, only that the network is rotated by 90 °. This can be seen in Fig. 1 on the left and right sectors. Fig. 2a shows the pipe network of an antenna array for the left upper sector; the same picture, rotated by 90 °, gives the line network shown in FIG. 2b of a radiator group for the upper right sector.

Claims (5)

1. Planar microwave antenna, consisting essentially of

• - Feed network radiator element structures in stripline technology,
• - ground surfaces surrounding the feed network,
• - Spotlight windows in the ground surfaces in which the spotlight elements effect the wave conversion from or to the free space, and
• - Means for HF connection of a converter to the feed network, which are arranged in a closed and mechanically load-bearing housing,

characterized by the following features:

• - The radiator windows distributed in a grid pattern over the antenna area are divided into several sectors ( 8 ), each with an equal number of groups ( 11 ),
• - Each radiator window is assigned two radiator elements ( 14, 15 ) which are connected to one of two separate partial feed networks within a sector ( 8 ),
• - Each of the two partial feed networks of a sector connects all radiator elements ( 14 ) or ( 15 ) for the same polarization component of the wave to be converted,
• - The partial feed networks are preferably connected in pairs with a connecting line ( 4, 5 ) to the central feed point ( 1 ) and consist of distribution lines ( 9, 10 ) to the groups ( 11 ) and connecting lines ( 12, 13 ) to the radiator elements ( 14, 15 ),
• - The connection points ( 6, 7 ) of the partial feed networks for each polarization component in a sector ( 8 ) and in the group ( 11 ) are arranged diametrically opposite one another, and the distribution lines ( 9, 10 ) and the connecting lines ( 12, 13 ) penetrate each other like a comb and free of crossings,
• - The proportions of all lines of the food network are designed so that the length of each line between a radiator element ( 14, 15 ) and the feed point ( 1 ) is an integer multiple of the mean operating wavelength.

2. Planar microwave antenna according to claim 1, characterized records that the feed network structure in stripline - or in suspended stripline technology is built. 3. Planar microwave antenna according to claim 1, characterized records that the feed network emitter structure and the mass surfaces are built in coplanar line technology. 4. Planar microwave antenna according to claim 1, characterized through the combination of stripline and suspended stripline and or or coplanar technology in an antenna construction tion.