NO864563L - REFLECTOR ANTENNA WITH SELF-SUSTAINABLE MEASUREMENT ELEMENT. - Google Patents

Abstract

A reflector antenna with a dish-shaped main reflector (10), and a self-supporting feed (11) for the transmission or reception of polarized electromagnetic waves. The feed (11) consists of a tube (12) which is attached to the middle of the main reflector (10) and is terminated by a subreflector (13) so that an intermediate space (14) is formed between the subreflector and the end of the tube. The part of the tube that is nearest the intermediate space (14) contains a cylindrical waveguide (15), or is the waveguide itself, and has an approximately circular or quadratic cross-section. Externally, the intermediate space (14) is bounded by a circular, cylindrical surface (16) with the same diameter as the outer diameter of the tube (12) this being called the aperture surface. The surface of the subreflector (13) which is located just outside the surface of the aperture (16) has circular corrugations (17), or other means of creating a reactive, anisotropic surface impedance, to ensure that the electromagnetic waves are propagated along the surface disregardless of whether the electrical field is tangential to the surface or is normally on it. The part of the subreflector (13) that is located within the aperture surface (16) is shaped as a central conical element (18) with reflecting characteristics and which is inclined towards the tube (12).

Description

The invention relates to a reflector antenna with a self-supporting feed element of the type specified in the introduction to patent claim 1, for radiating or receiving polarized electromagnetic waves. The use is mainly for receiving TV signals from satellite, but it can also be used for radio line purposes, and as an earth station for satellite communication.

Such reflector antennas are used in particular because they are simple and cheap to manufacture. They also provide higher antenna efficiency and lower sidelobes i

the radiation diagram than if the feed element has to be attached using inclined struts. Such struts block the main reflector. A self-supporting feed element is also easily accessible from the rear of the reflector. Therefore, it is often used when the transmitter and/or receiver is to be placed there. This results in lower losses than if the waves had to be guided in a cable along an inclined strut.

In Norwegian patent application 862192, a reflector antenna with a self-supporting feed element is described. This consists of a circular waveguide which is attached to the center of the reflector. In front of the opening at the other end, a subreflector is placed which has an anisotropic and reactive surface impedance to create a polarization independent reflection coefficient for the radial waves propagating along the surface of the subreflector. This antenna can be used to transmit and receive electromagnetic waves on two orthogonal polarizations; in other words, it is double-polarized. The antenna has low cross-polarization within the main lobe of the radiation pattern. However, the frequency bandwidth for the most relevant embodiment in the above-mentioned patent application is very small due to large reflection losses.

The main purpose of the invention is therefore to create an improvement of the antenna described in Norwegian patent application 862192; an improvement that provides greater bandwidth.

The purpose is achieved with the help of the features described in the characterizing part of patent claim 1. That is to say, the middle part of the subreflector is designed as a conical tip that points in the direction of the main reflector. This tip reflects an incident wave from the waveguide in the radial direction so that the wave, which is reflected back into the waveguide, has a small amplitude. At the same time, there is a correct balance between the axial and circumferential fields that are set up above the aperture surface, so that you get low cross-polarization. A prerequisite for this is that the pipe is relatively thin-walled.

The invention will be described in more detail below with reference to the drawings, where: Fig. 1 shows an example of a reflector antenna with a self-supporting feed element,

fig. 2 shows an axial section through a feed element designed in accordance with the invention, while

fig. 3 shows an axial section through another embodiment of the feeding element.

The antenna in fig. 1 comprises a bowl-shaped main reflector 10. In the middle of this a self-supporting tubular feed element 11 is attached. This consists of a cylindrical tube 12 and a sub-reflector 13. The tube and the sub-reflector are separated by a space 14, which is limited externally by a imaginary cylindrical and circumferential surface 16 which is called the aperture surface or simply the aperture.

Fig. 2 shows an axial section through the feeding element. The tube 12 or the part of the tube which is closest to the subreflector 13 forms a cylindrical waveguide 15 with a preferably circular cross-section. The waveguide is designed to propagate the fundamental mode. This is the TE^mode when the internal cross-section is circular with smooth and conducting walls. This then has a diameter larger than approx. 0.6 wavelengths and less than approx. 1.2. The pipe 12 is mainly made of electrically conductive material. The tube 12 is relatively thin-walled.

The part of the subreflector 13 which lies outside the aperture surface 16 has an anisotropic and reactive surface impedance. The surface is drawn smooth, but the desired surface impedance is usually realized with rotationally symmetrical grooves or grooves in the surface. The center of the sub-reflector is formed as a substantially conical tip 18, which points towards the tube 12. The tip 18, which is reflective, is about the same length as the aperture surface 16, which has a cross-sectional dimension of approx. 0.5 wavelengths^ . The space 14 within the aperture 16 can be completely or partially filled with dielectric material.

The way the invention works is essentially the same as for the realization in patent claim 8 in patent application 862192. The fields above the aperture 16 are assumed to consist of two modes. One mode where the electric fields are directed exclusively in the axial z direction (TM z), and one where the electric fields are mainly circumferential (TE z). These two modes radiate as explained in patent application 862192. In the present invention, the optimal balance between the excitations of the two modes is achieved by means of the conical tip 18. This reflects the fields from an incident wave in the waveguide in the radial direction so that one automatically gets roughly the right balance between TE and TMz, and so that the wave that is reflected back into the waveguide has a small amplitude.

Fig. 3 shows another embodiment of the invention. The desired surface impedance of the subreflector 13 is realized here with circular grooves 17 facing the tube 12. The subreflector is also provided with such a groove within the aperture 16. The depth of the grooves 17 is approx. 0.25^.. Furthermore, the central part of the subreflector 13 is designed as a substantially conical tip 18 which corresponds to the tip 18 in fig. 2. In the center of this tip there is a cylindrical outlet coaxial with the pipe 12.

The space 14 within the aperture 16 is filled with dielectric material. This material takes the form of a plug 19, which is cylindrical on the outside, and fits into the end of the pipe 12 and into the interior of the grooves 17 with a projecting annular rib 20.

In addition, it is provided with a pin 21 which fits into the outlet in the center of the tip 18. The ring rib 20 and the pin 21 can be provided with threads that fit against corresponding threads in the sub-reflector, to ensure a good attachment.

The various elements shown in fig. 2 and 3 can be combined and modified in different ways. The tube 12 may be a square tube or otherwise polygonal. The subreflector 13 can be made of plastic with a metallic surface. The plug 19 in the space can be connected to the subreflector 13 in other ways than that shown, e.g. with only one of the elements 20 and 21. If only the element 20 is used, the subreflector will not have a central outlet in the tip 18. If only the element 21 is used, the subreflector will not have any groove within the aperture 16.

Claims (6)

1. Reflector antenna consisting of a bowl-shaped main reflector (10), and a self-supporting feed element (11) for sending or receiving polarized electromagnetic waves, where the feed element (11) essentially consists of a supporting straight tube (12) which is attached at one end to the center of the main reflector (10), and at the other is terminated with a sub-reflector (13) in such a way that a space (14) is formed between the sub-reflector and the end of the tube, where the part of the tube (12) which is closest to the space (14) contains a cylindrical waveguide (15) or is itself such a waveguide, where this waveguide (15) has an approximately circular or square cross-section, where the space (14) constitutes a connection between the waves inside the waveguide, and the waves outside the feed element, and where the space (14) is externally limited by a circumferential and cylindrical geometric surface (16) which has the same diameter as the outer diameter of the pipe (12) and which is called the aperture surface, and where the part of the subreflector's (13) surface that lies outside the aperture surface (16) is provided with means to create a anisotropic and reactive surface impedance to achieve that the radial cylindrical electromagnetic waves are reflected from and propagate along the surface in approximately the same way whether the electric field is normal to the surface or it is tangent to the surface, and where this is preferably realized using circular tracks (17 ), so that this, together with the design of the other geometry of the feed element, contributes to the radiation diagram of the feed element having low cross-polarization and becoming approximately rotationally symmetrical around the tube (12), characterized in that the part of the subreflector (13) that lies within the aperture surface (16) ) is designed as a central conical or similar converging element (18) which has reflective properties and which faces the pipe (12), so that incident waves from the waveguide (15) are reflected in such a way that there is a balance between the axial field and the circular field which is set up above the aperture surface (16) and so that it undulates one that is reflected back into the waveguide gets a low amplitude over a large frequency range.. 2. Reflector antenna in accordance with patent claim 1, characterized in that the conical part (18) of the subreflector is manufactured in one with the subreflector (13) or as a separate element (18) inserted in a central opening in the subreflector (13). 3. Antenna in accordance with patent claim 1 or 2, characterized in that the space (14) between the waveguide (15) and the subreflector (13) is completely or partially filled with a dielectric element (19). 4. Antenna in accordance with patent claim 3, characterized in that the dielectric filler element (19) engages with the waveguide (12) and with the subreflector (13). 5. Antenna in accordance with patent claim 4, characterized in that the filling element (19) has a central pin (21) facing and engaged in a corresponding outlet in the conical element (18). 6. Antenna in accordance with patent claim 4 or 5, characterized in that the filler element (19) has an annular rib (20) which engages with an annular groove (17) in the subreflector (13').