DE4437594A1 - Microwave septum orthomode transducer for satellite communications - Google Patents

Abstract

The microwave septum OMT operates with circular polarised signals. The unit has a rectangularly shaped waveguide 1 of thin section metal and the internal space is sub divided into two regions by a thin metal septum element 3. The OMT has a single wave guide input port 7 at one end and dual output ports 7, 8 created by the septum at the other. The shape of the septum is such that there are three stages having projection teeth shaped elements. The device operates in the 7-8 GHz region.

Description

The invention relates to a microwave septum orthomode Transducer. The invention is for use in satellite communications communication systems with polarization processing and Evaluation and especially for use in devices in such systems for the resolution of any polarized Signals into a required or predetermined polarization base thought.

Such orthomode transducer (OMT) with a septum, which means a kind of partition and an In line configurations are known per se. According to US 4,122,406 works as an OMT in a wide frequency range combined OMT and polarizer. This polarizer ver turns a falling septum and a constricted mite telstück, their combination a good separation and a circular execution in a wide frequency range guarantee.

However, this device only achieves a resolution of an arbitrarily polarized signal in two circularly polarized components. This means that the device just as an OMT in a circular orthogo base works. In addition, this OMT changing waveguide cross sections to complications and its central part constriction leads to enlarged worlds conductor cross-sectional dimensions.

Another orthomode transducer is from Ver publication "A wide band compact endentry septum polarizer OMT "by N.D. Dan, S. Karats and D.J. Brain in Porch. of CAP 87, pp. 419-421. This OMT is too Can be used as a polarizer.

The invention has for its object a To create OMT, which is in a wide frequency range in egg a desired elliptically orthogonally polarized base is working.

This problem is solved according to the characteristic Features of claim 1. Advantageous further developments are described in the dependent claims.

In this way you get an OMT that is designed for who can that he polarized in a linear orthogonal Basis works and / or is particularly compact.

The OMT according to the invention has a waveguide body an input port, which is also called a connection, for Receive signals with orthogonally polarized compo and an output port with a dual connection label rich on that from a first and second connection each side has a common wall-shaped septum. There is also a coupling area between them Connections into which the waveguide connection opens, where gradually increase in height of the septum sloping or becoming narrower and a dif ferential phase shifter element provided, the Projections from the waveguide axis of symmetry align with the Cut the septum protrusions on the same axis. The septum and the differential phase shifter elements are con structurally summarized in a compact area to the desired ellipticity and good separation in one to achieve a large frequency band range. The adaptation pro blem, one also speaks of "matching", becomes simultaneous for the septum and the differential phase shifters elements solved because they influence each other.  

The septum and the differential are advantageous Phase shifter elements in the form of thin metal teeth, formed like a comb or as webs and in one piece one unit. So both functions are in integrated into a component and thus simplify the overall process construction.

In one embodiment, the septum coexists with the differential phase shifter elements an entire differential phase shift of 90 degrees. The OMT in this case works in a circular orthogonal polarized base. The phase difference can of course also by integer multiples of 360 degrees larger or be less than 90 degrees.

In another embodiment, the septum causes together with the differential phase shifter elements a total differential phase shift of 180 Degree. In this case, the OMT works in a linear manner orthogonally polarized base. Of course, this also applies for all other values that are an integer multiple of Are 360 degrees larger or smaller than 180 degrees.

In another embodiment, the septum and the differential phase shifter elements in orthogonal symme arranged and generate trical levels of the waveguide together a total differential phase shift of 0 degrees. In this case too, the OMT works in a li near orthogonally polarized base.

The invention will be further elucidated on the basis of a drawing explained. In detail show the schematic Representations in:  

Fig. 1 is a perspective view of a microwave septum OMT in circular polarization base according to the invention;

FIG. 2 is a sectional view in a plane crossing the septum according to FIG. 1;

FIG. 3 shows a detail view in the plane of the septum according to FIG. 1;

Fig. 4 is a schematic perspective view of a microwave septum OMT in linear polarization base according to the invention;

FIG. 5 shows a detail view in the plane of the differential phase shifter elements according to FIG. 4;

FIG. 6 shows a detail view in the plane of the septum according to FIG. 4;

Fig. 7 is a sectional view in the longitudinal plane of symmetry of a microwave septum OMT; and

FIGS. 8 and 9 is a view similar to Fig. 7 with other forms of the septum and the differential phase shifter elements.

As a preferred embodiment of the invention, the microwave septum OMT is described in a circular polarization basis. This OMT, which is shown schematically in FIG. 1, consists of a rectangular, in particular square, waveguide body 1 which is divided into two identical rectangular areas by a centrally arranged, thin, metallic and graduated septum 2 . The OMT thus has a single right-angled waveguide input port 7 at one end and a dual-port area, which has right-angled waveguide output connections 8 and 9 , at the other end.

The shape of the septum is shown in FIGS. 2 and 3. The septum has three levels 4 , 5 and 6 . As a differential phase shifter elements, a group of thin metallic teeth 3 is used, which are integrated into the stepped septum 2 in one unit. The teeth 3 can also be described as a shaped or stepped comb. The upper teeth 3 together with the stepped septum 2 generate the required value of the differential phase shift between the orthogonally polarized field components.

It is important that the phase response characteristic of the differential phase shifter elements 3 in the operating frequency range either cause an opposite or an overturning twist with respect to the phase response characteristic of the septum 2 . Because of this possibility, the range of the OMT can be expanded without constriction of the middle section. In the preferred embodiment for expanding the working frequency range, it is necessary to provide opposite rotations of the phase response characteristics of the septum 2 and the differential phase shifter elements 3 . This can be achieved by choosing a suitable tooth geometry. In general, it is possible to control and control the polarization base of the OMT efficiently and effectively through the differential phase shifter elements. The control can be achieved by changing the geometry of these elements and their arrangement in the shaft guide. In this preferred embodiment, the value of the differential phase shift between the orthogonally polarized field components is 90 degrees. It is a septum OMT in a circular orthogonal polarization base that can be used as a polarizer. The dimensions of this preferred embodiment, which operates in the frequency range from 7.2 GHz to 8.5 GHz, are shown in FIGS . 2 and 3.

The measured performance parameters, also performance ge are: standing wave ratio (VSWR) - better than 1.15, Decoupling - better than 35 dB, ellipticity - better than 1 dB over 15% of the frequency range. The cross-sectional dimensions in units of the average wavelength are un dangerous 0.6 × 0.6. The ellipticity range through a change in tooth height is at least 1 dB without thereby losses in the standing wave ratio and the separation to fear.

Another preferred embodiment of the invention is the microwave septum OMT with a linearly orthogonal polarization base, in which the differential phase shift elements 3 are arranged in the rectangular waveguide symmetry plane so that they are orthogonal to the plane of the stepped septum 2 . This OMT, which is shown schematically in Fig. 4, has a rectangular waveguide body 1 , which is divided into two equal rectangular sections by a central stepped septum 2 , and a differential phase shifter element 3 in the form of two opposing, thin, metallic and ge shaped combs, which are arranged in the waveguide symmetry plane orthogonal to the septum plane. The OMT thus has a right-angled, in particular square, waveguide input port 7 at one end and a dual port area at the other end, which consists of two rectangular waveguide output ports 8 and 9 . The differential phase shifter element 3 , which has the shape of two opposing, thin, metallic combs, is shown in Fig. 5. The shape of the septum is shown in Fig. 6. The septum consists of three levels 4 , 5 and 6 .

The operation of this preferred embodiment of the invention will now be described. An arbitrarily polarized signal can be resolved into a first and a second orthogonal component. One component is linearly polarized in the plane of the ridge and the other is linearly polarized in the plane of the stepped septum. The two thin combs, the points of which are not of the same height, give the same value for the differential phase shift for the first component as the stepped septum for the second component. As a result, the total differential phase shift in a certain frequency range is equal to 0 degrees. In order to achieve a large bandwidth of the OMT, the phase response characteristic of the differential phase shifter elements 3 in the working frequency range must match the phase response characteristic of the graduated septum 2 . In this case, the septum OMT can be used to resolve arbitrarily polarized signals in linearly orthogonally polarized components. The polarization planes are inclined at 45 degrees to the plane of the stepped septum 2 .

An OMT with an alternative linear base can be realized with a total differential phase shift of 180 degrees of the septum OMT. This may have the same construction as the first preferred embodiment ( FIGS. 1 to 3), but obviously must have a larger number of teeth (on the comb).

By choosing different shapes of the septum and different shapes of the differential phase shifter elements, a large number of different embodiments of the invention can be realized. The septum and differential phase shifter elements can be integrated in one unit. Some of the possible shapes of the septum and differential phase shifter elements are shown in FIGS. 7-9.

In Fig. 7, a simple stepped septum is formed in one unit with a thin metallic comb consisting of various gradations. This is one of the best solutions to achieve the required frequency characteristics in a wide frequency range.

For reasons of simpler manufacture, a beveled septum with a phase-shift element protruding from the back may be more suitable. This embodiment is shown in Fig. 8. The septum 2 and the thin metallic phase shifter element 3 are formed in one piece in one unit.

Another possible embodiment of the septum 2 and the differential phase shifter elements 3 are shown in FIG. 9. The septum 2 is of a rounded, rising shape and is tapered in a conical shape. The differential phase shifter element 3 consists of a corrugated thin metallic back.

In addition, a septum OMT according to the invention can be formed with any combination of any shape of the phase shifter element, to which the requirement is that they ensure the required differential phase shift. The septum and the differential phase shifter elements are structurally combined in a compact area to ensure the required ellipticity (polarization basis) and good separation in a large frequency range. In order to achieve the greatest possible compactness of the OMT, the projections of the septum and the differential phase shifter elements on the waveguide symmetry axis must be crossed or intersect. This can be achieved by opposing an arrangement, as shown in FIG. 1 or the rectangular arrangement of FIG. 4 can be achieved. The adaptation problem must be solved simultaneously for the interfering differential phase shifter elements and the septum, because these two have an influence on one another.

Claims (7)

1. Microwave septum with OMT
a waveguide body ( 1 ) with an input port ( 7 ) for receiving signals with orthogonally polarized components,
a dual port area consisting of a first ( 8 ) and a second port ( 9 ) on each side of the common septum wall in the waveguide body ( 1 ),
a coupling area between the output ports ( 8 , 9 ) and the input port ( 7 ), in which the height of the septum gradually decreases,
differential phase shifter elements ( 3 ), the projections of which are directed to a waveguide symmetry axis and the projections of the septum ( 2 ) are directed on the same axis. 2. Microwave septum OMT according to claim 1, characterized in that the septum ( 2 ) and the differential phase shifter elements ( 3 ) are integrally formed in one unit in the form of a thin metallic tooth or comb-shaped or back-shaped. 3. Microwave septum OMT according to one of the preceding claims, characterized in that the septum ( 2 ) together with the differential phase shifter elements ( 3 ) generates an overall differential phase shift of 90 degrees. 4. Microwave septum OMT according to one of the preceding claims, characterized in that the septum ( 2 ) together with the differential phase shifter elements ( 3 ) generates an overall differential phase shift of 180 degrees. 5. Microwave septum OMT according to one of the preceding claims, characterized in that the septum ( 2 ) and the differential phase shifter elements ( 3 ) are arranged in orthogonal symmetry planes of the waveguide and together produce an overall differential phase shift of 0 degrees. 6. Microwave septum OMT according to one of the preceding claims, characterized in that the height of the septum ( 2 ) is successively reduced by steps, bevels or tapers. 7. Microwave septum OMT according to one of the preceding claims, characterized in that the septum ( 2 ) and phase shifter elements ( 3 ) are formed in one plane.