DE19752100C1 - Compact and low-attenuation type directional microwave filter - Google Patents

Abstract

The filter has a substrate 1 with a planar conductor structure in the way of a microwave circuit and within the substrate are formed two hollow waveguide filters 2,3 that have the characteristics of a directional filter. The filters have multiple resonator chambers 21-24,31-34 that have coupling orifices 25-28, 35-38. The exact number of resonators and orifices define the filter characteristics.

Description

State of the art

The present invention relates to a directional filter, consisting of two filters with the same Filter characteristics and at least one 3 dB Lei power divider that is equal to an input signal Share power between the two filters and the Output signals of the filters combined.

There is frequency filtering in active microwave modules e.g. B. between frequency converters and amplifier units necessary to avoid disturbing image frequency and Suppress oscillator signals, the one used Filters also outside of the useful frequency band largely reflection-free conclusion for the active Circuit components must provide. To this end directional filters are generally used.

A directional filter consisting of two as described in the introduction Filter with the same filter characteristics and one 3 dB power divider to split one Input signal power to the two filters and one another 3 dB power divider for combining the  Output signals of the two filters is off "Microwave Filters Impedance-Matching Networks, and Coupling Structures "by G.L. Matthaei, L. Young, E.M.T. Jones, McGraw-Hill Book Company 1964, pp. 966-968.

It is now the object of the present invention Directional filter of the type mentioned to specify that is as compact as possible and also low-damping is and has good selection properties.

Advantages of the invention

According to the features of claim 1, said Problem solved in that the two filters with the same Filter characteristics are designed as a waveguide filter and this waveguide filter in a planar line structure are integrated, the at least one Input signal between the two filters and the Output signals of the filter combining 3 dB Lei designed in planar line technology and is coupled to the waveguide filters.

The use of waveguide filters can be very meet high selection requirements (blocking frequency band approx. 3% next to the useful frequency band). With a planar Such a good selection cannot be made using a filter structure realize, also not a very small one Insertion loss, as can be achieved with waveguide filters is. Because even slight fluctuations in the properties of the Substrate material lead to strong fluctuations in the Filter characteristic, which is particularly disadvantageous a serial product. With waveguide filters can be  Realize optimal filter characteristics, in particular because damping poles at any frequencies in the stop band can be realized. Because all the rest Circuit components implemented in planar line technology results in a very space-saving Circuit arrangement with the very high demands on the Quality of the directional filter can be met.

Advantageous developments of the invention can be seen in the Sub-claims emerge.

A very compact arrangement is obtained in that the Waveguide filters are part of a housing that accommodates serves a substrate of the planar line structure. So can e.g. B. the waveguide filter from two half-shells exist, of which a half-shell in the lid of the Housing and the other half shell in the bottom of the housing is integrated and that the substrate with the at least one 3 dB power divider in the separation plane between the two Half shells.

The at least one is preferably coupled planar 3 dB power divider to the waveguide filter in that the input or output line arms of the 3 dB Lei stung Divider on tongue-like extensions of the substrate extend which protrude into the waveguide filter.

The directional filter can be constructed so that a first 3 dB power divider the input signal to the two Split waveguide filter with bandpass characteristics and that a second 3 dB power divider the output signals of the combined two waveguide filters.  

Another embodiment is that a single one 3 dB power divider the input signal to the two Split waveguide filter with band stop characteristic and that the same 3 dB power divider that of the two Waveguides combined signals combined.

Description of exemplary embodiments

Using several shown in the drawing The invention is described in more detail below explained. Show it:

Fig. 1 shows a first cross-section AA,

Fig. 2 shows a second cross section B-B through a directional filter with two 3-dB power splitters,

Fig. 3 shows a cross section through a directional filter with a 3 dB power divider and

Fig. 4 shows a detail of a directional filter with a variant for coupling of a planar 3 dB power divider to a waveguide filter.

In Figs. 1 and 2 two mutually orthogonal sections through a directional filter. The section AA shown in FIG. 1 runs parallel to a cut-out substrate 1 with a planar line structure of a microwave circuit. Two waveguide filters 2 and 3 are inserted into the substrate 1 , both of which have the same filter characteristic for a directional filter. The waveguide filter 2 or the waveguide filter 3 each have a plurality of cavity resonators 21 , 22 , 23 , 24 or 31 , 32 , 33 , 34 , which are connected to one another via coupling screens 25 , 26 , 27 , 28 or 35 , 36 , 37 , 38 are coupled. The number and position of the cavity resonators and coupling diaphragms of the two waveguide filters 2 and 3 is chosen so that a desired filter characteristic results.

On the substrate 1 there is a first 3 dB power divider 4 , which is implemented in planar line technology and divides an input signal on its input line 41 over its two output lines 42 and 43 in equal parts. The output line 42 of the 3 dB power divider is coupled to the waveguide filter 2 and the output line 43 to the waveguide filter 3 . Each output line 42 or 43 is coupled to the respective waveguide filter 2 or 3 by extending on a tongue-shaped extension 44 or 45 of the substrate 1 , which extends into the first cavity resonator 21 or 31 of the waveguide filter 2 or 3 protrudes. As the cross-section BB shown in FIG. 2 illustrates, the tongue-shaped extension 45 projects through a slot 6 in the waveguide wall of the cavity resonator 31 . The idling end of the output line 43 on the tongue-shaped extension 45 acts like a coupling antenna. The same applies to the tongue-shaped extension 44 and the idling end of the output line 42 extending thereon.

In the illustrated embodiment, the 3 dB power divider is a so-called Wilkinson divider. Its two output lines 42 and 43 are bridged by an ohmic resistor 46 . Thus, a required phase difference is created in this divider between the output signals of the two output lines 42 and 43 of 90 ° exists between the two output lines 42 and 43, a length difference of λ / 4. Instead of a Wilkinson divider, any type of 3 dB power divider can also be used.

The output signals of the two waveguide filters 2 and 3 are combined via a second 3 dB power divider 5 . For this purpose, the two input lines 52 and 53 of the 3 dB power divider 5 are coupled to the two waveguide filters 2 and 3 in the same way as the output lines 42 and 43 of the first 3 dB power divider 4 . The input line 52 extends on a tongue-shaped extension 54 , which projects into the cavity resonator 24 of the first waveguide filter 2 , and the output line 53 extends on a tongue-shaped extension 55 , which projects into the cavity resonator 34 of the second waveguide filter 3 . Using the example of the input line 53, it is shown in FIG. 2 that the tongue-shaped extension 55 projects with the end of the input line 53 through a slot 7 into the cavity resonator 34 . The second 3 dB power divider is also designed, for example, as a Wilkinson divider, in which the input lines 52 and 53 are bridged by an ohmic resistor 56 .

The cross-sectional view BB in FIG. 2 shows that the substrate 1 is provided with a ground surface 8 in a known manner on its side opposite the line structure. This ground surface 8 is contacted with the waveguide filters 2 and 3 where the tongue-shaped extensions 44 , 45 , 54 , 55 lead through slots 6 , 7 in the waveguide walls into the cavity resonators 21 , 31 , 24 , 34 . The ground surface 8 is removed below the ends of the lines 44 , 45 , 54 , 55 projecting into the cavity resonators 21 , 31 , 24 , 34 .

As FIG. 2 shows, the substrate 1 is accommodated in a housing 9 , which consists of a bottom part 91 and a cover part 92 . A very compact arrangement results when the two waveguide filters 2 and 3 are divided into two half-shells in such a way that the first half-shell of the two filters 2 and 3 is integrated on the bottom part 91 and the second half-shell on the cover part 92 . The substrate 1 with the planar line structure runs in the parting plane 10 between the two half-shells of the waveguide filters 2 and 3 . This results in a very simple assembly of the waveguide filters 2 and 3 with the 3 dB power dividers 4 and 5 on the substrate 1 . The separation of the waveguide filters 2 and 3 into two half-shells also has advantages in the production of the cavity resonators of the waveguide filters 2 and 3 .

In the exemplary embodiment of a directional filter shown in FIG. 3, a single 3 dB power divider (for example a ring hybrid coupler) is coupled to the two waveguide filters 2 and 3 . This 3 dB power divider has four gates 111 , 112 , 113 and 114 . The line ends of the gates 112 and 113 are coupled to the waveguide filters 2 and 3 in the manner described above via the tongue-like extensions 44 and 45 . An input signal present at the gate 111 is divided via the 3 dB power divider 11 into the same power units between the two gates 112 and 113 . In contrast to the exemplary embodiment in FIG. 3, the two filters 2 and 3 , into which the power components are coupled, do not have a bandpass characteristic but a bandstop characteristic. Accordingly, the cavity resonators 21 , 22 , 23 , 24 and 31 , 32 , 33 , 34 and the associated coupling plates 25 , 26 , 27 , 28 and 35 , 36 , 37 , 38 of the two filters 2 , 3 are arranged such that the input signal is reflected in the useful frequency band. The reflected signal components at the gates 112 and 113 are combined by the 3 dB power divider 11 , so that the entire output power of the useful frequency band is available at the gate 114 .

In a modification of the filters 2 and 3 of the exemplary embodiment shown in FIG. 1, a further cavity 244 or 344 is coupled to the cavity resonator 24 or 34 of the filter 2 or 3 via a coupling aperture 244 or 345 . This additional cavity 244 or 344 is at least partially filled with an absorber material 246 or 346 in order to absorb frequency components outside the useful frequency band.

In Fig. 4 is shown using the example of the waveguide filter 2 that the coupling of the planar lines 42 of the 3 dB Lei stung Divider does not have to be made directly to the first resonator 21 of the filter, but that the coupling also via a short-circuited waveguide piece 211 to the Filter 2 can be done. The waveguide piece 211 is in turn coupled to the first cavity 21 of the filter 2 via a coupling screen 212 . Thus, the coupling of the 3 dB power divider to the filter is independent of the planar line on the tongue-like extension 44 of the substrate 1 . In this way, each planar line can be coupled to filter 2 or 3 .

Claims (6)

1. Directional filter, consisting of two filters ( 2 , 3 ) with the same filter characteristics and at least one 3 dB power divider ( 4 , 5 , 11 ), which distributes an input signal to the two filters ( 2 , 3 ) in equal amounts and the output signals of the filters ( 2 , 3 ) combined, characterized in that the two filters ( 2 , 3 ) are realized as waveguide filters and that these waveguide filters ( 2 , 3 ) are integrated in a planar line structure ( 1 ), the at least one 3 dB power divider ( 4 , 5 , 11 ) executed in planar line technology and coupled to the waveguide filters ( 2 , 3 ). 2. Directional filter according to claim 1, characterized in that the waveguide filter ( 2 , 3 ) are part of a housing ( 9 ) which serves to receive a substrate ( 1 ) of the planar line structure. 3. Directional filter according to claim 1, characterized in that a first 3 dB power divider ( 4 ) divides the input signal into the two waveguide filters ( 2 , 3 ) with bandpass characteristics and that a second 3 dB power divider ( 5 ) divides the output signals of the two waveguide filters ( 2 , 3 ) combined. 4. direction Filter according to claim 1, characterized in that a single 3 dB power divider (11), the input signal to the two waveguide filters (2, 3) is divided with bandstop characteristic and that the same 3 dB Lei stungsteiler (11) of the two waveguide filters ( 2 , 3 ) reflected signals combined. 5. Directional filter according to claim 2, characterized in that the waveguide filter ( 2 , 3 ) consist of two half-shells, of which one half-shell in the cover part ( 92 ) of the housing ( 9 ) and the other half-shell in the bottom part ( 91 ) of the housing ( 9 ) is integrated and that the substrate ( 1 ) with the at least one 3 dB power divider ( 4 , 5 , 11 ) lies in the parting plane ( 10 ) between the two half-shells. 6. Directional filter according to one of the preceding claims, characterized in that for coupling the at least one planar 3 dB power divider ( 4 , 5 , 11 ) to the waveguide filter ( 2 , 3 ) there are input and output line arms ( 42 , 43 , 52 , 53 , 112 , 113 ) of the 3 dB power divider ( 4 , 5 , 11 ) on tongue-like extensions ( 44 , 45 , 54 , 55 ) of the substrate ( 1 ), which protrude into the waveguide filter ( 2 , 3 ) .