DE1942867A1 - Filter for very short electromagnetic waves - Google Patents

Description

Very Short Electromagnetic Wave Filters The invention relates to a filter for very short electromagnetic waves with at least six interconnected coupled resonators, of which the first and last resonator with connecting lines for the feed or the decrease of the electromagnetic energy are provided, and not directly between at least two in terms of electrical operation successive resonators an additional coupling is providedo filter of microwave technology are known to consist of several, coupled with each other Microwave resonators are built whose coupling is either capacitive or inductive can be done. The resonators themselves can, for example, as so-called Coaxial line resonators or waveguide resonators are contrary to the With concentrated switching elements built piltern can be due to the geometrical fixed configuration of the resonators not all in concentrated technology realizable circuit easily transferred to the frequency range of microwaves. This difficulty is particularly annoying when it comes to it ankomrat, in the damping characteristics of the yter so-called damping poles, i.e. thus creating infinity points of damping. At least about this crankiness to partially remedy it is already known from US Pat. No. 2,749,523 become, with a micro wave filter each other in the electrical mode of operation Resenators that are not consecutive additionally with each other to couple. Apart from the fact that according to this known arrangement only resonators certain different groups can be coupled with each other occurs Then there is the difficulty that the additional coupling of not with one another neighboring resonators via line elements, in which on the one hand the special dimensioning of the length must be taken into account and with which on the other hand an additional space consumption occurs because these contributions outside the filter resonators are arranged The invention is based on the object to remedy the aforementioned difficulties in a relatively simple manner.

Starting from a filter for very short electromagnetic waves with at least six resonators coupled to one another, each of which is the first and last resonator with connecting lines for supply and removal the electromagnetic energy are provided, and at least zwisch.en two resonators that are not directly consecutive in their electrical mode of operation an additional coupling is provided, this object is achieved according to the invention solved in such a way that the individual resonators in at least zvrei superimposed Lines are arranged in such a way that the two lines next to one another or one above the other lying resonators each have a common partition that those in the partition walls organs provided for coupling the resonators are arranged such that the Electromagnetic energy supplied to the filter successively the resonators of the first and second line passes, and that the additional couplings between in the electrical mode of action not directly on successive resonators in the common partition each time, in different lines arranged resonators are provided.

The invention will be explained below with the aid of an exemplary embodiment explained in more detail.

The drawings show: FIG. 1 a sectional view of a filter; Fig. 2 is a section along line A-A of Fig. 1; Fig. 3 the electrical Equivalent circuit diagram of a filter according to FIGS. 1 and 2; 4 shows the schematic attenuation curve of a filter according to FIG. 1.

In the embodiment of FIG. 1 there is one of eight coaxial line resonators 1 to 8 existing filters are shown, their inner conductors with the reference numerals 1 to 8 'are provided. The first resonator 1 and the last resonator 8 are in the embodiment with coaxial connection lines 9 and 9 ', the Inner conductors continued directly and with the inner conductors 1 'and 8' of the resonators 1 or 8 are galvanically connected. Instead of this coupling to the first one or the last resonator, other known coupling types are also conceivable. The resonators 1 to 8 are arranged in two superimposed rows B and C in such a way that the resonators lying next to or one above the other in both rows have a common partition, i.e. that resonators 1 and 2, the resonators 1 and 8, the resonators 2 and 7 and likewise the resonators 7 and 8 always have a common partition. Exactly the same considerations apply also for the resonators 3 to 6. The coupling elements for coupling the individual resonators are arranged in such a way that the filters fed to the filter at connection 9, for example electromagnetic energy successively the resonators of the first and second rows runs through, i.e. that the electromagnetic energy first passes through the resonators 1 to 4 of row B passes through, in resonator 4 in the first resonator 5 of the second Row C is deflected and then the resonators 5 to 8 of the second row passes through. In the embodiment, these Kqppelorgane are designed as hole couplings, which can optionally also be replaced by a loop coupling and it the coupling from resonator 1 to resonator 2 takes place through the coupling opening 12, from the resonator 2 to the adjacent resonator 3 via the coupling opening 23, from the resonator 3 to the resonator 4 via the coupling opening 34 and finally the resonators 4 to 8 are coupled via the coupling openings 45, 56, 67 and 78.

Ln the partition wall common to resonators 1 and 8, as well as in of the resonators 2 and 7 and in the partition wall common to the resonators 3 and 6 an additional coupling element 18 or 27 or 36 is arranged by the resonators that are not directly consecutive in their electrical mode of operation can also be coupled with each other. The additional coupling elements 18, 27 and 36 are therefore in the common partition, two in each of the different ones Rows B and C of arranged resonators.

In the exemplary embodiment, the additional coupling elements 18 and 36 designed as capacitive pin couplings, being the pins are each fixed in consisting of dielectric material disks 11, the Attachment in turn to the partition walls of the resonators, for example by a Gluing can be done. The additional coupling element 27 couples the resonators 2 and 7 and is an inductive hole coupling, i.e. it is similar to the coupling the resonators.

In the sectional drawing according to Pig. 2 the inner conductors 1 ', 2', 3 'and 4' of the resonators 1, 2, 3 and 4 can be seen, as well as the tuning elements acting screws 10, which the inner conductors on the front side opposite are arranged and the final capacitance of the resonators is still due to their immersion depth changed and thus the resonance frequency of the individual circuits can be set can.

In FIG. 3 is the physical equivalent circuit diagram of the one in FIG The filters shown in FIGS. 1 and 2 are shown and those with the filter according to FIG. 1 have the same effect Elements in FIG. 3 have been given the same reference numerals. The equivalent circuit diagram shows a four-pole circuit, in the cross points of which the parallel resonance circuits 1 to 8 are located0 The input 9 and the output 9 'are as a tap on the coils of the resonance circuits 1 and 8 because, as can be seen from Fig. 2, the inner conductors of the supply lines 9 or 9 'brought up to a section of the resonator inner conductor 1' or 8 ' sind0 The coupling of the parallel resonance circuits 1 to 8 takes place via the coils 12, 23, 34, 45, 56, 67 and 78, through which the inductively acting hole coupling, like them in Fig0 1 can be seen, is simulated. In addition, there are the parallel resonance circuits 3 and 6 via a capacitor 36, the parallel resonance circuits 2 and 7 via a Coil 27 and the Parallel resonance circuits 1 and 8 via another Capacitor 18 coupled together. Capacitors 36 and 18 form the stitches 36 and 18 in the exemplary embodiment according to FIG. 1, the coil 27 forms the hole coupling 27 after.

The additional overcouplings 18, 27 and 36 can be three Generate pairs of damping poles. The attenuation from a filter according to FIG. 1 is schematic Plotted in Pig. 4 as a function of the frequency f. As can be seen from Fig.4 is, the additional couplings create attenuation poles in the blocking area the frequencies f + 001, f-oo1, f + 2 'f- 2' + oo 3 and f co-co3 'which are each paired are above and below the pass band DB.

Waveguide resonators can also be used instead of coaxial line resonators or arrange strip line resonators in the manner described. Farther it is possible to place the resonators in more than two rows one above the other in the to be arranged in the manner described.

If, with resonators of the same type, the coupling of the resonators is inductive takes place and the additional couplings alternate capacitive and inductive or conversely, the coupling of the resonators capacitive and the additional couplings alternately inductive and capacitive, then pole positions can be used at real frequencies are generated, which express themselves as poles in the damping curve. After the on known rules of filter theory, it is also possible for the coupling of the To use resonators and the additional coupling similar coupling means, whereby Poles can also be generated at so-called complex frequencies. Such poles are known to express themselves through an influence of the runtime behavior of a filter and can therefore be used to achieve special runtime properties be used with a microwave filter. For this reason it is for example possible, in the embodiment of FIG. 1, the additional coupling elements 18 and 36 to be replaced by a hole coupling, which then acts just as inductively as the couplings 12, 23, 34 etc., with the additional coupling 27 as a capacitive Pin coupling can be designed to leave attenuation poles at complex frequencies can also be achieved if, instead of the hole couplings, capacitive pin couplings are used to couple the resonators and the couplings shown in FIG. 1 18, 27 and 36 are retained as additional couplings.

By the filter described above, which is used to achieve the The desired effect must consist of at least six individual resonators a mechanically compact structure can be achieved with only a small amount of space required. In addition, filters with poles of attenuation also have the advantage that the Running time within a relatively large area of the pass band relatively small and almost independent of frequency. As the resonators If you have a common partition wall, resonators with a rectangular or circular shape will be used Use cross-section, which makes it relatively easy to manufacture and thus achieve only a small spread of the individual copies during production leaves. Since the coupling of the resonators takes place in such a way that the -electromagnetic Energy successively passes through resonators lying in the same row and the additional couplings each have resonators in different rows couple, lets. the maximum with such a filter structure achievable Realize the number of attenuation poles without taking up additional space.

6 claims 4 figures

Claims (6)

P a t e n t a n t check s for very short electromagnetic filters Waves with at least six resonators coupled together, each of which the first and last resonator with connecting lines for supply and removal the electromagnetic energy are provided, and in which between at least two In terms of their electrical mode of operation, the resonators are not directly consecutive an additional coupling is provided, d u r c h g e n n n z e i 0 h n e t that the individual resonators (1 to 8) in at least two superimposed Lines (B, C) are arranged in such a way that the two lines (S, C) next to each other (e.g. 1.2; 7.8) or one above the other (e.g. 1.8; 2.7) each one have common partition that in the partition walls for coupling the resonators (1 to 8) provided organs (12,23,54,45, 56,67,78) are arranged in such a way that the electromagnetic energy supplied to the filter successively the resonators the first (B) and second (C) lines, and that the additional couplings (18, 27, 36) between those which are not directly consecutive in their electrical mode of operation Resonators (1.8; 2.7; 3.6) in the common partition are two, in different Rows (B, C) arranged resonators (1.8; 2.7; 3.6) are provided. 2. Filter according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the organs (z.3. 12,23,341 as inductive couplings and the additional couplings (18,27,36) alternate are designed as capacitive and inductive couplings. 3. Filter according to claim 1, d a d u r c h g e-k e n nz e i c h n e t that the organs provided for coupling the resonators (1 to 8) (e.g. 12, 23, 34) as inductively acting couplings and the additional couplings (18,27,36) alternately are designed as inductive and capacitive acting couplings. 4. Filter according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the organs provided for coupling the resonators (1 to 8) (e.g. 12,23,34) as capacitive couplings and the additional couplings (18,27,36) alternately are designed as inductively and capacitively acting couplings. 5. Filter according to claim 1, (1 a (1 u r c h g e k e n n -z e i c h n e t that the organs provided for coupling the resonators (1 to 8) (e.g. 12,23,34) as capacitive couplings and the additional couplings (18,27,36) are alternately designed as capacitive and inductive couplings. 6. Filter according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the coupling of the resonators (1 to 8) and the additional couplings (18,27,36s are similar to one another. L e r s e i t e