DE1143247B - Frequency-selective mode converter for very short electromagnetic waves - Google Patents

Description

Frequency-selective wave type converter for very short electromagnetic Waves The invention relates to a wave type converter for devices of High-frequency technology, in particular hollow cable transmission systems, for frequency-selective Conversion of H, waves in the circular waveguide into H "waves in the rectangular waveguide.

For the transmission of very short-wave electromagnetic energy The H, wave in the round tube is preferred over long lines because it is in contrast has a very low path attenuation compared to other wave types. Since H, waves Do not allow unimodal reinforcement in the round tube and otherwise no "more stable" Wave type, you need wave type converters at least at the sending and receiving locations, which allow the H, waves from the round tube into a rectangular waveguide decoupling and transforming them into waves of the stable H "-type. Such wave-type converters are generally constructed according to the directional coupler principle, the rectangular waveguide z. B. is coupled via a row of holes in the partition they share. the The coupling path must be selected to be relatively long in order to achieve the desired mode purity ensure during the conversion. In addition, in some applications of a certain frequency selectivity are required of such facilities. For example it occurs in hollow cable transmission systems whose hollow cable shafts of the H, -type in a broad frequency band lead, on this, certain sub-frequency bands selectively to be coupled into a rectangular waveguide without disturbing the rest of the frequency band. For this purpose, wave-type directional couplers of the type described can no longer be used, because they cannot be trained in a sufficiently frequency-selective manner. A frequency selective wave type converter can also be realized with the help of resonators that resonate from a make use of the rotating shaft. Wave type converters of this type consist of one Waves of the H.1-type leading round waveguide, the one with the rectangular waveguide over preferably several ring line resonators are connected. Here are the Round waveguide and the rectangular waveguide on the resonator assembly on top of each other opposite sides of the line rings connected. Since the coupling lines especially between the ring lines and the circular waveguide with regard to a wave type conversion that is as perfect as possible have a relatively great length have to result in very unwieldy dimensions of the overall arrangement.

The invention is based on the object of a frequency-selective Wave type converter of the type described in the introduction, among other things, with regard to its to improve constructive structure significantly.

For a wave type converter for the frequency-selective conversion of H "waves in the round waveguide in H "waves in the rectangular waveguide in which the round waveguide with the rectangular hollow conductor via one that works according to the principle of circumferential resonance Resonator arrangement is in electrically conductive connection and the coupling both the circular waveguide and the rectangular waveguide to the resonator arrangement Directional coupler type takes place, the object is achieved in that the Resonator arrangement consists of at least one ring pot with an inner conductor, which the Circular waveguide encloses concentrically.

There are wave type converters known in which one in the circular waveguide Guided wave of the H, -type converted into a Hlo wave in a rectangular waveguide that surrounds the circular waveguide in a ring and goes through with the circular waveguide Coupling slots is connected. Such arrangements leave no selectivity in Meaning of the subject matter of the invention. This is evident from the fact that the from Rectangular waveguide enclosed circular waveguide section short-circuited on one side is. In addition, the known arrangement lacks the essential for the subject matter of the invention, a ring pot with inner conductor representing resonator arrangement.

The invention will be explained in more detail below using exemplary embodiments that are shown in the drawing. The single-circuit frequency-selective wave type converter according to the invention, shown in section in FIG. 1, consists of an inner round tube 1 which is concentrically enclosed by a ring cup 24. The inner conductor 3 of the ' ring bowl # e #, 2> consists of' metal rings 4 and rings 5 made of vissored dielectric material, which are alternately stacked to form a laminated cylinder. Furthermore, a rectangular waveguide 6 is coupled to the outside of the ring pot 2, which is arranged axially parallel to the round tube 1 and merges into the connecting flange 7 at its left end. The right end of the rectangular waveguide 6 is closed with a wedge 8 made of lossy dielectric material with little reflection.

The round tube 1 as well as the rectangular waveguide 6 are coupled to the ring cup 2 by coupling sections 9 and 10 , which each run in the axial direction of the arrangement. While the coupling section 10 between the ring pot 2 and the rectangular waveguide 6 consists only of a row of holes, the coupling section 9 between the round tube 1 and the ring pot 2 consists of six rows of holes, which are arranged at equal angular intervals of 60 ' on the circumference of the round tube 1 are.

The ring pot 2 represents a torus, that is to say a body that is closed in two dimensions in the shape of a ring. On the one hand it closes in a ring around the round tube 1, and on the other hand it forms a closed ring around the inner conductor 3 . A waveband of the H "type, which enters the round tube 1 from the left and is designated A (f, + J), excites a wave in the ring pot 2 via the coupling path 9 which encircles the inner conductor 3 in only one direction (arrows) due to the directional coupling effect of the H "type. If the (mean) length of the circumference of the ring is a multiple of the wavelength of the rotating wave, resonance occurs. The corners 11 of the ring pot 2 are suitably beveled so that the rotating resonance wave is deflected around the end faces of the inner conductor 3 in a reflection-like manner. As indicated in the exemplary embodiment in FIG. 1 , the ring cup 2 is dimensioned for the partial frequency range, 1f, (with f, = center frequency of the pass band). Practically all of the energy in this partial frequency range is coupled over from the round tube 1 into the rectangular waveguide 6 . Conversely, electromagnetic energy in a partial frequency range, df, can also be coupled into the round tube 1 via the rectangular waveguide 6 without disturbing other wavebands already present in the round tube 1.

The bandwidth of the sub-frequency band to be coupled out as well as the selectivity of the filter arrangement is - apart from the number of circles used - dependent on the coupling factors between the ring pot 2 and the round tube 1 on the one hand and the rectangular waveguide 6 on the other. The smaller the coupling factors are compared to 1 , the narrower and steeper the filter is. The filter also has a whole series of periodically alternating pass and stop ranges, the number of half-waves occurring on one revolution around the inner conductor being decisive for the frequency width of this period. The more half-waves that can be accommodated in one cycle, the faster the passage and cut-off areas of the ring-pot filter follow one another and the narrower the cut-off areas are up to the next (undesired) pass band. The ring pot 2 is therefore expediently made as short as possible, for. B. so that the circuit around the inner conductor 3 is only # two or three half-waves long.

The purpose of the lamination of the inner conductor 3 is to suppress the resonance of the ring cup 2 in undesired, interfering wave types. The laminated inner conductor 3 causes a strong attenuation for all non-rotationally symmetrical H .. waves with m = 0. In contrast to Ho. Waves, they have an axial component of the wall currents and are therefore effectively attenuated by the rings 5 made of lossy dielectric material. For the absorption of the non-rotationally symmetrical waves of the Hm. Type with m > 0 , other wall parts of the ring cup 2 can of course also be laminated in place of the inner conductor 3 or in addition in the manner described.

If the inner conductor 1 were only coupled to the ring pot via a row of holes, then even with an H "resonance of the ring pot in the round tube, in addition to the H, wave, at least the H", H, and H "waves would be of comparable strength However, this is prevented by the six rows of holes in the coupling path 9 , which are regularly distributed around the circumference and which only work together correctly for the circularly symmetrical wave types, but compensate for each other in their effect for all other H .. types with m < 6.

The absorption losses resulting from the suppression of the interfering wave types in the ring pot 2 are extremely low. The unwanted wave types namely in the ring pot 2 only occur with small voltage amplitudes, because they, unlike the H "waves no opportunity to come into resonance. The excitation disturbing rotationally symmetric modes (n> 1) in the round tube 1 can in can be prevented in a manner known per se in that the diameter of the tube 1 is selected with regard to the frequency band to be transmitted so that the lowest frequency is still above the critical frequency of the 14 wave and the highest frequency is still below the critical frequency of the H " -Wave.

The frequency selective wave type converter according to the invention is not limited to single-circuit embodiments of the type shown in FIG. 1. In Fig. 2, a two-circle arrangement with two ring pots 2 and 2 'is shown schematically. The ring pot 2 is coupled to the round tube 1 by the coupling section 9 in the manner already described. The ring pot 2 'with the lamellar inner conductor 3' also concentrically surrounds the round tube 1 and is directly connected to the ring pot 2 on the left-hand side. The coupling between the two ring pots 2 and 2 'also takes place via a coupling path 12, for example a row of holes or slots in the partition wall common to both ring pots. Analogously to the exemplary embodiment according to FIG. 1 , in FIG. 2 the rectangular waveguide 6 is coupled to the ring cup 2 'via the coupling path 10'.

Another exemplary embodiment of a dual-circuit arrangement, however, the two ring pots are arranged 2 and T 'concentrically one above the other in which is also shown schematically in FIG. 3. The mutual coupling of the two ring pots 2 and T 'takes place here via the coupling section 13 in the outer jacket of the ring pot 2 and the coupling of the rectangular waveguide 6 with the ring pot Y' via the coupling section 10 ".

For arrangements with more than two circles, it is advantageous to arrange the individual ring pots both one behind the other around the round tube 1 and one above the other, because this enables particularly favorable dimensions to be achieved.

In the case of narrow, multi-circle ring pot arrangements, the Resonance frequency of the individual circuits required. This can be done in an expedient manner parallel to the end faces of the ring pots each have an annular disk made of low-loss dielectric material, for example polystyrene, are installed in the axial direction is movable.

Claims (2)

PATENT CLAIMS: 1. Wave type converter for devices of the high frequency technology, in particular hollow cable transmission systems, for the frequency selective conversion of H, -waves in the round waveguide in H "-waves in the rectangular waveguide, in which the round waveguide with the rectangular waveguide over a working according to the principle of the revolving resonance resonator arrangement into electrical conductive connection and the coupling of both the circular waveguide and the rectangular waveguide to the resonator arrangement takes place in the directional coupler type, characterized in that the resonator arrangement consists of at least one ring pot with inner conductor which concentrically surrounds the circular waveguide. 2. Wave type converter according to claim 1, characterized in that the coupling of the ring pot to the circular waveguide takes place through several rows of holes or slots which are distributed at equal angular intervals on the circumference of the circular waveguide and are attached to run in the axial direction. 3. Wave type converter according to claim 1 or 2, characterized in that the rectangular waveguide is arranged on the outside of the ring cup parallel to the circular waveguide and is coupled to the ring cup via a coupling path extending in its axial direction. 4. wave type converter according to one of claims 1 to 3, characterized in that the walls of the ring pot are at least partially laminated in the manner of a wave type cleaner. 5. wave type converter according to one of the preceding claims, characterized in that the inner conductor of the ring pot is a cylinder arranged concentrically to the ring pot. 6. Wave type converter according to claim 4 or 5, characterized in that the cylinder consists of metal rings and rings made of lossy dielectric material which are stacked one on top of the other. 7. wave type converter according to one of the preceding claims, characterized in that in the interior of the ring pot in each case one to the end faces arranged parallel in the axial direction displaceable annular disc is provided, which from low-loss. dielectric material. 8. Wave type converter according to one of the preceding claims, characterized in that the circular waveguide is in electrically conductive connection with the rectangular waveguide via a resonator arrangement of two or more superposed and / or side by side, via coupling paths in series coupled to one another ring pots with inner conductor. Documents considered: German Auslegeschrift No. 1011018; U.S. Patent No. 2,676,306.