DE1221737B - An arrangement for very short electromagnetic waves inserted in the course of a hollow line, designed as a band pass or band stop - Google Patents

Description

Inserted in the course of a hollow pipe, as a band pass or band stop trained arrangement for very short electromagnetic waves The invention relates focus on frequency-selective waveguide band filters for very high frequencies. she is applicable to frequency selective waveguide band filters, d. H. on filters that a Block or let through a certain frequency band.

Compared to the known waveguide band filters with comparable operating properties The present invention seeks to move waveguide band filters of the resonant element type create that have much smaller overall dimensions. Will filters be the type described at the beginning, namely in movable systems, preferably aircraft systems, used so it is of great importance that the size, weight and thus the cost of the filter can be kept as low as possible.

Frequency-selective waveguide band filters with resonance elements are known. Basically, however, they use filter elements that work with the advancing wave in the waveguide, usually with the wave of the predominant mode of oscillation (main mode), although filters with waves of harmonic oscillation are already known. The known filters consist of a large number of resonance elements - in the case of bandpass filters resonance slots, in the case of band-stop filters resonance waveguide lengths - which are arranged in cross-sectional planes within a rectangular waveguide in such a way that they are parallel to one another and, in the case of resonance slots, parallel to the broad sides of the waveguide lie or, in the case of the resonance conductor, lie parallel to the narrow sides. Here, successive elements along the waveguide are separated by a distance of a quarter wavelength or an odd multiple thereof. If the basic principles are taken into account, it can be seen that in a known filter the smallest spatial distance between two successive resonance elements in the waveguide is a quarter wavelength. The absolute smallest total length of the simplest frequency band filter, which consists of two resonance elements, is therefore only a quarter wavelength. In practice, however, where the construction of the filter requires the use of high quality factors, it is not possible to obtain these smallest dimensions satisfactorily because of the undesirable couplings between successive elements. In practice, a smallest spatial distance of 3/4 A is chosen. In the professional world prevailed to this day the opinion that the effect of this mutual undesired influence is only negligibly small if you choose the distance between the resonance elements greater than 2/4, as z. B. from the reference "Radio Engineering Handbook" by Keith Henney, 4th edition, MeGraw will Book Co. Inc., 1950, pp. 699 to 701, emerges.

There are already known waveguide filters that consist of a waveguide section provided with resonance elements arranged therein in the form of resonance slots are. The angled walls in which the slots are arranged, have a mutual distance of d / 4 or an odd number Multiples of this.

The German patent specification 755 343 also provides a directional radiator arrangement known for very short waves, where the distance between the radiator wall and the planar reflectors slightly smaller than A, / 4 is selected.

The object of the present invention is to provide improved frequency-selective To show waveguide band filters, in which the above-mentioned distance limits of successive resonance elements are significantly shortened.

Based on one inserted in the course of a hollow pipe, as a band pass or bandstop-shaped arrangement for very short electromagnetic waves with a waveguide section in which in at least two cross-sectional planes correspondingly dimensioned distance a discontinuity effective as a resonator is provided in the form of a resonance diaphragm or a dipole and the axes of the Aperture openings or the dipoles are rotated against each other within their planes and the resonance frequency of these discontinuities corresponds to the frequency range of the previous one An arrangement to be transmitted or to be blocked electromagnetic waves belongs, which oscillate in a stable, lowest order wave type is therefore in accordance with the invention proposed that the waveguide section having the discontinuities a has such a low cut-off wavelength compared to wavelength A, .the of the Arrangement to be transmitted or to be damped electromagnetic waves in the the input of this waveguide section preceding- hollow line that in connection with the appropriately chosen, preferably about 60 ° amounting angle between the Axes of the slots or dipoles of two successive discontinuities as well as due to the small mutual distance of all .discontinities, the, related on the wavelength A, is significantly smaller than a quarter of this wavelength and is preferably one eighth of this wavelength, the energy transfer of one to the other discontinuity exclusively through a decaying vibrational field type is effected.

While in the previously known arrangements the distance of the Has consciously chosen resonance elements (resonance slots) so large that the coupling by. the main mode transmitted via the waveguide is effected, makes the present invention for the coupling of - the arising on the resonance elements decaying types of vibration, uni thereby the required overall length to be able to shorten the arrangement significantly. Such types of vibration are through constant phase in connection with amplitude decrease characterized. The inventive The use of such types of vibration is in sharp contrast to the known Practice of waveguide filter design, as one has so far taken the greatest care applied to avoid such types of vibration.

It is possible to use the coupling required for this with a given coupling to calculate the minimum distance between two successive resonance elements. In in practice, however, this calculation is not necessary because the distance, which is approximately A / 8, can easily be determined empirically.

In the case of bandpass filters, the resonance elements are e.g. B. by Realized resonance slots. These slots are preferably in the form of a in the Anglo-Saxon specialist literature with the "dumb bell slot" designated slot, each of which consists of a straight slot cut through circular slits at both ends Holes is completed, punched out of a metallic partition, which is in a Cross-sectional plane of a rectangular waveguide is arranged. in case of a Band-stop filter, the resonance slots are replaced by resonance conductor lengths, e.g. B. by dipoles which are arranged in a cross-sectional plane in the waveguide and z. B. are supported by suitable insulating, supporting partitions, d. H. Partitions made of so-called extensive insulation in mesh form. In a very simple and preferred embodiment of the invention there are only two Resonance elements in the waveguide, and these are inclined to each other at an angle of 60 °, one at an angle of 60 ° and the other at an angle of 120 ° to the broad side of the Waveguide stands; in other words, the slots are at the same angle (quantitative) arranged to the waveguide, although the angles are opposite to each other are. However, it is not necessary that the angles with respect to the broad sides are equal (quantitative). More than two resonance elements can be used; in this case some of them may be parallel to each other, depending the design requirements. In all cases, however, there are at least two resonance elements, which are angularly offset from one another, d. H. which are not parallel to each other are. In the following the invention is based on 'exemplary embodiments and drawings explained in more detail. In the drawings, F i g. 1 is a perspective, schematic View of an exemplary embodiment, with part of the waveguide broken away is shown to reveal the internal structure; F i g. 2 is a diagram which shows the results obtained experimentally with the embodiment of FIG F i g. 1 have been achieved; F i g. 3 shows the invention applied to a Filter between two colinear ones. Waveguide lengths that are rotated by 90 ° against each other are, and F i g. 4 shows the invention applied to a filter between two waveguide lengths, which form a bend of 90 ° with one another and which also form a bend of 90 ° against one another are twisted.

In Fig. 1 contains a rectangular waveguide of normal variety in two cross-sectional planes two partition walls 2 and 3, which are spaced from each other. A centrally arranged resonance slot 4 or 5 of the "dumb-bell" type is formed from each partition wall punched out. In the arrangement shown, the slots are offset from one another by 60 °, each forming an angle of 60 ° with the broad side of the waveguide, however the angles are opposite in direction. The 60 ° angles are denoted by a. If the two slots 4 and 5 were parallel to each other, as in the case of known ones For belt filter designs, the spacing between partitions 2 and 3 would need to be a quarter wavelength be. In the arrangement according to the invention shown, however, the spacing is very large much lower. As I said before, the actual distance depends on the design parameters and is best determined empirically.

In one embodiment of the invention, as shown in FIG. 1 shown the cross-sectional dimensions of the waveguide were 10.75-5.46 cm, and the spacing between the slots was 0.12 the waveguide wavelength at the band center frequency, which was 2120 MHz. The experimental results achieved are shown graphically in F i g. 2, where the curve L is the attenuation in db (ordinate) and the curve P the differential phase shift in degrees (ordinate) means that both are dependent plotted against the frequency in MHz (abscissa).

If you adjust the spacing of the slots empirically, you will find easily a critical distance value where a critical coupling is achieved analogously to the one that one with a pair of same but parallel slots, which have a distance of a quarter wavelength, can observe.

It is of course not necessary to use the critical distance found in this way to adhere to exactly, because if you are a bit of this distance in one or the other deviates in the other direction, a degree of coupling can be achieved that is slightly above or something below the critical coupling, and that means a paractic one Degree of empirical freedom of design.

Of course, you can use known voting devices and known Coupling adapters, e.g. B. tuning and coupling adjustment screws, which in the waveguide are introduced, use in a filter according to the invention.

The invention allows kinks or bends to be built in waveguides in an elegant manner, which saves a great deal of space. F i g. 3 shows the application of the invention to two collinear waveguides 6 and 7 which are rotated by 90 ° with respect to one another. Between these waveguides there is a type of coupling chamber 8 with a rectangular cross section, which is enclosed between the narrow sides of the waveguides 6 and 7. A metallic partition 9 with a dumbbell-shaped slot 10 extends over one end of the chamber. Across the other end of this chamber extends an identical metal partition wall 11 with an identical dumbbell-shaped slot 12 therein. The slot 10 is at a suitable angle, e.g. B. 60 °, inclined relative to the broad side of the waveguide 6, while the slot 12 at a suitable angle, for. B. 60 °, to the broad side of the waveguide 7 is inclined.

F i g. 4 shows an exemplary embodiment where the waveguides are twisted in combination with one another and have a bend. There you can see two waveguides 13 and 14 at right angles to one another, which are also rotated by 90 ° with respect to one another. The broad end 15 of the waveguide 13 is arranged in a plane parallel to the narrow side of the waveguide 14, while the end side 21 of the waveguide 14 adjoining the coupling chamber overlaps the upper and lower broad sides of the waveguide 13 equally, as shown at 17 and 18. In fact, the waveguide 14 is inserted into the corner of the waveguide 13, as shown in FIG. 4 is clearly visible. A metallic partition 19 with a dumbbell-shaped slot 20 extends over the waveguide 13, where it opens into the coupling chamber formed between the waveguides, and a further partition 21 with a dumbbell-shaped slot 22 extends over the entry into the waveguide 14. The slot 20 is at a suitable angle, e.g. B. 60 °, inclined to the broad side of the waveguide 13, and the slot 22 can also be inclined at an angle α of 60 ° to the broad side of the waveguide 1.4.

In both embodiments of FIG. 3 and 4 are the angles of inclination of the two slots (one in each partition) chosen - the choice will be best empirically made - so that the evanescent waves in the space between them unite so that a critical coupling is achieved. The coupling can be made to the critical value can be adjusted by varying the angle between the slots or the distance between them or the dimensions of the boundary walls of the Space (the coupling chamber) in between or by some combination of these Measures. The angle between the slotted partitions in turn can be between fairly wide limits can be changed: they do not need to be changed as in FIG. 3 in parallel to be to each other or perpendicular to each other, as in FIG. 4. In the case of complex, combined twisting and bending can be three or more consecutive, inclined, critically coupled slots are used. The invention can also be used for critical coupling via rotary joints, which are often used in Radar systems are used to connect the feed waveguide to a rotating rotating antenna waveguide to connect.

The invention is suitable for the construction of highly dispersive, loaded lines. If you have a large number consecutive and in one Provides spaced apart, mutually offset resonance elements, this waveguide will act as a dispersive, loaded conduit, and it is easily possible to make such a line more than ten times as dispersive as an otherwise similar, unloaded line over a bandwidth of approximately 6 % of the center frequency or even more dispersive over a narrower bandwidth.

Although in FIGS. 1, 3 and 4 contain the resonance elements slots and the waveguides are rectangular, e.g. B. Dipoles as resonance elements and circular, capacitively and / or inductively loaded ridge waveguides can be used.

Claims (1)

Claims: 1. In the course of a hollow line, designed as a bandpass or bandstop arrangement for very short electromagnetic waves with a waveguide section, in which in at least two cross-sectional planes correspondingly dimensioned spacing a discontinuity effective as a resonator is provided in the form of a resonance diaphragm or a dipole and the axes of the diaphragm openings or the dipoles are rotated against each other within their plane and the resonance frequency of these discontinuities belongs to the frequency range of the electromagnetic waves to be transmitted or blocked by the arrangement, which oscillate in a stable wave type of the lowest order, characterized by a so low cut-off wavelength of the waveguide section (1) having the discontinuities in comparison to the wavelength A of the electromagnetic waves to be transmitted or attenuated by the arrangement in the ahead of the input of this waveguide section going hollow pipe, that in connection with the appropriately selected, preferably about 60 ° amounting angle (a) between the axes of the slots (4, 5) or dipoles of two successive discontinuities and due to the small mutual distance of all discontinuities, based on the wavelength A, is significantly smaller than a quarter of this wavelength and is preferably an eighth of this wavelength, the energy transfer from one to the other discontinuity is effected exclusively by a decaying oscillation field type (Fig. 1). 2. Arrangement according to claim 1, characterized in that the resonance elements consist of correspondingly dimensioned waveguide sections (6, 7, 8) which are arranged at an angle to one another (F i g. 3). 3. Arrangement according to claim 2, characterized in that. that the waveguide sections (13, 14), which serve as resonance elements, are arranged rotated relative to one another (FIG. 4). 4. Arrangement according to claim 3, characterized in that. To form a dispersion line, a plurality of resonance elements are arranged at a distance from one another, approximately in cross-sectional planes of a waveguide and at an angle to one another. Documents considered: German Patent No. 755 343; U.S. Patent No. 2,541,375; Swiss Patent No. 298 283; "Radio Engineering Handbook," Keith Henney; 4th edition, 1950, pp. 699 to 701.