DE1010595B - Arrangement for coupling a coaxial power line to a rectangular waveguide to excite the H-wave - Google Patents

Description

GERMAN

In. With the centimeter wave technology, it is very often necessary to _{excite an H 10} wave in a rectangular tube through a coaxial line. A perfect match in a larger frequency range is associated with difficulties, since the transformation from the low-ohmic impedance of the coaxial line to the relatively high-ohmic impedance of the waveguide must be very large (about 1 to 8). Known couplings use a combination of reactances (e.g. series capacitance and parallel inductance, see FIG. 1), which is known to be very frequency-dependent with a high transformation ratio. Another known solution to the problem consists in coupling in as shown in FIG. 2. In this case, the exciting antenna is not located in the middle of the broad side of the waveguide, but in the vicinity of the side walls. One makes use of the fact that the voltage-current ratio at this location of the waveguide is smaller, ie the waveguide itself contributes to the transformation. The then still required transformation by dummy elements is reduced as a result. However, the asymmetrical excitation has a disadvantageous effect as a result of the generation of higher excitation states which are not capable of propagation in the waveguide. The resulting reactive components have to be compensated again, which makes the adaptation more frequency-dependent. In FIGS. 1 and 2, α and b denote the edge lengths of the waveguide.

A coupling arrangement has also become known, in which the feeding coaxial line splits into two before entering the rectangular waveguide Branched coaxial lines with double wave resistance, the inner conductors then at a distance of a third of the long side of the waveguide cross-section enter this. This arrangement permits Although a symmetrical excitation of the waveguide, it has different construction-related factors Disadvantages which make their practical application appear to be unsuitable. First brings the intended branch point increases the cost of manufacture; also occur Each branch point has reactive components that are compensated for by special measures have to; after all, the two branched lines must have twice the characteristic impedance have like the original coaxial line, so that you have to resort to very thin inner conductors that require special mechanical support which is disadvantageous in itself.

The invention has an arrangement for coupling a coaxial power line to a rectangular hollow conductor to the subject, which also has a symmetrical arrangement for coupling a

coaxial power line to one

Rectangular waveguide for excitation

the H ₁₀ -WeIIe

Applicant:

Pintsch-Electro GmbH,
Constance (Lake Constance), Bücklestr. 3

Dr.-Ing. Hermann Ritzl, Munich,
has been named as the inventor

Irish excitation of the H ₁₀ wave is achieved, but all the above-mentioned deficiencies are avoided. The essence of this arrangement, in which to achieve a favorable adaptation, the feed is also in the

he proximity of the opposing narrow boundary surfaces takes place, consists in that the coaxial line opposite to the narrow boundary surfaces parallel plane of symmetry laterally offset to one of the wide boundary surfaces of the Waveguide is brought up, its inner conductor entering through an opening in the waveguide and there causes a first coupling, then a line of such a line running transversely to the plane of symmetry Length and phase velocity form that a phase inversion takes place in it, and finally approximately symmetrical for the first coupling point brought up to the wide boundary surface a second time and connected to her there.

An example of an embodiment of this coupling arrangement is shown in FIG. 3. The outer conductor the feeding coaxial line 9 ends laterally offset on the waveguide wall, during the Inner conductor enters through an opening in the waveguide, where it merges into a cylinder 1 and through this causes a first coupling. A web 3 connects to the cylinder 1, which makes the connection to a second cylinder 2 lying symmetrically to the cylinder 1. This is at 7 with the Waveguide wall connected. The web 3 forms together with the waveguide wall a line of such a length and phase velocity that a phase reversal takes place in it. This flows into the both cylinders 1 and 2 each have a current in the same direction, so that a magnetic field is created which

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is already very similar to the known, undisturbed H _{10 -FeId.} In order to achieve the phase inversion mentioned in the exemplary embodiment according to FIG. 3, the length of the line located in the waveguide between planes 4 and 5 must be approximately half a wavelength of the mean operating wavelength. In this case, when the operating wavelength changes, the sum of the two currents in the two cylinders remains approximately constant over a large area.

There is also a screw 6 is provided, with the help of which the electrical length of the line between the Cylinders 1 and 2 can also be adjusted, with an electrical coupling between Coaxial line and hollow line occurs. With the help of this screw you can adjust the middle frequency range move and adjust the adaptation of the transition. The line itself is used to produce dummy components to avoid, in the best case dimensioned so that the wave resistance inside of the waveguide comes as close as possible to the respective coupled effective resistance at every point. Provided if you accept a slight loss of bandwidth, it is sufficient to reduce this wave resistance make equal to the wave resistance of the connection line. Because in this case the line is too high resistance is, two longitudinal inductances occur, which are compensated by the screw 6 (transverse capacitance) can.

As can be seen from Fig. 3, the line is not fully coupled to the waveguide, since the two current-carrying cylinders do not occupy the entire height of the waveguide. This creates on the On the waveguide side of the transition, a leakage inductance in series with the coupled resistor. This inductance together with the short-circuited waveguide section 8 as a capacitive parallel resistor contributes again to the transformation. It follows that in the example shown, the length this piece must be between a quarter and a half waveguide wavelength. Are the Cylinder half as high as the height of the waveguide, the experimental length 1 in FIG. 3 results about three eighths of the waveguide wavelength for the mean operating wavelength.

Claims (2)

Patent claims: 1. Arrangement for coupling a coaxial power line to a rectangular waveguide to excite the H ₁₀ -WeIIe, in which the feed in the to achieve a favorable adaptation ■ The proximity of the opposing narrow boundary surfaces takes place, characterized in that that the coaxial line opposite the plane of symmetry parallel to the narrow boundary surfaces laterally offset to one of the broad boundary surfaces of the waveguide is, its inner conductor entering through an opening in the waveguide and there a first coupling then causes a line running transversely to the plane of symmetry of such a length and Phase velocity forms that a phase inversion takes place in it, and finally approximately symmetrical at the first coupling point brought up to the wide boundary surface a second time and is connected to it there. 2. Arrangement according to claim 1, characterized in that in the vicinity of the transverse to the plane of symmetry running part of the coupling inner conductor a capacitively acting adjustment screw is arranged. Considered publications:
U.S. Patent No. 2,588,103;
"Proceedings of the IRE, 1947, Vol. 35, pp. 921 and 922. 1 sheet of drawings © 709 549/292 6.57