CS197237B2 - Coaxial double resonator for the hiogh-frequency filtering and device for ultrashort waves - Google Patents

Description

BACKGROUND OF THE INVENTION The present invention relates to a coaxial double high-frequency filtering resonator in a very short wave device in which two equally coupled quarter-wave resonators are provided with parallel longitudinal axes and each resonator has a variable length internal vein and a single high frequency magnetic coupling loop connection. of the individual resonators is made of a tube open at both ends, the end of the tube facing the connection is terminated by a closure plate, and that there is exclusively one clamp connection between the closure plate and the inner vein of the resonator and the two resonators are next to each other; It has a double coupling loop with an axis directed perpendicular to and rotatable about the resonator, with one part of the double coupling loop located in the interior of each resonator. Such a coaxial double resonator is particularly suitable for use in filter circuits of radiotelephone equipment and systems.

With the increase in the number of radiotelephone equipment, problems caused by mutual interference of equipment are increasingly coming to the fore. These problems arise mainly from the mutual interference and intermodulation effects occurring due to the small distance between the device antennas and the increasing use of the available frequency band.

One of the most effective methods of reducing interference of this kind is the best possible high-frequency filtering of disturbed devices. The ideal high-frequency filter requires that its damping in the pass-through band be as low as possible, but outside the band as large as possible.

In high-frequency filtering for very short wave devices, quarter wave resonators have a proven track record and have an idle quality factor of more than 3000. These resonators also have the most advantageous properties. However, the use of resonators of the known embodiment raises problems which make their use cumbersome and impossible to solve individual tasks. Furthermore, there were serious technological problems in the manufacture of these resonators.

The classically constructed quarter-wave resonator was a coaxial system that generally had an outer conductor made of copper with a circular cross-section and another variable length conductor positioned within the outer conductor and with an axis parallel to the outer conductor axis. The outer and inner conductors were terminated by end plates located at the end of the reso197237. Binding at the resonator was effected by means of a fixed standing coupling loop located on the end plate and coupled magnetically to the resonator space.

There are numerous problems when using a filter formed by such a resonator. On a given band (usually + 10% of the relative bandwidth corresponding to one of the radiotelephony bands and related to the base frequency), the resonator frequency may be affected by changing the length of the inner conductor. Due to the firmly located coupling loop, the properties of the resonator within the upper band varied significantly. For example, the resonator quality factor under load at both extreme bandwidths could also have a 1: 2 ratio. Because resonator selectivity is determined by the load quality factor, the worst problem was to a large extent detrimental to the usability of the resonator. already for other frequencies and it was not possible to adjust them.

In the production of upper, classically designed, resonators, the mechanical connection between the closure plate and the inner conductor was achieved by welding or brazing. This operation was followed by post-treatment to eliminate stresses in order to center both tubes. Welding and brazing as well as subsequent stress relief were related to the cross-section of the internal resonator conductor exposed to the highest stress, a circumstance which, besides being a very expensive technology, also adversely affected the mechanical stability of the resonator. The assembled system of the closing plate and the inner conductor was connected to the outer conductor by a flange connection just in the cross section corresponding to the sales maximum of the resonate. This connection had the extremely disadvantageous property that the quality factor of the resonate was greatly influenced by the tensioning force used for the flange connection. Furthermore, they increased due to the upper coupling at the current maximum of the current path resonator, causing considerable losses.

Against the classic classic resonators, another known resonator, a double, significant progress. The use of double resonators is considered necessary, since the transmission properties of the double resonator with bandpass filter characteristics have proven to be more advantageous for performing interference suppression tasks.

The biggest disadvantage of the coaxial double resonator mentioned here is that the coupling between permeability attenuation and resonators can be set to a predetermined frequency only at the factory. There is no possibility of continuously adjusting the coupling between the high-frequency power line and the directors. This feature of the double resonator greatly limits its use. The transmission properties of an already set resonator vary within the band. The use of a double resonator basically allows for the possibility of an input coupling for individual resonators as well as a change in coupling between the resonators, so that any throughput curve with two-circuit bandpass filters can be set. A variation in the permeability curve of the resonators over a wide range is required, since the frequency of faults at the place of use of the filters, as well as their intensity and distribution, may be extremely different. For example, in the case of a strong disturbance signal, it may be justified, or necessary, to cause a significant increase in throughput attenuation, in which the steepness of the flanks of the resonator characteristic increases to a large extent.

If a filter with a characteristic that cannot be realized by double resonators is needed to suppress the disturbances to be filtered, it may prove expedient to construct re-conductors from which band filters of more than two circuits can be constructed.

Continuous input and output coupling adjustments are also necessary because the input impedance of the antennas connected generally to the resonator is not always exactly ohmic, and by setting the coupling loop to the associated antenna complex impedance value, a good ratio of standing coils is achievable.

Furthermore, the connection of the input coupling loop and the output coupling loop with each standard connection is very problematic. This problem is that one end of the input coupling loop or the output coupling loop must be connected to the inner conductor of the standard connection, while the other end must be well grounded. This problem is made even more difficult by the fact that the plane of the coupling loops must be adjustable to allow exact alignment. In the known solutions, the wire of the coupling loop is used to change the size of the input bond and the output bond, resulting in rapid fatigue or breaking of the wire ends.

These drawbacks are eliminated in the coaxial double resonator according to the invention in that the connections are rotatable on the closing plate by means of externally releasable terminal connections.

The double resonator according to the invention not only does not present the above mentioned problems, but it is suitable for setting various transfer characteristics and there are no technological problems and no adverse side effects caused by the production, for example welding, during its production.

The invention has created a structure in which both ends of the magnetic coupling loop are connected to a standard connection. The plane of this loop can be easily changed by turning the standard connection.

By means of the corresponding rotation of the connections as well as the double coupling loops, the transmission properties of the double resonator libo197237 can be freely adjusted over a wide range.

An example of a coaxial double resonator according to the invention is shown in the attached drawing, in which Fig. 1 is a sectional view of a resonator; Fig. 2 is a side view of a resonator with a thermostat for temperature compensation mounted;

In Fig. 1, the double resonator is shown in longitudinal section. The double resonator consists of two identical quarter-wave resonators, the outer conduit of which is a tube 1 open at both ends. An inner bed 14 is formed at one end of the pipe 1. In the bed 14 there is a closing plate 3 shorting the end of the pipe 1. In the center of the closing plate 3 is a bore into which it is inserted by screw connection of the inner vein 2 of the resonator. Thereby the closure plate 3 closes the tube 1 forming the outer conductor of the resonator and the inner vein 2. The inner vein 2 is a rod-shaped rod, the length of which can be varied within given limits by rotating the piston axis. Even in the extreme position of the piston, the length of the inner vein does not equal the length of the tube 1, so that the end of the inner vein 2 opposite to the closing plate 3 is always terminated by a fraction.

In the closure plate 3, another bore is provided extending into the interior space of the resonator, into which the high-frequency connection 6 with a coupling loop 7 soldered to its end is introduced. The connection G is fixed together with the coupling loop 7 by means of a clamp connection from a releasable exterior. Thus, in the relaxed state, it is possible to rotate the connection 7 at any angle.

The closing plates 3 are supported in the tubes 14 of the tube 1 in such a way that their outer planes extend over the flanges of the tube 1. Therefore, the two resonators are connected to each other by using two end plates 5 formed in the same manner, preferably by casting. depressions are provided to determine the position of the tubes 1 and adapted to their outer plane. End plates S adapted to both ends of the pipes 1 are pressed together by threaded bolts 13 inserted in a bore arranged near the edges. The tensioning force of the threaded bolts 13 pushes the closing plates 3 into bearings 14 generally conical. In bed 14, a very stable electrical contact of good quality is formed between the pipe 1 and the edge of the closing plate 3 at the edge. This solution ensures electrical contact between the tube 1 and the closure plate 3 without increasing the surface current paths of the resonator.

Coupling between the two resonators is effected by a double coupling loop 8, wherein the double coupling loop 8 has an axis directed perpendicular to the axis of the resonator. A double resonant loop 8 is fixed between the two tubes 1 in the rotating disc 12. It is ensured that the spacing of the two tubes 1 is minimized. The spacing between the two tubes 1 is determined by a dimension adapted to the distance of the deflected disc springs 13 provided on both sides of the disc 12. Drillings are provided on the disc housing 12 in which the disc 12 can be rotated externally using a corresponding tool. the coupling between resonators changed.

In Fig. 2, the double resonator is shown in a top view. Here, the relative position of the coupling loops as well as the positioning of the thermostats for temperature adaptation of the resonators can be well observed.

The thermostat 9 is preferably made of a binary strip located in a cylindrical vessel along a cylindrical shell with an axis parallel to the axis of the resonators. One end of the bimetallic strip, preferably the top, is fixed, the bottom end being connected via the end plate 5 and the closing plate 3 to the resonator shaft projecting into the interior space of the resonator. Due to temperature changes, the shaft 10 is rotated. At the end of the shaft 10, a deformation element 11, for example a metal plate, is mounted.

The outer surface of the end plate 5 of the double resonator simultaneously forms the front plate of the resonators, since all connecting and adjusting elements are located here. To facilitate the adjustment of the double resonator, an appropriately described writing plate may also be placed on the front plate. Scales indicating the actual plane of the connections 6 as well as an indication showing the angular adjustment of the disc 12 can then be formed thereon.

The coaxial double resonators of the invention operate as follows:

A coaxial quarter wave cavity is formed between the tube 1, shorted by the closing plug 3 and the inner vein 2, in the form of a piston, whose current peak is, as is known, near the shorted end but whose voltage peak is close to the fractional end. The resonant frequency of the resonator can be changed by changing the length of the inner vein 2 by about + 10 ° / o.

In addition to mechanical dimensions, the no-load quality factor determines the smoothness of the surface and the conductivity of the inner surface of the cavity. To increase the quality factor, tubes 1 with a polished and silver-plated inner surface as well as inner veins 2 with a similar surface are preferably used. The resonator material may be copper or brass.

The coupling loop is assembled with a normal high-frequency connection. The loop plane is located near the shorted end of the resonator, located at the maximum magnetic field. The coupling between the coupling loop 7 and the resonator can be influenced by the rotation of the coupling loop 7, since it is known that only that component of the plane of the coupling loop 7 that is perpendicular to the field lines is effective.

Since the double coupling loop 8 connecting the two resonators is located near the maximum of the magnetic fields of the resonators, this also affects the magnetic field of the resonators. By rotating the loop plane, the constraint can also be varied between 0 and the highest value. The surface of the binding loops is selected in a manner corresponding to the maximum attainable binding.

The axis of the double coupling loop 8 as well as the axis of both coupling loops 7 lie in a plane running along the axis of the resonator. Thermostats 9 are placed along diameters perpendicular to this plane. Thermostat shaft 9 rotates as the temperature changes. A magnetic force field is deformed by a measure of the position of the field deformation element 11 mounted at the end of the shaft 10, whereby the resonator changes its resonant frequency.

If the plane of the deformation element 11 is directed tangentially to the magnetic field lines, no tuning occurs. Since the degree of such tuning thus changes sinusoidally with the angular rotation of the shaft 10, linear control is obtained practically when the rotation value is maintained practically within an angle of 45 ° + 15 °. If the direction of rotation of the thermostat shaft 9 is selected such that the rotation caused by the temperature increase increases the resonant frequency, then the frequency reduction caused by the linear thermal expansion is equalized. By correspondingly selecting the surface of the deformation element 11, the frequency stability of the resonator can be improved by about one order over the entire band.

The tuning of the double resonator is accomplished by connecting the resonator connections 6 to the high frequency circuit to be filtered and then adjusting the desired throughput rate by the apparatus, for example, a frequency spreader, or by some other method by varying the coupling between input coupling, resonant frequency and resonators. With the double resonator according to the invention, virtually all transmittance curves required and related to the two-circuit bandpass filters can be adjusted.

Two double resonators can be connected as a four-circuit bandpass filter by simple serial connection, where a permeability curve can be achieved for better selectivity. The adjustment is made in terms of the upper terminals.

The double resonator of the present invention can be used in a variety of ways to reduce interference by mutual modulation, interference of ultra-short wave devices, to suppress noise spectrum and emit higher harmonic waves to transmitters, to couple multiple transmitters to a single common antenna and to perform other filtering tasks.

The simple design of the double resonator and the possibility of changing all the parameters on a single face plate make the device very easy to operate. The fact that the position of the tuning elements on the scale can be monitored simultaneously with the tuning can be observed on the scale of the double resonator front plate.

Claims (1)

Subject A coaxial double high-frequency filtering resonator in a very short-wave device in which two equally coupled quarter-wave resonators with parallel longitudinal axes are provided and each resonator has a variable-length inner vein and a single high-frequency magnetic coupling loop connection made of a pipe open at both ends, the end of the pipe facing the connection is terminated by a closing plate and that between the closing plate YNELEZU and the inner vein of the resonator is exclusively one clamp connection and the two resonators are placed side by side, further that the double resonator has a double coupling loop with an axis directed perpendicular to and rotatable about the resonator, each part of the double coupling loop being located in the interior Individual resonators, characterized in that the connections (6) are fixed to the closure plate (3) in a rotatable manner by means of externally releasable terminal connections.