DE3506471A1 - Method for tuning a dielectric resonator - Google Patents

Abstract

The invention proposes the application of a metallic coating (2) on the top of dielectric resonators (1) in order to tune them, and that the surface which is covered by the coating (2) be changed for fine tuning. Using the method according to the invention, particularly low sensitivity of the tuned resonator (1) to temperature changes and vibration is achieved. A substrate (6, 8) which is coated with metal on one side or both sides can also be applied instead of a coating. <IMAGE>

Description

Method for tuning a dielectric resonator

The invention relates to a method for tuning a dielectric resonator. Resonators are used in microwave technology frequency-determining components, especially for filters and oscillators. Instead of the line components previously used as resonators, e.g. certain coaxial conductors, Waveguide or stripline designs have been increasing for a number of years dielectric resonators are used.

Dielectric resonators and their applications are i.a.

known from H. Abe, Y. Takayama, A. Higashisaka and H. Takamizawa, "A Highly Stabilized Low-Noise GaAsFET Integrated Oscillator with a Dielectric Resonator in the C Band, "IEEE Trans. Microwave Theory a. Tech., Vol.

MTT-26, pp. 156-162, March 1978 (Document 1) and W. Wersing and G. Wolfram, "Dielectric resonators and high dielectric substrates for microwave circuits, NTG-Fachberichte 1981, "Rundfunk-SatellitensystemeT ?, October 19-21, 1982, p. 244 to 251 (brochure 2). Such dielectric resonators are Body made of a dielectric with a high dielectric constant, i.e.

made of a dielectric ceramic. Due to the large difference between the dielectric constant of the reactor and that of its surroundings can vary Form standing electromagnetic waves in the resonator with appropriate excitation. The electric and magnetic fields of dielectric resonators are similar Configurations like those of cavity resonators.

The fields are highly concentrated within the dielectric resonator. Via the weaker external magnetic fields, resonators can be connected to one another or to be coupled to line sections. By influencing the clean magnetic or electric fields can dielectric resonators also with regard to their resonance frequency be matched.

In the method known from the aforementioned documents 1 and 2 For tuning the dielectric resonators, metallic tuning means are in the form provided by pins or plates that are attached to a bracket or to a housing cover are attached and with respect to their distance from the surface, namely the top of the dielectric resonator can be changed e.g. with an adjusting screw. These Tuning means do not touch the resonator, but are only inserted into the the field surrounding the resonator (stray field) immersed c. Such arrangements are shown in document 1, FIG. 2 and document 2, FIG. 8.

Voting according to the known procedure makes it necessary the tuning means very close (a few tenths of a millimeter to a few millimeters) bring the resonator and there during operation with high accuracy to keep. As a result, a high mechanical effort is necessary to fix the Voting means in the Proximity of the resonator, being sensitive to shock and vibration or the temperature range of the individual parts must be taken into account. The fine-tuning Adjusting screws makes it difficult to automate the tuning process.

Proceeding from this, the invention is based on the object of an improved Specify a method for tuning a dielectric resonator.

This object is achieved by a method according to claim 1. Advantageous refinements are given in the subclaims. In the difference the tuning means are not in the vicinity of the resonator, but arranged directly on the surface of the resonator. The voting process allows cost-effective, also automated coordination and enables production of microwave circuits with low sensitivity to mechanical and thermal influences. Alternative methods are given in claims 7 and 8.

Further advantages emerge from the following description of FIG Embodiments based on the drawing.

They show: FIG. 1 different forms of a metallic coating dielectric coated on top of a dielectric resonator, Fig. 2 Resonator with metal wings for fine tuning, Fig. 3a, b dielectric resonator with glued-on metal and 4a, metal-coated substrate.

Fig. 1 shows three dielectric resonators 1 with one in a first Process step vapor-deposited metallic coating 2. With the help of masks metallized surfaces of different shapes can be produced. Of course the metallization can also be done in other ways, e.g. by sticking a metal foil, e.g. made of aluminum or copper.

A fine adjustment to the desired resonance frequency can be done in a Measuring arrangement for the dielectric resonator 1 alone or after installation in a final microwave circuit done. In this second step, the area of the coating 2 changed.

If, in the first step, a surface that is too coarse is generally coated can, in the second step, simply by removing part of the coating 2 to be voted on. This can be done e.g. with the help of a laser beam with the Parts of the coating 2 can be removed by evaporation. This voting process can also be automated, with the laser beam controlled by the measuring device will.

Too small an area of the coating 2 can be achieved by applying a suitable metal, e.g. conductive silver.

The method according to the invention can be carried out inexpensively, since no special materials with low thermal expansion are required for tuning agents are.

The structural design of the housing of a microwave device with dielectric resonators 1 is simplified, since no tuning screws moving parts must be provided. The elimination of such temperature and vibration-sensitive parts is the frequency stability better or the frequency drifts less than with tuned according to known methods dielectric resonators 1.

It should be noted that by applying metal layers the resonator surface the losses in the resonator increase and thus the quality decreases. Therefore, the smallest possible fleas should be provided for the fine adjustment.

Fig. 2 shows a cylindrical dielectric resonator 1 with a Coating 2. Such a dielectric resonator 1 can be in different modes vibrate, the resonance frequency of the modes on the dimensions or the ratio depends on length to radius. A concentric hole in the resonator affects the field distribution of the basic mode is practically not, since the electrical one is in the center Field is nearly zero. Therefore, as shown in Fig. 2, a concentric threaded hole 3 can be made for receiving a screw 4, with which a metal wing 5 on top of the dielectric resonator 1 is attached. The metal wing 5 can be arranged so that it has the coating 2 partially covered. With this arrangement, the entire metallic surface can be changed within certain limits and thus the resonance frequency. The hole 3 in the dielectric resonator 1 hardly changes the basic mode, but changes the field distribution of the next higher mode. As a result, the frequency spacing can advantageously can be increased between these modes. Also, following this procedure can be very easy and be manufactured and coordinated inexpensively.

FIGS. 3a, 3b, 4a and 4b show a further possibility for voting dielectric resonators. Either a first piece of substrate 6 is used here, which is metallized on both sides, or a second substrate piece 8, which is on a Page is meallized. The first substrate piece 6 is metallized with one of the Pages, or the second substrate piece 8 with the non-metallized side on the Top of the dielectric resonator 1 placed. During the voting process the substrate piece 6, 8 is shifted so far - also over the edge of the dielectric Resonator 1 also -until the desired resonance frequency is reached. After that, will the substrate piece 6, 8 is fixed with an adhesive.

Figures 3a and 3b or 4a and 4b show different views of the dielectric resonator 1 with the glued-on substrate piece 6 or 8. In 3a and 4a also show a carrier substrate 7 on which dielectric Resonators 1 are usually arranged. The carrier substrate 7 has on the underside a continuous metallization 9 and on the top one according to the required Circuit structured metallization 9.1. The resonator 1 can be metallized on a Surface or on a non-metallized part of the upper side of the carrier substrate 7 be arranged.

The use of a Substrate piece 6 or 8 can be cheaper than the production of a coating 2 by vapor deposition of the dielectric resonator 1.

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Claims (8)

Claims 1. A method for tuning a dielectric resonator, characterized in that, in a first step, the top of the dielectric Resonator at least partially provided with a metallic coating (2) and in a second step fine adjustment by changing the Coating (2) covered surface of the dielectric resonator (1) takes place. 2. The method according to claim 1, characterized in that the coating t2) is produced by the deposition of metal from the vapor phase. 3. The method according to claim 1, characterized in that the coating takes place by gluing a metal foil. 4. The method according to any one of claims 1 to 3, characterized in that that for fine adjustment a part of the coating (2) is removed by means of a laser beam will. 5. The method according to any one of claims 1 to 3, characterized in, a suitable material for fine adjustment, e.g. conductive silver, in addition to the coating (2) applied to the surface of the dielectric resonator (1) and optionally is partially removed again. 6. The method according to any one of claims 1 to 3, characterized in that that the fine adjustment takes place with the help of a metal wing (5), which with a screw (4) in a concentric, threaded hole (3) in the dielectric Resonator (1) is attached, wherein the metal wing (5) partly the coated surface and partly the uncoated surface of the top of the dielectric resonator (1) covered. 7. Method of tuning a dielectric resonator, thereby characterized in that, in the first step, a piece of substrate that is metallized on at least one side (6) with a metallized side on top of the dielectric resonator (1) is placed and in the second step so far - also over the edge of the dielectric Resonator (1) also - is shifted until the desired resonance frequency is reached and then the substrate piece (6) is fixed with an adhesive. 8. Method of tuning a dielectric resonator, thereby characterized in that the first step is a piece of substrate metalized on one side (8) with the non-metallized side on top of the dielectric resonator (1) is placed and in the second step so far - also over the edge of the dielectric Resonator (1) also - is shifted until the desired resonance frequency is reached and then the substrate piece (6) is fixed with an adhesive.