EP0961340A1 - Method for tuning the resonance frequency of a dielectric resonator - Google Patents

Abstract

The tuning method uses a stripline tuning line (3) which is open at either end, coupled to the dielectric resonator (1) applied to a substrate in a region of the line where the current is a minimum, with one or more line sections (4,5) removed from at least one end of the tuning line for adjusting the resonance frequency of the dielectric resonator.

Description

State of the art

The present invention relates to a method for Tuning the resonant frequency of a dielectric Resonators, which on a substrate next to an as Stripline running signal line is arranged, with at least one of the dielectric resonators Influencing resonance frequency, as a strip line implemented tuning line that runs empty at both ends is coupled.

For the generation of vibrations with the help of an oscillator or filtering out a narrow frequency range a resonator vibrating at the desired frequency needed. It is in order to get the best electrical To achieve the properties of the oscillator or filter, the highest possible quality of the resonator is required. A dielectric resonators have a high resonator quality. A dielectric resonator usually consists of one round disc made of a dielectric material that next to a planar signal line, through which the to be filtered Signal is transmitted on the substrate of the planar Line is glued on. Such dielectric resonators are e.g. from [1] D.Kjfez, P.Guillon: Dielectric Resonators, Artech House, Dedham, MA, 1986, pages 509-510 and from [2] K.V. Buer, El-B. El-Sharawy: A Novel Technique for Tuning Dielectric Resonators, IEEE Transactions on Microwave Theory and Technique, Vol. 43, No. 1, January 1995, pages 36-41 known.

A dielectric resonator usually has after Installation in a circuit due to material fluctuations and manufacturing tolerances are not exactly what you want Resonance frequency. That is why a subsequent vote the resonance frequency of the dielectric resonator required. According to the publication [1], this is done Vote on one in the lid of a dielectric Resonator housing, integrated tuning screw, with this tuning screw the distance between the Cover the housing and the dielectric resonator is adjustable. The disadvantage is that both Housing as well as the tuning screw due to thermal conditions Expansion fluctuations are subject, which leads to a unwanted drift of the resonance frequency comes. This Disadvantage is with the tuning device according to the Circumvented publication [2] in that on a Tuning screw is completely dispensed with and instead one planar tuning line with the dielectric resonator is coupled. This voting line acts like one Resonator admittance connected in parallel. The admittance and so the resonance frequency depend on the length of the line and their position relative to the dielectric resonator. over the length of the line and its location with respect to the dielectric resonator can be so Adjust resonance frequency. For the one to be tuned Resonance frequency must now be the tuning line of a whole certain length and with a very specific range of Line near the dielectric resonator on the Substrate are applied. If after that Resonance frequency still has an offset, disclosed the publication [2] no measures, like this offset can still be eliminated with simple means.

The invention is therefore based on the object Specify the procedure of the type mentioned at the beginning, with the a very exact coordination of the Resonance frequency of a dielectric resonator is feasible.

Advantages of the invention

The above task is carried out with the characteristics of Claim 1 solved in that the tuning line so is coupled to the dielectric resonator that they with an area where the line has a minimum current, runs next to the dielectric resonator and that at one or both ends of the tuning line one or more Line pieces of such a length are removed that the Resonance frequency takes a desired value. With this The procedure allows a very large tuning range for the Realize the resonance frequency of the dielectric resonator.

Advantageous further developments of the invention Procedures emerge from the subclaims. After that leaves the tuning range continues to increase by the at least one voting line for coupling with a round one dielectric resonator over a length less than half the wavelength on the tuning line is in one Arc around the resonator, following its round contour, to be led. This is a very close coupling of the Tuning line reached with the dielectric resonator, which changes the tuning range for the resonance frequency expanded.

It is useful that at least one first tuning line for a coarse tuning of the resonance frequency closely with the dielectric resonator is coupled and that at least a second tuning line for fine tuning the Resonance frequency at a greater distance than the first Tuning line coupled to the dielectric resonator becomes. The line length can be very fine with a laser change dosed so that a very exact adjustment of the Resonance frequency is possible. Another method to change the length of the tuning line is that several short ones at both ends of the tuning line Line pieces are strung together via bond connections and that for resonance frequency tuning the bond connections interrupted by one or more pipe sections.

Description of exemplary embodiments

Figur 1 einen dielektrischen Resonator mit einer Abstimmlmeitung,

Figur 2 einen dielektrischen Resonator mit zwei Abstimmleitungen,

Figur 3 einen dielektrischen Resonator mit zwei Abstimmleitungen zur Grobabstimmung und einer Abstimmleitung zur Feinabstimmung der Resonanzfrequenz,

Figur 4 einen dielektrischen Resonator mit einer Abstimmleitung zur Grobabstimmung und einer Abstimmleitung zur Feinabstimmung der Resonanzfrequenz und

Figur 5 die Änderung der Resonanzfrequenz in Abhängigkeit von der Länge der Abstimmleitung.

The invention is explained in more detail below with the aid of several exemplary embodiments shown in the drawing. Show it:

FIG. 1 shows a dielectric resonator with a tuning line,

FIG. 2 shows a dielectric resonator with two tuning lines,

FIG. 3 shows a dielectric resonator with two tuning lines for coarse tuning and one tuning line for fine tuning the resonance frequency,

Figure 4 shows a dielectric resonator with a tuning line for coarse tuning and a tuning line for fine tuning the resonance frequency and

Figure 5 shows the change in resonance frequency depending on the length of the tuning line.

In Figure 1 is the top view of a dielectric Resonators 1 shown with a signal line 2nd is coupled to a specific one via the signal line 2 filter out the transmitted frequency range. The dielectric Resonator 1 is in the form of a round disk, for example on the substrate (lying in the plane of the drawing) Signal line 2 arranged directly next to this. Depending on Distance of the dielectric resonator 1 from the Signal line 2 exists between the two more or less strong coupling. It becomes the frequency on the Filtered out signal line 2, on which the dielectric Resonator 1 resonates. The resonance frequency of the dielectric resonator is on that frequency to coordinate which one should be filtered out.

Can between the dielectric resonator and the substrate a dielectric spacer can be inserted. Depending on Height of the spacer, i.e. depending on the distance of the dielectric resonator against the substrate between the dielectric resonator and those on the Coupling lines extending more or a substrate less strong coupling.

To match the resonance frequency as precisely as possible The dielectric resonator 1 one designed as a strip line at both ends idle tuning line 3 coupled. The voting line 3 is guided past the dielectric resonator 1 in such a way that an area of the tuning line 3 in which the line Current minimum has the closest to the dielectric resonator 1 lies. Under these circumstances, the voting line has 3 almost no influence on the resonance frequency of the dielectric resonator 1. If the tuning line 3 shortened at their ends, the location of the Current minimums and the tuning line 3 begins as one dielectric resonator 1 admittance connected in parallel act which the resonance frequency of the dielectric Resonators 1 shifts.

In the embodiment shown in Figure 1 are the two ends of the tuning line 3 in the form of several briefly lined up via bond connections Line pieces 4 and 5 executed. The line shortening takes place in that the bond connections at the ends or several short line sections 4 and 5 interrupted become.

A less complex shortening of the tuning line 3 can be made with a laser with the arbitrarily short one Pieces of the line can be removed. The Line shortening using a laser therefore leaves a lot fine tuning of the resonance frequency too.

5 shows the dependence of the Resonance frequency change Δf from the length of the tuning line shown. In the initial state, the tuning line has a length of 2λ, so that the dielectric resonator 1 in a current minimum of the tuning line 3 is coupled and therefore the tuning line does not change the resonance frequency influenced. Now, at both ends of the tuning line 3 successively removed pipe sections, so increases Resonance frequency on until the tuning line 3 has a length of Has 1.5 λ. It can be seen from FIG. 5 that this Place a resonance pole.

If the tuning line 3 and the length of 1.5 λ further shortened, the resonance frequency drops very sharply, then rises again and reaches at Cable length λ the same value as for the cable length 2 λ. The method described thus opens up very wide tuning range.

A further increase in the tuning range can be by realizing that the coupling between the Tuning line 3 and the dielectric resonator 1 is reinforced. This can be done as in FIG. 1 emerges, thereby achieve that the tuning line 3 over a length that is less than half the wavelength on the Is tuning line 3, in an arc around the dielectric Resonator 1, the round contour of which is guided.

Is the reachable with a voting line 3 Tuning range of the resonance frequency is not sufficient, as shown in FIG. 2, also a plurality of tuning lines 6 and 7 are coupled to the dielectric resonator 1. Each of these tuning lines 6, 7 covers one Tuning range of the resonance frequency.

In the embodiment in Figure 3 are two Tuning lines 8 and 9 very closely with the dielectric Resonator 1 coupled. Another tuning line 10 is because of their greater distance from the dielectric Resonator 1 coupled with it much looser. With the tight coupled tuning lines 8 and 9 is a rough one Tuning the resonance frequency feasible, and with the weakly coupled tuning line 10 can fine tune the resonance frequency.

Figure 4 shows an embodiment in which a tight coupled tuning line 11 for coarse tuning and one weakly coupled tuning line 12 for fine tuning the resonance frequency are arranged one behind the other, so that the tightly coupled tuning line 11 between the weak coupled tuning line 12 and the dielectric Resonator 1 lies.

The number, location and coupling strength of the tuning lines is not to those shown in Figures 1 to 4 Embodiments limited.

Claims (5)

Method for tuning the resonance frequency of a dielectric resonator that is on a substrate next to a signal line designed as a strip line is arranged, with the dielectric resonator at least one influencing its resonance frequency as Stripline executed, idling at both ends Tuning line is coupled, characterized in that the tuning line (3, 6, ..., 12) with the dielectric Resonator (1) is coupled to an area in which the line has a current minimum next to dielectric resonator (1), and that at one or both ends of the tuning line (3, 6, ..., 12) one or several pipe sections (4, 5) of such a length are removed be that the resonant frequency is a desired value assumes. A method according to claim 1, characterized in that the at least one voting line (3, 6, ..., 12) for Coupling with a round dielectric resonator (1) a length that is less than half the wavelength on the Tuning line is, in an arc around the resonator (1), following its round contour. A method according to claim 1 or 2, characterized in that that at least a first tuning line (8, 9, 11) for a Coarse tuning of the resonance frequency closely with that dielectric resonator (1) is coupled and that at least one second tuning line (10, 12) for one Fine-tune the resonance frequency in a larger one Distance as the first tuning line with the dielectric Resonator (1) is coupled. A method according to claim 1, characterized in that to tune the resonance frequency the line section (s) from the at least one voting line (3, 6, ..., 12) be removed by means of a laser. A method according to claim 1, characterized in that two ends of the at least one tuning line (3) several short line sections (4, 5) via bond connections are strung together and that for Resonance frequency tuning the bond connections from one or several line sections (4, 5) are interrupted.

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