DE3906286A1 - Ceramic microwave filter having aperture-coupled ceramic resonators with steepened resonance curve - Google Patents

Abstract

A ceramic microwave filter (1) having short-circuiting capacitors C1, C2 for increasing edge steepness. The short-circuiting capacitors C1 and C2 are constructionally integrated into the microwave filter (1). <IMAGE>

Description

The present invention relates to a microwave filter, such as it is specified in the preamble of claim 1.

A dielectric microwave is known from EP-A-02 08 424 Filters with 1/4 wavelength coaxial resonators known. This Filter consists of a number of ceramic individual resonators, which are coupled to each other via an electromagnetic field. Each of these individual resonators comprises a tubular one dielectric body made of high-frequency-compatible ceramic. These bodies have at least one flat surface in which the coupling aperture is located. The ceramic resonator bodies are in particular on their outer surface the outer surface and on the inner surface of the Bore of the pipe metallized electrically conductive. Which he Aperture opening is a recess in the Metalli sation. So that two individual resonators directly next to each other can be arranged adjacent, they already have flat surface mentioned above. In this flat surface the coupling aperture is positioned. Among other things, the Size of the coupling through the area size of the aperture opening selectable.

Further details on such a known ceramic filter can be found in the abovementioned EP-A-02 08 424, in particular in FIG. 7. In view of the description available to those skilled in the art from this publication, no further explanations are required regarding the structure and mode of operation of such a known ceramic microwave filter with aperture-coupled individual resonators.

The object of the present invention is to provide such a micro  wave filter of the above type to specify a ver steepened, especially on the one ver has steeper resonance curve. It is the job of present invention, a technologically particularly favorable embodiment of such a filter to be realized with to specify a distributed resonance curve.

These tasks are done with a microwave filter solved according to the features of claim 1 and further refinements and developments of the invention emerge from the subclaims.

It has long been known that for capacitor Coil filter with concentrated components one-sided Edge distribution of the resonance curve by capacitive or inductive bridges between the individual resonators circles can be reached.

Fig. 1 shows a circuit diagram of such a conventional bridged filter. Due to the bridging capacitors C 1 and C 2 , such a filter has such a resonator or transmission curve, which optionally has a greater slope on one side. This is advantageous for message transmission in a frequency channel in which the transmission in one direction is immediately adjacent in frequency to the frequency range for the opposite transmission direction, as is possible, for example, for mobile radio.

It was found that the principle of bridging also for an aperture-coupled ceramic microwave filter leads to a steepening of the resonance curve. This was surprised. The relevant specialist was aware that that with such an aperture-coupled filter inevitably existing inductive coupling such Behavior is not expected, but this is nevertheless kicked. This is apparently due to the fact that the Aperture coupling with such filters is negative Represents inductance.  

FIG. 2 shows the known filter according to FIG. 7 of the above-mentioned publication.

FIG. 3 shows a bridged filter which substantially improves the state of the art in accordance with the invention and its structural design in accordance with a development of the invention. This filter also has to Fig. 3 improved over the prior art capacitive coupling.

The filter 1 of FIG. 3 is a filter consisting of four individual resonators 2 to 5. Each of the individual resonators consists of a tubular body made of high-frequency ceramic, which has the highest possible dielectric constant ε up to about 100 with the lowest possible high-frequency losses (smaller tg δ ). With this high dielectric constant, the filter can be reduced by the corresponding factor compared to an air resonator filter.

The tubular body 11 preferably has the shape of a parallelepiped, for example also a cuboid, so that it has at least one flat surface 12 . The individual resonator 2 lies against the individual resonator 3 with this surface 12 . Correspondingly, the individual resonators 3 and 4 as well as 4 and 5 lie against each other with such flat surfaces.

The respective tubular body 11 is metallized on the outer surface 13 and optionally also on its bottom surface 14 electrically conductive. Corresponding metallization is provided on the inner surface 15 of the tubular body 11 .

With 21 electrically conductive pins, in particular made of metal, are designated. These protrude according to the given input or output coupling, each with a correspondingly predetermined length l ₃, l ₄ into the bore 16 of the respective tubular body 11 . With 22 is a sleeve-shaped part made of a dielectric, which fills the sleeve-shaped space between the pin 21 and the inner wall of the tubular body 11 provided with the metallization 15 .

As a dielectric, high-frequency, low-loss materials are considered, for which even a smaller dielectric constant is sufficient. For example, styrene commonly used for the sleeve-shaped part for capacitors can be provided. The capacitance C 3 of the input coupling is given by the capacitance between the pin 21 and the metallization 15 and can be adjusted accordingly. In particular, a plastic which is filled, preferably with ceramic powder, of the material of the tubular body 11 is used as the material for this sleeve 22 .

With 17 , a recess in the outer metallization 13 of the tubular body 11 , namely on the flat upper surface 12 is referred to. This aperture 17 serves the magnetic coupling between the two adjacent single resonators 2 and 3 .

The features of the further individual resonators 3 , 4 and 5, which are not discussed further below, are provided with the reference symbols already explained above and correspond to one another therein.

Reference number 121 denotes a further pin of filter 1 , which is preferably formed in the same way and protrudes through a predetermined length l ₁ into bore 16 of individual resonator 3 . Between this pin 121 and the metallization 15 provided with the inner wall of the bore 16 is again a sleeve 22 made of dielectric material. About this dielectric material, the pin 121 and the metallization 15 form the bridging capacitor C 1 of the equivalent circuit diagram of FIG. 1. With 23 , a conductive connection between the pins 21 and 121 is designated.

The conductive connection 23 can be a wire soldered or welded to the pins 21 and 121 . The conductive Ver connection 23 can also be part of a printed circuit board, which would be seen in FIG. 3 in a side view and the corresponding conductor track is conductively connected to the pins 21 and 121 .

Fig. 4 shows a plan view a detail of such a printed wiring board 123rd

In addition to its known features, the individual resonator 4 also has a pin 121 which protrudes into the bore 16 of the individual resonator 4 by a length l ₂ which is again to be specified. This pin 121 forms with the dielectric sleeve 22 and the metallization 15 of the inner surface of the bore 16, the bridging capacitance C 2 of FIG. 1. Further details correspond to the description.

The individual resonator 5 , which is described here as the output resonator of the filter 1 , has a pin 21 in a sleeve 22 which is inserted in the bore 16 of the tubular body 11 . These three parts together form the output coupling capacitance C 4 of the filter 1 .

A filter 1 according to the invention or designed according to the invention as shown in FIG. 3 has a technologically logically simple implementation. It is easily adjustable, especially with regard to the capacitances C 1 to C 4 , by changing the respective length l ₁ to l ₄ .

The sectional view in FIG. 5 shows in the detail for the individual resonator 2 (and also valid for the further individual resonators 3 , 4 and 5 ) a particularly advantageous measure for coordinating the individual resonators 2 to 5 . As such, the individual resonators can be tuned to their respective resonance center frequency by mechanical reworking of their respective length L of their tubular bodies 11 . Such a measure is understandably quite agile. The measure explained with reference to FIG. 5 is advantageous to provide an essentially annular additional electrode 52 on the surface 51 of the tubular body 11 (of the single resonator 2 ). This additional electrode 52 is electrically connected to the metallization 15 of the inner surface of the tubular body 11 and extends over this surface 51 in the direction of the outer metallization 13 . By changing the distance between the outer edge 53 and the metallization 13 , a corresponding additional capacitance C 5 can be set, which enables a fine adjustment of the resonance center frequency of the individual resonator 2 . Distance changes can be achieved by erosion of the additional electrode 52 on the edge, for example by the action of laser radiation. This method is inexpensive and therefore particularly advantageous.

Corresponding additional capacities can be provided for the further individual resonators 3 to 5 .

Exact calculations of the filter or the sizes of the capacities and inductances of the equivalent circuit diagram according to FIG. 1 can be carried out according to methods known per se. They can also be determined from experimental results.

An LC equivalent circuit can be determined using appropriate software. This equivalent circuit is reduced to such an extent that the equivalent circuit diagram resembles that of a Tschebycheff filter. In particular, the bridges c 2 , c 3 are neglected and the wave resistances of Qeulle and load are adapted to that of the filter. Nodal frequencies, external qualities and couplings are calculated from this residual circuit. Since the ceramic resonators are individually tuned, their respective resonance center frequency is not the same as the nodal frequencies. A frequency shift must be taken into account that depends on the coupling or the external quality values.

The relationships between the aperture size to be selected, the coupling and the frequency shift or the coupling capacitances C 3 and C 4 and the external quality are determined experimentally per se.

Claims (3)

1. microwave filter, consisting of dielectric individual resonators as input, as output and as further resonators with interposed coupling apertures,
with dielectric bodies in the form of tubular bodies, the outer surface and the inner surface of which are metallized as electrodes, characterized in that
that for coupling to the input and to the output single resonator ( 2 , 5 ) a coaxial capacitor ( C 1 , C 4 ) is seen before, each of a metal pin ( 21 ) as a first electrode of the capacitor ( C 1 , C 4 ), consists of a sleeve ( 22 ) surrounding this metal pin ( 21 ) from an HF dielectric and from the metallization ( 15 ) of the inner surface of the tubular body ( 11 ),
the pin ( 21 ) and the sleeve ( 22 ) protrude at least by a length ( l ₃ , l ₄ ) into the bore ( 16 ) of the respective tubular body ( 11 ) of the individual resonator ( 2 , 5 ) in question and the metallization ( 15 ) the inner surface of the bore ( 16 ) forms the second electrode of this capacitor ( C 1 , C 4 ) and
that to increase the filter curve at least one bridging capacitor ( C 1 , C 2 ) is provided, which is a coaxial capacitor made of a metal pin ( 121 ) as a first electrode of this capacitor ( C 1 , C 2 ), from a metal pin ( 21 ) enclosing sleeve ( 22 ) from an HF dielectric and from the metallization ( 15 ) of the inner surface of the tubular body ( 11 ) of the individual resonator ( 3 , 4 ) in question,
wherein the pin ( 121 ) and the sleeve ( 22 ) protrude at least by a length ( l ₁ , l ₂ ) into the bore ( 16 ) in the respective tubular body ( 11 ) of the individual resonator ( 3 , 4 ) concerned and the metallization ( 15 ) the inner surface of the bore ( 16 ) forms the second electrode of this capacitor ( C 1 , C 2 ), and
that in each case the pin (21) of the coupling capacitor (C 3, C 4) and the pin (121) of the bypass capacitor (C 1, C 2) to one another (23) are connected. 2. Microwave filter according to claim 1, characterized in that the respective metal pin ( 21 , 121 ) enclosing sleeve ( 22 ) consists of a filled plastic. 3. Microwave filter according to claim 2, characterized in that the plastic is filled with ceramic powder that is equal to the ceramic material of the tubular body ( 11 ).