FI102433B - Radio frequency filter and method for adjusting the frequency function of the filter - Google Patents

Description

102433

The invention relates to radio frequency filters and to a method for adjusting the frequency response of a filter, in particular to filters with resonator structures.

Ceramic filters are very popular in radio technology. Their advantages include a simple structure. Due to their fixed structure, they are stable, as a device, and the frequency characteristics of the ceramic filters are not significantly affected by temperature variations. In addition, they are well suited for series production due to their simple structure.

The known basic structure of a ceramic filter consists, as shown in Figure 1, of 15 dielectric bodies with two metallized holes on the inside. Other surfaces of the part except the so-called the open top surface is metallized throughout, and the metallization of the lower surface is associated with the metallization of the holes. The metallized holes form a short-circuited resonator structure at their lower ends, which is capacitively fed through the metallized areas formed on the upper surface of the body. The frequency characteristics of the structure are mainly determined by the size of the holes, the distance between them and the capacitive coupling determined by the pattern of the upper surface of the body. If the resonator holes are short-circuited at only one end as above, the structure will form a quarter-wave resonator. Half-wave resonators can also be implemented with a similar basic structure, in which case both ends of the resonator holes are short-circuited. At the open end of the resonator structure, the electric field strength is at a maximum with the magnetic field at its minimum, while at the short-circuited end, the electric field is at its minimum (approximately zero) and the magnetic field is at its maximum. Thus, the surface currents present in the coating are also at their maximum at the short-circuited end of the structure.

30 A number of variations have been developed from this basic structure, e.g. there may be only one or more resonators, as disclosed in U.S. Patent No. 4,431,977 to Sokola et al. There are numerous other patented solutions for ceramic resonator filter structures (e.g. US 5,239,279 Turunen, Näppä). However, all of these are characterized by the fact that the short-circuited ends of the resonators are connected throughout the coated base. Figure 2 shows an equivalent surrogate connection of such a basic structure, where C1 and C2 are the switching capacitances and K represents the resonate electromagnetic connection between the holes TL1 and TL2.

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Helix-based resonator structures can be tuned, for example, by bending strips formed in the wall of the metal shell forming the outer conductor of the resonator structure. In such a tuning procedure, there is a risk that the tuning of the resonator will later change as the strips bend, for example due to vibration or during handling of the resonator.

It is an object of the invention presented in this application to provide a compact and more versatile resonator filter structure than the prior art. It is also an object of the invention to provide a structure whose properties can be easily changed even in series production. It is a further object of the invention to provide a simple resonator structure which can be tuned after manufacture, in which no moving parts are required for tuning.

The objectives are achieved by changing the surface currents of the short-circuited end of the structure. This can be done, for example, by forming patterns in the area between the right-closed ends of the resonators.

The structure according to the invention is characterized in that at least one short-circuited end of the inner conductor of the filter is provided with means for controlling the electric currents between the inner conductor and the outer conductor.

The invention further relates to a method for adjusting the frequency response of a filter. The method is characterized in that the frequency response is adjusted by changing the electric currents generated in said short-circuiting members of the resonator structure.

25

The operation of the invention is based on the fact that a change in the surface current causes a change in the inductive properties of the structure and vice versa. Due to this, the patterning of the coating on the bottom of the filter structure can influence the flow of surface currents characteristic of different waveforms, which determine e.g. the effective receiver inductance of the resonator at 30 to the ground. This receiver inductance controls the resonant frequency of the resonator as well as the coupling between the resonators. The patterning of the coating can also affect the magnitude of the series inductance between the inner conductors of the resonators, which mainly regulates the coupling between the resonators.

It will be apparent to those skilled in the art that, in accordance with established practice, the bottom or bottom surface of a filter structure refers to the surface of a substantially rectangular body corresponding to the short-closed end of a quarter wave resonator and the upper surface to the surface corresponding to the checked-lusuuntaan.

The invention will now be described in more detail with reference to exemplary preferred embodiments and the accompanying figures, in which Figure 1 shows a basic structure of a ceramic resonator according to the prior art, Figure 2 shows an electrical mating of such a structure, Figure 3 shows an example of a structure according to the invention, Figure 4 shows such a structure Fig. 5 shows the frequency response of such a structure and the change of the frequency response when changing one part of the pattern, Fig. 6 shows the frequency response of such a structure and the change of the frequency response when changing another part of the pattern, Fig. 7 shows a variation of the basic structure according to the invention without direct resonator ends Figure 8 shows a variant of the basic structure according to the invention, in which the input and output connections of the filter are realized instead of capacitive connection. 20 as inductive connections, Fig. 9 shows the electrical counter-connection of the structure according to Fig. 8, and Fig. 10 shows by way of example other possible variations of the structure according to the invention.

25 In the illustrations, the same reference numbers and designations are used for the corresponding parts.

According to the invention, only a partially coated area of electrically conductive material is formed at the short-circuited end of the filter. It is essential for the invention that the surface currents of the filter 30 and thus the coupling between the resonators and the specific frequency of the resonators are influenced by means of the pattern formed by said coating. In addition to the actual coating, it can be used other than by coating an electrically conductive material attached to the structure.

Figure 3 shows a method of illustrating the lower surface of a filter structure according to the invention. The inner conductors of the resonators are galvanically connected via strips A1 and A2 to the ground potential of the end faces of the filter structure. In addition, the strip area A12 connects the areas A1 and A2 to each other.

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The structure can be shown by the surrogate connection shown in Figure 4. The coils L1 and L2 in the figure illustrate the effective inductance caused by the strip regions A1 and A2 between the center conductor of the resonator and the ground potential of the structure. Coil L12 describes the inductance of the strip region A12 between the inner conductors.

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According to the invention, the lower surface is coated either completely or partially with an electrically conductive coating. To achieve the desired properties, the coating is removed or added as needed. For example, if it is desired to influence the coupling between the resonators, material can be removed from the pattern of Fig. 3 from the strip-10 ka region A12, whereby the magnitude of the inductance between the resonators increases. If it is desired to move the natural frequencies of the resonators upwards, a conductive substance can be added to the strip regions A1 and A2 in the figure made according to Fig. 3, whereby the effective series inductance seen by the resonator against ground decreases.

Figure 5 shows the effect of narrowing the strip region A12, i.e. increasing the inductance of the coil L12 shown in the surrogate circuit, on the frequency response (transmission attenuation) of the filter. The intact curve depicts the initial response of the filter shown in Figure 3 and the dashed situation after narrowing of the region A12. The tapering reduces the magnitude of the total inductive coupling, while the capacitive coupling 20 remains nearly constant. As can be seen from the figure, the narrowing of the region A12 has a clear effect on the coupling between the resonators.

Figure 6 shows the effect of the widening of the strip areas A1 and A2, i.e. the reduction of the inductances of the coils L1 and L2 shown in the substitution circuit, on the frequency-25 response of the filter. The intact curve depicts the initial response of the filter shown in Figure 3 and the dashed situation after widening of areas A1 and A2. The widening of said regions reduces the total inductive coupling field between the resonators. As can be seen from the figure, the widening of the regions A1 and A2 shifts the frequencies of the resonators up.

30

According to the invention, strip areas that provide the desired electrical properties can be made by removing certain coating areas from a surface that has first been completely coated. Another option is to make a directly finished textured coating that has properties that affect surface flows. If further adjustment is desired, the coating 35 can be removed at specific points or added to desired locations in the lower surface coating.

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Figure 7 shows a variation of the base pattern according to the invention. The inner conductors of the resonators are connected via strip areas to the main surfaces of the filter structure. There is no conductor in the region A5 between the conductors and thus the inductance between the resonators of the substitute circuit (L12 in Fig. 4) is missing.

5

In the above example structures, the input and output connections of the filter to the resonators are implemented capacitively. An advantage of the structure according to the invention is that the input and output switching can also be easily implemented inductively by connecting the input and output signals directly to galvanic contact with the strip areas of the base. Fig. 8 shows an embodiment in which open extensions A3 and A4 are made in the strip areas A1 and A2, which galvanically connect the inner conductors of the resonators to the ground potential of the filter structure, to which the filter ports IN and OUT can be connected directly galvanically. The substitution circuit of the structure is shown in Figure 9, where coils L3 and L4 illustrate the effective series inductances of the strip regions A3 and A4.

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Figure 10 shows examples of other preferred resonator structure base patterns. In the first example, there is no direct connection between the resonators, but the lower ends of the resonators are in electrical communication with the side surface of the filter structure. The second example is as shown in Fig. 3, but the second resonator of the example has a second connection to the side surface of the filter structure in addition to the connection connecting to the end surface of the filter structure. The third example shows a pattern with a non-conductive region parallel to one side surface of the filter structure, and the resonators are in electrical communication with only three side surfaces of the filter structure.

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The dielectric filter according to the invention may consist of a single dielectric body, the pattern according to the invention being entirely on the surface of the body. The dielectric filter according to the invention may also comprise a combination of a dielectric body and a plate patterned with a conductive material, wherein the patterns of the body and the plate 30 are in electrical communication with each other, and wherein the pattern according to the invention may also be partially or completely on the plate.

Although a dielectric filter structure has been used as an example above, it will be clear to a person skilled in the art that the invention is also well suited for use with filters implemented with other resonator structures, such as stripline, helix or coaxial resonator structures, i.e. with at least one end of the resonator! short-circuited, whereby surface currents are formed at the short-circuited end, which are affected according to the invention.

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The invention makes it possible to implement more versatile filter structures than the prior art. The invention is well suited for series production and facilitates the series production of resonator filters, since the invention makes it possible to produce a basic model which can be subsequently adjusted for different applications. In addition, the invention enables a stable tuning possibility: no separate tuning parts are used for tuning, which could move due to vibration, shocks, etc.

Claims (24)

A radio frequency filter comprising at least two resonators forming conductive inner conductors and an outer conductor of conductive material, the inner conductor of the filter being short-circuited to the outer conductor at least at one end, characterized in that at least at one short-ended end of it the inner conductor of the filter has been formed means for controlling the electrical currents between the inner conductor and the outer conductor. Filter according to claim 1, characterized in that the control means for the electric currents in the short-circuited end are formed by forming samples in the short-circuited conductive material of the inner conductors. Filter according to claim 2, characterized in that said control means forms a band area (A 12) which forms inductance between the inner conductor of the filter. Filter according to claim 2, characterized in that said control means forms a non-conductive region (A5) in the region between the inner conductor of the filter. Filter according to claim 2, characterized in that said control means is in contact with the conductive coating on the side surface which forms outer conductors in two or three resonator structures. Filter according to claim 2, characterized in that said control means forms a non-conductive region parallel to the side surface forming outer conductors in a resonator structure. 25 Filter according to claim 1, characterized in that the control means for the electric currents in the short-circuited end are formed with the design of the conductive material which forms a short-circuit of the inner conductors. Filter according to claim 2 or 7, characterized in that said inner conductor is short-circuited only at one end to form a quarter-way resonator structure. Filter according to claim 2 or 7, characterized in that said inner conductor is shorted at each end to form a half-way resonator structure. 35 Filter according to claim 9, characterized in that the control means of the electric currents at each resonator is formed only in the one means which shortens the ends of the resonator. 102433 Filter according to claim 9, characterized in that the control means of the electric currents are formed at each resonator in each of the means which short-circuits the ends of the resonator. 12. A filter according to claim 8, 9, 10 or 11, characterized in that the input and output signals of the filter are galvanically coupled to some of the control means for the electric currents to arrange inductive supply to the filter. Filter according to claim 8, 9, 10, 11 or 12, characterized in that the basic structure of the filter is a ceramic filter. 10 Filter according to claim 13, characterized in that the control means for the electric currents lie on the surface of the dielectric piece forming the filter. 15. A filter according to claim 13, characterized in that the control means for the electric currents 15 lie on a disc, which forms a galvanic contact between the resonator tail of the dielectric piece and the side surface. Filter according to claims 8, 9, 10, 11 or 12, characterized in that the resonators of the filter are formed with band conduction resonator construction. 20 Filter according to claims 8, 9, 10, 11 or 12, characterized in that the filter resonators are formed with helix resonator construction. Filter according to claims 8, 9, 10, 11 or 12, characterized in that the resonators of the filter are formed with coaxial resonator construction. A method of controlling the frequency function of a radio frequency filter with resonator construction, wherein said filter comprises at least two resonators which form conductive inner conductors, and an outer conductor of conductive material, the inner conductor of the filter being short-circuited to the outer conductor at least one end, whereby in the means that short-circuit the inner conductors to the outer conductor, strong electrical currents are generated, the method being characterized in that the frequency function is controlled by changing the electrical currents generated in said short-circuit means in the resonator structure. 35 20. A method according to claim 19, characterized in that the surface of the resonator structure on which the short-circuit electrical connection is formed is completely covered with conductive material and the electrical currents of the structure are changed by selectively removing said conductive material. 21. A method according to claim 19, characterized in that the surface of the resonator structure on which the short-circuited electrical connection is formed is partially covered with conductive material and the electrical currents of the structure are changed by selectively removing said conductive material. Method according to claim 19, characterized in that the surface of the resonator structure on which the short-circuit electrical connection is formed is partially covered with conductive material and the electrical currents of the structure are changed by selectively adding conductive material. Method according to claim 21 or 22, characterized in that said part shows coverage of said surface forming a desired sample on the surface, which is fine-controlled by removing said conductive material. The method according to claim 21 or 22, characterized in that said partial coverage of said surface forms a desired sample on the surface, which is fine-tuned by adding conductive material.