FI87407C - BAND PASS FILTER - Google Patents

Description

Bandpass filter! 874G7

The invention relates to a bandpass filter comprising a body of dielectric material having upper, lower and side surfaces, at least the lower and side surfaces of which are covered with an electrically conductive layer, one or more holes coated with a conductive material extending from the lower surface to the upper surface. a toresonator, and electrically conductive connection patterns 10 formed on the surface of the body for connection to the transmission line resonators.

It is typical for commonly used ceramic filter solutions that the coupling to the filter is realized by capacitively coupling to the open end of the transmission line resonators with coupling strips placed on the upper surface of the body. From electrotechnical capacitive coupling means coupling to an electric field. A ceramic filter of this type is disclosed, for example, in U.S. Patent Nos. 4,431,977 and 4,716,391. The latter publication also discloses coupling to a resonator by coupling patterns formed on the side surface of the body, either capacitively or inductively. Inductive coupling means coupling to the magnetic field of a resonator near its grounded lower 25-end. In known solutions, the connections between the different resonators of the filter are formed capacitively from the upper surface of the ceramic body. In addition, there is an inductive coupling between the resonators depending on the dimensioning of the ceramic body and the distance between the resonators, which, however, can only be influenced by changing the dimensioning of the ceramic body or by machining the ceramic body. For example, in U.S. Patent No. 4,431,977, the coupling between the resonators is also provided between the resonators by holes made in the body or by 35 grooves made in the surface of the body.

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The center frequency of the bandpass filter made of ceramic material can be adjusted by changing the height of the ceramic body in the direction of the longitudinal axis of the holes forming the transmission line resonators. When the body of ceramic 5 is made by pressing, changing the height is quite easy to implement with one and the same tool. The bandwidth of the bandpass filter can be adjusted by changing the width of the ceramic body. Fine-tuning the bandwidth therefore requires some degree of machining of the ceramic body to obtain an optimal bandwidth because it is difficult to make ceramic bodies of different widths with the same tool.

It is an object of the present invention to provide a bandpass filter made of a dielectric material, the electrical properties of which can be easily adjusted over a wide range without having to change the dimensioning of the dielectric body of the filter and the tool used to manufacture it or mechanically machine the finished body.

This is achieved by a bandpass filter of the type described in the introduction, characterized in that at least some of the coupling patterns are on one side surface parallel to the longitudinal axes of said holes between the side and said electrically conductive layer, so that there is an electrically conductive space between the electrically conductive layer and / or an insulating layer.

By making the connection patterns required for connection to the transmission line resonators completely or at least mainly on the other side surface of the body, the input and output of the bandpass filter and the connections between the resonators can be made as desired by either purely capacitive or inductive connection or suitable inductive and capacitive connection. In this way, the frequency-35 response of the filter can be modified and the maximum points of attenuation above and below the passband of the filter can be formed only by means of connection patterns to the side wall and by changing them. In practice, this means that when changing the characteristics of the bandpass filter, only the mask by which the coupling patterns are formed on the side wall of the ceramic body has to be changed. Since inductive switching can also be used to the desired extent in the solution according to the invention, in one bandpass filter according to the invention it has been possible to reduce the number of transmission line resonators from six to four and thus reduce the size of the bandpass filter by one third.

The abundant patterning on the side surface of the body significantly breaks the uniform metal coating required on the side surface, which in turn adversely affects the electrical properties of the bandpass filter. In the bandpass filter according to the invention, this is solved by placing a substantially uniform electrically conductive layer on the coupling patterns so that there is an air gap and / or an insulating layer between the electrically conductive layer and the coupling patterns.

Another feature of this electrically conductive layer is that by changing the thickness of said air gap or insulating material layer, the bandwidth of the bandpass filter can be easily fine-tuned. In a preferred embodiment of the invention, the electrically conductive layer 25 is formed by a movable metal cover, by moving which the size of the air gap and thereby the width of the band can be adjusted.

The invention will now be described in more detail by means of exemplary embodiments with reference to the accompanying drawing, in which Figure 1 shows a perspective view of a bandpass filter according to the invention, Figure 2 shows a cross-sectional view of the bandpass filter of Figure 1 Fig. 4 shows a cross-sectional view of a second bandpass filter according to the invention, and Fig. 5 shows a cross-sectional view of a third bandpass filter according to the invention.

Figures 1 and 2 show a ceramic bandpass filter embodying the present invention. The filter includes a body 1 formed of a dielectric material selectively coated with a conductive material. The filter may be formed of any suitable dielectric material.

The body 1 is substantially rectangular in shape and comprises an upper surface, a lower surface and two side surfaces. The body 1 further comprises four holes 3, 4, 5 and 6 in the longitudinal row 15 of the body, which extend from the lower surface of the body to its upper surface. The lower and upper surfaces of the body and the second side surface are coated throughout with an electrically conductive material layer 11 except for the annular area 20 7 surrounding each hole 3, 4, 5 and 6 on the upper surface of the body. In addition, each hole 3, 4, 5 and 6 is also coated with conductive material that at the lower end of the holes their coating coincides with the coating on the lower surface of the body while at the upper end of the hole the coating is not bonded to the coating on the upper surface of the body. Each of the coated holes 3-6 capacitively couples at the open end to the surrounding coating to form a transmission line resonator, the length of which is selected for the desired filter response curve.

In a preferred embodiment of the invention, the holes 3-6 are located eccentrically with respect to the longitudinal axis of the body 1 so that the holes are closer to the uncoated side wall of the body than to the coated side wall. The uncoated side wall of the body has connection patterns 13 and 14 formed by metal foil patterns for connection to the filter 35 and for connections between transmission line resonators 5 874G7.

Figure 3 shows circuit diagrams made on the side surface of a bandpass filter according to the invention. The inductive connection to the resonator is made by 5 strip patterns which are grounded at one end to a metal coating on the lower surface of the body. Such an inductive coupling pattern is illustrated in Fig. 3 by coupling patterns 31 and 35 connected at their lower ends to the respective transverse side strips 10 and 37 of Fig. 33. A purely capacitive coupling to a resonator or Figure 34. Extensions 15 32 and 36 of the inductive coupling patterns 31 and 35, which extend between resonators 3 and 4 and 5 and 6, respectively, provide inductive and capacitive mixed coupling between these resonators. Such a mixed coupling between two resonators can also be realized by using both an inductive and a capacitive coupling pattern at the same time.

Inductive coupling is greatest near the lower end of the resonator, where the magnetic field of the resonator is strongest, while capacitive coupling is strongest near the upper end of the resonator, where the electric field is strongest. Thus, both inductive and capacitive switching can be adjusted both by changing the size of the switching pattern and by changing the position of the switching pattern in the height direction. For example, widening and raising the inductive coupling pattern reduces the inductance of the pattern, thereby increasing the coupling to the resonator. Correspondingly, increasing the size of the capacitive coupling pattern or increasing its position increases the coupling to the resonator. Capacitive connections can affect the lower end of the passband and inductive connections can affect the upper end of the passband, respectively. Since the use of inductive connections 6 8 7 4 ind 7 directly results in a low-pass type filter, a bandpass filter according to the invention can be implemented with four transmission line resonators, when previously at least six transmission line resonators were always needed.

Figure 3 is only intended to illustrate the use of coupling patterns on the side surface of the body 1, and their shape, number and other properties will, of course, be determined by the electrical properties of the particular filter and the chosen embodiment.

Referring again to Figures 1 and 2, the side surface of the body 1 with connection patterns is covered with a removable, box-like metal cover 2, the side sides 2a and 2b of which are partially pushed over the upper and lower surface of the body 1 and the electrically conductive coating 11 thereon. In this case, the cover 2 forms an electrically conductive surface corresponding to the coating 11 around the side surface comprising the connection patterns, which ensures the operation of the resonators 3-6. The inner surfaces of the side sides of the cover 2 have shoulders 2c which come against the side surface of the body, determining the distance by which the inner surface of the cover 20 2 is from the side surface of the body 1. In the preferred embodiment of the invention, an air gap 12 is left between the cover 2 and the side surface of the body 1. By moving the cover 2 and changing the size of this air gap 12, the bandwidth of the bandpass filter can be adjusted. Alternatively, the air gap 12 may be partially or completely filled with a suitable dielectric material. The cover 2 further has one or more openings 9 through which the connecting conductors can be inserted into the cover for connection to the connection patterns on the side surface of the body 1.

Fig. 4 is a cross-sectional view of a bandpass filter according to another invention, which for the body 1 corresponds exactly to the bandpass filter according to Figs. 1 and 2, and in which the same reference numerals describe the same headings. The difference with the previously described embodiment 35 is that the side surface provided with the connection patterns 13 and 14 of the body 1 87407 is first coated with a layer 15 of a suitable dielectric material, on which an electrically conductive metal film 17, which may be similar to the coating 11, is then coated. and formed simultaneously with the coating 11. In addition, one or more openings 18 for the connecting conductors 10 are left in the electrically conductive layer 17. In this case, the electrically conductive layer 17 has exactly the same effect as the cover 2 shown in Figs. 1 and 2. However, the bandwidth of the filter 10 can be adjusted only by changing the thickness of the dielectric material layer 15 when manufacturing the filter.

Fig. 5 shows a cross-sectional view of another bandpass filter according to the invention, which also fully corresponds to the bandpass filter 15 according to Fig. 4 with respect to the body 1. The body 1 is mounted on its side on the circuit board 50, the side comprising the circuit diagrams 13 and 14 against the circuit board, at a point where the insulating plate 53 forming the body of the circuit board is exposed at least in the area of the sides of the body 1. The body 1 is preferably attached to the silicon 20 plate 50 by soldering its side surfaces 54 to the metal film 51 surrounding said area on the circuit board 50 or, alternatively, e.g. by glue. The opposite surface of the circuit board 50 has a metal film 52 at least on the side of the body 1, which is electrically connected to the metal film 51, for example by a coated bushing 55 and thereby to the metal coating 11 of the body 1. The metal film 52 thus has the same meaning as the cover 2 and conductive layer 17 in the previous in embodiments, and the insulator layer is formed by a body 53 of circuit board insulator 30.

The accompanying figures and the related description are intended to illustrate the present invention only. The details of the bandpass filter of the present invention may vary within the scope of the appended claims.

Claims (9)

8 87407 A bandpass filter comprising a body 5 (1) of dielectric material having upper, lower and side surfaces, at least the lower and side surfaces of which are covered with an electrically conductive layer (11, 2, 17), from one or more upper surfaces towards the lower surface a hole (3-10 6) coated with a conductive material forming a transmission line resonator and electrically conductive connection patterns (13, 14) formed on the surface of the body (1) for connection to the transmission line resonators (3-6), characterized in that at least some of the connection patterns 15 (13) , 14, 31-36) on one side surface parallel to the longitudinal axes of said holes between the side surface and said electrically conductive layer (2, 17) so that there is an air gap (12) between the electrically conductive layer (2, 17) and the coupling patterns. ) and / or an insulating layer (15). A filter according to claim 1, characterized in that the electrically conductive layer covering the side surface comprising the coupling patterns is formed by a metal lid having a box-like shape. A filter according to claim 1, characterized in that the electrically conductive layer covering the side surface comprising the coupling patterns is formed by a metal film (17) formed on the insulating material layer (15). Filter according to claim 2, characterized in that the bandwidth of the filter is adjustable by adjusting the distance of the cover (2) from the side surface of the body (1) and thereby said air gap (12). Filter according to Claim 1, 2 or 3, characterized in that the bandwidth of the filter can be adjusted by selecting an insulating material (15) having a suitable dielectric constant. 9 87407 Filter according to Claim 1, 2 or 3, characterized in that the bandwidth of the filter is adjustable by changing the strength of the insulating layer (15). Filter according to claim 1, 2, 3 or 5, characterized in that the body (1) is mounted on the insulating plate (53) against a side surface comprising connection patterns, said insulating layer covering said side surface being formed by an insulating plate (53) and said electrically conductive layer 10. forms a metal coating (52) on the opposite side of the insulating plate (53), which is electrically connected to the electrically conductive coating (11) of the filter body (1). A filter according to claim 2 or 4, characterized in that the electrically conductive cover (2) comprises a recess for receiving and holding the body, and means (2c) for holding the inner surface of the cover (3) at a predetermined distance from the side surface of the body (1). Filter 20 according to one of the preceding claims, characterized in that the filter has four transmission line resonators (3-6). ίο 8 7 4 0 7