FI87853C - Ceramic barrier filter - Google Patents

Description

1 37853

The present invention relates to a dielectric blocking filter comprising two or more coaxial transmission line resonators.

As is known, a ceramic resonator consists of a basic structure in which a hole with a high dielectric constant, e.g. a titanium-10-based ceramic block having side surfaces, an upper surface and a lower surface, is made to pass from the upper surface to the lower surface. The surfaces of the block, with the exception of the upper surface, and the inner surface of the hole are coated with an electrically conductive material. On the upper surface, switching patterns are placed, with which the signal 15 is capacitively connected to and removed from the resonator. The structure forms a transmission line resonator, the resonant frequency of which is determined by the length of the hole, i.e. the thickness of the block. Usually, the hole length is dimensioned to obtain a quarter-wavelength transmission line resonator. By making several holes in the block 20, a bandpass filter with several poles can be implemented, but the number of zeros is limited to one because the isolation of a zero-resonator from other resonators is difficult to implement. Indeed, a blocking filter implemented with ceramic technology has only recently become commercially available. All these known blocking filters are characterized in that the filter consists of separate resonators, i.e. basic structures as described at the beginning, in which the ceramic piece contains one hole and the piece is coated with a conductive material at least on its side and bottom surface. These coated individual resonator pieces are placed in the desired number in succession to obtain a bandpass filter of the desired bandwidth and center frequency. Each resonator piece in its own way forms a suction circuit and these suction circuits are connected in series via an inductive or reactive connection, by means of which the upper ends of the resonators are connected using e.g. a separate section of the transmission line. The use of separate coated resonators is necessary because the inductive and capacitive leaks between the resonators are otherwise difficult to control, i.e. to provide adequate insulation between the resonators. The insulation 5 between the individual resonators is formed precisely by the coating of the resonators, which forms an effective partition between the pieces.

A disadvantage of a blocking filter assembled from separate resonators is that a filter assembled from several pieces requires a large manufacturing capacity because each piece is sintered and coated separately and the pieces are electrically connected to each other individually, usually by soldering the connecting wires by hand. In addition, the individual pieces must be mechanically securely attached to one of the mounting bases.

15

In principle, it would be possible to make a blocking filter consisting of several resonators on a single piece of ceramic. In this case, however, in order to obtain good insulation, the distance between the holes of the resonators should be made very large, so that the filter would become very large. This would increase material costs and large size is otherwise detrimental to portable radios.

U.S. Patent 4,823,098 to Motorola describes a monolithic ceramic filter with anti-bandwidth capability. The filter comprises 7 resonators placed on the same piece of ceramic, three of which act as a band-stop filter and the rest as a band-pass filter. The band-blocking side resonators are connected to a quarter-wavelength transmission lines 30 to each other. The transmission lines reverse the impedance of the resonators, causing the resonators to produce zeros in the filter. The publication mentions that said three filters can also be separated by sawing from the block and coating the new sidewall created in the cut with a conductive material, whereby the obtained filter acts as an independent band-stop filter with several zeros. The publication does not mention what inductive coupling between resonators via ceramics affects the characteristic curves of filters, but it is likely that coupling between resonators makes it difficult to control the properties.

Finnish patent applications FI-892855 and Fi-892856, applicant LK-Products Oy, describe bandpass filters implemented with one ceramic block, the inventive idea of which is based on the fact that one side surface of the filter is substantially uncoated and strip conductor patterns for transmission conductor resonators are placed on this side surface 10. When the connection patterns are made on the side surface of the body, the inlet and outlet of the filter and the connections between the resonators can be made as desired, either purely capacitively or inductively, or a combination thereof.

It is an object of the present invention to provide a blocking filter implemented in a single ceramic block having a plurality of resonators in which the effect of the electric and magnetic fields between the resonators can be blocked without the use of separate resonator pieces according to the prior art. The invention is based on the further development of resonator connections for filters according to said FI applications.

This object is achieved by a blocking filter according to claim 1.

It has surprisingly been found that by making a region 30 between the resonator circuits leading to the uncoated side surface of the filter block, the coating, the electrical and magnetic coupling between the resonators can be adjusted to almost zero in a suitable manner. By making the conductive area a strip extending from the lower surface of the ceramic block, where it communicates with the conductive coating of the block, all the way to the upper surface of the side, 35 an almost complete electrical and magnetic separation between the resonators is obtained. The conductive regions of the invention provide, as it were, an electrical "septum" between the resonators. If it is desired to make an "opening" in the partition through which a connection can be made between the resonators 4 37853, this can be done by shortening or narrowing the conductive area or by making both. Depending on whether the shortening is made at the open end 5 or the short-circuited end of the resonator, capacitive or inductive coupling is affected. By narrowing the conductive area in the direction of the resonator, the strength of the coupling between the resonators can be influenced. The individual resonators are connected to each other by means of an inductive and / or reactive switch. In this case, the same principle can be used as in FI applications 892856 and 892855, ie a connection pattern made with a mask on the side of the filter can be used. Separate components such as chip capacitors and inductance wires can also be connected to the connection patterns. If the conductive region 15 is the height of the entire side wall, the connection from one resonator to another is made with an inductive wire that crosses the conductive region. This entire page can finally be covered with a conductive deck.

The invention will be described more illustratively with reference to the accompanying figures, which show in Fig. 1 a blocking filter comprising three resonators, Fig. 2 is a reduced representation of the filter of Fig. 1 with 25 conductive regions modified, and Fig. 3 is a resonator attenuation curve of Fig. 1.

The blocking filter 1 according to the invention consists of three transmission line resonators A, B and C. In the rod-like block of ceramic material 30, holes 2], 22 and 2g are formed, which extend from the upper surface 3 to the lower surface of the block. The holes, the lower surface of the block, the ends and the other side are coated with a conductive material, e.g. a silver-copper alloy. The upper surface 3 can also be coated, except for a narrow annular area 35 around the upper edge of the holes 21f 23 and 23. A conductor pattern 5 is formed on the uncoated side 4 of the block by means of a mask, which also wraps as a strip at the edges of the side. The mask also forms contact spots 9, 10 and 11 5 87853 on the side of each resonator. The same mask also forms the inter-resonator conductive regions 14 and 15 according to the invention, which extend from the lower edge of the block where they join the conductive strip at the lower side of the side 4, to the upper edge of the block 5 where they join the conductive strip at the upper edge. The conductor pattern formed on the side of the block by means of the mask is shown in the figure in diagonal lines. The end surface of the block, which is one of the coated sides, is also shown in slash. The mask-formed conductor-10 pattern connects the necessary components and conductors to connect the signal to the filter, to connect the resonators to each other, and to conduct the signal out of the filter. A high frequency signal is applied by a conductor IN to a switching point 9 in the middle of resonator A. A block capacitor 6 is connected between this point 15 and the conductive strip at the bottom of the side. leading tape. The conductor wire 12 20 represents a given inductance. Correspondingly, the resonator B is connected to the resonator C by means of a conductor wire 13 representing the inductance, and the connection dot 11 is connected to the conductive strip at the bottom of the side by a block capacitor 8. The signal is output from the dot 11 and thus out of the filter 1 by conductor OUT. In order for the coupling to act as a blocking filter, there must be no coupling between the resonators A, B and C via the dielectric material, but the coupling must take place only via the conductor wires 12 and 13. This is possible only if the conductive regions 14 and 15 are placed between the resonators as shown in the figure.

It has been found that with the dimensions of the conductive regions, an almost complete reversal of the inductive and capacitive coupling between the resonators can be achieved, forming an almost complete electrical "partition" between the resonator-thighs. This allows the connection to act as a blocking filter with a defined blocking band. The bandwidth and applied frequency are determined by the conductor pattern made with the help of the mask and the centered inductances and capacitances, 6 87853, so by varying these, the desired blocking filter can be obtained. After forming the conductor pattern and attaching the components, the side of the block is covered with a metal protective cover so that there is a small gap between it and the side surface of the block.

5

For some purposes, it may be necessary to reduce the insulation between the resonators. In this case, a controlled connection can be arranged between the resonators according to Fig. 2. The same reference numerals are used in the figure as in Figure 10 1, but the separate switching means have been omitted for simplicity. The coupling between the resonators can be increased by shortening the conductive region between the resonators, as is done in the conductive region 14 between resonators A and B, or by narrowing the conductive region 15, as is done in the conductive region 15 between resonators B and C. Combinations of these can also be used. For which end of the conductive region is shortened, it has its own significance for the nature of the coupling between the resonators.

20

Figure 3 shows the actual measured attenuation curve of a block of one ceramic block made according to the invention. The implemented filter is intended in particular to attenuate the frequency range 890 to 915 MHz, which is the transmission frequency range of the GSM mobile telephone system, whereby the filter is suitable for use e.g. in connection with an antenna filter in the receiver branch. It can be seen from curve I, which is the attenuation curve, that the attenuation is large between marks 1 and 2, greater than 40 dB, which is the frequency range just mentioned, after which the attenuation 30 rapidly approaches zero. This is advantageous so that the frequency of the transmitter does not reach the receiver. Curve 11 shows the fit of the filter.

Thus, by using the conductive region according to the invention between the resonators-35, an "electrical partition" is provided between the resonators. There are many benefits to this. The blocking filter does not have to be assembled from separate coated resonator pieces, but a single ceramic 7 87 8 5 3 body can be used. This saves both work steps and material.

Since the necessary connections are made to the side of the ceramic body by means of a mask, the same body can be used both for the manufacture of a blocking filter and for the manufacture of an emission filter, in which case the emission filter is constructed in accordance with Finnish patent applications FI-892855 or FI-892856. The properties of the blocking filter can be easily varied by changing the mask and component values.

10

Claims (5)

A ceramic barrier filter comprising two or more resonators consisting of blocks (A, B, C) of dielectric material in which a heel (2X, 22, 23) lined with conductive material extends from the upper to the lower the surface and the upper, lower and side surfaces of which are at least partially covered with an electrically conductive layer, coupling means and coupling patterns for conducting a signal to the filter and for coupling to the resonators, and for conducting an output signal from the filter, characterized in that the blocks of the resonators (A, B, C) form a single ceramic block (1), one side of which is not fully lined with conductive material and that this side surface has strip-like areas (14; 15) of electrolytic maltite Lal soin runs along the upper edge, which are in the area between the reso-:; : the generators (A and B, B and C) and whose measurements are chosen so as to substantially cancel the electric and magnetic field -: between the resonators. ... 30 2. Ceramic barrier filter according to claim 1, characterized in that the conductive band-like region (14; 15) is not continuous, thereby affecting the length of the discontinuity location between the adjacent resonators (A, B). or B, C). 35 3. Ceramic barrier filter according to claim 1, characterized in that the conductive band-like region (14; 15) is narrower than that required to cancel the electric and magnetic field between the resonators, wherein: changing the width of the area affects the connection between adjacent resonators (A, B or B, C). 4. Ceramic barrier filter according to claim 1, characterized in that the coupling means, the coupling patterns and the conductive areas (14; 15) are on the same side surface (4) and the conductive layer covering this side surface (4) is a separate cover. of conductive material. 10 5. Ceramic barrier filter according to claim 4, characterized in that the conductive band-like area (14; 15) is provided in the side surface (4) of the filter with the same mask with which the coupling patterns are transmitted to said side surface.