KR102127506B1 - Ceramic Waveguide Filter With Enhanced Spurious Property - Google Patents

Abstract

A ceramic waveguide filter comprising a ceramic dielectric block is disclosed. In the ceramic waveguide filter of the present invention, in the ceramic dielectric block, a plurality of resonator regions are connected by a narrower connection region, and conductive metal layers are stacked on the surface of the ceramic dielectric block, and the resonator regions are It is divided into resonator regions of different sizes, and a resonant mode compensation groove for coincidence of a basic resonant mode is formed in the resonator region, so that spurious signal components of the ceramic waveguide filter are dispersed and do not overlap. The ceramic waveguide filter according to the present invention improves the spurious characteristics by preventing the spurious signal components from being dispersed and overlapping, and further suppressing the spurious characteristics by suppressing the dispersed spurious signal components by being combined with a multilayer printed circuit board including a harmonic removal circuit. Improve further.

Description

Ceramic waveguide filter with improved spurious properties{Ceramic Waveguide Filter With Enhanced Spurious Property}

The present invention relates to a ceramic waveguide filter, and more particularly, to a ceramic waveguide filter having improved spurious characteristics by preventing spurious signal components from being dispersed and overlapping.

The ceramic waveguide filter transmits signals through a dielectric medium instead of air. Ceramic waveguide filters can achieve a miniaturization that is inversely proportional to the square root of high dielectric constant than air-borne waveguide filters, but the manufacturing process is difficult because the inside is filled with dielectric material.

The ceramic waveguide filter may contain unwanted spurious or harmonic components in addition to the resonance frequency of the basic resonance mode on the frequency spectrum. This spurious degrades the filter's blocking properties and must be removed or suppressed.

Patent registration No. 10-0253679 (registered on January 26, 2000) discloses a dielectric filter with improved spurious characteristics. Patent registration No. 10-0314086 (registered on October 25, 2001) discloses a ceramic filter with improved spurious characteristics by shifting the frequency of the parasitic pass band by a harmonic characteristic control unit. Patent registration No. 10-0388053 (registered on June 4, 2003) discloses a dielectric filter and a dielectric duplexer with further improved spurious characteristics. Patent Publication No. 10-2015-0112179 (published on Oct. 07, 2015) discloses a waveguide bandpass filter that removes unwanted spurious or harmonic components from the frequency spectrum by constructing a ground stub lowpass filter in the waveguide resonator.

As in the prior arts described above, unwanted spurious or harmonic components in the frequency spectrum are also removed or appropriately removed in the ceramic waveguide filter, including a ceramic dielectric block in which a plurality of resonator regions are connected by narrower connection regions than that. It is preferred to be treated. However, it is difficult to find an example of improving the spurious characteristics in the ceramic waveguide filter itself.

Accordingly, an object of the present invention is to provide a ceramic waveguide filter with improved spurious characteristics by preventing spurious signal components from being dispersed and overlapping.

In addition, an object of the present invention is to implement the function of suppressing the spurious signal component from overlapping and suppressing the spurious signal component by combining the above ceramic waveguide filter with a multi-layer printed circuit board including a harmonic elimination circuit, to achieve spurious characteristics. This is to provide a further improved ceramic waveguide filter.

On the other hand, other objects and advantages of the present invention will be clearly understood by the detailed description of the invention described below.

The ceramic waveguide filter having improved spurious properties according to the present invention for achieving the above object includes a ceramic dielectric block. In the ceramic dielectric block, a plurality of resonator regions are connected by a narrower connection region, and a conductive metal layer is stacked on the surface of the ceramic dielectric block. The resonator regions are divided into resonator regions of different sizes, and the resonator region compensation grooves for matching the basic resonant modes are formed in the resonator regions, so that spurious signal components of the ceramic waveguide filter are dispersed and do not overlap.

It is preferable that the depth of the resonance mode compensation groove is set to 50% or less of the height of the resonator region.

It is preferable that the notch resonator region is formed adjacent to the input/output resonator region among the resonator regions, and the notch resonator region is formed with a notch adjustment groove, so that the filter forms an attenuation pole.

The depth of the notch adjustment groove is preferably set to 50% or less of the height of the notch resonator region.

It is preferable that the notch resonator region has a through hole for adjusting the notch resonance impedance adjacent to the notch adjustment groove.

The through hole for adjusting the notch resonance impedance may be to adjust the intensity of the attenuation pole generated by the notch resonance by adjusting the notch resonance impedance according to the distance away from the notch adjustment groove.

The through hole for adjusting the notched resonance impedance may serve to fix a clasp in an electroplating process, so that the ceramic dielectric block can be formed by electroplating.

In the electroplating process, the clasp is caught in the opposite portion of the notch-adjusting groove in the through-hole for adjusting the notch resonant impedance, so that the electrical characteristics of the filter are not affected even if the clasp is not plated. do.

It is preferable that the ceramic waveguide filter further includes a multi-layer printed circuit board including a harmonic elimination circuit so that spurious signal components are suppressed by the harmonic elimination circuit.

The multilayer printed circuit board includes first and second surface layers and three layers of an intermediate layer between the first and second surface layers, and the intermediate layer includes a pair of input/output terminals and the input/output resonator region of the ceramic dielectric block It is preferable that a pair of connection terminals electrically connected to the connection pins installed in the is formed, and that the harmonic removal circuit is formed between one input/output terminal and one connection terminal.

The ceramic waveguide filter according to the present invention improves the spurious characteristics by preventing the spurious signal components from being dispersed and overlapping, and further suppressing the spurious characteristics by suppressing the dispersed spurious signal components by being combined with a multilayer printed circuit board including a harmonic removal circuit. Improve further.

1 is a perspective view of a ceramic waveguide filter according to an embodiment of the present invention as viewed from above mounted on a multi-layer printed circuit board including a harmonic removal circuit.
2 is a perspective view of a ceramic waveguide filter according to an embodiment of the present invention when a coaxial terminal is attached from the bottom.
3 is a perspective view of a ceramic waveguide filter according to an embodiment of the present invention mounted on a multilayer printed circuit board including a harmonic removal circuit.
4 is a perspective view showing an intermediate layer of a multilayer printed circuit board in FIG. 3.
5 is a graph showing frequency characteristics of a band pass region for a ceramic waveguide filter according to an embodiment of the present invention.
6 is a graph illustrating harmonic characteristics for a ceramic waveguide filter according to an embodiment of the present invention.
7 is a graph showing harmonic characteristics implemented by a combination of a ceramic waveguide filter and a harmonic removal circuit of a multilayer printed circuit board according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings.

1 and 2, the ceramic waveguide filter 10 according to the present invention includes a ceramic dielectric block 100. In the ceramic dielectric block 100, a plurality of resonator regions 110 are connected by a connection region 120 having a width narrower than that. A conductive metal layer is stacked on the surface of the ceramic dielectric block 100. The conductive metal layer can be partially removed for specific functions. For example, the conductive metal layer may be partially removed from the input/output resonator region for plating and circuit break around the interface of the input/output groove, and the conductive metal layer of a specific portion may be removed to tune frequency and coupling amount.

The resonator regions 110 are divided into resonator regions R1, R2, and R3 of different sizes, and the resonator region compensation grooves RH1, RH2, for matching the basic resonant modes are provided in the resonator regions R1, R2, and R3. RH3, RH4, RH5 and RH6) are formed. In this way, the spurious signal components of the ceramic waveguide filter 10 of the present invention are not superimposed but dispersed. Therefore, according to the ceramic waveguide filter 10 of the present invention, the harmonic characteristics of the filter are improved.

The ceramic dielectric block 100 of the ceramic waveguide filter 10 according to one embodiment of the present invention shown in FIGS. 1 and 2 has six resonator regions 110. The resonator region 110 is divided into three different size resonator regions R1, R2, and R3. Different sizes mean that the horizontal and vertical dimensions are different when the shape of the resonator region is square. It is common for the height or thickness of the resonator region to coincide in all resonator regions. At this time, the pair of input/output resonator regions R1 are formed with the same size, and the pair of resonator regions R2 adjacent to the input/output resonator regions R1 are also formed with the same size, and the resonator regions R2 A pair of resonator regions R3 adjacent to each other are also formed in the same size. The pair of resonator regions R3 are adjacent to each other. It is also possible that all six resonator regions 110 are connected in a straight line shape, but the resonator regions R2, R3, R3 and R2 are formed in a linear shape to form a filter in a compact structure, and input/output resonator regions are formed. (R1 and R1) may be vertically connected to the resonator regions R2 and R2. In the ceramic waveguide filter 10 of the present invention, since the resonators R1, R2 and R3 have different sizes, the spurious signal components of the filter are distributed without overlapping.

On the other hand, the resonance mode compensation groove 112 is to match the basic resonance mode. If there is no resonance mode compensation groove 112 in the ceramic waveguide filter 10 of the present invention, since the sizes of the resonator regions R1, R2, and R3 are different, the basic resonance modes do not coincide, so that the resonance frequencies do not approach. No frequency pass band is formed. Accordingly, the present invention is to form a frequency pass band by matching the basic resonance modes by forming the known mode compensation groove 112 in each of the resonator regions R1, R2 and R3. The basic resonance mode of the six resonators is determined by determining the dimensions for the depth and diameter (for a circular groove) or horizontal x vertical (for a square groove) of the resonance mode compensation grooves (RH1, RH2, RH3, RH4, RH5 and RH6). You can match. At this time, the depth of the resonance mode compensation groove 112 should be set to 50% or less of the height of the resonator region. If the depth of the resonance mode compensation groove 112 is too deep, the basic resonance mode is changed, and a problem such as deterioration of the Q value occurs. In addition, the size of the resonator region 110 can be reduced by forming the resonance mode compensation groove 112.

On the other hand, the ceramic dielectric block 100 has a notched resonator region 130 or N1. The notched resonator region N1 is formed adjacent to the input/output resonator region R1. The notch resonator region N1 may be connected to the input/output resonator region R1 by a narrower connection region, but the notch resonator region N1 is directly input/output resonator region R1 without a narrow connection region. It is preferred to be connected to. It is not necessary to employ a complicated structure because the former structure is inconvenient to manufacture.

1 and 2, in order to form a filter in a compact structure, input/output resonators and notch resonator arrays R1, N1, N1 and parallel to the linear resonator arrays (R2, R3, R3 and R2 arrays) R1 arrangement) is shown. The notch resonator region N1 is for forming a notch, that is, an attenuation pole, and is set differently in size from the input/output resonator region R1 for the same reason as mentioned above.

A notch adjustment groove 132 is formed in the notch resonator region N1. The notch adjustment groove 132 may be divided into a notch adjustment groove NH1 and a notch adjustment groove NH2. At this time, the depth and size of the notch adjustment groove NH1 and the notch adjustment groove NH2 may be formed the same or may be formed differently. The position of the attenuation pole can be adjusted by appropriately determining the depth and size of the notch adjustment groove NH1 and the notch adjustment groove NH2. The depth of the notch adjustment grooves NH1 and NH2 should be set to 50% or less of the height of the notch resonator region N1. The reason is as mentioned above.

On the other hand, the notch resonator region N1 is formed with through holes H1 and H2 for adjusting the notch resonance impedance adjacent to the notch adjustment grooves NH1 and NH2. The notch resonance impedance adjustment through holes H1 and H2 adjust the notch resonance impedance according to the distance away from the notch adjustment grooves NH1 and NH2 to adjust the intensity of attenuation poles generated by the notch resonance. The notch resonant impedance adjusting through-holes H1 and H2 also serve to fix the clasp in the electroplating process, so that the ceramic dielectric block 100 can be formed by electroplating.

Typically, a dipping plating method is employed to form a conductive metal layer on the ceramic dielectric block 100. However, this dipping plating method has a disadvantage in that it is difficult to uniformly form the thickness of the conductive metal layer as compared to the electroplating method, and it is difficult to economically perform because it has to be performed several times. Despite these disadvantages, the ceramic dielectric block 100 could not be applied to the electroplating method because it cannot be fixed with a clasp for the electroplating process. If the ceramic dielectric block 100 is electroplated by holding the clasp, the electroplating is not performed on the clasp, so that the electrical characteristics required by the filter cannot be satisfied.

Thus, the present invention is an electroplating process in which the clasp is caught in the opposite part 134-1 of the part facing the notch adjustment grooves NH1 and NH2 in the through holes H1 and H2 for adjusting the notch resonance impedance in the electroplating process. To enforce. Thus, even if the clasp is not plated on the 134-1, the electrical properties of the ceramic waveguide filter 10 of the present invention are not affected.

The ceramic waveguide filter 10 of the present invention may further include a multilayer printed circuit board 200 including a harmonic removal circuit, as shown in FIGS. 1 and 3. The harmonic removal circuit provided on the multilayer printed circuit board 200 acts as a harmonic removal filter to suppress spurious signal components. The multilayer printed circuit board 200 includes first and second surface layers 210 and 230 and an intermediate layer 220 that exists between the first and second surface layers 210 and 230, as shown in FIG. 3. . The ceramic dielectric block 100 is mounted on the first surface layer 210. As shown in FIG. 4, the intermediate layer 220 includes a pair of input/output terminals 221 and 222, a pair of connection terminals 223 and 224, and a harmonic removal circuit 226. A conductive metal layer is formed on the second surface layer 230.

The input/output terminals 221 and 222 take a signal input to the printed circuit board 200 or output a signal from the printed circuit board 200. The connection terminals 223 and 224 serve to input a signal from the printed circuit board 200 to the ceramic dielectric block 100 or to output a signal from the ceramic dielectric block 100 to the printed circuit board 200. The connection pin 150 is installed in the input/output resonator R1 region of the ceramic dielectric block 100 to allow signals to be input to or output from the ceramic dielectric block 100. The connection pin 150 is mounted in the input/output groove provided in the input/output resonator region R1 and slightly protrudes from the input/output groove. The connection pin 150 is electrically connected to the connection terminals 223 and 224 provided on the intermediate layer 220 of the multilayer printed circuit board 200. To this end, a through hole 212 is formed in the multilayer printed circuit board 200 from the first surface layer 210 to the intermediate layer 220. Accordingly, the connection terminals 223 and 224 are exposed by the through-hole 212 and can contact the connection pin 150 installed on the ceramic dielectric block 100.

According to this configuration, a signal is input to the printed circuit board 200 by the input/output terminal 221 formed on the intermediate layer 220 of the multilayer printed circuit board 200, and the connection terminal 223 and the connection pin 150 are connected. Through the ceramic dielectric block 100. The signal passing through the ceramic dielectric block 100 is output from the ceramic dielectric block 100 through the connection pin 150 and the connection terminal 224 and printed through the input/output terminal 222 after passing through the harmonic removal circuit 226. It is output from the circuit board 200. In this process, in the ceramic dielectric block 100, not only the frequency band pass is generated due to the basic resonance mode, but also the dispersion of the spurious signal component is made and the suppression of the spurious signal component occurs. In the above, the signal is input by the input/output terminal 221 and the signal is output by the input/output terminal 222. However, in the opposite case, the same function as described above is performed.

On the other hand, instead of forming the connecting pin 150 on the ceramic dielectric block 100 and forming the multilayer printed circuit board 200 in the above-described structure, it is described in Patent Registration No. 10-2041514 filed by the applicant of the present invention. It is also possible to apply a configuration of a multilayer printed circuit board and a ceramic dielectric block for input and output from and to a multilayer printed circuit board.

Referring to FIG. 5, the ceramic waveguide filter 10 of the present invention functions as a bandpass filter with a bandwidth of 1 to 2 sections around 3.5 GHz. Six resonance electrode characteristics can be confirmed by the reflection characteristic graph. The attenuation pole is formed adjacent to the passband frequency section due to the frequency characteristic of the notch resonator, which can be confirmed by the goal between the attenuation pole markers 7 to 5 and 6 to 8.

Referring to FIG. 6, the ceramic waveguide filter 10 of the present invention, which is not combined with multiple printed circuit boards 200 including the harmonic removal circuit 226, includes spurious or harmonic components in a frequency range of 6.2 GHz or higher. Can be confirmed. At this time, it can be seen that resonance mode components and harmonic components other than the basic resonance mode are dispersed without overlapping each other, and are moved to a high frequency band sufficiently farther than the frequency band (3.5 GHz band) of the basic resonance mode. Therefore, even if the ceramic waveguide filter 10 of the present invention is not combined with the multiple printed circuit board 200 including the harmonic removal circuit 226, the spurious characteristics are improved to some extent. However, since the spurious is hardly canceled at a frequency of 6.2 GHz or higher, it is necessary to be combined with the multiple printed circuit board 200 including the harmonic removal circuit 226, if necessary.

Referring to FIG. 7, the ceramic waveguide filter 10 of the present invention combined with multiple printed circuit boards 200 including a harmonic removal circuit 226 sufficiently suppresses spurious or harmonic components even in a frequency range of 6.2 GHz or higher. Can be confirmed.

10: ceramic waveguide filter 100: ceramic dielectric block
110,R1,R2,R3: Resonator area
112,RH1,RH2,RH3,RH4,RH5,RH6: Resonant mode compensation groove
120: connection area 130, N1: notch resonator area
132,NH1,NH2: Notch adjustment groove
134,H1,H2: Through hole for adjusting notch resonance impedance
134-1: Electroplating clasp fixing part
150: connecting pin 200: multi-layer printed circuit board
210: first surface layer 212: through hole
220: middle floor 221,222: input/output terminals
223,224: Connection terminal 226: Harmonic elimination circuit
230: second surface layer

Claims (10)

A ceramic waveguide filter comprising a ceramic dielectric block,
In the ceramic dielectric block, a plurality of resonator regions are connected by a narrower connection region, and a conductive metal layer is stacked on the surface of the ceramic dielectric block,
The resonator regions are divided into resonator regions of different sizes, and a resonant mode compensation groove is formed in the resonator regions to match the basic resonant modes, so that spurious signal components of the ceramic waveguide filter are dispersed and do not overlap.
A ceramic waveguide filter with improved spurious characteristics, characterized in that a frequency pass band is formed by matching the basic resonance modes of the resonators by determining the depth and diameter of the resonant mode compensation groove or the dimensions for the width and length. According to claim 1,
The depth of the resonance mode compensation groove is 50% or less of the height of the resonator region and the ceramic waveguide filter with improved spurious characteristics, characterized in that is set to 1% or more of the height of the resonator region. According to claim 2,
Among the resonator regions, a notch resonator region is formed in a size different from the input/output resonator region adjacent to the input/output resonator region, and the notch resonator region is provided with a notch adjustment groove, so that the filter forms an attenuation pole. Ceramic waveguide filter with improved spurious characteristics. According to claim 3,
The depth of the notch adjusting groove is 50% or less of the height of the notch resonator region and the ceramic waveguide filter with improved spurious characteristics, characterized in that is set to 1% or more of the height of the notch resonator region. According to claim 4,
A ceramic waveguide filter with improved spurious characteristics, characterized in that a through hole for adjusting the notch resonance impedance is formed in the notch resonator region adjacent to the notch adjustment groove. The method of claim 5,
The through hole for adjusting the notch resonant impedance is a ceramic waveguide filter with improved spurious characteristics, wherein the intensity of the attenuation pole caused by the notch resonance is controlled by adjusting the notch resonance impedance according to a distance away from the notch adjustment groove. The method of claim 6,
The through-hole for adjusting the notched resonant impedance serves to fix a clasp in an electroplating process, thereby allowing the ceramic dielectric block to be formed by electroplating, wherein the ceramic waveguide filter has improved spurious characteristics. The method of claim 7,
In the electroplating process, the clasp is caught in the opposite portion of the notch-adjusting groove in the through-hole for adjusting the resonant impedance, so that even if the clasp is not plated, the electrical characteristics of the filter are not affected. A ceramic waveguide filter with improved spurious characteristics. The method according to any one of claims 1 to 8,
The ceramic waveguide filter further comprises a multi-layer printed circuit board including a harmonic elimination circuit, wherein a spurious signal component is suppressed by the harmonic elimination circuit. The method of claim 9,
The multilayer printed circuit board includes first and second surface layers and three layers of an intermediate layer between the first and second surface layers, and the intermediate layer includes a pair of input/output terminals and the input/output resonator region of the ceramic dielectric block A ceramic waveguide filter with improved spurious characteristics, characterized in that a pair of connection terminals which are electrically connected to the connection pins installed in the formation is formed between the input and output terminals and one connection terminal.

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