KR100468303B1 - A dielectric filter and duplexer dielectric filter - Google Patents

Abstract

A dielectric filter and a duplexer dielectric filter are disclosed. In the dielectric filter and the duplexer dielectric filter of the present invention, an input stage resonator, an intermediate resonator and an output stage resonator are combined in a triangle form according to an elliptic function filter theory, and any one of an input stage resonator or an output stage resonator may be used. The stop band resonator is coupled to the resonator, and the stop band resonator is coupled to the intermediate resonator to modify the coupling relationship. In addition, the attenuation widening resonator group may be replaced in the input stage resonator or output stage resonator region to which the stop band resonator is coupled. According to the present invention, the cutoff frequency characteristics having a steeper inclination angle in the transition band band can be obtained through the expansion of the attenuation amplification resonator group and the stop band resonator, especially in the duplexer dielectric filter, thereby minimizing the interference of adjacent bands. However, efficient use of the bandwidth is possible. In addition, according to the compact shape, not only can be easily applied to products requiring miniaturization, but also can be used for repeaters and the like requiring high power.

Description

Dielectric filter and duplexer dielectric filter

TECHNICAL FIELD The present invention relates to a dielectric filter and a duplexer dielectric filter, and in particular, to achieve an in-band and out-band frequency characteristic as well as to obtain a frequency characteristic with a steep slope in the transition band, to realize the expansion and compact design of the coupled resonator. It relates to a dielectric filter and a duplexer dielectric filter capable of achieving this.

The role of a filter in a communication device is to select a signal of a desired frequency band, and the most ideal filter is a filter that passes only a signal of the desired frequency band without loss and removes all remaining signals. Therefore, the most important characteristics of the filter are a signal pass band, that is, an in-band characteristic that passes only a signal of a frequency band without loss and an out-band characteristic that removes the remaining frequency bands. I'm satisfied. Dielectric filters, such as those used in portable communication devices, are generally made by combining two or more dielectric resonators, for example a coaxial resonator or a re-entrant resonator, which resonates at a specific frequency. . The dielectric filter mainly determines the bandwidth, insertion loss, skirt and spurious frequency responses of the filter by the number of resonators constituting the filter and the coupling method. However, due to the limitation of the bandwidth in the currently allocated frequency, there is a need for a sudden attenuation of frequency components other than the passband frequency. That is, when filtering, the skirt which shows the electrical characteristic of the filter is required to be steep.

Existing dielectric filter has an input stage resonator and an output stage resonator coupled to any one of an input (In) or an output (Pro) probe interpolated into a vibration hole, and an intermediate resonator coupled between the input stage resonator and the output stage resonator. The basic configuration is a three-pole filter that combines columns or rows. In order to obtain a steep skirt frequency characteristic in one or both frequency bands from the dielectric filter configured as described above, a stop band resonator (BSR) may be coupled to one or both sides of the input stage resonator or the output stage resonator. As a result, a steep skirt frequency characteristic can be obtained at either side of the passband. As described above, the cut-off frequency characteristic in the stopband band among the in-band characteristics can be greatly improved by combining the stopband resonator with each of the input stage resonator and the output stage resonator as described above. However, there is a disadvantage that the insertion loss is increased by combining a plurality of resonators.

In order to solve this problem, the applicant of Patent Application No. 10-2001-0002523, by combining an input stage resonator and an output stage resonator and attaching an odd or even number of resonators to it, it is possible to obtain a steep skirt frequency characteristic at both sides or one side. In addition, a method to reduce insertion loss was presented. In this case, the elliptic function filter theory is applied. To apply the elliptic function theory to make an elliptic function filter, first, an array of resonators is connected so that the input stage resonator and the output stage resonator are coupled to each other. It must be correct and also find a suitable binding method for combining them. In addition, another requirement is that the elliptic coupling between the input stage resonator and the output stage resonator must be negative coupling. This can be satisfied by combining three resonators in a triangle.

In addition, in order to improve the frequency characteristics in both the in-band and the out-band, the applicant has not only been able to lower the insertion loss, which was a conventional problem in the "dielectric filter and duplexer dielectric filter" patent application No. 10-2001-0002523 In addition, the variation of the coupling characteristics between the resonator configuration of the dielectric filter and the stopband resonator also improves the skirt frequency characteristics and spurious frequency characteristics.

Then, a brief look at the prior art here.

1A and 1B are perspective and front views of a three-pole filter designed by an elliptic function filter theory that can reduce insertion loss while having a steep cutoff frequency characteristic on one side of the transition band. Referring to Figs. 1A and 1B, three coaxial resonators 1, 2, and 3 are configured to join each other. At this time, the input stage resonator 1 and the output stage resonator 3 are coupled to each other, and the coupling between the input stage resonator 1 and the output stage resonator 3 has a weak negative coupling. In other words, as shown in Fig. 1B, the elliptic negative coupling -k (1,3) is performed. In order to achieve this elliptic negative coupling, in the case of an odd number of resonators as shown, the input stage resonator 1 and the output stage resonator 3 must be coupled in the same direction, so that the negative elliptic tip coupling based on the elliptic function filter theory, -k (1,3) can be achieved. Input and output probes (Probe) are inserted into the input stage resonator (1) and the output stage resonator (3).

2A and 2B are graphs schematically showing frequency characteristics of the dielectric filter of FIG. 1. As shown in Figs. 2a and 2b, the frequency characteristics of the three-pole filter shown in Figs. 1a and 1b are compared to the frequency characteristics of the filter using a stopband resonator combined only in the conventional column or row form. At the same time, it exhibits a steep skirt frequency characteristic on one side of the transition bands on both sides of the passband. Here, the steep skirt frequency characteristics of the high or low transition frequency bands formed on the left and right sides of the passband can be adjusted by tuning the resonator shown in FIG. 1.

On the other hand, in order to obtain steep cutoff frequency characteristics in both stopbands of the passband, the number of resonators of the elliptic filter must be at least four. This can be confirmed through FIG. 3.

3A and 3B are a perspective view and a front view schematically showing a dielectric filter including a stop band resonator. 3A and 3B, three coaxial resonators 1, 2, and 3 are joined to each other, and as shown in FIG. 1, the input stage resonator 1 and the output stage resonator 3 are mutually connected. The coupling between the input stage resonator 1 and the output stage resonator 3 is weak. Here, the stop band resonator BSR is further coupled to the output stage resonator 3 in order to obtain a steep cutoff frequency characteristic in the other passband. According to the four-pole filter configured in this way, the input / output stage resonators 1 and 3 according to the elliptic function filter theory can achieve negative elliptic tip coupling, -k (1,3), and in both passbands. A steep cutoff frequency characteristic can be obtained. Coupling between each of the resonators and the coaxial resonators of each of the stop band resonators is accomplished through IRIS coupling. It is well known and proven by theory and experiment that this elliptic function filter exhibits a high rate of steep cutoff response in the transition band with low insertion loss.

In order to improve spurious frequency characteristics, the coupling direction of the intermediate resonator is reversed, or another resonator is combined to achieve this.

Meanwhile, in the case of the duplexer dielectric filter, since the dielectric filter is coupled to both sides of the antenna stage, the duplexer dielectric filter can be easily understood through the patent application No. 10-2001-0002523 which the applicant has proceeded. do.

4 is a graph illustrating the frequency characteristics output from the dielectric filter of FIG. 3, and FIG. 5 is a graph showing the frequency characteristics output from the duplexer dielectric filter manufactured by applying FIG. 3. As shown in FIGS. 4 and 5, it can be seen that the transition attenuation width is output as A with a predetermined bandwidth.

However, as described above, in order to overcome the limitation of the bandwidth, an alternative for outputting a skirt frequency characteristic having a steeper slope is required, as well as control thereof, and thus the present invention has been proposed. In addition, in the case of the duplexer dielectric filter proposed in the patent application No. 10-2001-0002523 filed by the present applicant, the present invention has been proposed to overcome the limitation of the compact manufacturing as the length increases.

Accordingly, an object of the present invention is to provide an intermediate resonator which is simultaneously coupled to an input stage resonator and an output stage resonator for selectively performing a role of a signal input or a signal output in a combined state of a triangular resonant period designed by an elliptic function filter theory. Incorporating a stop band resonator to obtain a skirt frequency characteristic, or increasing the attenuation width on an extension line connecting one of the input resonator and the output resonator and the resonant hole (H) respectively formed in the intermediate resonator coupled to the input and output resonator. On the basis of the dielectric filter in which the attenuation amplification resonator group is combined, two dielectric filters are combined to each of the transmitting and receiving dielectric filters in the manufacture of the duplexer dielectric filter which selectively performs the role of transmission and reception. To secure space for additional stopband resonator By further combining the attenuation amplification resonator at the time, a steep skirt frequency characteristic can be obtained, as well as a dielectric filter and a duplexer dielectric filter that can realize a compact design.

1A and 1B are a perspective view and a front view of a three-pole filter designed by the elliptic function filter theory,

2A and 2B are graphs schematically showing frequency characteristics of the dielectric filter of FIG. 1;

3A and 3B are a perspective view and a front view schematically showing a dielectric filter including a stop band resonator;

4 is a graph showing a frequency characteristic output from the dielectric filter of FIG.

FIG. 5 is a graph illustrating frequency characteristics output from a duplexer dielectric filter manufactured by applying FIG. 3. FIG.

6A and 6B are a perspective view and a plan view schematically showing a dielectric filter having a changed position of an input / output stage resonator;

7A and 7B are a perspective view and a plan view schematically showing a dielectric filter incorporating a stop band resonator in a state where an input / output stage resonator is changed;

8A to 8C are graphs schematically showing frequency characteristics of the dielectric filter of FIG.

9A to 9C are a perspective view and a plan view schematically showing a dielectric filter according to a first embodiment of the present invention;

10A to 10D are graphs schematically showing frequency characteristics of the dielectric filter of FIG. 9;

11A to 11C are a top perspective view, a bottom perspective view, a plan view of an integrated dielectric filter;

12 is an application example of the dielectric filter of FIG.

13A to 13C are a top perspective view, a bottom perspective view, a plan view, showing an integrated dielectric filter according to a second embodiment of the present invention;

14 is an application example of the dielectric filter of FIG.

15 is a modification of the dielectric filter of FIG.

16 is an application example of FIG.

17A to 17C are views illustrating an integrated duplexer dielectric filter manufactured using the integrated dielectric filter shown in FIG. 11;

18 is a graph showing the frequency characteristics of the duplexer dielectric filter shown in FIG.

19 is an application example of the duplexer dielectric filter of FIG.

20A to 20C illustrate a top perspective view, a bottom perspective view, and a plan view of a duplexer dielectric filter in which two stop band resonators are formed on both sides of a receiver and a transmitter, respectively, as a third embodiment of the present invention;

21A and 21B are graphs schematically showing frequency characteristics of the duplexer dielectric filter of FIG. 20;

22 is an application example of FIG. 20;

23 is a modification of FIG. 20,

24 is an application example of FIG.

25 is a plan view schematically showing a dielectric filter in which attenuation amplification resonator groups are formed;

26 is a graph showing the frequency characteristics of the dielectric filter shown in FIG.

27 is an application example of FIG. 25;

28 is a plan view illustrating a duplexer dielectric filter manufactured using the dielectric filter shown in FIG. 25;

29 is an application example of FIG. 28;

30 is a modification of FIG. 28,

31 is an application example of FIG.

32 is a graph schematically illustrating the frequency characteristics of FIGS. 28 to 31;

33 is a plan view showing a dielectric filter according to a fourth embodiment of the present invention;

34 is a graph schematically showing a frequency characteristic of the dielectric filter of FIG. 33;

35 is an application example of FIG.

36 is a plan view showing a duplexer dielectric filter according to a fifth embodiment of the present invention;

37A and 37B are graphs schematically showing frequency characteristics of the duplexer dielectric filter of FIG. 36;

38 is an application example of FIG. 36;

39 shows an example in which the attenuation amplification resonator group is expanded.

Explanation of symbols on the main parts of the drawings

# 1: input stage resonator # 2: intermediate resonator

BSR: Stop Band Resonator # 3: Output Stage Resonator

# 3-1: Medium resonator GE: Common electrode

CE: Coupling electrode IE: Input terminal electrode

OE: Output electrode AE: Antenna electrode

TE: Transmitting electrode RE: Receiving electrode

The present invention is applied to a dielectric filter composed of a resonator having a resonant hole (H) having a penetrating coaxial or one-sided open corner shape. The dielectric filter of the present invention for achieving the object of the present invention includes a signal input. An input stage resonator # 1 coupled to the input stage; An intermediate resonator (# 2) coupled to and coupled to the input stage resonator (# 1); An output stage resonator (# 3) coupled to the intermediate resonator (# 2) and simultaneously coupled with the input stage resonator (# 1); A first stop band resonator (BSR) coupled to any one of the input stage resonator (# 1) or output stage resonator (# 3); And a second stop band resonator (BSR) coupled to the intermediate resonator (# 2).

In this case, the input stage resonator # 1 or the output stage resonator # 3 region is coupled to the input stage resonator # 1 and the intermediate resonator # 2 in order to increase the attenuation width of the frequency characteristic. 1 medium resonator (# 3-1); An output stage resonator coupled to the first intermediate resonator # 3-1 and the output stage; In addition, the attenuated amplification resonator group consisting of at least one second intermediate resonator (# 3-2) formed and coupled between the first intermediate resonator (# 3-1) and the output stage resonator is optionally provided. It is also preferable to make it. At this time, the input stage resonator # 1 and the first intermediate resonator # 3-1 are in the same direction so that a negative coupling is made between the input stage resonator # 1 and the first intermediate resonator # 3-1. Coupled between the input stage resonator # 1 and the first intermediate resonator # 3-1 so that the coupling between the input stage resonator # 1 and the first intermediate resonator # 3-1 is weakly compared with that between other resonators; An inductor coupling groove ICH may be formed between the resonators # 3-1.

In addition, at least one resonator of the input stage resonator # 1, the intermediate resonator # 2, the output stage resonator # 3, and the stop band resonator BSR has a shape of the resonance hole H in comparison with the other resonators. It is preferable that they are different from each other, and it is more preferable that the intermediate resonator # 2 has a coupling direction opposite to that of the other resonators.

In the case where each resonator is manufactured separately, an iris is formed on each of the resonant period bonding surfaces so that adjacent resonant period coupling can be performed, or when the dielectric of each resonator is integrally formed. The coupling electrode is patterned on one surface of the open resonance hole (H) region formed in each of the resonators so that each resonance period coupling can be performed, and the region except for the patterned portion is coated by the common electrode. .

The dielectric filter made up of a separate resonator includes an intermediate resonator # 2 having a resonant hole H formed laterally in a central portion thereof; At least one intermediate resonator (# 3-1) having a resonance hole (H) formed laterally at a central portion thereof on one side parallel to the resonance hole (H) of the intermediate resonator (# 2), and the intermediate resonator On one side surface parallel to the resonant hole (H) of (# 3-1), an attenuation widened resonator group consisting of an output stage resonator having a probe is provided in contact with the resonant hole (H) formed in the transverse direction at the center thereof; A stop band resonator (BSR) having a resonant hole (H) formed in a transverse direction at a central portion thereof is provided in contact with one side parallel to the resonant hole (H) of the output stage resonator; A stop band resonator (BSR) having a resonant hole (H) formed laterally in a central portion thereof is provided on one side surface parallel to the resonant hole (H) of the intermediate resonator (# 2); In addition, the upper end of the contact portion between the intermediate resonator (# 3-1) and the input stage resonator (# 1) is formed by coupling the input stage resonator (# 1) having a probe to the resonance hole (H) formed in the transverse direction at the center thereof. .

On the other hand, a dielectric filter composed of an integrally formed resonator includes a second coupling electrode in a dielectric filled therein, and an intermediate portion of the second coupling electrode having a resonant hole H formed laterally in a central portion of the second coupling electrode. A resonator # 2 is formed; At one end of the intermediate resonator # 2, a coupling electrode of one of the third coupling electrode groups is provided, and at the center of the coupling electrode, a medium resonator having a resonance hole H formed in the transverse direction (# 3-). 1) and one coupling electrode of the third coupling electrode group are provided at one end of the intermediate resonator # 3-1, and the resonance hole H formed in the transverse direction is formed at the center of the coupling electrode. An attenuation wide amplification resonator group including an output end resonator having an output end electrode OE disposed adjacent to the coupling electrode at one side of the dielectric spaced apart from the coupling electrode; A fourth coupling electrode is provided at one end of the output stage resonator spaced apart from the output terminal electrode OE, and a stop band resonator BSR having a resonant hole H formed in the transverse direction is provided at the center of the fourth coupling electrode. Integrally formed; A resonance formed on a side surface of the intermediate resonator # 2 and the intermediate resonator # 3-1, one surface of which is provided with a first coupling electrode, and a central portion of the first coupling electrode formed in a transverse direction; A hole H is formed, and an input terminal resonator # 1 having an input terminal electrode IE is formed at one side of the dielectric spaced apart from the first coupling electrode; A fifth coupling electrode is provided at one end of the intermediate resonator (# 2), and a stop band resonator (BSR) having a resonance hole (H) formed in the transverse direction is integrally formed at the center of the fifth coupling electrode. do.

At this time, between the coupling electrodes formed between the other resonators such that the coupling between the coupling electrode formed in the intermediate resonator among the first coupling electrode and the third coupling electrode group is weakly compared with the coupling between the other resonators. Compared to the opposing distance, the opposing distance between the first coupling electrode and the coupling electrode formed in the intermediate resonator is made far or reduced. In addition, to adjust the coupling force of the second coupling electrode of the intermediate resonator (# 2) coupled to the first coupling electrode of the input stage resonator (# 1) and the coupling electrode of the intermediate resonator formed in the attenuation amplification resonator group To this end, the first coupling electrode has an opposing surface including both opposing surface forming regions of the second coupling electrode and the coupling electrode of the intermediate resonator.

Meanwhile, the present invention relates to a duplexer dielectric filter in which a dielectric filter including a resonator having a penetrating coaxial or one-sided resonant hole is symmetrically coupled to both sides about an antenna end. A transmitter-side input stage resonator # 1 coupled to an antenna stage for performing signal input / output with the device; A transmission-side intermediate resonator (# 2) coupled to and coupled to the transmission-side input stage resonator (# 1); A transmission-side output stage resonator (# 3) coupled to the transmission-side intermediate resonator (# 2) and negatively coupled to the transmission-side input stage resonator (# 1); A transmission-side first stop band resonator (BSR) coupled to either the transmission-side input stage resonator or the transmission-side output stage resonator; And a transmission-side second stop band resonator (BSR) coupled to the transmission-side intermediate resonator (# 2).

An output stage resonator (# 1 ') coupled to the antenna stage; A receiving side intermediate resonator (# 2 ') coupled to and coupled to the receiving side output stage resonator (# 1'); A receiver input stage resonator (# 3 ') coupled with the receiver intermediate resonator (# 2') and negatively coupled with the receiver output stage resonator (# 1 '); A receiving side first stop band resonator BSR 'coupled to any one of the receiving side output stage resonator # 1' or the receiving side input stage resonator # 3 '; And a receiving side second stop band resonator (BSR ') coupled to the receiving side intermediate resonator (# 2').

At this time, in order to increase the attenuation width of the frequency characteristic at each of the transmitting side and the receiving side, the transmitter-side input stage resonator # 1, the output stage resonator # 3, and the receiver-side output stage of the second dielectric filter of the first dielectric filter. The transmitter-side first intermediate resonator (# 3) in which the transmitter-side input stage resonator (# 1) and the transmitter-side intermediate resonator (# 2) are coupled to and coupled to a resonator (# 1 ') or input stage resonator (# 3') region. -1) and a receiving side first resonator # 3-1 'to which the receiving side output stage resonator # 1' and the receiving side intermediate resonator # 2 'are coupled and coupled; The transmitter-side first resonator # 3-1 and the transmitter-side output stage are coupled to provide a transmitter-side output stage resonator, and the receiver side first resonator # 3-1 'and the receiver input stage are coupled. Providing a receiver side input stage resonator coupled and coupled; And at least one transmitting side second resonator coupled between the transmitting first intermediate resonator and the transmitting side output resonator and optionally provided, and coupled between the receiving first intermediate resonator and the receiving input resonator. It is also preferably formed by forming at least one second receiving medium-side resonator ring and optionally provided. At this time, for each of the first dielectric filter and the second dielectric filter, between the transmitting side input stage resonator # 1 and the transmitting side first resonator # 3-1, the receiving side output stage resonator # 1 ' ) And the transmitting side first stage resonator (# 1), the transmitting side first intermediate resonator (# 3-1), and the receiving side output stage such that negative coupling is performed between It is preferable that the resonator # 1 'and the receiving side first intermediate resonator # 3-1' are coupled in the same direction. Further, for each of the first dielectric filter and the second dielectric filter, between the transmitting side input stage resonator # 1 and the transmitting side first resonator # 3-1, the receiving side output stage resonator # 1 '. The transmitter-side first stage resonator # 1 and the transmitter-side first intermediate resonator # 3 so that the coupling between the receiver and the first side resonator # 3-1 'is weakly coupled as compared with the coupling between the other resonators. -1) It is also preferable that an inductor coupling groove is formed between the receiving output stage resonator # 1 'and the receiving first intermediate resonator # 3-1'.

Further, for each of the first dielectric filter and the second dielectric filter, the transceiver side input stage resonators # 1 and # 1 ', the transceiver side intermediate resonators # 2 and # 2', and the transceiver side output stage resonators # 3, # 3 '), at least one of the resonators in the transmission / reception side stop band resonators BSR and BSR' may have a different shape from the remaining resonators and the resonance holes, and for each of the first dielectric filter and the second dielectric filter, The transmission and reception side resonators # 2 and # 2 'may have opposite coupling directions as compared with the remaining resonators.

In addition, when the dielectric of each resonator is integrally formed with respect to the first dielectric filter and the second dielectric filter, the coupler is coupled to an open resonance hole region formed in each of the resonators so that coupling of each resonant period is possible. The ring electrode is patterned, and an area except for the patterned portion is coated by a common electrode.

When the duplexer dielectric filter is manufactured as described above, the second coupling electrode is provided in the dielectric filled therein, and the center portion of the second coupling electrode has the resonant hole H formed in the transverse direction. A transmitting side resonator # 2 is formed; One transmitting electrode of the third coupling electrode group is provided at one end of the transmitting-side intermediate resonator # 2, and a transmitting-side intermediate resonator having a resonance hole H formed in the transverse direction at the center of the coupling electrode. (# 3-1) and one coupling electrode of the third coupling electrode group are provided at one end of the transmitter-side resonator # 3-1, and the central portion of the coupling electrode is formed in the transverse direction. The resonance hole H is formed, and on one side of the dielectric separated from the coupling electrode, a transmission side attenuation amplification resonator group consisting of a transmission side output stage resonator having a transmission end electrode TE adjacent to the coupling electrode is integrated. Formed; A fourth coupling electrode is provided at one end spaced apart from the transmission end electrode TE of the transmission-side output stage resonator, and the transmission-side first stop has a resonance hole H formed in the transverse direction at the center of the fourth coupling electrode. The band resonator BSR is integrally formed; It is formed on the side between the transmitting intermediate resonator (# 2) and the transmitting side intermediate resonator (# 3-1), one surface is provided with a first coupling electrode, the central portion of the first coupling electrode in the transverse direction A resonance hole (H) formed in the first and second sides of the dielectric spaced apart from the first coupling electrode is provided with a transmission side input stage resonator (# 1) having an antenna electrode (AE); A fifth coupling electrode is provided at one end of the transmission-side intermediate resonator # 2, and a transmission-side second stop band resonator having a resonance hole H formed in the transverse direction is formed at the center of the fifth coupling electrode. A first dielectric filter integrally formed with BSR); and

A seventh coupling electrode is provided in the dielectric filled therein, and a receiving side intermediate resonator # 2 'having a resonant hole H formed in the transverse direction is formed in the center of the seventh coupling electrode; One receiving electrode of the eighth coupling electrode group is provided at one end of the receiving side intermediate resonator # 2 ', and has a receiving side parameter having a resonance hole H formed in the transverse direction at the center of the coupling electrode. One end of the eighth coupling electrode group is provided at one end of the resonator # 3-1 'and the receiving side medium resonator # 3-1', and the central portion of the coupling electrode is in the transverse direction. And a receiving side attenuation amplification resonator comprising a receiving side input stage resonator having a receiving end electrode RE adjacent to the coupling electrode at one side of the dielectric spaced from the coupling electrode. The groups are formed integrally; A ninth coupling electrode is provided at one end spaced apart from the receiving end electrode RE of the receiving side input resonator, and the first stop of the receiving side has a resonance hole H formed in a lateral direction at the center of the ninth coupling electrode. The band resonator BSR 'is integrally formed; It is formed on the side between the receiving side intermediate resonator (# 2 ') and the receiving side intermediate resonator (# 3-1'), the one side is provided with a sixth coupling electrode, the central portion of the sixth coupling electrode A resonance hole H formed in the lateral direction is formed, and a receiving side output stage resonator # 1 ′ having an antenna electrode AE is formed at one side of the dielectric spaced apart from the sixth coupling electrode; One end of the receiving intermediate resonator (# 2 ') is provided with a tenth coupling electrode, and the receiving end second stop band resonator having a resonance hole (H) formed in the transverse direction in the center of the tenth coupling electrode And a second dielectric filter integrally formed with (BSR '), wherein the first dielectric filter and the second dielectric filter are integrally formed so that one end thereof, that is, the first coupling electrode and the sixth coupling electrode are in contact with each other. And the junction portion is provided with an antenna electrode (AE).

At this time, between the coupling electrode of the intermediate resonator in the first coupling electrode and the third coupling electrode group, and between the coupling electrode of the intermediate resonator in the sixth coupling electrode and the eighth coupling electrode group. Among the first coupling electrode and the third coupling electrode group, the coupling electrode of the intermediate resonator is compared with the opposing distance between the coupling electrodes formed between the other resonators so that the coupling is weakly compared with the coupling between the other resonators. And a transmitting side of the sixth coupling electrode and the eighth coupling electrode group, which increases the distance between the coupling electrodes of the intermediate resonator or reduces the mutually opposing area, or which is coupled with the first coupling electrode of the transmitting side input resonator. In order to adjust the coupling force between the second coupling electrode of the intermediate resonator and the coupling electrode of the mediated resonator formed in the transmission side attenuation amplification resonator group, the first coupling electrode is the second coupling electrode. The seventh coupling electrode and the receiving side of the receiving intermediate resonator coupled to the sixth coupling electrode of the receiving output stage resonator while forming an opposite surface including all of the opposite surface forming regions of the coupling electrode of the intermediate resonator; The sixth coupling electrode includes both opposing surface forming regions of the seventh coupling electrode and the coupling electrode of the intermediate resonator in order to adjust the coupling force of the intermediate resonator formed in the attenuation amplification resonator group. The opposite surface is formed.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

First, in the description of the drawings of the present invention, the same reference numerals are assigned to components that perform the same function, and the same concepts will be omitted for repeated and repeated description.

Although the input stage resonator # 1 and the output stage resonator # 3 proposed in this embodiment are performed by complementarily interlocking respective functions of an input or an output according to the input / output of the signal, they are projected for convenience of description. The resonator in the region is defined and described as an input stage resonator # 1 through which signals are input.

6A and 6B are a perspective view and a plan view schematically showing a dielectric filter having a changed position of an input / output stage resonator. 6A and 6B show that the input stage resonator # 1 is coupled to the existing intermediate resonator # 2 at the position of the existing intermediate resonator # 2, and the intermediate resonator ## is positioned at the existing input / output stage resonators # 1 and # 3. It can be seen that 2) is located. Here, in the case of a hexahedral resonator, a slight deformation may be made in the coupling form. However, when the resonator is manufactured in a cylindrical shape, the resonator is rotated around the joint coupling points of the three resonators. The concept is combined. That is, this is to make it easier to understand the coupling form to be described later through the comparison of FIG. At this time, although the positions of the input / output stage resonators # 1 and # 3 and the intermediate resonator # 2 are deformed, an elliptic function filter is provided between the input stage resonator # 1 and the output stage resonator # 3. According to the theory, negative coupling -k (1,3) is achieved as shown in FIG. 6B. Frequency characteristics appearing in the dielectric filter configured as described above are similar to those of FIG. 2. In other words, a steep skirt frequency characteristic can be obtained from one side of the transition bands on both sides. As in the prior art, the steep skirt frequency characteristics of the high or low transition frequency bands appearing on the left and right sides of the passband can be adjusted by tuning the resonator shown in FIG.

7A and 7B are a perspective view and a plan view schematically illustrating a dielectric filter incorporating a stop band resonator in a state where an input / output stage resonator is changed. 7A and 7B are also comparative examples with FIG. 3 for explaining a coupling relationship which is subsequently coupled as in FIG. 6. As shown in FIGS. 7A and 7B, the input stage resonator # 1 is coupled to the existing intermediate resonator # 2, and the intermediate resonator # 2 at the existing input / output stage resonators # 1 and # 3. It can be seen that the stop band resonator (BSR) is selectively coupled to the input and output stage resonators (# 1, # 3). As in FIG. 6, in the case of a hexahedral resonator, a slight deformation may be made in the coupling shape. However, when the resonator is manufactured in a cylindrical shape, the resonator is rotated about a joint point, and thus the same concept as in FIG. 3. It can be said to be combined. As shown in FIG. 3, a negative coupling -k (1,3) is formed between the input stage resonator # 1 and the output stage resonator # 3 as shown in FIG. 8B according to an elliptic function filter theory.

8A to 8C are graphs schematically showing frequency characteristics of the dielectric filter of FIG. 7. As shown in FIG. 8A, steep skirt frequency characteristics may be obtained in both transition bands, and by tuning the resonator, steep cutoff frequency characteristics may be obtained in one passband as illustrated in FIGS. 8B and 8C. As shown, it can be seen that the transition attenuation width is output as A with a constant bandwidth in all of these frequency characteristics. It shows the skirt frequency characteristic at one side by input stage resonator (# 1), intermediate resonator (# 2), and output stage resonator (# 3) combined by elliptic function filter theory, and on the other side by stopband resonator (BSR). The skirt frequency characteristic is shown. As shown in FIGS. 8B and 8C, a skirt frequency characteristic by an elliptic function filter and a skirt frequency characteristic by a stop band resonator (BSR) may be formed at one side to obtain a steeper skirt frequency characteristic. It should not be overlooked here that the inclination in the transition band band in Fig. 8A and the inclination in the transition band band in Figs. 8B and 8C are different even though the attenuation width is output as A equally. That is, in order to prevent overlapping with other frequencies in the transition band according to the application characteristic, it means that the slopes in FIGS. 8B and 8C may be required.

9A to 9C are perspective and plan views schematically illustrating a dielectric filter according to a first embodiment of the present invention. 9A to 9C are dielectric filters in which one more stop band resonator (BSR) is coupled with respect to FIG. 7. Conventional stop band resonator (BSR) is usually coupled to the input stage resonator (# 1) or output stage resonator (# 3) was coupled to the input and output stage resonators (# 1, # 3), in the present invention, the stop band resonator (BSR) is coupled to one of the resonators of the input and output stage resonators (# 1, # 3) to form a coupling, the other stopband resonator (BSR) is coupled to the intermediate resonator (# 2) This is done. That is, a coupling concept of a new concept of coupling the stop band resonator BSR to the intermediate resonator # 2 is made. The dielectric filter shown in FIGS. 6 and 7 is the same as the coupling relationship of the existing dielectric filter, while FIG. 9 shows a new coupling relationship in which the intermediate resonator # 2 and the stop band resonator BSR are coupled. . Although it may be determined that the stop band resonator (BSR) is simply coupled to the intermediate resonator (# 2), its structure is not only a coupling relationship necessary for compactly manufacturing the duplexer dielectric filter described below, Through the deformation, the skirt frequency characteristic having a sharper slope can be obtained, and the output power can be increased.

Meanwhile, as shown in FIG. 9C, the inductor coupling groove ICH may be formed in the resonance hole H or the junction portion of the resonance period to adjust the resonance period coupling strength. This can be applied to both the duplexer dielectric filter as well as the dielectric filter.

10A to 10D are graphs schematically showing frequency characteristics of the dielectric filter of FIG. 9. As shown in FIGS. 10A and 10B, one or two skirt frequency characteristics may be obtained in each transition band by resonator tuning, or one side transition may be obtained by resonator tuning as shown in FIGS. 10C and 10D. Three skirt frequency characteristics can be obtained in the band. As such, it can be seen that the elliptic function filter and the skirt frequency characteristic enhancement factors of the two stop band resonators (BSR) can be arbitrarily adjusted in the transition band through tuning.

Although the resonators of the dielectric filters shown in FIGS. 6, 7, and 9 are all composed of coaxial resonators, they may also be configured as yaw resonators. The resonator is coated with a metal material except for the surface where the input and output probes are inserted. Here, the resonator used in the embodiment described later including the first embodiment has a hexahedron shape, but is not limited thereto. In addition, since these resonators are separately manufactured, the coupling of each resonance period is performed through the IRIS coupling. In particular, as described above, the input stage resonator # 1 and the output stage resonator # 3 are negatively coupled. In addition, by combining the coaxial resonator and the resonant resonator at an arbitrary position, the spurious frequency characteristic, which is an outband characteristic, can be improved, and the higher-order mode harmonics including the second harmonic can be suppressed. In addition, the same effect can be expected to be improved by coupling the resonator in the opposite coupling direction.

11A to 11C show a top perspective view, a bottom perspective view, and a plan view of the integrated dielectric filter, respectively. 11A to 11C, the integrated dielectric filter shown in FIG. 9 is manufactured by integrally manufacturing the dielectric filter shown in FIG. 9. The difference from the dielectric filter shown in FIG. 9 is that the resonance hole H is formed in the integrated dielectric. The coupling electrode CE connected to the resonance hole H is patterned to an arbitrary size on the upper surface, and the side and bottom surfaces thereof are coated with the common electrode GE. Here, the input terminal electrode (IE) and the output terminal electrode (OE) for input and output of the signal are formed adjacent to the coupling electrode (CE), the adjacent region of the output stage resonator (# 3) and the stop band resonator (BSR), It is formed in the input stage resonator (# 1) region protruding to one side. As such, by forming the coupling electrode CE and the input / output end electrodes IE and OE on the upper surface, the process of powder pressing, electrode patterning, and the like, which is subsequently performed, becomes very simple, and thus the process is easy. The number of processes can be reduced.

On the other hand, the integral dielectric filter shown in Figure 11 is formed integrally and may be said to be slightly different in shape, but basically a stop band resonator to any one resonator selected from the input stage resonator (# 1) or output stage resonator (# 3) A dielectric filter having the same concept as that of FIG. 7 in which (BSR) is coupled, is presented as a comparative example for distinguishing a difference from a dielectric filter to be performed later.

FIG. 12 is an application example of the dielectric filter of FIG. 11, but in FIG. 11, all the resonators have been described with a dielectric filter including a coaxial resonator. However, in this application example, a coaxial resonator and a resonant resonator may be selectively used. It is shown that they can be combined at any position by combining them. In addition, the coupling direction of the resonator may be reversed for coupling. As a result, not only the spurious frequency characteristic, which is an outband characteristic, but also the high order mode harmonic including the second harmonic can be suppressed.

13A to 13C are a top perspective view, a bottom perspective view, and a plan view showing an integrated dielectric filter according to a second embodiment of the present invention. 13A to 13C, the integrated dielectric filter according to the second embodiment is a dielectric filter to which one stop band resonator (BSR) is coupled as compared with FIG. 11, and the dielectric filter shown in FIG. 9 is integrated. It is a dielectric filter formed. The integrated dielectric filter presented in the second embodiment has the following differences. That is, when two stop band resonators (BSR) are coupled to an existing dielectric filter, they are usually coupled to an input stage resonator (# 1) or an output stage resonator (# 3), respectively, and coupled to the input / output stage resonators (# 1, # 3). Although this has been done, in the present invention, the stop band resonator (BSR) is coupled to one of the resonators of the input and output stage resonators (# 1, # 3), the coupling is made, the other stopband resonator (BSR) Coupling is performed in combination with the intermediate resonator # 2. In other words, the stop band resonator BSR is formed on an extension line connecting any one selected from the input resonator # 1 or the output resonator # 3 and the resonance hole H formed in the intermediate resonator # 2, respectively. It is made by combining. The dielectric filter shown in FIG. 11 may be similar to the existing dielectric filter because the coupling relationship is similar because only the outer shape of the existing dielectric filter is modified. However, the dielectric filter shown in FIG. 13 has a stop band resonator (BSR) as an intermediate resonator. Since it is combined with (# 2), it has a coupling relationship that cannot be obtained by modifying the shape of an existing dielectric filter. This coupling relationship is not only a coupling relationship necessary for compactly manufacturing the duplexer dielectric filter described below, but also a skirt frequency characteristic having a sharper slope can be obtained through the deformation of this coupling relationship, and the output power can be increased. have. FIG. 14 is an application example of the dielectric filter of FIG. 13 and is the same as the intention of FIG.

FIG. 15 is a modified example of the dielectric filter of FIG. 13, except that the shape of the input resonator protruding to one side is tapered in an arbitrary region as compared with FIG. 13. The deformed input stage resonator # 1 includes a coupling electrode CE formed in the output stage resonator # 3 and the intermediate resonator # 2, and the coupling electrode CE of the input stage resonator # 1 is tapered. It is formed. That is, the coupling electrode CE has a trapezoidal shape. This is to easily adjust the strength of the coupling between each resonator. In the present modified example, the tapered case is described, but it may be manufactured in a semicircle to make the manufacturing process easier. FIG. 16 shows that another resonator may be combined as the application example of FIG. 15. Since this is the same concept as in FIGS. 12 and 14, repeated descriptions thereof will be omitted.

Hereinafter, the duplexer dielectric filter will be described. In the description of the duplexer dielectric filter, each resonator should be described by applying the dielectric filter shown in FIG. 6 described above. However, the duplexer dielectric filter is most preferable and described from the integrated duplexer dielectric filter in consideration of ease of fabrication. Shall be. Of course, it is well known that the above-described dielectric filters shown in FIGS. 6, 7, and 9 can be applied to both the duplexer dielectric filter. In the duplexer dielectric filter of the present invention, the dielectric filter is symmetrically formed. Therefore, in the description of the reference numeral, the duplexer dielectric filter is distinguished from the dielectric filter in the form of a reference numeral (reference numeral). This reference numeral shall be indicated only when necessary.

17A to 17C illustrate an integrated duplexer dielectric filter manufactured by using the integrated dielectric filter shown in FIG. 11. 17A to 17C, the integrated duplexer dielectric filter illustrated in FIG. 17 is an input stage resonator in which two dielectric filters illustrated in FIG. 11 are symmetrically integrated in one body and a signal is input and output from each dielectric filter. # 1) or the output stage resonator # 3 are adjacent to each other and the antenna electrode AE is formed in these combined regions. That is, the antenna electrode AE is formed between the coupling electrodes CE adjacent to each other by combining the dielectric filters. Accordingly, the transmitting end electrode TE is formed on one side of the antenna electrode AE, and the receiving side electrode RE is formed on the other side of the transmitting end electrode TE. This duplexer dielectric filter is also an example presented for comparison with the embodiments described later, since the results can be similar to that of FIG. 11 when only the dielectric filters formed on both sides of the antenna electrode AE are observed.

In the duplexer dielectric filter, the coupling electrode CE is formed on the front surface of the duplexer dielectric filter, and the top, side, bottom and back surfaces thereof are coated with the common electrode GE.

18 is a graph showing the frequency characteristics of the duplexer dielectric filter shown in FIG. As shown in FIG. 5, this shows the cutoff frequency characteristics in the transition bands on both sides of the pass band in each of the transmission frequency band and the reception frequency band, or as shown in FIG. 18, the cutoff frequency characteristics can be formed to one side. Yes is the same as the dielectric filter presented in the above embodiment. It is possible to obtain a steep cutoff frequency characteristic in the transition band on one side of the passband through the input stage resonator (# 1), the intermediate resonator (# 2), and the output stage resonator (# 3), and the stopband resonator (BSR) Through this, the steep cutoff frequency characteristic of the transition band of one side is obtained, and it means that the frequency characteristic of the transition band band can be adjusted by tuning.

FIG. 19 is a diagram showing that another resonator may be combined as an application example of the duplexer dielectric filter of FIG. Since this is the same concept as in FIGS. 12, 14, and 16, repeated description will be omitted. Here, the transmitting end electrode TE, the receiving end electrode RE, and the antenna electrode AE may be coupled to or separated from the adjacent coupling electrode CE, and may be modified in various shapes to control the coupling strength. have. It is well known that this applies to both the dielectric filter and the duplexer dielectric filter presented herein.

20A to 20C illustrate a top perspective view, a bottom perspective view, and a plan view of a duplexer dielectric filter in which two stop band resonators (BSRs) are formed on both sides of a receiver and a transmitter, respectively, as a third embodiment of the present invention. The difference between the duplexer dielectric filter shown in the third embodiment is that the stop band resonator (BSR) is coupled to the intermediate resonator (# 2) at each of the transmitting end and the receiving end, as compared with the duplexer dielectric filter shown in FIG. This is an embodiment showing that the stop band resonator (BSR) is easily extended to the duplexer dielectric filter, and the structure of the present invention satisfies both the expandability and the compact structure.

21A and 21B are graphs schematically illustrating frequency characteristics of the duplexer dielectric filter of FIG. 20. As shown in FIG. 21, one or two skirt frequency characteristics may be obtained in each transition band in each of a transmission band and a reception band. In addition to the frequency characteristics shown, three skirt frequency characteristics can be obtained in one transition band by resonator tuning. The result of the frequency characteristic is the frequency characteristic in the transition band band through the elliptic function filter and the skirt frequency characteristic enhancement factor of two stop band resonators (BSR). FIG. 22 is a view showing that another resonator may be combined as an example of application of FIG. 20. Since this is the same concept as FIGS. 12, 14, 16, and 19, repeated description is omitted. FIG. 23 is a modified example of FIG. 20. As shown in FIG. 23, the shape of the adjacent input stage resonator # 1 or the output stage resonator # 3 is tapered on one side as compared with the duplexer dielectric filter shown in FIG. Formed is different. This is to easily adjust the strength of the coupling between each resonator. FIG. 24 is a view showing that another resonator may be combined as an example of application of FIG. 23. Since this is the same concept as FIG. 12, FIG. 14, FIG. 16, FIG. 19 and FIG. 22, repeated description is omitted.

Next, the dielectric filter and the duplexer dielectric filter for increasing the attenuation width to have a sharper slope in the skirt frequency characteristics appearing in the dielectric filter and the duplexer dielectric filter will be described. Hereinafter, the perspective view may sufficiently flow out through the plan view, and thus only the plan view will be described.

25 is a plan view schematically showing a dielectric filter in which attenuation amplification resonator groups are formed. As shown in FIG. 25, two resonators, that is, a medium resonator # 3-1 and an output stage resonator # 3-2, are located in the output stage resonator # 3 region of FIG. 11 compared to the dielectric filter shown in FIG. The difference is that the attenuation amplification resonator group consisting of) is formed. That is, the intermediate resonator (# 3-1) is coupled with the input stage resonator (# 1) and the intermediate resonator (# 2), and the output stage resonator (# 3-2) and the intermediate resonator (# 3-1) Coupling is performed on the input / output end electrodes IE and OE. The input stage resonator # 1 and the intermediate resonator # 3-1 have negative elliptic tip coupling -k (1, 3-1) based on the elliptic function filter theory, and are also provided in one or both transition band bands. By reducing the attenuation width than the dielectric filter shown in Fig. 11, a steeper cutoff frequency characteristic can be obtained. However, this dielectric filter, too, may be said to have been deformed in the external shape, but since the coupling relationship of each resonance period is the same, it is an example for comparison with the dielectric filter to be achieved by the present invention.

FIG. 26 is a graph illustrating the frequency characteristics of the dielectric filter illustrated in FIG. 25. As shown in FIG. 26, the cutoff attenuation width B is clearly different from the conventional cutoff attenuation width A at a high rate in the transition bands on both sides of the passband. Through this, a cutoff frequency characteristic having a steeper slope can be obtained. It is possible to obtain a steep cutoff frequency characteristic in the transition band on one side of the passband through the input stage resonator (# 1), the intermediate resonator (# 2), and the intermediate resonator (# 3-1). Through this, a steep cutoff frequency characteristic of the other transition band can be obtained, and a steep inclination angle of the cuffoff frequency characteristic can be obtained through the attenuation amplification resonator group. It is well known that frequency characteristics similar to those of 8b and 8c can be obtained. FIG. 27 is a view showing that another resonator may be combined as an example of the application of FIG. 25. Since this is the same concept as FIGS. 12, 14, 16, 19, 22, and 24, repeated description is omitted.

FIG. 28 is a plan view illustrating a duplexer dielectric filter manufactured using the dielectric filter shown in FIG. 25. This configuration is made by combining the dielectric filters of each of the transmitting side and the receiving side constituting the duplexer dielectric filter, each of which includes a group of attenuation amplification resonators. This, too, can be said that the deformation of the external shape of the duplexer dielectric filter, but the coupling relationship is the same for each resonant period is an example for comparison with the duplexer dielectric filter of the present invention described below. FIG. 29 is a diagram showing that another resonator may be combined as an example of the application of FIG. 28. Since this is the same concept as FIGS. 12, 14, 16, 19, 22, 24, and 27, repeated description is omitted. FIG. 30 is a modified example of FIG. 28, in which the shapes of the adjacent input stage resonator # 1 or the output stage resonator # 3-2 are tapered on one side, compared to the duplexer dielectric filter shown in FIG. 28. This is to easily adjust the strength of the coupling between each resonator as described above. FIG. 31 shows that another resonator can be combined as the application example of FIG. 30. Since this is the same concept as FIGS. 12, 14, 16, 19, 22, 24, 27, and 29, repeated description thereof will be omitted.

32 is a graph schematically illustrating the frequency characteristics of FIGS. 28 to 31. As shown, steep cutoff frequency characteristics can be obtained in the transition band bands on both sides of the passband for each of the transmitting side and the receiving side, and all of the skirt frequency characteristics may appear on one side. In any case, by further improving the attenuation width B, a steeper inclination angle can be obtained.

33 is a plan view showing a dielectric filter according to a fourth embodiment of the present invention. As shown in FIG. 33, it can be seen that one more stop band resonator (BSR) is formed in the dielectric filter of FIG. 25. That is, the stop band resonator BSR is coupled to the intermediate resonator # 2 to form a coupling. The dielectric filter shown in FIG. 25 may be similar to the existing dielectric filter because the coupling relationship is similar to the existing dielectric filter only by deforming the external shape of the existing dielectric filter. However, the dielectric filter shown in the fourth embodiment is a stop band resonator (BSR). ) Is coupled with the intermediate resonator (# 2), and has a coupling relationship that cannot be obtained by modifying the shape of the existing dielectric filter. The coupling relationship is not only a coupling relationship necessary for compactly manufacturing the duplexer dielectric filter described below, but also a skirt frequency characteristic having a sharper slope can be obtained through the deformation of the coupling relationship.

FIG. 34 is a graph schematically showing frequency characteristics of the dielectric filter of FIG. As shown in FIG. 34, one or two skirt frequency characteristics may be obtained in each transition band by resonator tuning, or similar results may be obtained in FIGS. 10C and 10D. However, it can be seen that the attenuation width has a size of B as compared with FIG. 10. In other words, a skirt frequency characteristic result having a steeper slope can be obtained. FIG. 35 is a view showing that another resonator may be combined as the application example of FIG. 33. Since this is the same concept as FIGS. 12, 14, 16, 19, 22, 24, 27, 29 and 31, repeated description thereof will be omitted.

36 is a plan view illustrating a duplexer dielectric filter according to a fifth embodiment of the present invention. The duplexer dielectric filter shown in this embodiment is different from the duplexer dielectric filter shown in FIGS. 28 to 31 in that the stop band resonator BSR is coupled to the transmitting and receiving intermediate resonators # 2, respectively. have. This duplexer dielectric filter increases attenuation width and has three skirt frequency characteristics.

37A and 37B are graphs schematically illustrating frequency characteristics of the duplexer dielectric filter of FIG. 36. As shown in FIGS. 37A and 37B, one or two skirt frequency characteristics may be obtained in each transition band in each of a transmission band and a reception band. In addition, as the attenuation width is increased to B, a steeper skirt frequency characteristic can be obtained. In addition to the frequency characteristics shown, three skirt frequency characteristics can be obtained in one transition band by resonator tuning. The result of the frequency characteristic is arbitrarily adjusted in the transition band through the elliptic function filter and the skirt frequency characteristic improvement factor of two stop band resonators (BSR). FIG. 38 shows that another resonator can be combined as the application example of FIG. 36. Since this is the same concept as FIGS. 12, 14, 16, 19, 22, 24, 27, 29, 31, and 35, repeated description thereof will be omitted.

39 is a plan view schematically showing a dielectric filter in which a group of three attenuation amplification resonators is formed. As illustrated in FIG. 39, three resonators, that is, the first parasitic resonator # 3-1 and the second parasitic resonator (# 3-1) and the second parasitic resonator (# 3-1), are located in the output stage resonator # 3 region of FIG. The difference is that the attenuation widening resonator group consisting of # 3-2) and the output stage resonator # 3-3 are formed. This shows that the attenuation amplification resonator group can be composed of multiple resonators. Here, it is well known that the second intermediate resonators # 3-2 and # 3-2 'are formed on the transmitting side and the receiving side, respectively, when the duplexer dielectric filter is manufactured using FIG. 39. Is omitted.

As described above, according to the present invention, not only the resonator coupled to the transmitting and receiving dielectric filters including the dielectric filter, especially in the case of the duplexer dielectric filter, is free, but also the compact design is possible despite the expansion. There is this. The expansion of the resonator, that is, the expansion of the attenuation width amplification resonator group and the stop band resonator can obtain a skirt frequency characteristic having a steeper slope in the transition band band, thereby making it possible to efficiently use a limited band. In addition, it is also possible to improve the outband characteristics by changing the configuration of the resonator or by adjusting the coupling relationship.

As a result, a cutoff frequency characteristic having a steep inclination angle can be obtained, thereby minimizing interference of adjacent bands and efficiently utilizing the bandwidth. In addition, according to the compact shape, not only can be easily applied to products requiring miniaturization, but also can be used for repeaters and the like requiring high power.

The present invention is not limited to the above-described embodiment, and it will be apparent that many modifications are possible by those skilled in the art within the technical spirit of the present invention.

Claims (22)

In the dielectric filter made of a resonator having a penetrating coaxial or one-side opening resonant hole (H), An input stage resonator # 1 coupled to an input terminal on which a signal is input; An intermediate resonator (# 2) coupled to and coupled to the input stage resonator (# 1); An output stage resonator (# 3) coupled to the intermediate resonator (# 2) and simultaneously coupled with the input stage resonator (# 1); A first stop band resonator (BSR) coupled to any one of the input stage resonator (# 1) or output stage resonator (# 3); And A second stop band resonator (BSR) coupled to the intermediate resonator (# 2); Dielectric filter, characterized in that consisting of. The input stage resonator (# 1) or the output stage resonator (# 3) region is coupled to the input stage resonator (# 1) and the intermediate resonator (# 2) in order to increase the attenuation width of the frequency characteristic. A first intermediate resonator # 3-1 to be ringed; An output stage resonator coupled to the first intermediate resonator # 3-1 and the output stage; In addition, the attenuated amplification resonator group consisting of at least one second intermediate resonator (# 3-2) formed and coupled between the first intermediate resonator (# 3-1) and the output stage resonator is optionally provided. A dielectric filter characterized in that. The input stage resonator (# 1) and the first intermediate resonator (# 3-1) according to claim 2, wherein a negative coupling is made between the input stage resonator (# 1) and the first intermediate resonator (# 3-1). Dielectric filter, characterized in that coupled in the same direction. The input stage resonator (# 1) and the first stage resonator (# 1) and the first intermediate resonator (# 3-1) is coupled to the input stage resonator (# 1) and the first so that the coupling is weak compared to the coupling between the other resonators A dielectric filter formed by forming an inductor coupling groove ICH between a first intermediate resonator # 3-1. The at least one resonator of the input resonator (# 1), the intermediate resonator (# 2), the output resonator (# 3), the stop band resonator (BSR) is compared with the other resonators (H). A dielectric filter, characterized in that the shape of) different from each other. 6. The dielectric filter according to claim 1 or 5, wherein the intermediate resonator (# 2) has a coupling direction opposite to that of the other resonators. The dielectric filter according to claim 1, wherein an iris is formed on each of the resonant period bonding surfaces so that adjacent resonant period coupling can be performed when the resonators are manufactured separately. The coupling electrode of claim 1, wherein a coupling electrode is formed on one surface of an open resonant hole (H) region formed in each of the resonators so that the resonant coupling may be performed when the dielectric of each resonator is integrally formed. And patterning and coating a region excluding the patterned portion with a common electrode. An intermediate resonator # 2 having a resonance hole H formed laterally in the central portion thereof; At least one intermediate resonator (# 3-1) having a resonance hole (H) formed laterally at a central portion thereof on one side parallel to the resonance hole (H) of the intermediate resonator (# 2), and the intermediate resonator On one side surface parallel to the resonant hole (H) of (# 3-1), an attenuation widened resonator group consisting of an output stage resonator having a probe is provided in contact with the resonant hole (H) formed in the transverse direction at the center thereof; A stop band resonator (BSR) having a resonant hole (H) formed in a transverse direction at a central portion thereof is provided in contact with one side parallel to the resonant hole (H) of the output stage resonator; A stop band resonator (BSR) having a resonant hole (H) formed laterally in a central portion thereof is provided on one side surface parallel to the resonant hole (H) of the intermediate resonator (# 2); And The upper end of the contact portion between the intermediate resonator (# 3-1) and the input stage resonator (# 1) formed by coupling the input stage resonator (# 1) having a probe to the resonance hole (H) formed in the transverse direction at the center thereof A dielectric filter characterized by the above-mentioned. A second coupling electrode is provided in the dielectric filled therein, and an intermediate resonator # 2 having a resonant hole H formed in the transverse direction is formed in the center of the second coupling electrode; At one end of the intermediate resonator # 2, a coupling electrode of one of the third coupling electrode groups is provided, and at the center of the coupling electrode, a medium resonator having a resonance hole H formed in the transverse direction (# 3-). 1) and one coupling electrode of the third coupling electrode group are provided at one end of the intermediate resonator # 3-1, and the resonance hole H formed in the transverse direction is formed at the center of the coupling electrode. An attenuation wide amplification resonator group including an output end resonator having an output end electrode OE disposed adjacent to the coupling electrode at one side of the dielectric spaced apart from the coupling electrode; A fourth coupling electrode is provided at one end of the output stage resonator spaced apart from the output terminal electrode OE, and a stop band resonator BSR having a resonant hole H formed in the transverse direction is provided at the center of the fourth coupling electrode. Integrally formed; A resonance formed on a side surface of the intermediate resonator # 2 and the intermediate resonator # 3-1, one surface of which is provided with a first coupling electrode, and a central portion of the first coupling electrode formed in a transverse direction; A hole H is formed, and an input terminal resonator # 1 having an input terminal electrode IE is formed at one side of the dielectric spaced apart from the first coupling electrode; A fifth coupling electrode is provided at one end of the intermediate resonator (# 2), and a stop band resonator (BSR) having a resonance hole (H) formed in the transverse direction is integrally formed at the center of the fifth coupling electrode. Dielectric filter, characterized in that. 12. The coupler of claim 10, wherein the coupling between the first coupling electrode and the coupling electrode formed in the intermediate resonator of the third coupling electrode group is weakly coupled as compared with the coupling between the other resonators. And a distance between the first coupling electrode and the coupling electrode formed in the intermediate resonator or reducing the mutually opposite area compared with the distance between the ring electrodes. 11. The method of claim 10, wherein the second coupling electrode of the intermediate resonator (# 2) coupled with the first coupling electrode of the input stage resonator (# 1) and the coupling electrode of the intermediate resonator formed in the attenuation width amplification resonator group And the first coupling electrode has an opposing surface including both opposing surface forming regions of the second coupling electrode and the coupling electrode of the intermediate resonator to adjust the bonding force. A duplexer dielectric filter in which a dielectric filter including a resonator having a penetrating coaxial or one-sided resonant hole is symmetrically coupled to both sides about an antenna end, A transmitter-side input stage resonator # 1 coupled to an antenna stage for performing signal input / output with the device; A transmission-side intermediate resonator (# 2) coupled to and coupled to the transmission-side input stage resonator (# 1); A transmission-side output stage resonator (# 3) coupled to the transmission-side intermediate resonator (# 2) and negatively coupled to the transmission-side input stage resonator (# 1); And A transmission-side first stop band resonator (BSR) coupled to either the transmission-side input stage resonator or the transmission-side output stage resonator; A first dielectric filter comprising: a transmission-side second stopband resonator (BSR) coupled to the transmission-side intermediate resonator # 2; and An output stage resonator (# 1 ') coupled to the antenna stage; A receiving side intermediate resonator (# 2 ') coupled to and coupled to the receiving side output stage resonator (# 1'); A receiver input stage resonator (# 3 ') coupled with the receiver intermediate resonator (# 2') and negatively coupled with the receiver output stage resonator (# 1 '); And A receiving side first stop band resonator BSR 'coupled to any one of the receiving side output stage resonator # 1' or the receiving side input stage resonator # 3 '; A second dielectric filter comprising: a receiving side second stop band resonator BSR 'coupled to the receiving side intermediate resonator # 2'; Duplexer dielectric filter, characterized in that consisting of. The method of claim 13, wherein the transmission-side input stage resonator # 1, the output stage resonator # 3, and the second dielectric filter of the first dielectric filter in order to increase the attenuation width of the frequency characteristic at each of the transmitting side and the receiving side, respectively. In the receiving output stage resonator (# 1 ') or input stage resonator (# 3') area, The transmitter-side first resonator (# 3-1) coupled to the transmitter-side input stage resonator (# 1) and the transmitter-side intermediate resonator (# 2) are coupled, and the receiver side output stage resonator (# 1 ') Providing a receiving-side first intermediate resonator # 3-1 'to which the receiving-side intermediate resonator # 2' is coupled and coupled; The transmitter-side first resonator # 3-1 and the transmitter-side output stage are coupled to provide a transmitter-side output stage resonator, and the receiver side first resonator # 3-1 'and the receiver input stage are coupled. Providing a receiver side input stage resonator coupled and coupled; And At least one transmitting side second resonator which is coupled between the transmitting first side resonator and the transmitting side output resonator and optionally provided, and coupled between the receiving first first resonator and the receiving side resonator And at least one or more receiving side second intermediate resonators, optionally provided. 15. The apparatus of claim 14, wherein for each of the first dielectric filter and the second dielectric filter, between the transmitting side input stage resonator # 1 and the transmitting side first resonator # 3-1, the receiving side output stage resonator ( # 1 ') and the transmitter-side first stage resonator # 1 and the transmitter-side first intermediate resonator # 3-1 so that negative coupling is performed between the first side resonator # 3-1' and the receiving side first resonator # 3-1 '. A duplexer dielectric filter, characterized in that the receiving side output stage resonator (# 1 ') and the receiving side first intermediate resonator (# 3-1') are coupled in the same direction. 15. The apparatus of claim 14, wherein for each of the first dielectric filter and the second dielectric filter, between the transmitting side input stage resonator # 1 and the transmitting side first resonator # 3-1, the receiving side output stage resonator ( # 1 ') and the transmitting side first stage resonator # 1 and the transmitting side first parameter such that the coupling between the receiving side first resonator # 3-1' is weakly coupled compared to the coupling between other resonators. A duplexer dielectric filter formed by forming an inductor coupling groove between a resonator (# 3-1), the receiver side output stage resonator (# 1 ') and the receiver side first resonator (# 3-1'). The transmitter / receiver input stage resonator (# 1, # 1 '), the transceiver side intermediate resonator (# 2, # 2'), and the transceiver side output stage resonator for each of the first dielectric filter and the second dielectric filter. (# 3, # 3 '), at least one resonator in the transmission / reception side stop band resonators (BSR, BSR') is characterized in that the remaining resonator and the shape of the resonance hole is different from each other. The method of claim 13 or 17, wherein for each of the first dielectric filter and the second dielectric filter, the transmission and reception side intermediate resonators (# 2, # 2 ') has a coupling direction opposite to the other resonators. A duplexer dielectric filter, characterized in that. 14. The open resonance of claim 13, wherein the first dielectric filter and the second dielectric filter have an opening resonance formed in each of the resonators so that coupling of the respective resonant periods is possible when the dielectric of each resonator is integrally formed. A duplexer dielectric filter comprising patterning a coupling electrode in a hole region and applying a region except for the patterned portion to a common electrode. A second coupling electrode is provided in the dielectric filled therein, and a transmission-side intermediate resonator # 2 having a resonant hole H formed in the transverse direction is formed in the center of the second coupling electrode; One transmitting electrode of the third coupling electrode group is provided at one end of the transmitting-side intermediate resonator # 2, and a transmitting-side intermediate resonator having a resonance hole H formed in the transverse direction at the center of the coupling electrode. (# 3-1) and one coupling electrode of the third coupling electrode group are provided at one end of the transmitter-side resonator # 3-1, and the central portion of the coupling electrode is formed in the transverse direction. The resonance hole H is formed, and on one side of the dielectric separated from the coupling electrode, a transmission side attenuation amplification resonator group consisting of a transmission side output stage resonator having a transmission end electrode TE adjacent to the coupling electrode is integrated. Formed; A fourth coupling electrode is provided at one end spaced apart from the transmission end electrode TE of the transmission-side output stage resonator, and the transmission-side first stop has a resonance hole H formed in the transverse direction at the center of the fourth coupling electrode. The band resonator BSR is integrally formed; It is formed on the side between the transmitting intermediate resonator (# 2) and the transmitting side intermediate resonator (# 3-1), one surface is provided with a first coupling electrode, the central portion of the first coupling electrode in the transverse direction A resonance hole (H) formed in the first and second sides of the dielectric spaced apart from the first coupling electrode is provided with a transmission side input stage resonator (# 1) having an antenna electrode (AE); A fifth coupling electrode is provided at one end of the transmission-side intermediate resonator # 2, and a transmission-side second stop band resonator having a resonance hole H formed in the transverse direction is formed at the center of the fifth coupling electrode. A first dielectric filter integrally formed with BSR); and A seventh coupling electrode is provided in the dielectric filled therein, and a receiving side intermediate resonator # 2 'having a resonant hole H formed in the transverse direction is formed in the center of the seventh coupling electrode; One receiving electrode of the eighth coupling electrode group is provided at one end of the receiving side intermediate resonator # 2 ', and has a receiving side parameter having a resonance hole H formed in the transverse direction at the center of the coupling electrode. One end of the eighth coupling electrode group is provided at one end of the resonator # 3-1 'and the receiving side medium resonator # 3-1', and the central portion of the coupling electrode is in the transverse direction. And a receiving side attenuation amplification resonator comprising a receiving side input stage resonator having a receiving end electrode RE adjacent to the coupling electrode at one side of the dielectric spaced from the coupling electrode. The groups are formed integrally; A ninth coupling electrode is provided at one end spaced apart from the receiving end electrode RE of the receiving side input resonator, and the first stop of the receiving side has a resonance hole H formed in a lateral direction at the center of the ninth coupling electrode. The band resonator BSR 'is integrally formed; It is formed on the side between the receiving side intermediate resonator (# 2 ') and the receiving side intermediate resonator (# 3-1'), the one side is provided with a sixth coupling electrode, the central portion of the sixth coupling electrode A resonance hole H formed in the lateral direction is formed, and a receiving side output stage resonator # 1 ′ having an antenna electrode AE is formed at one side of the dielectric spaced apart from the sixth coupling electrode; One end of the receiving intermediate resonator (# 2 ') is provided with a tenth coupling electrode, and the receiving end second stop band resonator having a resonance hole (H) formed in the transverse direction in the center of the tenth coupling electrode And a second dielectric filter integrally formed with (BSR '), The first dielectric filter and the second dielectric filter are integrally formed such that one end thereof, that is, the first coupling electrode and the sixth coupling electrode are in contact with each other, and the junction portion is provided with an antenna electrode AE. Duplexer dielectric filter. 21. The method of claim 20, wherein the coupling electrode of the medium resonator is arranged between the coupling electrode of the medium resonator in the first coupling electrode and the third coupling electrode group. The coupling of the intermediate resonator among the first coupling electrode and the third coupling electrode group in comparison with the opposing distance between the coupling electrodes formed between the other resonators so that the coupling between the couplings is weakly compared with the coupling between the other resonators. A duplexer dielectric filter, characterized in that the distance between the ring electrodes, the coupling electrode of the intermediate resonator among the sixth and eighth coupling electrode groups is increased or the mutually reduced area is reduced. 21. The coupling force according to claim 20, wherein the coupling force between the second coupling electrode of the transmission-side intermediate resonator coupled to the first coupling electrode of the transmission-side input stage resonator and the coupling electrode of the intermediate resonator formed in the transmission-side attenuation amplification resonator group In order to adjust, the first coupling electrode forms an opposing surface including both opposing surface forming regions of the second coupling electrode and the coupling electrode of the intermediate resonator, and at the same time, a sixth couple of the output stage resonator of the receiving side. In order to adjust the coupling force between the seventh coupling electrode of the receiving side intermediate resonator coupled to the ring electrode and the coupling electrode of the intermediate resonator formed in the receiving side attenuation amplification resonator group, the sixth coupling electrode is connected to the seventh coupler. A duplexer dielectric filter formed by forming an opposing surface including all of the opposing surface forming regions of a ring electrode and a coupling electrode of an intermediate resonator.