KR100468302B1 - A dielectric filter and duplexer dielectric filter - Google Patents

Abstract

A dielectric filter and a duplexer dielectric filter are disclosed. The dielectric filter of the present invention is formed by combining at least one elliptic function filter with the remaining resonators except for the resonator through which the input and output of signals are performed in the elliptic function filter in which the resonator is coupled in a triangle form according to the elliptic function filter theory. The duplexer dielectric filter forms two or more coupled dielectric filters around the antenna electrode on the transmitting side and the receiving side, respectively. According to the present invention, by connecting a plurality of elliptic function filters having a skirt frequency characteristic factor to manufacture a dielectric filter and a duplexer dielectric filter, a steeper frequency characteristic can be obtained in the transition band band, and an insertion loss can be prevented from increasing. In addition, there is an advantage that a compact design can be designed.

Description

Dielectric filter and duplexer dielectric filter

The present invention relates to a dielectric filter and a duplexer dielectric filter, and more particularly, to a dielectric filter and a duplexer dielectric filter capable of compact design design while achieving a steeper frequency characteristic in a transition band band and reducing insertion loss.

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 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 the input stage resonator and the output stage resonator one by one 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.

Then, a brief look at the prior art here.

1 is a perspective view showing an integrated dielectric filter manufactured according to the elliptic function filter theory. As shown in FIG. 1, a dielectric filled therein is formed, and a resonance hole (H) is formed in the dielectric, and three resonance holes (H) are formed in a triangle at a predetermined interval and all in the transverse direction. Let's do it. The coupling electrode CE is patterned on the upper surface of each of the resonance hole H regions for coupling the resonance period, and all regions except the patterned portion are coated with the common electrode GE. In this case, the coupling electrode CE, the inner wall of the resonance hole H, and the common electrode GE are integrally connected. Functionally, the input stage resonator (# 1), the intermediate resonator (# 2), the output stage resonator (# 3), the intermediate resonator (# 2) between the input stage resonator (# 1) and output stage resonator (# 3) It is coupled to one side.

Meanwhile, an input terminal electrode IE and an output terminal electrode OE through which signals are input and output are formed adjacent to the coupling electrode CE. In this case, the input end electrode IE and the output end electrode OE are complementary in function, and thus the input end electrode IE may perform the function of the output end electrode OE, and is linked to the output end electrode OE. ) Serves as the input terminal electrode IE. Accordingly, the region where the coupling electrode CE adjacent to the input terminal electrode IE through which the signal is input serves as the input terminal resonator # 1, and the coupling electrode CE adjacent to the output terminal electrode OE is formed. The area serves as the output stage resonator (# 3). Like the input end electrode IE and the output end electrode OE, the input end resonator # 1 and the output end resonator # 3 have a complementary function, and the input end electrode IE and the output end electrode OE have a signal. By performing any one function in the input / output relationship of the input stage resonator (# 1) and the output stage resonator (# 3) to perform a complementary function.

Coupling electrodes CE are formed in each resonator region as described above, and these coupling electrodes CE are spaced apart from each other and patterned. At this time, the input stage resonator # 1 and the output stage resonator # 3 may be negatively coupled according to the elliptic function filter theory, that is, the input stage resonator may be weakly coupled as compared with the coupling between other resonators. The opposing distance between the coupling electrode CE formed in the region of # 1) and the output stage resonator # 3 is increased or the mutually opposing area is reduced.

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 3-pole filter shown in FIG. 1 have an insertion loss compared to that of a filter in which a stop band resonator (BSR) is coupled to a conventional column or row type. At the same time, it shows a steep skirt frequency characteristic on one side of the transition bands on both sides of the passband and attenuation width is A. Here, A is an arbitrary value for comparison of the attenuation width described later. On the other hand, the steep skirt frequency characteristics of the high or low transition frequency band formed on the left and right sides of the passband can be adjusted by tuning the resonator shown in FIG.

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 function filter must be at least four. This can be confirmed through FIG. 3.

3 is a perspective view of a dielectric filter incorporating an intermediate resonator for increasing attenuation width to an integrated dielectric filter manufactured according to the elliptic function filter theory. Referring to FIG. 3, it can be seen that one more medium resonator # 4 is coupled to the dielectric filter shown in FIG. 1. The medium resonator # 4 is located in the input stage resonator # 1 region of FIG. 1. As a result, the input stage resonator # 1 is formed at one side thereof. The intermediate resonator # 4 is a resonator that mediates the input and output of signals to adjacent resonators, and serves to increase attenuation width in frequency characteristics. In addition, the intermediate resonator # 4 has negative coupling with the output stage resonator # 3 among the resonators coupled in a triangle form according to the elliptic function filter theory.

4A and 4B are graphs schematically showing frequency characteristics of the dielectric filter of FIG. 3. 4A and 4B, it can be seen that the attenuation width A1 is increased compared to the results shown in FIGS. 2A and 2B. As a result, a skirt frequency characteristic having a steeper slope in the transition band band can be obtained.

By the way, in order to obtain a steeper frequency characteristic in the transition band band, the method of increasing the above-mentioned intermediate resonator # 4 has been proposed. However, the disadvantage that the insertion loss increases due to the length of the dielectric filter is increased. In addition, as the length increases, there is a limit to the compact design design. In addition, in order to obtain a steep skirt frequency characteristic at both sides of the transition band band, a stop band resonator coupled to the input end electrode IE or the output end electrode OE simultaneously in the region of the input end resonator # 1 or the output end resonator # 3. BSR) is coupled, but when the stop band resonator (BSR) is coupled in a long length state as described above, the insertion loss increases as it is combined in the form of a row or column like the intermediate resonator (# 4). Occurs.

The same problem occurs even when a duplexer dielectric filter in which the dielectric filter configured as described above is symmetrically coupled around the antenna electrode in the state having such a problem.

Accordingly, an object of the present invention is to combine the input stage resonator, the intermediate resonator and the output stage resonator in a triangle form to obtain a steeper frequency characteristic in the transition band band, to compensate for the disadvantage that the insertion loss increases, and to enable a compact design design The present invention provides at least two elliptic function filters, that is, a dielectric filter combining an input side elliptic function filter for inputting a signal and an output side elliptic function filter for outputting a signal.

In addition, an object of the present invention is to combine the input stage resonator, the intermediate resonator and the output stage resonator in the form of a triangle to obtain a steeper frequency characteristic in the transition band band, to compensate for the disadvantage that the insertion loss is increased, and to enable a compact design design An elliptic function filter in which at least two elliptic function filters are provided to combine a transmitting-side dielectric filter for transmitting signals, and an input stage resonator, an intermediate resonator, and an output stage resonator in a triangle form. The present invention provides a duplexer dielectric filter in which at least two c) s are coupled to a receiving side dielectric filter in which a signal is received, centered around an antenna electrode.

1 is a perspective view showing an integrated dielectric filter manufactured according to the elliptic function filter theory;

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

3 is a perspective view of a dielectric filter incorporating one more medium resonator for increasing attenuation in an integrated dielectric filter manufactured according to the elliptic function filter theory;

4A and 4B are graphs schematically showing frequency characteristics of the dielectric filter of FIG. 3;

5A and 5B are top and bottom perspective views showing a dielectric filter according to a first embodiment of the present invention;

6a and 6b are graphs showing the frequency characteristics of the dielectric filter shown in FIGS. 5a and 5b;

7A and 7B are top and bottom perspective views showing a dielectric filter according to a second embodiment of the present invention;

8 is a graph showing the frequency characteristics of the dielectric filter shown in FIGS. 7A and 7B;

9 is a plan view showing a dielectric filter according to a third embodiment of the present invention;

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

11 is a plan view showing an integrated duplexer dielectric filter according to a fourth embodiment of the present invention;

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

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

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

15 is a plan view showing an integrated duplexer dielectric filter according to a sixth embodiment of the present invention;

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

17 is a plan view showing an integrated duplexer dielectric filter according to a seventh embodiment of the present invention;

18 is a plan view showing an integrated dielectric filter in accordance with an eighth exemplary embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

# 1: input stage resonator # 2: intermediate resonator

# 3: output stage resonator # 4: intermediate resonator

BSR: Stop Band Resonator

CE: Coupling Electrode GE: Common Electrode

IE: Input electrode OE: Output electrode

TE: Transmitting electrode RE: Receiving electrode

AE: Antenna electrode

The present invention for achieving the above object of the present invention relates to a dielectric filter composed of a resonator having a resonant hole (H) of the penetrating coaxial or one-sided opening angle, the dielectric filter of the present invention, the input of the signal An input stage resonator # 1 coupled to the input stage, a first intermediate resonator # 2 coupled to and coupled to the input stage resonator # 1, and a couple with the first intermediate resonator # 2. A first elliptic function filter (10) comprising a first intermediate resonator (# 4-1) which is ringed and has a negative coupling with the input stage resonator (# 1); And a second intermediate resonator # 4-2 coupled to the intermediate resonator # 4-1, and a second intermediate resonator # 2 coupled to and coupled to the second intermediate resonator # 4-2. ) And a second elliptic function filter comprising an output stage resonator (# 3) coupled to the second intermediate resonator (# 2) and simultaneously coupled to the second intermediate resonator (# 4-2). 20); characterized in that consisting of.

At this time, it is preferable that at least one or more intermediate resonators are further formed between the first intermediate resonator # 4-1 and the second intermediate resonator # 4-2.

In addition, the input stage resonator # 1 and the first intermediate resonator # 4-1 are in the same direction so that negative coupling is made between the input stage resonator # 1 and the first intermediate resonator # 4-1. Coupled and the second intermediate resonator (# 4-2) and the output stage resonator (# 3) in the same direction so that a negative coupling is made between the second intermediate resonator (# 4-2) and the output stage resonator (# 3). Are combined.

In addition, the input stage resonator # 1 and the first intermediate resonator # 1 are coupled so that the coupling between the input stage resonator # 1 and the first intermediate resonator # 4-1 is weakly coupled as compared with the coupling between other resonators. It is possible to form an inductor coupling groove ICH between # 4-1), and the coupling between the second intermediate resonator # 4-2 and the output stage resonator # 3 is coupled with the coupling between the other resonators. In comparison, an inductor coupling groove ICH may be formed between the second intermediate resonator # 4-2 and the output stage resonator # 3 so as to be weakly coupled.

On the other hand, it is also preferable to further combine the stop band resonator (BSR) that is selectively coupled to the input terminal or output terminal.

When the dielectric of each resonator is integrally formed, the coupling electrode is patterned on one surface of an open resonance hole (H) region formed in each of the resonators so that coupling between the resonators may occur. A region except for the patterned portion is applied by applying a common electrode.

Specifically, the dielectric filter composed of a resonator formed integrally includes a first coupling electrode in a dielectric filled therein, and has a resonant hole H formed laterally in a central portion of the first coupling electrode. An input end resonator # 1 having an input end electrode IE adjacent to the coupling electrode is formed at one side of the dielectric spaced apart from the first coupling electrode; A coupling electrode of one of the coupling electrode groups adjacent to one end of the input stage resonator # 1 is provided, and a first intermediate resonator (#) having a resonance hole H formed in a transverse direction in the center of the coupling electrode. 4-1) and another coupling electrode of the adjacent coupling electrode group are provided at one end of the first intermediate resonator # 4-1, and the resonance hole H formed in the transverse direction is formed at the center of the coupling electrode. A second intermediate resonator (# 4-2) having () is formed; A third coupling electrode is provided at one end of the second intermediate resonator # 4-2, and a resonance hole H formed in a transverse direction is formed at the center of the coupling electrode, and spaced apart from the coupling electrode. An output stage resonator # 3 having an output terminal electrode OE disposed adjacent to the coupling electrode on one side of the dielectric; It is formed on the side between the input stage resonator (# 1) and the first intermediate resonator (# 4-1), one side thereof is provided with a coupling electrode, the central portion of the coupling electrode formed in the transverse direction (resonance hole ( A first intermediate resonator # 2 having H) formed thereon; It is formed on the side between the second intermediate resonator (# 4-2) and the output stage resonator (# 3), the coupling electrode is provided on one surface, the resonator hole formed in the transverse direction in the center portion of the coupling electrode ( It characterized in that the second intermediate resonator (# 2) formed with H) is formed integrally.

At this time, another coupling electrode among the adjacent coupling electrode groups is continuously formed between the first intermediate resonator # 4-1 and the second intermediate resonator # 4-2, and a central portion of each coupling electrode is formed. It is preferable that at least one N-th resonator (# 4-N) having the resonance hole (H) formed in the lateral direction is formed integrally with each other.

In addition, a coupling electrode may be selectively provided at one end spaced apart from the input end electrode IE of the input stage resonator # 1 or spaced apart from the output end electrode OE of the output stage resonator # 3. It is also preferable that the stop band resonator BSR having the resonance hole H formed in the transverse direction is integrally formed at the center of the coupling electrode.

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. And a transmitter-side input stage resonator # 1 coupled to the antenna stage performing signal input / output with the device, and a transmitter-side first intermediate resonator # 2 coupled to and coupled to the transmitter-side input stage resonator # 1. And a transmitting-side first coupling resonator comprising a transmitting-side first intermediate resonator # 4-1 coupled to the transmitting-side first intermediate resonator # 2 and having negative coupling with the transmitting-side input stage resonator # 1. One elliptic function filter 10; And is coupled to and coupled to a transmitting side second intermediate resonator # 4-2 coupled to the transmitting side first resonator # 4-1 and the transmitting side second resonator # 4-2. The transmission is coupled to the second intermediate resonator # 2 and the second intermediate resonator # 2 at the same time, and the transmission is performed with the second intermediate resonator # 4-2 at the same time. A transmission-side dielectric filter 100 composed of a side output stage resonator # 3; and a transmission-side dielectric filter 100 composed of:

A receiver side output stage resonator # 1 'coupled to the antenna stage, a receiver side first resonator # 2' coupled to and coupled to the receiver side output stage resonator # 1 ', and the receiver side The first side of the receiver comprising the first intermediate resonator # 4-1 'coupled to the first intermediate resonator # 2' and receiving negative coupling with the receiving side output stage resonator # 1 '. Liptic function filter 10; And a receiver side second resonator # 4-2 'coupled to the receiver side first resonator # 4-1' and coupled to the receiver side second resonator # 4-2 '. The second intermediate resonator # 2 'coupled to the receiver side and the second intermediate resonator # 4-2' coupled with the second intermediate resonator # 2 'at the same time; And a receiving side dielectric filter 200 comprising a receiving side second elliptic function filter 20 including a receiving side input stage resonator # 3 'having negative coupling.

At this time, the transmitter-side dielectric filter and the receiver-side dielectric filter may be selectively formed, respectively, and the first or second parasitic resonators # 4-1 or # 4-1 'and the second parasitic resonators # 4- may be formed. 2 or # 4-2 ') preferably at least one medium resonator is further formed.

In addition, the transmitter-side dielectric filter and the receiver-side dielectric filter are selectively formed, respectively, between the transmitter-side input stage resonator # 1 and the transmitter-side first resonator # 4-1, and the receiver-side output stage resonator # 1 ') and the transmitting side first stage resonator # 1 and the transmitting side first intermediate resonator # 4-1 and the receiving side such that a negative coupling is made between the receiving side first resonator # 4-1'. The side output stage resonator # 1 'and the receiving side first intermediate resonator # 4-1' are combined in the same direction, or the second transmission side resonator # 4-2 and the transmitting side resonator # 3 ) And the second intermediate resonator # 4-2 and the output stage resonator so that a negative coupling is made between the second secondary resonator # 4-2 'and the second input resonator # 3'. # 3), the receiving side second intermediate resonator # 4-2 'and the receiving side input stage resonator # 3' are coupled in the same direction.

And selectively formed in each of the transmitter-side dielectric filter and the receiver-side dielectric filter, between the transmitter-side input stage resonator # 1 and the transmitter-side first resonator # 4-1, wherein the receiver-side output stage resonator # 1 ') and the transmitting side first resonator # 1 and the transmitting side first resonator # 1 so that the coupling between the receiving side first resonator # 4-1' is weakly coupled compared to the coupling between the other resonators. (# 4-1), an inductor coupling groove ICH is formed between the receiving side output stage resonator # 1 'and the receiving first intermediate resonator # 4-1', and the transmitting side second parameter Between the resonator # 4-2 and the transmitter-side output stage resonator # 3, and the coupling between the receiving second secondary resonator # 4-2 'and the receiver-side input stage resonator # 3' between different resonators. The transmitting-side second intermediate resonator (# 4-2), the transmitting-side output stage resonator (# 3), and the receiving-side second intermediate resonator so as to be weakly coupled as compared with the coupling. A (# 4-2 ') and the receiving input stage resonator (# 3') inductor coupling groove (ICH) in between is formed.

On the other hand, a stop band resonator (BSR) selectively formed in each of the transmitting side dielectric filter and the receiving side dielectric filter, and coupled to the transmitting end of the transmitting side output stage resonator # 3 or the receiving end of the receiving side input stage resonator # 3 '. ) Can be made by combining more.

In the case where the dielectrics of the resonators formed on the transmitting and receiving dielectric filters are integrally formed, the opening of the resonance hole H region formed in each of the resonators so that the coupling of the respective resonant periods can be performed. The coupling electrode is patterned on one surface, and a region except for the patterned portion is coated by a common electrode.

Specifically, in the duplexer dielectric filter formed of an integrally formed resonator, a first coupling electrode is provided in a dielectric filled therein, and a center portion of the first coupling electrode includes a resonance hole H formed in a lateral direction. A transmission side input stage resonator # 1 having an antenna electrode AE adjacent to the coupling electrode on one side of the dielectric spaced apart from the first coupling electrode; A coupling electrode of one of the coupling electrode groups adjacent to one end of the transmission-side input stage resonator # 1 is provided, and a transmission-side first having a resonance hole H formed in the transverse direction at the center of the coupling electrode. The intermediate resonator # 4-1 and one end of the transmitting side first intermediate resonator # 4-1 are provided with other coupling electrodes of adjacent coupling electrode groups, and the central portion of the coupling electrode is provided in the transverse direction. A transmission-side second intermediate resonator # 4-2 having the formed resonance hole H is formed; A third coupling electrode is provided at one end of the transmission-side second intermediate resonator # 4-2, and a resonance hole H formed in the transverse direction is formed at the center of the coupling electrode. A transmission side output stage resonator # 3 having a transmission terminal electrode TE disposed adjacent to the coupling electrode at one side of the dielectric spaced apart from the dielectric; It is formed on the side between the transmitter-side input stage resonator (# 1) and the transmitter-side first intermediate resonator (# 4-1), one side is provided with a coupling electrode, the central portion of the coupling electrode formed in the transverse direction A transmitting side first intermediate resonator # 2 having one resonance hole H formed therein; It is formed on the side between the transmitting side second intermediate resonator (# 4-2) and the transmitting side output stage resonator (# 3), one side thereof is provided with a coupling electrode, the central portion of the coupling electrode formed in the transverse direction A transmission-side dielectric filter in which the transmission-side second intermediate resonator # 2 having one resonance hole H is formed integrally; and

A fourth coupling electrode is provided in the dielectric filled therein, and a central portion of the fourth coupling electrode has a resonance hole H formed in the transverse direction, and one side of the dielectric spaced apart from the fourth coupling electrode. A receiving side output stage resonator # 1 'having an antenna electrode AE provided adjacent to the coupling electrode; A coupling electrode of one of the coupling electrode groups adjacent to one end of the receiving side output stage resonator # 1 'is provided, and the receiving side has a resonance hole H formed in the transverse direction at the center of the coupling electrode. At one end of the first intermediate resonator # 4-1 'and the receiving side first intermediate resonator # 4-1', another coupling electrode among the adjacent coupling electrode groups is provided, and the central portion of the coupling electrode is provided. A receiving side second intermediate resonator # 4-2 'having a resonance hole H formed in the transverse direction is formed; A third coupling electrode is provided at one end of the receiver-side second intermediate resonator # 4-2 ', and a resonance hole H formed in a transverse direction is formed at the center of the coupling electrode. A receiving side input stage resonator # 3 'having a receiving end electrode RE disposed adjacent to the coupling electrode on one side of the dielectric spaced from the electrode; It is formed on the side between the receiving side output stage resonator (# 1 ') and the receiving side first intermediate resonator (# 4-1'), one side of the coupling electrode is provided, the central portion of the coupling electrode in the transverse direction A reception side first intermediate resonator # 2 'having the resonance hole H formed therein is formed; It is formed on the side between the receiving side second intermediate resonator (# 4-2 ') and the receiving side input stage resonator (# 3'), one side of the coupling electrode is provided, the central portion of the coupling electrode in the transverse direction Receiving-side dielectric filter in which the receiving-side second intermediate resonator (# 2 ') formed with the resonance hole (H) formed integrally formed of: wherein the transmitting-side dielectric filter and the receiving-side dielectric filter The first coupling electrode and the fourth coupling electrode are integrally formed to be in contact with each other, and the junction portion is provided with an antenna electrode AE.

In this case, a coupling electrode adjacent to each other between the first and second intermediate resonators # 4-1 and # 4-1 'and the second intermediate resonators # 4-2 and # 4-2' is selectively provided at each transmitting and receiving side. Another coupling electrode is continuously formed, and at least one N-type resonator (# 4-N) having a resonance hole (H) formed in the transverse direction is formed integrally at the center of each coupling electrode. desirable.

In addition, a coupling electrode is provided at one end spaced apart from the transmitter end electrode of the transmitter-side input stage resonator or one end spaced from the receiver end electrode RE of the receiver-side output stage resonator, and a central portion of the coupling electrode is formed in the transverse direction. It is also preferable that the stop band resonators BSR having the resonance holes H are formed integrally with each other.

On the other hand, as another embodiment, the duplexer dielectric filter composed of a resonator formed integrally, the first coupling electrode is provided in the dielectric filled therein, the central portion of the first coupling electrode formed in the transverse resonator hole A transmission-side input stage resonator # 1 having (H) and having an antenna electrode AE adjacent to the coupling electrode on one side of the dielectric spaced from the first coupling electrode; A coupling electrode of one of the coupling electrode groups adjacent to one end of the transmission-side input stage resonator # 1 is provided, and a transmission-side first having a resonance hole H formed in the transverse direction at the center of the coupling electrode. The intermediate resonator # 4-1 and one end of the transmitting side first intermediate resonator # 4-1 are provided with other coupling electrodes of adjacent coupling electrode groups, and the central portion of the coupling electrode is provided in the transverse direction. A transmission-side second intermediate resonator # 4-2 having the formed resonance hole H is formed; A third coupling electrode is provided at one end of the transmission-side second intermediate resonator # 4-2, and a resonance hole H formed in the transverse direction is formed at the center of the coupling electrode. A transmission side output stage resonator # 3 having a transmission terminal electrode TE disposed adjacent to the coupling electrode at one side of the dielectric spaced apart from the dielectric; It is formed on the side between the transmitter-side input stage resonator (# 1) and the transmitter-side first intermediate resonator (# 4-1), one side is provided with a coupling electrode, the central portion of the coupling electrode formed in the transverse direction A transmitting side first intermediate resonator # 2 having one resonance hole H formed therein; It is formed on the side between the transmitting side second intermediate resonator (# 4-2) and the transmitting side output stage resonator (# 3), one side thereof is provided with a coupling electrode, the central portion of the coupling electrode formed in the transverse direction A transmission-side dielectric filter in which the transmission-side second intermediate resonator # 2 having one resonance hole H is integrally formed; and

A fifth coupling electrode is provided in the dielectric filled therein, and a central portion of the fifth coupling electrode has a resonant hole H formed in the transverse direction, and one side of the dielectric spaced apart from the fifth coupling electrode. A receiving side output stage resonator # 1 'having an antenna electrode AE provided adjacent to the coupling electrode; A coupling electrode of one of the coupling electrode groups adjacent to one end of the receiving side output stage resonator # 1 'is provided, and the receiving side has a resonance hole H formed in the transverse direction at the center of the coupling electrode. At one end of the first intermediate resonator # 4-1 'and the receiving side first intermediate resonator # 4-1', another coupling electrode among the adjacent coupling electrode groups is provided, and the central portion of the coupling electrode is provided. A receiving side second intermediate resonator # 4-2 'having a resonance hole H formed in the transverse direction is formed; A seventh coupling electrode is provided at one end of the second intermediate resonator # 4-2 'on the receiving side, and a resonance hole H formed in a transverse direction is formed at the center of the coupling electrode. A receiving side input stage resonator # 3 'having a receiving end electrode RE disposed adjacent to the coupling electrode on one side of the dielectric spaced from the electrode; It is formed on the side between the receiving side output stage resonator (# 1 ') and the receiving side first intermediate resonator (# 4-1'), one side of the coupling electrode is provided, the central portion of the coupling electrode in the transverse direction A reception side first intermediate resonator # 2 'having the resonance hole H formed therein is formed; It is formed on the side between the receiving side second intermediate resonator (# 4-2 ') and the receiving side input stage resonator (# 3'), one side of the coupling electrode is provided, the central portion of the coupling electrode in the transverse direction Receiving-side dielectric filter in which the receiving-side second intermediate resonator (# 2 ') formed with the resonance hole (H) formed integrally formed of: wherein the transmitting-side dielectric filter and the receiving-side dielectric filter The coupling electrodes formed on the transmitting first intermediate resonator # 2 and the receiving first intermediate resonator # 2 'may be integrally formed to contact each other, or the transmitting second intermediate resonator # 2 may be formed. And a coupling electrode formed on the receiving side second intermediate resonator # 2 'are integrally formed to be in contact with each other, and the junction portion is provided with an antenna electrode AE.

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.

5A and 5B are top and bottom perspective views showing a dielectric filter according to a first embodiment of the present invention. As shown in FIGS. 5A and 5B, the dielectric filter shown in the first embodiment includes a first elliptic filter 10 and a second elliptic filter 20. That is, by combining two dielectric filters of FIG. 1, each of the first elliptic function filter 10 and the second elliptic function filter 20 forms a dielectric filled therein, and the dielectric Resonant holes (H) are formed in the three resonant holes (H) in a triangle shape at a predetermined interval and all in the transverse direction. The coupling electrode CE is patterned on the upper surface of each of the resonance hole H regions for coupling the resonance period, and all regions except the patterned portion are coated with the common electrode GE. In this case, the coupling electrode CE, the inner wall of the resonance hole H, and the common electrode GE are integrally connected. Then, the first elliptic function filter 10 and the second elliptic function filter 20 are combined, but coupled with any one resonator except for the input stage resonator # 1 or the output stage resonator # 3 in which signals are inputted and outputted. It is made in one piece. An input stage resonator (# 1), an intermediate resonator (# 2), and a first intermediate resonator (# 4-1) are formed on the first elliptic function filter (10), and a second elliptic function filter (20) is provided on the second elliptic function filter (20). An intermediate resonator # 4-2, an intermediate resonator # 2, and an output stage resonator # 3 are formed. The intermediate resonator (# 2) is coupled to protrude to one side.

Accordingly, the parasitic resonator (# 4) not only has two skirt frequency characteristics caused by the first elliptic function filter 10 and the second elliptic function filter 20 but also increases the attenuation width by being manufactured integrally. -1, # 4-2) can be seen that naturally formed. Also, it can be seen that two are formed between the input stage resonator # 1 and the output stage resonator # 3. As can be seen from the graph to be described later, not only the frequency characteristic having a steeper slope can be obtained by using the factor in which the skirt frequency characteristic appears, but also the dual effect of making the slope steeper through the increase of the attenuation width.

Meanwhile, an input terminal electrode IE and an output terminal electrode OE through which signals are input and output are formed adjacent to the coupling electrode CE. In this case, since the complementary relationship in the function of the input terminal electrode IE and the output terminal electrode OE is the same as in the related art, a detailed description thereof will be omitted. In addition, since the functions of the input stage resonator (# 1) and the output stage resonator (# 3) are also complementary interlocked accordingly, detailed description thereof will be omitted.

Coupling electrodes CE are formed in each resonator region as described above, and these coupling electrodes CE are spaced apart from each other and patterned. At this time, the input stage resonator # 1 and the first intermediate resonator # 4-1 of the first elliptic function filter 10 are negatively coupled according to the elliptic function filter theory, and the second elliptic function is performed. The first elliptic so that the second intermediate resonator # 4-2 and the output stage resonator # 3 of the filter 20 can be negatively coupled, that is, weakly coupled compared to the coupling between the other resonators. The opposing distance between the input stage resonator # 1 and the coupling electrode CE formed in the region of the first intermediate resonator # 4-1 of the water filter 10 is increased or the mutually opposing area is reduced. The same applies to the output stage resonator # 3 and the second intermediate resonator # 4-2 of the second elliptic function filter 20.

In addition, the coupling between the input stage resonator # 1 and the first intermediate resonator # 4-1, and the coupling between the second intermediate resonator # 4-2 and the output stage resonator # 3 is different from the coupling between the resonators. Inductor coupling grooves ICH may be formed therebetween so as to be weakly coupled in comparison.

6A and 6B are graphs showing the frequency characteristics of the dielectric filter shown in FIGS. 5A and 5B. As shown in FIGS. 6A and 6B, the cutoff attenuation widths A2 of the dielectric filter shown in FIGS. 1 and 3 have the cutoff attenuation widths A2 at high ratios in the transition bands on both sides of the passband. It can be seen that the increase. Through this, a cutoff frequency characteristic having a steeper slope can be obtained. As shown in FIG. 6A, a steep skirt frequency characteristic may be obtained in both transition bands, and by tuning the resonator, a steeper cutoff frequency characteristic may be obtained in one passband as illustrated in FIG. 6B. Here, it should not be overlooked that the inclination in the transition band band in FIG. 6A and the inclination in the transition band band in FIG. 6B are different even if the attenuation width is output as A2. That is, in order to prevent overlapping with other frequencies in the transition band according to the application characteristic, it means that the slope in FIG. 6B may be required. This can be seen in more detail through patent application No. 10-2002-0011214 filed by the applicant.

7A and 7B are top and bottom perspective views showing a dielectric filter according to a second embodiment of the present invention. As shown in Figs. 7A and 7B, the dielectric filter shown in the second embodiment includes the first elliptic function filter 10 'and the second elliptic function filter 20' as in the first embodiment. Is done. That is, by combining two dielectric filters of FIG. 3, the first elliptic function filter 10 ′ and the second elliptic function filter 20 ′ are compared with the dielectric filters shown in FIGS. 5A and 5B. It can be seen that there is one more medium resonator. This medium resonator is designed to increase the attenuation width as the existing purpose. Since the coupling electrode CE patterned on the top surface of the dielectric filter and the common electrode GE applied to the side and bottom surfaces thereof are applied to FIGS. 5A and 5B, redundant description thereof will be omitted.

It is important here that the first elliptic function filter 10 'and the second elliptic function filter 20' are integrally formed to have two skirt frequency characteristics factors and increase the damping width. (# 4-1, # 4-2, # 4-3, # 4-4) are naturally formed, but four are formed between the input stage resonator # 1 and the output stage resonator # 3. As can be seen from the graph to be described later, the frequency characteristic having a steeper slope than that of FIGS. 5A and 5B can be obtained by using the factor in which the skirt frequency characteristic appears, as well as the steepness of the slope by increasing the attenuation width. It can be estimated that the effect of.

FIG. 8 is a graph showing frequency characteristics of the dielectric filter shown in FIGS. 7A and 7B. As illustrated in FIG. 8, the attenuation width A3 is larger than the cutoff attenuation width A2 of the dielectric filter shown in FIGS. 5A and 5B. The increase in attenuation width is because the resonators # 4-1, # 4-2, # 4-3, # 4-4 are larger than the dielectric filters shown in FIGS. 5A and 5B as described above.

The drawings to be described below can be sufficiently described through a plan view in which the portion where the coupling electrode CE is formed in the above perspective is clearly shown, so only the plan view will be shown.

9 is a plan view showing a dielectric filter according to a third embodiment of the present invention. As shown in FIG. 9, the dielectric filter shown in the third embodiment has the intermediate resonators # 4-1, # 4-2, # 4-3, # 4-4, # compared with the second embodiment. 4-5 and # 4-6) are further increased to form the first elliptic filter 10 " and the second elliptic filter 20 ". This is to increase the attenuation width to obtain a steeper slope in the transition band band in the skirt frequency characteristics.

10 is a graph showing the frequency characteristics of the dielectric filter shown in FIG. As shown in FIG. 10, it can be seen that the attenuation width A4 is larger than the cutoff attenuation width A3 of the dielectric filter shown in FIG. 8. As described above, the attenuation width increasing factors are shown in FIG. 8 by the intermediate resonators # 4-1, # 4-2, # 4-3, # 4-4, # 4-5, and # 4-6 as described above. This is because there are more than the dielectric filter.

Next, the duplexer dielectric filter will be described. In the description of the duplexer dielectric filter, since the two dielectric filters shown in the present invention are formed in a symmetrical manner, the receiving dielectric filter 200 has reference to the reference numeral of the transmitting dielectric filter 100 ( Reference marks are distinguished from one another in the form of reference numerals, and these reference marks are indicated only when necessary.

11 is a plan view illustrating an integrated duplexer dielectric filter according to a fourth exemplary embodiment of the present invention. As shown in FIG. 11, the integrated duplexer dielectric filter shown in the fourth embodiment is formed by combining two dielectric filters shown in FIG. 5 integrally and symmetrically about the antenna electrode AE. That is, the transmitting side dielectric filter 100 is formed at one side around the antenna electrode AE, and the receiving side dielectric filter 200 is formed at the other side. That is, the transmitter dielectric filter 100 and the receiver dielectric filter 200 are coupled to each other, and each of the transmitter dielectric filter 100 and the receiver dielectric filter 200 has a dielectric charged therein. And a resonance hole (H) formed in the dielectric, and the three resonance holes (H) are formed in a lateral direction at a predetermined interval in a triangular shape. And a second elliptic function filter 20. The coupling electrode CE is patterned on the upper surface of each of the resonance hole H regions for coupling the resonance period, and all regions except the patterned portion are coated with the common electrode GE. In this case, the coupling electrode CE, the inner wall of the resonance hole H, and the common electrode GE are integrally connected.

Accordingly, each of the transmitting dielectric filter 100 and the receiving dielectric filter 200 may have two skirt frequency characteristics caused by the first elliptic filter 10 and the second elliptic filter 20. In addition, it can be seen that the intermediate resonator (# 4-1, # 4-2, # 4-1 ', # 4-2') is naturally formed to increase the attenuation width as a monolithic manufacturing. Specifically, two between the transmitter-side input stage resonator # 1 coupled to the antenna electrode AE and the transmitter-side output stage resonator # 3, and the receiver-side output stage resonator # 1 'coupled to the antenna electrode AE. ) And two are formed between the receiver side input stage resonator (# 3 '). As can be seen from the graph to be described later, the frequency characteristic with steeper slope can be obtained not only by using the factor in which the skirt frequency characteristic appears at the transmitting side and the receiving side, but also by making the slope steeper through increasing the attenuation width. There is a dual effect.

Meanwhile, the transmitting end electrode TE and the receiving end electrode RE, through which signals are transmitted and received, are formed adjacent to the coupling electrode CE. At this time, the complementary relationship between the transmitting end electrode TE and the receiving end electrode RE may be understood in more detail through the patent application No. 10-2002-0011214 filed by the present applicant, and thus the detailed description thereof will be omitted. do.

Coupling electrodes CE are formed in each resonator region as described above, and these coupling electrodes CE are spaced apart from each other and patterned. At this time, the first and second transmission functions of the elliptic filter 10 and the second elliptic filter 20 formed according to the elliptic function filter theory have a negative coupling in a resonance period in which signals are inputted and outputted in the formation region thereof. You lose. That is, in the transmitting side dielectric filter 100, the transmitting side input stage resonator # 1 and the transmitting side first resonator # 4-1, which are coupled to the antenna electrode AE, transmit the second side resonator # 4. -2) and the transmitting side output stage resonator # 3 are negatively coupled, and the receiving side dielectric filter 200 has a receiving side output stage resonator # 1 'coupled to the antenna electrode AE and the receiving side first receiver. The intermediate resonator # 4-1 'has a negative coupling between the receiving side second intermediate resonator # 4-2' and the receiving side input stage resonator # 3 '.

Here, since the embodiment of FIG. 7 and FIG. 9 applied to the transmitting side and the receiving side of the integrated duplexer dielectric filter can be sufficiently inferred, description thereof will be omitted. That is, since the attenuation width can be increased by applying the above FIGS. 7 and 9 to each of the transmitting side and the receiving side, overlapping descriptions will be omitted.

12 is a graph illustrating the frequency characteristics of the integrated duplexer dielectric filter shown in FIG. 11. As shown in FIG. 12, it can be seen that the cutoff attenuation width A2 is shown to have the same magnitude as that of FIG. Of course, although not shown, as shown in Figure 6b through the tuning of the resonator for each of the transmitting and receiving side can exhibit the skirt frequency characteristics on one side.

13 is a plan view schematically showing a dielectric filter according to a fifth embodiment of the present invention. Referring to FIG. 13, the difference is that the stop band resonator BSR is coupled to both sides in comparison with FIG. 5. Of course, the stop band resonator BSR may be coupled to only one of the input terminal electrode IE and the output terminal electrode OE. Thus, the reason for providing the stop band resonator (BSR) is to construct a dielectric filter having a steeper slope by providing a plurality of factors of the skirt frequency characteristics. That is, four skirt frequency characteristics factors including the first elliptic function filter 10-1, the second elliptic function filter 20-1, and two stop band resonators (BSR) are provided, The resonator is tuned so that four skirt frequency characteristics can be obtained to obtain a frequency characteristic with a steeper slope. Although the input / output end resonators (# 1, # 3) and the stop band resonator (BSR) coupled to the input end electrode IE and the output end electrode OE are simultaneously coupled, the insertion loss is lower than that of the dielectric filter shown in FIG. Although many occur, frequency characteristics having a steeper slope can be obtained by using the four skirt frequency characteristics described above, and thus can be utilized to the maximum.

14 is a graph showing the frequency characteristics of the dielectric filter shown in FIG. As shown in FIG. 14, although the cutoff attenuation width A2 is the same as that of FIGS. 6A and 6B at a high rate in the transition bands on both sides of the passband, two skirt frequency characteristics appear on each side of the transition band. It has a steeper slope as compared to FIG. 6B.

FIG. 15 is a plan view illustrating an integrated duplexer dielectric filter according to a sixth exemplary embodiment of the present invention. As shown in FIG. 15, the integrated duplexer dielectric filter shown in the sixth embodiment is formed by combining two dielectric filters shown in FIG. 13 integrally and symmetrically about the antenna electrode AE. That is, it consists of the transmission side dielectric filter 100 'and the reception side dielectric filter 200'.

FIG. 16 is a graph illustrating the frequency characteristics of the integrated duplexer dielectric filter shown in FIG. 15. As shown in FIG. 16, three skirt frequency characteristic factors appear on each of the transmission and reception sides, and as shown in FIG. 16, all of the skirt frequency characteristic factors may appear on one side through tuning of the resonator.

17 is a plan view illustrating an integrated duplexer dielectric filter according to a seventh embodiment of the present invention. As illustrated in FIG. 17, the transmitting dielectric filter and the receiving dielectric filter are symmetrical with respect to the antenna electrode AE, but are symmetrical on the XY axis. That is, FIGS. 11 and 15 show that the transmission dielectric filter and the reception dielectric filter are different from each other in the Y-axis symmetry with respect to the antenna electrode AE. This is the main purpose of the present application filed in the patent application No. 10-2002-0011214 filed by the applicant, the input or output of the signal in each region of the transmitting side elliptic function filter and the receiving side elliptic function filter adjacent to the antenna electrode (AE) The embodiment of the present invention provides a compact structure while providing an extended region of the stop band resonator BSR and an intermediate region of the resonator by changing the position of the resonator. That is, in FIG. 15, only two stopband resonators (BSRs) may be coupled to the duplexer dielectric filter, whereas the duplexer dielectric filters shown in FIG. 17 may be additionally formed in the intermediate resonators # 2 and # 2 'of the transmitting and receiving sides. As a result, a total of four stop band resonators (BSR) can be combined.

At this time, a negative coupling is performed between the transmitter-side input stage resonator # 1 and the transmitter-side first intermediate resonator # 4-1. Coupling grooves (not shown) are formed to allow for weak coupling. The same applies to the receiving side output stage resonator # 1 'and the receiving side first intermediate resonator # 4-1'.

18 is a plan view showing an integrated dielectric filter in accordance with an eighth exemplary embodiment of the present invention. As shown in FIG. 18, it can be seen that three elliptic function filters 10, 20, and 30 are combined. Since the skirt frequency characteristic factor is three, the skirt frequency characteristic can be used more effectively than the dielectric filter shown in FIGS. 5A and 5B. In the dielectric filter shown in FIG. 18, the intermediate resonator shown in FIGS. 7 and 9 may be expanded, and the stop band resonator (BSR) shown in FIG. 13 may be combined. It is well known that the above-described extensions can be applied to the duplexer dielectric filter, including the dielectric filter described in the following, and thus a detailed description thereof will be omitted.

On the other hand, in the present embodiment is shown as an embodiment only in the case of the one-piece type, by combining the respective resonators manufactured separately to achieve the object of the present invention as well as in this embodiment, only the coaxial resonator is given as an example, A resonant resonator may be used to form a dielectric filter and a duplexer dielectric filter, and a combination of a coaxial resonator and a resonant resonator may be used. In addition, the coupling strength may be adjusted by changing the shape of each resonator, adjusting the distance interval, and the inductor coupling groove ICH. In addition, the coupling direction of at least one resonator may be changed in order to improve not only the in-band frequency characteristic but also the out-band frequency characteristic. This can be seen in Patent Application No. 10-2002-0011214 filed by the Applicant.

As described above, according to the present invention, a dielectric filter and a duplexer dielectric filter are manufactured by connecting a plurality of elliptic function filters having a skirt frequency characteristic factor to have a steep slope in the transition band band in the frequency characteristic while minimizing the insertion loss. As a result, a steeper frequency characteristic can be obtained in the transition band band, the insertion loss is increased, and a compact design can be designed. 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, the compact shape may be easily applied to products requiring miniaturization.

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 (23)

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, a first intermediate resonator # 2 coupled to and coupled to the input stage resonator # 1, and the first intermediate resonator # 2 A first elliptic function filter (10) comprising a first intermediate resonator (# 4-1) coupled to the input stage resonator (# 1) and negative coupling at the same time; And A second intermediate resonator # 4-2 coupled to the intermediate resonator # 4-1, and a second intermediate resonator # 2 coupled to and coupled to the second intermediate resonator # 4-2. And a second elliptic function filter 20 which is coupled to the second intermediate resonator # 2 and comprises an output stage resonator # 3 having negative coupling with the second intermediate resonator # 4-2. ); Dielectric filter, characterized in that consisting of. The dielectric filter as claimed in claim 1, wherein at least one medium resonator is further formed between the first medium resonator (# 4-1) and the second medium resonator (# 4-2). The input stage resonator (# 1) and the first intermediate resonator (# 4-1) according to claim 1, wherein a negative coupling is made between the input stage resonator (# 1) and the first intermediate resonator (# 4-1). Dielectric filter, characterized in that coupled in the same direction. According to claim 1, wherein the second intermediate resonator (# 4-2) and the output stage resonator (# 3) so that the negative coupling between the second resonator (# 4-2) and the output stage resonator (# 3) 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 (# 4-1) is coupled so that the coupling between the input stage resonator (# 1) and other resonator weakly compared A dielectric filter formed by forming an inductor coupling groove ICH between a first intermediate resonator # 4-1. 2. The second intermediate resonator (# 4-) according to claim 1, wherein the coupling between the second intermediate resonator (# 4-2) and the output stage resonator (# 3) is weakly coupled compared to the coupling between other resonators. 2) and an inductor coupling groove (ICH) formed between the output stage resonator (# 3). The dielectric filter as claimed in claim 1, further comprising a stop band resonator (BSR) selectively coupled to the input terminal or the output terminal. 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 respective resonance period 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. A first coupling electrode is provided in the dielectric filled therein, and a central portion of the first coupling electrode has a resonant hole H formed in a transverse direction, and one side of the dielectric spaced apart from the first coupling electrode. An input stage resonator # 1 in which an input stage electrode IE is provided adjacent to the coupling electrode is formed; A coupling electrode of one of the coupling electrode groups adjacent to one end of the input stage resonator # 1 is provided, and a first intermediate resonator (#) having a resonance hole H formed in a transverse direction in the center of the coupling electrode. 4-1) and another coupling electrode of the adjacent coupling electrode group are provided at one end of the first intermediate resonator # 4-1, and the resonance hole H formed in the transverse direction is formed at the center of the coupling electrode. A second intermediate resonator (# 4-2) having () is formed; A third coupling electrode is provided at one end of the second intermediate resonator # 4-2, and a resonance hole H formed in a transverse direction is formed at the center of the coupling electrode, and spaced apart from the coupling electrode. An output stage resonator # 3 having an output terminal electrode OE disposed adjacent to the coupling electrode on one side of the dielectric; It is formed on the side between the input stage resonator (# 1) and the first intermediate resonator (# 4-1), one side thereof is provided with a coupling electrode, the central portion of the coupling electrode formed in the transverse direction (resonance hole ( A first intermediate resonator # 2 having H) formed thereon; It is formed on the side between the second intermediate resonator (# 4-2) and the output stage resonator (# 3), one side is provided with a coupling electrode, the central portion of the coupling electrode formed in the transverse direction (resonance hole ( A dielectric filter comprising a second intermediate resonator (# 2) having H) formed integrally. 10. The method of claim 9, wherein another coupling electrode among the adjacent coupling electrode groups is continuously formed between the first intermediate resonator # 4-1 and the second intermediate resonator # 4-2, and each coupling And at least one N-th resonator (# 4-N) having a resonant hole (H) formed laterally in a central portion of the electrode. The coupling electrode of claim 9, wherein a coupling electrode is selectively disposed at one end spaced apart from the input terminal electrode IE of the input stage resonator # 1 or spaced apart from the output terminal electrode OE of the output stage resonator # 3. And a stop band resonator (BSR) having a resonant hole (H) formed laterally in a central portion of the coupling electrode. 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 transmitter-side first intermediate resonator # 2 coupled to and coupled to the transmitter-side input stage resonator # 1, And a transmitting side first comprising a transmitting side first intermediate resonator # 4-1 coupled to the transmitting side first intermediate resonator # 2 and having negative coupling with the transmitting side input stage resonator # 1. Elliptic function filter 10; And A second side resonator # 4-2 coupled to the first side resonator # 4-1 on the transmission side, and coupled to the second side resonator # 4-2 on the transmission side The transmitting side which is coupled to the transmitting side second intermediate resonator # 2 and the transmitting side second intermediate resonator # 2 and is negatively coupled to the transmitting side second intermediate resonator # 4-2. A transmission-side second elliptic function filter 20 formed of an output stage resonator # 3; Transmitting-side dielectric filter 100 consisting of: and A receiver side output stage resonator # 1 'coupled to the antenna stage, a receiver side first resonator # 2' coupled to and coupled to the receiver side output stage resonator # 1 ', and the receiver side The first side of the receiver comprising the first intermediate resonator # 4-1 'coupled to the first intermediate resonator # 2' and receiving negative coupling with the receiving side output stage resonator # 1 '. Liptic function filter 10; And It is coupled to the receiving side second parasitic resonator (# 4-2 ') and the receiving side second parasitic resonator (# 4-2') coupled to the receiving first parasitic resonator (# 4-1 '). A coupling with the receiving second intermediate resonator # 2 'and a coupling with the receiving second intermediate resonator # 2' and a negative of the receiving second intermediate resonator # 4-2 ' A receiving-side second elliptic function filter 20 formed of a receiving-side input stage resonator # 3 'which is coupled; Receiving-side dielectric filter 200 consisting of: Duplexer dielectric filter, characterized in that consisting of. 13. The method of claim 12, wherein the transmitter-side dielectric filter and the receiver-side dielectric filter are selectively formed, respectively, between the first-side resonator # 4-1 and the second-side resonator # 4-2. A duplexer dielectric filter, characterized in that at least one intermediate resonator is further formed. 13. The method of claim 12, wherein the transmitting side dielectric filter and the receiving side dielectric filter are selectively formed, respectively, between the transmitting side input stage resonator # 1 and the transmitting side first resonator # 4-1. The transmitter-side input stage resonator # 1 and the transmitter-side first side resonator # 4-1 such that a negative coupling is made between the output stage resonator # 1 'and the receiving side first resonator # 4-1'. And the receiving side output stage resonator (# 1 ') and the receiving side first intermediate resonator (# 4-1') are coupled in the same direction. The method of claim 12, wherein the transmitting side dielectric filter and the receiving side dielectric filter are selectively formed, respectively, between the transmitting side second intermediate resonator (# 4-2) and the transmitting side output stage resonator (# 3), the receiving side The second intermediate resonator # 4-2 and the output stage resonator # 3, and the receiving unit to perform negative coupling between the second intermediate resonator # 4-2 'and the receiving side input stage resonator # 3'. A duplexer dielectric filter, characterized in that the second side resonator (# 4-2 ') and the receiving side input stage resonator (# 3') are coupled in the same direction. 13. The method of claim 12, wherein the transmitting side dielectric filter and the receiving side dielectric filter are selectively formed, respectively, between the transmitting side input stage resonator # 1 and the transmitting side first resonator # 4-1. The transmitting side input stage resonator # 1 and the transmitting side such that the coupling between the output stage resonator # 1 'and the receiving side first intermediate resonator # 4-1' is weakly coupled compared to the coupling between the other resonators. It is made by forming an inductor coupling groove (ICH) between a first intermediate resonator (# 4-1), the receiving side output stage resonator (# 1 ') and the receiving first first resonator (# 4-1'). Duplexer dielectric filter. The method of claim 12, wherein the transmitting side dielectric filter and the receiving side dielectric filter are selectively formed, respectively, between the transmitting side second intermediate resonator (# 4-2) and the transmitting side output stage resonator (# 3), the receiving side The second side resonator (# 4-2) of the transmitting side such that the coupling between the second intermediate resonator (# 4-2 ') and the receiving side input stage resonator (# 3') is weakly coupled compared to the coupling between the other resonators. ), And an inductor coupling groove ICH is formed between the transmitting side output stage resonator # 3, the receiving second intermediate resonator # 4-2 'and the receiving side input stage resonator # 3'. Duplexer dielectric filter. 13. The stop according to claim 12, wherein the stop is selectively formed in each of the transmitting side dielectric filter and the receiving side dielectric filter, and coupled to the transmitting end of the transmitting side output stage resonator # 3 or the receiving end of the receiving side input stage resonator # 3 '. A duplexer dielectric filter, characterized in that the band resonator (BSR) is further coupled. The method of claim 12, wherein when the dielectric of each resonator formed in the transmitting dielectric filter and the receiving dielectric filter is integrally formed, an opening resonator hole formed in each of the resonators so that coupling of the respective resonant periods is possible. H) patterning the coupling electrode on one surface of the region, and the duplexer dielectric filter, characterized in that by applying a region except the patterned portion to the common electrode. A first coupling electrode is provided in the dielectric filled therein, and a central portion of the first coupling electrode has a resonant hole H formed in a transverse direction, and one side of the dielectric spaced apart from the first coupling electrode. A transmitter-side input stage resonator # 1 having an antenna electrode AE provided adjacent to the coupling electrode is formed in the second stage; A coupling electrode of one of the coupling electrode groups adjacent to one end of the transmission-side input stage resonator # 1 is provided, and a transmission-side first having a resonance hole H formed in the transverse direction at the center of the coupling electrode. The intermediate resonator # 4-1 and one end of the transmitting side first intermediate resonator # 4-1 are provided with other coupling electrodes of adjacent coupling electrode groups, and the central portion of the coupling electrode is provided in the transverse direction. A transmission-side second intermediate resonator # 4-2 having the formed resonance hole H is formed; A third coupling electrode is provided at one end of the transmission-side second intermediate resonator # 4-2, and a resonance hole H formed in the transverse direction is formed at the center of the coupling electrode. A transmission side output stage resonator # 3 having a transmission terminal electrode TE disposed adjacent to the coupling electrode at one side of the dielectric spaced apart from the dielectric; It is formed on the side between the transmitter-side input stage resonator (# 1) and the transmitter-side first intermediate resonator (# 4-1), one side is provided with a coupling electrode, the central portion of the coupling electrode formed in the transverse direction A transmitting side first intermediate resonator # 2 having one resonance hole H formed therein; It is formed on the side between the transmitting side second intermediate resonator (# 4-2) and the transmitting side output stage resonator (# 3), one side thereof is provided with a coupling electrode, the central portion of the coupling electrode formed in the transverse direction A transmission-side dielectric filter in which the transmission-side second intermediate resonator # 2 having one resonance hole H is integrally formed; and A fourth coupling electrode is provided in the dielectric filled therein, and a central portion of the fourth coupling electrode has a resonance hole H formed in the transverse direction, and one side of the dielectric spaced apart from the fourth coupling electrode. A receiving side output stage resonator # 1 'having an antenna electrode AE provided adjacent to the coupling electrode; A coupling electrode of one of the coupling electrode groups adjacent to one end of the receiving side output stage resonator # 1 'is provided, and the receiving side has a resonance hole H formed in the transverse direction at the center of the coupling electrode. At one end of the first intermediate resonator # 4-1 'and the receiving side first intermediate resonator # 4-1', another coupling electrode among the adjacent coupling electrode groups is provided, and the central portion of the coupling electrode is provided. A receiving side second intermediate resonator # 4-2 'having a resonance hole H formed in the transverse direction is formed; A third coupling electrode is provided at one end of the receiving second second resonator # 4-2 ', and a resonance hole H formed in a transverse direction is formed at the center of the coupling electrode. A receiving side input stage resonator # 3 'having a receiving end electrode RE disposed adjacent to the coupling electrode on one side of the dielectric spaced from the electrode; It is formed on the side between the receiving side output stage resonator (# 1 ') and the receiving side first intermediate resonator (# 4-1'), one side of the coupling electrode is provided, the central portion of the coupling electrode in the transverse direction A reception side first intermediate resonator # 2 'having the resonance hole H formed therein is formed; It is formed on the side between the receiving side second intermediate resonator (# 4-2 ') and the receiving side input stage resonator (# 3'), one side of the coupling electrode is provided, the central portion of the coupling electrode in the transverse direction Receiving-side dielectric filter in which the receiving-side second intermediate resonator (# 2 ') formed with the resonance hole (H) formed integrally formed of: wherein the transmitting-side dielectric filter and the receiving-side dielectric filter And the first coupling electrode and the fourth coupling electrode are integrally formed to be in contact with each other, and the junction portion is provided with an antenna electrode (AE). 21. The apparatus of claim 20, wherein the first and second parasitic resonators # 4-1 and # 4-1 'and the second parasitic resonators # 4-2 and # 4-2' are selectively adjacent to each other. Another coupling electrode of the coupling electrode group is continuously formed, and at least one N-th resonator (# 4-N) having a resonance hole (H) formed in the transverse direction is integrally formed at the center of each coupling electrode. A duplexer dielectric filter, characterized in that formed. The coupling electrode of claim 20, wherein a coupling electrode is provided at one end spaced apart from the transmitter end electrode of the transmitter-side input stage resonator or at one end spaced from the receiver end electrode RE of the receiver-side output stage resonator. A duplexer dielectric filter, characterized in that each stop band resonator (BSR) having a resonant hole (H) formed in the transverse direction is formed integrally. A first coupling electrode is provided in the dielectric filled therein, and a central portion of the first coupling electrode has a resonant hole H formed in a transverse direction, and one side of the dielectric spaced apart from the first coupling electrode. A transmitter-side input stage resonator # 1 having an antenna electrode AE provided adjacent to the coupling electrode is formed in the second stage; A coupling electrode of one of the coupling electrode groups adjacent to one end of the transmission-side input stage resonator # 1 is provided, and a transmission-side first having a resonance hole H formed in the transverse direction at the center of the coupling electrode. The intermediate resonator # 4-1 and one end of the transmitting side first intermediate resonator # 4-1 are provided with other coupling electrodes of adjacent coupling electrode groups, and the central portion of the coupling electrode is provided in the transverse direction. A transmission-side second intermediate resonator # 4-2 having the formed resonance hole H is formed; A third coupling electrode is provided at one end of the transmission-side second intermediate resonator # 4-2, and a resonance hole H formed in the transverse direction is formed at the center of the coupling electrode. A transmission side output stage resonator # 3 having a transmission terminal electrode TE disposed adjacent to the coupling electrode at one side of the dielectric spaced apart from the dielectric; It is formed on the side between the transmitter-side input stage resonator (# 1) and the transmitter-side first intermediate resonator (# 4-1), one side is provided with a coupling electrode, the central portion of the coupling electrode formed in the transverse direction A transmitting side first intermediate resonator # 2 having one resonance hole H formed therein; It is formed on the side between the transmitting side second intermediate resonator (# 4-2) and the transmitting side output stage resonator (# 3), one side thereof is provided with a coupling electrode, the central portion of the coupling electrode formed in the transverse direction A transmission-side dielectric filter in which the transmission-side second intermediate resonator # 2 having one resonance hole H is integrally formed; and A fifth coupling electrode is provided in the dielectric filled therein, and a central portion of the fifth coupling electrode has a resonant hole H formed in the transverse direction, and one side of the dielectric spaced apart from the fifth coupling electrode. A receiving side output stage resonator # 1 'having an antenna electrode AE provided adjacent to the coupling electrode; A coupling electrode of one of the coupling electrode groups adjacent to one end of the receiving side output stage resonator # 1 'is provided, and the receiving side has a resonance hole H formed in the transverse direction at the center of the coupling electrode. At one end of the first intermediate resonator # 4-1 'and the receiving side first intermediate resonator # 4-1', another coupling electrode among the adjacent coupling electrode groups is provided, and the central portion of the coupling electrode is provided. A receiving side second intermediate resonator # 4-2 'having a resonance hole H formed in the transverse direction is formed; A seventh coupling electrode is provided at one end of the second intermediate resonator # 4-2 'on the receiving side, and a resonance hole H formed in a transverse direction is formed at the center of the coupling electrode. A receiving side input stage resonator # 3 'having a receiving end electrode RE disposed adjacent to the coupling electrode on one side of the dielectric spaced from the electrode; It is formed on the side between the receiving side output stage resonator (# 1 ') and the receiving side first intermediate resonator (# 4-1'), one side of the coupling electrode is provided, the central portion of the coupling electrode in the transverse direction A reception side first intermediate resonator # 2 'having the resonance hole H formed therein is formed; It is formed on the side between the receiving side second intermediate resonator (# 4-2 ') and the receiving side input stage resonator (# 3'), one side of the coupling electrode is provided, the central portion of the coupling electrode in the transverse direction Receiving-side dielectric filter in which the receiving-side second intermediate resonator (# 2 ') formed with the resonance hole (H) formed integrally formed of: wherein the transmitting-side dielectric filter and the receiving-side dielectric filter The coupling electrodes formed on the transmitting first intermediate resonator # 2 and the receiving first intermediate resonator # 2 'may be integrally formed to contact each other, or the transmitting second intermediate resonator # 2 may be formed. And a coupling electrode formed on the receiving second intermediate resonator (# 2 ') to be integrally formed so as to be in contact with each other, and an antenna electrode (AE) is provided at the junction thereof.