KR100995758B1 - Junction dielectric resonator, band pass filter and duplexer - Google Patents

Abstract

The junction dielectric resonator of the present invention has a hexagonal shape, a dielectric material is filled therein, an outer surface has a conductive material forming portion and a non-conductive material forming portion, and a signal is transmitted through the non-conductive material forming portion. In addition, in the bandpass filter of the present invention, a plurality of bonded dielectric resonators are connected in a line, and at least one of the plurality of resonators and the other resonator have non-conductive material forming input and output ports on the upper or lower surface thereof. Each of the plurality of resonators is provided with non-conductive portions formed on the inner side or the outer side of each other so as to face each other. In addition, the duplexer of the present invention has a plurality of bonded dielectric resonators are bonded in a row, at least one of the plurality of resonators, the other resonator and another resonator has a transmission port, a receiving port and an antenna port on the top or bottom The conductive material non-formed portion is provided, and each of the plurality of resonators is in contact with another conductive material non-formed portion formed on the inner side or the outer side of each other.

Junction, Dielectric, Resonator, Band, Pass, Filter, Duplexer

Description

Junction dielectric resonators, bandpass filters and duplexers {JUNCTION DIELECTRIC RESONATOR, BAND PASS FILTER AND DUPLEXER}

The present invention relates to a bonded dielectric resonator, a bandpass filter and a duplexer, and more particularly, to a bonded dielectric resonator, a bandpass filter, and a duplexer, which can implement various forms and can significantly reduce manufacturing costs.

Currently used wireless communication systems provide a variety of services using a variety of frequencies, which requires a variety of filter characteristics. In order to cope with various filter characteristics, the resonator constituting the filter should be able to be changed in various forms according to conditions.

In order to implement this, a technique of dividing a plurality of resonators that are integrally implemented and joining them into various shapes desired is disclosed in Korean Patent Application No. 10-2008-0089814 filed on September 11, 2008. Is disclosed.

As shown in FIGS. 6 and 7, the conventional dielectric resonator assembly 10 has conductive coating layers 22, 32, 42, and 52 formed on the outer surface of the dielectric blocks 21, 31, and a conductive nose. Indentations 22, 32, 42, and 52 are formed with inlet holes 33, 43, 53 and outlet holes 24, 34, 44, 54 that partially expose dielectric blocks 21, 31. It is provided with a plurality of resonant units (20, 30, 40, 50).

Neighboring resonant units 20, 30, 40, and 50 have neighboring outlet holes 24, 34, 44, 54 and inlet holes 33, 43, 53 at least partially overlapping each other. External connection terminals are provided to be electrically separated from the conductive coating layers 22, 32, 42, and 52 in the inlet hole and the outlet hole 24 which are exposed.

The conventional dielectric resonator assembly having the above-described configuration forms slots having various sizes or shapes in each resonator as couplings connecting the blocks, and this processing process is not easy, such as a filter or a duplexer. Not only was it difficult to implement a variety of products with a resonator, but it was also very difficult to change the size or shape of the slots that were already processed. This also has limitations in implementing various products. In addition, many machining tools needed to match the size and shape of the slots had to be prepared, increasing the price of products such as filters and duplexers.

The present invention has been made to solve the above-described problems of the prior art, the problem to be solved of the present invention is a coupling connecting the blocks between the various strip lines having a desired size or shape through a printing operation on each resonator The present invention provides a bonded dielectric resonator, a bandpass filter, and a duplexer that can be implemented in various forms as well as lower the cost.

delete

delete

A plurality of bonded dielectric resonators are bonded in a line, and at least one of the plurality of resonators and the other resonator are provided with non-conductive materials that form an input port and an output port on an upper or lower surface thereof, and each of the plurality of resonators Is another conductive material non-formed portion formed on the inner side or the outer side of each other is in contact with each other,
The junction dielectric resonator has a hexagonal shape, and a dielectric material is filled therein, an outer surface has a conductive material forming portion and a conductive material forming portion, and a signal is transmitted through the conductive material forming portion. Provided is a band pass filter, characterized in that the conductive material is not formed or the conductive material is removed.

In the band pass filter of the present invention, an input port or an output port is formed with a non-conductive portion having a non-conductive portion formed in one resonator and a nonconductive portion having a non-conductive portion formed in another resonator. It is characterized by consisting of a "ㅁ" shape.

A plurality of bonded dielectric resonators are bonded in a line, and at least one of the plurality of resonators, the other resonator, and the other resonator have a conductive material non-formation portion that becomes a transmission port, a receiving port, and an antenna port on the upper or lower surface thereof. Each of the plurality of resonators is in contact with each other, the non-conductive material formed on the inner side or the outer side of each other, facing each other,
The junction dielectric resonator has a hexagonal shape, and a dielectric material is filled therein, an outer surface has a conductive material forming portion and a conductive material forming portion, and a signal is transmitted through the conductive material forming portion. It provides a duplexer that does not form a conductive material or is made by removing a conductive material.

The duplexer of the present invention includes a "c" shaped nonconductive material formed at one of the plurality of resonators and a "|" shaped nonconductive material formed at the other resonator. It is characterized by consisting of a "ㅁ" shape.

According to the bonded dielectric resonator, the bandpass filter and the duplexer of the present invention, since the couplings connecting the blocks are composed of various strip lines having a desired size or shape by printing on the front and back of each resonator, Not only can it be implemented in more various forms, but it can also significantly lower the price of the product.

Hereinafter, a bonded dielectric resonator, a band pass filter, and a duplexer according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the junction dielectric resonator 100 according to the present exemplary embodiment is formed in a block form.

The resonator 100 has a cube shape, and a dielectric material (not shown) is filled therein. The resonator 100 includes a conductive material forming unit 101 having a conductive material having excellent conductivity such as silver, copper, or various metals, and a non-conductive material forming unit 103 having no conductive material. The signal entering the resonator 100 enters through the non-conductive material 103 and causes various types of resonance in the dielectric material. Therefore, the conductive material non-forming part 103 serves as a coupling like a slot of the prior art, or acts as an inlet or an outlet for a signal to enter, such as an entrance and exit hole of the prior art.

The conductive material non-forming part 103 forms the conductive material forming part 101 on the entire outer surface of the resonator 100 and then removes the conductive material from a desired part through a known method, or does not form the conductive material in the desired part. Can be formed.

A plurality of block-type resonators 100 having such a configuration are connected to implement a band pass filter as shown in FIG. 2 or a duplexer as shown in FIG. 3.

The bandpass filter according to the present invention may be composed of a plurality of resonators of the same size or different sizes. A representative example thereof is shown in FIG. 2.

As shown in FIG. 2 and FIG. 3, the present embodiment implements a band pass filter 100 ′ composed of six resonators. The six resonators are called first, second, third, fourth, fifth, and sixth resonators 100a, 100b, 100c, 100d, 100e, and 100f, respectively, and are joined in order in order to be joined by lead or the like. .

The first and sixth resonators 100a and 100f are positioned at the outermost side, and the non-conductive material forming portions 103a and 103f are formed in an approximately “c” shape on the upper surface and have a substantially rectangular shape on the inner surface thereof. . Only conductive material forming portions 101a and 101f are formed on the other surface.

The second and fifth resonators 100b and 100e have outer surfaces facing the inner surfaces of the first and sixth resonators 100a and 100f, respectively, and the non-conductive material forming portions 103b and 103e are approximately " It is formed in the shape of "|" and on the outer side it is formed in a substantially rectangular shape. Conductive material non-forming parts 103b and 103e are formed on the inner side in a substantially "-" shape in the height direction, and only conductive material forming parts 101b and 101e are formed on the other side.

The outer surfaces of the second and fifth resonators 100b and 100e are joined to the inner surfaces of the first and sixth resonators 100a and 100f, respectively, and at this time, the outside of the second and fifth resonators 100b and 100e The conductive material non-forming parts 103b and 103e formed on the side and the conductive material non-forming parts 103a and 103f formed on the inner side surfaces of the first and sixth resonators 100a and 100f face each other. In addition, the "ㅣ" shaped conductive material non-forming portions 103b and 103e formed on the upper surfaces of the second and fifth resonators 100b and 100e may have the upper surface of the first and sixth resonators 100a and 100f. Subsequent to the shape of the conductive material non-forming portions 103a and 103f in the shape of a shape, the input port IP and the output port OP having a shape of approximately ". &Quot;

The third and fourth resonators 100c and 100d are positioned on the outer side so as to be in contact with the inner surfaces of the second and fifth resonators 100b and 100e, respectively. It is formed in a substantially "|" shape, and only the conductive material forming portions 101c and 101d are formed on the other surface.

The outer surfaces of the third and fourth resonators 100c and 100d are joined to the inner surfaces of the second and fifth resonators 100b and 100e, respectively, and at this time, the outside of the third and fourth resonators 100c and 100d is The conductive material non-forming parts 103c and 103d formed on the side surfaces and the conductive material non-forming parts 103b and 103e formed on the inner surfaces of the second and fifth resonators 100b and 100e face each other. In addition, the non-conductive material forming portions 103c and 103d formed on the inner surfaces of the third and fourth resonators 100c and 100d face each other.

The band pass filter 100 ′ having the above-described configuration is filtered to have a desired band through each conductive material non-forming part 103a to 103f when a signal is input to the input port IP, and then output to the output port OP. . At this time, the conductive material non-forming parts 103a to 103f formed in the resonators 100a to 100f may be freely changed to have a desired size or shape, thereby generating various types of signals.

In addition, the duplexer according to the present invention may be composed of a plurality of blocks of the same size or different. A representative example thereof is shown in FIG. 3.

As shown in Figures 4 and 5, this embodiment implements a duplexer 100 "consisting of nine resonators. The nine resonators are first, second, third, fourth, fifth, and fifth, respectively. The sixth, seventh, eighth, and ninth resonators (100 "a, 100" b, 100 "c, 100" d, 100 "e, 100" f, 100 "g, 100" h, 100 "i) , In order, to be joined in line with lead or the like.

The first and ninth resonators 100 "a and 100" i are located at the outermost side, and the non-conductive material forming portions 103 "a and 103" i are formed in a substantially "C" shape on the upper surface, Subsequently formed in a substantially rectangular shape. Only conductive material forming portions 101 "a and 101" i are formed on the other surface.

The second and eighth resonators 100 "b and 100" h have outer surfaces that contact the inner surfaces of the first and ninth resonators 100 "a and 100" i, respectively. " b, 103 " h) is formed in a substantially " | " On the inner side, the conductive material non-forming portions 103 "b and 103" h are formed in a substantially thick "ㅣ" shape and a thin "ㅣ" shape in the height direction, and the conductive material forming portions 101 "b, Only 101 "h) is formed.

The outer surfaces of the second and eighth resonators 100 "b and 100" h are joined to the inner surfaces of the first and ninth resonators 100 "a and 100" i, respectively. Conductive material non-forming portions 103 " b, 103 " h formed on the outer surface of the resonators 100 " b, 100 " h and conductive formed on the inner surfaces of the first and ninth resonators 100 " a, 100 " i. The material non-forming portions 101 "a and 101" i come into contact with each other. In addition, the non-conductive portions 103 " b and 103 " h formed on the upper surfaces of the second and eighth resonators 100 " b and 100 " h are formed of the first and ninth resonators 100 " a. And the " c " shaped conductive material non-forming portion 101 " a, 101 " i formed on the upper surface of the " 100 " Each will be configured.

The third and seventh resonators 100 "c and 100" g are positioned on the outer side of the third and seventh resonators, respectively and in contact with the inner sides of the second and eighth resonators 100 "b and 100" h, respectively. "c, 103" g) is formed in a substantially thick or thin "|" shape on both the inner and outer sides, and only the conductive material forming portions 101 "c and 101" g are formed on the remaining surfaces.

The outer surfaces of the third and seventh resonators 100 "c and 100" g are joined to the inner surfaces of the second and eighth resonators 100 "b and 100" h, respectively. Conductive material non-formed portions 103 " c, 103 " g formed on the outer surface of the resonators 100 " c, 100 " g and conductive formed on the inner surfaces of the second and eighth resonators 100 " b, 100 " h. The material non-forming portions 103 "b and 103" h come into contact with each other. In addition, the non-conductive material forming portions 103 " c and 103 " g formed on the inner surfaces of the third and seventh resonators 100 " c and 100 " g face each other.

The fourth resonator (100 "d) is the outer surface is in contact with the inner surface of the third resonator (100" c), the non-conductive material 103 "d is formed in a substantially" | "shape on the upper surface The inner surface is formed in a substantially rectangular shape. The conductive material non-forming portion 103 " d is formed on the outer surface in a substantially thin " " shape in the height direction, and the conductive material forming portion 101 " d is formed on the other surface. ) Is formed.

The fifth resonator 100 "e is positioned so that its outer surface is in contact with the inner surface of the fourth resonator 100" d, and the non-conductive material forming portion 103 "e is formed in a substantially" C "shape on the upper surface thereof. The outer side surface is formed in a substantially rectangular shape. The conductive layer forming portion 101 "e is formed only on the outer side surface.

The outer side surface of the fourth resonator 100 "d and the inner side surface of the fifth resonator 100" e are bonded to each other, and at this time, the non-conductive material forming portion 103 formed on the outer side surface of the fourth resonator 100 "d. " d) and the non-conductive material forming portion 103 " e formed on the inner surface of the fifth resonator 100 " e face each other. In addition, the "ㅣ" shaped conductive material non-forming portion 103 "d formed on the upper surface of the fourth resonator 100" d has a "C" shaped conductive material shape formed on the upper surface of the fifth resonator 100 "e. It is connected with the voice portion 103 "e to form an antenna port ANTP having a shape of" W ".

The sixth resonator 100 " f is positioned such that its outer side is on the inner side of the fifth resonator 100 " e and the inner side is in contact with the outer side of the seventh resonator 100 " g. "f" is similar to the third resonator 100 "c, the conductive material non-forming portion 103" f is formed in a substantially thick or thin "|" shape on the inner and outer sides, the conductive material forming portion 101 only "f) is formed.

The duplexer 100 ″ having the above-described configuration is filtered to have a desired band through each conductive material non-forming portion 100 ″ a to 100 ″ i when a signal is input to the antenna port ANTP. The conductive material non-forming parts 103 " a ~ 103 " i formed in each resonator 100 " a ~ 100 " i are freely changed to have a desired size or shape. It is possible to generate a band of.

The junction dielectric resonator, bandpass filter, and duplexer of the present invention have been described above with reference to a preferred embodiment, but it is apparent to those skilled in the art that various changes, modifications, or variations are possible without departing from the spirit of the present invention.

1 is a schematic perspective view of a bonded dielectric resonator in accordance with a preferred embodiment of the present invention;

FIG. 2 is a schematic exploded perspective view of a bandpass filter according to a preferred embodiment of the present invention constituted by the junction dielectric resonator of FIG. 1; FIG.

3 is a schematic exploded perspective view of the bandpass filter of FIG. 2;

4 is a schematic perspective view of a duplexer according to a preferred embodiment of the present invention constructed with the junction dielectric resonator of FIG.

5 is a schematic exploded perspective view of the duplexer of FIG. 3;

6 is a schematic perspective view of a bandpass filter of the prior art; And

7 is a schematic exploded perspective view of the bandpass filter of FIG. 6.

<Explanation of symbols for main parts of drawing>

100: dielectric resonator 100 ': band pass filter

100 ": duplexer 101,101'a ~ 101'f, 101" a ~ 101 "i: conductive material forming portion

103,103'a ~ 103'f, 103 "a ~ 103" i: non-conductive material

Claims (6)

delete delete A plurality of bonded dielectric resonators are bonded in a line, and at least one resonator of the plurality of resonators and the other public are provided with non-conductive material forming portions that are input ports and output ports on the upper or lower surface thereof. Each of the resonators of the non-conductive material formed on the inner surface or the outer surface of each other is characterized in that the contact with each other, The junction dielectric resonator has a hexagonal shape, a dielectric material is filled in the outer surface, and a conductive material forming portion and a non-conductive material forming portion are formed on an outer surface thereof, and a signal is transmitted through the non-conductive material forming portion. The band pass filter of the conductive material is not formed or the conductive material is removed. The non-conductive portion of claim 3, wherein the input port or the output port is formed of a non-conductive portion having a "-" shape formed in one of the plurality of resonators and a non-conductive portion having a "-" shape formed in the other resonator. Band pass filter, characterized in that formed in the shape of "ㅁ". A plurality of bonded dielectric resonators are bonded in a line, and at least one of the plurality of resonators, the other resonator, and the other resonator are non-conductive material which is a transmission port, a receiving port, and an antenna port on an upper surface or a lower surface thereof. In addition, the plurality of resonators, each of the non-conductive material formed on the inner surface or the outer surface of each other is characterized in that the contact with each other, The junction dielectric resonator has a hexagonal shape, a dielectric material is filled in the outer surface, and a conductive material forming portion and a non-conductive material forming portion are formed on an outer surface thereof, and a signal is transmitted through the non-conductive material forming portion. The duplexer is formed by removing the conductive material or removing the conductive material. 6. The conductive material of claim 5, wherein the transmitting port, the receiving port, or the antenna port is formed of a non-conductive material having a "-" shape formed in one of the plurality of resonators and a resonant shape formed in the other resonator. A duplexer, characterized in that the non-material forming portion is connected to form a "ㅁ" shape.

Images