KR20210130415A - Waveguide filter - Google Patents

Abstract

The present invention relates to a waveguide filter with an enhanced characteristic of a specific pass band through cross-coupling using a resonator that allows cross-coupling to be set-up within a limited space by installing a notch post, allows the complexity of the filter to be simplified by allowing the characteristic or strength of the cross-coupling to be changed according to the location or shape, and a performance of various filters can be implemented. The waveguide filter comprises: a housing; a plurality of resonators; and a partition.

Description

waveguide filter {WAVEGUIDE FILTER}

The present invention relates to a waveguide filter of an antenna, and more particularly, to a waveguide filter using cross-coupling including a resonator.

Recently, as the types of wireless communication services increase, the frequency environment is becoming more complex. Since a frequency for wireless communication is limited, there is a need to effectively utilize a frequency resource as close as possible to a wireless communication channel.

However, since signal interference occurs in an environment in which various wireless communication services are provided, the antenna includes a band filter for a specific band in order to minimize signal interference between adjacent frequency resources.

In general, in order to improve the attenuation characteristics of the band filter, it is essential to apply a transmission zero (hereinafter, referred to as 'notch'), which is achieved by applying cross coupling between non-adjacent resonant elements. implement

Among RF filters, the dielectric waveguide filter includes a resonator for notch adjustment in a dielectric block surrounded by a conductive film. The resonator is designed to limit a specific frequency by giving resonant characteristics to electromagnetic waves.

At this time, when cross-coupling is performed across an even number of resonators, a symmetrical notch is generated in the passband, and when cross-coupling is performed across an odd number of resonators, one notch is generated on the left or right side depending on the type of coupling. It is common.

The notch implementation of the communication filter needs to be implemented in various ways depending on the performance of the communication system, but the performance is limited in implementing a filter suitable for the characteristics of the communication system.

Accordingly, it is necessary to set the filter differently depending on the communication system so that the notch can be implemented on the left and right sides of a specific passband in the antenna.

In particular, in implementing the notch on the left and right sides of the passband with one cross coupling, if a strong coupling is required on the left side, which is not symmetrical, and a weak coupling on the right side, it is inevitable to use two cross coupling structures. However, the implementation of these two cross-couplings acts as a lot of restrictions on the filter design, and in particular, it becomes a bigger problem in the ceramic filter structure, where it is difficult to insert a structure to implement the cross-coupling inside the filter.

In addition, in order to satisfy the desired characteristics by implementing two notches on the left or right side of the passband, two cross-couplings passing through an odd number of resonators must be implemented, so there are many design restrictions.

In addition, the notch structure between the resonators, which plays a similar role to the resonator, generates spurious in front of the band, and this has a problem in that a specific section communication system is constrained according to a level and a location.

Republic of Korea Patent Publication No. 10-2017-0112583 (published on October 12, 2017)

The present invention has been devised to solve the above technical problem, and an object of the present invention is to provide a waveguide filter with enhanced characteristics of a specific passband through cross-coupling using a resonator.

Another object of the present invention is to provide a waveguide filter designed to suppress generation of spurious occurring within a band range or to maximize spurious spacing within a band range.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

The waveguide filter according to an embodiment of the present invention configured as described above is provided with a dielectric material having a predetermined dielectric constant and includes a housing including a plurality of resonant blocks, and a plurality of resonant blocks provided in the housing, respectively. a plurality of resonators each functioning as a single resonator by the resonator posts of The resonator block provided with the first zone resonator post and the first zone resonator post provided between the second zone resonator posts, the outer surface of which is provided to match the other surface of the housing opposite to the first zone resonator post. Includes a partition wall provided to partition all or a part of the resonance block provided with.

A waveguide filter according to another embodiment of the present invention is provided with a dielectric material having a predetermined dielectric constant, and includes a housing including a plurality of resonant blocks, and a plurality of resonator posts respectively provided in the plurality of resonant blocks provided in the housing. A plurality of resonators each functioning as a single resonator, at least one of the plurality of resonators, a first zone resonator post installed to match one surface of the housing, at least one of the plurality of resonators, wherein the outer surface is the second A second zone resonator post installed to match the other surface of the housing opposite to the first zone resonator post, and a second zone resonator post provided between the second zone resonator post, the outer surface matching the one surface of the housing opposite to the second zone resonator post Includes a notch post installed.

A waveguide filter according to another embodiment of the present invention is provided with a dielectric material having a predetermined dielectric constant, a housing forming a plurality of resonant blocks, and a plurality of resonators formed by resonator posts provided in the plurality of resonator blocks, respectively. , a plurality of barrier ribs provided to partition all or a part of an adjacent resonant block among the plurality of resonator blocks, and a resonator post provided in a resonator not separated by the plurality of barrier ribs among the plurality of resonators (hereinafter referred to as "second and a notch post provided between the regional resonator posts (abbreviated as "regional resonator posts") so that the effect of coupling between the second regional resonator posts is reversed and implemented, wherein the second regional resonator posts are located on the plurality of partition walls. A resonator post (hereinafter, referred to as a “first zone resonator post”) provided in the plurality of resonators divided by

Here, the notch post may be provided on one surface of the same housing as the first zone resonator post.

Also, the second zone resonator post and the first zone resonator post may have the same size.

In addition, the notch post may be formed to have a larger volume than that of the second zone resonator post and the first zone resonator post.

In addition, the amount of the coupling may be adjusted according to a shape and size of a resonator post adjacent to the second zone resonator post among the first zone resonator posts.

According to the waveguide filter according to an embodiment of the present invention, the coupling converted to the effect of cross coupling can be implemented by inverting the opening direction of the adjacent resonator posts or by providing a predetermined structure therebetween, so the pass band It has the effect that the design of the notches formation on both sides is easy.

1 is a perspective view showing a waveguide filter according to an embodiment of the present invention;
Figure 2 is a perspective view of the projection of Figure 1,
3 is a projection view of a top view, a front view and a side view of FIG. 1 ;
4 is a cross-sectional view taken along AA, BB and CC;
Figure 5a is a cutaway perspective view taken along line AA of Figure 4,
Figure 5b is a cutaway perspective view taken along line BB of Figure 4,
Figure 5c is a cutaway perspective view taken along line CC of Figure 4,
6 is a schematic diagram and a result table for explaining the principle of forming notches at both ends through L-coupling and C-coupling on both left and right sides of a pass band using a waveguide filter according to an embodiment of the present invention;
7 is a circuit diagram of a waveguide filter according to an embodiment of the present invention;
8 is a graph showing the frequency characteristics according to FIG. 7,
9 is a perspective view of a waveguide filter according to the first comparative example;
10 is a circuit diagram of a waveguide filter according to the first comparative example,
11 is a graph showing the frequency characteristic according to FIG. 10,
12 is a perspective view of a waveguide filter according to a second comparative example;
13 is a circuit diagram of a waveguide filter according to a second comparative example;
14 is a graph showing the frequency characteristic according to FIG. 13,
15 is a perspective view of a waveguide filter according to Comparative Example 3;
16 is a circuit diagram of a waveguide filter according to Comparative Example 3;
17 is a graph showing frequency characteristics according to FIG. 16 .

Advantages and features of the present invention and methods of achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only these embodiments allow the disclosure of the present invention to be complete, and common knowledge in the art to which the present invention pertains It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout.

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

1 is a perspective view showing a waveguide filter according to an embodiment of the present invention, FIG. 2 is a projected perspective view of FIG. 1, FIG. 3 is a plan view, a front view, and a side view of FIG. 1, and FIG. 4 is AA, It is a cross-sectional view taken along BB and CC, FIG. 5A is a cut-away perspective view taken along line AA of FIG. 4, FIG. 5B is a cut-away perspective view taken along line BB of FIG. 4, and FIG. 5C is a cut-away perspective view taken along line CC of FIG. is a perspective view.

The communication antenna includes a filter for filtering a signal of a specific passband. As the filter, a cavity filter, a waveguide filter, etc. may be used according to characteristics, but in the embodiment of the present invention, the waveguide filter provided in the antenna will be mainly described.

1 to 5c , the waveguide filter 100 according to an embodiment of the present invention includes a plurality of resonance blocks 11 to 16 .

The waveguide filter 100 includes at least four or more resonance blocks, and for example, may include 4 to 20 resonance blocks in one filter. The waveguide filter 100 according to an embodiment of the present invention will be described with reference to FIGS. 1 to 5C , exemplifying the configuration of six resonant blocks 11 to 16 .

In the waveguide filter 100, a plurality of resonance blocks 11 to 16 are formed in one housing 99, and each resonance block 11 to 16 may be divided by a partition wall 40, a part of which will be described later. .

The inside of each resonant block 11 to 16 is filled with a dielectric material, and ceramic or air may be used as the dielectric material, but other dielectric materials may also be used.

The plurality of resonator blocks 11 to 16 each operate as one resonator, and a waveguide filter composed of four resonators can be formed through the four resonator blocks. In the waveguide filter 100 according to an exemplary embodiment of the present invention, six resonator blocks 11 to 16 are provided, and thus the six resonators 1 to 6 can operate.

Meanwhile, resonator posts 31 to 36 may be provided in each resonator block 11 to 16 . The resonator posts 31 to 36 may be provided in a form in which a dielectric different from the dielectric constant of the resonator blocks 11 to 16 is sandwiched, and since air is a type of dielectric having a predetermined dielectric constant, the resonator posts 31 to 36 On the premise that has a permittivity of air, each resonator post 31 to 36 may be formed in the form of an empty space in which a part of each resonator block 11 to 16 is removed.

Hereinafter, for convenience of description, each of the resonator posts 31 to 36 will be described on the premise that they are provided in a hollow shape into which a dielectric having a dielectric constant of air is inserted. The partition wall 40, which will be described later, should be interpreted in the same way.

If each of the resonator posts 31 to 36 is air, it means that they are provided in the form of an empty space in the housing 99, cut or deleted, and each of the resonator posts 31 to 36 has a predetermined dielectric constant. When provided as a dielectric, it means that the shape of each resonator post 31 to 36 is inserted into the housing 99 .

The resonator posts 31 to 36 may be provided on one surface (upper surface) or the other surface (lower surface) of the housing 99 constituting each resonance block 11 to 16 . Here, the precise meaning that the resonator posts 31 to 36 are provided on one surface and the other surface of the housing 99 means that the outer surface of each resonator post 31 to 36 is the outer surface (one surface or the other surface) of the housing 99 and It may be defined as being provided inside the housing 99 to match.

On the other hand, when the first resonator post 31 is installed on one surface (upper surface) of the first resonator block 11, the other resonator posts 32 to 36 are also located on one surface (upper surface) of each resonator block 12 to 16. can be installed. That is, the outer surfaces of all resonator posts 31 may be provided to match one surface of the housing 99 .

However, it is not necessary that all of the resonator posts 31 to 36 be installed on the same side of the housing 99 . For example, as shown in FIGS. 1 to 5C , the first resonator post 31 of the first resonator 1 , the second resonator post 32 of the second resonator 2 , and the fifth resonator 5 ) of the fifth resonator post 35 and the sixth resonator post 36 of the sixth resonator 6 are installed on one surface (upper surface) of the housing 99, and the third resonator post of the third resonator 3 ( 33) and the fourth resonator post 34 of the fourth resonator 4 may be installed on the other surface (lower surface) of the housing 99 . Here, the notch post 50, which will be described later, is one surface ( top) can be installed.

When each of the resonator posts 31 to 36 and the notch post 50 is made of air having a predetermined dielectric constant, it means that they are installed on one surface (upper surface) or the other surface (lower surface) of the housing 99, each opening direction is It means that it is formed to be opened toward one surface (upper surface) or the other surface (lower surface) of the housing 99 . Hereinafter, when the opening directions of each of the resonator posts 31 to 36 are different, the term 'inversion' will be used.

The first to sixth resonator blocks 11 to 16 are coupled to the first to sixth resonator posts 31 to 36 and operate as independent resonators, respectively. Accordingly, first to sixth resonators (1 to 6 in FIG. 1 to be described later) may be formed in one housing 99 .

A partition wall 40 may be formed between each of the resonance blocks 11 to 16, and the size of each resonance block 11 to 16 and the size (width, length) and location of the partition 40 The resonance characteristic may be varied.

The partition wall 40 may include a first partition wall 41 and a second partition wall 42 as shown in FIGS. 1 to 3 .

The first partition wall 41 completely partitions the first resonance block 11 and the sixth resonance block 16 , and partially partitions the second resonance block 12 adjacent to the first resonance block 11 . and may be cut in a cross (+) shape to partially partition the fifth resonance block 15 adjacent to the sixth resonance block 16 .

The second partition wall 42 partially partitions the third resonance block 13 adjacent to the second resonance block 12 , and the fifth resonance block 15 adjacent to the second resonance block 12 . English letters to partially partition, partially partition the fourth resonance block 14 adjacent to the fifth resonance block 15, and partially partition the second resonance block 12 adjacent to the fifth resonance block 15 The incision may be formed in a T-shaped (T) shape.

For reference, a partition wall separating the third resonance block 13 and the fourth resonance block 14 is not formed, but the third resonance block 13 and the fourth resonance block 14 are formed by a notch post 50 to be described later. (14) can be distinguished.

Hereinafter, among the first resonator posts 31 to 36, the third resonator post 33 and the fourth resonator post which are not partitioned by the first partition wall 41 and the second partition wall 42 ( 34) is abbreviated as “second zone resonator post”, and the remaining resonator posts (first resonator post 31, second resonator post 32, fifth resonator post 35 and the second resonator post) other than the second zone resonator post. 6 resonator post 36) will be abbreviated as "the first zone resonator post" and will be described separately.

Referring to FIG. 3 , the housing 99 is formed to have a predetermined thickness between an approximately upper surface (one surface) and a lower surface (the other surface), and may be formed in a rectangular parallelepiped shape having a rectangular horizontal cross-section.

Hereinafter, for convenience of explanation, a relatively long side of the housing 99 is referred to as a 'long side', and a side having a relatively shorter length than the long side is referred to as a 'short side', and between the short side of one side and the short side of the other side. The direction referred to is called the 'length direction', the direction between the long side of one side and the long side of the other side is called the 'width direction', and the direction between the one surface (upper surface) and the other surface (lower surface) of the housing is called the 'thickness direction'.

Referring to FIG. 3 , the first partition wall 41 of the partition wall 40 extends a predetermined length in the longitudinal direction from the center of one short side, and the second resonator post 32 and the fifth resonator post 35 are provided in the center. The center of the first resonator post 31 and the second resonator post 32 at any one point of the 1-1 cut-out 41a extending in the longitudinal direction to be close to the portion and the 1-1 cut-out 41a It may include a portion and a 1-2 incision portion 41b extending in the width direction to be close to the central portion of the fifth resonator post 35 and the sixth resonator post 36 .

The first partition wall 41 is cut and formed so as to extend in the longitudinal direction from the center of one short side of the housing 99 by the 1-1 cut-out 41a and the 1-2 cut-out part 41b, thereby forming a 'cross ( +)' shape.

The 1-1 cutout 41a completely partitions the first resonator post 31 and the sixth resonator post 36, as well as the second resonator post 32 and the second resonator post 32, as shown in FIG. 5 It serves to partition a part of the resonator post (35).

As shown in FIG. 3 , the 1-2 cut-out portion 41b divides a portion of the first resonator post 31 and the second resonator post 32 , and includes the sixth resonator post 36 and It serves to partition a part of the fifth resonator post (35).

Meanwhile, referring to FIG. 3 , the second partition wall 42 of the partition wall 40 includes a fourth resonator post 34 and a fifth resonator post 34 and a fifth resonator post 34 at the center of the second resonator post 32 and the third resonator post 33 . The 2-1 cut-out portion 42a, which is cut to extend a predetermined length in the width direction toward the central portion of the resonator post 35, and the central portion of the 2-1 cut-out portion 42a toward the short side of one side of the housing 99 It may include a 2-2 incision portion 42b that is cut to extend a predetermined length in the longitudinal direction.

The second partition wall 42 is formed in an overall 'English letter T' shape inside the other short side of the housing 99 by the 2-1 cut-out portion 42a and the 2-2 cut-out portion 42b. can be

As shown in FIG. 3 , the 2-1 cut-out portion 42a partitions a portion of the second resonator post 32 and the third resonator post 33 , and includes the fourth resonator post 34 and It serves to partition a part of the fifth resonator post (35).

As shown in FIG. 3 , the 2-2 cut-out portion 42b serves to partition a portion of the second resonator post 32 and the fifth resonator post 35 .

Here, the separation distance between the tip of the first 1-1 cut-out 41a of the first partition 41 and the tip of the 2-2 cut-out 42b of the second partition 42 is the second resonator post 32 . and a length equal to the diameter of the fifth resonator post 35 . However, as will be described later, it is natural that the separation distance may be designed differently depending on the filter performance design.

Hereinafter, the resonator post (third resonator post 33) of the resonators (the third resonator 3 and the fourth resonator 4) not separated by the plurality of partition walls 40 among the plurality of resonators 1 to 6 and the fourth resonator post 34) is abbreviated as "second zone resonator post", and the resonator posts of the plurality of resonators which are at least partially separated by the plurality of partition walls 40 among the plurality of resonators 1 to 6 are " Abbreviated as "the first zone resonator post", each will be separately described.

Meanwhile, as shown in FIGS. 1 to 5C , the waveguide filter 100 may include an input post 21 to which a signal is input and an output post 22 to which a signal is output.

The input post 21 and the output post 22 are formed in different resonance blocks, respectively, and the input post 21 and the output post 22 may be installed on any one surface in the resonance block, respectively.

More specifically, the input post 21 and the output post 22 may be respectively formed in the first resonance block 11 and the sixth resonance block 16 which are resonance blocks at both ends of the waveguide filter 100 . . The input post 21 may be formed in the first resonance block 11 , and the output post 22 may be formed in the sixth resonance block 16 .

The signal input through the input post 21 is sequentially first resonator post 31 - second resonator post 32 - third resonator post 33 - fourth resonator post 34 - fifth resonator post ( 35) - It is output while filtering the frequency through the output post 22 via the sixth resonator post 36 .

On the other hand, the waveguide filter 100 may further include a notch post 50 provided to be implemented by switching to the effect of cross-coupling when implementing coupling between adjacent resonators. The notch post 50 may be positioned between the third resonator post 33 and the fourth resonator post 34 that are C-notch posts 33 and 34 .

In general, when the notch post 50 is not provided between the third resonator post 33 and the fourth resonator post 34 when the coupling is implemented, the third resonator post 33 and the fourth resonator are adjacent resonators. The posts 34 are essentially adjacently coupled and operate as an inductive coupling.

Here, in order to operate as a capacitive coupling between the third resonator post 33 and the fourth resonator post 34, cross-coupling is performed across odd or even resonator posts, or at least adjacent to each other. When the adjacent resonator posts are coupled, the opening directions of the adjacent resonator posts are reversed, and a partition wall (refer to reference numeral 40 in FIGS. 1 and 2 ) is provided between them, or a structure corresponding to the opening with the adjacent resonator posts. It can be seen that the notch post 50 having the mutually inverted direction must be provided.

If the notch post 50 is not provided between the third resonator post 33 and the fourth resonator post 34 adjacent to each other, as described above, the third resonator post 33 and the fourth resonator post 34 . (34) operates as an inductive coupling by an adjacent coupling. However, as in the waveguide filter 100 according to an embodiment of the present invention, a notch post ( 50), notches may be formed on both left and right sides of the pass band when coupling between the third resonator post 33 and the fourth resonator post 34 adjacent to each other is implemented.

To this end, the second zone resonator post may be provided on the other surface opposite to one surface of the housing 99 provided with the first zone resonator post. That is, the second zone resonator post provided with the third resonator post 33 and the fourth resonator post 34 with the notch post 50 interposed therebetween the rest of the first zone resonator post (first resonator post). 31 , the second resonator post 32 , the fifth resonator post 35 , and the sixth resonator post 36 ) may be formed in the housing 99 to open in a different direction.

In this case, the notch post 50 may be provided on the same surface of the housing 99 as the first zone resonator post. That is, the notch post 50 may be formed to open in a different direction from the third resonator post 33 and the fourth resonator post 34 that are the second zone resonator posts.

Meanwhile, the second zone resonator post and the first zone resonator post may have the same size. That is, although there is a difference in that the second zone resonator post and the first zone resonator post are formed to be opened through different surfaces of the housing 99, the overall size may be the same. However, the second zone resonator post and the first zone resonator post do not necessarily have to be formed in the same shape, and it is natural that they may be formed in different shapes depending on the filter design according to the implementation of the coupling. At this time, among the first zone resonator posts, the resonator posts adjacent to the second zone resonator post (for example, the second resonator post 32 adjacent to the third resonator post 33 and the fourth resonator post 34 are adjacent to each other) The amount of the coupling may be adjusted according to the shape and size of the fifth resonator post 35 that corresponds to this.

Here, although the notch post 50 is not the partition wall 40 having a structure that completely penetrates one surface and the other surface of the housing 99, it is formed to have an opening surface in a different direction from that of the second zone resonator post, so that when implementing a coupling It can be seen that when the coupling between the third resonator post 33 and the fourth resonator post 34 is implemented, the partition wall 40 forms notches on the left and right sides of the pass band.

In addition, a part of the partition wall 40 is partitioned between the second resonator post 32, which is one of the first zone resonator posts, and the third resonator post 33, which is one of the second zone resonator posts, of the first zone resonator post. The partition wall 42 that partially partitions one of the fifth resonator post 35 and the fourth resonator post 34 that is one of the second zone resonator posts is the first zone resonator post, the second resonator post 32, and the fifth resonator post. Even when the opening direction of the resonator post 35 and the opening direction of the third resonator post 33 and the fourth resonator post 34, which are the second zone resonator posts, are opposite to each other, there are notches on the left and right sides of the pass band when implementing the coupling. can form.

That is, the opening direction of the second resonator post 32 , which is one of the first zone resonator posts, is formed to be opened through one surface of the housing 99 and is provided adjacent to the second resonator post 32 , the second zone resonator The opening direction of the third resonator post 33, which is one of the posts, is formed to be opened through the other surface of the housing 99 opposite to the second resonator post 32, and the second resonator post 32 and the third resonator post are formed. (33) By providing the 2-1 cut-out portion 42a of the second partition wall 42 to partially partition between them, notches can be formed on both left and right sides of the pass band when the coupling is implemented.

In addition, the opening direction of the fifth resonator post 35 , which is one of the first zone resonator posts, is formed to be opened through one surface of the housing 99 and is provided adjacent to the fifth resonator post 35 , the second zone resonator The opening direction of the fourth resonator post 34, which is one of the posts, is formed to open through the other surface of the housing 99 opposite to the fifth resonator post 35, and the fifth resonator post 35 and the fourth resonator post By providing the second-first cut-out portion 42a of the second partition wall 42 to partially partition between the 34 , notches may be formed on both left and right sides of the pass band when the coupling is implemented.

Here, the notch post 50 may be formed to have a larger volume than the second zone resonator post and the first zone resonator post. However, the shape of the notch post 50 is not necessarily limited as described above, and it will be natural that it may be determined according to the filter design according to the implementation of the coupling. At this time, the amount of coupling may be adjusted according to the shape and size of the notch post 50 .

In addition, as shown in FIG. 3 , the notch post 50 is a cylinder (or a cylinder) such that a position corresponding to an arbitrary reference line passing through the center of the third resonator post 33 and the fourth resonator post 34 is concentric. It may be provided in the form of a circular groove).

Here, the notch post 50 is formed to be opened through one surface of the housing 99 , and is preferably provided in a form that is shielded from the other surface of the housing 99 . That is, the notch post 50 does not completely penetrate the housing 99 in the thickness direction.

5A, the first resonator post 31 and the second resonator post 32 among the first zone resonator posts are provided to be spaced apart by a predetermined length in the longitudinal direction from the short side of one side of the housing 99 toward the short side of the other side. , the opening direction may be formed to open toward one surface (upper surface) of the housing 99 .

In addition, a third resonator post 33 is provided as one of the second zone resonator posts as one side of the second resonator post 32 in the longitudinal direction among the first zone resonator posts and adjacent to the other short side of the housing 99, The opening direction may be formed to open toward the other surface (lower surface) of the housing 99 .

Here, the input post 21 is provided on the other surface opposite to one surface of the housing 99 on which the first resonator post 31 is formed, and the opening direction may be formed to face the other surface (lower surface) of the housing 99 . .

Referring to FIG. 5B , the third resonator post 33 and the fourth resonator post 34, which are the second zone resonator posts, are each formed so that the opening direction is opened toward the other surface (lower surface) of the housing 99, In the middle between the third resonator post 33 and the fourth resonator post 34 , the notch post 50 may be formed so that the opening direction is opened toward one surface (upper surface) of the housing 99 .

And, referring to FIG. 5C , as the other side in the longitudinal direction of the fourth resonator post 34, which is one of the second zone resonator posts, a fifth resonator post 35, which is one of the first zone resonator posts, is provided, in the opening direction. The 65th resonator that is formed to open toward one surface (upper surface) of the housing 99 and is one of the first zone resonator posts adjacent to one short side of the housing 99 as the other longitudinal side of the fifth resonator post 34 . The post 36 may be formed so that the opening direction is opened toward one surface (top surface) of the housing 99 .

Here, the output post 22 is provided on the other surface opposite to one surface of the housing 99 on which the sixth resonator post 36 is formed, and the opening direction may be formed to face the other surface (lower surface) of the housing 99 . .

6 is a schematic diagram and a result table for explaining the principle of forming notches at both ends through L-coupling and C-coupling on both left and right sides of a pass band using a waveguide filter according to an embodiment of the present invention.

As shown in FIG. 6, regardless of whether it is L-coupling or C-coupling, the 3rd resonance moves the frequency to a lower side than the pass band and applies a notch only above the resonant frequency, so only the -90 degree phase apply

First, the Below Resonance of L-coupling is -270 degrees in the case of Path 1-2-(3)-4-5 and -90 degrees in the case of Path 1-5, so the phase difference is 180 degrees, The result is obtained, and the Above Resonace of L-coupling is -270 degrees in the case of Path 1-2-(3)-4-5 and -90 degrees in the case of Path 1-5, so the phase difference is 180 degrees. With the result of out of phase, notches can be formed at both ends of the passband.

Next, the Below Resonance of C-coupling is +90 degrees in the case of Path 1-2-(3)-4-5 and -90 degrees in the case of Path 1-5, so the phase difference is 180 degrees and out of phase , and the Above Resonance of C-coupling is -270 degrees for Path 1-2-(3)-4-5 and -90 degrees for Path 1-5, so the phase difference is 180 degrees. The result of out of phase is obtained by writing, and notches can be formed at both ends of the passband.

The operation and effect of the waveguide filter according to an embodiment of the present invention according to the principle of forming notches at both ends of the pass band as described above will be described in more detail.

7 is a circuit diagram of a waveguide filter according to an embodiment of the present invention, and FIG. 8 is a graph showing frequency characteristics according to FIG. 7 .

Referring to FIG. 7 , coupling may be implemented in eight places until a predetermined signal input through the input post 21 is output through the output post 22 .

That is, it operates as an inductive coupling (L1) between the input post 21 and the first resonator post 31, and an inductive coupling (L1) between the first resonator post 31 and the second resonator post 32 L3), operated as a capacitive coupling C10 between the second resonator post 32 and the third resonator post 33, and a capacitive coupling between the third resonator post 33 and the notch post 50. Operated as a sexual coupling (C8), operated as a capacitive coupling (C9) between the notch post (50) and the fourth resonator post (34), the fourth resonator post (34) and the fifth resonator post (35) ) is operated as a capacitive coupling (C11) between It is operated with an inductive coupling (L15) between the output posts (22).

As shown in FIG. 8 , if this is expressed as a graph showing frequency characteristics, notches are formed on both sides of the pass band, and the level of spurs formed on the left side of the pass band is significantly lowered, so that the level is further pushed to the left to reduce communication restrictions be able to do

9 is a perspective view of the waveguide filter according to the first comparative example, FIG. 10 is a circuit diagram of the waveguide filter according to the first comparative example, and FIG. 11 is a graph showing frequency characteristics according to FIG. 10 .

As shown in FIG. 9 , the waveguide filter 1000 according to the first comparative example is compared with the waveguide filter 100 according to the embodiment of the present invention, and the third resonator post 1033 which is a second zone resonator post. ) and the opening direction of the fourth resonator post 1034 is formed to face the same surface (top surface) of the housing 99 as the first zone resonator post, and the notch post 1050 is in one embodiment of the present invention. It was configured in the same way as the waveguide filter 100 according to the present invention.

According to the waveguide filter 1000 according to this first comparative example, as shown in FIG. 10 , all eight couplings from the input post 1021 to the output post 1022 operate as inductive couplings. Able to know. This is despite the presence of the notch post 1050 between the third resonator post 1033 and the fourth resonator post 1034, the notch post 1050 is the waveguide filter 100 according to an embodiment of the present invention. The results show that, unlike performing the role of the partition wall 40 or the notch post 50, which is a structure corresponding thereto, it should be understood that one resonator post is additionally provided.

However, referring to FIG. 11 , which is a graph showing the frequency characteristics of the waveguide filter 1000 according to the first comparative example, when cross-coupling is implemented despite the above-described structure, notches may be formed on both left and right sides of the pass band. . However, the level of spurs formed on the left side of the pass band is usually high, so communication restrictions in a specific band are severe, and the spurs are close to the pass band, so the notch above the pass band is raised higher than the notch below the pass band can be known

12 is a perspective view of the waveguide filter according to the second comparative example, FIG. 13 is a circuit diagram of the waveguide filter according to the second comparative example, and FIG. 14 is a graph showing frequency characteristics according to FIG. 13 .

As shown in FIG. 12 , the waveguide filter 2000 according to the second comparative example is compared with the waveguide filter 100 according to the embodiment of the present invention, and a third resonator post 2033 which is a second zone resonator post. ) and the fourth resonator post 2034 are formed to open so that the opening direction faces the same surface (top surface) of the housing 99 as the first zone resonator post, and the notch post 2050 is the second zone resonator post. The third resonator post 2033 and the fourth resonator post 2034 were opened to face the other surface (lower surface) of the housing 99 opposite to the opening direction.

According to the waveguide filter 1000 according to the second comparative example, as shown in FIG. 13 , the second region resonator post among the eight couplings from the input post 1021 to the output post 1022 is Between the third resonator post 2033 and the notch post 2050 and between the notch post 2050 and the fourth resonator post 2034, which is the other one of the second zone resonator posts, operates as a capacitive coupling, and the rest operates as an inductive coupling. It can be seen that the coupling works. This is by forming the opening direction of the notch post 2050 to be opposite to the opening direction of the third resonator post 2033 and the fourth resonator post 2034, so that the notch post 2050 is formed according to an embodiment of the present invention. It can be seen that the partition wall 40 in the waveguide filter 100 serves as a structure corresponding to the partition wall 40 .

Referring to FIG. 14 , which is a graph showing the frequency characteristics of the waveguide filter 2000 according to the second comparative example, notches may be formed on both left and right sides of the pass band. In addition, it can be seen that the spurs that are normally formed on the left side of the pass band have a lower level compared to the first comparative example, so that the notches on both sides of the pass band can be balanced to a certain extent, and it can be seen that the spurs are further pushed to the left side of the pass band. Even compared to the waveguide filter 100 according to an embodiment of the present invention, it is confirmed that the passband is closer to the passband and the level is higher.

15 is a perspective view of a waveguide filter according to Comparative Example 3, FIG. 16 is a circuit diagram of a waveguide filter according to Comparative Example 3, and FIG. 17 is a graph showing frequency characteristics according to FIG. 16 .

As shown in FIG. 15 , the waveguide filter 3000 according to the third comparative example is compared with the waveguide filter 100 according to the embodiment of the present invention, and the third resonator post 3033 which is the second zone resonator post. ) and the opening direction of the fourth resonator post 3034 are configured to be the same, but the opening direction of the notch post 1050 is opened to the other surface (lower surface) of the housing 99 .

According to the waveguide filter 3000 according to the third comparative example, as shown in FIG. 16 , the first region in which the opening direction is reversed among the eight couplings from the input post 3021 to the output post 3022 . Between the second resonator post 3032 that is a resonator post and the third resonator post 3033 that is a second zone resonator post, and a fourth resonator post 3034 that is a second zone resonator post and a fifth resonator post that is a first zone resonator post It can be seen that only the coupling between 3035 operates as a capacitive coupling, and all other couplings operate as an inductive coupling. This is the second incision portion 42a of the second partition wall 42 between the second resonator post 3032 and the third resonator post 3033 and between the fifth resonator post 3035 and the fourth resonator post 3034 . ) can be assumed to act as a structure giving the effect of cross-coupling, and at the same time, despite the presence of the notch post 3050 present between the third resonator post 3033 and the fourth resonator post 3034, Unlike the notch post 3050 serving as the partition wall 40 in the waveguide filter 100 according to an embodiment of the present invention or the notch post 50, which is a structure corresponding thereto, simply one resonator post is added. The results show that it should be understood as more equipped with

Referring to FIG. 17 , which is a graph showing the frequency characteristics of the waveguide filter 3000 according to the third comparative example, it can be seen that the graph is very similar to FIG. 11 , which is a graph of the first comparative example. This is when the opening directions of the third resonator post 3033 and the fourth resonator post 3034 and the notch post 3050, which are second zone resonator posts provided adjacent to the notch post 3050, are not mutually reversed. , it can be presumed to disprove that it is difficult to eliminate the adverse effects of spurs.

As described above, the waveguide filter 100 according to an embodiment of the present invention is formed by inverting the opening directions of the first zone resonator posts 31 , 32 , 35 , 36 and the second zone resonator posts 33 and 34 . In addition, a structure such as a partition wall 42 is provided between the resonator posts 33 and 34 in the second zone, and a notch post 50 in which the opening direction is reversed between the resonator posts 33 and 34 in the second zone. ), has the advantage of being able to form notches on both sides of the pass band through a simpler structural design.

Even though it has been described that all components constituting the embodiment of the present invention operate in combination as one, the present invention is not necessarily limited to this embodiment. As long as it is within the scope of the object of the present invention, depending on the embodiment, all components may operate by selectively combining one or more.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains.

① to ⑥: resonators 11 to 16: resonance block
21: input post 22: output post
31 to 36: resonator post 31, 32, 35, 36: first zone resonator post
33,34: second zone resonator post 40: bulkhead
41: first partition wall 41a: first incision 1-1
41b: first 1-2 cut-out 42: second partition wall
42a: 2-1 incision 42b: 2-2 incision
50: notch post 99: housing
100: waveguide filter 1000: first comparative example
2000: 2nd comparative example 3000: 3rd comparative example

Claims (7)

a housing provided with a dielectric having a predetermined dielectric constant and including a plurality of resonance blocks;
a plurality of resonators each functioning as a single resonator by a plurality of resonator posts provided on each of the plurality of resonator blocks provided in the housing; and
A first zone resonator post installed so that an outer surface of the plurality of resonator posts matches one surface of the housing, and adjacently coupled to the first zone resonator post, the outer surface of which is opposite to the first zone resonator post A partition wall provided between the second zone resonator posts installed to match the other surface of the housing to partition all or a part of the resonance block provided with the first zone resonator post and the resonator block provided with the first zone resonator post. ; Including, a waveguide filter. a housing provided with a dielectric having a predetermined dielectric constant and including a plurality of resonance blocks;
a plurality of resonators each functioning as a single resonator by a plurality of resonator posts provided on each of the plurality of resonator blocks provided in the housing;
at least one of the plurality of resonators, a first zone resonator post having an outer surface installed to match one surface of the housing;
a second zone resonator post, at least one of the plurality of resonators, provided with an outer surface matching the other surface of the housing opposite to the first zone resonator post; and
a notch post provided between the second zone resonator posts, the outer surface of which is installed to match one surface of the housing opposite to the second zone resonator post; Including, a waveguide filter. a housing provided with a dielectric material having a predetermined dielectric constant and forming a plurality of resonance blocks;
a plurality of resonators formed by resonator posts respectively provided in the plurality of resonator blocks;
a plurality of partition walls provided to partition all or a part of an adjacent resonance block among the plurality of resonance blocks; and
Effect of coupling between resonator posts (hereinafter, abbreviated as "second zone resonator posts") provided in resonators not separated by the plurality of partition walls among the plurality of resonators a notch post provided to be inverted and implemented; including,
The second zone resonator post is on the other surface opposite to one surface of the housing provided with the resonator posts (hereinafter, abbreviated as "first zone resonator post") provided in the plurality of resonators separated by the plurality of partition walls. provided, a waveguide filter. 4. The method according to claim 2 or 3,
The notch post is provided on one surface of the same housing as the first zone resonator post. 4. The method according to claim 2 or 3,
and the second zone resonator post and the first zone resonator post are formed to be the same size. 4. The method according to claim 2 or 3,
wherein the notch post is formed to have a larger volume than the second zone resonator post and the first zone resonator post. 4. The method according to claim 2 or 3,
and the amount of the coupling is adjusted according to a shape and size of a resonator post adjacent to the second zone resonator post among the first zone resonator posts.

Images