KR101884984B1 - Ceramic waveguide resonator filter - Google Patents

Abstract

The present invention relates to a ceramic waveguide resonator filter that is easy to fabricate, and more particularly, to a ceramic waveguide resonator filter that has a constant height of the ceramic waveguide structure and is easy to manufacture. According to the present invention, in a waveguide structure in which a ceramic waveguide resonator filter is fabricated by using a ceramics having a high dielectric constant different from that of a conventional method, a filter is implemented using a new input / output single- It is possible to manufacture the filter more simply and easily.

Description

Ceramic waveguide resonator filter

The present invention relates to a ceramic waveguide resonator filter that is easy to fabricate, and more particularly, to a ceramic waveguide resonator filter that has a constant height of the ceramic waveguide structure and is easy to manufacture.

In general, a bandpass filter consists of a resonator, a coupling structure between the resonators, a coupling structure between the input and output stages and the resonator, and a transition connected to the input and output stages, if necessary.

Particularly, as a method of designing a filter using a resonator having a high dielectric constant ceramic waveguide structure, there are Reddy Vangala, Dielectric Waveguide Filter with Direct Coupling and Alternative Cross-Coupling, US Pat. US 2012/0286901 A1, Nov. 15, and 2012, respectively.

According to this, generally, the entire filter structure is manufactured by making two ceramic parts and attaching two parts. If a sixth filter is fabricated, the input part, the three resonators, the coupling structure between the input and the resonator, and the coupling structure between the resonators are formed in one part, and the output part, the three resonators, A coupling structure between the resonators, and a coupling structure between the resonators are formed. In addition, a coupling structure between the resonator and the part where two parts are attached is formed if necessary. If necessary, two parts may be attached to form a coupling structure between the resonators.

In the filter structure described in the patent document, since there is a step difference in the height of the waveguide structure in forming the coupling structure between the input end and the first resonator, and between the output end and the last resonator, in fabricating the waveguide structure using the dielectric There is a disadvantage of increasing difficulty level.

It also has the disadvantage that a separate circuit must be attached to the dielectric filter structure to implement the negative coupling between the resonators to implement the transfer zero.

KR 10-0651627 B1

SUMMARY OF THE INVENTION The present invention provides a ceramic waveguide resonator filter which is designed to solve such a problem and has a different input / output single-stage coupling structure and can realize a transmission zero in a stop band using a combination of resonance period sounds The purpose.

According to an aspect of the present invention, there is provided a ceramic waveguide resonator filter comprising: an upper member having an input stage converter and a plurality of resonators formed integrally and silver coated; And a lower member which is formed by integrally forming a plurality of resonators and output stage converters and is silver coated and is coupled to a lower surface of the upper member.

The upper member and the lower member have the same height.

The upper member includes an input stage converter between the input end of the coaxial connector structure and the waveguide structure, a first resonator extending in one direction of the input stage converter, a second resonator extending in one direction of the first resonator, And the lower member includes a fourth resonator sequentially coupled to a lower portion of the third resonator, and a third resonator extending in one direction of the fourth resonator and cross-coupled to the second resonator A fifth resonator, a sixth resonator extending in one direction of the fifth resonator, and an output stage transducer extending in one direction of the sixth resonator and between the output of the coaxial connector structure and the waveguide structure.

An input stage converter, an input stage converter, an input stage converter, an input stage converter, a first resonator, a second resonator, and a third resonator, And a fifth resonator and an output stage converter, wherein an iris is formed between the fourth resonator, the fifth resonator, the sixth resonator, and the output stage converter to form a resonance period coupling, The sixth resonator and the output stage converter are integrally formed.

A first groove is formed on an upper surface of the input stage converter to insert and connect a first connector to the first groove and a second groove is formed on a lower surface of the output stage converter to insert a second connector into the second groove, .

The first signal line of the first connector inserted into the first groove formed on the upper surface of the input stage converter is surrounded by Teflon and inserted into a second groove formed on the upper surface of the output stage converter, The second signal line of the second connector is surrounded by a teflon.

A first slot not formed with silver coating is formed on a lower surface of the second resonator, and a fourth slot, which is not coated with silver, is formed on an upper surface of the fifth resonator, and the second resonator and the fifth resonator form an intersection A third slot not formed with a silver coating is formed on an upper surface of the fourth resonator, and a third slot, which is not coated with silver, is formed on a lower surface of the third resonator, The resonators are sequentially coupled.

The cross coupling between the second resonator and the fifth resonator forms an electric field coupling, and the sequential coupling between the third and fourth resonators forms a magnetic field coupling.

The attenuation of adjacent frequency bands or a desired frequency band is maximized by the second resonator and the fifth resonance period cross-coupling structure, and by the third resonator and the fourth resonance period progressive coupling structure, the influence of other signals or noise is minimized.

According to an aspect of the present invention, there is provided a waveguide resonator filter comprising: a first resonator formed integrally with an input end of a coaxial connector structure; a plurality of resonators formed integrally with the first resonator; And a lower member coupled to the lower surface of the upper member, the sixth resonator being integrally formed with the resonator and the output end of the coaxial connector structure being integrally formed and silver-coated.

The upper member and the lower member have the same height.

Wherein the upper member includes a first resonator having an input end integrally formed with the coaxial connector structure, a second resonator extending in one direction of the first resonator, and a third resonator extending in one direction of the second resonator A fourth resonator that is sequentially coupled to a lower portion of the third resonator, a fifth resonator that extends in one direction of the fourth resonator and is cross-coupled with the second resonator, And an output end of the coaxial connector structure is integrally formed.

An input terminal of the coaxial connector structure is integrally formed with an input terminal of the coaxial connector structure, and an iris which forms a resonance period coupling is formed between the second resonator and the third resonator, A first resonator, a second resonator, and a third resonator are integrally formed, and between the fourth resonator, the fifth resonator, and the sixth resonator in which the output ends of the coaxial connector structure are integrally formed, And a sixth resonator in which the fourth resonator, the fifth resonator, and the output end of the coaxial connector structure are integrally formed are integrally formed.

Wherein a first groove is formed on an upper surface of a first resonator in which an input end of the coaxial connector structure is integrally formed, a first connector is inserted and coupled to the first groove, and an output end of the coaxial connector structure is integrally formed 6 A second groove is formed on the lower surface of the resonator, and the second connector is inserted into the second groove.

The first signal line of the first connector inserted into the first groove formed on the upper surface of the first resonator formed integrally with the coaxial connector structure is not wrapped by the teflon, The second signal line of the second connector inserted into the second groove formed on the lower surface of the sixth resonator formed integrally with the output terminal of the second connector is not wrapped by the teflon.

A first slot not formed with silver coating is formed on a lower surface of the second resonator, and a fourth slot, which is not coated with silver, is formed on an upper surface of the fifth resonator, and the second resonator and the fifth resonator form an intersection A third slot not formed with a silver coating is formed on an upper surface of the fourth resonator, and a third slot, which is not coated with silver, is formed on a lower surface of the third resonator, The resonators are sequentially coupled.

The attenuation of the adjacent frequency band or the desired frequency band is maximized by the second resonator and the fifth resonance period cross-coupling structure, the third resonator and the fourth resonance period progressive coupling structure, thereby minimizing the influence of other signals or noise do.

According to the present invention, in a waveguide structure in which a ceramic waveguide resonator filter is fabricated by using a ceramics having a high dielectric constant different from that of a conventional method, a filter is implemented using a new input / output single- It is possible to manufacture the filter more simply and easily.

Also, by forming the positions of the slots between the resonators differently, it is possible to realize the transmission zero by implementing the negative coupling coefficient.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a combined view of a sixth order bandpass filter having a pair of transfer zeroes in accordance with an embodiment of the present invention.
FIG. 2 is a graph showing a frequency response characteristic curve showing a synthesis result curve of a 6th-order bandpass filter having a pair of transmission zeroes in FIG. 1; FIG.
3 is a view showing a structure of a filter using a resonator having six ceramic waveguide structures according to an embodiment of the present invention.
FIG. 4 is a diagram illustrating a frequency response characteristic when the filter of FIG. 3 implements the coupling matrix of Equation 2. FIG.
5 is a view illustrating a structure of a filter using a resonator of a ceramic waveguide structure according to another embodiment of the present invention.
FIG. 6 is a diagram showing a frequency response characteristic when the filter of FIG. 5 implements the coupling matrix of Equation 2. FIG.
FIG. 7 is a cross-sectional view of the first resonator and the sixth resonator of FIG. 5;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

In one embodiment of the present invention, the dielectric waveguide filter includes filters of other orders that are applicable, such as any order of filters, rectangular and cylindrical waveguide resonator filters. In a preferred embodiment of the present invention, a sixth-order filter using a rectangular waveguide resonator will be described as the above-mentioned ceramic waveguide resonator filter. However, it should be noted that the present invention does not depend on the resonator structure of the filter and / or the order of the filter.

Further, in one embodiment, as the ceramic waveguide resonator filter, an example of a filter having two slots will be described. However, it should be noted that the present invention is not limited by the number and position of the slots. It is also noted in advance that the present invention is independent of the number of transfer zeroes determined by the number and position of the slots.

FIG. 1 is a combined view of a sixth-order bandpass filter having a pair of transmission zeroes according to an embodiment of the present invention. The solid line represents direct coupling, and the dotted line represents cross coupling. The nodes include resonators 1, 2, 3, 4, 5 and 6 and input and output stages S and L, and in the case of the filter having the coupling diagram shown in FIG. 1, the total number of nodes is eight. 1 shows the combination of a general 6th-order bandpass filter having a series coupling and having a cross-coupling between the resonator 2 and the resonator 5. Fig.

The coupling matrix corresponding to the coupling degree shown in FIG. 1 is an (8 × 8) matrix and is expressed as follows.

In the above matrix, S is the input, L is the output, and the number is the number of the resonator. In the combination matrix of the above equation, individual factors can be extracted from the transmitted power ratio of the filter, and the power transfer ratio is set so that the filter designer can obtain desired response characteristics. A method for extracting a coupling matrix from a power transfer ratio representing a frequency response characteristic is known from R. J. Cameron, R. Mansour, and C. M. Kudsia, Microwave filters for communications systems: Fundamentals, design, and applications, Wiley,

FIG. 2 is a frequency response characteristic graph showing a synthesis result curve of a 6th-order bandpass filter having a pair of transmission zeroes in FIG. 1, wherein a coupling matrix of a filter having a coupling structure as shown in FIG. 1 is obtained as follows.

The frequency response characteristics of FIG. 2 can be implemented by forming a physical coupling structure that satisfies the individual coupling coefficients of the coupling matrix.

3 is a view illustrating a structure of a filter using a resonator having six ceramic waveguide structures according to an embodiment of the present invention.

Referring to FIG. 3, the entire filter of the ceramic waveguide filter has a structure in which the upper member 10 and the lower member 20 of ceramic material having the same shape are vertically symmetrically coupled to each other. The upper member 10 and the lower member 20 are made of a dielectric material having a high dielectric constant. The upper member 10 and the lower member 20 made of a ceramic material each have a silver coating, and a signal is transmitted through a slot portion which is not coated with a silver coating.

The upper member 10 includes an input stage transducer 11 between the input of the coaxial connector structure and the waveguide structure and a first resonator 12, a second resonator 13 and a third resonator 14 in sequence And three pairs of iris (first resonator 12 and second resonator 13), which form resonator-to-resonator coupling between the first resonator 12 and the second resonator 13 and the third resonator 14, iris) 15, 16, 17 are formed.

A first slot 18 having a rectangular shape which is not coated with silver is formed on the lower surface of the second resonator 13 and a second slot 18 having a rectangular shape A slot 19 is formed. The first slot 18 and the second slot 19, which form the resonator coupling, may have a shape other than a rectangular shape, and the size of the first slot 18 and the second slot 19 may be adjusted.

A circular groove 11a having a predetermined depth is formed in the center of the upper surface of the input stage converter 11 of the upper member 10 so that the first connector 30 connected to other components and receiving signals is inserted and coupled. The first signal line 31 of the first connector 30 inserted into the circular groove 11a formed at the center of the upper surface of the input stage converter 11 is surrounded by Teflon. The first signal line 31 wrapped with Teflon has the effect of preventing shaking during assembly.

The upper member 10 is plated with silver except for the first slot 18, the second slot 19 and the circular groove 11a portion.

The lower member 20 is configured such that output stage transducers 24 between the output of the fourth resonator 21 and the fifth resonator 22 and the output of the sixth resonator 23 and the coaxial connector structure and the waveguide structure are sequentially disposed And an iris 25, which forms a resonator-to-resonator symmetry between the fourth resonator 21 and the fifth resonator 22 and the sixth resonator 23 and the output stage converter 24, 26 and 27 are formed.

A third slot 28 having a rectangular shape which is not coated with silver is formed on the upper surface of the fourth resonator 21 and a fourth slot 28 having a rectangular shape having no silver coating is formed on the upper surface of the fifth resonator 22. [ A slot 29 is formed. The third slot 28 and the fourth slot 29, which form the resonator coupling, may have a shape other than a rectangular shape, and the size of the third slot 28 and the fourth slot 29 may be adjusted.

A circular groove 24a having a predetermined depth is formed at the center of the lower surface of the output stage converter 24 of the lower member 20 so that the second connector 40 connected to other components and receiving signals is inserted and coupled. Here, the second signal line 41 of the second connector 40 inserted into the circular groove 24a formed at the center of the lower surface of the output stage converter 24 is surrounded by Teflon. The second signal line 41 wrapped with the Teflon has the effect of preventing shaking during assembly.

The lower member 20 is plated with silver except for the third slot 28 and the fourth slot 29 and the circular groove 24a portion.

A first slot 18 formed on the lower surface of the second resonator 13 of the upper member 10 and a fourth slot 29 formed on the upper surface of the fifth resonator 22 of the lower member 20 ) Are not coated with silver but contact each other with exposed portions of the ceramics so that the signal is transmitted.

The third slot 28 formed on the upper surface of the fourth resonator 21 of the lower member 20 and the second slot 19 formed on the lower surface of the third resonator 14 of the upper member 10 Without the silver coating, the parts exposed to the ceramic are brought into contact with each other to transmit the signals.

The lower surface of the upper member 10 excluding the first slot 18 and the second slot 19 and the upper surface of the lower member 20 except for the third slot 28 and the fourth slot 29, So that the upper member 10 and the lower member 20 can be joined together by soldering by mutual soldering.

In this structure, the coupling structure between the third resonator 14 and the fourth resonator 21 is formed as a slot, and the coupling structure between the second resonator 13 and the fifth resonator 22 is also formed as a slot However, due to the characteristic that the characteristics of the coupling vary depending on the position of the slot, one of the two is a negative combination. A slot which is a coupling structure between the third resonator 14 and the fourth resonator 21 forms a magnetic field coupling with a magnetic field located in a portion where the magnetic field is transmitted, and the second resonator 13 and the fifth resonator 21, The slot, which is a coupling structure between the first and second electrodes 22, is located in a portion where the electric field is high, and forms electric field coupling.

3, the structure of the upper member 10 and the lower member 20, which are two parts forming the dielectric waveguide filter, have the same height, and therefore, the height of the waveguide It is advantageous in that it is easier to fabricate than existing structures in which a step is present.

3, a circular groove 11a having a predetermined depth is formed at the center of the upper surface of the input stage converter 11 of the upper member 10, The connector 30 is inserted and coupled. A circular groove 24a having a predetermined depth is formed in the central portion of the lower surface of the output stage converter 24 of the lower member 20 so that the second connector 40 connected to other components and receiving signals is inserted and coupled .

That is, the circular grooves 11a and 24a formed in the upper member 10 and the lower member 20 of the present invention have shapes that are formed not only to penetrate each other but to a certain depth. Therefore, the first and second connectors 30 and 40 inserted into the respective circular grooves 11a and 24a are not completely passed through the upper member and the lower member, but are inserted only to a certain portion. This is an important design parameter of the input transducer 11 and the output transducer 24 depending on the degree of insertion of the signal lines 31 and 41 included in the first and second connectors 30 and 40 inserted into the circular groove So as to change the impedance matching characteristic. That is, the insertion degree of the signal lines 31 and 41 is determined according to the used frequency band, and the impedance matching characteristic is more efficiently performed through this configuration. At this time, the degree of insertion of the signal lines 31 and 41 is determined according to the impedance matching characteristic obtained by the experiment according to the frequency band to be used.

In the structure of FIG. 3, which is shown in FIG. 3, an iris pair is formed for resonance period coupling in a symmetrical shape facing each other between resonators. The iris serves to adjust the amount of electric field that is passed to each resonator. The electric field has the largest value at the center of the resonance. If the iris is formed on both sides as in the present invention, it becomes possible to more effectively control the electric field amount. Such a filter structure is more efficient when implementing a wideband filter.

Therefore, the structure shown in Fig. 3, which is shown, shows a rectangular parallelepiped structure having no step. According to this structure, since the conventional process steps for forming the stepped portion are omitted, it is economical and has an effect in terms of production time.

FIG. 4 shows the frequency response characteristics when the filter of FIG. 3 implements the coupling matrix of Equation (2).

As shown, S ₁₁ represents the impedance matching characteristic of the filter of FIG. 3, and S ₂₁ represents the loss characteristic with the transmission zero. The second resonator 13 of the upper member 10 and the fifth resonator 22 of the lower member 20 are cross-coupled and the third resonator 14 of the upper member 10 the fourth resonator 21 of the lower member 20 to maximize the frequency band or attenuation of a desired frequency band adjacent to the pass band, as shown in S ₂₁ that indicates the loss characteristics as the sequential combination of the influence of other signals or noise So that it can be minimized.

As described above, in the structure of FIG. 3 of the present invention, a converter is used to convert the structure between the dielectric waveguide structure and the coaxial connector. In this case, of course, the present invention does not form a step between the transducer and the resonator.

5 is a view illustrating a structure of a filter using a resonator of a ceramic waveguide structure according to another embodiment of the present invention.

As shown, the filter structure of FIG. 3 shows a sixth order filter having a structure in which a converter between the input end and the first resonator and a converter between the output end and the last resonator are removed.

Referring to FIG. 5, the entire filter of the ceramic waveguide filter has a structure in which the upper member 50 and the lower member 60 of ceramic material having the same shape are vertically symmetrically coupled to each other. The upper member 50 and the lower member 60 are made of a dielectric material having a high dielectric constant. The upper member 50 and the lower member 60 made of a ceramic material each have a silver coating, and a signal is transmitted through a slot portion where the silver coating is not applied.

The upper member 50 includes a first resonator 51, a second resonator 52 and a third resonator 53 in which an input end of the coaxial connector structure is integrally formed, Two pairs of iris 54 and 55 are formed between the resonator 51 and the second resonator 52 and the third resonator 53 to form resonator-to-resonator symmetrical shapes. That is, in the embodiment of the present invention, the input end of the coaxial connector structure is integrally formed in the first resonator 51. The degree of insertion of the signal line 71 is determined so that the signal inputted through the signal line 71 of the coaxial connector 70 can be impedance-matched according to the frequency band used by the first resonator 51. The degree of insertion at this time is determined based on the experimental value according to the frequency band used.

A first slot 56 having a rectangular shape that is not coated with silver is formed on the lower surface of the second resonator 52 and a second slot 56 having a square shape having no silver coating is formed on the lower surface of the third resonator 53. A slot 57 is formed. The first and second slots 56 and 57, which form the resonator coupling, may have a shape other than a rectangular shape, and the size of the first and second slots may be adjusted.

A circular groove 51a having a predetermined depth is formed at the center of the upper surface of the first resonator 51 in which the input end of the coaxial connector structure of the upper member 50 is integrally formed, 1 connector 70 is inserted and coupled. The first signal line 71 of the first connector 70, which is inserted into the circular groove 51a formed at one side of the upper surface of the first resonator 51 integrally formed with the input end of the coaxial connector structure, It is not wrapped by teflon.

The upper member 50 is plated with silver except for the first slot 56 and the second slot 57 and the circular groove 52a portion.

The lower member 60 includes a fourth resonator 61 and a fifth resonator 62 and a sixth resonator 63 integrally formed with the output end of the coaxial connector structure, An iris 64 or 65 is formed between the fifth resonator 62 and the sixth resonator 63 in which the output ends of the coaxial connector structure are integrally formed to form resonator-to-resonator symmetrical shapes .

That is, in the embodiment of the present invention, the output terminal of the coaxial connector structure is integrally formed in the sixth resonator 63. The degree of insertion of the signal line 81 is determined so that the signal output through the signal line 81 of the coaxial connector 80 can be impedance-matched according to the frequency band used by the sixth resonator 63. The degree of insertion at this time is determined based on the experimental value according to the frequency band used.

A third slot 66 having a rectangular shape which is not coated with silver is formed on the upper surface of the fourth resonator 61 and a fourth slot 66 having a square shape A slot 67 is formed. The third slot 66 and the fourth slot 67, which form the resonator coupling, may have a shape other than a rectangular shape, and the size of the third slot 66 and the fourth slot 67 may be adjusted.

A circular groove 63a having a predetermined depth is formed on one side of the lower surface of the sixth resonator 63 in which the output end of the coaxial connector structure of the lower member 60 is integrally formed, The second connector 80 is inserted and coupled. The second signal line 81 of the second connector 80, which is inserted into the circular groove 63a formed at the center of the lower surface of the sixth resonator 63 having the output end of the coaxial connector structure, is not wrapped by teflon.

The lower member 60 is plated with silver except for the third slot 66 and the fourth slot 67 and the circular groove 63a portion on the lower surface.

A first slot 56 formed on the lower surface of the second resonator 52 of the upper member 50 and a fourth slot 67 formed on the upper surface of the fifth resonator 62 of the lower member 60 ) Are not coated with silver but contact each other with exposed portions of the ceramics so that the signal is transmitted.

The second slot 57 formed on the lower surface of the third resonator 53 of the upper member 50 and the third slot 66 formed on the upper surface of the fourth resonator 61 of the lower member 60 Without the silver coating, the parts exposed to the ceramic are brought into contact with each other to transmit the signals.

The lower surface of the upper member 50 excluding the first slot 56 and the second slot 57 and the upper surface of the lower member 60 except for the third slot 66 and the fourth slot 67, So that the upper member 50 and the lower member 60 can be joined together by soldering by mutual soldering.

The filter using the resonator of the ceramic waveguide structure shown in FIG. 5 is different from the filter shown in FIG. 3 in that there is no transducer connected to the input / output stage and the coaxial connector forming the input / output stage is connected to the first resonator and the last resonator . As in the embodiment shown in Fig. 5, when the converter constituting the input stage and the output stage are omitted, the effect of reducing the overall length of the resonator is obtained.

As can be seen from the filter structure shown in FIG. 5, the filter structure in which the transducer connected to the input / output stage is removed also has an advantage that it is possible to design the waveguide height to be constant and easy to manufacture.

5, a circular groove 51a having a predetermined depth is formed at the center of the upper surface of the transducer-integrated first resonator 51 of the upper member 50, The receiving first connector 70 is inserted and coupled. In addition, a circular groove 63a having a predetermined depth is formed in a central portion of the lower surface of the transducer-integrated sixth resonator 63 of the lower member 60, and a second connector 80, . 7 is a cross-sectional view showing only the portions of the first resonator and the sixth resonator shown in Fig.

That is, the circular grooves 51a and 63a formed in the upper member 50 and the lower member 60 of the present invention have shapes that are formed not only to penetrate each other but to a certain depth. Accordingly, the first and second connectors 70 and 80 inserted into the respective circular grooves 51a and 63a are not completely penetrated through the upper member and the lower member, but are inserted only to a certain portion. This is because the critical design of the first resonator 51 and the sixth resonator 63 depends on the degree of insertion of the signal lines 71 and 81 included in the first and second connectors 70 and 80 inserted into the circular groove So as to change the impedance matching characteristic, which is a parameter. That is, the degree of insertion of the signal lines 71 and 81 is determined in accordance with the used frequency band, and the impedance matching characteristic is more efficiently performed through this configuration. In this case, the degree of insertion of the signal lines 71 and 81 is determined according to the optimum impedance matching characteristic obtained by the experiment according to the frequency band used when the input stage integrated resonator and the output stage integrated resonator are implemented.

In the structure of Fig. 5, which is shown in the figure, an iris pair is formed for resonance period coupling in a symmetrical shape facing each other between resonators. The iris serves to adjust the amount of electric field that is passed to each resonator. The electric field has the largest value at the center of the resonance. If the iris is formed on both sides as in the present invention, it becomes possible to more effectively control the electric field amount. Such a filter structure is more efficient when implementing a wideband filter.

Therefore, the structure shown in Fig. 5, which is shown, shows a rectangular parallelepiped structure without a step. According to this structure, since the conventional process steps for forming the stepped portion are omitted, it is economical and has an effect in terms of production time.

FIG. 6 shows the frequency response characteristics when the filter of FIG. 5 implements the coupling matrix of Equation (2).

As shown, S ₁₁ represents the impedance matching characteristic of the filter of FIG. 5, and S ₂₁ represents the loss characteristic with the transmission zero. The second resonator 52 of the upper member 50 and the fifth resonator 62 of the lower member 60 are cross-coupled and the third resonator 53 of the upper member 50 the fourth resonator 61 of the lower member 60 to maximize the attenuation of the frequency band and desired frequency band adjacent to the pass band, as shown in S ₂₁ that indicates the loss characteristics as the sequential combination of the influence of other signals or noise So that it can be minimized.

That is, the structure of FIG. 5, which is another embodiment of the present invention, shows a filter structure in which the converter is completely removed. That is, in the present invention, a resonator is integrally formed at an input end and an output end. The characteristics of the present invention thus realized can be confirmed by the graph of FIG.

The arrow shown in the figure is a graph showing the slope of the filter, and linearly indicates the frequency response. FIG. 6 shows the characteristics of the present invention as a graph showing a steep slope of the angle, as shown in FIG. 6.

In Fig. 6, which is shown, the SPAN at the bottom is measured at 300 MHz. That is, the filter degree of the resonator is 6, and the attenuation characteristic is obtained while realizing a small size of the product.

As described above, the present invention provides a ceramic waveguide filter structure having a new input / output single-stage coupling structure different from the conventional one and having a resonance period noise combination for transfer zero implementation.

The ceramic waveguide filter structure includes a plurality of ceramic waveguide resonators, a coupling structure coupling the first resonator with the coaxial connector constituting the input end, a coupling structure coupling the coaxial connector and the last resonator constituting the output end, and a coupling structure . The number of the resonators is four or more, and if the resonator including the input terminal and the output terminal are integrally combined, six resonators are constituted. Further, the coupling structure formed between the resonators has a positive coupling coefficient or a negative coupling coefficient. Therefore, the signal inputted through the signal line 71 is first impedance-matched by the first resonator constituted integrally with the input coaxial connector, and sequentially passes through the second, third, fourth and fifth resonators, And a sixth resonator formed integrally with the first resonator.

In the embodiment shown in FIG. 5, the signal lines 71 and 81 are not covered with Teflon. In the embodiment shown in FIG. 3, the signal lines 31 and 41 are surrounded by Teflon. In the embodiment of FIG. 3 wrapped with Teflon, the advantage that the signal line is fixed by the Teflon in the assembling process by the coupling of the upper member and the lower member is additionally obtained.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be understood that various modifications and changes may be made without departing from the scope of the appended claims.

10, 50:
20, 60:
11, 24: converter
12, 13, 14, 21, 22, 23, 51, 52, 53, 61, 62, 63:
15,16,17,25,26,27,54,55,64,65: Iris
18, 19, 28, 29, 56, 57,
30, 40, 70, 80:
31, 41, 71, 81:
11a, 24a, 51a, 63a:

Claims (6)

A ceramic waveguide resonator filter comprising a ceramic waveguide upper member and a ceramic waveguide lower member coupled to each other,
The upper member comprising an input stage transformer between the input of the coaxial connector structure and the waveguide structure; A first resonator, a second resonator, and a third resonator are sequentially arranged in the longitudinal direction without a step with the input stage converter; A first resonator, a second resonator, a second resonator, and a third resonator, wherein the first resonator, the second resonator, and the third resonator have a rectangular parallelepiped shape in which an iris pair forming a resonance period coupling is formed symmetrically with respect to each other,
Wherein the lower member is vertically symmetrical in the same rectangular parallelepiped shape as the upper member and has an output stage converter between the output end of the coaxial connector structure and the waveguide structure; A sixth resonator, a fifth resonator, and a fourth resonator are sequentially disposed without a step with the output stage converter; An iris pair is formed between the output stage converter and the sixth resonator, between the sixth resonator and the fifth resonator, and between the fifth resonator and the fourth resonator to form resonance period coupling symmetrically with each other,
A quadrangular-shaped slot that is not coated with silver is formed on the lower surface of the second and third resonators of the upper member and the upper surfaces of the fourth and fifth resonators of the lower member, and the second resonator of the upper member and the fifth resonator And forming a signal coupling between the third resonator of the upper member and the fourth resonator of the lower member,
Wherein the input stage converter and the output stage converter are formed with grooves having a predetermined depth by determining an insertion degree of a signal line to be inserted according to a frequency band to be used and the upper and lower members have the same shape and size, The grooves formed in the output stage converter have the same depth and width,
P12 = P21 = P78 = P87 = 1.095 and P23 = P32 = P67 = P76 = 0.922 when the ceramic waveguide resonator filter is composed of an 8 * 8 coupling matrix P11, , P34 = P43 = P56 = P65 = 0.600, P45 = P54 = 0.754, P36 = P63 = -0.195, and the remaining matrix values are 0 Wherein the ceramic waveguide resonator filter is formed by forming a dielectric layer on the dielectric layer.
The method according to claim 1,
Wherein the ceramic waveguide resonator filter is silver-coated except for the slot and the groove.
The method of claim 2,
Wherein the signal line is surrounded by Teflon.
delete A ceramic waveguide resonator filter comprising a ceramic waveguide upper member and a ceramic waveguide lower member coupled to each other,
The upper member includes a first resonator, a second resonator, and a third resonator sequentially arranged in the longitudinal direction with no step; Wherein the first resonator and the second resonator are formed in a rectangular parallelepiped shape in which an iris pair is formed between the second resonator and the third resonator to form a resonance period coupling in a symmetrical shape opposing each other,
The lower member is vertically symmetrical in a rectangular parallelepiped shape identical to that of the upper member, and the sixth resonator, the fifth resonator, and the fourth resonator are sequentially arranged without a step; An iris pair is formed between the sixth resonator and the fifth resonator, the fifth resonator and the fourth resonator to form resonance period coupling symmetrically with respect to each other,
A quadrangular-shaped slot that is not coated with silver is formed on the lower surface of the second and third resonators of the upper member and the upper surfaces of the fourth and fifth resonators of the lower member, and the second resonator of the upper member and the fifth resonator And forming a signal coupling between the third resonator of the upper member and the fourth resonator of the lower member,
The first resonator of the upper member has an input end integrally formed with the coaxial connector structure and the sixth resonator of the lower member has an output end integrally formed with the coaxial connector structure,
The input terminal and the output terminal are formed with a groove having a predetermined depth by determining the degree of insertion of a signal line inserted according to a frequency band to be used, and the upper member and the lower member have the same shape and size, The grooves are of the same depth and width,
P12 = P21 = P78 = P87 = 1.095 and P23 = P32 = P67 = P76 = 0.922 when the ceramic waveguide resonator filter is composed of an 8 * 8 coupling matrix P11, , P34 = P43 = P56 = P65 = 0.600, P45 = P54 = 0.754, P36 = P63 = -0.195, and the remaining matrix values are 0 Wherein the ceramic waveguide resonator filter is formed by forming a dielectric layer on the dielectric layer. delete

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