BR112014003555B1 - COMMUNICATION CAVITY COMPONENT AND ITS COMBINATION AND DISTRIBUTION STRUCTURE - Google Patents

Abstract

COMMUNICATION CAVITY COMPONENT AND ITS COMBINATION AND DISTRIBUTION STRUCTURE. A communication cavity component and a combination and distribution structure are presented. The combining and distribution structure includes a connecting member, one end of which is to the common port, while the other end thereof is capacitively coupled to the first signal path; an impedance transformation transmission line, one end of which is connected to the second signal path, while the other end thereof is connected to the connecting member; additionally, the line comprises at least two line segments with different impedance; a resonance station connected to the impedance transformation transmission line at a central location on the line; and a dielectric support member for securing the resonance post and isolating it from the cavity.

Description

SCOPE OF THE INVENTION

[001] The present invention relates to a communication cavity component for combining multi-communication signals and suitable for cavity components such as combiners, duplexers and filters and the like, and more specifically, relates to a structure of combination and distribution applied to the component of the communicating cavity.

BACKGROUND OF THE INVENTION

[002] With the development of three-network convergence and launch of the LTE band, new frequency bands have been developed in trends to have higher or lower frequencies compared to conventional frequency bands. With the introduction of a new standard or system, the requirements for combiners in the market increase. It is intended that these combiners carry out the combination and distribution of higher frequency band signals. However, a prior art combiner is not capable of performing combination and distribution of signals of this higher frequency band, thus not satisfying the above-mentioned requirements. As such, a new combiner must be developed.

[003] Chinese patent publication No. CN101478071A discloses a dual frequency combiner with a relatively high bandwidth as an advantageous result of efforts in the art. In the technical solution presented by this patent application, bandstop filters are used to obtain a signal path with low frequencies. The relative bandwidth of the signal path! at low frequencies it can go up to 200%. However, it is limited in that it is difficult for the stopband filter stopband to have sufficient suppression in the higher frequency band. Consequently, the other path of the signal can only be realized by the narrowband filter to ensure that there is sufficient band isolation between the two paths. As a result, the range of application of this type of combiner is narrow and therefore unsuitable for the new market environment.

[004] It is necessary technique for performing the combination of two signal paths with relatively high bandwidth to combine the signals into two paths without interference. Although the combination and distribution structure of the prior art can meet this requirement in part, this structure may not achieve a good technical effect.

SUMMARY OF THE INVENTION

[005] Correspondingly, a main object of the invention is to provide a component of the communication cavity capable of bringing a relatively high bandwidth to the two signal paths and having a high bandpass isolation. Additionally, the construction of the communicating cavity component can also be adapted to combiners, duplexers or filters.

[006] Another object of the invention is to overcome the disadvantages of the prior art and provide a combination and distribution structure capable of bringing a relatively high bandwidth to two signal paths and performing signal combination without any interference. The structure is adapted to devices such as combiners, duplexers or filters.

[007] To achieve the above objectives, the following technical solution is provided.

[008] The communication cavity component of the invention includes two signal paths realized in a cavity and used to transmit signals with different frequencies. One end of the two signal paths combines and distributes the two signals with different frequencies through the combination and distribution structure and forms a common gate. The combination and distribution structure includes: a connecting member, one end of which is connected to the component port, while its other end is capacitively coupled to the first signal path; an impedance transformation transmission line, one end of which is connected to the second signal path, while its other end is connected to the connection member; additionally, the line includes at least two line segments with different impedance; a resonance station connected to the impedance transforming transmission line at a central location of the line; and a dielectric support member for securing the resonant station and isolating it from the cavity.

[009] In one model, the impedance transformation transmission line includes two line segments. One end of the line segment is connected to the connecting member and the other end of the line segment is connected to the second signal path. The other ends of the two line segments are connected to the resonance station.

[010] In another model, the two line segments of the impedance transformation transmission are integrally formed. A through hole is radially defined in the resonant station. The impedance transfer transmission line passes through the through hole.

[011] Preferably, the line segments of the impedance transformation transmission line have different diameters.

[012] Preferably, the first signal path is a bandpass filter path, while the second signal path is a lowpass filter path. More preferably, the second signal path is an elliptical function low-pass filter path.

[013] The first signal path includes a plurality of resonating stations. A hole is defined radially in a resonant post of the first signal path near the common port. The connecting member is inserted into the hole and capacitively connected to the same resonant post. Specifically, one end of the connection member is connected to an inner conductor of the common gate, while the other end is capacitively connected to the resonator post, and a dielectric sleeve is threaded into the connection member at a location where it is coupled to the resonator post. .

[014] The second signal path includes a number of sub-cavities communicating with each other sequentially, a number of resonance stations, each lying between two underlying sub-cavities, a conductive rod disposed in these resonance stations and a number of tuning screws corresponding to the plurality of sounding stations in terms of location and quantity. A number of threaded holes are defined in the conductive rod corresponding to the plurality of resonant stations in terms of location and quantity. Each tuning screw passes through a respective threaded hole and is inserted deep into a respective hole in the sounding station so as to realize capacitive coupling between the tuning screw and the sounding station. The impedance transformation transmission line is physically connected to the conductive rod, thus connecting it to the second signal path.

[015] In a model, the plurality of sub-cavities are arranged along the same direction. Correspondingly, the conductive rod is linearly arranged. In another model, the plurality of subcavities are not disposed along the same direction. Correspondingly, the conductive rod has a bent construction.

[016] For the threaded hole to have enough space, a partial segment around the threaded hole of the conductive rod has a larger diameter than a main body of the conductive rod.

[017] A slot is formed between a respective resonance station and a lower wall of the metal cavity. Each slit, which corresponds to the respective resonance station, has a different height.

[018] Preferably, in said number of sub-cavities, the sub-cavities located between a front sub-cavity and a rear sub-cavity are of the same size.

[019] To avoid contact, the dielectric sleeve is located between the tuning screw and the resonance post.

[020] The invention also provides a combiner/duplexer/filter that has the same construction as the aforementioned communication cavity component.

[021] A distribution and combination structure of the invention is used in a communication cavity component and it includes: a connecting member, one end of which forms a common port and the other end is used to connect to a first frequency signal of the communication cavity component; an impedance transformation transmission line, one end of which is used to input a second frequency signal from the communication cavity component, while its other end is connected to the connection member; additionally, the line includes at least two line segments with different impedance; a resonance station connected to the impedance transforming transmission line at a central location of the line; and a dielectric support member for securing the resonant post and isolating it from the cavity of the communicating cavity component.

[022] In one model, the impedance transformation transmission line includes two line segments. One end of the line segment is connected to the connecting member and the other end of the line segment is connected to the second signal path. The other ends of the two line segments are connected to the resonance station.

[023] In another model, the two line segments of the impedance transformation transmission are integrally formed. A through hole is radially defined in the resonant station. The impedance transfer transmission line passes through the through hole.

[024] Preferably, the line segments of the impedance transformation transmission line have different diameters. The diameter of the line segments of the impedance transforming transmission line gradually becomes larger from one end near the connecting member to its other end.

[025] The invention also provides a combiner/duplexer/filter/feeder having the same construction as the aforementioned communication cavity component.

[026] Compared with the prior art, the invention has the following advantages.

[027] First, for the distribution and combination structure of the invention, a capacitive connection is realized between the above structure and the first signal path of the communication cavity component through the connection member. Additionally, the connection to the second signal path is established through the cooperation of the impedance transfer transmission line and the resonance station, thus realizing signal transmission. Regarding the previous point, in case the capacitance is constant, the impedance is inversely proportional to the frequency. Therefore, signals with higher frequencies can be transmitted between the common port, the connecting member and the first signal path. Regarding the latter, the cooperation of the impedance transformation transmission line and the resonance station have the effect of inductance, and in case the inductance is constant, the impedance is proportional to the frequency. Therefore, signals with lower frequencies can be transmitted between the common port, the impedance transformation transmission line, the resonant station and the second signal path. Correspondingly, the distribution and combination structure of the invention is capable of separating the high frequency signal from the low frequency signal, thus realizing signal distribution and combination.

[028] Second, for the impedance transformation transmission line with a certain length, the interference frequency created by the resonance was shifted, as well as the transmission line to the resonance station. Through adjustment, the interference frequency was shifted away from the frequency of the first and second signal paths. Correspondingly, the impedance transformation transmission line arrangement has no bad effects on the electrical performance of the communicating cavity component.

[029] Thirdly, the elliptical function low-pass filter path is employed in the communication cavity component of the invention. This type of low pass filter path has a unique construction. Compared to a prior art low-pass filter with a candy-shaped array, and instead of a conventional low-impedance part, in the elliptical-function low-pass filter of the invention, an equivalent inductance-capacitance-resonator has been added. in-series to the main path. The equivalent inductance of the oscillator is realized by a high impedance produced between the resonant post and the sidewall. Equivalent capacitance is realized by the coupling created in a defined gap between the tuning screw and the inner wall of the resonator post. The thus-formed communication cavity component can bring strong suppression to a larger out-of-band frequency range, thus satisfying the requirement of high isolation between communication systems.

[030] REVIEW DESCRIPTION OF THE DRAWINGS

[031] Figure 1 shows a schematic structure of a communication cavity component according to the invention.

[032] Figure 2 shows a view illustrating a partially assembled distribution and combination structure of the invention with a low-pass filter path;

[033] Figure 3 also shows the assembly relationship between a resonance station, a conductive rod, a dielectric sleeve and a tuning screw; It is

[034] Figure 4 shows an assembled view of the distribution and combination structure of the invention.

DETAILED DESCRIPTION OF THE INVENTION

[035] Several embodiments of the invention will be described in detail below with reference to the accompanying drawings.

[036] With reference to Figure 1, a preferred embodiment of the invention provides a communication cavity component, which is a combiner for combining and distributing two walls in two different frequency bands. The combiner includes a main body which is a cavity 12. There is a cover plate 11 above the cavity 12 so that the combiner forms an integral cavity component. There are two signal paths 31 and 32 in the cavity 12. A first signal path 31 is a bandpass filter path for filtering signals from the first frequency band, while a second signal path 32 is a lowpass filter path to filter signals from a second frequency band. The first frequency band contains relatively high frequencies, while the second frequency band contains relatively low frequencies. Additionally, each frequency band may contain one or more subfrequency bands with their separate communication patterns. For example, the first frequency band may include one or more of the following frequency bands: DCS, WCDMA, TD-SCDMA, WLAN and LTE2600; while the second frequency band may include one or more of the following frequency bands: CATV, LTE700, CDMA and GSM. In this model, the two signal paths 31 and 32 are designed such that the relative bandwidth of the bandpass filter path is up to 45%, and the relative bandwidth of the lowpass filter path is up to 200% . On the same side of the two signal paths 31 and 32, two subports 21 and 22 are respectively provided. and 32, a common door 20 is provided and this door 20 is also shown on the other side of the cavity wall 12, said common door 20 functioning as a distribution and combination structure.

[037] The first path of signal 31 (ie, the bandpass filter path) is defined in an elongated cavity slot. An elongated slot 310 projects into a bottom wall of the cavity slot to enhance the coupling effect between a plurality of resonant cavities, each defined by a respective resonant station 311. A plurality of resonant stations 311 are located in the slot 310 in line. There is an inductive coupling performed by an open ended coupling between two adjacent resonant cavities defined by two adjacent resonant stations 311 respectively. In another embodiment of the invention, to improve out-of-band suppression, there may be cross-coupling between the resonant cavities. This type of cross-coupling can include inductive cross-coupling accomplished by forming a U-shaped gap or line and capacitive cross-coupling accomplished by hanging bar. To facilitate tuning, corresponding to the respective sounding posts 311, a plurality of tuning screws 312 are also provided which pass through the plate cover 11 and are inserted into the sounding posts 311 respectively. Referring to Figures 1 and 2, the front and back resonator stations 311 within the first signal path 31 are used to be connected to a corresponding subport 21 and common port 20 respectively via two connecting members 41' and 41. end of connecting members 41' and 41 (a first part 412) is connected to an inherent inner conductor (not shown) of the port (from subport 21 or common port 20); while the other end (a second part 414) is capacitively connected to a front or back resonator 311. Specifically, a thin coupling bar 416 is formed in the second part 414 which acts as a coupling part. Correspondingly, a hole (not shown) in a corresponding resonance station 311 is defined radially. The coupling bar 416 located in the second part 414 is inserted into a hole of the resonance station 311, thus producing capacitive coupling. To avoid direct physical contact between yoke 416 and resonator post 311, a dielectric sleeve (not shown) constructed of polytetrafluoroethylene (PTFE) or other insulating material is threaded into yoke 416.

[038] Using the above connection members 41 and 41', the resonance posts 311 at two ends of the first signal path 31 can be connected to the common port 20 and subport 21 respectively in a capacitive manner.

[039] Again, referring to Figures 1 and 2. In the present invention, the second signal path 32 is a low-pass filter path of elliptic function and mainly includes a plurality of subcavities defined in the cavity 12, a number of parts of slits 64, each being formed between two underlying sub-cavities, a number of resonant posts 63, each meeting in a respective part of the slit 64, a conductive rod 5 extending in the cavity 12 along a longitudinal direction and disposed on sounding stations 63, and a number of tuning screws 61, each passing through the conductive rod 5 and connected to the respective sounding station 63 in a capacitive way. Two ends of the conductive rod 5 are used to be connected to the common port 20 and subport 22 belonging to the path respectively.

[040] With regard to Figure 3, the detailed construction of the low-pass filter path of this model is also illustrated.

[041] The number of subcavities is arranged substantially along the same direction (in a line). The volume of subcavities 11-15 depends on a specific design of the electrical performance requirement. Preferably, except the front and rear sub-cavities 11, 15 which have a relatively small volume, other centrally located sub-cavities 12-14 have substantially the same or an identical volume.

[042] An opening is defined at a connection location, where two adjacent subcavities communicate with each other. A slotted portion 64 projects from a lower wall of cavity 12 at a location corresponding to the connection location. A resonant station 63 is erected on a respective grooved part 64. A different grooved part 64 can have different heights, so as to adapt to different frequency bands. Therefore, a group of resonance stations 63 are formed in line. These resonator posts 63, together with the apertures, form an inductance equivalent of the aforementioned capacitance and inductance equivalent resonator in series.

[043] Its ends of the conductive rod 5 are connected to internal conductors (not shown) of the common port 20 and subport 22 belonging to the path respectively. The conductive rod 5 is also secured in the respective resonance station 63. Specifically, one end of the conductive rod 5 is directly connected to the inner conductor of the subport 22 of the path 32, while the other end is connected to the common port 20 through the distribution structure and combination of the invention.

[044] In the present model, the conductive rod 5 is linearly arranged and its main body has a relatively smaller diameter. At a location corresponding to a resonating station, the conductive rod 5 includes a partial segment 51 of greater diameter. The partial segment 51 is larger in diameter than the main body, so as to be able to define a through hole in the partial segment 51 through which the tuning screw 61 passes.

[045] So that each tuning screw 61 passes radially through the conductive rod 5 and performs capacitive coupling with the respective resonance station 63, a passage hole 50 with threads (that is, a threaded hole) is defined radially in each segment partial 51 with a larger diameter of the conductive rod 5. Furthermore, a hole 630 is defined in the resonance station 63, into which the tuning screw 61 can be axially inserted. Consequently, after passing through the threaded hole 50 of the conductive rod 5 , the tuning screw 61 extends deep into the hole 630 of the resonant station 63 corresponding to the location of the threaded hole 50, thus realizing capacitive coupling between the tuning screw 61 and a respective resonant station 63. To ensure that the tuning screw 61 is insulated against the resonant post 63, a dielectric sleeve 62 constructed of polytetrafluoroethylene (PTFE) or other insulating material is threaded onto the tuning screw 61.

[046] From the above description it becomes evident that after passing through the respective threaded holes 50 formed in the conductive rod 5, the plurality of tuning screws 61 become capacitively coupled to the resonator posts 63 at corresponding locations. This capacitive coupling is the equivalent capacitance of the series equivalent inductance capacitance resonator.

[047] As such, when connecting in series the equivalent inductance and equivalent equivalent capacitance, the equivalent resonator is consequently formed in series. The cooperation of multiple equivalent resonators in series helps the low pass filter path to create relatively high suppression (e.g. 70dB or more) over a larger out-of-band frequency range (the relative bandwidth can be up to 45%) .

[048] In another not shown model of the invention, the plurality of subcavities may not be arranged in the same direction (in line). For example, they can be arranged to define a right angle to each other. As an adaptive change, the conductive rod 5 can also be designed to have a bent construction. Apparently, the technical effects of the invention can still be obtained, although some individual components of the invention can be suitably modified. To connect the first and second signal paths 31 and 32 to the common port 20 via their respective ends and thus perform signal combining and distribution, a combining and distributing structure is provided for the invention.

[049] Referring to Figures 2 and 4. The combination and distribution structure of the invention includes a connecting member 41 for connecting the common port 20 and a resonating station 311 of the first signal path 31 adjacent the common port 20. an impedance transformation transmission line 42, a resonator post 43, and a dielectric support member 44. The impedance transformation transmission line 42 includes two line segments 421 and 422, which are separate from one another and have different diameters. The line segment 421 near the common port 20 and first signal path 31 has a smaller diameter, while the line segment 422 near the second signal path 32 has a larger diameter. Resonance station 43 is electrically connected to two line segments 421, 422 in series at precisely a central location.

[050] One end of the line segment 421 with a smaller diameter is welded with the connecting member 41 adjacent to the common port 20, while its other end is welded with one side of the resonant post 43. One end of the line segment 422 with a larger diameter is welded with the other side of the resonator post 43, while its other end is welded with a corresponding end of the conductive rod 5. Clearly, from the connection member 41 adjacent the common port 20 to the conductive rod 5, the line segments 421 and 422 of the impedance transforming transmission line 42 of the invention have different diameters, and the diameter is gradually increased. The dielectric support member 44 is attached to the bottom wall of the cavity 12 and the recess is defined in the member 44 to support the sounding post 43, thereby ensuring that the sounding station 43 is isolated from the floor and the cavity 12.

[051] The number of line segments 421 and 422 of the impedance transformation transmission line 42 is not limited to the preferred model. Instead, more than two line segments 421, 422 can be presented based on the current requirement. Multiple line segments 421, 422 may also be integrally formed which then pass through a radially extending through hole 430 of the resonator station 43. Correspondingly, the impedance transformation transmission line 42 includes two line segments 421 and 422 of different diameters , and they can be integrally formed, and therefore the integrally formed line segment can pass through a through hole 430 of the resonant station 43. In this situation, the impedance transfer transmission line 42 can be considered to extend through the resonance station 43 and connects to it.

[052] As described above, on the one hand, the connecting member 41 near the common port 20 is capacitively coupled to a closer resonating post 311 of the first signal path 31, and on the other hand, it is directly and physically soldered to the conductive rod 5 of the second signal path 32 through the impedance transformation transmission line 42 and resonance station 43. Therefore, the combination and distribution of signals in two frequency bands is achieved between the common port 20 and two signal paths. sign 31,32.

[053] The principles of combination and distribution are described below.

[054] For the first signal path 31, as capacitive coupling exists between the link member 41 and the resonant post 311, the equivalent capacitance is constant. In this case, the impedance is inversely proportional to the frequency. Therefore, higher frequency signals can be transmitted over the first signal path 31. For the second signal path 32, as the transmission distance from link member 41 to impedance transformation transmission line 42 (including the resonance station 43) is equivalent to the inductance, the impedance is proportional to the frequency in case the inductance is constant. As such, lower frequency signals can be transmitted through the second signal path 32. Clearly, the combination and distribution structure of the invention has a unique design that achieves better isolation effect for signals with different frequencies.

[055] The resonant signals, which are caused by the resonance of the impedance transformation transmission line 42 during the combination and distribution performed by the two signal paths 31 and 32, may result in interference. However, due to the frequency shift function of the resonant station 43, the resonant signals are shifted outside the frequency bands. Therefore, resonant signals no longer become a source of interference, thus ensuring good electrical characteristics of the communication cavity component of the invention.

[056] With regard to signals with two different frequencies arriving along a forward direction from the two subports 21 and 22, after being filtered by the first signal path 31, the signal with high frequency is coupled to the common port 20 through the linker member 41 of the combining and distributing structure; after being filtered by the second signal path 32, the low-frequency signal is transferred to the common port 20 from the impedance transform transmission line 42, through the resonator station 43 and the link member 41. different frequencies are combined with each other at link member 41 and are output through common port 20.

[057] With regard to the mixed signals arriving from the common port 20 along a reverse direction, after passing through the link member 41, the high-frequency signal is coupled into the first signal path 31, transmitted here, and then is filtered and finally produced by subgate 21 of the first signal path 31. The low-frequency signal travels on the second signal path 32 from the link member 41, through the impedance transformation transmission line 42 and resonance 43, and then filtered on path 32. Finally, the low-frequency signal is produced by subgate 22 of the second signal path 32.

[058] In summary, a person skilled in the art understands, from the models of the invention, that the combination and distribution structure of the invention can also be applied to other communication cavity components, such as a combiner, duplexer and multi-frequency filter , and which is not limited to a dual frequency combiner as described above.

[059] Although several models of the invention have been illustrated above, a lay person understands that variations and improvements to the illustrative models are within the scope of the invention, and that the scope of the invention is only limited by the appended claims and their equivalents.

Claims (23)

1. Communication cavity component, characterized by comprising two signal paths, carried out in a cavity and used to transmit signals with different frequencies; wherein one end of the two signal paths combines and distributes two signals having different frequencies through the combination and distribution structure and forms a common port; wherein the distribution and combination structure comprises: a connecting member, one end of which is connected to the component port, while its other end is capacitively coupled to the first signal path; an impedance transformation transmission line, one end of which is connected to the second signal path, while its other end is connected to the connection member; additionally, the line comprises at least two line segments with different impedance; a resonant station connected to the impedance transformation transmission line at a central location on the line; and a dielectric support member for securing the resonant station and isolating it from the cavity. A communication cavity component according to claim 1, characterized in that the impedance transformation transmission line includes two line segments; wherein one end of one line segment is connected to the connecting member and one end of the other line segment is connected to the second signal path; wherein the other ends of both line segments are connected to the resonant station. A communication cavity component according to claim 1, characterized in that the two line segments of the impedance transformation transmission line are integrally formed; wherein a through hole is radially defined in the resonant station; wherein the impedance transfer transmission line passes through the through hole. Communication cavity component according to any one of claims 1 to 3, characterized in that the line segments of the impedance transforming transmission line have different diameters. Communication cavity component according to any one of claims 1 to 3, characterized in that the first signal path is a bandpass filter path, while the second signal path is a lowpass filter path. 6. Communication cavity component according to claim 5, characterized in that the second signal path is an elliptical low-pass filter path. Communication cavity component according to any one of claims 1 to 3, characterized in that the first signal path comprises a plurality of resonating stations; wherein the orifice is defined radially at a first signal resonating post close to the common port; wherein the connecting member is inserted into the hole and capacitively coupled to the same resonant post. A communication cavity component according to claim 7, characterized in that one end of the connecting member is connected to an inner conductor of the common port, while the other end is capacitively coupled to the resonating station. 9. Communication cavity component according to claim 8, characterized in that a dielectric sleeve is threaded into the connection member at a location where it is coupled to the resonance station. 10. Communication cavity component according to any one of claims 1 to 3, characterized in that the second signal path comprises a number of subcavities that communicate with each other sequentially, a number of resonance stations, each one being arranged between two adjacent subcavities, a conductive rod disposed in these resonating stations, and a number of tuning screws corresponding to the plurality of resonating stations in terms of location and quantity; wherein a number of threaded holes are defined in the conductive rod corresponding to the plurality of resonating stations in terms of location and quantity; wherein each tuning screw passes through a respective threaded hole and is inserted deep into a respective hole of the resonating station, so as to realize capacitive coupling between the tuning screw and the resonating station; wherein the impedance transformation transmission line is directly and physically connected to the conductive rod, thus establishing its connection to the second signal path. 11. Communication cavity component according to claim 10, characterized in that the number of subcavities are arranged along the same direction; correspondingly, the conductive rod is arranged linearly. 12. Communication cavity component according to claim 10, characterized in that the number of subcavities is not arranged along the same direction; correspondingly, the conductive rod has a bent construction. A communication cavity member according to claim 10, characterized in that the partial segment around the threaded through hole of the conductive rod has a diameter greater than a main body of the conductive rod. 14. A communication cavity component according to claim 10, characterized in that it forms a slit between a respective resonance station and a lower wall of the metal cavity; wherein each slit corresponding to the respective resonance station has a different height. A communication cavity component according to claim 10, characterized in that in said number of sub-cavities, the sub-cavities located between a front and a rear sub-cavity are of the same size. 16. Communication cavity component according to claim 10, characterized in that a dielectric sleeve is arranged between the tuning screw and the resonance station. 17. Combiner/duplexer/filter characterized in that it comprises a communication cavity component as defined in any one of claims 1 to 16. 18. Combination and distribution structure used in a communicating cavity component, characterized by comprising: a connecting member, one end of which forms a common port and the other end is used to connect to a first frequency signal of the cavity component of communication; an impedance transformation transmission line, one end of which is used to input a second frequency signal from the communicating cavity component, while its other end is connected to the connection member; additionally, the line includes at least two line segments with different impedance; a resonant station connected to the impedance transformation transmission line at a central location on the line; and a dielectric support member for securing the resonator post and isolating it from the cavity of the communicating cavity component. Combination and distribution structure according to claim 18, characterized in that the impedance transformation transmission line includes two line segments; wherein one end of one line segment is connected to the connecting member and one end of the other line segment is connected to the second signal path; wherein the other ends of both line segments are connected to the resonant station. Combination and distribution structure according to claim 18, characterized in that the two line segments of the impedance transformation transmission line are integrally formed; wherein a through hole is radially defined in the resonant station; wherein the impedance transfer transmission line passes through the through hole. Combination and distribution structure according to any one of claims 18 to 20, characterized in that the line segments of the impedance transforming transmission line have different diameters. A combination and distribution structure according to claim 21, characterized in that the diameter of the line segments of the impedance transforming transmission line gradually becomes larger from one end close to the connecting member to its other end . 23. Combiner/duplexer/filter characterized by comprising a communication cavity component as defined in any one of claims 18 to 22.

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