CN113571856A - Filter and communication equipment - Google Patents

Filter and communication equipment Download PDF

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Publication number
CN113571856A
CN113571856A CN202010352410.8A CN202010352410A CN113571856A CN 113571856 A CN113571856 A CN 113571856A CN 202010352410 A CN202010352410 A CN 202010352410A CN 113571856 A CN113571856 A CN 113571856A
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China
Prior art keywords
filter
cavity
filtering
branch
filtering cavity
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CN202010352410.8A
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Chinese (zh)
Inventor
张宝真
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Shenzhen Tatfook Technology Co Ltd
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Shenzhen Tatfook Technology Co Ltd
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Priority to CN202010352410.8A priority Critical patent/CN113571856A/en
Publication of CN113571856A publication Critical patent/CN113571856A/en
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01PWAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
    • H01P1/00Auxiliary devices
    • H01P1/20Frequency-selective devices, e.g. filters
    • H01P1/207Hollow waveguide filters
    • H01P1/208Cascaded cavities; Cascaded resonators inside a hollow waveguide structure

Abstract

The application discloses a filter and communication equipment. The filter includes: a housing having a first direction and a second direction which are arranged perpendicular to each other; the filtering branch is arranged on the shell and consists of twelve filtering cavities which are sequentially coupled, inductive cross coupling is respectively carried out between a second filtering cavity and a fourth filtering cavity of the filtering branch, between the fourth filtering cavity and a sixth filtering cavity, between the sixth filtering cavity and an eighth filtering cavity, and between the eighth filtering cavity and an eleventh filtering cavity of the filtering branch, and capacitive cross coupling is respectively carried out between a ninth filtering cavity and an eleventh filtering cavity of the filtering branch so as to form five cross coupling zero points of the filtering branch; the bandwidth range of the filter is 3400MHz-3600 MHz. In this way, the stop-band rejection performance of the filter can be improved.

Description

Filter and communication equipment
Technical Field
The present application relates to the field of communications technologies, and in particular, to a filter and a communications device.
Background
The cavity filter is a key device of a modern mobile communication system and is widely applied to wireless communication base stations and various communication terminals; the cavity filter is composed of a radio frequency connector, a cavity, a cover plate, a plurality of resonator units and a frequency tuning and coupling strength adjusting component, wherein the resonant frequencies of the plurality of resonator units are distributed in the passband range, and the cavity filter has a blocking function on signals outside the resonant frequencies, so that the function of selecting microwave transmission signals is realized; the cavity filter has the advantages of reliable structure, wide filtering frequency band, parasitic pass band far away from a channel, high Q value, stable electrical property, good heat dissipation performance and the like.
The inventor of the application finds that the arrangement of a plurality of filter cavities in the existing cavity filter is complex and irregular, the size of the filter is increased, and the stop band inhibition performance of the cavity filter is poor.
Disclosure of Invention
The application provides a filter and communication equipment, so as to improve stop band suppression performance of the filter.
In order to solve the technical problem, the application adopts a technical scheme that: there is provided a filter comprising: a housing having a first direction and a second direction which are arranged perpendicular to each other; the filtering branch is arranged on the shell and consists of twelve filtering cavities which are sequentially coupled, inductive cross coupling is respectively carried out between a second filtering cavity and a fourth filtering cavity of the filtering branch, between the fourth filtering cavity and a sixth filtering cavity, between the sixth filtering cavity and an eighth filtering cavity, and between the eighth filtering cavity and an eleventh filtering cavity of the filtering branch, and capacitive cross coupling is respectively carried out between a ninth filtering cavity and an eleventh filtering cavity of the filtering branch so as to form five cross coupling zero points of the filtering branch; the bandwidth range of the filter is 3400MHz-3600 MHz.
Optionally, twelve filter cavities of the filter branch are divided into two rows arranged along the second direction; the first filtering cavity, the second filtering cavity, the fourth filtering cavity, the sixth filtering cavity, the eighth filtering cavity, the eleventh filtering cavity and the twelfth filtering cavity of the filtering branch are in a row and are sequentially arranged along the first direction; and the third filtering cavity, the fifth filtering cavity, the seventh filtering cavity, the ninth filtering cavity and the tenth filtering cavity of the filtering branch are in a row and are sequentially arranged along the first direction. The twelve filtering cavities are divided into five rows which are sequentially arranged along the first direction, the cavities of the twelve filtering cavities are arranged regularly, the size of the filtering branch is reduced, and the size of the filter is further reduced.
Optionally, first windows are respectively arranged between a second filtering cavity and a fourth filtering cavity of the filtering branch, between the fourth filtering cavity and a sixth filtering cavity, between the sixth filtering cavity and an eighth filtering cavity, and between the eighth filtering cavity and an eleventh filtering cavity; and flying rods are arranged between the ninth filtering cavity and the eleventh filtering cavity of the filtering branch.
Optionally, the flying bar comprises a support clamping seat and a capacitive coupling flying bar, the capacitive coupling flying bar is fixed on the support clamping seat, and the support clamping seat is disposed in a window between a ninth filtering cavity and an eleventh filtering cavity of the filtering branch. Capacitive cross coupling can be achieved by flying rods.
Optionally, the capacitively coupled flying bar includes a first coupling portion, a second coupling portion and a connecting portion, and two ends of the connecting portion are respectively connected to the first coupling portion and the second coupling portion.
Optionally, metal coupling ribs are respectively disposed between the first filtering cavity and the second filtering cavity of the filtering branch, and between the eleventh filtering cavity and the twelfth filtering cavity of the filtering branch. Coupling strength between the first filtering cavity and the second filtering cavity and between the eleventh filtering cavity and the twelfth filtering cavity can be improved through the metal coupling ribs, so that energy loss is reduced, and energy transmission quality is improved.
Optionally, each of the filter cavities is provided with: the resonance rod comprises a U-shaped side wall and a hollow inner cavity formed by the U-shaped side wall; a tuning rod, one end of the tuning rod being disposed within the hollow interior; the two ends of the U-shaped side wall bend and extend in the direction away from the hollow inner cavity, so that disc-shaped structures are formed at the two ends of the U-shaped side wall, and the disc-shaped structures are arranged in parallel with the bottom of the U-shaped side wall. The disc-shaped structures at the two ends of the U-shaped side wall can increase the signal coupling amount of the resonant rod, and the resonant frequency of the resonant cavity can be adjusted by adjusting the depth of the tuning rod in the hollow inner cavity.
Optionally, the housing is further provided with a mounting post, and the U-shaped side wall is fixed to the mounting post.
The filter further comprises: the first port is connected with the first filtering cavity of the filtering branch circuit; and the second port is connected with the twelfth filtering cavity of the filtering branch circuit. The filtering branch circuit is convenient to design and manufacture by arranging the first port and the second port, and is favorable for improving the implementation of a scheme.
In order to solve the above technical problem, the present application adopts another technical solution: a communication device is provided. The communication equipment comprises an antenna and a radio frequency unit connected with the antenna, wherein the radio frequency unit comprises the filter and is used for filtering radio frequency signals.
The beneficial effect of this application is: different from the prior art, the filter of the embodiment of the application comprises: a housing having a first direction and a second direction which are arranged perpendicular to each other; the filtering branch is arranged on the shell and consists of twelve filtering cavities which are sequentially coupled, the fourth filtering cavity and the sixth filtering cavity of the filtering branch, the sixth filtering cavity and the eighth filtering cavity of the filtering branch are respectively in inductive cross coupling, and the second filtering cavity and the fourth filtering cavity and the ninth filtering cavity and the eleventh filtering cavity of the filtering branch are respectively in capacitive cross coupling so as to form five cross coupling zeros of the filtering branch; the bandwidth range of the filter is 3400MHz-3600 MHz. In the embodiment of the application, the inductive cross coupling is respectively performed between the fourth filter cavity and the sixth filter cavity, between the sixth filter cavity and the eighth filter cavity, and between the eighth filter cavity and the eleventh filter cavity of the filter branch, so that the high-end rejection of the bandwidth of the filter branch can be well controlled, and the high-end rejection of the bandwidth of the filter branch can be obtained, and the capacitive cross coupling is respectively performed between the second filter cavity and the fourth filter cavity, and between the ninth filter cavity and the eleventh filter cavity of the filter branch, so that two capacitive coupling zeros can be realized, the low-end rejection of the bandwidth of the filter can be well controlled, and the low-end rejection of the bandwidth of the filter can be obtained, and therefore, the stop band rejection performance of the filter can be improved; in addition, the bandwidth range of the filtering branch circuit is 3400MHz-3600MHz, and the bandwidth of the filtering branch circuit can be accurately controlled.
Drawings
In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.
FIG. 1 is a schematic diagram of an embodiment of a filter according to the present application;
FIG. 2 is a schematic diagram of the topology of the filter of the embodiment of FIG. 1;
FIG. 3 is a schematic diagram of the structure of the flying rod in the filter of FIG. 1;
FIG. 4 is a schematic structural diagram of a tuning rod, a resonant rod and a mounting post combined structure of the filter cavity of FIG. 1;
FIG. 5 is a schematic diagram of an equivalent circuit configuration of the filter of the embodiment of FIG. 1;
FIG. 6 is a diagram illustrating a simulated structure of the filter of the embodiment of FIG. 1;
fig. 7 is a schematic structural diagram of an embodiment of the communication device of the present application.
Detailed Description
The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.
The terms "first" and "second" in this application are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. In the description of the present application, "plurality" means at least two, e.g., two, three, etc., unless explicitly specifically limited otherwise. Furthermore, the terms "include" and "have," as well as any variations thereof, are intended to cover non-exclusive inclusions. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those steps or elements listed, but may alternatively include other steps or elements not listed, or inherent to such process, method, article, or apparatus.
First, a filter is provided, please refer to fig. 1 and fig. 2, in which fig. 1 is a schematic structural diagram of a first embodiment of the filter of the present application, and fig. 2 is a schematic topological structural diagram of the filter of fig. 1. The filter 10 of the present embodiment includes: a housing 11 and twelve filter chambers, wherein the housing 11 has a first direction x and a second direction y arranged perpendicular to each other; the filtering branch 12 is arranged on the shell 11 and is composed of twelve filtering cavities which are coupled in sequence.
Specifically, the twelve filter cavities of the filter branch 12 include: a first filtering cavity A1, a second filtering cavity A2, a third filtering cavity A3, a fourth filtering cavity A4, a fifth filtering cavity A5, a sixth filtering cavity A6, a seventh filtering cavity A7, an eighth filtering cavity A8, a ninth filtering cavity A9, a tenth filtering cavity A10, an eleventh filtering cavity A11 and a twelfth filtering cavity A12; inductive cross coupling is respectively performed between the second filtering cavity A2 and the fourth filtering cavity A4, between the fourth filtering cavity A4 and the sixth filtering cavity A6, between the sixth filtering cavity A6 and the eighth filtering cavity A8, and between the eighth filtering cavity A8 and the eleventh filtering cavity A11 of the filtering branch 12, and capacitive cross coupling is respectively performed between the ninth filtering cavity A9 and the eleventh filtering cavity A11 of the filtering branch 12; wherein, the bandwidth range of the filter 10 is 3400MHz-3600 MHz.
It can be seen that, inductive cross coupling is respectively performed between the second filter cavity a2 and the fourth filter cavity a4, between the fourth filter cavity a4 and the sixth filter cavity A6, between the sixth filter cavity A6 and the eighth filter cavity A8, and between the eighth filter cavity A8 and the eleventh filter cavity a11 of the filter branch 12, so that high-end rejection of the bandwidth of the filter branch 12 can be well controlled, and better high-end rejection of the bandwidth is obtained, and capacitive cross coupling is respectively performed between the second filter cavity a2 and the fourth filter cavity a4, and between the ninth filter cavity a9 and the eleventh filter cavity a11 of the filter branch 12, so that two capacitive coupling zeros can be realized, and low-end rejection of the bandwidth of the filter branch 12 can be well controlled, so that better low-end rejection of the bandwidth can be obtained, and therefore, the stop-band rejection performance of the filter 10 can be improved; in addition, the bandwidth range of the filtering branch 12 is 3400MHz-3600MHz, and the bandwidth of the filtering branch 12 can be accurately controlled.
Alternatively, as shown in fig. 1, the twelve filter cavities of the filter branch 12 are divided into two rows arranged along the second direction y; the first filtering cavity a1, the second filtering cavity a2, the fourth filtering cavity a4, the sixth filtering cavity a6, the eighth filtering cavity A8, the eleventh filtering cavity a11 and the twelfth filtering cavity a12 of the filtering branch 12 are in a row and are sequentially arranged along the first direction x; the third filtering cavity A3, the fifth filtering cavity a5, the seventh filtering cavity a7, the ninth filtering cavity a9 and the tenth filtering cavity a10 of the filtering branch 12 are in a row and are sequentially arranged along the first direction x.
It can be seen that the twelve filter cavities are divided into two rows arranged in sequence along the second direction y, and the twelve filter cavities are arranged regularly, so as to reduce the volume of the filter branch 12 and thus the volume of the filter 10.
Optionally, first windows are respectively arranged between the second filter cavity a2 and the fourth filter cavity a4, between the fourth filter cavity a4 and the sixth filter cavity a6, between the sixth filter cavity a6 and the eighth filter cavity A8, and between the eighth filter cavity A8 and the eleventh filter cavity a11 of the filter branch 12; flying rods are arranged between the ninth filtering cavity A9 and the eleventh filtering cavity A11 of the filtering branch circuit 12.
Referring to fig. 3, fig. 3 is a schematic structural diagram of a flying rod in the filter of fig. 1. Optionally, the flying bar comprises a support clamp 70 and a capacitive coupling flying bar 60, the capacitive coupling flying bar 60 is fixed on the support clamp 70, and the support clamp 70 is disposed in the window between the ninth filter cavity a9 and the eleventh filter cavity a11 of the filter branch 12. Capacitive cross coupling can be achieved by flying rods.
Specifically, the capacitively coupled flying bar 60 includes a first coupling portion 610, a second coupling portion 620 and a connecting portion 630, two ends of the connecting portion 630 are respectively connected to the first coupling portion 610 and the second coupling portion 620, and the first coupling portion 610 and the second coupling portion 620 are located on the same side of the connecting portion 630. The first coupling part 610, the connecting part 630 and the second coupling part 620 are connected in sequence to form the capacitive coupling flying bar 60; the first coupling part 610 is coupled to the resonance rod 20 in the ninth filter cavity a9 such that a coupling capacitance is formed between the first coupling part 610 and the resonance rod 20, and the second coupling part 620 is coupled to the resonance rod 20 in the eleventh filter cavity a11 such that a coupling capacitance is formed between the second coupling part 620 and the resonance rod 20.
As shown in fig. 1 and 3, the supporting clamp 70 may be disposed on the housing 11, and the supporting clamp 70 is provided with a through hole (not shown), wherein the connecting portion 630 penetrates through the through hole to fix the capacitively coupled flying bar 60 on the supporting clamp 70.
The capacitively coupled flying bar 60 of this embodiment may be implemented by a metal probe, and the support holder 70 may be implemented by PTFE or engineering plastic.
Optionally, as shown in fig. 1, twelve filter cavities of the filter branch 12 are sequentially window-coupled, and a second window is disposed between two filter cavities of the filter branch 12 that are sequentially coupled. That is, a second window is disposed between the first filter cavity a1 and the second filter cavity a2, a second window is disposed between the second filter cavity a2 and the third filter cavity A3, a second window is disposed between the third filter cavity A3 and the fourth filter cavity A4, a second window is disposed between the fourth filter cavity A4 and the fifth filter cavity A5, a second window is disposed between the fifth filter cavity A5 and the sixth filter cavity A6, a second window is disposed between the sixth filter cavity A6 and the seventh filter cavity A7, a second window is disposed between the seventh filter cavity A7 and the eighth filter cavity a8, a second window is disposed between the eighth filter cavity a8 and the ninth filter cavity a9, a second window is disposed between the ninth filter cavity a9 and the tenth filter cavity a10, a twelfth filter cavity a11 a11 and the eleventh filter cavity a12 are disposed between the tenth filter cavity a10 and the eleventh filter cavity a 585.
Therefore, the second window between two adjacent filter cavities on the coupling path of the filter branch 12 is pure window coupling, so that the cost of the filter 10 is reduced.
Optionally, the first window and the second window are both provided with a first tuning rod 31 for adjusting the coupling strength, and in particular, the first tuning rod 31 may be used for adjusting the coupling bandwidths of the second filter cavity a2 and the fourth filter cavity a4, the fourth filter cavity a4 and the sixth filter cavity a6, the sixth filter cavity a6 and the eighth filter cavity A8, and the eighth filter cavity A8 and the eleventh filter cavity a 11. Electromagnetic energy can be transmitted between two adjacent filter cavities on the coupling path through the filter branch 12 through the window, and the coupling bandwidth can be adjusted through the first tuning rod 31 of the filter branch.
Further, as shown in fig. 1, metal coupling ribs 80 are respectively disposed between the first filter cavity a1 and the second filter cavity a2, and between the eleventh filter cavity a11 and the twelfth filter cavity a12 of the filter branch 12.
The coupling strength between the first filter cavity A1 and the second filter cavity A2 and between the eleventh filter cavity A11 and the twelfth filter cavity A12 can be improved through the metal coupling ribs 80, so that the loss of energy is reduced, and the quality of energy transmission is improved.
Referring to fig. 4, fig. 4 is a schematic structural diagram of a tuning rod, a resonant rod and a mounting post combined structure of the filter cavity of fig. 1. Optionally, each filter cavity is provided with: a resonant rod 20 including a U-shaped sidewall 210 and a hollow interior 220 formed by the U-shaped sidewall 210; a tuning rod 30, one end of the tuning rod 30 being disposed within the hollow interior 220; the two ends of the U-shaped sidewall 210 are bent and extended away from the hollow cavity 220, so as to form a disc-shaped structure 230 at the two ends of the U-shaped sidewall 210 and parallel to the bottom of the U-shaped sidewall 210. The housing 11 is further provided with a mounting post 40, the U-shaped sidewall 210 is fixed on the mounting post 40, and the resonant rod 20 is fixed on the housing 11 through the mounting post 40.
The resonant rod 20, the hollow cavity 220 and the tuning rod 30 of the present embodiment are coaxially disposed.
Further, a mounting hole (not shown) may be formed in the bottom of the U-shaped sidewall 210, one end of the mounting post 40 is fixed to the housing 11, and the other end of the mounting post 40 is mounted in the mounting hole, so as to fix the resonant rod 20 to the mounting post 40; the mounting holes may be through holes, the mounting holes may be threaded holes, and the mounting posts 40 are studs. In other embodiments, the mounting hole may also be a blind hole.
Optionally, the twelve filter cavities of the present embodiment may be metal filter cavities, and the resonant rod 20 may be a metal resonant rod.
The material of the resonant rod 20 of the present embodiment may be the cut 1215 MS. Of course, in other embodiments, the resonant rod 20 may be an M8 or M4 screw rod, and may be made of copper or silver.
The twelve filter cavities have the same size, so that the production is convenient, and the cost is saved. The radius of the twelve filter cavities may be less than 21mm, e.g. 20mm, 19mm, 18mm, etc.
It can be seen that the resonant rod 20 can be secured to the housing 11 by the mounting post 40 and the resonant frequency of the resonant cavity can be adjusted by adjusting the depth of the tuning rod 30 within the hollow interior 220.
Further, the filter 10 further includes a cover plate (not shown) disposed on the twelve filter cavities, and the other end of the tuning rod 30 penetrates the cover plate, wherein the tuning rod 30 may be a metal screw.
As shown in FIG. 2, the second filter cavity A2 and the fourth filter cavity A4 of the filter branch 12 are inductively cross-coupled to form an inductive coupling zero L1(ii) a The fourth filter cavity A4 and the sixth filter cavity A6 are inductively cross-coupled to form an inductive coupling zero point L2(ii) a The sixth filter cavity A6 and the eighth filter cavity A8 are inductively cross-coupled to form an inductive coupling zero point L3(ii) a The eighth filter cavity A8 and the eleventh filter cavity A11 are inductively cross-coupled to form an inductive coupling zero point L4(ii) a The ninth filter cavity A9 and the eleventh filter cavity A11 of the filter branch 12 are capacitively cross-coupled to form a capacitive coupling zero point C1(ii) a To form five cross-coupling zeros of the filter branch 12. The cross-coupling zero is also referred to as a transmission zero. The transmission zero is the transmission function of the filter 10 equal to zero, that is, the electromagnetic energy at the frequency point corresponding to the transmission zero cannot pass through the network, so that the complete isolation effect is achieved, the suppression effect on the signals outside the passband is achieved, and the high isolation among a plurality of passbands can be better achieved.
The filter 10 further comprises: a first port connected to the first filter cavity a1 of the filter branch 12; and a second port connected to the twelfth filter cavity a12 of the filter branch 12.
The equivalent circuit of the filter 10 of this embodiment is shown in fig. 5, where the impedance Z1 at the input port is about 50 ohms, and the impedance Z2 at the output port is about 50 ohms; in order to ensure that electromagnetic signals are transmitted between the twelve filter cavities of the filter 10, impedance adjusters ZV1 are respectively disposed between the input port and the first filter cavity a1, between adjacent filter cavities on the coupling path, between non-cascaded filter cavities forming cross coupling, and between the twelfth filter cavity a12 and the output port, so as to achieve impedance matching.
The bandwidth range of the filter 10 of the present embodiment is: 3400MHz-3600 MHz. Specifically, the coupling bandwidth between the first port and the first filter cavity A1 ranges from 196Mhz to 222 Mhz; the coupling bandwidth between the first filter cavity a1 and the second filter cavity a2 ranges from 155Mhz to 176 Mhz; the coupling bandwidth between the second filter cavity a2 and the third filter cavity A3 ranges from 74Mhz to 86 Mhz; the coupling bandwidth between the second filter cavity a2 and the fourth filter cavity a4 ranges from 76Mhz to 89 Mhz; the coupling bandwidth between the third filter cavity A3 and the fourth filter cavity a4 ranges from 63Mhz to 74 Mhz; the coupling bandwidth between the fourth filter cavity a4 and the fifth filter cavity a5 ranges from 89Mhz to 103 Mhz; the coupling bandwidth between the fourth filter cavity a4 and the sixth filter cavity a6 ranges from 32Mhz to 40 Mhz; the coupling bandwidth between the fifth filter cavity a5 and the sixth filter cavity a6 ranges from 88Mhz to 102 Mhz; the coupling bandwidth between the sixth filter cavity a6 and the seventh filter cavity a7 ranges from 78Mhz to 91 Mhz; the coupling bandwidth between the sixth filter cavity a6 and the eighth filter cavity A8 ranges from 50Mhz to 60 Mhz; the coupling bandwidth between the seventh filter cavity a7 and the eighth filter cavity A8 ranges from 80Mhz-93 Mhz; the coupling bandwidth between the eighth filter cavity A8 and the ninth filter cavity a9 ranges from 93Mhz-107 Mhz; the coupling bandwidth between the eighth filter cavity A8 and the eleventh filter cavity a11 ranges from 26Mhz to 33 Mhz; the coupling bandwidth between the ninth filter cavity a9 and the tenth filter cavity a10 ranges from 38Mhz to 46 Mhz; the coupling bandwidth between the ninth filter cavity a9 and the eleventh filter cavity a11 ranges from (-97) Mhz- (-83) Mhz; the coupling bandwidth between the tenth filter cavity a10 and the eleventh filter cavity a11 ranges from 83Mhz to 97 Mhz; the coupling bandwidth between the eleventh filter cavity a11 and the twelfth filter cavity 12 ranges from 155Mhz to 176 Mhz; the coupling bandwidth between the twelfth filter cavity a12 and the second port ranges from 196Mhz to 222Mhz, which can meet the design requirements.
Therefore, the resonant frequencies of the first filter cavity a1 through the twelfth filter cavity a12 of the filter 10 are sequentially located in the following ranges: 3498Mhz-3500Mhz, 3677Mhz-3679Mhz, 3494Mhz-3496Mhz, 3533Mhz-3535Mhz, 3496Mhz-3498Mhz, 3555Mhz-3557Mhz, 3500Mhz-3502Mhz, 3477Mhz-3479Mhz, 3411Mhz-3413Mhz, 3498Mhz-3500Mhz, and 3498Mhz-3500 Mhz. Therefore, the resonant frequency of each resonant cavity is within the designed bandwidth range, so that the convenience of manufacturing and debugging is improved; the method can be manufactured by adopting similar specification parameters, and the required parameter range can be reached only by simple debugging in the actual process.
The simulation result of the filter 10 of the present embodiment is shown in fig. 6, and it can be known from fig. 6 that the bandwidth of the filter 10 of the present embodiment is about 3400MHz-3600 MHz; as shown in the frequency band curve S1, there are two low-end coupling zeros a, b and three high-end coupling zeros c, d, e. The suppression of the filtering branch 12 at the frequency point 3.400GHz (m1) is-0.966 dB, the suppression of the filtering branch 12 at the frequency point 3.600GHz (m2) is-1.795 dB, the suppression of the filtering branch 12 at the frequency point 3.370GHz (m3) is-76.390 dB, the suppression of the frequency point 3.380GHz (m4) is-47.208 dB, the suppression of the filtering branch 12 at the frequency point 3.610GHz (m5) is-36.979 dB, the suppression of the frequency point 3.620GHz (m6) is-72.333 dB, the suppression of the filtering branch 12 at the frequency point 3.630GHz (m7) is-98.495 dB, and the suppression of the filtering branch 12 at the frequency point 3.700GHz (m8) is-112.667 dB, so that the design requirement of out-of-band suppression of the filter 10 can be met.
The filter 10 of the present embodiment is a 12-order microwave filter applied to a 5G mobile communication system, and has the characteristics of a working frequency band of 3400MHz-3600MHz, strong anti-interference capability, small overall size, and light weight.
The filter 10 in the embodiment of the application has low loss, and can ensure low energy consumption of the communication module; the filter 10 is designed by combining 12-order resonant cavities, and a coupling zero structure is introduced, so that the filter has strong anti-interference capability and can ensure that a communication system is not interfered by stray signals; the filter 10 has a simple design scheme, low cost, and good structural and electrical performance stability; the filter 10 can meet the use of the current latest 5G mobile communication system, and the filter 10 mainly relates to the 3400MHz-3600MHz frequency band.
The present application further provides a communication device, as shown in fig. 7, fig. 7 is a schematic structural diagram of an embodiment of the communication device of the present application. The communication device of the present embodiment includes an antenna 92 and a radio frequency unit 91 connected to the antenna 92, the radio frequency unit 91 includes a filter 10 as shown in the above-mentioned embodiment, and the filter 10 is used for filtering a radio frequency signal.
In other embodiments, the rf Unit 91 may be integrated with the Antenna 92 to form an Active Antenna Unit (AAU).
Some embodiments of the present application are referred to as filters and may also be referred to as combiners, i.e., dual-frequency combiners. It is understood that in other embodiments, the duplexer may be referred to as a duplexer.
The above description is only for the purpose of illustrating embodiments of the present application and is not intended to limit the scope of the present application, and all modifications of equivalent structures and equivalent processes, which are made by the contents of the specification and the drawings of the present application or are directly or indirectly applied to other related technical fields, are also included in the scope of the present application.

Claims (10)

1. A filter, characterized in that the filter comprises:
a housing having a first direction and a second direction which are arranged perpendicular to each other;
the filtering branch is arranged on the shell and consists of twelve filtering cavities which are sequentially coupled, inductive cross coupling is respectively carried out between a second filtering cavity and a fourth filtering cavity of the filtering branch, between the fourth filtering cavity and a sixth filtering cavity, between the sixth filtering cavity and an eighth filtering cavity, and between the eighth filtering cavity and an eleventh filtering cavity of the filtering branch, and capacitive cross coupling is respectively carried out between a ninth filtering cavity and an eleventh filtering cavity of the filtering branch so as to form five cross coupling zero points of the filtering branch;
the bandwidth range of the filter is 3400MHz-3600 MHz.
2. The filter of claim 1,
twelve filter cavities of the filter branch circuit are divided into two rows arranged along the second direction;
the first filtering cavity, the second filtering cavity, the fourth filtering cavity, the sixth filtering cavity, the eighth filtering cavity, the eleventh filtering cavity and the twelfth filtering cavity of the filtering branch are in a row and are sequentially arranged along the first direction;
and the third filtering cavity, the fifth filtering cavity, the seventh filtering cavity, the ninth filtering cavity and the tenth filtering cavity of the filtering branch are in a row and are sequentially arranged along the first direction.
3. The filter according to claim 2, wherein first windows are respectively arranged between the second filter cavity and the fourth filter cavity, between the fourth filter cavity and the sixth filter cavity, between the sixth filter cavity and the eighth filter cavity, and between the eighth filter cavity and the eleventh filter cavity of the filter branch;
and a flying rod is arranged between the ninth filtering cavity and the eleventh filtering cavity of the filtering branch.
4. The filter according to claim 3, wherein the flying bar comprises a support clamping seat and a capacitive coupling flying bar, the capacitive coupling flying bar is fixed on the support clamping seat, and the support clamping seat is arranged on a window between the ninth filtering cavity and the eleventh filtering cavity of the filtering branch.
5. The filter of claim 4, wherein the capacitively coupled flying bar comprises a first coupling portion, a second coupling portion and a connecting portion, and both ends of the connecting portion are respectively connected with the first coupling portion and the second coupling portion.
6. The filter according to claim 4, wherein metal coupling ribs are respectively disposed between the first filter cavity and the second filter cavity, and between the eleventh filter cavity and the twelfth filter cavity of the filter branch.
7. The filter of claim 1, wherein each of the filter cavities has disposed therein:
the resonance rod comprises a U-shaped side wall and a hollow inner cavity formed by the U-shaped side wall;
a tuning rod, one end of the tuning rod being disposed within the hollow interior;
the two ends of the U-shaped side wall bend and extend in the direction away from the hollow inner cavity, so that disc-shaped structures are formed at the two ends of the U-shaped side wall, and the disc-shaped structures are arranged in parallel with the bottom of the U-shaped side wall.
8. The filter of claim 7, wherein the housing further comprises a mounting post, and the U-shaped sidewall is secured to the mounting post.
9. The filter of claim 8,
the filter further comprises:
the first port is connected with the first filtering cavity of the filtering branch circuit;
and the second port is connected with the twelfth filtering cavity of the filtering branch circuit.
10. A communication device, characterized in that the communication device comprises an antenna and a radio frequency unit connected to the antenna, the radio frequency unit comprising a filter according to any of claims 1-9 for filtering a radio frequency signal.
CN202010352410.8A 2020-04-28 2020-04-28 Filter and communication equipment Pending CN113571856A (en)

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Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE19602815A1 (en) * 1995-01-27 1996-08-08 Israel State Microwave band pass filter with cross coupling
CN209691912U (en) * 2018-12-31 2019-11-26 深圳市大富科技股份有限公司 A kind of duplexer and communication equipment
CN209691910U (en) * 2018-12-31 2019-11-26 深圳市大富科技股份有限公司 A kind of filter, duplexer and communication equipment
CN209691911U (en) * 2018-12-31 2019-11-26 深圳市大富科技股份有限公司 A kind of duplexer and communication equipment

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE19602815A1 (en) * 1995-01-27 1996-08-08 Israel State Microwave band pass filter with cross coupling
CN209691912U (en) * 2018-12-31 2019-11-26 深圳市大富科技股份有限公司 A kind of duplexer and communication equipment
CN209691910U (en) * 2018-12-31 2019-11-26 深圳市大富科技股份有限公司 A kind of filter, duplexer and communication equipment
CN209691911U (en) * 2018-12-31 2019-11-26 深圳市大富科技股份有限公司 A kind of duplexer and communication equipment

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Application publication date: 20211029