阅读说明：本技术 带阻滤波器、用于带阻滤波器的传输线、以及复用器 (Band-stop filter, transmission line for band-stop filter, and multiplexer ) 是由 李贤祥 吕扬准 米青 顾琦云 G·瑞斯纳缇 于 2019-03-14 设计创作，主要内容包括：本发明涉及通信系统中使用的带阻滤波器,包括壳体,包括顶壁、底壁以及至少一个侧壁,所述壳体限定了内部空腔；设置在所述至少一个侧壁中的一个侧壁上的信号输入端口和信号输出端口；设置在所述内部空腔中的谐振元件,所述谐振元件包括顶部、底部和侧部；以及传输线,所述传输线设置于所述内部空腔中并耦接在所述信号输入端口与所述信号输出端口之间,所述传输线包括与所述谐振元件耦合的耦合段,其中,所述耦合段被构造为围绕所述谐振元件的侧部半周以上,并且被构造为不与所述壳体和所述谐振元件直接接触。本发明还涉及用于带阻滤波器的传输线和复用器。(The present invention relates to a band reject filter for use in a communication system, comprising a housing comprising a top wall, a bottom wall and at least one side wall, the housing defining an internal cavity; a signal input port and a signal output port disposed on one of the at least one side wall; a resonating element disposed in the internal cavity, the resonating element comprising a top, a bottom, and a side; and a transmission line disposed in the internal cavity and coupled between the signal input port and the signal output port, the transmission line including a coupling section coupled with the resonant element, wherein the coupling section is configured to surround more than a half-circumference of a side of the resonant element and is configured not to directly contact the housing and the resonant element. The invention also relates to a transmission line and a multiplexer for a band stop filter.)

1. A band stop filter comprising:

a housing including a top wall, a bottom wall, and at least one side wall, the housing defining an interior cavity;

a signal input port disposed on one of the at least one side wall;

a signal output port disposed on one of the at least one side wall;

a resonating element disposed in the internal cavity, the resonating element comprising a top, a bottom, and a side; and

a transmission line disposed in the internal cavity and coupled between the signal input port and the signal output port, the transmission line including a coupling segment coupled to the resonant element,

wherein the coupling section is configured to surround a side half-circumference or more of the resonance element and is configured not to be in direct contact with the housing and the resonance element.

2. The band reject filter according to claim 1, wherein the coupling section is configured to completely surround a side portion of the resonant element.

3. The band-stop filter of claim 2, wherein the coupling segment is configured as a substantially ring shape substantially parallel to the bottom wall.

4. The band reject filter of claim 3, wherein the resonant element is a coaxial resonant element and a longitudinal axis of the coaxial resonant element is substantially perpendicular to the bottom wall, wherein the resonant element and the transmission line are positioned such that the longitudinal axis of the coaxial resonant element passes substantially through a center of the coupled section.

5. The band reject filter according to claim 3, wherein the transmission line further comprises a first connection segment and a second connection segment,

the coupling section is joined with the first connecting section through a first joint and is coupled to the signal input port through the first connecting section;

the coupling section is joined to the second connection section by a second junction and coupled to the signal output port via the second connection section,

wherein the first junction point and the second junction point are positioned at different locations of an outer circumference of the substantially annular coupling section.

6. The band reject filter of claim 5, wherein the first junction point and the second junction point are non-centrally symmetric about a center of the inner circumference of the substantially circular coupling section.

7. The band reject filter of claim 5, wherein the transmission line is coupled between the signal input port and the signal output port sequentially through the first connection segment, the coupling segment, and the second connection segment.

8. The band reject filter of claim 3, wherein the resonant element is a first resonant element, the coupled section is a first coupled section, the band reject filter further comprising a second resonant element, the transmission line further comprising a second coupled section,

the second coupling section is configured in a substantially annular shape completely surrounding a side of the second resonator element and is configured not to be in direct contact with the housing and the second resonator element,

wherein the second coupling section and the first coupling section are positioned on a common plane.

9. The band reject filter according to claim 8, wherein the housing further comprises a partition extending upwardly from the bottom wall to the internal cavity to define therein substantially mutually isolated first and second cavities on opposite sides of the partition, respectively, wherein the first resonant element is disposed within the first cavity with the first coupling section and the second resonant element is disposed within the second cavity with the second coupling section.

10. The band reject filter of claim 9, wherein the first and second resonant elements are adjacent to each other, the transmission line further comprising a connecting segment configured to connect the first and second coupled segments, the connecting segment being positioned on the common plane and having a bend.

Technical Field

The present invention relates to communication systems, and more particularly to a band-stop filter suitable for use in a radio communication system, a transmission line for a band-stop filter, and a multiplexer including a band-stop filter.

Background

Radio communication systems are designed to operate in specific frequency bands. For example, in North American countries, radio communication systems use frequency bands including (among others) Cell800MHz band (frequency range 824-894 MHz), PCS (Personal Communications Service) 1900MHz band (frequency range 1850-1990 MHz, hereinafter referred to as PCS band), AWS (Advanced Wireless Services) 1700MHz band (frequency range 1710-1755 MHz, hereinafter referred to as AWS1 band), and AWS 2100MHz band (frequency range 2110-2155 MHz, hereinafter referred to as AWS2 band).

There is a great demand for base stations (hereinafter referred to as multi-band base stations) configured to operate in a plurality of RF bands (e.g., PCS, AWS1, and AWS2 bands). Fig. 1A is a schematic diagram of a conventional multi-band base station. As shown in fig. 1A, a multi-band base station may include an antenna 640 configured to transmit and receive radio communication signals in multiple RF bands, a radio 610 for a first frequency band (e.g., PCS band), a radio 620 for a second frequency band (e.g., AWS1 and AWS2 bands), and a multiplexer 630. Wherein the radios 610, 620 may also be connected to respective baseband units (not shown). Multiplexer 630 is connected to antenna 640 by a connection path 650 (e.g., coaxial cable). In some cases, connection 650 may be connected to a duplexer (not shown) so that transmit and receive signals may be carried on a single connection 650. It should also be understood that the base station may generally include various other devices not shown in fig. 1A, such as a power supply, a battery backup, a power bus, an Antenna Interface Signal Group (AISG) controller, and the like.

In a multi-band base station supporting services in the PCS, AWS1, and AWS2 bands, multiplexer 630 is configured to: synthesizing the signals of the first and second frequency bands into a combined signal when transmitting the transmission signal; and separating the received signals to separate out signals in each frequency band when the received signals are transmitted. In one known implementation, the multiplexer 630 includes three bandpass filters for passing signals within the PCS, AWS1, and AWS2 frequency bands, respectively. In another known implementation, the multiplexer 630 includes a band pass filter for passing signals in the PCS band and a band reject filter for rejecting signals in the PCS band and passing signals in the AWS1/2 band (which refers to the combination of the AWS1 band and the AWS2 band).

Fig. 1B is a perspective view schematically showing a conventional band-stop filter, in which at least a partial structure of the band-stop filter is shown. The band-reject filter may be used for the multiplexer 630 described above. A band reject filter (including a notch filter) has an input port, an output port, a housing defining an internal cavity, a resonating element disposed in the internal cavity, and a transmission line coupled to the resonating element.

As shown in fig. 1B, the band elimination filter may include a case 10 defining an internal cavity, which has a plurality of partition walls 11, 12, 13 extending from a sidewall of the case 10 to the internal cavity and extending upward from a bottom surface of the case 10, thereby dividing the internal cavity into a plurality of cavities 20-1 to 20-4. It should be noted that herein when a plurality of identical or similar elements are provided, they may be labeled in the figures using two-part reference numerals (e.g., cavity 20-1). These elements may be referred to herein individually by their full reference number (e.g., cavity 20-1), and may be referred to collectively by a first portion of their reference number (e.g., cavity 20). Each cavity 20 is provided therein with a mounting portion 15 fixed to the bottom surface of the housing 10 for mounting a corresponding resonant element.

Each resonant element 40 is disposed in the corresponding cavity 20 by being fixed to the mounting portion 15. In the example shown in FIG. 1B, the resonating element used in the cavity 20-1 is omitted to better illustrate the mounting portion 15. Resonant elements 40-1 through 40-3 are disposed in cavities 20-2 through 20-4, respectively. Any one of the resonant elements 40 may comprise, for example, a dielectric resonant element or a coaxial metallic resonant element. The band stop filter further comprises a frequency tuning element 41 for each resonant element 40. The resonant frequency of its associated resonant element 40 can be tuned by adjusting the frequency tuning element 41.

The band reject filter further comprises a transmission line 30. Transmission line 30 is coupled between an input port (not shown) and an output port (not shown) of the band stop filter. The transmission line 30 comprises a coupling section 31 arranged close to the resonator elements 40 on one side of each resonator element 40 for coupling with the respective resonator element 40. The transmission line 30 further includes a mounting segment 32, the mounting segment 32 being secured to the clip 14 provided by the housing 10 such that the transmission line 30 is located within the interior cavity defined by the housing 10.

A top wall (not shown) of the housing 10 may be mounted by fitting mounting screws to the mounting holes 16 so that the inner cavity defined by the housing 10 is isolated from the outside. When the top wall is mounted, the partition walls 11, 12, 13 are in close contact with the top wall, so that the isolation between the cavities 20 meets the design requirements of the filter. Each resonant element 40 resonates at a resonant frequency in the corresponding cavity 20.

Aspects of the frequency response of the band-stop filter may be adjusted by tuning the resonant frequency of each resonant element 40, and the coupling between the transmission line 30 and each resonant element 40.

Disclosure of Invention

It is an object of the present invention to provide a band-stop filter, a transmission line for a band-stop filter, and a multiplexer suitable for use in a communication system.

According to a first aspect of the present invention, there is provided a band stop filter comprising: a housing including a top wall, a bottom wall, and at least one side wall, the housing defining an interior cavity; a signal input port disposed on one of the at least one side wall; a signal output port disposed on one of the at least one side wall; a resonating element disposed in the internal cavity, the resonating element comprising a top, a bottom, and a side; and a transmission line disposed in the internal cavity and coupled between the signal input port and the signal output port, the transmission line including a coupling section coupled with the resonant element, wherein the coupling section is configured to surround more than a half-circumference of a side of the resonant element and is configured not to directly contact the housing and the resonant element.

According to a second aspect of the present invention, there is provided a transmission line for a band-stop filter, the band-stop filter comprising a housing defining an internal cavity, a signal input port and a signal output port provided on the housing, and a resonant element and a transmission line provided in the internal cavity, wherein the transmission line is coupled between the signal input port and the signal output port, the transmission line comprising a coupling section configured as a substantially ring shape substantially parallel to a bottom wall of the housing and completely surrounding a side of the resonant element, and the coupling section being free from direct contact with the housing and the resonant element such that the transmission line is coupled with the resonant element through the coupling section.

According to a third aspect of the present invention, there is provided a band-stop filter comprising: a housing defining an interior cavity; a signal input port on the housing; a signal output port on the housing; a resonating element located in the internal cavity; and a transmission line located in the internal cavity and coupled between the signal input port and the signal output port, the transmission line including a coupling section through which the transmission line is coupled with the resonant element, wherein the coupling section includes a first portion surrounding the resonant element from a first side portion thereof, and a second portion surrounding the resonant element from a second side portion thereof opposite the first side, a first end of the first portion and a first end of the second portion being connected by the first joint.

According to a fourth aspect of the present invention, there is provided a multiplexer comprising: a band pass filter configured to pass signals within a first frequency band and reject signals within other frequency bands; a band-stop filter, as described above, configured to reject at least signals within the first frequency band and pass at least signals within a second frequency band and signals within the frequency band, wherein the second frequency band is lower than the first frequency band, wherein the first frequency band is lower than the third frequency band; inputting a signal; a first output coupled to the signal input via the band pass filter; and a second output coupled to the signal input via the band-stop filter.

According to a fifth aspect of the present invention, there is provided a method of self-adjusting coupling between a transmission line and a resonant element in a band stop filter, the method comprising: at least part of the transmission line is configured to completely surround a side of the resonant element and not to be in direct contact with the resonant element, such that the transmission line is coupled with the resonant element.

Other features of the present invention and advantages thereof will become apparent from the following detailed description of exemplary embodiments thereof, which proceeds with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description, serve to explain the principles of the invention.

Fig. 1A is a simplified schematic diagram schematically illustrating a conventional multi-band base station in a radio communication system.

Fig. 1B is a perspective view schematically showing a conventional band-stop filter, in which at least a partial structure of the band-stop filter is shown.

Fig. 2 is a top view of a part of a radio frequency device comprising a multiplexer according to one embodiment of the invention, the multiplexer comprising a band-stop filter according to another embodiment of the invention, the top view showing at least part of the structure of the multiplexer and the band-stop filter.

Fig. 3 is a perspective view of the radio frequency device shown in fig. 2 with the resonating element, the coupling tuning element, and the transmission line removed.

Fig. 4 is another perspective view of the radio frequency device shown in fig. 2 with the resonating element, the coupling tuning element, the transmission line, and the input-output port removed.

Fig. 5 is an enlarged partial perspective view of the radio frequency device shown in fig. 2.

Fig. 6 is a plan view of a transmission line in the radio frequency device shown in fig. 2, wherein the transmission line is a transmission line according to an embodiment of the present invention.

Fig. 7 is a highly simplified top view of a band-stop filter according to another embodiment of the invention.

Fig. 8 is a highly simplified top view of a band-stop filter according to yet another embodiment of the invention.

Fig. 9A to 9C are schematic block diagrams of applications of the radio frequency device shown in fig. 2.

Fig. 10A to 10C are schematic diagrams illustrating test parameters of the radio frequency device shown in fig. 2.

Note that in the embodiments described below, the same reference numerals are used in common between different drawings to denote the same portions or portions having the same functions, and a repetitive description thereof will be omitted. In some cases, similar reference numbers and letters are used to denote similar items, and thus, once an item is defined in one figure, it need not be discussed further in subsequent figures.

For convenience of understanding, the positions, sizes, ranges, and the like of the respective structures shown in the drawings and the like do not sometimes indicate actual positions, sizes, ranges, and the like. Therefore, the present invention is not limited to the positions, dimensions, ranges, and the like disclosed in the drawings and the like.

Detailed Description

The present invention will now be described with reference to the accompanying drawings, which illustrate several embodiments of the invention. It should be understood, however, that the present invention may be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein; rather, the embodiments described below are intended to provide a more complete disclosure of the present invention and to fully convey the scope of the invention to those skilled in the art. It is also to be understood that the embodiments disclosed herein can be combined in various ways to provide further additional embodiments.

It is understood that the terminology used herein is for the purpose of describing particular embodiments only, and is not intended to limit the scope of the present invention. All terms (including technical and scientific terms) used herein have the meaning commonly understood by one of ordinary skill in the art unless otherwise defined. Well-known functions or constructions may not be described in detail for brevity and/or clarity.

When an element is referred to herein as being "on," attached to, "" connected to, "coupled to," or "contacting" another element, etc., it can be directly on, attached to, connected to, coupled to or contacting the other element or intervening elements may be present. In contrast, when an element is referred to as being "directly on," "directly attached to," directly connected to, "directly coupled to," or "directly contacting" another element, there are no intervening elements present. In this context, one feature being disposed "adjacent" another feature may refer to one feature having a portion that overlaps or is above or below the adjacent feature.

In this document, reference may be made to elements or nodes or features being "coupled" together. Unless expressly stated otherwise, "coupled" means that one element/node/feature may be mechanically, electrically, logically, or otherwise joined to another element/node/feature in a direct or indirect manner to allow for interaction, even though the two features may not be directly connected. That is, to "couple" is intended to include both direct and indirect joining of elements or other features, including connection with one or more intermediate elements.

In this document, spatial relationship terms such as "upper", "lower", "left", "right", "front", "back", "high", "low", and the like may describe one feature's relationship to another feature in the drawings. It will be understood that the terms "spatially relative" encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, features originally described as "below" other features may be described as "above" other features when the device in the figures is inverted. The device may also be otherwise oriented (rotated 90 degrees or at other orientations) and the relative spatial relationships may be interpreted accordingly.

Herein, the term "a or B" includes "a and B" and "a or B" rather than exclusively including only "a" or only "B" unless otherwise specifically stated.

In this document, the term "exemplary" means "serving as an example, instance, or illustration," and not as a "model" that is to be reproduced exactly. Any implementation exemplarily described herein is not necessarily to be construed as preferred or advantageous over other implementations. Furthermore, there is no intention to be bound by any expressed or implied theory presented in the preceding technical field, background, brief summary or the detailed description.

In this document, the term "substantially" is intended to encompass any minor variations due to design or manufacturing imperfections, tolerances of the devices or components, environmental influences and/or other factors. The term "substantially" also allows for differences from a perfect or ideal situation due to parasitics, noise, and other practical considerations that may exist in a practical implementation.

In addition, "first," "second," and like terms may also be used herein for reference purposes only, and thus are not intended to be limiting. For example, the terms "first," "second," and other such numerical terms referring to structures or elements do not imply a sequence or order unless clearly indicated by the context.

It will be further understood that the terms "comprises/comprising," "includes" and/or "including," when used herein, specify the presence of stated features, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, steps, operations, elements, and/or components, and/or groups thereof.

Embodiments of the present invention provide band-stop filters that may be used as stand-alone devices, or to form duplexers, diplexers, combiners/splitters, and/or multiplexers/demultiplexers, etc. Embodiments of the present invention provide a multiplexer to which the band-stop filter is applied and a transmission line for the band-stop filter. Embodiments of the present invention also provide a radio frequency device comprising a multiplexer according to an embodiment of the present invention, the multiplexer comprising a band-reject filter according to an embodiment of the present invention. Some embodiments of the invention are described based on such a radio frequency device.

The band elimination filter according to an embodiment of the present invention includes a transmission line in which a coupling section of the transmission line is configured to surround a side half-circumference or more of a resonant element to be coupled with the resonant element, increases a coupling area between the transmission line and the resonant element compared to a case where the coupling section of the transmission line is close to the resonant element at one side of the resonant element in the conventional band elimination filter as shown in fig. 1B, thereby enabling a greater coupling strength to be obtained with the same separation distance between the transmission line and the resonant element, which is advantageous in providing a better frequency response to the filter; and allows increasing the separation distance between the transmission line and the resonant element, which facilitates the manufacturing and assembly of the band-stop filter, in case the same coupling strength is to be achieved.

In some embodiments, configuring the coupling section of the transmission line to completely surround the side of the resonant element allows the band stop filter to self-adjust the coupling between the transmission line and the resonant element, for example, when the longitudinal axis of the resonant element is not well aligned with the center of the coupling section, the same amount of coupling can still be achieved as if the longitudinal axis of the resonant element just passed through the center of the coupling section. This can relax the requirements of the manufacturing and assembly processes of the transmission line and the resonant element, making the band stop filter easy to manufacture and assemble. In some embodiments, the connecting section of the transmission line for connecting the coupling sections has a bend, which enables a physical distance between two adjacent resonant elements to be reduced in the case where an electrical distance between the two adjacent resonant elements is a predetermined value, which is advantageous in reducing the volume of the band-stop filter. In some embodiments, the coupling section is configured as a substantially ring shape (or called a circular ring) completely surrounding the resonant element, which makes the characteristics of the coupling section at each point of the circumference of the ring substantially the same, so that the joint point of the connecting section and the coupling section can be selectively arranged at any position of the circumference of the ring according to the design requirement of the filter, which is beneficial to the arrangement design of the filter and the routing design of the transmission line. In some embodiments, the transmission line is a substantially flat conductor that is easy to manufacture.

Referring to fig. 2 to 6, a radio frequency device according to an embodiment of the present invention will be described. Fig. 2 is a top view of a part of a radio frequency device comprising a multiplexer according to an embodiment of the invention, the multiplexer comprising a band-stop filter, at least part of the structure of the multiplexer and at least part of the structure of the band-stop filter being shown in the top view. Fig. 3 is a perspective view of the radio frequency device shown in fig. 2 with the resonating element, the coupling tuning element, and the transmission line removed. Fig. 4 is another perspective view of the radio frequency device shown in fig. 2 with the resonating element, the coupling tuning element, the transmission line, and the input-output port removed. Fig. 5 is an enlarged perspective view of a portion of the radio frequency device shown in fig. 2. Fig. 6 is a plan view of a transmission line in the radio frequency device shown in fig. 2.

Referring first to fig. 3, a radio frequency device according to one embodiment of the present invention includes a housing 50 including a top wall (not shown), a bottom wall, and side walls 51, thereby defining an internal cavity. The housing 50 further includes a partition wall 52 extending from the side wall 51 to an internal cavity and extending upward from the bottom wall, the internal cavity being divided by the partition wall 52 into a total of four sections (see fig. 4), cavities 71, 72, 73 and 74, respectively. As shown in FIGS. 3 and 4, the partition wall 52-1 defines a cavity 71 with the side walls 51-1, 51-2 and 51-3, the partition wall 52-1, the side walls 51-1 and 51-3, and the partition wall 52-3 define a cavity 72, the partition wall 52-3, the side walls 51-1 and 51-3, and the partition wall 52-2 define a cavity 73, and the partition wall 52-2 defines a cavity 74 with the side walls 51-1, 51-3 and 51-4. The cavity 71 is used to form a first band-pass filter, the cavity 72 is used to form a first band-stop filter, the cavity 73 is used to form a second band-stop filter, and the cavity 74 is used to form a second band-pass filter. When the top wall of the housing 50 is mounted in place, the side walls 51 and the partition walls 52 are brought into close contact with the top wall, so that the respective cavities 71 to 74 form substantially closed spaces, respectively.

The radio frequency device further comprises a plurality of signal input and output ports 61, 62, 63 extending through the side wall 51. With port 63-1 extending through sidewall 51-1 and port 61-1 extending through sidewall 51-3 opposite sidewall 51-1. The port 63-1 is coupled to the port 61-1 through a first band stop filter. Port 62-1 extends through sidewall 51-3 and port 63-1 is coupled to port 62-1 through a first bandpass filter. The first bandpass filter and the first band stop filter share port 63-1 such that when a signal is input at port 63-1, a first signal component of the signal lying in the passband of the first bandpass filter is output via port 62-1 and a second signal component lying in the passband of the first band stop filter is output via port 61-1. When signals are input at ports 61-1, 62-1, a combined signal comprising a first signal located in the pass band of the first bandpass filter and a second signal located in the pass band of the first bandpass filter is output via port 63-1.

Port 63-2 extends through sidewall 51-1 and ports 61-2 and 62-2 extend through sidewall 51-3, wherein port 61-2 is coupled to port 63-2 through a second band-stop filter and port 62-2 is coupled to a second band-pass filter, respectively, such that when a signal is input at port 63-2, a first signal component of the signal lying in the passband of the second band-pass filter is output through port 62-2 and a second signal component lying in the passband of the second band-stop filter is output through port 61-2. When signals are input at ports 61-2, 62-2, a combined signal comprising a first signal located in the passband of the second band pass filter and a second signal located in the passband of the second band stop filter is output via port 63-2.

As shown, the outside of the portions of the ports 61, 62, 63 that extend outside of the housing 50 are provided with connectors 64, 65, 66 (e.g., threaded connectors, flanges, etc.) for connection to other equipment. For example, the connectors 64, 65, 66 may be implemented as coaxial connectors that mate with coaxial cables, and the ports 61, 62, 63 may be implemented as conductors that may be electrically connected to the center conductors of the coaxial cables, as shown.

As can be seen from the above description, the first band-pass and first band-stop filters and their respective ports form a first three-port device (which may be applied, for example, as a combiner/splitter, a diplexer/demultiplexer), and the second band-pass and second band-stop filters and their respective ports form a second three-port device. When the top wall of the housing 50 is installed in place, each of the first and second three-port devices may be independently operated since the intermediate partition wall 52-3 continuously contacts the top wall such that the first and second three-port devices are substantially completely isolated from each other. Although in the embodiment shown in the drawings the first and second three-port devices are of almost identical construction, it will be appreciated that the two three-port devices operating independently may have different constructions and characteristics. Furthermore, the transmission direction of the signals in the first and second three-port devices may also be different.

Examples of some applications of radio frequency devices are shown in fig. 9A to 9C. As shown in fig. 9A, in one example, a first three-port device 331 in the radio frequency device 330 may be used for a signal transmit path and a second three-port device 332 may be used for a signal receive path. A duplexer 320 is connected between the antenna 310 and the radio frequency device 330, a transmit channel port Tx of the duplexer 320 is connected to a port 63-1 of a first three-port device 331 of the radio frequency device 330, and ports 61-1, 62-1 of the first three-port device 331 are connected to two ports 341, 342 of a radio transmitter 340, respectively. The two ports 341, 342 may be used for signals of different frequency bands. The receive path port Rx of the duplexer 320 is connected to the port 63-2 of the second three-port device 332 of the radio frequency device 330, and the ports 61-2, 62-2 of the second three-port device 332 are connected to the two ports 351, 352, respectively, of the radio receiver 350. The two ports 351, 352 may be used for signals of different frequency bands. For example, in a multi-band base station supporting the PCS, AWS1/2 bands, a first bandpass filter in the first three-port device 331 is used to pass signals in the PCS band, a first bandpass filter is used to block at least signals in the PCS band and to pass at least signals in the AWS1/2 band. Port 342 of radio transmitter 340 outputs signals in the PCS band to port 62-1 of first three-port device 331 and port 341 outputs signals in the AWS1/2 band to port 61-1. The combined PCS, AWS1/2 band signal is output at port 63-1 of the first three-port device 331 and is transmitted through duplexer 320 to antenna 310 for transmission. The signal received by the antenna 310 passes through the duplexer 320 and enters the second three-port device 332 from the receive path port Rx and port 63-2, a first signal component in the PCS band of the received signal is output from port 62-2 to port 352 of the radio receiver 350, and a second signal component in the AWS1/2 band is output from port 61-2 to port 351. Since the first and second three-port devices 331 and 332 operate in the same frequency band in this example, the duplexer 320 may be configured as a Time Division Duplex (TDD) device. In other examples not shown in the figures, the first and second three-port devices 331 and 332 may operate at different frequency bands, and the duplexer 320 may be configured as a Frequency Division Duplex (FDD) or a time division duplexer.

In another example, as shown in fig. 9B, a first three-port device 431 and a second three-port device 432 in the radio frequency device 430 may both be used for signal transmission and/or reception channels. Radio 440 may provide signals in the AWS1/2 band and radio 450 may provide signals in the PCS band. The two ports 441 and 442 of the radio 440 may output signals in the AWS1/2 frequency band having first and second polarizations, respectively, and are connected to port 61-1 of the first three-port device 431 and port 61-2 of the second three-port device 432, respectively. Two ports 451 and 452 of radio 450 may output signals in the PCS band with first and second polarizations, respectively, and are connected to port 62-1 of first three-port device 431 and port 62-2 of second three-port device 432, respectively. First three-port device 431 outputs a first combined signal having a first polarization from port 63-1 and second three-port device 432 outputs a second combined signal having a second polarization from port 63-2. The first and second combined signals may be multiplexed by the multiplexer 420 and transmitted to the antenna 410.

In yet another example, as shown in FIG. 9C, the base station may include more than one antenna, two antennas 511 and 512 being shown. A first three-port device 531 and a second three-port device 532 in the radio frequency device 530 may be used for the antennas 511 and 512, respectively. Port 541 of radio 540 providing signals in the AWS1/2 band is coupled to ports 61-1 and 61-2 (e.g., may be through a power coupler), and port 551 of radio 550 providing signals in the PCS band is coupled to ports 62-1 and 62-2. The first and second three port devices 531, 532 output combined signals from ports 63-1, 63-2, respectively, which are provided to antennas 511, 512, respectively.

Further, although not shown in the figures, it should be understood that each of the three-port devices in the radio frequency device may operate as a diplexer, for example, when the bandpass filter and the bandstop filter therein pass signals in different frequency bands, respectively. In addition, the radio frequency device itself may also operate as a duplexer when the first three-port device and the second three-port device operate at different frequency bands.

It should be noted that "input" and "output" in the description of the two examples of fig. 9B and 9C describe the situation when the base station transmits RF signals. It should be understood that "input" and "output" in these descriptions may operate as "output" and "input," respectively, when the base station receives an RF signal.

Although a radio frequency device comprising two three-port devices, each comprising a band-pass filter and a band-stop filter, has been described above with reference to fig. 2 to 6, it will be appreciated that a radio frequency device according to other embodiments of the present invention may comprise only one three-port device, or more than two three-port devices. Furthermore, although the input and output ports of each of the radio frequency devices shown in fig. 2 to 6 are disposed on opposite sidewalls, it should be understood that the input and output ports of each three-port device may be disposed on adjacent sidewalls, respectively, or collectively on the same sidewall.

The band pass and band reject filters comprised by the radio frequency device are described below with continued reference to fig. 2 to 6.

A first band pass filter is formed in the cavity 71. The first band pass filter comprises resonant elements 81-1 to 81-5 and frequency tuning elements 82-1 to 82-5 (e.g. frequency tuning screws). The resonant element 81 is formed on the bottom wall of the housing 50 and extends upward. The resonant element 81 may be integrally formed on the bottom wall of the housing 50 or may be mounted to the bottom wall of the housing 50. The interior of each resonator element 81 comprises a cavity and each resonator element 81 has an upward opening. Each frequency tuning element 82 is configured to extend to a variable depth into the cavity formed by the corresponding resonant element 81 to tune the resonant frequency of the respective resonant element 81. In addition, the first bandpass filter further includes coupling tuning elements (e.g., coupling tuning screws), such as coupling tuning elements 83-1 and 83-2 for adjusting the coupling between adjacent resonant elements 81, and coupling tuning element 83-4 for adjusting the coupling between non-adjacent resonant elements 81 (e.g., resonant elements 81-1 and 81-5). The port 62-1 of the first band pass filter may be coupled to the resonant element 81-1. For example, when port 62-1 is implemented as a conductor, the conductor may extend into the cavity formed by resonating element 81-1 to transmit a signal. Port 63-1 may be coupled to resonant element 81-3 to transmit a signal. In the illustrated embodiment, the bottom wall is also formed with upwardly extending mounting portions 89-1 (in the second bandpass filter, the mounting portions are shown as 89-2). The mounting portion 89 is formed with a threaded hole for mounting the top wall.

A first band stop filter is formed in the cavity 72. The housing 50 also includes a partition wall 53 extending upwardly from the bottom wall into the cavity 72 to divide the cavity 72. The partition wall 53-1 defines a cavity 72-1 together with the side wall 51-3 and the partition walls 52-1, 52-3. The partition wall 53-2 and the partition walls 52-1, 52-3, 53-1 together define a cavity 72-2. The partition wall 53-3 defines a cavity 72-3 together with the side wall 51-1 and the partition walls 53-2 and 52-3. The partition wall 53-3 defines a cavity 72-4 together with the side wall 51-1 and the partition wall 52-1. The upper end of the partition wall 53-1 is provided with a recess 3 to accommodate the transmission line 90. When the top wall of the housing 50 is mounted in place, the cavities 72 are substantially isolated from each other, i.e., each forms a substantially closed space, since the upper ends of the partition walls 53-1 are continuously in contact with the top wall except for the recess. Each of the cavities 72-1 to 72-4 is provided therein with a mounting portion 84-1 to 84-4 for mounting a resonant component 85-1 to 85-4, respectively. The mounting portion 84 may be integrally formed on the bottom wall of the housing 50, or may be mounted to the bottom wall of the housing 50. The resonant assemblies 85 are positioned and operate in the respective cavities 72 by being mounted to the respective mounts 84. The first band stop filter further comprises a transmission line 90 disposed in the cavity 72 and coupled to the resonant element in the resonant assembly 85. The transmission line 90 passes through the cavities 72-1 through 72-4 in sequence and is coupled between the ports 61-1 and 63-1.

Ends 94-1 and 94-2 of transmission line 90 are formed to facilitate coupling to ports 61-1 and 63-1, respectively. For example, the end 94-1 is formed with a recess into which the port 61-1, implemented as a conductor, may protrude to implement coupling to the transmission line 90. End 94-2 tapers in width and may be positioned on an upper surface of port 63-1 to effect coupling to port 63-1. In the illustrated embodiment, the two ends 94-1 and 94-2 of the transmission line 90 make electrical contact with the conductors of the ports 61-1 and 63-1, respectively, such that these couplings are implemented as galvanic connections, enabling the transmission line 90 to pass lower frequency signals and DC signals in addition to higher frequency signals. The lower frequency signal or dc signal may be, for example, a power supply signal, a detection signal, a control signal (e.g., a control signal sent by an operator from a remote location to control the antenna to adjust its pointing direction), and the like. It should be understood that the transmission line 90 may also be coupled between the ports 61-1 and 63-1 in other known manners.

Since the structures of the portions of the first band stop filter located in each cavity 72 are similar, fig. 5 shows only the portion of the first band stop filter located in the cavity 72-4 as an example, and those skilled in the art can derive the structures of the filters located in other cavities 72 from this and other figures.

The resonant assembly 85-4 includes a resonant element 851 and a frequency tuning screw 852. The resonator element 851 is mounted on the mounting part 84-4 positioned in the cavity 72-4 and does not contact with the side wall of the cavity 72-4. The interior of the resonator element 851 is formed with a cavity and the resonator element 851 has an upward opening. The frequency tuning screw 852 is configured to extend a variable depth into the cavity formed by the resonator element 851 to tune the resonant frequency of the resonator element 851 such that the resonator element 851, which is located in the substantially closed cavity 72-4, resonates at the desired resonant frequency. It will be appreciated that mounting holes are provided in the top wall of the housing 50 at corresponding locations so that the frequency tuning screws 852 may extend into the cavity formed by the resonant element 851 to a desired depth after being mounted in the mounting holes.

The transmission line 90 includes four coupled segments 91-1 through 91-4 and four connecting segments 92-1 through 92-4. Each coupling segment 91 may be configured as a substantially ring shape completely surrounding the sidewall of the corresponding resonant element (e.g., resonant element 851) and the coupling segments 91 are not in direct contact with the housing 50 and/or the resonant element, such that the transmission line 90 is electromagnetically coupled to the resonant element via the coupling segments 91. In the illustrated embodiment, the upper edge of the upward opening of the resonator element 851 has an outward flange 851-1, the lower surface of the flange 851-1 being opposite to the upper surface of the coupling section 91-4. In some embodiments, the flange 851-1 and the coupling section 91-4 have an overlapping portion in a plan view parallel to the bottom wall of the housing 50. This increases the coupling area between the resonator element 851 and the coupling section 91-4, increases the coupling strength with a certain spacing between the resonator element 851 and the coupling section 91-4, and also allows a suitable increase in the spacing between the resonator element 851 and the coupling section 91-4 with a certain coupling strength, as compared to conventional designs.

The resonator element 851 is a coaxial resonator element and the longitudinal axis of the resonator element 851 is substantially perpendicular to the bottom wall of the housing 50 and the plane in which the coupling section 91-4 is located is substantially parallel to the bottom wall of the housing 50. In some cases, the resonant element 851 and the coupling segment 91-4 of the transmission line 90 are positioned such that the longitudinal axis of the resonant element 851 passes substantially through the center of the substantially annular coupling segment 91-4. In these cases, for example, the distance from the sidewall of the resonant element 851 (referring to the portion of the sidewall adjacent to portion A) to portion A of coupling section 91-4 is substantially equal to the distance from the sidewall of the resonant element 851 (referring to the portion of the sidewall adjacent to portion B) to portion B of coupling section 91-4, which makes a first coupling strength between the resonant element 851 and portion A of coupling section 91-4 equal to a second coupling strength between the resonant element 851 and portion B of coupling section 91-4. In other words, the coupling strength between the resonator element 851 and the parts of the coupling segment 91-4 is substantially equal in these cases.

In other cases, a misalignment (e.g., a slight offset) of the longitudinal axis of the resonant element 851 with the center of the coupling segment 91-4 may result, for example, due to manufacturing/assembly errors of the resonant element 851 or the transmission line 90. In these cases, for example, when the longitudinal axis of the resonant element 851 is biased toward part A of coupling segment 91-4, the distance from the sidewall of resonant element 851 to part A of coupling segment 91-4 is less than the distance from the sidewall of resonant element 851 to part B of coupling segment 91-4, which results in a third coupling strength between resonant element 851 and part A of coupling segment 91-4 that is greater than a fourth coupling strength between resonant element 851 and part B of coupling segment 91-4. And the third coupling strength in these cases is greater than the first coupling strength in the above-described case, while the fourth coupling strength is less than the second coupling strength in the above-described case. This makes the total coupling strength of the resonator element 851 and the entire coupling section 91-4 in these cases equal to that in the above-described case. In other words, according to the transmission line of the embodiment of the present invention, it is possible to make the coupling between the transmission line and the resonance element self-adjustable in the band stop filter. For example, although the coupling strengths between the resonant element 851 and the portions of the coupling segment 91-4 are not equal, the total coupling strength between the resonant element 851 and the entire coupling segment 91-4 is substantially equal to the total coupling strength when the longitudinal axis of the resonant element 851 passes right through the center of the substantially circular coupling segment 91-4, since the coupling strength between the resonant element 851 and some portions of the coupling segment 91-4 increases while the coupling strength between other portions decreases. This may reduce the requirements on the manufacturing and assembly process. It should be appreciated that the portion A, B in the above example may be any two opposing portions on the coupling segment 91-4.

The four connection segments 92 of the transmission line 90 include connection segments 92-1 to 92-3 connected between adjacent two of the coupling segments 91, and connection segments coupled between the coupling segments 91 and the input/output ports (e.g., connection segment 92-4 coupling segment 91-4 to port 63-1). For example, connecting segment 92-4 is formed at a first end thereof with a tapered width end 94-2, as described above for coupling to port 63-1, and at a second end thereof with coupling segment 91-4 via junction C. The first end of connecting segment 92-3 is connected to coupling segment 91-4 through junction D. The second end of connecting segment 92-3 is connected to coupling segment 91-3 through junction E and the first end of connecting segment 92-2 is connected to coupling segment 91-3 through junction F. Since the coupling section 91 is constructed in a substantially circular shape, the characteristics of the transmission line 90 are substantially the same at each point on the circumference of the circular shape, and therefore, those skilled in the art can select the positions of two junctions located on the same coupling section 91 circumference according to the design requirements of the filter (e.g., the positions where the respective resonant elements are disposed), that is, the junction C and the junction D can be respectively located at any two different points on the outer circumference of the substantially circular coupling section 91-4, and the junction E and the junction F can be respectively located at any two different points on the outer circumference of the substantially circular coupling section 91-3. For example, the locations of the two junctions may be selected to be substantially centrosymmetric (e.g., junctions E and F) or non-centrosymmetric (e.g., junctions C and D) about the center of the outer circumference of the substantially annular coupling segment 91.

The phase difference introduced by the two paths between the first junction point and the second junction point located on the same coupling segment 91 circumference (e.g. the left and right parts of the loop between junction point C and junction point D) can be calibrated in the processing of the received and/or transmitted signal (e.g. by a baseband processing device).

The connecting segment 92 for connecting two adjacent coupling segments 91 may extend substantially along a straight line (e.g., the connecting segment 92-3 for connecting the coupling segments 91-4 and 91-3) or may have bends (e.g., the connecting segment 92-2 for connecting the coupling segments 91-3 and 91-2 and the connecting segment 92-1 for connecting the coupling segments 91-2 and 91-1). The bends may have any suitable shape, such as S-shaped, right-angled, etc. In designing a band stop filter, the electrical distance between two adjacent resonant elements in the filter (which affects the difference in phase of the signal transmitted on the transmission line at the two resonant elements, respectively) has a desired value. In the case where the electrical distance between two adjacent resonance elements is determined, the use of the connecting section 92 having a bend allows the physical distance between the two adjacent resonance elements to be reduced compared to the use of the connecting section 92 extending in a straight line, which is advantageous in terms of compactness of the structure.

Each partition wall 53 for partitioning the adjacent two cavities 72 may have a recess for receiving the connecting section 92. Taking the partition wall 53-1 as an example, as shown in fig. 4, a first surface of the partition wall 53-1 adjacent to the cavity 72-1 has an opening 1 for receiving a G portion of the connecting segment 92-1 of the transmission line 90 (as shown in fig. 2), and a second surface of the partition wall 53-2 opposite to the first surface has an opening 2 for receiving an H portion of the connecting segment 92-1 (as shown in fig. 2). There is a positional stagger of the openings 1 and 2 so that the connecting section 92-1 may not extend along a straight line. The top surface of the partition wall 53-1 has a recess 3 for receiving the main body portion of the connecting section 92-1. When the top wall of the housing 50 is mounted in place, the portion of the top surface of the partition wall 53-1 excluding the recess 3 is brought into close contact with the top wall, thereby isolating the cavities 72-1 and 72-2 from each other. The bottom of the recess 3 is provided with mounting holes 4 and the main body portion of the connecting section 92-1 is separately provided with mounting holes 93-1 (see fig. 6), so that the connecting section 92-1 can be fixed to the partition wall 53-1 via the mounting holes 4 and 93-1 using fasteners such as plastic screws.

The connecting segments 92-2 to 92-4 of the transmission line 90 are also provided with mounting holes 93-2 to 93-4, respectively (see fig. 6), for fixing the connecting segments 92-2 to 92-4 to the corresponding partitions 53-2, 53-3, 52-1, respectively. In addition, the connecting segment 92-4 of the transmission line 90 is formed with an extension 95 (extending in the plane of the transmission line 90) that can be used to support the coupling tuning element 83-3 of the first three-port device. The coupling tuning element 83-3 is used to tune the coupling between the first band pass filter and the first band stop filter.

In the embodiment shown in the figures, the transmission line 90 is formed as a strip line and is configured to be substantially flat. In other words, the portions of the transmission line 90, including the coupling segment 91 and the connecting segment 92 (even with the bent connecting segment 92), are substantially in the same plane. This facilitates the manufacture of the transmission line 90, for example, the entirety of the transmission line 90 may be formed by a stamping process.

The second bandpass filter is formed in the cavity 74 and includes resonant elements 88-1 through 88-5 (see fig. 4). Since the structure of the second band pass filter is similar to that of the first band pass filter in the illustrated embodiment, the description of the second band pass filter is omitted. A second band reject filter is formed in the cavity 73. The cavity 73 is divided by the partition walls 54-1 to 54-3 and 52-2 into four cavities 73-1 to 73-4 substantially isolated from each other, and the cavities 73-1 to 73-4 are respectively provided with mounting portions 87-1 to 87-4 for mounting the corresponding resonance elements. Since the structure of the second band-stop filter is similar to that of the first band-stop filter in the illustrated embodiment, the description of the second band-stop filter is omitted.

Fig. 10A to 10C are schematic diagrams illustrating test parameters of the radio frequency device shown in fig. 2. Fig. 10A is a plot of the ratio of the output signal at the two ports 63-1 and 61-1 of the first band stop filter in the radio frequency device to the strength of the input signal (with port 63-1 as the input and port 61-1 as the output, or port 61-1 as the input and port 63-1 as the output), i.e., the power of the output signal divided by the power of the input signal, versus frequency, which may reflect the frequency response of the first band stop filter. The frequency and intensity ratios are shown for six points m1 to m6 on the graph. It can be seen that the stop band of the first band-stop filter at least includes the PCS frequency band (between 1.85GHz corresponding to point m1 and 1.995GHz corresponding to point m 2), and the rejection of signals in the PCS frequency band is greater than 40 dB. Meanwhile, the first band-stop filter has substantially no suppression on signals in the AWS1 frequency band (between 1.695GHz corresponding to the point m5 and 1.78GHz corresponding to the point m 3) and the AWS2 frequency band (between 2.11GHz corresponding to the point m6 and 2.7GHz corresponding to the point m 4).

Fig. 10B is a plot of the ratio of the reflected signal to the input signal strength at port 61-1 of the first band stop filter in the radio frequency device as a function of frequency, which may also reflect the frequency response of the first band stop filter. The frequency and intensity ratios corresponding to four points m1 to m4 on the curve are shown. It can be seen that for the AWS1 frequency band (between 1.695GHz corresponding to the point m1 and 1.78GHz corresponding to the point m 2) and the AWS2 frequency band (between 2.11GHz corresponding to the point m3 and 2.7GHz corresponding to the point m 4), the ratio of the intensity of the reflected signal to the intensity of the input signal is-24 dB or less, i.e., the intensity of the reflected signal of the first band-stop filter for the signals in the two frequency bands is small, which indicates that the signals in the AWS1/2 frequency band input from the port 61-1 are allowed to pass through the rf device and output by the other ports. Whereas for the PCS band the ratio of the strength of the reflected signal to the input signal is 0dB, i.e. the signals in this band are almost totally reflected back, indicating that signals in the PCS band input to port 61-1 are almost not allowed to pass through the radio device.

Fig. 10C is a plot of the ratio of the reflected signal to the input signal strength at the common port 63-1 (i.e., the common port of the first band stop filter and the first band pass filter) in the radio frequency device as a function of frequency. The frequency and intensity ratios are shown for six points m1 to m6 on the graph. It can be seen that, whether for the AWS1 frequency band (between 1.695GHz corresponding to point m1 and 1.78GHz corresponding to point m 2) and the AWS2 frequency band (between 2.11GHz corresponding to point m5 and 2.7GHz corresponding to point m 6), or for the PCS frequency band (between 1.85GHz corresponding to point m3 and 1.995GHz corresponding to point m 4), the ratio of the intensity of the reflected signal to the input signal is-23 dB or less, which indicates that after the signals in these three frequency bands are input to port 63-1, they are allowed to pass through the rf device shown in fig. 2 and can be output by other ports.

In the above embodiments, the band-stop filter is one that blocks at least signals in the PCS band and passes at least signals in the AWS1/2 band. It should be understood that band-stop filters may also be used to block signals in other frequency bands and/or passing through other frequency bands. Although in the above embodiments the band-stop filter comprises four resonant elements, it will be appreciated that the number of resonant elements in the band-stop filter depends on the width of the stop band of the band-stop filter. Thus, the band-stop filter may comprise fewer or more than four resonant elements. Correspondingly, the transmission line in the band stop filter may also comprise a corresponding number of coupled sections. In the above embodiments, the band-stop filter is used in a three-port device operating with a band-pass filter. It will be appreciated that the band reject filter may also operate with other filters or other radio frequency devices, and of course may not operate with any filters or radio frequency devices.

In the above embodiments, the coupling section of the transmission line is substantially annular completely around the side of the resonant element. It will be appreciated that in some embodiments the coupling section of the transmission line may be of other shapes that completely surround the resonant element at the sides of the resonant element. The other shape may be a planar shape similar to the annular shape in the above-described embodiment, such as an elliptical ring shape, a triangular shape, a rectangular shape, or another polygonal shape, and may also be a three-dimensional shape, such as a cylindrical shape having a cross section of a circle, an elliptical shape, a triangular shape, a rectangular shape, or another polygonal shape. In other embodiments, the coupling section of the transmission line may partially surround the side of the resonant element.

As shown in fig. 7, the band elimination filter 100 according to another embodiment of the present invention includes a housing 110, and four cavities 131 to 134 are formed in the housing 110. Resonant elements 151 through 154 are located in cavities 131 through 134, respectively, to resonate at respective resonant frequencies. The transmission line 140 has a main line coupled in a straight line between the input port 123 and the output port 124. Ports 123 and 124 are connected to external cables through connectors 121 and 122, respectively. Transmission line 140 further includes four branches extending from the main line into four respective cavities 131 to 134, each branch including a respective coupling segment 141-1 to 141-4 coupled to a resonant element 151 to 154, respectively, and a connecting segment 142-1 to 142-4 for connecting coupling segments 141-1 to 141-4 to the main line. Coupling section 141 may be configured as a substantially ring shape completely surrounding the resonant elements 151, 153, 154 on the sides of the resonant element 151, such as coupling sections 141-1, 141-3, 141-4, or as a fan ring partially surrounding the resonant element 152, such as coupling section 141-2.

As shown in fig. 8, the band reject filter 200 according to still another embodiment of the present invention includes a case 210, and three cavities 231 to 233 are formed in the case 210. Resonant elements 251 to 253 are located in the cavities 231 to 233, respectively, to resonate at respective resonant frequencies. Transmission line 240 is coupled between input port 223 and output port 224. Ports 223 and 224 are connected to external cables through connectors 221 and 222, respectively. The transmission line 240 includes coupling segments 241-1 to 241-3 coupled to the resonant elements 251 to 253, respectively, the coupling segments 241-1 to 241-3 being configured to partially surround the sides of the resonant elements 251 to 253. Transmission line 240 also includes connecting segments 242-1 and 242-2 that connect adjacent coupled segments 241. Where the connection segment 242-1 is straight and the connection segment 242-2 has bends, which can be designed depending on the spacing of the band stop filter 200 and the desired electrical distance between adjacent resonant elements 252 and 253.

In the above embodiments, the resonant elements in the band-stop filter according to the embodiment of the present invention each have a circular (or annular) cross section. It is to be understood that the invention is not limited to the shape of the resonator element, which may be designed according to the actual requirements.

In addition, embodiments of the present disclosure may also include the following examples:

1. a band stop filter comprising:

a housing including a top wall, a bottom wall, and at least one side wall, the housing defining an interior cavity;

a signal input port disposed on one of the at least one side wall;

a signal output port disposed on one of the at least one side wall;

a resonating element disposed in the internal cavity, the resonating element comprising a top, a bottom, and a side; and

a transmission line disposed in the internal cavity and coupled between the signal input port and the signal output port, the transmission line including a coupling segment coupled to the resonant element,

wherein the coupling section is configured to surround a side half-circumference or more of the resonance element and is configured not to be in direct contact with the housing and the resonance element.

2. The band-stop filter according to 1, wherein the coupling section is configured to completely surround a side portion of the resonance element.

3. The band-stop filter of claim 2, wherein the coupled section is configured as a substantially ring shape substantially parallel to the bottom wall.

4. The band-stop filter of claim 3, wherein the resonant element is a coaxial resonant element and a longitudinal axis of the coaxial resonant element is substantially perpendicular to the bottom wall, wherein the resonant element and the transmission line are positioned such that the longitudinal axis of the coaxial resonant element passes substantially through the center of the coupled section.

5. The band reject filter of claim 3, wherein the transmission line further comprises a first connection segment and a second connection segment,

the coupling section is joined with the first connecting section through a first joint and is coupled to the signal input port through the first connecting section;

the coupling section is joined to the second connection section by a second junction and coupled to the signal output port via the second connection section,

wherein the first junction point and the second junction point are positioned at different locations of an outer circumference of the substantially annular coupling section.

6. The band reject filter of claim 5, wherein the first junction point and the second junction point are non-centrosymmetric about a center of the inner circumference of the substantially circular coupled section.

7. The band-reject filter of claim 5, wherein the transmission line is coupled between the signal input port and the signal output port sequentially through the first connection segment, the coupling segment, and the second connection segment.

8. The band reject filter of claim 3, wherein the resonant element is a first resonant element, the coupled section is a first coupled section, the band reject filter further comprising a second resonant element, the transmission line further comprising a second coupled section,

the second coupling section is configured in a substantially annular shape completely surrounding a side of the second resonator element and is configured not to be in direct contact with the housing and the second resonator element,

wherein the second coupling section and the first coupling section are positioned on a common plane.

9. The band reject filter according to claim 8, wherein the housing further comprises a partition wall extending upwardly from the bottom wall to the internal cavity to define therein substantially mutually isolated first and second cavities on opposite sides of the partition wall, respectively, wherein the first resonant element is disposed within the first cavity together with the first coupling section and the second resonant element is disposed within the second cavity together with the second coupling section.

10. The band reject filter of claim 9, wherein the first and second resonant elements are adjacent to each other, the transmission line further comprising a connecting segment configured to connect the first and second coupled segments, the connecting segment being positioned on the common plane and having a bend.

11. The band reject filter of claim 10, wherein the transmission line is coupled between the signal input port and the signal output port sequentially through the first coupling segment, the connection segment, and the second coupling segment.

12. The band reject filter according to 10, wherein the upper end of the partition wall comprises a recess to accommodate the connection segment.

13. The band reject filter of 1, wherein the transmission line is fluidly connected between the signal input port and the signal output port.

14. The band reject filter of claim 1, wherein the transmission line comprises a strip transmission line.

15. The band reject filter according to claim 1, wherein the bottom of the resonator element is fixed to the bottom wall, the top of the resonator element has an upward opening, the upper edge of the resonator element has an outward flange, and the flange has a lower surface opposite to the upper surface of the coupling section.

16. The band-stop filter of claim 15, wherein the flange overlaps the coupling section in a plan view parallel to the bottom wall.

17. A transmission line for a band-stop filter comprising a housing defining an internal cavity, a signal input port and a signal output port disposed on the housing, and a resonant element and a transmission line disposed in the internal cavity, wherein the transmission line is coupled between the signal input port and the signal output port, the transmission line comprises a coupling section configured as a substantially ring shape substantially parallel to a bottom wall of the housing and completely surrounding a side of the resonant element, and the coupling section is not in direct contact with the housing and the resonant element such that the transmission line is coupled with the resonant element through the coupling section.

18. The transmission line of claim 17, wherein the transmission line further comprises a first connection segment and a second connection segment,

the coupling section is joined with the first connecting section through a first joint and is coupled to the signal input port through the first connecting section;

the coupling section is joined to the second connection section by a second junction and coupled to the signal output port via the second connection section,

wherein the first junction point and the second junction point are positioned at different locations of an outer circumference of the substantially annular coupling section.

19. The transmission line of claim 18, wherein the transmission line is coupled between the signal input port and the signal output port sequentially through the first connection segment, the coupling segment, and the second connection segment.

20. The transmission line according to 18, wherein the first and second junctions are non-centrosymmetric about a center of the outer circumference of the substantially annular coupling section.

21. The transmission line of claim 17, wherein the resonant element is a first resonant element, the coupled segment is a first coupled segment, the band-stop filter further comprises a second resonant element, the transmission line further comprises a second coupled segment,

the second coupling section is configured in a substantially annular shape completely surrounding a side of the second resonator element and is configured not to be in direct contact with the housing and the second resonator element,

wherein the second coupling section is positioned on a common plane with the first coupling section.

22. The transmission line of claim 21, wherein the first and second resonant elements are adjacent to each other, the transmission line further comprising a connecting segment configured to connect the first and second coupling segments, the connecting segment being positioned on the common plane and having a bend.

23. The transmission line of claim 22, wherein the transmission line is coupled between the signal input port and the signal output port sequentially through the first coupling segment, the connecting segment, and the second coupling segment.

24. The transmission line of claim 17, wherein the transmission line comprises a strip transmission line.

25. The transmission line of claim 17, wherein the entirety of the transmission line is formed by a stamping process.

26. A band stop filter comprising:

a housing defining an interior cavity;

a signal input port on the housing;

a signal output port on the housing;

a resonating element located in the internal cavity; and

a transmission line positioned in the internal cavity and coupled between the signal input port and the signal output port, the transmission line including a coupling segment through which the transmission line is coupled with the resonant element,

wherein the coupling section comprises a first portion surrounding the resonator element from a first side portion of the resonator element and a second portion surrounding the resonator element from a second side portion of the resonator element opposite to the first side, a first end of the first portion and a first end of the second portion being connected by the first joint.

27. The band reject filter of 26, wherein the second end of the first portion and the second end of the second portion are connected by the second joint.

28. The band reject filter of 27, wherein the transmission line further comprises a first connection segment and a second connection segment,

the coupling section is connected to the first connection section through the first joint and is coupled to the signal input port via the first connection section; and

the coupling section is connected to the second connection section through the second joint and is coupled to the signal output port via the second connection section.

29. The band reject filter of 28, wherein the length of the first portion is different from the length of the second portion.

30. A multiplexer, comprising:

a band pass filter configured to pass signals within a first frequency band and reject signals within other frequency bands;

a band-stop filter, as in any of 1-16 and 26-29, configured to at least reject signals within the first frequency band and pass at least signals within a second frequency band and signals within the frequency band, wherein the second frequency band is lower than the first frequency band, and the first frequency band is lower than the third frequency band;

inputting a signal;

a first output coupled to the signal input via the band pass filter; and

a second output coupled to the signal input via the band-stop filter.

31. A method of self-adjusting coupling between a transmission line and a resonant element in a band stop filter, the method comprising:

at least part of the transmission line is configured to completely surround a side of the resonant element and not to be in direct contact with the resonant element, such that the transmission line is coupled with the resonant element.

32. The method of claim 31, wherein the at least part of the transmission line is substantially annular, a longitudinal axis of the at least part being substantially parallel to a longitudinal axis of the resonant element.

Although some specific embodiments of the present invention have been described in detail by way of illustration, it should be understood by those skilled in the art that the above illustration is only for the purpose of illustration and is not intended to limit the scope of the invention. The various embodiments disclosed herein may be combined in any combination without departing from the spirit and scope of the present invention. It will also be appreciated by those skilled in the art that various modifications may be made to the embodiments without departing from the scope and spirit of the invention. The scope of the invention is defined by the appended claims.