WO2015010326A1 - 一种双极化差分馈电网络、天线及基站 - Google Patents

一种双极化差分馈电网络、天线及基站 Download PDF

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Publication number
WO2015010326A1
WO2015010326A1 PCT/CN2013/080197 CN2013080197W WO2015010326A1 WO 2015010326 A1 WO2015010326 A1 WO 2015010326A1 CN 2013080197 W CN2013080197 W CN 2013080197W WO 2015010326 A1 WO2015010326 A1 WO 2015010326A1
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WIPO (PCT)
Prior art keywords
transmission line
dual
sub
differential
differential feed
Prior art date
Application number
PCT/CN2013/080197
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English (en)
French (fr)
Inventor
彭宏利
赵建平
罗伟
Original Assignee
华为技术有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
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Publication date
Application filed by 华为技术有限公司 filed Critical 华为技术有限公司
Priority to CN201380000903.3A priority Critical patent/CN103650246B/zh
Priority to PCT/CN2013/080197 priority patent/WO2015010326A1/zh
Publication of WO2015010326A1 publication Critical patent/WO2015010326A1/zh

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Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q21/00Antenna arrays or systems
    • H01Q21/24Combinations of antenna units polarised in different directions for transmitting or receiving circularly and elliptically polarised waves or waves linearly polarised in any direction
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q1/00Details of, or arrangements associated with, antennas
    • H01Q1/12Supports; Mounting means
    • H01Q1/22Supports; Mounting means by structural association with other equipment or articles
    • H01Q1/24Supports; Mounting means by structural association with other equipment or articles with receiving set
    • H01Q1/241Supports; Mounting means by structural association with other equipment or articles with receiving set used in mobile communications, e.g. GSM
    • H01Q1/246Supports; Mounting means by structural association with other equipment or articles with receiving set used in mobile communications, e.g. GSM specially adapted for base stations
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q21/00Antenna arrays or systems
    • H01Q21/0006Particular feeding systems
    • H01Q21/0075Stripline fed arrays

Definitions

  • the present invention relates to the field of communications, and in particular, to a dual-polarized differential feed network, an antenna, and a base station.
  • a dual-polarized differential feed network In mobile communication systems, the rapid development and application of base station antenna technology has strongly promoted the development of base station antennas toward miniaturization, integration, and multi-function (i.e., multi-band, multi-polarization, and multi-purpose).
  • the antenna feed network is one of the important components in the base station antenna system. Further miniaturization of the base station antenna system requires a high-performance, compact base station antenna feed network. Therefore, designing a high performance and miniaturized base station antenna feed network has become the focus of research on base station antenna technology.
  • the differential feed network is a new type of base station antenna feed network, usually composed of balun, for feeding a single-polarized dual-port antenna radiating element.
  • the dual-polarized radiating element has four ports.
  • the differential feeding network needs to provide four feeding points and two channels for the dual-polarized radiating element. Therefore, the differential feed network layout for dual-polarized radiating elements is more complex than single-polarized radiating elements.
  • the existing differential feed network layout for dual-polarized radiating elements causes structural interference between the feeder network lines and an excessive area of the feeder network, which is not conducive to miniaturization of the antenna system.
  • Embodiments of the present invention provide a dual-polarization differential feed network, an antenna, and a base station, which realize miniaturization of a dual-polarization differential feed network.
  • the technical solution adopted by the embodiment of the present invention is
  • an embodiment of the present invention provides a dual-polarized differential feed network, including: a metal ground and two sub-differential feed networks respectively connected to the metal ground; the two sub-differential feed networks are respectively located in the Two opposite surfaces of the front and back surfaces of the metal ground, and one of the two differential feed networks is used for differentially feeding a pair of port pairs of the dual polarized antenna radiating element Another sub-differential feed network of the two sub-differential feed networks is configured to differentially feed another pair of port pairs of the dual-polarized antenna radiating element.
  • each of the sub-differential feed networks includes a media board, a microstrip transmission line, and three ports, where
  • the three ports include an input port and two differential output ports, and one of the two differential output ports is configured to be connected to one of a pair of port pairs of the dual-polarized antenna radiating unit And another one of the two differential output ports is configured to be connected to another port of the port pair of the dual-polarized antenna radiating unit;
  • microstrip transmission lines are respectively connected to the three ports, and the microstrip transmission line and the three ports are located on one surface of the dielectric board, and the other surface of the dielectric board and one of the metal grounds Surface connection.
  • the dual-polarized differential feed network includes a first sub-differential feed network and a second sub-differential feed Electric network
  • a hole is disposed in the metal ground corresponding to the input port of the first sub-differential feeding network, and a metal post is disposed in the via hole, and the second sub-differential feeding corresponding to the position of the via hole is
  • the network is provided with an equivalent input port, and an input port of the first sub-differential feed network is connected to an equivalent input port of the second sub-differential network feed network side through the metal post.
  • main transmission line wherein the main transmission line is used to connect to four ports respectively;
  • At least two branch transmission lines for connecting the primary transmission line or the secondary transmission line;
  • the secondary transmission line being used for connection between the branch transmission lines;
  • the main transmission line includes a first main transmission line, a second main transmission line, a third main transmission line, and a fourth main transmission line, and the first main transmission line and the second main transmission line are respectively connected to the two differential output ports.
  • the third main transmission line and the fourth main transmission line are respectively connected to the input port and the load absorption port, and the first main transmission line and the second main transmission line combine to have a 90-degree phase shifting function for the transmission signal;
  • the sub-differential feeding network includes three branch transmission lines, and the three branch transmission lines include: a first branch transmission line connected to the third main transmission line and the fourth main transmission line, and the a second branch transmission line connected to the sub transmission line, and a third branch transmission line connected to the first main transmission line and the second main transmission line;
  • the electrical lengths of the first branch transmission line, the second branch transmission line, and the third branch transmission line are equal, and are one quarter of a wavelength of the transmission signal.
  • the impedance of the first branch transmission line is greater than or equal to the impedance of the second branch transmission line;
  • the impedance of the first branch transmission line is greater than or equal to the impedance of the third branch transmission line.
  • the impedance of the second branch transmission line is equal to the impedance of the third branch transmission line.
  • the sub-transmission line includes:
  • a first secondary transmission line for connecting the first primary transmission line, the third branch transmission line, and the second branch transmission line;
  • a second secondary transmission line for connecting the second primary transmission line, the third branch transmission line, and the second branch transmission line;
  • a third secondary transmission line for connecting the third primary transmission line, the first branch transmission line, and the second branch transmission line;
  • a fourth secondary transmission line for connecting the fourth primary transmission line, the first branch transmission line, and the second branch transmission line;
  • the first sub-transmission line, the second sub-transmission line, the third sub-transmission line, and the fourth sub-transmission line have equal electrical lengths and are one quarter of a wavelength of the transmission signal.
  • the impedance of the first main transmission line and the second main transmission line is greater than the third The impedances of the main transmission line and the fourth main transmission line; and the impedances of the first main transmission line and the second main transmission line are smaller than the impedance of each of the branch transmission lines.
  • the dielectric plate has a dielectric constant of 2-4.
  • the first primary transmission line and the second primary transmission line are further used for The two differential output ports perform impedance matching.
  • an embodiment of the present invention provides an antenna, including: a dual-polarized antenna radiating unit, configured to radiate space or receive electromagnetic waves from a space; and any one of the above dual-polarized differential feed networks for The dual-polarized antenna radiating element performs differential feeding.
  • an embodiment of the present invention provides a base station, including any one of the above dual-polarization differential feed networks or the antenna.
  • Embodiments of the present invention provide a dual-polarization differential feed network, which is differentially fed to a dual-polarized antenna radiating element by placing two sub-differential feeding networks on opposite surfaces of the metal to achieve dual-polarized difference.
  • the feeder network is miniaturized.
  • the two differential feed networks are placed in a plane to perform the four-port feeding on the dual-polarized radiating elements, and the solution of the embodiment of the present invention can effectively solve the two feeding network lines of the prior art. Structural interference occurs and the area of the feed network is too large, which facilitates miniaturization of the antenna system.
  • FIG. 1 is a schematic diagram of a dual-polarization differential feed network according to an embodiment of the present invention
  • FIG. 2 is a schematic diagram of a dual-polarization differential feed network feed system according to an embodiment of the present invention
  • FIG. 4 is a schematic structural diagram of a dual-polarization differential feed network according to an embodiment of the present invention
  • FIG. 5 is a schematic structural diagram of another dual-polarization differential feed network according to an embodiment of the present invention
  • FIG. 6 is a structural diagram of an apparatus for an antenna according to an embodiment of the present invention.
  • GSM Global System of Mobile communication
  • CDMA Code Division Multiple Access
  • Wideband Code Division Multiple Access referred to as Wideband Code Division Multiple Access
  • WCDMA Wideband Code Division Duplex
  • GPRS General Packet Radio Service
  • LTE Long Term Evolution
  • FDD Frequency Division Duplex
  • TDD Time Division Duplex
  • Universal Mobile Telecommunication System Universal Mobile Telecommunication System
  • UMTS Global Interoperability for Microwave Access
  • WiMAX Global Interoperability for Microwave Access
  • FIG. 1 is a schematic diagram of a dual-polarization differential feed network 100 according to an embodiment of the present invention.
  • the dual-polarized differential feed network 100 includes: a metal ground 10 and two sub-differential feed networks 20, 30 respectively connected to the metal ground 10; the two sub-differential feed networks 20, 30 are respectively located on opposite sides of the front and back sides of the metal ground 10, and one of the two differential feed networks 20 is used to transmit a pair of ports of the dual-polarized antenna radiating unit
  • another sub-differential feeding network 30 of the two sub-differential feeding networks is used to differentially feed another pair of port pairs of the dual-polarized antenna radiating element.
  • the two sub-differential feeds 20, 30 in the embodiment of the present invention may be any differential feed network capable of implementing differential feed, for example, a broadband balun, or by a bridge and a phase shifter.
  • the constituent network of the present invention is not limited in this embodiment of the present invention.
  • the structure of the two sub-differential feed networks 20, 30 in the embodiment of the present invention is symmetrical, and the consistency of the two polarization channels generated by the two sub-differential feed networks 20, 30 can be ensured.
  • the structural symmetry of the two sub-differential feed networks 20, 30 means that the two sub-differential feed networks 20, 30 belong to the same type of differential feed network, and it is not necessary to require the structure of the two sub-differential feed networks 20, 30 to be identical, for example
  • the two sub-differential feeding networks 20 and 30 are all feeder networks composed of broadband baluns.
  • the metal floor 10 may be a thicker metal plate or a metal layer having a smaller thickness.
  • the metal floor 10 has a thickness of 2-3 mm.
  • the two sub-differential feed networks are referred to as a first sub-differential feed network 20 and a second sub-differential feed network 30, preferably, when multiple first sub-differential feed networks are used.
  • the plurality of first sub-differential feeding networks 20 and the second sub-differential feeding networks 30 distributed by the array may share one metal ground 10, that is, a plurality of first The sub-differential feed network 20 and the plurality of second sub-differential feed networks 30 are respectively arrayed on two opposite surfaces of the front side and the back side of a metal ground 10.
  • the embodiment of the present invention uses a sub-differential feeding network as an example to describe the feeding principle of the dual-polarized differential feeding network 100.
  • the sub-differential feed network includes a dielectric board, a microstrip transmission line, and three ports, wherein the three ports include one input port and two differential output ports, and one of the two differential output ports is used for One of a pair of port pairs of the dual-polarized antenna radiating unit is connected, and the other of the two differential output ports is for the port pair of the dual-polarized antenna radiating unit Another port is connected; the microstrip transmission lines are respectively connected to the three ports, and the microstrip transmission line and the three ports are located on one surface of the dielectric board, and the other surface of the dielectric board is connected to one surface of the metal ground. Referring to FIG.
  • a sub-differential feed network 20 includes a dielectric board 201, a microstrip transmission line 202, and a port A1, a port A2, and a port A3.
  • the port A1 is an input port
  • the port A2 and the port A3 are differential output ports
  • the open band transmission line 202 is respectively Port A1, port A2, and port A3 are connected
  • the microstrip transmission line 202 and the port A1, port A2, and port A3 are both located on the media board 201.
  • the second sub-differential feed network 30 includes a dielectric board 301, an open-band transmission line 302, and a port B1, a port B2, and a port B3.
  • the port B1 is an input port
  • the port B2 and the port B3 are differential output ports
  • the start-band transmission line 302 is respectively
  • the port B1, the port B2, and the port B3 are connected
  • the transmission line 302 and the port B1, the port B2, and the port B3 are located on one surface of the dielectric board 301, and the other surface of the dielectric board 301 is connected to the surface of the metal ground 10.
  • the antenna radiating unit includes four feeding ports: port PA2, port PA3, port PB2, and port PB3, and constitutes two sets of port pairs, each of which is used to connect with two output ports of one sub-differential feeding network.
  • Port PA2 and port PA3 are a group of port pairs
  • port PB2 and port PB3 are a group of port pairs.
  • the port A2 is electrically connected to the port PA2 of the antenna radiating unit through the transmission line 401
  • the port A3 is electrically connected to the port PA3 of the antenna radiating unit through the transmission line 402
  • the port B2 is electrically connected to the port PB2 of the antenna radiating unit through the transmission line 403
  • the port B3 is passed through the transmission line 404.
  • the first sub-differential feed network 20 and the second sub-differential feed network 30 simultaneously feed the four ports PA2, PA3, PB2, PB3 of the antenna radiating element through the transmission lines 401, 402, 403 and 404, respectively.
  • the differential excitation feeds of the first sub-differential feed network 20 and the second sub-differential feed network 30 respectively correspond to two orthogonal polarization channels.
  • the differential excitation feeds of the first sub-differential feed network 20 respectively correspond to + The 45 degree antenna polarization state
  • the differential excitation feed of the second sub-differential feed network 30 corresponds to the -45 degree antenna polarization state.
  • the feeding process of the first sub-differential feed network 20 and the second sub-differential feed network 30 will be separately described below.
  • the excitation signal AS entering the port A1 (+45 degree polarization port), the power distribution and phase shift of the first sub-differential feed network 20, and two equal-amplitude inverted signals AS2 and AS3 are output at the port A2 and the port A3, AS2 and AS3 are transmitted to the PA2 and PA3 port pairs of the antenna radiating unit through transmission lines 401 and 402.
  • the first sub-differential feeding network 20 implements a +45 degree polarization feeding of the excitation signal AS.
  • the port B1 is entered.
  • the excitation signal BS of the 45-degree polarization port through the power distribution and phase shift of the second sub-differential feed network 30, outputs two equal-amplitude inverted signals BS2 and BS3, BS2 and BS3 through port B2 and port B3.
  • Transmission lines 403 and 404 are transmitted to the PB2 and PB3 port pairs of the antenna radiating element, and the second sub-differential feeding network 30 effects a -45 degree polarization feeding of the excitation signal BS.
  • the dual-polarized differential feed network 100 implements feeding of dual-polarized channels of the antenna radiating elements.
  • the dual-polarization differential feed network 100 provided by the embodiment of the present invention differentially feeds a pair of ports of the dual-polarized antenna radiating unit through two sub-differential feeding networks 20 and 30 respectively located on the front and back sides of the metal ground 10 respectively.
  • the feeding of the dual-polarized antenna radiating unit is realized, and the miniaturization of the antenna system is realized.
  • sub-differential feed network further includes a load absorption port
  • the microstrip transmission line includes:
  • Main transmission line for connecting to four ports respectively
  • At least two branch transmission lines for connecting the primary transmission line or the secondary transmission line;
  • the main transmission line includes a first main transmission line, a second main transmission line, a third main transmission line, and a fourth main transmission line, and the first main transmission line and the second main transmission line respectively and two a differential output port connection, a third main transmission line and a fourth main transmission line are respectively connected to the input port and the load absorption port, and the first main transmission line and the second main transmission line have a 90-degree phase shifting function for transmitting signals; and the sub-differential feeding network and After a pair of port pairs of the dual-polarized antenna radiating unit are electrically connected, the main transmission line, the branch transmission line, and the sub-transmission line constitute an equivalent balun to differentiate the pair of port pairs of the dual-polarized antenna radiating unit through the two differential output ports. Feeding.
  • FIG. 3 is a schematic structural diagram of a sub-differential feeding network according to an embodiment of the present invention. Because the first sub-differential feeding network 20 and the second sub-differential feeding network 30 are symmetric in structure, the embodiment of the present invention is only applicable to The structure of the first sub-differential feed network 20 will be described. As shown in FIG. 3, the first sub-differential feed network 20 includes: four ports A1, A2, A3, A4, main transmission lines 11, 12, 13, 14, three branch transmission lines 31, 32, 33 and a sub-transmission line 41. , 42, 43, 44.
  • Port A1 is an input port for connection with an excitation source
  • ports A2 and A3 are differential output ports for connection with an antenna radiating unit
  • port A4 is a load absorption port for matching loads.
  • the input impedance of the four ports Al, A2, A3, A4 can be matched to the impedance of the external device, for example to match the impedance of the excitation source, and to match the impedance of the antenna radiating element.
  • the input impedance of the four ports Al, A2, A3, A4 is 50 ohms.
  • the embodiment of the present invention is described by taking only the input impedances of the four ports A1, A2, A3, and A4 as 50 ohms as an example, but the present invention is not limited thereto, and the four ports Al, A2, A3, and A4 are
  • the input impedance can also be other values to match the impedance of the connected external device.
  • the main transmission line 1 1 , 12 , 13 , 14 may include a first main transmission line 1 1 , a second main transmission line 12 , a third main transmission line 13 , and a fourth main transmission line 14 , wherein the first main transmission line 1 1 and the second main transmission line 12 is connected to port A2 and port A3, respectively, and the first main transmission line 11 and the second main transmission line 12 are combined to have a 90-degree phase shifting function, so that the sub-differential feeding network 20 can be electrically connected to the antenna radiating unit, and the sub-differential
  • the feed network 20 constitutes an equivalent balun to differentially feed the antenna radiating element through the port A2 and the port A3 of the sub-differential feeding network 20; the third main transmission line 13 and the fourth main transmission line 14 respectively and the port A1 Connect to port A4.
  • branch transmission lines for respectively connecting the third main transmission line 13 and the fourth main transmission line 14, the first main transmission line 1 1 and the second main transmission line 12, and preferably one or more connections may be added to the sub transmission line.
  • the branch transmission line between the two embodiments is described as an example of adding a branch transmission line connected between the sub-transmission lines.
  • the embodiment of the present invention does not impose any limitation.
  • the three branch transmission lines 31, 32, and 33 may be included, and specifically include: a first branch transmission line 31 connected to the third main transmission line 13 and the fourth main transmission line 14; the second branch transmission line 32 The second branch transmission line 32 is connected to the sub-transmission lines 41, 42, 43, 44; and a third branch transmission line 33 is connected to the first main transmission line 11 and the second main transmission line 12.
  • the sub-transmission lines 41, 42, 43, 44 may include:
  • the first main transmission line 11 may include a first main transmission line unit 1 1 , the first main transmission line unit 11 may be connected to the port A2, and respectively connected to the third branch transmission line 33 And the first sub-transmission line 41 is connected;
  • the second main transmission line 12 may include a second main transmission line unit 12, and the second main transmission line unit 12 may be connected to the port A3 and connected to the third sub-transmission line 33 and the second sub-transmission line 42;
  • the third main transmission line 13 may include a
  • a fourth master unit 14 may include a transmission line 14, the fourth main unit of the fourth transmission line 14 may be a main transmission line and the unit
  • the port A4 is connected and connected to the first branch transmission line 31 and the first sub-transmission line 41, and the fourth main transmission line unit 14 is a matching absorption path.
  • the first secondary transmission line 41 may be connected to the first primary transmission line unit 11, the second branch transmission line 32, the third branch transmission line 33, and the third secondary transmission line 43, and the second secondary transmission line 42 may be second The main transmission line unit 12, the second branch transmission line 32, the third branch transmission line 33, and the fourth sub transmission line 44 are connected; the third sub transmission line 43 may be connected to the third main transmission line unit 13, the first branch transmission line 31, the second branch transmission line 32, and The first sub-transmission line 41 is connected; the fourth sub-transmission line 44 may be connected to the fourth main transmission line unit 14, the first sub-transmission line 31, the second sub-transmission line 32, and the second sub-transmission line 42.
  • the first main transmission line 11 and the second main transmission line 12 are also used for impedance matching of the port A2 and the port A3, for example, impedance matching of 50 ohms.
  • the third main transmission line 13 and the fourth main transmission line 14 may also be used for impedance matching between the port A1 and the port A4, depending on the load connected to the sub-differential feeding network 20, For example, 50 ohm impedance matching is performed, but the embodiment of the present invention is not limited thereto.
  • the first main transmission line 11 and the second main transmission line 12 included in the main transmission line may be used to generate a 90-degree phase shift on the transmission signal, and perform impedance matching on the differential port, for example, to perform 50 ohm impedance. match.
  • the electrical lengths of the first main transmission line unit 11 and the second main transmission line unit 12 are higher than the electric power of the third main transmission line unit 13 and the fourth main transmission line unit 13. The length is short, and the difference between the electrical lengths of the first main transmission line unit 11 and the second main transmission line unit 12 and the electrical lengths of the third main transmission line unit 13 and the fourth main transmission line unit 14 is the wavelength of the transmission signal.
  • the electrical length of the transmission line is measured by the wavelength of the electrical signal transmitted by the transmission line.
  • the electrical length of a transmission line refers to the physical length of the transmission line.
  • the ratio of the wavelength ⁇ of the electrical signal transmitted on the transmission line may be approximated as the wavelength of the transmission signal.
  • a quarter, for example, the difference is 0.22 ⁇ , 0.24 ⁇ , 0.26 ⁇ or 0.28 ⁇ , etc., where ⁇ is the wavelength of the transmission signal, for example, the frequency of the transmission signal is in the range of 1.71 GHz to 2.17 GHz.
  • the branch transmission line and the secondary transmission line can be used to generate a coupled branch transmission path to control the amplitude and phase of the transmission signal, specifically, by superimposing signals of the plurality of coupled branch paths, so that port A1 is isolated from port A4 and is made to pass through the differential port.
  • the transmission signal reproduces a phase difference of 90 degrees, that is, the transmission signal output through the port A3 is delayed by 90 degrees from the transmission signal output through the port A2, so that the antenna radiation unit is differentially fed through the differential ports A2 and A3.
  • the electrical lengths of the first branch transmission line 31, the second branch transmission line 32, and the third branch transmission line 33 may be approximately one quarter of the wavelength of the transmission signal.
  • the electrical length of each branch transmission line is Between 0.2 ⁇ and 0.3 ⁇ , where ⁇ is the wavelength of the transmission signal; for example, the electrical length of each branch transmission line is 0.14 ⁇ , 0.24 ⁇ , 0.26 ⁇ or 0.28 ⁇ , and the like.
  • the first branch transmission line 31, the second branch transmission line 32, and the third branch transmission line 33 have equal electrical lengths and are one quarter of a wavelength of the transmission signal.
  • the first sub-transmission line 41, the second sub-transmission line 42, the third sub-transmission line 43, and the fourth sub-transmission line 44 have the same electrical length, and are wavelengths of the transmission signal. One quarter of the. It should be understood that the electrical length of each sub-transmission line can also be approximately one quarter of the wavelength of the transmission signal.
  • the electrical length of each sub-transmission line is between 0.2 ⁇ and 0.3 ⁇ , where ⁇ is the wavelength of the transmission signal;
  • the electrical length of each of the sub-transmission lines is 0.14 ⁇ , 0.24 ⁇ , 0.26 ⁇ or 0.28 ⁇ , etc., but the embodiment of the present invention is not limited thereto.
  • the impedance of the first branch transmission line 31 is greater than or equal to the impedance of the second branch transmission line 32; and the impedance of the first branch transmission line 31 is greater than or equal to the impedance of the third branch transmission line 33.
  • the impedance of the second branch transmission line 32 is similar to the impedance of the third branch transmission line 33.
  • the impedance of the second branch transmission line 32 is equal to the impedance of the third branch transmission line 33.
  • the first main transmission line 1 1 and the second main transmission line 12 The impedance of the first main transmission line 11 and the second main transmission line 14 is greater than the impedance of each of the sub-transmission lines.
  • the sub-differential feeding network 20 of the embodiment of the present invention after being electrically connected to the antenna radiating unit, the main transmission line, the three branch transmission lines, and the sub-transmission line included in the sub-differential feeding network 20 constitute an equivalent balun, thereby enabling sub-difference
  • the two differential output ports of the feed network 20 differentially feed the antenna radiating elements, thereby avoiding the use of impedance devices, reducing energy losses, and improving the performance of the sub-differential feed network 20.
  • the sub-differential feed network 20 can not only maintain the transmission signal inversion through the differential port over a wide bandwidth, but also maintain the amplitude of the transmission signal through the differential port over a wide bandwidth, and has a low reflection coefficient. , small size and low loss.
  • the dual-polarized differential feed network 100 includes: a metal ground 10; an upper surface and a lower surface of the metal ground 10 are closely connected to one surface of the dielectric plates 201 and 301, and the other surfaces of the dielectric plate 201 and the dielectric plate 301 are respectively disposed
  • a plurality of microstrip lines, the dielectric plate 201 and the microstrip lines thereon constitute a first sub-differential feed network 20, and the dielectric plate 301 and the microstrip lines thereon constitute a second sub-differential feed network 30.
  • the metal ground 10 has a thickness of 1.5 mm, the dielectric plates 201 and 301 have a thickness of 0.8 mm, and the dielectric plates 201 and 301 have dielectric constants of 2.55 and 2.6, respectively. It should be understood that the embodiment of the present invention is only described by taking the above specific numerical value as an example, but the present invention is not limited thereto. In a specific implementation, the transmission line group structure, impedance, and length of the differential feed network according to the embodiment of the present invention may be Optimized according to needs.
  • the first sub-differential feed network 20 includes four ports Al, A2, A3, and A4, wherein port A1 is an input port, ports A2 and A3 are differential output ports, and port A4 is a load sink port.
  • the second sub-differential feed network 30 includes four ports Bl, B2, B3, and B4, wherein port B 1 is an input port, ports B2 and B3 are differential output ports, and port B4 is a load sink port.
  • Port A2 and port A3 form a +45 degree polarization differential port pair
  • port B2 and port B3 form a -45 degree polarization differential port pair.
  • the dual-polarized channel feed is realized by feeding the four ports of the antenna radiating unit simultaneously through the transmission line.
  • the dual-polarized differential feed network 100 provided by the embodiment of the present invention is respectively located in the metal ground 10 opposite two surface sub-differential feeding networks 20, 30 respectively differentially feed a pair of ports of the dual-polarized antenna radiating unit to realize feeding of the dual-polarized antenna radiating unit, and realize the antenna system miniaturization.
  • FIG. 5 it is a specific configuration of another dual-polarization differential feed network 100 according to an embodiment of the present invention.
  • the dual-polarized differential feed network 100 includes: a metal ground 10; the front and back sides of the metal ground 10 are closely connected to one surface of the dielectric plates 201 and 301, and the other surfaces of the dielectric plate 201 and the dielectric plate 301 are respectively provided with a plurality of strips
  • the microstrip line, the dielectric plate 201 and the microstrip lines thereon constitute a first sub-differential feed network 20, and the dielectric plate 301 and the microstrip lines thereon constitute a second sub-differential feed network 30.
  • the first sub-differential feed network 20 includes four ports A1, A2, A3, and A4, wherein port A1 is an input port, ports A2 and A3 are differential output ports, and port A4 is a load sink port.
  • the second sub-differential feed network 30 includes four ports B1, B2, B3, and B4, wherein port B1 is an input port, ports B2 and B3 are differential output ports, and port B4 is a load sink port. Port A2 and port A3 form a +45 degree polarization differential port pair, and port B2 and port B3 form a -45 degree polarization differential port pair.
  • the dual-polarized channel feed is realized by feeding the four ports of the antenna radiating unit simultaneously through the transmission line.
  • the metal ground 10 corresponding to the input port A1 of the first sub-differential feed network 20 is provided with a via 50, and the via 50 is provided with a metal post 60, and the second differential feed network 30 corresponding to the position of the via 50
  • the dielectric board 301 is provided with an equivalent input port A1, and the input port A1 of the first sub-differential feed network 20 is connected to the equivalent input port A1 of the second differential mesh feed network 30 side via the metal post 60.
  • the metal post 60 in the via 50 is insulatively connected to the metal ground 10.
  • the metal post 60 and the metal ground 10 may be connected by air insulation, which is not limited in the embodiment of the present invention.
  • the dual-polarization differential feed network 100 provided by the embodiment of the present invention performs differential feed to a pair of ports of the dual-polarized antenna radiating unit through the sub-differential feeding networks 20 and 30 respectively located on opposite surfaces of the metal ground 10 respectively. Electricity, the feeding of the dual-polarized antenna radiating unit is realized, and the miniaturization of the antenna system is realized.
  • the input ports of the first sub-differential feed network 20 and the second sub-differential feed network 30 can be placed on one plane by the arrangement of the via holes, so that the power distribution of the +45 polarization channel and the -45 degree polarization channel
  • the electrical network is coplanarly arranged to facilitate the layout of the antenna feed network.
  • an embodiment of the present invention provides an antenna 60, which is shown in FIG. 6, and includes: a dual-polarized antenna radiating unit 600 for radiating or receiving electromagnetic waves into space; the dual-polarization described in any of the above embodiments.
  • the differential feed network 100 is configured to differentially feed the dual-polarized antenna radiating unit 600.
  • the dual-polarization differential feed network 100 separately differentially feeds a pair of ports of the dual-polarized antenna radiating unit 600 through sub-differential feeding networks respectively located on opposite surfaces of the metal ground. The feeding of the dual-polarized antenna radiating unit 600 is realized, and the miniaturization of the antenna system is realized.
  • an embodiment of the present invention provides a base station, including the dual-polarized differential feed network 100 of any one of the embodiments described above, or the antenna 60 of any of the embodiments.
  • the base station provided by the embodiment of the present invention separately differentially feeds a pair of ports of the dual-polarized antenna radiating unit through the sub-differential feeding networks respectively located on opposite surfaces of the metal ground to realize the radiating unit of the dual-polarized antenna.
  • the power is fed, and the antenna system is miniaturized.
  • the disclosed system and apparatus may be implemented in other manners.
  • the device embodiments described above are merely illustrative.
  • the division of the unit is only a logical function division.
  • the mutual coupling or direct coupling or communication connection shown or discussed may be an indirect coupling or communication connection through some interface, device or unit, or an electrical, mechanical or other form of connection.
  • the units described as separate components may or may not be physically separated, and the components displayed as units may or may not be physical units, that is, may be located in one place, or may be distributed to multiple network units. Some or all of the units may be selected according to actual needs to achieve the objectives of the embodiments of the present invention.
  • each functional unit in each embodiment of the present invention may be integrated into one processing unit, or each unit may exist physically separately, or two or more units may be integrated into one unit.
  • the above integrated unit can be implemented in the form of hardware or in the form of a software functional unit.
  • the integrated unit if implemented in the form of a software functional unit and sold or used as a standalone product, may be stored in a computer readable storage medium.
  • the technical solution of the present invention is essential or part of the contribution to the prior art, or all or part of the technical solution may be embodied in the form of a software product, which is stored in a storage medium, including The instructions are used to cause a computer device (which may be a personal computer, server, or network device, etc.) to perform all or part of the steps of the methods described in various embodiments of the present invention.
  • the foregoing storage medium includes: a U disk, a removable hard disk, a read-only memory (ROM), a random access memory (RAM), a magnetic disk or an optical disk, and the like, which can store program codes. .

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Abstract

本发明实施例公开了一种双极化差分馈电网络及天线,涉及通信领域,通过将两个子差分馈电网络分别置于金属地相对的两个表面,向双极化天线辐射单元差分馈电,实现双极化差分馈电网络小型化。本发明实施例提供的双极化差分馈电网络,包括:金属地以及分别与所述金属地连接的两个子差分馈电网络;所述两个子差分馈电网络分别位于所述金属地的正面和反面两个表面,且所述两个差分馈电网络中的一个子差分馈电网络用于向双极化天线辐射单元的的一对端口对进行差分馈电,所述两个子差分馈电网络中的另一个子差分馈电网络用于向所述双极化天线辐射单元的另一对端口对进行差分馈电。

Description

一种双极化差分馈电网络、 天线及基站
技术领域
本发明涉及通信领域, 尤其涉及一种双极化差分馈电网络、 天线及基 站。 背景技术 在移动通信系统中,基站天线技术的迅速发展和应用有力地推动了基 站天线向小型化、 集成化和多功能(即多频段、 多极化和多用途) 的方向 发展。 天线的馈电网络是基站天线系统中的重要部件之一, 基站天线系统 进一步小型化需要高性能、 小型化的基站天线馈电网络。 因而, 设计高性 能、 小型化的基站天线馈电网络己成为基站天线技术的研究重点。 差分馈电网络是一种新型的基站天线馈电网络, 一般用巴伦组成, 用 于对单极化的双端口天线辐射单元进行馈电。 而双极化辐射单元有四个端口, 对双极化辐射单元馈电时, 差分馈电 网络需要为双极化辐射单元提供四个馈电点和双通道。 因此, 针对双极化 辐射单元的差分馈电网络布局方式相比于单极化辐射单元更为复杂。 目前 已有的、 针对双极化辐射单元的差分馈电网络布局方式, 会导致馈电网络 线路之间发生结构干涉和馈电网络面积过大, 不利于天线系统小型化。 发明内容 本发明的实施例提供一种双极化差分馈电网络、 天线及基站, 实现双 极化差分馈电网络小型化。 为达到上述目的, 本发明实施例釆用的技术方案是,
一方面, 本发明实施例提供一种双极化差分馈电网络, 包括: 金属地 以及分别与所述金属地连接的两个子差分馈电网络;所述两个子差分馈电 网络分别位于所述金属地的正面和反面两个表面两个相对的表面, 且所述 两个差分馈电网络中的一个子差分馈电网络用于向双极化天线辐射单元的 一对端口对进行差分馈电, 所述两个子差分馈电网络中的另一个子差分馈 电网络用于向所述双极化天线辐射单元的另一对端口对进行差分馈电。 结合第一方面, 在第一方面的第一种可能实现的方式中, 所述每个子 差分馈电网络包括介质板、 微带传输线以及三个端口, 其中,
所述三个端口包括一个输入端口和两个差分输出端口, 所述两个差分 输出端口中的一个差分输出端口用于与所述双极化天线辐射单元的一对端 口对中的一个端口连接, 所述两个差分输出端口中的另一个差分输出端口 用于与所述双极化天线辐射单元的所述端口对的另一个端口连接;
所述微带传输线分别与所述三个端口连接, 且所述微带传输线和三个 端口都位于所述介质板的一个表面上, 所述介质板的另一个表面与所述金 属地的一个表面连接。
结合第一方面的第一种可能的实现方式,在第一方面的第二种可能实 现的方式中, 所述双极化差分馈电网络包括第一子差分馈电网络和第二子 差分馈电网络,
所述第一子差分馈电网络的输入端口对应位置的所述金属地设置有 过孔, 所述过孔内设置有金属柱, 与所述过孔位置对应的所述第二子差分 馈电网络设置有等效输入端口, 所述第一子差分馈电网络的输入端口通过 所述金属柱与所述第二子差分网馈电网络侧的等效输入端口连接。
结合第一方面的第一或第二种可能的实现方式,在第一方面的第三种 可能实现的方式中, 所述每个子差分馈电网络还包括一个加载吸收端口; 所述微带传输线包括:
主传输线, 所述主传输线用于分别与四个端口连接;
至少两个分支传输线, 所述分支传输线用于连接所述主传输线或副传 输线;
副传输线, 所述副传输线用于所述分支传输线之间的连接;
其中, 所述主传输线包括第一主传输线、 第二主传输线、 第三主传输 线和第四主传输线, 所述第一主传输线和所述第二主传输线分别与所述两 个差分输出端口连接, 所述第三主传输线和所述第四主传输线分别与所述 输入端口和所述加载吸收端口连接, 所述第一主传输线和第二主传输线结 合对于传输信号具有 90度移相功能;在所述子差分馈电网络与所述双极化 天线辐射单元的一对端口对电气连接后, 所述主传输线、 所述至少两个分 支传输线、 所述副传输线构成等效巴伦, 以通过所述两个差分输出端口对 所述双极化天线辐射单元的一对端口对进行差分馈电。
结合第一方面的第三种可能的实现方式,在第一方面的第四种可能实 现的方式中, 所述子差分馈电网络包括三个分支传输线, 所述三个分支传 输线包括: 与所述第三主传输线和所述第四主传输线连接的第一分支传输 线、 与所述副传输线连接的第二分支传输线、 以及与所述第一主传输线和 所述第二主传输线连接的第三分支传输线;
其中, 所述第一分支传输线、 所述第二分支传输线和所述第三分支传 输线的电长度相等, 且为所述传输信号的波长的四分之一。
结合第一方面的第四种可能的实现方式,在第一方面的第五种可能实 现的方式中, 所述第一分支传输线的阻抗大于或等于所述第二分支传输线 的阻抗; 且所述第一分支传输线的阻抗大于或等于所述第三分支传输线的 阻抗。 结合第一方面的第四或第五种可能的实现方式,在第一方面的第六种 可能实现的方式中, 所述第二分支传输线的阻抗等于所述第三分支传输线 的阻抗。
结合第一方面的第四至第六任一项可能的实现方式,在第一方面的第 七种可能实现的方式中, 所述副传输线包括:
用于连接所述第一主传输线、 所述第三分支传输线和所述第二分支传 输线的第一副传输线; 或
用于连接所述第二主传输线、 所述第三分支传输线和所述第二分支传 输线的第二副传输线; 或
用于连接所述第三主传输线、 所述第一分支传输线和所述第二分支传 输线的第三副传输线; 或
用于连接所述第四主传输线、 所述第一分支传输线和所述第二分支传 输线的第四副传输线;
其中, 所述第一副传输线、 所述第二副传输线、 所述第三副传输线和 所述第四副传输线的电长度相等, 且为所述传输信号的波长的四分之一。
结合第一方面的第四至第七任一种可能的实现方式,在第一方面的第 八种可能实现的方式中, 所述第一主传输线和第二主传输线的阻抗大于所 述第三主传输线和第四主传输线的阻抗; 并且所述第一主传输线和第二主 传输线的阻抗小于所述每个分支传输线的阻抗。 结合第一方面的第一至第八任一种可能的实现方式,在第一方面的第 九种可能实现的方式中, 所述介质板的介电常数为 2-4。 结合第一方面的第三至第九任一项可能的实现方式,在第一方面的第 十种可能实现的方式中, 所述输入端口、 所述差分输出端口和所述加载吸 收端口的输入阻抗都为 50欧姆。
结合第一方面的第三至第十任一种可能的实现方式,在第一方面的第 十一种可能实现的方式中, 所述第一主传输线和所述第二主传输线还用于 对所述两个差分输出端口进行阻抗匹配。
第二方面, 本发明实施例提供一种天线, 包括: 双极化天线辐射单元, 用于向空间辐射或从空间接收电磁波; 和 上述任一项双极化差分馈电网络,用于对所述双极化天线辐射单元进 行差分馈电。
第三方面, 本发明实施例提供一种基站, 包括上述任一项双极化差分 馈电网络或者上述天线。 本发明的实施例提供了双极化差分馈电网络,通过将两个子差分馈电 网络分别置于金属地相对的两个表面, 向双极化天线辐射单元差分馈电, 实现双极化差分馈电网络小型化。相对于现有技术将两个差分馈电网络放 置在一个平面内对双极化辐射单元进行四端口馈电的方案,本发明实施例 的方案可以有效解决现有技术方案两个馈电网络线路之间发生结构干涉 和馈电网络面积过大的问题, 从而有利于天线系统小型化。
附图说明 为了更清楚地说明本发明实施例或现有技术中的技术方案,下面将对 实施例或现有技术描述中所需要使用的附图作简单地介绍, 显而易见地, 下面描述中的附图仅仅是本发明的一些实施例,对于本领域普通技术人员 来讲, 在不付出创造性劳动的前提下, 还可以根据这些附图获得其他的附 图。
图 1为本发明实施例提供的一种双极化差分馈电网络原理图; 图 2为本发明实施例提供的一种双极化差分馈电网络馈电原理图; 图 3为本发明实施例提供的一种子差分馈电网络的结构示意图; 图 4为本发明实施例提供的一种双极化差分馈电网络的结构示意图; 图 5为本发明实施例提供另一种双极化差分馈电网络的结构示意图; 图 6为本发明实施例提供的一种天线的装置结构图。
具体实施方式 下面将结合本发明实施例中的附图,对本发明实施例中的技术方案进 行清楚、完整地描述,显然,所描述的实施例仅仅是本发明一部分实施例, 而不是全部的实施例。 基于本发明中的实施例, 本领域普通技术人员在没 有做出创造性劳动前提下所获得的所有其他实施例,都属于本发明保护的 范围。
应理解, 本发明实施例的技术方案可以应用于各种通信系统, 例如: 全球移动通讯 ( Global System of Mobile communication, 简称为 " GSM" ) 系统、 码分多址 ( Code Division Multiple Access , 简称为 " CDMA" ) 系 统、 宽带码分多址 ( Wideband Code Division Multiple Access , 简称为
"WCDMA" ) 系统、 通用分组无线业务 ( General Packet Radio Service , 简称为 " GPRS" ) 、 长期演进 ( Long Term Evolution, 简称为 "LTE" ) 系统、 LTE频分双工 ( Frequency Division Duplex , 简称为 "FDD" ) 系 统、 LTE时分双工 (Time Division Duplex , 简称为 "TDD" ) 、 通用移 动通信系统 ( Universal Mobile Telecommunication System , 简称为
" UMTS " ) 或全球互联 ί波接入 ( Worldwide Interoperability for Microwave Access , 简称为 "WiMAX" ) 通信系统等。
参见图 1 , 为本发明实施例提供的一种双极化差分馈电网络 100的原 理性示意图。 如图 1 所示, 该双极化差分馈电网络 100 包括: 金属地 10 以及分别与所述金属地 10连接的两个子差分馈电网络 20、 30; 所述两个 子差分馈电网络 20、 30分别位于所述金属地 10的正面和反面两个相对的 表面,且所述两个差分馈电网络中的一个子差分馈电网络 20用于向双极化 天线辐射单元的的一对端口对进行差分馈电, 所述两个子差分馈电网络中 的另一个子差分馈电网络 30 用于向所述双极化天线辐射单元的另一对端 口对进行差分馈电。 示例性的, 本发明实施例中的两个子差分馈电 20、 30可以是任意的 能够实现差分馈电的差分馈电网络, 例如, 宽带巴伦, 或由电桥和移相器 组成的馈电网络, 本发明实施例对此不进行限制。 优选的, 本发明实施例中两个子差分馈电网络 20、 30的结构是对称 的, 能够保证两个子差分馈电网络 20、 30产生的两个极化通道的一致性, 需要说明的是, 两个子差分馈电网络 20、 30的结构对称指的是两个子差 分馈电网络 20、 30属于同一类差分馈电网络, 而不必要求两个子差分馈 电网络 20、 30的结构完全一致, 例如, 两个子差分馈电网络 20、 30均为 宽带巴伦组成的馈电网络。 示例性的, 金属地 10可以是较厚的金属板, 也可以是厚度较小的金 属层, 优选的, 金属地 10的厚度为 2-3mm。 示例性的,本发明实施例将两个子差分馈电网络分被称为第一子差分 馈电网络 20和第二子差分馈电网络 30 , 优选的, 当多个第一子差分馈电 网络 20和第二子差分馈电网络 30分别成阵列分布时,阵列分布的多个第 一子差分馈电网络 20和第二子差分馈电网络 30可以共用一个金属地 10 , 即多个第一子差分馈电网络 20和多个第二子差分馈电网络 30分别阵列分 布于一个金属地 10的正面和反面两个相对的表面。 示例性的,本发明实施例以一种子差分馈电网络为例对双极化差分馈 电网络 100的馈电原理进行说明。 该子差分馈电网络包括介质板、 微带传输线以及三个端口, 其中, 三个端口包括一个输入端口和两个差分输出端口, 所述两个差分输出 端口中的一个差分输出端口用于与所述双极化天线辐射单元的一对端口对 中的一个端口连接, 所述两个差分输出端口中的另一个差分输出端口用于 与所述双极化天线辐射单元的所述端口对的另一个端口连接; 微带传输线分别与三个端口连接,且所述微带传输线和三个端口都位 于介质板的一个表面上, 介质板的另一个表面与金属地的一个表面连接。 参见图 2, 当金属地 10水平放置时, 第一子差分馈电网络 20和第二 子差分馈电网络 30分别位于金属地 10的正面(上表面)和反面(下表面), 其中, 第一子差分馈电网络 20包括介质板 201、微带传输线 202以及端口 Al、 端口 A2、 端口 A3 , 其中, 端口 A1为输入端口, 端口 A2、 端口 A3 为差分输出端口, 啟带传输线 202分别与端口 Al、 端口 A2、 端口 A3连 接, 且微带传输线 202与端口 Al、 端口 A2、 端口 A3都位于介质板 201 的一个表面上, 介质板 201 的另一个表面与金属地 10的表面连接。 第二 子差分馈电网络 30包括介质板 301、 啟带传输线 302以及端口 Bl、 端口 B2、 端口 B3 , 其中, 端口 B1为输入端口, 端口 B2、 端口 B3为差分输 出端口, 啟带传输线 302分别与端口 Bl、 端口 B2、 端口 B3连接, 且 带传输线 302与端口 B l、 端口 B2、 端口 B3位于介质板 301的一个表面 上, 介质板 301的另一个表面与金属地 10的表面连接。 天线辐射单元包含四个馈电端口: 端口 PA2、 端口 PA3、 端口 PB2、 端口 PB3 , 并构成两组端口对, 每组端口对分别用于与一个子差分馈电网 络的两个输出端口连接。 其中, 端口 PA2和端口 PA3为一组端口对, 端 口 PB2和端口 PB3为一组端口对。 端口 A2通过传输线 401与天线辐射 单元的端口 PA2电连接、端口 A3通过传输线 402与天线辐射单元的端口 PA3电连接;端口 B2通过传输线 403与天线辐射单元的端口 PB2电连接、 端口 B3通过传输线 404与天线辐射单元的端口 PB3电连接。 第一子差分馈电网络 20 和第二子差分馈电网络 30 分别通过传输线 401、 402、 403和 404同时对天线辐射单元的 4个端口 PA2、 PA3、 PB2、 PB3进行馈电。 第一子差分馈电网络 20和第二子差分馈电网络 30的差分 激励馈电分别对应两个正交极化通道, 例如, 第一子差分馈电网络 20 的 差分激励馈电分别对应 +45 度天线极化状态, 第二子差分馈电网络 30 的 差分激励馈电对应 -45度天线极化状态。 因此, 形成 +45度和 -45度两个正 交极化通道。 下面分别说明第一子差分馈电网络 20 和第二子差分馈电网 络 30的馈电过程。 进入端口 A1 ( +45度极化端口 ) 的激励信号 AS , 第一子差分馈电网 络 20的功率分配和移相,在端口 A2和端口 A3输出 2个等幅反相的信号 AS2和 AS3 , AS2和 AS3通过传输线 401和 402传输到天线辐射单元的 PA2和 PA3端口对, 第一子差分馈电网络 20实现对激励信号 AS的 +45 度极化馈电; 同理, 进入端口 B1 ( -45度极化端口 ) 的激励信号 BS , 通 过第二子差分馈电网络 30的功率分配和移相, 在端口 B2和端口 B3输出 2个等幅反相的信号 BS2和 BS3 , BS2和 BS3通过传输线 403和 404传输 到天线辐射单元的 PB2和 PB3端口对,第二子差分馈电网络 30实现对激 励信号 BS的 -45度极化馈电。 双极化差分馈电网络 100实现对天线辐射 单元的双极化通道馈电。 本发明实施例提供的双极化差分馈电网络 100 , 通过分别位于金属地 10正面和反面的两个子差分馈电网络 20、 30分别向双极化天线辐射单元 的一对端口进行差分馈电, 实现对双极化天线辐射单元的馈电, 且实现了 天线系统的小型化。
进一步的, 该子差分馈电网络还包括一个加载吸收端口;
所述微带传输线包括:
主传输线, 用于分别与四个端口连接;
至少两个分支传输线, 用于连接主传输线或副传输线;
副传输线, 用于分支传输线之间的连接; 其中, 主传输线包括第一主传输线、 第二主传输线、 第三主传输线和 第四主传输线, 第一主传输线和第二主传输线分别与两个差分输出端口连 接, 第三主传输线和第四主传输线分别与输入端口和加载吸收端口连接, 第一主传输线和第二主传输线对于传输信号具有 90度移相功能;在子差分 馈电网络与双极化天线辐射单元的一对端口对电气连接后, 主传输线、 分 支传输线、 副传输线构成等效巴伦, 以通过两个差分输出端口对双极化天 线辐射单元的一对端口对进行差分馈电。
如图 3所示,为本发明实施例提供的一种子差分馈电网络的结构示意 图, 因为第一子差分馈电网络 20和第二子差分馈电网络 30结构对称, 本 发明实施例仅对第一子差分馈电网络 20的结构进行说明。 如图 3所示, 第一子差分馈电网络 20包括: 四个端口 Al、 A2、 A3、 A4、 主传输线 11、 12、 13、 14、 三个分支 传输线 31、 32、 33和副传输线 41、 42、 43、 44。 其中, 端口 A1为输入端口, 用于与激励源连接、 端口 A2、 A3为差 分输出端口, 用于与天线辐射单元连接; 端口 A4为加载吸收端口, 用于 匹配负载。 四个端口 Al、 A2、 A3、 A4 的输入阻抗能够与外部器件的阻 抗相匹配, 例如能够与激励源的阻抗相匹配, 也能够与天线辐射单元的阻 抗相匹配。 可选地, 四个端口 Al、 A2、 A3、 A4的输入阻抗都为 50欧姆。 应理解, 本发明实施例仅以四个端口 Al、 A2、 A3、 A4 的输入阻抗 都为 50 欧姆为例进行说明, 但本发明并不限于此, 四个端口 Al、 A2、 A3、 A4的输入阻抗也可以为其它值, 以与连接的外部器件的阻抗相匹配。 主传输线 1 1、 12、 13、 14可以包括第一主传输线 1 1、 第二主传输线 12、 第三主传输线 13和第四主传输线 14 , 其中, 第一主传输线 1 1和第 二主传输线 12分别与端口 A2和端口 A3连接, 并且第一主传输线 1 1和 第二主传输线 12结合具有 90度移相功能,从而能够使得子差分馈电网络 20与天线辐射单元电气连接后, 子差分馈电网络 20构成等效巴伦, 以通 过子差分馈电网络 20的端口 A2和端口 A3对该天线辐射单元进行差分馈 电; 第三主传输线 13和第四主传输线 14分别与该端口 A1和端口 A4连 接。 分支传输线至少有两个, 分别用于连接第三主传输线 13和第四主传 输线 14 , 第一主传输线 1 1和第二主传输线 12 , 优选的, 可以增加一条或 一条以上的连接在副传输线之间的分支传输线,本实施例以增加一条连接 在副传输线之间的分支传输线为例进行说明,但是本发明实施例对此不构 成任何限制。 具体的, 可以包含三个分支传输线 31、 32、 33 , 具体可以 包括: 第一分支传输线 31 , 该第一分支传输线 31 与第三主传输线 13和 第四主传输线 14连接; 第二分支传输线 32 , 该第二分支传输线 32与副 传输线 41、 42、 43、 44连接; 以及第三分支传输线 33 , 该第三分支传输 线 33与第一主传输线 1 1和第二主传输线 12连接。
其中, 副传输线 41、 42、 43、 44可以包括:
用于连接第一主传输线 1 1、 第三分支传输线 33和第二分支传输线 32 的第一副传输线 41 ; 用于连接第二主传输线 12、 第三分支传输线 33和第 二分支传输线 32的第二副传输线 42; 用于连接第三主传输线 13、 第一分 支传输线 31和第二分支传输线 32的第三副传输线 43 ; 用于连接第四主传 输线 14、 第一分支传输线 31和第二分支传输线 32的第四副传输线 44; 进一步地, 第一主传输线 1 1可以包括第一主传输线单元 1 1 , 该第一 主传输线单元 1 1可以与端口 A2连接, 并分别与第三分支传输线 33以及 第一副传输线 41连接; 第二主传输线 12可以包括第二主传输线单元 12 , 该第二主传输线单元 12可以与端口 A3连接, 并与第三分支传输线 33和 第二副传输线 42连接; 第三主传输线 13可以包括第三主传输线单元 13 , 该第三主传输线单元 13可以与端口 A1连接, 并与第一分支传输线 31和 第三副传输线 43连接, 第三主传输线单元 13为传输路径; 第四主传输线 单元 14可以包括第四主传输线单元 14 , 该第四主传输线单元 14可以与 端口 A4连接, 并与第一分支传输线 31和第一副传输线 41连接, 第四主 传输线单元 14为匹配吸收路径。 具体地, 参见图 3 , 第一副传输线 41可以与第一主传输线单元 1 1、 第二分支传输线 32、 第三分支传输线 33和第三副传输线 43连接, 第二 副传输线 42可以与第二主传输线单元 12、 第二分支传输线 32、 第三分支 传输线 33和第四副传输线 44连接; 第三副传输线 43可以与第三主传输 线单元 13、 第一分支传输线 31、 第二分支传输线 32和第一副传输线 41 连接;第四副传输线 44可以与第四主传输线单元 14、第一分支传输线 31、 第二分支传输线 32和第二副传输线 42连接。 可选地, 第一主传输线 1 1和第二主传输线 12还用于对端口 A2和端 口 A3进行阻抗匹配 , 例如 , 进行 50欧姆的阻抗匹配。 应理解, 在本发 明实施例中, 随着与子差分馈电网络 20连接的负载的不同, 第三主传输 线 13和第四主传输线 14还可能用于对端口 A1和端口 A4进行阻抗匹配, 例如进行 50欧姆的阻抗匹配, 但本发明实施例并不限于此。 应理解, 本发明实施例仅以主传输线、 分支传输线和副传输线的上述 连接为例进行说明, 但本发明实施例并不限于此, 根据本发明实施例的差 分馈电网络还可以具有其它连接关系; 并且还应注意, 本发明实施例中所 涉及的 "第一" 和 "第二" 等术语的使用仅仅是为了描述的方便, 并不 对本发明实施例的范围构成限制,由于这些术语是对称的,因而可以互换。 在本发明实施例中, 主传输线包括的第一主传输线 1 1和第二主传输线 12 可以用于对传输信号产生 90度移相, 并用于对差分端口进行阻抗匹配, 例如进行 50欧姆的阻抗匹配。 具体而言, 可选地, 在本发明实施例中, 该第一主传输线单元 1 1和第二主传输线单元 12的电长度比该第三主传输 线单元 13 和第四主传输线单元 13 的电长度短, 且该第一主传输线单元 1 1和第二主传输线单元 12的电长度与该第三主传输线单元 13和第四主 传输线单元 14的电长度的差值为该传输信号的波长的四分之一。 从而使 得通过第三主传输线单元 14和第四主传输线单元 12输出的传输信号比通 过第一主传输线单元 1 1和第二主传输线单元 12输出的传输信号延迟 90 度相位。 其中, 传输线的电长度是以传输线所传输的电信号的波长为单位 来衡量传输线的长度, 例如, 某传输线的电长度指, 该传输线的物理长度 与该传输线上所传输电信号波长 λ的比值。 应理解,该第一主传输线单元 1 1和第二主传输线单元 12的电长度与 该第三主传输线单元 13和第四主传输线单元 14的电长度的差值可以近似 为该传输信号的波长的四分之一, 例如, 该差值为 0.22 λ 、 0.24 λ , 0.26 λ或 0.28 λ等, 其中 λ为传输信号的波长, 例如, 该传输信号的频率在 1.71GHz至 2.17GHz的范围内。 分支传输线和副传输线可以用于产生耦合分支传输路径,从而控制传 输信号的幅度和相位, 具体地, 通过多条耦合分支路径的信号叠加, 使得 端口 A1与端口 A4隔离,并且使得通过差分端口的传输信号再产生 90度 的相位差, 即使得通过端口 A3输出的传输信号比通过端口 A2输出的传 输信号再延迟 90度相位,从而使得通过该差分端口 A2和 A3对天线辐射 单元进行差分馈电。 在本发明实施例中, 第一分支传输线 31、 第二分支传输线 32和第三 分支传输线 33的电长度都可以近似为传输信号的波长的四分之一,例如, 各分支传输线的电长度在 0.2 λ至 0.3 λ之间, 其中 λ为传输信号的波长; 又例如, 各分支传输线的电长度为 0.14 λ 、 0.24 λ , 0.26 λ或 0.28 λ等。 可选地, 该第一分支传输线 31、 该第二分支传输线 32和该第三分支传输 线 33的电长度相等, 且为该传输信号的波长的四分之一。 在本发明实施例中, 可选地, 该第一副传输线 41、 该第二副传输线 42、 该第三副传输线 43和该第四副传输线 44的电长度相等, 且为该传输 信号的波长的四分之一。 应理解, 各副传输线的电长度也都可以近似为传 输信号的波长的四分之一, 例如, 各副传输线的电长度在 0.2 λ至 0.3 λ之 间, 其中 λ为传输信号的波长; 又例如, 各副传输线的电长度为 0.14 λ 、 0.24 λ , 0.26 λ或 0.28 λ等, 但本发明实施例并不限于此。 在本发明实施例中, 可选地, 第一分支传输线 31 的阻抗大于或等于 第二分支传输线 32的阻抗;且第一分支传输线 31的阻抗大于或等于第三 分支传输线 33 的阻抗。 第二分支传输线 32的阻抗与第三分支传输线 33 的阻抗相近, 优选地, 第二分支传输线 32的阻抗等于第三分支传输线 33 的阻抗。 在本发明实施例中, 可选地, 第一主传输线 1 1 和第二主传输线 12 的阻抗大于第三主传输线 13和第四主传输线 14的阻抗;并且第一主传输 线 1 1和第二主传输线 12的阻抗小于每个分支传输线的阻抗。 本发明实施例的子差分馈电网络 20 , 通过与天线辐射单元电气连接 后, 子差分馈电网络 20包括的主传输线、 三个分支传输线以及副传输线 构成等效巴伦, 从而能够通过子差分馈电网络 20的两个差分输出端口对 天线辐射单元进行差分馈电,由此能够避免使用阻抗器件,减小能量损耗, 并提高子差分馈电网络 20的性能。并且子差分馈电网络 20不仅能够在较 宽的带宽范围内保持通过差分端口的传输信号反相,还能够在较宽的带宽 范围内保持通过差分端口的传输信号等幅, 并具有反射系数低、 尺寸小以 及损耗低等优点。
参见图 4 , 为由上述子差分馈电网络组成的双极化差分馈电网络 100 的一种具体构造。 该双极化差分馈电网络 100包括: 金属地 10; 金属地 10的上表面和下表面紧密与介质板 201和 301的 一个表面连接,介质板 201和介质板 301的另一表面分别设置有多条微带 线, 介质板 201和其上的微带线组成第一子差分馈电网络 20 , 介质板 301 和其上的微带线组成第二子差分馈电网络 30。 其中,金属地 10厚度为 1.5mm,介质板 201和 301的厚度均为 0.8mm, 介质板 201和 301的介电常数分别为 2.55和 2.6。 应理解, 本发明实施例 仅以上述具体数值为例进行说明, 但本发明并不限于此, 在具体实施中, 根据本发明实施例的差分馈电网络的传输线组结构、阻抗及其长度可以根 据需求进行优化。
第一子差分馈电网络 20包括 4个端口 Al、 A2、 A3和 A4 , 其中, 端 口 A1为输入端口, 端口 A2、 A3为差分输出端口, 端口 A4为加载吸收 端口。 类似的 , 第二子差分馈电网络 30包括 4个端口 Bl、 B2、 B3和 B4 , 其中, 端口 B 1 为输入端口, 端口 B2、 B3为差分输出端口, 端口 B4为 加载吸收端口。 端口 A2和端口 A3组成 +45度极化差分端口对, 端口 B2 和端口 B3组成 -45度极化差分端口对。 通过传输线同时对天线辐射单元 的 4个端口馈电, 从而实现双极化通道馈电。
本发明实施例提供的双极化差分馈电网络 100 , 通过分别位于金属地 10相对的两个表面的子差分馈电网络 20、 30分别向双极化天线辐射单元 的一对端口进行差分馈电, 实现对双极化天线辐射单元的馈电, 且实现了 天线系统的小型化。 参见图 5 , 为本发明实施例提供的另一种双极化差分馈电网络 100的 具体构造。 该双极化差分馈电网络 100包括: 金属地 10; 金属地 10的正面和反面紧密与介质板 201和 301的一个 表面连接, 介质板 201和介质板 301的另一表面分别设置有多条微带线, 介质板 201和其上的微带线组成第一子差分馈电网络 20 , 介质板 301和 其上的微带线组成第二子差分馈电网络 30。 第一子差分馈电网络 20包括 4个端口 Al、 A2、 A3和 A4 , 其中, 端口 A1为输入端口, 端口 A2、 A3 为差分输出端口, 端口 A4为加载吸收端口。 类似的, 第二子差分馈电网 络 30包括 4个端口 Bl、 B2、 B3和 B4 , 其中, 端口 B1为输入端口 , 端 口 B2、 B3为差分输出端口, 端口 B4为加载吸收端口。 端口 A2和端口 A3组成 +45度极化差分端口对, 端口 B2和端口 B3组成 -45度极化差分 端口对。 通过传输线同时对天线辐射单元的 4个端口馈电, 从而实现双极 化通道馈电。 第一子差分馈电网络 20的输入端口 A1对应位置的金属地 10设置有 过孔 50 , 过孔 50内设置有金属柱 60, 与该过孔 50位置对应的第二差分 馈电网络 30的介质板 301上设置有等效输入端口 Al l , 第一子差分馈电 网络 20的输入端口 A1通过金属柱 60与第二差分网馈电网络 30侧的等 效输入端口 Al l连接。 示例性的, 过孔 50内的金属柱 60与金属地 10绝缘连接, 可选的, 金属柱 60与金属地 10可通过空气绝缘连接,本发明实施例对比不进行限 制。 本发明实施例提供的双极化差分馈电网络 100 , 通过分别位于金属地 10相对的两个表面的子差分馈电网络 20、 30分别向双极化天线辐射单元 的一对端口进行差分馈电, 实现对双极化天线辐射单元的馈电, 且实现了 天线系统的小型化。 通过过孔的设置可以实现第一子差分馈电网络 20和 第二子差分馈电网络 30的输入端口处在一个平面上, 使得 +45极化通道 和—45度极化通道的功分馈电网络共面布置,有利于天线馈电网络的布局。 一方面, 本发明实施例提供了一种天线 60 , 参见图 6 , 包括: 双极化天线辐射单元 600 , 用于向空间辐射或从空间接收电磁波; 上述任一实施例所述的双极化差分馈电网络 100 , 用于对所述双极化 天线辐射单元 600进行差分馈电。 本发明实施例提供的天线,双极化差分馈电网络 100通过分别位于金 属地相对的两个表面的子差分馈电网络分别向双极化天线辐射单元 600的 一对端口进行差分馈电, 实现对双极化天线辐射单元 600的馈电, 且实现 了天线系统的小型化。
一方面, 本发明实施例提供了一种基站, 包括上述任一实施例所述的 双极化差分馈电网络 100或任一实施例所述的天线 60。 本发明实施例提供的基站, 通过分别位于金属地相对的两个表面的子 差分馈电网络分别向双极化天线辐射单元的一对端口进行差分馈电, 实现 对双极化天线辐射单元的馈电, 且实现了天线系统的小型化。 在本申请所提供的几个实施例中,应该理解到,所揭露的系统和装置, 可以通过其它的方式实现。 例如, 以上所描述的装置实施例仅仅是示意性 的, 例如, 所述单元的划分, 仅仅为一种逻辑功能划分, 实际实现时可以 有另外的划分方式,例如多个单元或组件可以结合或者可以集成到另一个 系统, 或一些特征可以忽略, 或不执行。 另外, 所显示或讨论的相互之间 的耦合或直接耦合或通信连接可以是通过一些接口、装置或单元的间接耦 合或通信连接, 也可以是电的, 机械的或其它的形式连接。 所述作为分离部件说明的单元可以是或者也可以不是物理上分开的, 作为单元显示的部件可以是或者也可以不是物理单元,即可以位于一个地 方, 或者也可以分布到多个网络单元上。 可以根据实际的需要选择其中的 部分或者全部单元来实现本发明实施例方案的目的。 另外,在本发明各个实施例中的各功能单元可以集成在一个处理单元 中, 也可以是各个单元单独物理存在, 也可以是两个或两个以上单元集成 在一个单元中。 上述集成的单元既可以釆用硬件的形式实现, 也可以釆用 软件功能单元的形式实现。 所述集成的单元如果以软件功能单元的形式实现并作为独立的产品 销售或使用时, 可以存储在一个计算机可读取存储介质中。基于这样的理 解, 本发明的技术方案本质上或者说对现有技术做出贡献的部分, 或者该 技术方案的全部或部分可以以软件产品的形式体现出来,该计算机软件产 品存储在一个存储介质中, 包括若干指令用以使得一台计算机设备(可以 是个人计算机, 服务器, 或者网络设备等)执行本发明各个实施例所述方 法的全部或部分步骤。 而前述的存储介质包括: U盘、 移动硬盘、 只读存 储器( ROM , Read-Only Memory )、随机存取存储器( RAM, Random Access Memory ) 、 磁碟或者光盘等各种可以存储程序代码的介质。 以上所述, 仅为本发明的具体实施方式, 但本发明的保护范围并不局 限于此, 任何熟悉本技术领域的技术人员在本发明揭露的技术范围内, 可 轻易想到各种等效的修改或替换,这些修改或替换都应涵盖在本发明的保 护范围之内。 因此, 本发明的保护范围应以权利要求的保护范围为准。

Claims

权 利 要 求 书
1、 一种双极化差分馈电网络, 其特征在于, 包括:
金属地以及分别与所述金属地连接的两个子差分馈电网络;
所述两个子差分馈电网络分别位于所述金属地的正面和反面两个相 对的表面, 且所述两个差分馈电网络中的一个子差分馈电网络用于向双极 化天线辐射单元的的一对端口对进行差分馈电, 所述两个子差分馈电网络 中的另一个子差分馈电网络用于向所述双极化天线辐射单元的另一对端口 对进行差分馈电。
2、 根据权利要求 1 所述的双极化差分馈电网络, 其特征在于, 所述 每个子差分馈电网络包括介质板、 微带传输线以及三个端口, 其中,
所述三个端口包括一个输入端口和两个差分输出端口, 所述两个差分 输出端口中的一个差分输出端口用于与所述双极化天线辐射单元的一对端 口对中的一个端口连接, 所述两个差分输出端口中的另一个差分输出端口 用于与所述双极化天线辐射单元的所述端口对的另一个端口连接;
所述微带传输线分别与所述三个端口连接, 且所述微带传输线和三个 端口都位于所述介质板的一个表面上, 所述介质板的另一个表面与所述金 属地的一个表面连接。
3、 根据权利要求 2 所述的双极化差分馈电网络, 其特征在于, 所述 双极化差分馈电网络包括第一子差分馈电网络和第二子差分馈电网络, 所述第一子差分馈电网络的输入端口对应位置的所述金属地设置有 过孔, 所述过孔内设置有金属柱, 与所述过孔位置对应的所述第二子差分 馈电网络设置有等效输入端口, 所述第一子差分馈电网络的输入端口通过 所述金属柱与所述第二子差分网馈电网络侧的等效输入端口连接。
4、 根据权利要求 2或 3所述的双极化差分馈电网络, 其特征在于, 所述每个子差分馈电网络还包括一个加载吸收端口;
所述微带传输线包括:
主传输线, 所述主传输线用于分别与四个端口连接;
至少两个分支传输线, 所述分支传输线用于连接所述主传输线或副传 输线;
副传输线, 所述副传输线用于所述分支传输线之间的连接;
其中, 所述主传输线包括第一主传输线、 第二主传输线、 第三主传输 线和第四主传输线, 所述第一主传输线和所述第二主传输线分别与所述两 个差分输出端口连接, 所述第三主传输线和所述第四主传输线分别与所述 输入端口和所述加载吸收端口连接, 所述第一主传输线和第二主传输线结 合对于传输信号具有 90度移相功能;在所述子差分馈电网络与所述双极化 天线辐射单元的一对端口对电气连接后, 所述主传输线、 所述至少两个分 支传输线、 所述副传输线构成等效巴伦, 以通过所述两个差分输出端口对 所述双极化天线辐射单元的一对端口对进行差分馈电。
5、 根据权利要求 4 所述的双极化差分馈电网络, 其特征在于, 所述 子差分馈电网络包括三个分支传输线, 所述三个分支传输线包括: 与所述 第三主传输线和所述第四主传输线连接的第一分支传输线、 与所述副传输 线连接的第二分支传输线、 以及与所述第一主传输线和所述第二主传输线 连接的第三分支传输线;
其中, 所述第一分支传输线、 所述第二分支传输线和所述第三分支传 输线的电长度相等, 且为所述传输信号的波长的四分之一。
6、 根据权利要求 5 所述的双极化差分馈电网络, 其特征在于, 所述 第一分支传输线的阻抗大于或等于所述第二分支传输线的阻抗; 且所述第 一分支传输线的阻抗大于或等于所述第三分支传输线的阻抗。
7、 根据权利要求 5或 6所述的双极化差分馈电网络, 其特征在于, 所述第二分支传输线的阻抗等于所述第三分支传输线的阻抗。
8、 根据权利要求 5 至 7 中任一项所述的双极化差分馈电网络, 其特 征在于, 所述副传输线包括:
用于连接所述第一主传输线、 所述第三分支传输线和所述第二分支传 输线的第一副传输线; 或
用于连接所述第二主传输线、 所述第三分支传输线和所述第二分支传 输线的第二副传输线; 或
用于连接所述第三主传输线、 所述第一分支传输线和所述第二分支传 输线的第三副传输线; 或
用于连接所述第四主传输线、 所述第一分支传输线和所述第二分支传 输线的第四副传输线;
其中, 所述第一副传输线、 所述第二副传输线、 所述第三副传输线和 所述第四副传输线的电长度相等, 且为所述传输信号的波长的四分之一。
9、 根据权利要求 5 至 8 中任一项所述的双极化差分馈电网络, 其特 征在于, 所述第一主传输线和第二主传输线的阻抗大于所述第三主传输线 和第四主传输线的阻抗; 并且所述第一主传输线和第二主传输线的阻抗小 于所述每个分支传输线的阻抗。
10、 根据权利要求 2至 9中任一项所述的双极化差分馈电网络, 其特 征在于, 所述介质板的介电常数为 2-4。
1 1、 根据权利要求 4至 10 中任一项所述的双极化差分馈电网络, 其 特征在于, 所述输入端口、 所述差分输出端口和所述加载吸收端口的输入 阻抗都为 50欧姆。
12、 根据权利要求 4至 1 1 中任一项所述的双极化差分馈电网络, 其 特征在于, 所述第一主传输线和所述第二主传输线还用于对所述两个差分 输出端口进行阻抗匹配。
13、 一种天线, 其特征在于, 包括:
双极化天线辐射单元, 用于向空间辐射或从空间接收电磁波; 和 如权利要求 1 至 12任一项所述的双极化差分馈电网络, 用于对所述 双极化天线辐射单元进行差分馈电。
14、 一种基站, 其特征在于, 包括权利要求 1 至 12任一项所述的双 极化差分馈电网络或权利要求 13所述的天线。
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