EP2565985A1 - Antenne à microrubans et à double polarisation - Google Patents

Antenne à microrubans et à double polarisation Download PDF

Info

Publication number
EP2565985A1
EP2565985A1 EP11765012A EP11765012A EP2565985A1 EP 2565985 A1 EP2565985 A1 EP 2565985A1 EP 11765012 A EP11765012 A EP 11765012A EP 11765012 A EP11765012 A EP 11765012A EP 2565985 A1 EP2565985 A1 EP 2565985A1
Authority
EP
European Patent Office
Prior art keywords
antenna
dual
metal
polarized
dielectric layer
Prior art date
Legal status (The legal status 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 status listed.)
Ceased
Application number
EP11765012A
Other languages
German (de)
English (en)
Other versions
EP2565985A4 (fr
Inventor
Kunjie Zhuang
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Individual
Original Assignee
Individual
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.)
Filing date
Publication date
Priority claimed from CN2010201522504U external-priority patent/CN201690448U/zh
Priority claimed from CN2010201522580U external-priority patent/CN201689984U/zh
Priority claimed from CN2010205200868U external-priority patent/CN201812928U/zh
Priority claimed from CN2010205201019U external-priority patent/CN202121055U/zh
Priority claimed from CN2010205200590U external-priority patent/CN201812925U/zh
Priority claimed from CN2010205200711U external-priority patent/CN201812926U/zh
Priority claimed from CN2010205201131U external-priority patent/CN202121056U/zh
Priority claimed from CN2010205200779U external-priority patent/CN201812927U/zh
Priority claimed from CN2010205200904U external-priority patent/CN202121054U/zh
Priority claimed from CN2010105294164A external-priority patent/CN102332635B/zh
Application filed by Individual filed Critical Individual
Publication of EP2565985A1 publication Critical patent/EP2565985A1/fr
Publication of EP2565985A4 publication Critical patent/EP2565985A4/fr
Ceased legal-status Critical Current

Links

Images

Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q1/00Details of, or arrangements associated with, antennas
    • H01Q1/36Structural form of radiating elements, e.g. cone, spiral, umbrella; Particular materials used therewith
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q1/00Details of, or arrangements associated with, antennas
    • H01Q1/36Structural form of radiating elements, e.g. cone, spiral, umbrella; Particular materials used therewith
    • H01Q1/38Structural form of radiating elements, e.g. cone, spiral, umbrella; Particular materials used therewith formed by a conductive layer on an insulating support
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q1/00Details of, or arrangements associated with, antennas
    • H01Q1/42Housings not intimately mechanically associated with radiating elements, e.g. radome
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q1/00Details of, or arrangements associated with, antennas
    • H01Q1/48Earthing means; Earth screens; Counterpoises
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q19/00Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic
    • H01Q19/10Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic using reflecting surfaces
    • H01Q19/104Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic using reflecting surfaces using a substantially flat reflector for deflecting the radiated beam, e.g. periscopic antennas
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q21/00Antenna arrays or systems
    • H01Q21/06Arrays of individually energised antenna units similarly polarised and spaced apart
    • H01Q21/061Two dimensional planar arrays
    • H01Q21/065Patch antenna array
    • 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
    • H01Q21/00Antenna arrays or systems
    • H01Q21/28Combinations of substantially independent non-interacting antenna units or systems
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q21/00Antenna arrays or systems
    • H01Q21/29Combinations of different interacting antenna units for giving a desired directional characteristic
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q5/00Arrangements for simultaneous operation of antennas on two or more different wavebands, e.g. dual-band or multi-band arrangements
    • H01Q5/30Arrangements for providing operation on different wavebands
    • H01Q5/378Combination of fed elements with parasitic elements
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q9/00Electrically-short antennas having dimensions not more than twice the operating wavelength and consisting of conductive active radiating elements
    • H01Q9/04Resonant antennas
    • H01Q9/0407Substantially flat resonant element parallel to ground plane, e.g. patch antenna
    • H01Q9/0414Substantially flat resonant element parallel to ground plane, e.g. patch antenna in a stacked or folded configuration
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q9/00Electrically-short antennas having dimensions not more than twice the operating wavelength and consisting of conductive active radiating elements
    • H01Q9/04Resonant antennas
    • H01Q9/0407Substantially flat resonant element parallel to ground plane, e.g. patch antenna
    • H01Q9/0428Substantially flat resonant element parallel to ground plane, e.g. patch antenna radiating a circular polarised wave
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q9/00Electrically-short antennas having dimensions not more than twice the operating wavelength and consisting of conductive active radiating elements
    • H01Q9/04Resonant antennas
    • H01Q9/0407Substantially flat resonant element parallel to ground plane, e.g. patch antenna
    • H01Q9/0442Substantially flat resonant element parallel to ground plane, e.g. patch antenna with particular tuning means
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q9/00Electrically-short antennas having dimensions not more than twice the operating wavelength and consisting of conductive active radiating elements
    • H01Q9/04Resonant antennas
    • H01Q9/0407Substantially flat resonant element parallel to ground plane, e.g. patch antenna
    • H01Q9/045Substantially flat resonant element parallel to ground plane, e.g. patch antenna with particular feeding means
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q9/00Electrically-short antennas having dimensions not more than twice the operating wavelength and consisting of conductive active radiating elements
    • H01Q9/04Resonant antennas
    • H01Q9/0407Substantially flat resonant element parallel to ground plane, e.g. patch antenna
    • H01Q9/045Substantially flat resonant element parallel to ground plane, e.g. patch antenna with particular feeding means
    • H01Q9/0457Substantially flat resonant element parallel to ground plane, e.g. patch antenna with particular feeding means electromagnetically coupled to the feed line

Definitions

  • the invention relates to an antenna device, in particular a small microwave low-band multi-frequency high-gain dual-polarized microstrip antenna.
  • Embodiments disclose a microwave antenna with a multi-excitation and multi-layer tuning mechanism, belonging to the technical field of antennas for signal transmission and mobile communication as well as the wireless Internet.
  • the present microwave antenna with the defects of low work efficiency, clumsiness and difficulty in installation and maintenance, is far from meeting the requirements of the development of mobile communication technology for antenna technology.
  • CN200710145376.1 relates to a multi-antenna mode selection method during relay network cell switch.
  • CN200910085526.3 relates to a relay transmission method based on antenna beam overlapping.
  • CN201010222613.1 relates to a base station antenna and a base station antenna unit.
  • KR27919/08 relates to a device for processing signals in a distributed antenna system and a method.
  • JP144655/06 relates to an antenna device.
  • PCT/JP2007/000969 relates to a self-adaptive multi-antenna mobile communication system.
  • JP144655/06 relates to an antenna device.
  • US60/545896 relates to an antenna module.
  • PCT/US2002/028275 relates to a base station antenna array.
  • PCT/JP01/02001 relates to an array antenna base station device.
  • PCT/US99/19117 relates to a technology combining channel coding with space-time coding principle to enhance antenna performance.
  • US20110001682 , US7508346 and US7327317 relate to dual-polarized microstrip antennas. These antenna-related technologies can meet neither the design requirements for antennas to attain small size, small weight, high gain and adjustable VSWR, nor the performance requirements and technical standards for new-generation TDSCDMA and LTE antennas set by CMCC.
  • This invention aims to overcome the defects of the traditional microwave low-band (300MHz-6GHz) microstrip antenna, and to provide a small microwave low-band multi-frequency high-gain dual-polarized microstrip antenna featuring wide working band, high gain, excellent cross polarization isolation, small size and light weight.
  • This invention adopts the following technical scheme:
  • a VSWR independent adjustment unit connected with the first metal radiating patch is arranged, and it is preferred that the metal radiating patch is circular, so that when the metal radiating patch is adjusted, only the height parameter of the structural relationship between the metal radiating patch and other radiation tuning mechanisms is changed, rather than other parameters that are likely to affect the radiation effects of the antenna. As a result, the VSWR adjustment is simplified and facilitated during manufacture.
  • the excitation micro-slots are two discretely vertical H-shaped excitation micro-slots with the same dimensions, that is, the two H-shaped excitation micro-slots are not in contact.
  • the H-shaped excitation micro-slots are identical in dimensions which are related to the central frequency band wavelength ⁇ of the resonance radiation required by the antenna and used to ensure that the dual-polarized antenna has consistent radiation performance optimization in two polarization directions.
  • the cross arms "-" of the two H-shaped excitation micro-slots are mutually vertical for the purpose of guaranteeing excellent polarization isolation of the dual-polarized antenna. Experiment proves that the preferred design can ensure the planned isolation exceeds 25-30dBi.
  • the dual-polarized microstrip antenna according to the invention is a microwave antenna with a multi-excitation and multi-layer tuning mechanism.
  • the thickness of the first dielectric layer ranges from 1 to 20mm,and experiment proves that the source input end of the antenna achieves the optimal VSWR of less than 1.2 when the thickness ranges from 4 to 10mm at the frequency band of 2GHz-3GHz; a dielectric substrate 6 is arranged between the bipolar excitation microstrip lines and the ground metal layer.
  • the thickness of the dielectric substrate ranges from 0.2 to 5mm and is preferred to range from 0.5 to 2mm.
  • Front ends of the two excitation microstrip lines are linear. It is preferred that the front end of each excitation microstrip line is vertical to the cross arm "-" of one H-shaped excitation micro-slot, and the front ends pass through the middle points of the cross arms "-" of the respective H-shaped excitation micro-slots; the front ends of the two excitation microstrip lines are discretely vertical for the purposes of guaranteeing the polarization isolation of the dual-polarized antenna and leading it to be used as two independent antennas; the distance between the two discrete front ends which are not in contact ranges from 3 to 8mm; and the perpendicularity between the two discrete front ends which are not in contact is 90°. Simulation and experiment results prove that the above design and optimal design data can achieve a better radiation efficiency (gain) of 8-8.5dBi and a polarization isolation of 25-30dBi or above.
  • the two H-shaped excitation micro-slots are identical in size, width, slot depth, slot width and shape; it is preferred that two ends of the single cross arm "-" of each H-shaped excitation micro-slot intersect with the middle points of the two vertical arms "
  • a second dielectric layer is arranged. It is preferred that the second dielectric layer is a resonant dielectric layer, particularly a resonant dielectric layer of air or a layer of other optimization resonant materials.
  • the radiation-related parameters of the radiating patch, the dielectric layers and the ground metal layer are selected through simulations and experiments.
  • a second metal radiating patch is arranged and used for enlarging the radiation frequency bandwidth of the antenna or achieving the double-humped resonance between adjacent frequency bands; it is preferred that the second metal radiating patch is identical to the first metal radiating patch in material, thickness and shape; it is preferred that the size of the second metal radiating patch is freely optimized according to the requirements for widening the frequency band; it is preferred that the size relationship between the second metal radiating patch and the first metal radiating patch is subject to the relative relationship between the working frequency band and the widened frequency band, that is, a higher frequency results in a smaller area, and the comprehensive results of experiments and simulations show that the size ratio of the two patches approximately equals the center frequency wavelength ratio of two adjacent frequency bands to be widened; and it is preferred that the second metal radiating patch is arranged above the second dielectric layer so as to separate the first dielectric layer into two areas, where the lower part is preferred to be the slot cavity and the upper part is preferred to be a first dielectric layer area between the first and the second metal radiating patches.
  • An air dielectric layer namely air dielectric layer A, is arranged, which provides an undisturbed work space height for the excitation microstrip lines interfaced with a source.
  • the work space height needs to be more than 3-10 times of the thickness of the first dielectric substrate, and a smaller dielectric constant of the dielectric substrate leads to a larger multiple; it is preferred that a metal reflection ground baseplate is arranged and used for providing excellent backward radiation isolation for radiating units and providing convenient system ground for source parts, feed source parts or radiating units.
  • the dual-polarized microstrip antenna of the invention can act as an antenna unit which is connected through a two-way power divider.
  • the connected body includes two dual-polarized antenna units.
  • a first air dielectric layer, a first metal radiating patch, a second air dielectric layer, a ground metal layer with bipolar micro-slots, a first dielectric substrate, bipolar excitation microstrip lines, a third air dielectric layer and a metal reflection baseplate are sequentially arranged from top to bottom, that is, opposite to the direction of microwave radiation.
  • the first metal radiating patch is connected with an antenna cover through an insulation screw, a ground metal patch covers the upper end surface of the first dielectric substrate and is fixedly connected with a hollow metal support fixed on the metal reflection baseplate, bipolar excitation microstrip lines, of which the front ends are orthogonal but not in contact, are arranged on the lower end surface of the first dielectric substrate, and two bipolar stimulated radiation micro-slots, orthogonal but not in contact, are formed on the upper end surface of the ground metal patch and are corresponding to the front ends of the bipolar excitation microstrip lines in an orthogonal way.
  • the above orthogonal and vertical correspondence relationships can achieve excellent dual polarization characteristics, that is, high polarization isolation.
  • the dual-polarized microstrip antenna of the invention can act as an antenna unit which is connected through a four-way power division network.
  • the connected body includes four dual-polarized antenna units connected together through the four-way power division network in an antenna cover.
  • the four dual-polarized antenna units are distributed in a line in the antenna cover.
  • a first air dielectric layer, a first metal radiating patch, a second air dielectric layer, a ground metal layer with bipolar micro-slots, a first dielectric substrate, bipolar excitation microstrip lines, a third air dielectric layer and a metal reflection baseplate are sequentially arranged from top to bottom.
  • the first metal radiating patch is connected with the antenna cover through an insulation screw, a ground metal patch covers the upper end surface of the first dielectric substrate and is fixedly connected with a hollow metal support fixed on the metal reflection baseplate, bipolar excitation microstrip lines, of which the front ends are orthogonal but not in contact, are arranged on the lower end surface of the first dielectric substrate, and two bipolar stimulated radiation micro-slots, orthogonal but not in contact, are formed on the upper end surface of the ground metal patch and are corresponding to the front ends of the bipolar excitation microstrip lines in an orthogonal way.
  • the dual-polarized microstrip antenna of the invention can act as an antenna unit which is connected through a four-way power division network.
  • the connected body includes four dual-polarized antenna units connected together through the four-way power division network in an antenna cover.
  • the four dual-polarized antenna units are distributed in two lines and two rows in the antenna cover.
  • a first air dielectric layer, a first metal radiating patch, a second air dielectric layer, a ground metal layer with bipolar micro-slots, a first dielectric substrate, bipolar excitation microstrip lines, a third air dielectric layer and a metal reflection baseplate are sequentially arranged from top to bottom.
  • the first metal radiating patch is connected with the antenna cover through an insulation screw
  • the ground metal patch covers the upper end surface of the first dielectric substrate and is fixedly connected with a hollow metal support fixed on the metal reflection baseplate
  • bipolar excitation microstrip lines of which the front ends are orthogonal but not in contact, are arranged on the lower end surface of the first dielectric substrate
  • two bipolar stimulated radiation micro-slots orthogonal but not in contact, are formed on the upper end surface of the ground metal patch and are corresponding to the front ends of the bipolar excitation microstrip lines in an orthogonal way.
  • the invention further discloses a dual-polarized microstrip antenna, which is characterized by including two independent dual-polarized antennas in an antenna cover, said dual-polarized antenna includes two dual-polarized antenna units connected together through a two-way power divider, in each dual-polarized antenna unit, a first air dielectric layer, a first metal radiating patch, a second air dielectric layer, a ground metal layer with bipolar micro-slots, a first dielectric substrate, bipolar excitation microstrip lines, a third air dielectric layer and a metal reflection baseplate are sequentially arranged from top to bottom.
  • the first metal radiating patch is connected with the antenna cover through an insulation screw
  • the ground metal patch covers the upper end surface of the first dielectric substrate and is fixedly connected with a hollow metal support fixed on the metal reflection baseplate
  • bipolar excitation microstrip lines of which the front ends are orthogonal but not in contact, are arranged on the lower end surface of the first dielectric substrate
  • two bipolar stimulated radiation micro-slots orthogonal but not in contact, are formed on the upper end surface of the ground metal patch and are corresponding to the front ends of the bipolar excitation microstrip lines in an orthogonal way.
  • the invention further discloses a dual-polarized microstrip antenna, which is characterized by including eight dual-polarized antenna units connected together through an eight-way power division network in an antenna cover.
  • a first air dielectric layer, a first metal radiating patch, a second air dielectric layer, a ground metal layer with bipolar micro-slots, a first dielectric substrate, bipolar excitation microstrip lines, a third air dielectric layer and a metal reflection baseplate are sequentially arranged from top to bottom.
  • the first metal radiating patch is connected with the antenna cover through an insulation screw
  • the ground metal patch covers the upper end surface of the first dielectric substrate and is fixedly connected with a hollow metal support fixed on the metal reflection baseplate
  • bipolar excitation microstrip lines of which the front ends are orthogonal but not in contact, are arranged on the lower end surface of the first dielectric substrate
  • two bipolar stimulated radiation micro-slots orthogonal but not in contact, are formed on the upper end surface of the ground metal patch and are corresponding to the front ends of the bipolar excitation microstrip lines in an orthogonal way.
  • the invention further discloses a dual-polarized microstrip antenna, which is characterized by including four independent dual-polarized antennas in an antenna cover.
  • the dual-polarized microstrip antenna is characterized in that each row of dual-polarized antennas includes two dual-polarized antenna units connected together through a two-way power divider.
  • a first air dielectric layer, a first metal radiating patch, a second air dielectric layer, a ground metal layer with bipolar micro-slots, a first dielectric substrate, bipolar excitation microstrip lines, a third air dielectric layer and a metal reflection baseplate are sequentially arranged from top to bottom.
  • the first metal radiating patch is connected with the antenna cover through an insulation screw
  • the ground metal patch covers the upper end surface of the first dielectric substrate and is fixedly connected with a hollow metal support fixed on the metal reflection baseplate
  • bipolar excitation microstrip lines of which the front ends are orthogonal but not in contact, are arranged on the lower end surface of the first dielectric substrate
  • two bipolar stimulated radiation micro-slots orthogonal but not in contact, are formed on the upper end surface of the ground metal patch and are corresponding to the front ends of the bipolar excitation microstrip lines in an orthogonal way.
  • the invention further discloses a dual-polarized microstrip antenna, which is characterized by including four independent dual-polarized antennas in an antenna cover.
  • the dual-polarized microstrip antenna is characterized in that each row of dual-polarized antennas includes four dual-polarized antenna units connected together through a four-way power divider.
  • a first air dielectric layer, a first metal radiating patch, a second air dielectric layer, a ground metal layer with bipolar micro-slots, a first dielectric substrate, bipolar excitation microstrip lines, a third air dielectric layer and a metal reflection baseplate are sequentially arranged from top to bottom.
  • the first metal radiating patch is connected with the antenna cover through an insulation screw
  • the ground metal patch covers the upper end surface of the first dielectric substrate and is fixedly connected with a hollow metal support fixed on the metal reflection baseplate
  • bipolar excitation microstrip lines of which the front ends are orthogonal but not in contact, are arranged on the lower end surface of the first dielectric substrate
  • two bipolar stimulated radiation micro-slots orthogonal but not in contact, are formed on the upper end surface of the ground metal patch and are corresponding to the front ends of the bipolar excitation microstrip lines in an orthogonal way.
  • the invention further discloses a dual-polarized microstrip antenna, which is characterized by including a first air dielectric layer, a first metal radiating patch, a second air dielectric layer, a ground metal patch, a first dielectric substrate, bipolar excitation microstrip lines, a third air dielectric layer and a metal reflection baseplate sequentially arranged from top to bottom in an antenna cover.
  • the ground metal patch covers the upper end surface of the first dielectric substrate and is fixedly connected with a hollow metal support fixed on the metal reflection baseplate. Stimulated radiation micro-slots are formed on the upper end surface of the ground metal patch.
  • the first metal radiating patch is circular, where an adjusting screw is fixed in the center, and the first metal radiating patch is fixed through the threaded connection between the adjusting screw and the internal threads in the center of the antenna cover.
  • a wireless communication relay station employing the dual-polarized microstrip antenna of the invention is characterized by including at least one dual-polarized microstrip antenna, and it is preferred that the input port of the dual-polarized microstrip antenna is connected with the retransmission end of the relay station.
  • a wireless communication base station employing the dual-polarized microstrip antenna of the invention is characterized by including at least one dual-polarized microstrip antenna.
  • a communication system and terminal employing the dual-polarized microstrip antenna of the invention is characterized by including at least one piece of equipment equipped with the dual-polarized microstrip antenna.
  • the dual-polarized microstrip antenna of the invention is a microwave antenna with a multi-excitation and multi-layer tuning mechanism.
  • the invention discloses a dual-polarized microstrip antenna, including at least one metal radiating patch, i.e. a first metal radiating patch;
  • a unit connected with the first metal radiating patch for facilitating independent VSWR adjustment is arranged, and it is preferred that the metal radiating patch is circular.
  • the excitation micro-slots are two discretely vertical H-shaped excitation micro-slots with the same dimensions, that is, the two H-shaped excitation micro-slots are not in contact.
  • the H-shaped excitation micro-slots are identical in dimensions to ensure that the dual-polarized antenna has consistent radiation performance optimization in the two polarization directions.
  • the cross arms "-" of the two H-shaped excitation micro-slots are mutually vertical for the purpose of guaranteeing excellent polarization isolation.
  • the thickness of the dielectric layer ranges from 1 to 20mm and is preferred to range from 4 to 10mm; a dielectric substrate 6 is arranged between the bipolar excitation microstrip lines and the ground metal layer.
  • the thickness of the dielectric substrate ranges from 0.2 to 5mm and is preferred to range from 0.5 to 2mm.
  • Front ends of the two excitation microstrip lines are linear. It is preferred that the front end of each excitation microstrip line is vertical to the cross arm "-" of one H-shaped excitation micro-slot, and the front ends pass through the middle points of the cross arms "-" of the respective H-shaped excitation micro-slots; the front ends of the two excitation microstrip lines are discretely vertical for the purposes of guaranteeing the polarization isolation of the dual-polarized antenna and leading it to be used as two independent antennas; the distance between the two discrete front ends which are not in contact ranges from 3 to 8mm; and the perpendicularity between the two discrete front ends which are not in contact is 90°.
  • the two H-shaped excitation micro-slots are identical in size, width, slot depth, slot width and shape; it is preferred that two ends of the single cross arm "-" of each H-shaped excitation micro-slot intersect with the middle points of the two vertical arms "
  • a second dielectric layer is arranged. It is preferred that the second dielectric layer is a resonant dielectric layer, particularly a resonant dielectric layer of air or a layer of other optimization resonant materials.
  • the second dielectric layer is a slot cavity used to prevent the impact among arrays during the arrayed use of the antenna; and the height of the slot cavity depends on the relevance/isolation parameters determined in the ultimate antenna applications.
  • the slot cavity is preferred to be a cavity formed above the ground metal layer by the metal support for system ground, with the depth ranging from 0.5 to 20mm; if the first and the second dielectric layers are air layers and no other radiating patches or components are arranged above the second dielectric layer, the first and the second dielectric layers are connected into a whole and the second dielectric layer serves as one part of the first dielectric layer.
  • Heights and lengths of the radiating patch, the dielectric layers and the ground metal layer are determined based on frequency band and wavelength.
  • a second metal radiating patch is arranged; it is preferred that the second metal radiating patch is identical to the first metal radiating patch in material, thickness and shape; it is preferred that the size of the second metal radiating patch is freely optimized according to the requirements for widening the frequency band; it is preferred that the size ratio of the two patches approximately equals the corresponding frequency wavelength ratio of frequency bands to be tuned or widened; and it is preferred that the second metal radiating patch is arranged above the second dielectric layer so as to separate the first dielectric layer into two areas, where the lower part is preferred to be the slot cavity and the upper part is preferred to be a first dielectric layer area between the first and the second metal radiating patches.
  • An air dielectric layer namely air dielectric layer A, is arranged, which provides an undisturbed work space height for the excitation microstrip lines interfaced with a source.
  • the work space height needs to be more than 3-10 times of the thickness of the first dielectric substrate, and a lower dielectric constant of the dielectric substrate leads to a larger multiple; it is preferred that a metal reflection ground baseplate is arranged and used for providing excellent backward radiation isolation for radiating units and providing convenient system ground for source parts, feed source parts or radiating units.
  • the invention adopts the following technical scheme:
  • the technical scheme of the invention can be optimized into the following preferred second specific design scheme on the basis of the first specific design scheme:
  • the results of the test of the small dual-polarized ( ⁇ 45 ° polarized) antenna unit of the invention show that the gain is about 8.5dBi, basically the same as the simulation result; the test chart shows that the horizontal and vertical beam widths range from 70 to 75° , and the front-to-rear ratio is above 25dB.
  • the invention adopts the surface radiation mechanism involving multiple microwave excitation and multi-layer tuning components to achieve a high element gain.
  • a conventional element antenna often achieves an element gain of 5.5dBi, while the invention achieves 8.5dBi;
  • the gain of each channel ranges from 14 to 14.5dBi, the typical dimensions are 405*420*35 m 3 , the weight is less than 5kg, and the frontal area is only 0.17m 2 .
  • These indexes are far less than those of the commonly-used antenna; the product is easy to conceal and beautify, thereby diminishing the sensitiveness of users; a derrick can be shared for shared station construction so as to reduce investment in network construction; the product is characterized by good repeatability and strong consistency, and is convenient to operate and maintain.
  • LK-TD-2814-AF Frequency range 1,880-2,025MHz Gain (dBi) 14.5 ⁇ 0.2 Electrical downtilt 0 ° HPBW Vertical plane>18 Horizontal plane>75 Polarization mode ⁇ 45 ° polarization Front-to-rear ratio >25 Co-polarization isolation (dB) >30 Cross-polarization isolation (dB) >30 Input impedance 50 ⁇ VSWR ⁇ 1.4 Port (4+1+4)-N Dimensions (mm) 405*419*34 Weight (kg) 4.8 Lightning protection DC ground Maximum anti-wind speed 200km/h Working temperature ⁇ -40 to +60 Waterproof class 5A Antenna cover material ABS
  • the antenna of the invention can be applied to any fixed or mobile equipment using microwave antennas, including but not limited to various mobile terminals, such as mobile phones, handheld TV, notebooks, GPS, devices monitoring transport vehicles or road, communication relay station, repeater station and launch pad, and is particularly suitable for application in antenna systems for base stations/distributed base stations/network optimization equipment and others in complex intensive urban areas or groups of high-rise buildings.
  • various mobile terminals such as mobile phones, handheld TV, notebooks, GPS, devices monitoring transport vehicles or road, communication relay station, repeater station and launch pad, and is particularly suitable for application in antenna systems for base stations/distributed base stations/network optimization equipment and others in complex intensive urban areas or groups of high-rise buildings.
  • Fig.1 and Fig.2 show a small microwave low-band multi-frequency high-gain dual-polarized microstrip antenna according to this embodiment (a TD-SCDMA dual-polarized antenna; TD-SCDMA frequencies of CMCC under a 3G license: 1,880-1,920 MHz and 2,010-2,025MHz), wherein a first air dielectric layer 2, a first metal radiating patch 3, a second air dielectric layer 4, a ground metal patch 5, a first dielectric substrate 6, bipolar excitation microstrip lines 7, 7', a third air dielectric layer 8 and a metal reflection baseplate 9 are sequentially arranged in an antenna cover 1 from top to bottom.
  • the first metal radiating patch 3 is connected with the antenna cover 1 through a screw 10.
  • the ground metal patch 5 covers the upper end surface of the first dielectric substrate 6, and is fixedly connected with a hollow metal support 11 which is fixed on the metal reflection baseplate 9.
  • the bipolar excitation microstrip lines 7, of which the front ends are orthogonal yet not in contact, are laid on the lower end surface of the first dielectric substrate 6.
  • Two stimulated radiation micro-slots 12, 12', orthogonal but not in contact, are formed on the upper end surface of the ground metal patch 5, and are corresponding to the front ends of the bipolar excitation microstrip lines 7, 7' in an orthogonal way.
  • the first metal radiating patch 3 is circular, and the screw 10, which is fixedly connected with the center of the first metal radiating patch 3, is also in threaded connection with the antenna cover 1 through an internal threaded hole in the center of the antenna cover.
  • the screw can be rotated outside the antenna cover for fine adjustment of the height between the first metal radiating patch and the stimulated radiation micro-slots, so that the VSWR at the I/O port of the antenna can be easily adjusted to match the impedance of the microstrip lines for a higher antenna gain.
  • the circular metal radiating patch only has height variation during adjustment, so the adjustment is more convenient.
  • the two stimulated radiation micro-slots 12, 12' on the ground metal patch 5 are equal in size and both H-shaped, of which the middle cross arms are orthogonal.
  • Such configuration helps form the bipolar stimulated radiation micro-slots on the ground metal patch with a smaller area, so as to miniaturize the antenna.
  • the included angles between the middle cross arms of the two H-shaped stimulated radiation micro-slots 12, 12' and the X/Y axis of the ground metal patch are ⁇ 45°.
  • Such a technical scheme also helps form the bipolar stimulated radiation micro-slots on the ground metal patch with a smaller area, so as to miniaturize the antenna.
  • Fig.4 shows the measured reflection coefficient curves of the antenna, in which S11 is the reflection coefficient of Port 1, and S22 is that of Port 2.
  • S11 is the reflection coefficient of Port 1
  • S22 is that of Port 2.
  • the figure also shows the measured curve of isolation between the two ports of the dual-polarized antenna, in which the isolation between Port 1 and Port 2 (S21(S12)) is below -32dB within the bandwidth range. According to test results, the two ports of the dual-polarized antenna are satisfactorily isolated from each other and thus can work independently.
  • the antenna gain is 8.9dBi at a test frequency of 1,900MHz, and the theta-plane HPBW is 83°.
  • Fig.3 shows a small microwave low-band multi-frequency high-gain dual-polarized microstrip antenna according to this embodiment (coverage: TD-SCDMA and TD-LITE frequencies; WCDMA frequencies: 1,920-1,980 MHz and 2,110-2,170 MHz; TD-SCDMA frequencies: 1,880-1,920 MHz and 2,010-2,025 MHz), which is based on Embodiment 1 and further includes a second metal radiating patch 13 and a second dielectric substrate 14 in the second air dielectric layer 4.
  • the lower end surface of the second metal radiating patch 13 is jointed with the upper end surface of the second dielectric substrate 14 to form as a whole, which is then fixedly connected with the hollow metal support 11 fixed on the metal reflection baseplate 9 to form a fourth air dielectric layer 15 below the second dielectric substrate 14.
  • This configuration helps further enlarge the working frequency bandwidth of the antenna.
  • the second metal radiating patch 13 is circular, so that the VSWR at the I/O port of the antenna can be easily adjusted to match the impedance of the microstrip lines for a higher antenna gain.
  • Fig.5 shows the measured reflection coefficient curves of the antenna, in which the reflection coefficients of the two dual polarization ports within the TD-SCDMA and WCDMA frequencies are both below -17dB, with the bandwidth indexes all qualified. Due to the additional second radiating patch, the working frequency bandwidth of the antenna is effectively enlarged without changing the bandwidth effect and performance indexes of the original structure with only one radiating patch (relative bandwidth: 22.5%).
  • the figure also shows the measured curve of isolation between the two ports of the dual-polarized antenna, in which the isolation is below -32dB within the bandwidth range. According to test results, the two ports of the dual-polarized antenna are satisfactorily isolated from each other and thus can work independently.
  • the second metal radiating patch and a dielectric substrate holder are arranged in the second air dielectric layer.
  • the second metal radiating patch is fixed on the dielectric substrate holder, which is fixed on the hollow metal support to form the fourth air dielectric layer below the second metal radiating patch.
  • the technical scheme also helps further enlarge the working frequency bandwidth of the antenna.
  • Fig.6 shows a small dual-polarized microstrip antenna with three metal radiating patches based on Embodiment 2, in which a third metal radiating patch 18 and a third dielectric substrate 17 are further arranged between the second metal radiating patch 13 and the first metal radiating patch 3.
  • the third metal radiating patch 18 is parallel to the first metal radiating patch 3 and insulated from the second metal radiating patch 13 and the hollow metal support 11.
  • the lower end surface of the third metal radiating patch 18 is jointed with the upper end surface of the third dielectric substrate 17 to form as a whole, which is then fixedly connected with an insulation support 19 fixed on the second dielectric substrate 14 to form a fifth air dielectric layer 16 below the third dielectric substrate 17.
  • Test results prove that the working bandwidth of the antenna according to Embodiment 3 is further enlarged without changes of the original electric performance indexes of the antenna according to Embodiment 2 (relative bandwidth: about 40%).
  • the third metal radiating patch which is parallel to the first metal radiating patch, is arranged between the second metal radiating patch and the first metal radiating patch and insulated from the second metal radiating patch and the hollow metal support, and the fifth air dielectric layer is formed between the third metal radiating patch and the second metal radiating patch.
  • Such a technical scheme also helps further enlarge the working frequency bandwidth of the antenna.
  • This embodiment discloses a small multi-layer microstrip antenna with convenient VSWR adjustment, which is characterized in that a first air dielectric layers, a first metal radiating patch, a second air dielectric layer, a ground metal patch, a first dielectric substrate, excitation microstrip lines, a third air dielectric layer and a metal reflection baseplate are sequentially arranged in an antenna cover from top to bottom, the ground metal patch covers the upper end surface of the first dielectric substrate and is fixedly connected with a hollow metal support fixed on the metal reflection baseplate, stimulated radiation micro-slots are formed on the upper end surface of the ground metal patch, and the first metal radiating patch is circular and fixed by the threaded connection between an adjusting screw fixed in its center and the internal threads in the center of the antenna cover.
  • the screw can be rotated outside the antenna cover for fine adjustment of the height between the first metal radiating patch and the stimulated radiation micro-slots, so that the VSWR at the I/O port of the antenna can be easily adjusted to match the impedance of the excitation microstrip lines for a higher antenna gain.
  • the circular first metal radiating patch only has one variable in the adjustment, which makes the adjustment very convenient and fast and therefore greatly improves the productivity.
  • the dual-polarized microstrip antenna and the multi-layer radiation structure are designed in a relatively small space, of which the layout is smart and the structure is compact. It has been proved in practice that the relative working frequency bandwidth of the antenna provided by the utility model can exceed 20%, with a gain increase of 9dBi and a dual polarization cross-isolation as high as 30dB; a pair of dual-polarized antenna units are sufficient for a 2x2 MIMO system; and with a small volume and a light weight, the antenna is less demanding in installation space and load bearing and more convenient to manufacture, install and maintain, and can be easily arrayed and effectively save the installation and maintenance costs. Therefore, the antenna can be widely applied in mobile communication and Internet technologies.
  • Fig.1 and Fig.2 show the specific design of the small multi-layer microstrip antenna with convenient VSWR adjustment according to this embodiment.
  • a first air dielectric layer 2, a first metal radiating patch 3, a second air dielectric layer 4, a ground metal patch 5, a first dielectric substrate 6, excitation microstrip lines 7, 7' (bipolar excitation microstrip lines according to this embodiment), a third air dielectric layer 8 and a metal reflection baseplate 9 are sequentially arranged in an antenna cover 1 from top to bottom.
  • the first metal radiating patch 3 is connected with the antenna cover 1 through a screw 10.
  • the ground metal patch 5 covers the upper end surface of the first dielectric substrate 6, and is fixedly connected with a hollow metal support 11 which is fixed on the metal reflection baseplate 9.
  • Two stimulated radiation micro-slots 12, 12' are formed on the upper end surface of the ground metal patch 5.
  • the first metal radiating patch 3 is circular and fixed by the threaded connection between an adjusting screw 10 fixed in its center and the internal threads in the center of the antenna cover 1.
  • the bipolar excitation microstrip lines 7, of which the front ends are orthogonal yet not in contact, are laid on the lower end surface of the first dielectric substrate 6.
  • the two stimulated radiation micro-slots 12, 12', orthogonal but not in contact are formed on the upper end surface of the ground metal patch 5, and are corresponding to the front ends of the bipolar excitation microstrip lines 7, 7' in an orthogonal way.
  • the two stimulated radiation micro-slots 12, 12' on the ground metal patch 5 are equal in size and both H-shaped, of which the middle cross arms are orthogonal.
  • Such configuration helps form the bipolar stimulated radiation micro-slots on the ground metal patch with a smaller area, so as to miniaturize the antenna.
  • the included angles between the middle cross arms of the two H-shaped stimulated radiation micro-slots 12, 12' and the X/Y axis of the ground metal patch are ⁇ 45°. With this technical scheme, the effective area of the ground metal patch can be more fully used for miniaturization of the antenna.
  • Fig.3 shows a small multi-layer microstrip antenna with convenient VSWR adjustment according to this embodiment, which is based on Embodiment 4 and further includes a second metal radiating patch 13 and a second dielectric substrate 14 in the second air dielectric layer 4.
  • the lower end surface of the second metal radiating patch 13 is jointed with the upper end surface of the second dielectric substrate14 to form as a whole, which is then fixedly connected with the hollow metal support 11 fixed on the metal reflection baseplate 9 so as to form a fourth air dielectric layer 15 below the second dielectric substrate14.
  • the technical scheme helps further enlarge the working frequency bandwidth of the antenna.
  • the second metal radiating patch 13 is circular, so that the VSWR at the I/O port of the antenna can be easily adjusted to match the impedance of the excitation microstrip lines for a higher antenna gain.
  • the second metal radiating patch and a dielectric substrate holder are arranged in the second air dielectric layer, the second metal radiating patch is fixed on the dielectric substrate holder, and the dielectric substrate holder is fixed on the hollow metal support to form the fourth air dielectric layer below the second metal radiating patch.
  • the technical scheme also helps further enlarge the working frequency bandwidth of the antenna.
  • a wireless communication relay station with a built-in antenna includes a relay station main case and the antenna matched therewith, and is characterized by further including an arc-shaped upper cover of the relay station, in which the antenna is arranged in the arc-shaped upper cover of the relay station and fixedly connected therewith through screws, the input port of the antenna is directly connected with the retransmission end of the relay station, and the arc-shaped upper cover of the relay station is fixedly connected with the relay station main case through screws.
  • the wireless communication relay station with the built-in antenna includes the relay station main case and the antenna matched therewith, and is characterized by further including the arc-shaped upper cover of the relay station, in which the antenna is arranged in the arc-shaped upper cover of the relay station and fixedly connected therewith through screws, the input port of the antenna is directly connected with the retransmission end of the relay station, and the arc-shaped upper cover of the relay station is fixedly connected with the relay station main case through screws.
  • the antenna in this embodiment is a multi-layer microstrip antenna, particularly, a small multi-layer dual-polarized microstrip antenna.
  • the antenna in this embodiment is a ceiling-mounted antenna.
  • This embodiment has the following benefits: the antenna is placed in the main case of the wireless communication relay station to achieve compact structure, fewer connecting cables, low cost and convenient installation; the wireless communication relay station with the built-in antenna is suitable for wireless communication indoor distribution systems, featuring an attractive appearance as well as good transmission performance and high reliability of the antenna.
  • a miniature dual-polarized microstrip antenna is characterized by including two dual-polarized antenna units which are connected in an antenna cover through a two-way power divider.
  • a first air dielectric layer, a first metal radiating patch, a second air dielectric layer, a ground metal patch, a first dielectric substrate, bipolar excitation microstrip lines, a third air dielectric layer and a metal reflection baseplate are sequentially arranged from top to bottom in each dual-polarized antenna unit.
  • the first metal radiating patch is connected with the antenna cover through an insulation screw.
  • the ground metal patch covers the upper end surface of the first dielectric substrate, and is fixedly connected with a hollow metal support which is fixed on the metal reflection baseplate.
  • the bipolar excitation microstrip lines of which the front ends are orthogonal yet not in contact, are arranged on the lower end surface of the first dielectric substrate.
  • This embodiment has the following benefits: it achieves the advantages of small volume, compact structure and light weight by integrating microstrip, micro-slot and the multi-layer theory; the antenna has good energy radiation performance and high reliability; with the linear arrangement and a planar emission source, microwave harnesses have better direction selectivity; with the two antenna units, the dual-polarized antenna attains a qualified gain of 11dBi; microstrip routing inside the antenna helps reduce the consumption of connecting cables and the cost; and the antenna is more convenient to install due to its small volume and light weight. According to tests, the miniature dual-polarized microstrip antenna is totally qualified for operators' relevant requirements on electrical and mechanical performance indexes.
  • a miniature dual-polarized microstrip antenna includes two dual-polarized antenna units (B1, B2) which are connected in an antenna cover 1 through a two-way power divider (Wilkinson equal power divider).
  • a first air dielectric layer 2 As shown in Fig.2 , a first air dielectric layer 2, a first metal radiating patch 3, a second air dielectric layer 4, a ground metal patch 5, a first dielectric substrate 6, bipolar excitation microstrip lines 7, 7' , a third air dielectric layer 8 and a metal reflection baseplate 9 are sequentially arranged from top to bottom in each dual-polarized antenna unit (B1, for example).
  • the first metal radiating patch 3 is connected with the antenna cover 1 through an insulation screw 10.
  • the ground metal patch 5 covers the upper end surface of the first dielectric substrate 6, and is fixedly connected with a hollow metal support 11 which is fixed on the metal reflection baseplate 9.
  • the bipolar excitation microstrip lines 7, 7' are arranged on the lower end surface of the first dielectric substrate 6.
  • Two stimulated radiation micro-slots 12, 12' orthogonal but not in contact, are formed on the upper end surface of the ground metal patch, and are corresponding to the front ends of the bipolar excitation microstrip lines 7, 7' in an orthogonal way.
  • the first metal radiating patch 3 is circular, and the insulation screw 10, which is fixedly connected with the center of the first metal radiating patch 3, is also in threaded connection with the antenna cover 1 through an internal threaded hole in the center of the antenna cover 1.
  • the screw can be rotated outside the antenna cover for fine adjustment of the height between the first metal radiating patch and the stimulated radiation micro-slots, so that the VSWR at the I/O port of the antenna can be easily adjusted to match the impedance of the microstrip lines for a higher antenna gain.
  • the circular metal radiating patch only has height variations during adjustment, so the adjustment is more convenient.
  • the two stimulated radiation micro-slots 12, 12' on the ground metal patch 5 are equal in size and both H-shaped, of which the middle cross arms are orthogonal.
  • Such a technical scheme helps form the bipolar stimulated radiation micro-slots on the ground metal patch with a smaller area, so as to miniaturize the antenna.
  • the included angles between the middle cross arms of the two H-shaped stimulated radiation micro-slots 12, 12' and the X/Y axis of the ground metal patch are ⁇ 45°.
  • Such a technical scheme also helps form the bipolar stimulated radiation micro-slots on the ground metal patch with a smaller area, so as to miniaturize the antenna.
  • the gain of the dual-polarized antenna is 11dBi at a test frequency of 1,900MHz; the horizontal HPBW is 72°, the vertical HPBW is 36°, and the front-to-rear ratio is below -25dB; the VSWR at the I/O port is below 1.3, and the relative working frequency bandwidth is around 10%.
  • Fig.9 shows a miniature dual-polarized microstrip antenna which is based on Embodiment 7 and further includes a second metal radiating patch 13 and a second dielectric substrate 14 in the second air dielectric layer 4.
  • the second metal radiating patch 13 is parallel to the first metal radiating patch 3.
  • the lower end surface of the second metal radiating patch 13 is jointed with the upper end surface of the second dielectric substrate 14 to form as a whole, which is then fixedly connected with the hollow metal support 11 fixed on the metal reflection baseplate 9 to form a fourth air dielectric layer 15 below the second dielectric substrate 14.
  • This technical scheme helps further enlarge the working frequency bandwidth of the antenna.
  • the second metal radiating patch 13 is circular, so that the VSWR at the I/O port of the antenna can be easily adjusted to match the impedance of the microstrip lines for a higher antenna gain.
  • Embodiment 8 can enlarge the working bandwidth without changing the original electric performance indexes of the antenna according to Embodiment 7 (relative bandwidth: about 25%).
  • each dual-polarized antenna unit further includes a second metal radiating patch in the second air dielectric layer and parallel to the first metal radiating patch.
  • the second metal radiating patch is fixed with the hollow metal support in an insulated manner, so that a fourth air dielectric layer is formed between the second metal radiating patch and the ground metal patch.
  • the technical scheme also helps further enlarge the working frequency bandwidth of the antenna, though less remarkably without the second dielectric substrate.
  • Fig.10 shows a miniature dual-polarized microstrip antenna based on Embodiment 8, in which a third metal radiating patch 18 and a third dielectric substrate 17 are further arranged between the second metal radiating patch 13 and the first metal radiating patch 3.
  • the third metal radiating patch 18 is parallel to the first metal radiating patch 3 and insulated from the second metal radiating patch 13 and the hollow metal support 11.
  • the lower end surface of the third metal radiating patch 18 is jointed with the upper end surface of the third dielectric substrate 17 to form as a whole, which is then fixedly connected with an insulation support 19 fixed on the second dielectric substrate 14 to form a fifth air dielectric layer 16 below the third dielectric substrate 17.
  • Embodiment 9 can further enlarge the working bandwidth without changing the original electric performance indexes of the antenna according to Embodiment 8 (relative bandwidth: about 40%).
  • the third metal radiating patch is located between the second radiating patch and the first radiating patch and parallel to the first radiating patch, and is insulated from the second metal radiating patch and the hollow metal support.
  • a fifth air dielectric layer is formed between the third metal radiating patch and the second metal radiating patch.
  • a small dual-polarized microstrip antenna is characterized by including four dual-polarized antenna units which are connected through a four-way power divider and linearly distributed in an antenna cover.
  • a first air dielectric layer, a first metal radiating patch, a second air dielectric layer, a ground metal patch, a first dielectric substrate, bipolar excitation microstrip lines, a third air dielectric layer and a metal reflection baseplate are sequentially arranged from top to bottom in each dual-polarized antenna unit.
  • the first metal radiating patch is connected with the antenna cover through an insulation screw.
  • the ground metal patch covers the upper end surface of the first dielectric substrate, and is fixedly connected with a hollow metal support which is fixed on the metal reflection baseplate.
  • the bipolar excitation microstrip lines of which the front ends are orthogonal yet not in contact, are arranged on the lower end surface of the first dielectric substrate.
  • This embodiment has the following benefits: it achieves the advantages of small volume, compact structure and light weight by integrating microstrip, micro-slot and the multi-layer theory; the antenna has good energy radiation performance and high reliability; with the linear arrangement and a planar emission source, microwave harnesses have better direction selectivity; with the four antenna units, the dual-polarized antenna attains a qualified gain of 14dBi; microstrip routing inside the antenna helps reduce the consumption of connecting cables and the cost; and the antenna is more convenient to install due to its small volume and light weight. According to tests, the small dual-polarized microstrip antenna is totally qualified for operators' relevant requirements on electrical and mechanical performance indexes.
  • a small dual-polarized microstrip antenna includes four dual-polarized antenna units (B1, B2, B3, B4) which are connected through a four-way power divider (series connection of three Wilkinson equal power divider) and linearly distributed in an antenna cover 1.
  • a first air dielectric layer 2 a first metal radiating patch 3
  • a second air dielectric layer 4 a ground metal patch 5
  • a first dielectric substrate 6 bipolar excitation microstrip lines 7, 7'
  • a third air dielectric layer 8 and a metal reflection baseplate 9 are sequentially arranged from top to bottom in each dual-polarized antenna unit (B1, for example).
  • the first metal radiating patch 3 is connected with the antenna cover 1 through an insulation screw 10.
  • the ground metal patch 5 covers the upper end surface of the first dielectric substrate 6, and is fixedly connected with a hollow metal support 11 which is fixed on the metal reflection baseplate 9.
  • the bipolar excitation microstrip lines 7, 7' are arranged on the lower end surface of the first dielectric substrate 6.
  • Two stimulated radiation micro-slots 12, 12' orthogonal but not in contact, are formed on the upper end surface of the ground metal patch, and are corresponding to the front ends of the bipolar excitation microstrip lines 7, 7' in an orthogonal way.
  • the first metal radiating patch 3 is circular, and the insulation screw 10, which is fixedly connected with the center of the first metal radiating patch 3, is also in threaded connection with the antenna cover 1 through an internal threaded hole in the center of the antenna cover 1.
  • the screw can be rotated outside the antenna cover for fine adjustment of the height between the first metal radiating patch and the stimulated radiation micro-slots, so that the VSWR at the I/O port of the antenna can be easily adjusted to match the impedance of the microstrip lines for a higher antenna gain.
  • the circular metal radiating patch only has height variations during adjustment, so the adjustment is more convenient.
  • the two stimulated radiation micro-slots 12, 12' on the ground metal patch 5 are equal in size and both H-shaped, of which the middle cross arms are orthogonal.
  • Such a technical scheme helps form the bipolar stimulated radiation micro-slots on the ground metal patch with a smaller area, so as to miniaturize the antenna.
  • the included angles between the middle cross arms of the two H-shaped stimulated radiation micro-slots 12, 12' and the X/Y axis of the ground metal patch are ⁇ 45°.
  • Such a technical scheme also helps form the bipolar stimulated radiation micro-slots on the ground metal patch with a smaller area, so as to miniaturize the antenna.
  • the gain of the dual-polarized antenna is 14dBi at a test frequency of 1,900MHz; the horizontal HPBW is 70°, the vertical HPBW is 18°, and the front-to-rear ratio is below -25dB; the VSWR at the I/O port is below 1.3, and the relative working frequency bandwidth is around 10%.
  • Fig.13 shows a small dual-polarized microstrip antenna which is based on Embodiment 10 and further includes a second metal radiating patch 13 and a second dielectric substrate 14 in the second air dielectric layer 4.
  • the second metal radiating patch 13 is parallel to the first metal radiating patch 3.
  • the lower end surface of the second metal radiating patch 13 is jointed with the upper end surface of the second dielectric substrate 14 to form as a whole, which is then fixedly connected with the hollow metal support 11 fixed on the metal reflection baseplate 9 to form a fourth air dielectric layer 15 below the second dielectric substrate 14.
  • This technical scheme helps further enlarge the working frequency bandwidth of the antenna.
  • the second metal radiating patch 13 is circular, so that the VSWR at the I/O port of the antenna can be easily adjusted to match the impedance of the microstrip lines for a higher antenna gain.
  • Embodiment 11 can enlarge the working bandwidth without changing the original electric performance indexes of the antenna according to Embodiment 10 (relative bandwidth: about 25%).
  • each dual-polarized antenna unit further includes a second metal radiating patch in the second air dielectric layer and parallel to the first metal radiating patch.
  • the second metal radiating patch is fixed with the hollow metal support in an insulated manner, so that a fourth air dielectric layer is formed between the second metal radiating patch and the ground metal patch.
  • the technical scheme also helps further enlarge the working frequency bandwidth of the antenna, though less remarkably without the second dielectric substrate.
  • Fig.14 shows a small dual-polarized microstrip antenna based on Embodiment 11, in which a third metal radiating patch 18 and a third dielectric substrate 17 are further arranged between the second metal radiating patch 13 and the first metal radiating patch 3.
  • the third metal radiating patch 18 is parallel to the first metal radiating patch 3 and insulated from the second metal radiating patch 13 and the hollow metal support 11.
  • the lower end surface of the third metal radiating patch 18 is jointed with the upper end surface of the third dielectric substrate 17 to form as a whole, which is then fixedly connected with an insulation support 19 fixed on the second dielectric substrate 14 to form a fifth air dielectric layer 16 below the third dielectric substrate 17.
  • Embodiment 12 can further enlarge the working bandwidth without changing the original electric performance indexes of the antenna according to Embodiment 11 (relative bandwidth: about 40%).
  • the third metal radiating patch is located between the second radiating patch and the first radiating patch and parallel to the first radiating patch, and is insulated from the second metal radiating patch and the hollow metal support.
  • a fifth air dielectric layer is formed between the third metal radiating patch and the second metal radiating patch.
  • a small high-gain dual-polarized microstrip antenna is characterized by including four dual-polarized antenna units which are connected through a four-way signal power divider and distributed in an antenna cover in two lines and two rows.
  • a first air dielectric layer, a first metal radiating patch, a second air dielectric layer, a ground metal patch, a first dielectric substrate, bipolar excitation microstrip lines, a third air dielectric layer and a metal reflection baseplate are sequentially arranged from top to bottom in each dual-polarized antenna unit.
  • the first metal radiating patch is connected with the antenna cover through an insulation screw.
  • the ground metal patch covers the upper end surface of the first dielectric substrate, and is fixedly connected with a hollow metal support which is fixed on the metal reflection baseplate.
  • the bipolar excitation microstrip lines of which the front ends are orthogonal yet not in contact, are arranged on the lower end surface of the first dielectric substrate.
  • This embodiment has the following benefits: it achieves the advantages of small volume, compact structure and light weight by integrating microstrip, micro-slot and the multi-layer theory; the antenna has good energy radiation performance and high gain and reliability; with the linear arrangement and a planar emission source, microwave harnesses have better direction selectivity; with the four antenna units, the dual-polarized antenna attains a qualified gain of 14dBi; microstrip routing inside the antenna helps reduce the consumption of connecting cables and the cost; and the antenna is more convenient to install due to its small volume and light weight. According to tests, the small high-gain dual-polarized microstrip antenna is totally qualified for operators' relevant requirements on electrical and mechanical performance indexes.
  • a small high-gain dual-polarized microstrip antenna includes four dual-polarized antenna units (B1, B2, B3, B4) which are connected in an antenna cover 1 through a four-way power divider (dendriform series connection of three Wilkinson equal power divider, namely, one to two, and two to four).
  • a first air dielectric layer 2 As shown in Fig.2 , a first air dielectric layer 2, a first metal radiating patch 3, a second air dielectric layer 4, a ground metal patch 5, a first dielectric substrate 6, bipolar excitation microstrip lines 7, 7' , a third air dielectric layer 8 and a metal reflection baseplate 9 are sequentially arranged from top to bottom in each dual-polarized antenna unit (B1, for example).
  • the first metal radiating patch 3 is connected with the antenna cover 1 through an insulation screw 10.
  • the ground metal patch 5 covers the upper end surface of the first dielectric substrate 6, and is fixedly connected with a hollow metal support 11 which is fixed on the metal reflection baseplate 9.
  • the bipolar excitation microstrip lines 7, 7' are arranged on the lower end surface of the first dielectric substrate 6.
  • Two stimulated radiation micro-slots 12, 12' orthogonal but not in contact, are formed on the upper end surface of the ground metal patch, and are corresponding to the front ends of the bipolar excitation microstrip lines 7, 7' in an orthogonal way.
  • the first metal radiating patch 3 is circular, and the insulation screw 10, which is fixedly connected with the center of the first metal radiating patch 3, is also in threaded connection with the antenna cover 1 through an internal threaded hole in the center of the antenna cover 1.
  • the screw can be rotated outside the antenna cover for fine adjustment of the height between the first metal radiating patch and the stimulated radiation micro-slots, so that the VSWR at the I/O port of the antenna can be easily adjusted to match the impedance of the microstrip lines for a higher antenna gain.
  • the circular metal radiating patch only has height variations during adjustment, so the adjustment is more convenient.
  • the two stimulated radiation micro-slots 12, 12' on the ground metal patch 5 are equal in size and both H-shaped, of which the middle cross arms are orthogonal.
  • Such a technical scheme helps form the bipolar stimulated radiation micro-slots on the ground metal patch with a smaller area, so as to miniaturize the antenna.
  • the included angles between the middle cross arms of the two H-shaped stimulated radiation micro-slots 12, 12' and the X/Y axis of the ground metal patch are ⁇ 45°.
  • Such a technical scheme also helps form the bipolar stimulated radiation micro-slots on the ground metal patch with a smaller area, so as to miniaturize the antenna.
  • the gain of the dual-polarized antenna is 14dBi at a test frequency of 1,900MHz; the horizontal HPBW is 70°, the vertical HPBW is 18°, and the front-to-rear ratio is below -25dB; the VSWR at the I/O port is below 1.3, and the relative working frequency bandwidth is around 10%.
  • a small high-gain dual-polarized microstrip antenna is characterized by including eight dual-polarized antenna units which are connected in an antenna cover through an eight-way signal power divider.
  • a first air dielectric layer, a first metal radiating patch, a second air dielectric layer, a ground metal patch, a first dielectric substrate, bipolar excitation microstrip lines, a third air dielectric layer and a metal reflection baseplate are sequentially arranged from top to bottom in each dual-polarized antenna unit.
  • the first metal radiating patch is connected with the antenna cover through an insulation screw.
  • the ground metal patch covers the upper end surface of the first dielectric substrate, and is fixedly connected with a hollow metal support which is fixed on the metal reflection baseplate.
  • the bipolar excitation microstrip lines of which the front ends are orthogonal yet not in contact, are arranged on the lower end surface of the first dielectric substrate.
  • This embodiment has the following benefits: it achieves the advantages of small volume, compact structure and light weight by integrating microstrip, micro-slot and the multi-layer theory; the antenna has good energy radiation performance and high gain and reliability; with the linear arrangement and a planar emission source, microwave harnesses have better direction selectivity; with the eight antenna units, the dual-polarized antenna attains a qualified gain of 17dBi; microstrip routing inside the antenna helps reduce the consumption of connecting cables and the cost; and the antenna is more convenient to install due to its small volume and light weight. According to tests, the small high-gain dual-polarized microstrip antenna is totally qualified for operators' relevant requirements on electrical and mechanical performance indexes.
  • a small high-gain dual-polarized microstrip antenna includes eight dual-polarized antenna units (B1, B2, B3, B4, B5, B6, B7, B8) which are connected in an antenna cover 1 through an eight-way power divider (dendriform series connection of seven Wilkinson equal power divider, namely, one to two, two to four, and four to eight).
  • a first air dielectric layer 2 As shown in Fig.2 , a first air dielectric layer 2, a first metal radiating patch 3, a second air dielectric layer 4, a ground metal patch 5, a first dielectric substrate 6, bipolar excitation microstrip lines 7, 7' , a third air dielectric layer 8 and a metal reflection baseplate 9 are sequentially arranged from top to bottom in each dual-polarized antenna unit (B1, for example).
  • the first metal radiating patch 3 is connected with the antenna cover 1 through an insulation screw 10.
  • the ground metal patch 5 covers the upper end surface of the first dielectric substrate 6, and is fixedly connected with a hollow metal support 11 which is fixed on the metal reflection baseplate 9.
  • the bipolar excitation microstrip lines 7, 7' are arranged on the lower end surface of the first dielectric substrate 6.
  • Two stimulated radiation micro-slots 12, 12' orthogonal but not in contact, are formed on the upper end surface of the ground metal patch, and are corresponding to the front ends of the bipolar excitation microstrip lines 7, 7' in an orthogonal way.
  • the first metal radiating patch 3 is circular, and the insulation screw 10, which is fixedly connected with the center of the first metal radiating patch 3, is also in threaded connection with the antenna cover 1 through an internal threaded hole in the center of the antenna cover 1.
  • the screw can be rotated outside the antenna cover for fine adjustment of the height between the first metal radiating patch and the stimulated radiation micro-slots, so that the VSWR at the I/O port of the antenna can be easily adjusted to match the impedance of the microstrip lines for a higher antenna gain.
  • the circular metal radiating patch only has height variations during adjustment, so the adjustment is more convenient.
  • the two stimulated radiation micro-slots 12, 12' on the ground metal patch 5 are equal in size and both H-shaped, of which the middle cross arms are orthogonal.
  • Such a technical scheme helps form the bipolar stimulated radiation micro-slots on the ground metal patch with a smaller area, so as to miniaturize the antenna.
  • the included angles between the middle cross arms of the two H-shaped stimulated radiation micro-slots 12, 12' and the X/Y axis of the ground metal patch are ⁇ 45°.
  • Such a technical scheme also helps form the bipolar stimulated radiation micro-slots on the ground metal patch with a smaller area, so as to miniaturize the antenna.
  • the gain of the dual-polarized antenna is 17dBi at a test frequency of 1,900MHz; the horizontal HPBW is 70°, the vertical HPBW is 18°, and the front-to-rear ratio is below -25dB; the VSWR at the I/O port is below 1.3, and the relative working frequency bandwidth is around 10%.
  • an eight-channel high-isolation dual-polarized smart array antenna includes four independent dual-polarized antenna in an antenna cover, and is characterized in that: each dual-polarized antenna includes two dual-polarized antenna units connected through a two-way power divider; a first air dielectric layer, a first metal radiating patch, a second air dielectric layer, a ground metal patch, a first dielectric substrate, bipolar excitation microstrip lines, a third air dielectric layer and a metal reflection baseplate are sequentially arranged from top to bottom in each dual-polarized antenna unit; the first metal radiating patch is connected with the antenna cover through an insulation screw; the ground metal patch covers the upper end surface of the first dielectric substrate, and is fixedly connected with a hollow metal support which is fixed on the metal reflection baseplate; the bipolar excitation microstrip lines, of which the front ends are orthogonal yet not in contact, are arranged on the lower end surface of the first dielectric substrate; and two stimulated radiation micro-slots, orthogonal
  • This embodiment has the following benefits: it achieves the advantages of small volume, compact structure and light weight by integrating microstrip, micro-slot and the multi-layer theory; the antenna has good energy radiation performance and high reliability; with the linear arrangement and a planar emission source, microwave harnesses have better direction selectivity; with the two antenna units in each dual-polarized antenna, the gain can reach 11dBi, which is qualified for small areas with a high user density, such as urban residential communities, commercial buildings, etc; microstrip routing inside the antenna helps reduce the consumption of connecting cables and the cost; and the antenna is more convenient to install due to its small volume and light weight - it can be directly installed on the conventional 3G smart antenna installation support without a holder, thus greatly reducing the installation input and the expense for future maintenance.
  • the eight-channel high-isolation dual-polarized smart array antenna is suitable for small areas with a high user density, such as urban residential communities, commercial buildings, etc., and is tested as totally qualified for operators' relevant requirements on electrical and mechanical performance indexes.
  • the antenna units with a high unit gain form an antenna array, which makes the antenna much smaller and lighter without changing the original performance indexes, that is, the antenna is miniaturized. It can replace 3G antennas in the market and will strongly challenge 4G antennas.
  • the miniaturized antenna according to the utility model may be applied in residential communities, so as to eliminate and mitigate the concerns of nearby residents that large antennas are harmful because of radiation.
  • An eight-channel high-isolation dual-polarized smart array antenna includes four independent dual-polarized antenna (A1, A2, A3, A4) in an antenna cover 1.
  • Each dual-polarized antenna (A2, for example) includes two dual-polarized antenna units (B1, B2) which are connected through a two-way power divider (Wilkinson equal power divider).
  • a first air dielectric layer 2 As shown in Fig.2 , a first air dielectric layer 2, a first metal radiating patch 3, a second air dielectric layer 4, a ground metal patch 5, a first dielectric substrate 6, bipolar excitation microstrip lines 7, 7' , a third air dielectric layer 8 and a metal reflection baseplate 9 are sequentially arranged from top to bottom in each dual-polarized antenna unit (B1, for example).
  • the first metal radiating patch 3 is connected with the antenna cover 1 through an insulation screw 10.
  • the ground metal patch 5 covers the upper end surface of the first dielectric substrate 6, and is fixedly connected with a hollow metal support 11 which is fixed on the metal reflection baseplate 9.
  • the bipolar excitation microstrip lines 7, 7' are arranged on the lower end surface of the first dielectric substrate 6.
  • Two stimulated radiation micro-slots 12, 12' orthogonal but not in contact, are formed on the upper end surface of the ground metal patch, and are corresponding to the front ends of the bipolar excitation microstrip lines 7, 7' in an orthogonal way.
  • the first metal radiating patch 3 is circular, and the insulation screw 10, which is fixedly connected with the center of the first metal radiating patch 3, is also in threaded connection with the antenna cover 1 through an internal threaded hole in the center of the antenna cover 1.
  • the screw can be rotated outside the antenna cover for fine adjustment of the height between the first metal radiating patch and the stimulated radiation micro-slots, so that the VSWR at the I/O port of the antenna can be easily adjusted to match the impedance of the microstrip lines for a higher antenna gain.
  • the circular metal radiating patch only has height variations during adjustment, so the adjustment is more convenient.
  • the two stimulated radiation micro-slots 12, 12' on the ground metal patch 5 are equal in size and both H-shaped, of which the middle cross arms are orthogonal.
  • Such a technical scheme helps form the bipolar stimulated radiation micro-slots on the ground metal patch with a smaller area, so as to miniaturize the antenna.
  • the included angles between the middle cross arms of the two H-shaped stimulated radiation micro-slots 12, 12' and the X/Y axis of the ground metal patch are ⁇ 45°.
  • Such a technical scheme also helps form the bipolar stimulated radiation micro-slots on the ground metal patch with a smaller area, so as to miniaturize the antenna.
  • the two ports of the dual-polarized antenna are satisfactorily isolated from each other (isolation > 30dB) and thus can work independently;
  • the antenna gain is 11dBi at a test frequency of 1,900MHz;
  • the horizontal HPBW is 72°, the vertical HPBW is 36°, and the front-to-rear ratio is below -25dB;
  • the VSWR at the I/O port is below 1.3, and the relative working frequency bandwidth is around 10%.
  • an eight-channel high-gain high-isolation dual-polarized smart array antenna includes four independent dual-polarized antenna in an antenna cover, and is characterized in that: each dual-polarized antenna includes four dual-polarized antenna units connected through a four-way power divider; a first air dielectric layer, a first metal radiating patch, a second air dielectric layer, a ground metal patch, a first dielectric substrate, bipolar excitation microstrip lines, a third air dielectric layer and a metal reflection baseplate are sequentially arranged from top to bottom in each dual-polarized antenna unit; the first metal radiating patch is connected with the antenna cover through an insulation screw; the ground metal patch covers the upper end surface of the first dielectric substrate, and is fixedly connected with a hollow metal support which is fixed on the metal reflection baseplate; the bipolar excitation microstrip lines, of which the front ends are orthogonal yet not in contact, are arranged on the lower end surface of the first dielectric substrate; and two stimulated radiation micro-slots,
  • This embodiment has the following benefits: it achieves the advantages of small volume, compact structure and light weight by integrating microstrip, micro-slot and the multi-layer theory; the antenna has good energy radiation performance and high reliability; with the linear arrangement and a planar emission source, microwave harnesses have better direction selectivity; with the four antenna units in each dual-polarized antenna, the gain can reach 14dBi, which meets the coverage requirement of mobile communication base stations and solves the signal coverage in urban, suburban and rural areas with different landscapes, numbers of users, occasions and ranges; microstrip routing inside the antenna helps reduce the consumption of connecting cables and the cost; and the antenna is more convenient to install due to its small volume and light weight - it can be directly installed on the conventional 3G smart antenna installation support without a holder, thus greatly reducing the installation input and the expense for future maintenance.
  • the eight-channel high-isolation dual-polarized smart array antenna is suitable for the establishment of mobile communication base stations, and is tested as totally qualified for operators' relevant requirements on electrical and mechanical performance indexes.
  • the antenna units with a high unit gain form an antenna array, which makes the antenna much smaller and lighter without changing the original performance indexes, that is, the antenna is miniaturized. It can replace 3G antennas in the market and will strongly challenge 4G antennas.
  • An eight-channel high-gain high-isolation dual-polarized smart array antenna includes four independent dual-polarized antenna (A1, A2, A3, A4) in an antenna cover 1.
  • Each dual-polarized antenna (A2, for example) includes four dual-polarized antenna units (B1, B2, B3, B4) which are connected through a four-way power divider (series connection of three Wilkinson equal power divider).
  • a first air dielectric layer 2 As shown in Fig.2 , a first air dielectric layer 2, a first metal radiating patch 3, a second air dielectric layer 4, a ground metal patch 5, a first dielectric substrate 6, bipolar excitation microstrip lines 7, 7' , a third air dielectric layer 8 and a metal reflection baseplate 9 are sequentially arranged from top to bottom in each dual-polarized antenna unit (B1, for example).
  • the first metal radiating patch 3 is connected with the antenna cover 1 through an insulation screw 10.
  • the ground metal patch 5 covers the upper end surface of the first dielectric substrate 6, and is fixedly connected with a hollow metal support 11 which is fixed on the metal reflection baseplate 9.
  • the bipolar excitation microstrip lines 7, 7' are arranged on the lower end surface of the first dielectric substrate 6.
  • Two stimulated radiation micro-slots 12, 12' orthogonal but not in contact, are formed on the upper end surface of the ground metal patch, and are corresponding to the front ends of the bipolar excitation microstrip lines 7, 7' in an orthogonal way.
  • the first metal radiating patch 3 is circular, and the insulation screw 10, which is fixedly connected with the center of the first metal radiating patch 3, is also in threaded connection with the antenna cover 1 through an internal threaded hole in the center of the antenna cover 1.
  • the screw can be rotated outside the antenna cover for fine adjustment of the height between the first metal radiating patch and the stimulated radiation micro-slots, so that the VSWR at the I/O port of the antenna can be easily adjusted to match the impedance of the microstrip lines for a higher antenna gain.
  • the circular metal radiating patch only has height variations during adjustment, so the adjustment is more convenient.
  • the two stimulated radiation micro-slots 12, 12' on the ground metal patch 5 are equal in size and both H-shaped, of which the middle cross arms are orthogonal.
  • Such a technical scheme helps form the bipolar stimulated radiation micro-slots on the ground metal patch with a smaller area, so as to miniaturize the antenna.
  • the included angles between the middle cross arms of the two H-shaped stimulated radiation micro-slots 12, 12' and the X/Y axis of the ground metal patch are ⁇ 45°.
  • Such a technical scheme also helps form the bipolar stimulated radiation micro-slots on the ground metal patch with a smaller area, so as to miniaturize the antenna.
  • the two ports of the dual-polarized antenna are satisfactorily isolated from each other (isolation > 30dB) and thus can work independently;
  • the antenna gain is 14dBi at a test frequency of 1,900MHz;
  • the horizontal HPBW is 70°, the vertical HPBW is 18°, and the front-to-rear ratio is below -25dB;
  • the VSWR at the I/O port is below 1.3, and the relative working frequency bandwidth is around 10%.
  • the product according to this embodiment aims to improve a number of problems caused by the present large antennas, such as difficulty in engineering construction, etc., and relates to a miniaturized TD-LTE eight-channel dual-polarized smart antenna subjected to internal confidential tests.
  • the antenna is filled with a low-loss high-frequency medium, and adopts the structure of two or more layers of radiating patches and the shape of components, dielectric constant and feeding method in Embodiment 17, so as to greatly reduce the physical dimensions and further achieve the multi-frequency, multi-model and miniaturized effects.
  • this embodiment adopts the microwave aperture-coupled multi-cavity laminated plane microstrip radiation mechanism for a high unit element gain (the unit gain of the MM antenna is 8.5dBi, in contrast to an ordinary unit element gain of 5.5dBi).
  • the horizontal and vertical beam widths both range from 75 to 80°, and the front-to-rear ratio is above 25dB.
EP11765012.7A 2010-04-07 2011-04-19 Antenne à microrubans et à double polarisation Ceased EP2565985A4 (fr)

Applications Claiming Priority (12)

Application Number Priority Date Filing Date Title
CN2010201522504U CN201690448U (zh) 2010-04-07 2010-04-07 天线内置式无线通信中继站
CN2010201522580U CN201689984U (zh) 2010-04-07 2010-04-07 方便调试电压驻波比的小型多层微带天线
CN201020152260 2010-04-07
CN2010205201019U CN202121055U (zh) 2010-09-07 2010-09-07 高增益双极化微带天线
CN2010205200868U CN201812928U (zh) 2010-09-07 2010-09-07 微型双极化微带天线
CN2010205200590U CN201812925U (zh) 2010-09-07 2010-09-07 小型四通道双极化微带天线
CN2010205200711U CN201812926U (zh) 2010-09-07 2010-09-07 小型双极化微带天线
CN2010205201131U CN202121056U (zh) 2010-09-07 2010-09-07 八通道高增益高隔离度双极化智能阵列天线
CN2010205200779U CN201812927U (zh) 2010-09-07 2010-09-07 小型高增益双极化微带天线
CN2010205200904U CN202121054U (zh) 2010-09-07 2010-09-07 八通道高隔离度双极化智能阵列天线
CN2010105294164A CN102332635B (zh) 2010-04-07 2010-11-02 微波低波段多频带高增益双极化小型微带天线
PCT/CN2011/000682 WO2011124094A1 (fr) 2010-04-07 2011-04-19 Antenne à microrubans et à double polarisation

Publications (2)

Publication Number Publication Date
EP2565985A1 true EP2565985A1 (fr) 2013-03-06
EP2565985A4 EP2565985A4 (fr) 2013-12-18

Family

ID=47629990

Family Applications (1)

Application Number Title Priority Date Filing Date
EP11765012.7A Ceased EP2565985A4 (fr) 2010-04-07 2011-04-19 Antenne à microrubans et à double polarisation

Country Status (2)

Country Link
EP (1) EP2565985A4 (fr)
WO (1) WO2011124094A1 (fr)

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US10305185B2 (en) 2014-07-25 2019-05-28 Kathrein Se Multiband antenna
EP3713015A1 (fr) * 2019-03-19 2020-09-23 Wilson Electronics, LLC Antenne avec éléments parasites
CN112909497A (zh) * 2021-02-09 2021-06-04 福耀玻璃工业集团股份有限公司 天线组件及车辆
US11682832B2 (en) 2013-03-15 2023-06-20 Intel Corporation Low profile high performance integrated antenna for small cell base station

Families Citing this family (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
FR3055744B1 (fr) * 2016-09-02 2022-01-21 Taoglas Group Holdings Ltd Antennes plates mimo multibandes
US10840589B2 (en) 2016-09-02 2020-11-17 Taoglas Group Holdings Limited Multi-band MIMO panel antennas
CN107181058B (zh) * 2017-05-25 2022-12-30 广东工业大学 一种新型双波束定向辐射mimo贴片天线及移动终端
TWI712216B (zh) * 2018-11-29 2020-12-01 大陸商深圳市超捷通訊有限公司 天線結構及具有該天線結構的無線通訊裝置
CN110190389B (zh) * 2019-06-03 2020-11-20 深圳市景旺电子股份有限公司 一种天线板及其制作方法
JP7318712B2 (ja) * 2019-08-19 2023-08-01 株式会社村田製作所 アンテナ装置及び通信装置
CO2020016679A1 (es) * 2020-12-30 2021-12-31 Inst Tecnologico Metropolitano Dispositivo de antena sintonizado por luz

Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20090278746A1 (en) * 2008-05-07 2009-11-12 Nokia Siemens Networks Oy Wideband or multiband various polarized antenna

Family Cites Families (12)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN2329091Y (zh) * 1998-06-12 1999-07-14 庄昆杰 一种宽频带微带阵列天线单元
TW490888B (en) * 2000-05-02 2002-06-11 Jin-Lu Weng A broadband dual-polarized aperture-coupled patch antenna with modified H-shaped coupling slots
CN2492989Y (zh) * 2001-07-27 2002-05-22 台湾骏炎科技股份有限公司 双极化阵列天线
AU2003245796A1 (en) 2003-07-16 2005-02-04 Huber + Suhner Ag Dual polarised microstrip patch antenna
JP4281672B2 (ja) 2004-11-19 2009-06-17 トヨタ自動車株式会社 内燃機関の燃料噴射制御装置
CN2783548Y (zh) * 2005-02-01 2006-05-24 烟台高盈科技有限公司 3g45°双极化板状基站用天线
JP4954995B2 (ja) 2005-07-07 2012-06-20 エム ケー エス インストルメンツ インコーポレーテッド マルチ・チャンバ・ツールのためのオゾン・システム
US7508346B2 (en) 2007-04-16 2009-03-24 Research In Motion Limited Dual-polarized, microstrip patch antenna array, and associated methodology, for radio device
US8633856B2 (en) 2009-07-02 2014-01-21 Blackberry Limited Compact single feed dual-polarized dual-frequency band microstrip antenna array
CN201536151U (zh) * 2009-08-14 2010-07-28 南京理工大学 X波段双极化低互耦微带天线
CN201689984U (zh) * 2010-04-07 2010-12-29 福建省光微电子科技有限公司 方便调试电压驻波比的小型多层微带天线
CA2835208C (fr) 2011-05-09 2019-08-20 Impel Neuropharma, Inc. Buses pour l'administration de medicaments par voie nasale

Patent Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20090278746A1 (en) * 2008-05-07 2009-11-12 Nokia Siemens Networks Oy Wideband or multiband various polarized antenna

Non-Patent Citations (2)

* Cited by examiner, † Cited by third party
Title
KITATANI K ET AL: "Functional microwave flat antenna using alumina ceramic substrate and piezoelectric actuator", JOURNAL OF THE EUROPEAN CERAMIC SOCIETY, ELSEVIER SCIENCE PUBLISHERS, BARKING, ESSEX, GB, vol. 26, no. 10-11, 1 January 2006 (2006-01-01), pages 2189-2192, XP024960776, ISSN: 0955-2219, DOI: 10.1016/J.JEURCERAMSOC.2005.09.077 [retrieved on 2006-01-01] *
See also references of WO2011124094A1 *

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US11682832B2 (en) 2013-03-15 2023-06-20 Intel Corporation Low profile high performance integrated antenna for small cell base station
US10305185B2 (en) 2014-07-25 2019-05-28 Kathrein Se Multiband antenna
EP3713015A1 (fr) * 2019-03-19 2020-09-23 Wilson Electronics, LLC Antenne avec éléments parasites
CN112909497A (zh) * 2021-02-09 2021-06-04 福耀玻璃工业集团股份有限公司 天线组件及车辆

Also Published As

Publication number Publication date
WO2011124094A1 (fr) 2011-10-13
EP2565985A4 (fr) 2013-12-18

Similar Documents

Publication Publication Date Title
US9030364B2 (en) Dual-polarized microstrip antenna
EP2565985A1 (fr) Antenne à microrubans et à double polarisation
CN102299409B (zh) 一种用于IMT-Advanced系统的宽带双极化基站天线
CN101673873B (zh) 用于移动终端的平面型两天线系统
CN203013940U (zh) 双极化室内分布天线
CN101359770B (zh) 移动终端用的宽带双天线系统
CN102332635B (zh) 微波低波段多频带高增益双极化小型微带天线
CN106450706A (zh) 一种宽带双极化磁电偶极子基站天线
CN106450712A (zh) 一种多旋翼无人机高增益全向共形分集天线技术
CN102509875A (zh) 一种宽频带平面型两天线系统
Abdullah et al. Compact four-port MIMO antenna system at 3.5 GHz
CN201689984U (zh) 方便调试电压驻波比的小型多层微带天线
CN202633501U (zh) 一种宽频带紧凑型平面两天线系统
Gao et al. A dual-polarized compact patch antenna for sub-6 GHz 5G base stations
CN202333140U (zh) 一种双频段平面型两天线系统
CN111313140A (zh) 一种宽带高增益微带天线
CN203631723U (zh) 单、双极化天线阵子辐射单元以及宽频天线和多频天线
CN2893958Y (zh) 双向多频多模集成天线
CN206225547U (zh) 一种差分馈电宽带圆极化天线
CN201812926U (zh) 小型双极化微带天线
CN111355029A (zh) 用于第五代通信系统的高性能双极化微带天线
CN103474754A (zh) 一种单、双极化天线阵子辐射单元以及天线
CN105071025A (zh) 一种双室内吸顶宽带全向mimo天线
CN105514581B (zh) 一种超宽频带全向吸顶天线
CN204029986U (zh) 一种适于lte室内分布的宽带缝隙天线

Legal Events

Date Code Title Description
PUAI Public reference made under article 153(3) epc to a published international application that has entered the european phase

Free format text: ORIGINAL CODE: 0009012

17P Request for examination filed

Effective date: 20121107

AK Designated contracting states

Kind code of ref document: A1

Designated state(s): AL AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HR HU IE IS IT LI LT LU LV MC MK MT NL NO PL PT RO RS SE SI SK SM TR

DAX Request for extension of the european patent (deleted)
A4 Supplementary search report drawn up and despatched

Effective date: 20131114

RIC1 Information provided on ipc code assigned before grant

Ipc: H01Q 5/00 20060101ALI20131108BHEP

Ipc: H01Q 21/06 20060101ALI20131108BHEP

Ipc: H01Q 19/10 20060101ALI20131108BHEP

Ipc: H01Q 21/24 20060101ALI20131108BHEP

Ipc: H01Q 1/38 20060101AFI20131108BHEP

Ipc: H01Q 9/04 20060101ALI20131108BHEP

17Q First examination report despatched

Effective date: 20140901

REG Reference to a national code

Ref country code: DE

Ref legal event code: R003

STAA Information on the status of an ep patent application or granted ep patent

Free format text: STATUS: THE APPLICATION HAS BEEN REFUSED

18R Application refused

Effective date: 20160612