CN1649206A - Multiple band broad band micro strip plaster antenna - Google Patents
Multiple band broad band micro strip plaster antenna Download PDFInfo
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- CN1649206A CN1649206A CN 200410029819 CN200410029819A CN1649206A CN 1649206 A CN1649206 A CN 1649206A CN 200410029819 CN200410029819 CN 200410029819 CN 200410029819 A CN200410029819 A CN 200410029819A CN 1649206 A CN1649206 A CN 1649206A
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Abstract
A broad multi-micro-band antenna with an adhered plate includes: a metal plate, a metal earth plate parallel to the metal plate and an insulating filled medium between them characterizing that the metal plate is rectangular, two rectangular slots parallel to each other and vertical to two parallel edges of the rectangle are set on them, directions of all rectangular slots are parallel to excite multiple discrete resonant frequencies to realize the work with multiple broad bands. A feed probe is mounted vertically between the plate and the metal earth plate positioned on the horizontal central shaft line on the metal plate parallel to the slots. The medium is realized by applying double side PCB method. The probe is connected with a coaxial cable or microwave connector.
Description
Technical field
The present invention relates to a kind of multiband wideband microstrip paster antenna that is applied to radio communication, belong to resonant mode microstrip antenna technical field.
Background technology
In recent years, people constantly increase information and multimedia communications system demand, and communication network also constantly expands.Now, academia and engineering circle have been carried out a lot of explorations and effort in two waveband and triband microstrip antenna field, and main direction is to improve the common little bandwidth of operation of probe feed single-slice single-layer microstrip antenna.
Now, there have been many methods to be used to realize the small capacity double frequency microstrip antenna.Comprising being that paster loads with shorting pin or slit, and use straight-flanked ring.Various forms of loadings all are to realize by the resonance frequency that various patterns on its field distribution of disturbance and its paster of change constitute.Frequency ratio between needed different mode can be determined by choosing suitable loading position or heap(ed) capacity, and frequency tuning can be realized by the size that changes rectangular patch, and it realizes with frequency ratio irrelevant.
The form that loads with the slit has been used as a kind of traditional technological means and has been applied to reduce antenna size continually, realizes two-frequency operation and changes aspects such as polarization characteristic.
The field disturbance that is produced by the slit substantially is very complicated, can't be described with simple perturbation.In fact, the slit can be used as the influence of input impedance and introduces inductance and describe under some concrete condition.According to the application purpose difference, the slit can be located at the edge or the centre of paster.The simplest method that realizes the slit in paster antenna is to utilize the etching technique in the printed circuit board process to realize the slit on paster.Strengthen loading effect if desired, can adopt many parallel slits usually.
The multiband broadband technology of antenna exists many shortcomings now, wherein mainly be all more complicated of structure and feed system: most of existing multiband all channel antennas are provided with the slab construction that comprises two-layer different medium, perhaps have such as very complicated structure such as helical form paster, metal cavitg, coupling loading.Therefore complex process, required precision height, cost height, the rate of finished products of making processing are low, also are difficult for becoming one with miscellaneous equipment.
Summary of the invention
The purpose of this invention is to provide a kind of multiband wideband microstrip paster antenna that is applicable to radio communication.This device is when realizing the multiband broadband operation of antenna, and also have following characteristics: size is little, and cost is low, and is simple in structure, is easy to other equipment integrated etc.
The object of the present invention is achieved like this: a kind of multiband wideband microstrip paster antenna, include: metal patch, metal ground plate parallel with metal patch and the insulation filling medium between metal patch and metal ground plate, adopt printed circuit board process; It is characterized in that: the metal patch of this antenna is rectangular, on two parallel edges of rectangle, respectively have respectively two parallel to each other and perpendicular to the rectangular aperture on limit, place, the equal keeping parallelism of all rectangular aperture directions.To excite a plurality of discrete resonant frequencies, realize emission of multiband broadband or reception; Antenna is vertically installed with a feed probes between metal patch and metal ground plate, the installation site of described feed probes is positioned on the horizontal median axis parallel with the slit on the metal patch.Described metal patch, metal ground plate and the insulation filling medium between metal patch and metal ground plate adopt two sided pcb technology to realize, described feed probes is to make with the coaxial cable or the microwave junction of the coaxial configuration with inner wire, inner insulating layer, outer conductor and external insulation layer.
Described a kind of multiband wideband microstrip paster antenna, it is characterized in that: described some rectangular apertures all extend to central authorities from the paster edge, each slit is parallel to each other, and two slits that are on same the limit are that axial symmetry distributes with the horizontal median axis of paster.
The position distribution of described some rectangular apertures is: on two parallel edges of rectangle, respectively have respectively two parallel to each other and perpendicular to the rectangular aperture on limit, place, the equal keeping parallelism of all rectangular aperture directions is realized a plurality of resonance frequencys.
The installation of described feed probes is that inner wire with coaxial cable or microwave junction is as probe, through hole from printed circuit board passes, the aperture of this through hole should be slightly larger than this inner wire diameter, and the surface nothing is covered copper, between inner wire and ground plate hole wall, be filled with insulating material, insulate to keep both; This inner wire probe is perpendicular to the printed circuit board plane, extends upwardly to concordantly with the paster plane, and this probe extended position is distributing point, is connected with paster at the distributing point probe; The outer conductor of coaxial cable or microwave junction is connected with this metal ground plate below this metal ground plate.
Described metal patch is rectangular, and its thickness is the copper thickness of printed circuit board industrial standard, and the size of its length L and width W and the design parameter of antenna resonant frequency are:
W/h 〉=1 o'clock:
W/h≤1 o'clock:
In the formula: f
0Be the resonance frequency of antenna or the centre frequency of its working band; ε
0Be permittivity of vacuum or dielectric constant; μ
0It is permeability of vacuum; ε
rIt is the relative permittivity of medium; Δ L is equivalent radiating slot width; ε
eIt is the effective capacitance rate; H is the thickness of dielectric between metal ground plate and the metal patch, and its numerical value is the thickness of dielectric in the printed circuit board industrial standard.
The thickness of described metal ground plate is printed circuit board industrial standard copper thickness, and its length and width all should be than the big at least 20mm of described metal patch.
Described insulation filling medium between metal patch and metal ground plate, promptly the dielectric substrate of printed circuit board recommend to use relative permittivity less than 3 dielectric.
The present invention is a kind of novel structure, simple, practical multiband wideband microstrip paster antenna, and good bandwidth and radiation efficiency can be provided simultaneously, and this antenna can be used for the various Wireless Telecom Equipments that need the multiband all channel antenna.Its main feature is: adopt the single-layer metal paster as antenna, and simple in structure; And physical dimension is little, in light weight, is easy to be integrated in the various devices; Feed system is also very simple, has only single probe feed.Therefore the present invention compares with other baroque antennas, and is cheap for manufacturing cost, has popularizing application prospect preferably.
Description of drawings
Fig. 1 is the vertical view that multiband wideband microstrip patch-antenna structure of the present invention is formed.
Fig. 2 is the vertical view of one embodiment of the invention-two waveband wideband microstrip paster antenna.
Fig. 3 is that the master of an embodiment shown in Figure 1 looks cutaway view.
Fig. 4 is the end view of an embodiment shown in Figure 1.
Fig. 5 is the antenna return loss figure of an embodiment shown in Figure 1.
Fig. 6 is the antenna gain pattern of an embodiment shown in Figure 1.
Embodiment
Referring to Fig. 1, the present invention is a kind of multiband wideband microstrip paster antenna, includes: a block length is parallel metal ground plate 2 and the insulation filling medium 6 between metal patch 1 and metal ground plate 2 of rectangular metal paster 1, one and the metal patch 1 of W for the L width; This antenna is vertically installed with a feed probes 3 between metal patch 1 and metal ground plate 2.On two parallel edges of rectangle, respectively have respectively two parallel to each other and perpendicular to the rectangular aperture 4 and 5 on limit, place, the equal keeping parallelism of all rectangular aperture directions to excite a plurality of discrete resonant frequencies, is realized the emission of multiband broadband or is received.Described four rectangular apertures all extend to central authorities from the paster edge, two slits parallel to each other and any, each slit are all non-intersect, extend to central authorities from the paster edge, two slits parallel to each other and any, each slit are all non-intersect, are in two slits 4 on same the limit and two slits 5 being on another limit are that axial symmetry distributes with the horizontal median axis of metal patch 1.(this coordinate system is that the mid point with one side of metal patch 1 is an initial point at the x-y of metal patch 1 two dimensional surface in four slits shown in Figure 1, this limit is the y axle, the center line on vertical this limit is the x axle) on, be in nearer one of two slits, 4 middle distance y axles on the limit, its edge is W to the vertical range of y axle
1, its long and wide L that is respectively
S1And W
S1Be in nearer one of two slits, 5 middle distance y axles on the limit parallel with this limit, its edge is W to the vertical range of y axle
2, its length and wide size are respectively L
S2And W
S2
Coordinate (the x of feed probes 3
0, y
0) then according to the designing requirement decision, the operating frequency range of its installation site decision antenna; If the position of mobile distributing point, the operating frequency of antenna scope also will change thereupon.
Referring to Fig. 2~Fig. 4, it forms structure below in conjunction with illustrated one embodiment of the invention-double-band micro-band sticker antenna-further specify.The present invention is a kind of multiband wideband microstrip paster antenna, includes: metal ground plate 2 and the insulation filling medium 6 between metal patch 1 and metal ground plate 2 that metal patch 1, one and metal patch 1 are parallel; This antenna is vertically installed with a feed probes 3 between metal patch 1 and metal ground plate 2; Four slits that are used to load are arranged on the metal patch,, realize two waveband emission or reception to excite a plurality of discrete resonant frequencies.
On a limit of rectangular metal paster 1, have two parallel to each other and all perpendicular to the rectangular aperture 4 on this limit, two same rectangular apertures 5 perpendicular to the limit, place are arranged on the limit parallel with this limit, the equal keeping parallelism of all rectangular aperture directions, to excite a plurality of discrete resonant frequencies, realize emission of multiband broadband or reception.Article four, rectangular aperture all extends to central authorities from the paster edge, two slits parallel to each other and any, each slit are all non-intersect, are in two slits 4 on same the limit and two slits 5 being on another limit are that axial symmetry distributes with the horizontal median axis of metal patch 1.(this coordinate system is that the mid point with one side of metal patch 1 is an initial point at the x-y of metal patch 1 two dimensional surface in four slits as shown in Figure 2, this limit is the y axle, the center line on vertical this limit is the x axle) on, be in nearer one of two slits, 4 middle distance y axles on the limit, its edge is W to the vertical range of y axle
1=15.1mm, its long and wide L that is respectively
S1=24mm, W
S1=10.8mm; Be in nearer one of two slits, 5 middle distance y axles on the limit parallel with this limit, its edge is W to the vertical range of y axle
2=9.3mm, its length and wide size are respectively L
S2=21.5mm, W
S2=5.8mm.
The material of metal patch 1 of the present invention and metal ground plate 2 is materials that high conductivity metal or surface are coated with high conductivity metal, be to use metallic copper among this embodiment, feed probes 3 is to make with the coaxial cable or the microwave junction of coaxial configuration with inner wire 31, inner insulating layer, outer conductor 32 and external insulation layer, among the embodiment is with the coaxial cable of characteristic impedance 50 Ω its terminal a part of outer conductor and insulating barrier to be divested to make afterwards.Electrical connection among the present invention between the various hardwares all is to adopt soldering to realize.
Referring to Fig. 3 and Fig. 4, the installation of feed probes 3 is that inner wire 31 with coaxial cable or microwave junction is as probe, circular hole from metal ground plate 2 passes, the aperture of this circular hole should be slightly larger than this inner wire 31 diameters, between inner wire 31 and circular hole hole wall, be filled with insulating material 7, insulate to keep both.This inner wire probe 31 is perpendicular to metal ground plate 2 planes, and the below that extends upwardly to metal patch 1 is connected with this metal patch 1, and this probe 31 is distributing point with this metal patch 1 connection.The outer conductor 32 of coaxial cable or microwave junction is connected with this metal ground plate 2 below this metal ground plate 2.The installation site of distributing point is according to designing requirement decision, the operating frequency range of its determining positions antenna; If the position of mobile distributing point, the operating frequency of antenna scope also will change thereupon.Fig. 2 has showed that the coordinate position of distributing point 3 in the x-y of metal patch 1 two dimensional surface is: (28.3,19.45) mm.
Metal patch of the present invention 1 is rectangular, its long L=50.6mm among the embodiment shown in Figure 2, wide W=56.6mm; Parallel with metal ground plate 2; Its thickness is the copper thickness of printed circuit board industrial standard, and the size of its length L and width W and the design parameter of antenna resonant frequency are:
In the formula: f
0Be the resonance frequency of antenna or the centre frequency of its working band; ε
0Be permittivity of vacuum or dielectric constant; μ
0It is permeability of vacuum; ε
rIt is the relative permittivity of medium; Δ L is equivalent radiating slot width; ε
eIt is the effective capacitance rate; H is the thickness of dielectric between metal ground plate and the metal patch, and its numerical value is the thickness of dielectric in the printed circuit board industrial standard.
The thickness of described metal ground plate 2 is printed circuit board industrial standard copper thickness, its length and width all should be respectively than the length L and the big at least 20mm of width W of metal patch 1; The size that is M among Fig. 1 and Fig. 2 and N all should be more than 10mm.Other relevant CALCULATION OF PARAMETERS formula is:
W/h 〉=1 o'clock:
W/h≤1 o'clock:
In the formula: ε
eIt is the effective capacitance rate; ε
rIt is the relative permittivity of medium; Δ L is equivalent radiating slot width; L is the length of metal patch; W is the width of metal patch.The height h=8mm of illustrated embodiment.
The filled media 6 of the present invention between metal patch 1 and metal ground plate 2 is that the dielectric substrate of printed circuit board uses ε
r=2.59 pcb substrate.
Referring to Fig. 5~Fig. 6, the present invention makes the embodiment antenna of showing in above-mentioned Fig. 2~Fig. 4 have two discrete resonant frequencies: f by the installation site of the distance of size, metal patch and the metal ground plate of metal patch, four slits and distributing point being calculated and rationally arranging
01=1.64GHz and f
02=1.8GHz.Fig. 5 illustrated in the return loss at above-mentioned two resonance frequency places all less than-10dB, and the return loss value on most frequencies between two resonance frequencys is less than-10dB simultaneously, its maximum also is in-10dB about, satisfied the requirement of broadband operation.Fig. 6 has illustrated that then the antenna gain on these two resonance frequencys is respectively 5.8dB and 7dB, and the antenna gain between two resonance frequencys then is between the 5.8dB-7dB, can realize two waveband and broadband operation.
Claims (10)
1, a kind of multiband wideband microstrip paster antenna includes: metal patch, metal ground plate parallel with metal patch and the insulation filling medium between metal patch and metal ground plate, adopt two sided pcb technology; It is characterized in that: the metal patch of this antenna is rectangular, on two parallel edges of rectangle, respectively have respectively two parallel to each other and perpendicular to the rectangular aperture on limit, place, the equal keeping parallelism of all rectangular aperture directions to excite a plurality of discrete resonant frequencies, is realized multiband emission or reception; Antenna is vertically installed with a feed probes between metal patch and metal ground plate, the installation site of described feed probes is positioned on the horizontal median axis parallel with the slit on the metal patch.
2, a kind of multiband wideband microstrip paster antenna according to claim 1, it is characterized in that: described metal patch, metal ground plate and the insulation filling medium between metal patch and metal ground plate adopt two sided pcb technology to realize, described feed probes is to make with the coaxial cable or the microwave junction of the coaxial configuration with inner wire, inner insulating layer, outer conductor and external insulation layer.
3, a kind of multiband wideband microstrip paster antenna according to claim 1, it is characterized in that: described some rectangular apertures all extend to central authorities from the paster edge, each slit is parallel to each other, and two slits that are on same the limit are that axial symmetry distributes with the horizontal median axis of paster.
4, a kind of multiband wideband microstrip paster antenna according to claim 3 is characterized in that: described some rectangular strips slit all is that the edge from rectangular patch begins to extend to central authorities, and any two slits are all non-intersect.
5, according to claim 1 or 3 described a kind of multiband wideband microstrip paster antennas, it is characterized in that: on two parallel edges of rectangle, respectively have respectively two parallel to each other and perpendicular to the rectangular aperture on limit, place, the equal keeping parallelism of all rectangular aperture directions is realized a plurality of resonance frequencys.
6, a kind of multiband wideband microstrip paster antenna according to claim 2, it is characterized in that: the installation of described feed probes is that inner wire with coaxial cable or microwave junction is as probe, through hole from printed circuit board passes, the aperture of this through hole should be slightly larger than this inner wire diameter, and the surface nothing is covered copper, between inner wire and ground plate hole wall, be filled with insulating material, insulate to keep both; This inner wire probe is perpendicular to the printed circuit board plane, extends upwardly to concordantly with the paster plane, and this probe extended position is distributing point, is connected with paster at the distributing point probe; The outer conductor of coaxial cable or microwave junction is connected with this metal ground plate below this metal ground plate.
7, a kind of multiband wideband microstrip paster antenna according to claim 6, it is characterized in that: the installation site of described feed probes is positioned on the horizontal median axis parallel with the slit on the metal patch.
8, a kind of multiband wideband microstrip paster antenna according to claim 1, it is characterized in that: described metal patch is rectangular, its thickness is the copper thickness of printed circuit board industrial standard, and the size of its length L and width W and the design parameter of antenna resonant frequency are:
W/h 〉=1 o'clock:
W/h≤1 o'clock:
In the formula: f
0Be the resonance frequency of antenna or the centre frequency of its working band; ε
0Be permittivity of vacuum or dielectric constant; μ
0It is permeability of vacuum; ε
rIt is the relative permittivity of medium; Δ L is equivalent radiating slot width; ε
eIt is the effective capacitance rate; H is the thickness of dielectric between metal ground plate and the metal patch, and its numerical value is the thickness of dielectric in the printed circuit board industrial standard.
9, a kind of multiband wideband microstrip paster antenna according to claim 1, it is characterized in that: the thickness of described metal ground plate is printed circuit board industrial standard copper thickness, its length and width all should be than the big at least 20mm of described metal patch.
10, according to claim 1 or 9 described a kind of multiband wideband microstrip paster antennas, it is characterized in that: described insulation filling medium between metal patch and metal ground plate, promptly the dielectric substrate of printed circuit board recommend to use relative permittivity less than 3 dielectric.
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CN 200410029819 CN1649206A (en) | 2004-03-29 | 2004-03-29 | Multiple band broad band micro strip plaster antenna |
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CN 200410029819 CN1649206A (en) | 2004-03-29 | 2004-03-29 | Multiple band broad band micro strip plaster antenna |
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US8203492B2 (en) | 2008-08-04 | 2012-06-19 | Fractus, S.A. | Antennaless wireless device |
US8237615B2 (en) | 2008-08-04 | 2012-08-07 | Fractus, S.A. | Antennaless wireless device capable of operation in multiple frequency regions |
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US9147929B2 (en) | 2010-02-02 | 2015-09-29 | Fractus, S.A. | Antennaless wireless device comprising one or more bodies |
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US9997841B2 (en) | 2010-08-03 | 2018-06-12 | Fractus Antennas, S.L. | Wireless device capable of multiband MIMO operation |
US9112284B2 (en) | 2010-08-03 | 2015-08-18 | Fractus, S.A. | Wireless device capable of multiband MIMO operation |
US8952855B2 (en) | 2010-08-03 | 2015-02-10 | Fractus, S.A. | Wireless device capable of multiband MIMO operation |
CN104993244A (en) * | 2015-06-01 | 2015-10-21 | 华侨大学 | 4G indoor wall-mounted gain antenna |
CN106785431B (en) * | 2015-12-22 | 2019-10-18 | 中国电子科技集团公司第二十研究所 | Vertical contact pin transmission structure |
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CN112821064A (en) * | 2020-12-31 | 2021-05-18 | Oppo广东移动通信有限公司 | Antenna assembly and electronic equipment |
WO2024040529A1 (en) * | 2022-08-25 | 2024-02-29 | Telefonaktiebolaget Lm Ericsson (Publ) | Multiband filter and communication device |
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