CN202503102U - Compact type high-isolation ultra-wideband dual-waveband antenna - Google Patents
Compact type high-isolation ultra-wideband dual-waveband antenna Download PDFInfo
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- CN202503102U CN202503102U CN2012201223840U CN201220122384U CN202503102U CN 202503102 U CN202503102 U CN 202503102U CN 2012201223840 U CN2012201223840 U CN 2012201223840U CN 201220122384 U CN201220122384 U CN 201220122384U CN 202503102 U CN202503102 U CN 202503102U
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Abstract
The utility model discloses a compact ultra-wideband dual-waveband antenna with high isolation. The compact ultra-wideband dual-waveband antenna with high isolation comprises an antenna substrate (1) and three radiating elements, wherein the three radiating elements and the substrate (1) are in the same horizontal plane, the three radiating elements are placed side by side, and the bottom surface of the substrate (1) serves as a ground plane; a first radiating element (3) consists of an L-shaped metal strip and a semicircular metal block which are connected with each other; a second radiating element (4) consists of an S-shaped metal strip and a rectangular metal block which are connected with each other; a third radiating element (5) consists of an L-shaped metal strip and an elliptic metal block which are connected with each other; the first radiating element (3) and the third radiating element (5) are symmetrically arranged on two sides of the second radiating element (4) respectively; and feed ends of the three radiating elements are connected with the substrate respectively. A double-feed three-radiating-element antenna technique is adopted, so that the antenna can work at two wavebands, the coupling degree is less than -15dB (the corresponding isolation is greater than 15dB), the standing-wave ratio is less than 2, the gain is about 4dBi, and the antenna efficiency is greater than 65 percent.
Description
Technical field
The utility model relates to a kind of novel high-isolation ultra broadband dual-band antenna, and specifically a kind of compact high-isolation ultra broadband dual-band antenna belongs to the planar inverse F type antenna field.
Background technology
Along with electronic device towards miniaturization, microminiaturized direction, and the application of spread spectrum, frequency hopping has proposed increasingly high requirement to the broadband and miniaturization of communication equipment.UWB (ul-tra wide band; Ultra broadband) communication has many advantages such as message capacity is big, good confidentiality, average power density is little, the anti-multipath interference performance is strong; Be the important development direction of 21st century communication system, the ultra-wideband antenna technology that its development also requires to adapt with it.The ultra-wideband antenna design is a main direction of studying of Ultra-wideband Communication Technology, all has a wide range of applications in systems such as radio communication, wireless access, electronic countermeasuress.
Traditional ultra-wideband antenna such as logarithm periodic antenna, equiangular spiral Archimedian spiral antenna etc.; The feeding network complex design; Size is bigger; Do not satisfy of the miniaturization requirement of low-power short distance personal communication applications, and phase center is fixing, and more serious distortion is arranged when being applied to transmit the time domain short pulse signal in the pulsed radio system to ultra-wideband antenna.
The inverse F type antenna quality is little, and planar structure is easy to integrated, and the antenna frequency band can cover a plurality of communications bands, can reduce the number of the required antenna of communication system, and then reduces system cost, and helps the electromagnetic compatibility of system.Therefore, compare with traditional ultra-wideband antenna, inverse F type antenna has research prospect and Practical significance.
WLAN based on the IEEE802.11 standard allows in LAN environment, to use the 2.4GHz or the 5.3GHz radio-frequency range that need not to authorize to carry out free wireless connections.In practical application, the 2.4GHz wave band is usually crowded to capacity, thereby has proposed two waveband ultra broadband work antenna.Such antenna may be simultaneously operated in 2.4GHz and 5.3GHz wave band, has improved the capacity and the quality of local area network wireless communication greatly.But dual-band antenna has stronger mutual coupling because 5.3GHz and 2.4GHz audio range frequency differ almost 2 times, usually cause antenna can't be under two waveband the while operate as normal.At present generally be the antenna that design has two radiating elements, be operated in 5.3GHz and 2.4GHz wave band respectively.For improving isolation, the spacing with 2 radiating elements strengthens usually, but this has increased the size of antenna greatly, and the standing-wave ratio coefficient is bigger.Therefore designing the compact ultra broadband dual-band antenna with high-isolation is the key that addresses this problem.
The utility model content
The utility model technical problem to be solved is to the deficiency in the background technology, provides a kind of and can (< 15dB) realize the compact ultra-wideband antenna that two waveband (2.4GHz and 5.3GHz) is worked down at high-isolation.
The utility model adopts following technical scheme for solving the problems of the technologies described above:
A kind of compact high-isolation two waveband ultra-wideband antenna comprises antenna substrate and three radiant elements that are in the same horizontal plane with substrate and are arranged side by side each other, and the bottom surface of substrate is as ground plane; Wherein, first radiant element is linked to each other with half circular metal piece by a L shaped bonding jumper and constitutes, and the radiation that said semicircle metal derby is first radiant element is terminal; Second radiant element is linked to each other with a rectangular metal piece by a S shape bonding jumper and constitutes, and the radiation that said rectangular metal piece is second radiant element is terminal; The 3rd radiant element is linked to each other with an oval metal derby by a L shaped bonding jumper and constitutes, and the radiation that said oval metal derby is the 3rd radiant element is terminal; First radiant element and the 3rd radiant element are arranged symmetrically in the both sides of second radiant element respectively, and the feed end of said three radiant elements links to each other with substrate respectively.
Further, a kind of compact high-isolation two waveband ultra-wideband antenna of the utility model, said first radiant element is operated in the 2.4GHz wave band, and the 3rd radiant element is operated in the 5.3GHz wave band, and second radiant element is operated in the 4.2GHz wave band.
Further, a kind of compact high-isolation two waveband ultra-wideband antenna of the utility model, said antenna substrate is processed with metal material, and thickness is at 0.2mm ~ 0.5mm, and the both sides of edges that is positioned at substrate is symmetrically arranged with two coaxial cable welding fixing points.
Further; A kind of compact high-isolation two waveband ultra-wideband antenna of the utility model; Said first radiant element and second radiant element adopt a coaxial cable feed and a shared feed end, and feed end is positioned at the junction of S shape bonding jumper of L shaped bonding jumper and second radiant element of first radiant element.
Further, a kind of compact high-isolation two waveband ultra-wideband antenna of the utility model, said the 3rd radiant element adopts coaxial cable feed, and feed end is positioned at the L shaped bonding jumper of said the 3rd radiant element of formation and the junction of oval metal derby.
The utility model adopts above technical scheme compared with prior art, has following technique effect:
The utility model adopts three radiant element antenna technologies, and its cramped construction makes whole UWB antenna can be operated in two waveband (2.4GHz and 5.3GHz), and isolation is less than-15dB, and standing-wave ratio is less than 2, and gain is about 4dBi, and antenna efficiency is greater than 65%.
Description of drawings
Fig. 1 is a two waveband UWB antenna plane sketch map.
Fig. 2 is an antenna substrate planar structure sketch map.
Fig. 3 is radiant element 3,4 planar structure sketch mapes.
Fig. 4 is radiant element 5 planar structure sketch mapes.
Fig. 5 is that radiant element 3,4 feed ends are that P1 port, radiant element 5 feed ends are the S parametric plot under the P2 port case.
Fig. 6 is that radiant element 3,4 feed ends are that P1 port, radiant element 5 feed ends are the standing-wave ratio curve chart under the P2 port case.
Embodiment
Below in conjunction with accompanying drawing the technical scheme of the utility model is done further detailed description:
As shown in Figure 1, the ultra-wideband antenna of the utility model comprises antenna substrate 1 and three radiant elements that are in the same horizontal plane with substrate 1 and are arranged side by side each other, and wherein the feed end of three radiant elements links to each other with substrate respectively.
Wherein, radiant element 3 is linked to each other with half circular metal piece by a L shaped bonding jumper and constitutes, and semicircle metal derby is that the radiation of radiant element 3 is terminal.Radiant element 4 is linked to each other with a rectangular metal piece by a S shape bonding jumper and constitutes, and the rectangular metal piece is that the radiation of radiant element 4 is terminal.Radiant element 5 is linked to each other with an oval metal derby by a L shaped bonding jumper and constitutes, and oval metal derby is that the radiation of radiant element 5 is terminal.
Through the particular design of each radiate element structure, can effectively improve the CURRENT DISTRIBUTION on radiant element surface, and then improve, thereby improve the isolation of antenna in two service bands by the radiation field distribution that surface current encouraged.Different in addition radiate element structure designs have formed different radiation impedances, and then can reduce the standing-wave ratio of antenna in service band.
With reference to Fig. 2 and Fig. 3, radiant element 3 adopts with radiant element 4 and processes with substrate 1 the same material, and concrete realization can be processed Fig. 2 and pattern shown in Figure 3 through wire cutting technology or laser cutting parameter on a block of metal plate of material.
With reference to Fig. 3; Radiant element 3 and radiant element 4 shared feeds; Can the radiation that encouraged have higher isolation so that the surface current that radiation that the surface current distribution that forms at radiant element 3 and radiant element 4 is encouraged and radiant element 5 form distributes; Feed adopts coaxial cable, feed end 6 places that are positioned at as shown in Figure 1.
With reference to Fig. 4, radiant element 5 adopts coaxial cable feed, feed end 7 places that are positioned at as shown in Figure 1.
The mutual coupling of radiant element 3 and radiant element 5 has been disturbed in the introducing of radiant element 4, thereby has increased the isolation of 2.4GHz and two wave bands of 5.3GHz.
The feed end that Fig. 5 has provided radiant element 3,4 is that the feed end of P1 port, radiant element 5 is the S parameters simulation curve chart under the P2 port case, from figure, can see radiant element 3,4,5 S12 (degree of coupling) each other at 2.4GHz ~ 2.5GHz wave band, 4.2GHz ~ 4.75GHz wave band and 5.15GHz ~ 5.825GHz wave band all less than-15dB.
The feed end 6 that Fig. 6 has provided radiant element 3,4 is the feed end 7 of P1 port, the radiant element 5 simulation curve figure for the standing-wave ratio parameter under the P2 port case, from figure, can see radiant element 3,4,5 standing-wave ratio coefficient each other at 2.4GHz ~ 2.5GHz wave band, 4.2GHz ~ 4.75GHz wave band and 5.15GHz ~ 5.825GHz wave band all less than 2.0.
Claims (5)
1. a compact high-isolation two waveband ultra-wideband antenna is characterized in that: comprise antenna substrate (1) and be in the same horizontal plane and three radiant elements that are arranged side by side each other with substrate (1) that the bottom surface of substrate (1) is as ground plane; Wherein,
First radiant element (3) is linked to each other with half circular metal piece by a L shaped bonding jumper and constitutes, and said semicircle metal derby is that the radiation of first radiant element (3) is terminal;
Second radiant element (4) is linked to each other with a rectangular metal piece by a S shape bonding jumper and constitutes, and said rectangular metal piece is that the radiation of second radiant element (4) is terminal;
The 3rd radiant element (5) is linked to each other with an oval metal derby by a L shaped bonding jumper and constitutes, and said oval metal derby is that the radiation of the 3rd radiant element (5) is terminal;
First radiant element (3) and the 3rd radiant element (5) are arranged symmetrically in the both sides of second radiant element (4) respectively, and the feed end of said three radiant elements links to each other with substrate respectively.
2. a kind of compact high-isolation two waveband ultra-wideband antenna according to claim 1; It is characterized in that: the service band of said first radiant element (3) is 2.4GHz; The 3rd radiant element (5) service band is 5.3GHz, and second radiant element (4) service band is 4.2GHz.
3. a kind of compact high-isolation two waveband ultra-wideband antenna according to claim 1; It is characterized in that: said antenna substrate (1) is processed with metal material; Thickness is at 0.2mm ~ 0.5mm, and the both sides of edges that is positioned at substrate (1) is symmetrically arranged with two coaxial cable welding fixing points (2).
4. a kind of compact high-isolation two waveband ultra-wideband antenna according to claim 1; It is characterized in that: said first radiant element (3) and second radiant element (4) adopt a coaxial cable feed and a shared feed end, and feed end is positioned at the junction (6) of S shape bonding jumper of L shaped bonding jumper and second radiant element (4) of first radiant element (3).
5. a kind of compact high-isolation two waveband ultra-wideband antenna according to claim 1; It is characterized in that: said the 3rd radiant element (5) adopts coaxial cable feed, and feed end is positioned at the L shaped bonding jumper of said the 3rd radiant element of formation (5) and the junction (7) of oval metal derby.
Priority Applications (1)
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CN2012201223840U CN202503102U (en) | 2012-03-28 | 2012-03-28 | Compact type high-isolation ultra-wideband dual-waveband antenna |
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CN2012201223840U CN202503102U (en) | 2012-03-28 | 2012-03-28 | Compact type high-isolation ultra-wideband dual-waveband antenna |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102570010A (en) * | 2012-03-28 | 2012-07-11 | 南京信息工程大学 | Compact type high-isolation ultra-wideband dual-waveband antenna |
CN104868248A (en) * | 2014-02-26 | 2015-08-26 | 启碁科技股份有限公司 | Broadband antenna |
-
2012
- 2012-03-28 CN CN2012201223840U patent/CN202503102U/en not_active Expired - Fee Related
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102570010A (en) * | 2012-03-28 | 2012-07-11 | 南京信息工程大学 | Compact type high-isolation ultra-wideband dual-waveband antenna |
CN102570010B (en) * | 2012-03-28 | 2014-09-10 | 南京信息工程大学 | Compact type high-isolation ultra-wideband dual-waveband antenna |
CN104868248A (en) * | 2014-02-26 | 2015-08-26 | 启碁科技股份有限公司 | Broadband antenna |
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C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20121024 Termination date: 20150328 |
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EXPY | Termination of patent right or utility model |