共查询到20条相似文献,搜索用时 31 毫秒
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设计出一款可应用于射频识别(RFID)系统的5.8GHz传统微带矩形贴片天线。天线的辐射贴片尺寸为15.5mm×11.5mm,-10dB的阻抗带宽为80 MHz,最小回波损耗为-36.138dB。在传统微带天线的基础上,设计出一款采用互补开口谐振环(CSRR)缺陷地结构进行改进的小型化天线,天线的辐射贴片尺寸为10mm×7.5mm,-10dB阻抗带宽为62 MHz,最小回波损耗为-23.574dB。相比传统微带天线,改进后的天线的辐射贴片尺寸减小了57.9%,小型化的效果明显且带宽特性和增益特性都能符合RFID系统的一般要求。 相似文献
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设计出一款可应用于射频识别(RFID)系统的5.8 GHz传统微带矩形贴片天线。天线的辐射贴片尺寸为15.5 mm×11.5 mm,-10 dB的阻抗带宽为80 MHz,最小回波损耗为-36.138 dB。在传统微带天线的基础上,设计出一款采用互补开口谐振环(CSRR)缺陷地结构进行改进的小型化天线,天线的辐射贴片尺寸为10 mm×7.5 mm,-10 dB阻抗带宽为62 MHz,最小回波损耗为-23.574 dB。相比传统微带天线,改进后的天线的辐射贴片尺寸减小了57.9%,小型化的效果明显且带宽特性和增益特性都能符合RFID系统的一般要求。 相似文献
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设计了一种可用于无线局域网/无线城域网(WLAN/WiMax)频段的小型化三频微带天线。该结构形似太极鱼,在鱼眼附近同轴馈电,并利用贴片上的一条矩形缝隙,既可实现阻抗匹配,又可使天线在贴片外边界3个位置产生谐振,进而实现在3个频段内同时工作。通过电磁仿真软件HFSS对天线进行仿真,结果表明,该天线在中心频点为2.45GHz,3.95GHz和5.25GHz处的回波损耗分别为29.7dB,29.2dB和27.4dB,天线性能良好。同时天线整体尺寸只有0.24λ×0.18λ(λ为频点2.45GHz时的自由空间波长),具有小型化的特点。该天线尺寸小且结构简单,具有良好的应用价值。其中2.45GHz和5.25GHz可用于WLAN频段,3.9GHz可用于WiMax频段。 相似文献
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单槽双频微波带通滤波器设计与实现 总被引:1,自引:1,他引:0
在方形贴片上采用单槽线代替相互正交双槽线的方法设计出一款结构简单、紧凑的双频段带通滤波器。详细讨论了滤波器结构参数对滤波器性能的影响,并以2.45/5.2GHz双通带滤波器的设计为例,通过仿真优化得到了各结构参数,制作了相应的样品。测试结果表明:该滤波器在2.45GHz通带内回波损耗为20dB,通带内最小插损为0.9dB,相对带宽为10%;5.2GHz通带内回波损耗33.6dB,通带内最小插损为0.37dB,相对带宽为13.4%,其总体尺寸比文献中正交双槽线结构的滤波器缩小48%。 相似文献
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设计出一款可应用于RFID(Radio Frequency Identification)系统的5.8GHz传统矩形微带天线,天线辐射贴片尺寸为15.74mm×11.12mm,天线的回波损耗(S11)的实测结果为-23.276dB。此后,在矩形微带天线基础上进行设计改进,通过分别蚀刻15个超材料结构I型谐振环和6个超材料结构开口谐振环(Split Resonant Ring, SRR),构造出两款新型小型化天线。与传统矩形天线相比,在保持方向性、最大增益等参数性能基本不变的条件下,基于超材料结构的天线辐射贴片尺寸分别为12.44mm×9.12mm 和11.74mm×9.1mm,相比传统矩形天线分别缩小了35.2%和41.82%,辐射贴片小型化效果明显,其回波损耗实测结果分别为-21.83dB 和-15.40dB。 相似文献
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邵建兴 《中国电子科学研究院学报》2010,5(1):36-39
针对传统微带天线低频端尺寸较大的缺点,设计了一种基于光子晶体的新型微带天线结构,即通过采用在传统微带天线贴片下方挖出凹槽,将辐射板放入凹槽中,并在微带天线的介质基板中引入高度不同的周期性圆柱空气隙光子带隙(PBG)结构的设计方案。采用基于有限元方法的电磁仿真软件HFSS 10.0对所设计的天线进行了仿真。仿真结果表明,当回波损耗小于-10.0dB时,天线的工作频段分别为2.40GHz~2.51GHz和3.54GHz~3.62GHz,且天线在这两个频段内具有良好的辐射特性。与传统的微带天线相比,所设计的天线后向辐射明显降低,且其整体尺寸减少了59.19%,从而验证了这种设计方案的有效性。 相似文献
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本文在矩形微带贴片天线的基础上,通过在贴片上开两条对称的缝隙而得到E型贴片天线.经过仿真优化计算出E型贴片天线的尺寸,确定了最终方案模型,得到了方向图、回波损耗等参数.设计的天线工作频率为1.88GHz到2.4GHz,带宽达25.2%,谐振频率的增益达9.38dB.该天线拥有结构简单、体积小、宽频带特点,具有很好的实际... 相似文献
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A. Ameelia Roseline K. Malathi 《AEUE-International Journal of Electronics and Communications》2012,66(12):963-968
This paper presents a compact dual-band slot antenna for 1.8/2.4 GHz WLAN applications using electromagnetic bandgap (EBG) structures. The slotted rectangular radiating element is surrounded by a spiral-like EBG. The antenna size is very compact (60 mm × 60 mm × 3.27 mm), and can be integrated easily with other RF front-end circuits. The working frequency of the patch antenna falls inside the EBG which will lead to the suppression of the surface waves. It is demonstrated that the proposed antenna can completely cover the required bandwidths of IEEE 802.11b/g and IEEE 802.11a with satisfactory radiation characteristics. The simulation is carried out using the finite integration time domain method (FITD) analysis technique. The EM simulated return loss, gain, directivity, radiation pattern, antenna efficiency and VSWR are presented for proposed antenna array. Good agreement is achieved between the simulated and measured results. 相似文献
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电磁带隙(EBG)天线是一种可以提高天线辐射口径及增益的新型天线,以FSS作为EBG反射面,角锥喇叭作为辐射源,设计了一种可以工作在29.730.2 GHz,最大增益为23 dB的EBG天线,并对7个喇叭阵列进行了仿真分析,证明了该种EBG天线具有良好的工作性能,可以作为小型化单口径反射面多波束天线的辐射源,用于减小通信卫星的重量。 相似文献
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Zhengwei Du Ke Gong Jeffrey S. Fu 《Journal of Infrared, Millimeter and Terahertz Waves》2004,25(11):1669-1675
The radiation from electromagnetic bandgap (EBG) microstrip structures is studied. The results show that the radiation from an EBG microstrip structure at most of the frequencies in the stopband and the passband is larger than that of the corresponding conventional microstrip line. Therefore, EBG microstrip circuit s should be shielded and new EBG microstrip structures whose radiation is little should be developed. 相似文献
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Electromagnetic band-gap (EBG) structures have unique properties in controlling the propagation of electromagnetic wave and
have been applied to a wide range of electromagnetic devices design. In this paper, a double-sided printed dipole (DSPD) array
backed by an EBG reflector is proposed for achieving a low-profile design as well as gain enhancement. Simulation results
show that a reduction of more than 55% in antenna height can be obtained by placing the DSPD array over an EBG reflector rather
than a perfect electric conductor (PEC) reflector. And the obtained gain of the antenna with an EBG reflector is about 1.9 dB
higher than that with a PEC reflector at the operating frequency 2.77 GHz. The EBG reflector can be utilized to reduce a cavity-backed
antenna height and enhance the antenna radiation efficiency. The design has a good potential application to antenna arrays
with more elements in wireless communication. 相似文献
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A new method to design thin wideband directional dipole antennas on electromagnetic bandgap (EBG) structure is introduced. At the heart of this method is the idea to understand and properly utilize the complex interactions between the dipole impedance and the EBG reflection phase characteristics. Using the proposed technique a thin wideband printed dipole is designed, fabricated and tested. The antenna can satisfy applications, such as Digital Communication System (DCS, 1.71-1.88 GHz), Global System for Mobile Communication (GSM, 1.85-1.99 GHz), Personal Communication System (PCS, 1.85-2.05 GHz), Universal Mobile Telecommunication System (UMTS, 1.92-2.17 GHz) and Wireless Local Area Network (WLAN, 2.4-2.485 GHz) within VSWR les 2.5:1. Antenna peak gain varies from 5.5 to 8.3 dBi from 1700 to 2500 MHz while the front to back (F/B) ratio is higher than 15 dB for an overall antenna size of 102 mm by 76.4 mm by 5.9 mm. 相似文献
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Dual-band wearable antennas over EBG substrate 总被引:1,自引:0,他引:1
A dual-band coplanar patch antenna integrated with an electromagnetic bandgap substrate is reported. The antenna structure is made from common clothing fabrics and operates at the 2.45 and 5.1-5.8 GHz wireless bands. The bandgap array consists of just 3times3 elements but reduces radiation into the body by over 10 dB and improves the antenna gain by 3 dB 相似文献