A low profile dual-band multiple-input-multiple-output (MIMO) antenna system is proposed. The proposed MIMO antenna consists of two low profile unbalanced fed inverted L antennas with parasitic elements to resonate at...A low profile dual-band multiple-input-multiple-output (MIMO) antenna system is proposed. The proposed MIMO antenna consists of two low profile unbalanced fed inverted L antennas with parasitic elements to resonate at 2.45 GHz and 5 GHz. The structure is uncomplicated by locating two ultra low profile inverted L antennas on the finite conducting plane. The proposed MIMO antenna is numerically and experimentally analyzed. When the size of conducting plane is 55 mm by 55 mm and the height of antenna is 9 mm, the directive gain of 4.11 dBi and the S11 bandwidth of 5.71% are achieved for lower frequency of 2.45 GHz. At the upper frequency of 5 GHz, the directive gain of 8.22 dBi and the S11 bandwidth of 6% are obtained. The proposed antenna has good diversity gain, shown by the correlation coefficient becomes less than 0.005 at the frequency of 2.45 GHz and 5 GHz band when the distance between inverted L elements is 41 mm. A good agreement between calculated and measured results is obtained. The results show that the weak mutual coupling of the proposed antenna and this feature enables it to cover the required bandwidths for WLAN operation at the 2.4 GHz band and 5 GHz band.展开更多
Two ultra low profile inverted L antennas located on the square conducting plane are numerically and experimentally analyzed as the multiple input multiple output (MIMO) antenna system. When the size of conducting pla...Two ultra low profile inverted L antennas located on the square conducting plane are numerically and experimentally analyzed as the multiple input multiple output (MIMO) antenna system. When the size of conducting plane is 0.45 λ by 0.45 λ and the height of antenna is 0.03 λ, the directive gain of 4.12 dBi and the return loss bandwidth of 3.67% are achieved. The proposed antenna has good diversity gain shown by the correlation coefficient, and becomes less than 0.02 at the frequency of 2.45 GHz band when the distance between inverted L elements is 0.33 λ. The results show the weak mutual coupling of the proposed antenna and its performances are promising as MIMO antenna applications.展开更多
针对星载相控阵雷达应用背景,提出一款工作于Ku频段的低剖面轻量化一维相扫缝隙阵天线。天线基于射频-数字-供电一体化设计思路,并采用系统级封装(system in package,SiP)芯片实现高密度结构集成。与传统基于砖式或瓦片式收发(transmit/...针对星载相控阵雷达应用背景,提出一款工作于Ku频段的低剖面轻量化一维相扫缝隙阵天线。天线基于射频-数字-供电一体化设计思路,并采用系统级封装(system in package,SiP)芯片实现高密度结构集成。与传统基于砖式或瓦片式收发(transmit/receive,T/R)组件的相控阵天线相比,所提天线设计可以有效降低天线剖面高度和重量。天线中心工作频率为16 GHz,具有600 MHz工作带宽,可实现一维方向波束扫描。此外,天线设计了自校准网络,可用于在轨期间射频通道幅相特性实时检测。样机实测结果表明,天线扫描角度范围可达±30°,等效全向辐射功率(effective isotropic radiated power,EIRP)与接收增益与噪声温度比(gain-to-noise temperature ratio,G/T)值测试结果均与理论计算值吻合。展开更多
A metasurface(MTS)can be characterized in terms of dispersion properties of guided waves and surface waves.By engineering the rich dispersion relations,setting particular boundary conditions,and selecting proper excit...A metasurface(MTS)can be characterized in terms of dispersion properties of guided waves and surface waves.By engineering the rich dispersion relations,setting particular boundary conditions,and selecting proper excitation schemes,multiple adjacent resonance modes can be excited to realize the wideband operation of low-profile MTS antennas.We introduce the operating principles of typical dispersion-engineered MTS antennas,and review the recent progress in dispersion-engineered MTS antenna technology.The miniaturization,circular polarization,beam-scanning,and other functionalities of MTS antennas are discussed.The recent development of MTS antennas has not only provided promising solutions to the wideband and low-profile antenna design but also proven great potential of MTS in developing innovative antenna technologies.展开更多
文摘A low profile dual-band multiple-input-multiple-output (MIMO) antenna system is proposed. The proposed MIMO antenna consists of two low profile unbalanced fed inverted L antennas with parasitic elements to resonate at 2.45 GHz and 5 GHz. The structure is uncomplicated by locating two ultra low profile inverted L antennas on the finite conducting plane. The proposed MIMO antenna is numerically and experimentally analyzed. When the size of conducting plane is 55 mm by 55 mm and the height of antenna is 9 mm, the directive gain of 4.11 dBi and the S11 bandwidth of 5.71% are achieved for lower frequency of 2.45 GHz. At the upper frequency of 5 GHz, the directive gain of 8.22 dBi and the S11 bandwidth of 6% are obtained. The proposed antenna has good diversity gain, shown by the correlation coefficient becomes less than 0.005 at the frequency of 2.45 GHz and 5 GHz band when the distance between inverted L elements is 41 mm. A good agreement between calculated and measured results is obtained. The results show that the weak mutual coupling of the proposed antenna and this feature enables it to cover the required bandwidths for WLAN operation at the 2.4 GHz band and 5 GHz band.
文摘Two ultra low profile inverted L antennas located on the square conducting plane are numerically and experimentally analyzed as the multiple input multiple output (MIMO) antenna system. When the size of conducting plane is 0.45 λ by 0.45 λ and the height of antenna is 0.03 λ, the directive gain of 4.12 dBi and the return loss bandwidth of 3.67% are achieved. The proposed antenna has good diversity gain shown by the correlation coefficient, and becomes less than 0.02 at the frequency of 2.45 GHz band when the distance between inverted L elements is 0.33 λ. The results show the weak mutual coupling of the proposed antenna and its performances are promising as MIMO antenna applications.
文摘针对星载相控阵雷达应用背景,提出一款工作于Ku频段的低剖面轻量化一维相扫缝隙阵天线。天线基于射频-数字-供电一体化设计思路,并采用系统级封装(system in package,SiP)芯片实现高密度结构集成。与传统基于砖式或瓦片式收发(transmit/receive,T/R)组件的相控阵天线相比,所提天线设计可以有效降低天线剖面高度和重量。天线中心工作频率为16 GHz,具有600 MHz工作带宽,可实现一维方向波束扫描。此外,天线设计了自校准网络,可用于在轨期间射频通道幅相特性实时检测。样机实测结果表明,天线扫描角度范围可达±30°,等效全向辐射功率(effective isotropic radiated power,EIRP)与接收增益与噪声温度比(gain-to-noise temperature ratio,G/T)值测试结果均与理论计算值吻合。
基金supported by the Agency for Science,Technology and Research(A*STAR),Singapore,through its Industry Alignment Fund—Pre-Positioning Programme(IAF-PP)(No.A1897a0040)。
文摘A metasurface(MTS)can be characterized in terms of dispersion properties of guided waves and surface waves.By engineering the rich dispersion relations,setting particular boundary conditions,and selecting proper excitation schemes,multiple adjacent resonance modes can be excited to realize the wideband operation of low-profile MTS antennas.We introduce the operating principles of typical dispersion-engineered MTS antennas,and review the recent progress in dispersion-engineered MTS antenna technology.The miniaturization,circular polarization,beam-scanning,and other functionalities of MTS antennas are discussed.The recent development of MTS antennas has not only provided promising solutions to the wideband and low-profile antenna design but also proven great potential of MTS in developing innovative antenna technologies.