提出一种新颖的对偶复合左右手传输线(D-CRLH TL)结构单元,设计了一款小型化四阶宽带带阻滤波器。通过缝隙耦合形成左手电容和右手电感,位于结构下方的矩形贴片形成右手电容,与矩形贴片相连接的短截线形成左手电感。可以通过改变矩形贴...提出一种新颖的对偶复合左右手传输线(D-CRLH TL)结构单元,设计了一款小型化四阶宽带带阻滤波器。通过缝隙耦合形成左手电容和右手电感,位于结构下方的矩形贴片形成右手电容,与矩形贴片相连接的短截线形成左手电感。可以通过改变矩形贴片宽度和短截线的长度来调节带阻滤波器的中心频率和带宽。滤波器有效设计尺寸为11.5 mm×6.7 mm,等于0.23λ×0.13λ(λ为中心频率在自由空间的波长),尺寸较小。仿真测试结果表明该滤波器阻带中心频率为5.6 GHz,20 d B阻带带宽为50%,50 d B阻带带宽为30%。展开更多
提出了一种半哑铃型缺陷地结构的带阻滤波器。在传统哑铃型缺陷地结构的基础上,设计了半哑铃型缺陷地结构单元,实现了带阻特性。相较于传统的哑铃型DGS结构,半哑铃型DGS结构的阻带衰减更陡峭,阻带宽度更理想。文中分析了半哑铃型DGS结...提出了一种半哑铃型缺陷地结构的带阻滤波器。在传统哑铃型缺陷地结构的基础上,设计了半哑铃型缺陷地结构单元,实现了带阻特性。相较于传统的哑铃型DGS结构,半哑铃型DGS结构的阻带衰减更陡峭,阻带宽度更理想。文中分析了半哑铃型DGS结构单元的特性,得到最佳性能的仿真模型。对两个半哑铃型DGS单元级联构成的带阻滤波器进行仿真,结果表明,滤波器的带内最大阻带深度达到45 d B,-10 d B的阻带宽度达11.5 GHz(10.1 GHz21.6 GHz)。展开更多
Coding metasurfaces have attracted tremendous interests due to unique capabilities of manipulating electromagnetic wave.However,archiving transmissive coding metasurface is still challenging.Here we propose a transmis...Coding metasurfaces have attracted tremendous interests due to unique capabilities of manipulating electromagnetic wave.However,archiving transmissive coding metasurface is still challenging.Here we propose a transmissive anisotropic coding metasurface that enables the independent control of two orthogonal polarizations.The polarization beam splitter and the orbital angular momentum(OAM)generator have been studied as typical applications of the anisotropic 2-bit coding metasurface.The simulated far field patterns illustrate that the x and y polarized electromagnetic waves are deflected into two different directions,respectively.The anisotropic coding metasurface has been experimentally verified to realize an OAM beam with l=2 of right-handed polarized wave,resulting from both contributions from linear-to-circular polarization conversion and the phase profile modulation.This work is beneficial to enrich the polarization manipulation field and develop transmissive coding metasurfaces.展开更多
文摘提出了一种基于多开口田字形单元结构实现材料左手特性的设计方案.该结构是在介质基板单侧集成电、磁谐振器形成左手单元.通过理论分析、软件仿真、加工测试、提取有效电磁参数,结果表明该结构在12.7—21.1 GHz范围内具有双负特性(等效介电常数ε<0,等效磁导率μ<0),基本覆盖Ku波段,绝对带宽可达8.4 GHz,单元损耗低于0.3 d B.同传统的左手材料相比,该结构以更小的单元尺寸,更低的损耗实现了更宽的左手频带,为宽频带、低损耗微波左手材料的设计及广泛应用提供了重要参考.
文摘提出一种新颖的对偶复合左右手传输线(D-CRLH TL)结构单元,设计了一款小型化四阶宽带带阻滤波器。通过缝隙耦合形成左手电容和右手电感,位于结构下方的矩形贴片形成右手电容,与矩形贴片相连接的短截线形成左手电感。可以通过改变矩形贴片宽度和短截线的长度来调节带阻滤波器的中心频率和带宽。滤波器有效设计尺寸为11.5 mm×6.7 mm,等于0.23λ×0.13λ(λ为中心频率在自由空间的波长),尺寸较小。仿真测试结果表明该滤波器阻带中心频率为5.6 GHz,20 d B阻带带宽为50%,50 d B阻带带宽为30%。
文摘提出了一种半哑铃型缺陷地结构的带阻滤波器。在传统哑铃型缺陷地结构的基础上,设计了半哑铃型缺陷地结构单元,实现了带阻特性。相较于传统的哑铃型DGS结构,半哑铃型DGS结构的阻带衰减更陡峭,阻带宽度更理想。文中分析了半哑铃型DGS结构单元的特性,得到最佳性能的仿真模型。对两个半哑铃型DGS单元级联构成的带阻滤波器进行仿真,结果表明,滤波器的带内最大阻带深度达到45 d B,-10 d B的阻带宽度达11.5 GHz(10.1 GHz21.6 GHz)。
基金Project supported by the National Natural Science Foundation of China(Grant No.U1931121)the Natural Science Foundation of Heilongjiang Province in China(Grant No.ZD2020F002)+2 种基金111 Project to the Harbin Engineering University(Grant No.B13015)the Fundamental Research Funds for the Central Universities(Grant Nos.3072021CFT2501 and 3072021CF2508)the Postdoctoral Scientific Research Developmental Fund of Heilongjiang Province,China(Grant No.LBH-Q9097).
文摘Coding metasurfaces have attracted tremendous interests due to unique capabilities of manipulating electromagnetic wave.However,archiving transmissive coding metasurface is still challenging.Here we propose a transmissive anisotropic coding metasurface that enables the independent control of two orthogonal polarizations.The polarization beam splitter and the orbital angular momentum(OAM)generator have been studied as typical applications of the anisotropic 2-bit coding metasurface.The simulated far field patterns illustrate that the x and y polarized electromagnetic waves are deflected into two different directions,respectively.The anisotropic coding metasurface has been experimentally verified to realize an OAM beam with l=2 of right-handed polarized wave,resulting from both contributions from linear-to-circular polarization conversion and the phase profile modulation.This work is beneficial to enrich the polarization manipulation field and develop transmissive coding metasurfaces.
