矢量三角形基函数矩量法分析双馈天线

为了分析多馈源天线,采用矢量三角形基函数的矩量法求解天线积分方程。介绍了分析线天线所采用的基以及求解过程,对一种带状偶极子天线模型进行数值计算。研究了共模和差模两种馈电模式下,天线的电流分布以及频率特性。计算结果表明,双馈偶极子具有较小的回波损耗、宽频带以及双频工作等优点。

电小尺寸锥台上双馈圆极化共形微带天线阵设计

在电小尺寸锥台上,设计并实现一款锥台共形水平全向双馈圆极化微带天线阵。该天线的工作频率覆盖GPS L1频点(1.575 GHz)和北斗导航系统B1频点(1.562 GHz)。基于HFSS软件仿真,分析了锥台共形对天线阵单元的S11、轴比和增益等参数带来的影响,通过调整辐射贴片尺寸,减小了锥台共形对天线的影响,改善了圆极化性能,提高了天线的圆极化增益。加工天线阵并进行测试,测试结果表明,该天线阵在1.55~1.60 GHz频段内,S11参数≤-10 dB,在GPS L1频点和北斗B1频点,水平全向增益最大值达到了1.73 dB,1.25 dB,增益不圆度≤2.5 dB,实测结果表明该天线具有良好的水平全向圆极化辐射性能。

同频双极化双路输出天线的设计

介绍两种新型的基于 GPS频段的同频双极化双路输出天线 ,用于接收 GPS卫星信号。它们的共同点是在一个天线上面同时输出两路信号 ,两路信号频率相同 ,极化方式不同。

宽角覆盖多波束反射面天线设计

给出了一种双圆极化多波束反射面天线,具有高增益和宽角度覆盖的辐射特性。给出的天线由两部分组成:一个是以高效多模圆锥喇叭天线为单元组成的馈源阵,一个是侧馈双偏置卡塞格伦(SFOC)天线。馈源阵放置于反射面天线的焦平面,共有631个馈源,馈源阵采用蜂窝状布阵方式。该天线工作于Ku频段,工作带宽为13.3%,整个工作频段内可实现20°×9°的波束覆盖范围,在该范围内波束覆盖增益优于42dBic。

基于0.18μm CMOS工艺的300GHz高响应度探测器

基于0.18μm CMOS工艺设计了一种300 GHz高响应度探测器。该探测器集成了双馈差分天线和双场效应管(FET)对称差分自混频电路。双馈差分天线较单馈天线有更高的精确度及更优的抗干扰性。差分自混频电路能有效地抑制共模信号,减小噪声输入。双场效应管后增加一级放大电路,将自混频电路输出的微弱信号进一步放大以增大响应度。天线与电路间的匹配网络实现了信号的最大功率传输。在全波电磁场仿真软件HFSS下对双馈天线进行建模与仿真优化,并与电路进行联合仿真。结果显示探测器在栅源电压为0.43 V、输入功率为-40 dBm时,最大响应度为11.25 kV/W,最小噪声等效功率为115pW/√Hz。

An Efficient CSI Feedback Scheme for Dual-Polarized MIMO Systems Using Layered Multi-Paths Information

Massive MIMO is one of tile enabling technologies tbr beyond 4G and 5G systems due to its ability to provide beamforming gain and reduce interference Dual-polarized antenna is widely adopted to accommodate a large number of antenna elements in limited space. However, current CSI（channel state information） feedback schemes developed in LTE for conventional MIMO systems are not efficient enough for massive MIMO systems since the overhead increases almost linearly with the number of antenna. Moreover, the codebook for massive MIMO will be huge and difficult to design with the LTE methodology. This paper proposes a novel CSI feedback scheme named layered Multi-paths Information based CSI Feedback （LMPIF）, which can achieve higher spectrum efficiency for dual-polarized antenna system with low feedback overhead. The MIMO channel is decomposed into long term components （multipath directions and amplitudes） and short term components （multipath phases）. The relationship between the two components and the optimal precoder is derived in closed form. To reduce the overhead, different granularities in feedback time have been applied for the long term components and short term components Link and system level simulation results prove that LMPIF can improve performance considerably with low CSI feedback overhead.