利用广义嵌套阵列实现超宽带频率不变波束成形

IF 3.5 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Taeho Yu;Jin Myeong Heo;Cheolsun Park;Yong Ku Jeon;Gangil Byun
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引用次数: 0

摘要

本文提出了一种使用广义嵌套阵列的超宽带频率不变波束成形(FIB)。为了在减少阵元数量的情况下实现超宽带(带宽比为 9:1)FIB,目标频段被划分为多个子频段。根据子频带的带宽比,子阵列在最大频率处的半波长元件间距为整数倍。由于这种整数倍关系,子阵列的阵元被叠加在一起,从而减少了阵元总数,同时保持了目标频段的 FIB 性能。然后,利用反傅里叶变换,根据所需的波束模式得出 FIB 权值。巴特利特波束成形器用于生成拟议嵌套阵列的 FIB 模式。此外,我们还研究了所需最小阵元数与设计参数(目标带宽、波束宽度和侧叶水平)之间的相互关系。为了进行验证,我们制作并测量了 21 个印刷对数周期偶极子阵列天线。对其测向性能进行了评估,并与 35 元均匀线性阵列进行了比较。拟议阵列的到达方向(DoA)估计结果显示,当信噪比为 10 dB 时,入射角在 ±50° 范围内的均方根误差小于 2.02°。结果表明,拟议阵列的超宽带 FIB 性能类似于传统的均匀线性阵列,但元件数量要少得多。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Ultra-Wideband Frequency-Invariant Beamforming Using a Generalized Nesting Array
This paper proposes an ultra-wideband frequency-invariant beamforming (FIB) using a generalized nesting array. To implement ultra-wideband (9:1 bandwidth ratio) FIB with a reduced number of array elements, the target frequency band is divided into subbands. The subarrays have integer multiples of inter-element spacing of half-wavelength at the maximum frequency according to the bandwidth ratio of subbands. Due to this integer multiple relationships, the array elements of the subarrays are superimposed so that the total number of array elements is reduced while maintaining FIB performance over the target frequency band. Then, the FIB weights are derived based on the desired beam pattern using the inverse Fourier transform. A Bartlett beamformer is used to generate FIB patterns of the proposed nesting array. In addition, we investigate the interrelationship between the minimum required number of array elements and design parameters (target bandwidth, beamwidth, and side lobe level). For validation, 21 printed log-periodic dipole array antennas are fabricated and measured. The direction finding performance is evaluated and compared to that of a 35-element uniform linear array. The direction of arrival (DoA) estimation results of the proposed array show a root-mean-square error of less than 2.02° for an incident angle within ±50° when a signal-to-noise ratio is 10 dB. It is demonstrated that the proposed array exhibits ultra-wideband FIB performance similar to a conventional uniform linear array but with much fewer elements.
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来源期刊
CiteScore
6.50
自引率
12.50%
发文量
90
审稿时长
8 weeks
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