Optimal Adjacent Output Phase Difference Assignments in One-Dimensional Parallel Switching Matrices With Four Beams

IF 6.9 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Shengjia Wu;Jiro Hirokawa;Takashi Tomura;Nelson J. G. Fonseca
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Abstract

This article provides for the first time a detailed discussion of the optimal assignment of adjacent output phase differences in terms of matrix performance out of all possible combinations in generalized one-dimensional parallel switching matrices with four beams. In this specific case, the topology of the proposed matrix reduces to that of a single-layer Butler matrix, connecting hybrid couplers and crossovers with adequate phase shifters. The values of the phase shift required are dependent on the assignment of the output phase differences, which in turn is shown to have an impact on the radiation characteristics of the linear array fed by such networks when imposing constraints on the matrix layout for a more generic implementation. The configuration having the smallest phase difference with reference to the transmission phase of a straight waveguide with the same length as the coupled region of the crossover is chosen and compared with the conventional well-known Butler matrix. The two matrix configurations are implemented using post-wall waveguides designed to operate over the band 20 GHz – 24 GHz. The prototypes are manufactured and tested, using transitions to standard waveguide WR42. The measured results confirm the benefits of the identified optimal adjacent phase difference assignment in terms of transmission coefficients, reflection coefficients, phase differences between adjacent output ports, and frequency dependence of the array factor. These results will also benefit the design of larger generalized one-dimensional parallel switching matrices.
一维四光束并联开关矩阵的最优相邻输出相位差分配
本文首次从矩阵性能的角度详细讨论了广义一维四光束并联开关矩阵中所有可能组合中相邻输出相位差的最佳分配。在这种特殊情况下,所提出的矩阵的拓扑结构减少到单层巴特勒矩阵的拓扑结构,连接混合耦合器和具有适当移相器的交叉器。所需相移的值取决于输出相位差的分配,这反过来又表明,当对矩阵布局施加约束时,这种网络馈送的线性阵列的辐射特性会产生影响,以实现更通用的实现。选择与交叉耦合区长度相同的直波导传输相位相位差最小的结构,并与传统的巴特勒矩阵进行比较。这两种矩阵配置使用后壁波导实现,设计工作在20 GHz - 24 GHz频段。原型制造和测试,使用转换到标准波导WR42。测量结果证实了所确定的最佳相邻相位差分配在传输系数、反射系数、相邻输出端口之间的相位差和阵列因子的频率依赖性方面的好处。这些结果对更大的广义一维并联开关矩阵的设计也有借鉴意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
10.70
自引率
0.00%
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审稿时长
8 weeks
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