Da Yu, Hongmei Liu, Yan Zhang, Zhongbao Wang, Shaojun Fang
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By using only one voltage to control the phase shifts of the T-PS in a 90° range for each input excitation of the Nolen matrix, a full 360° range of the progressive phase difference is realized by switching four input ports. The measured fractional bandwidth under 10 dB return loss and isolation is larger than 24.5% with the in − band ± 1.5 dB amplitude imbalance and ±15° phase deviation error for ports 1-4 excitations. Besides, for a more strict criterion of ±1 dB amplitude imbalance and 10° phase deviation error, the measured bandwidths are larger than 15% for all port excitations.</p>\n </div>","PeriodicalId":54944,"journal":{"name":"International Journal of RF and Microwave Computer-Aided Engineering","volume":"2024 1","pages":""},"PeriodicalIF":0.9000,"publicationDate":"2024-01-27","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1155/2024/8835630","citationCount":"0","resultStr":"{\"title\":\"Wideband 4 × 4 Nolen Matrix with 360° Continuously Tuned Differential Phase and Low In-Band Phase Deviation Error\",\"authors\":\"Da Yu, Hongmei Liu, Yan Zhang, Zhongbao Wang, Shaojun Fang\",\"doi\":\"10.1155/2024/8835630\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div>\\n <p>In the paper, a wideband tunable 4 × 4 Nolen matrix is proposed. 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The measured fractional bandwidth under 10 dB return loss and isolation is larger than 24.5% with the in − band ± 1.5 dB amplitude imbalance and ±15° phase deviation error for ports 1-4 excitations. 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引用次数: 0
摘要
本文提出了一种宽带可调 4×4 诺伦矩阵。利用所提出的诺伦矩阵拓扑结构,通过插入一种可调相移器(T-PS),可实现输出端口相位差的可调。此外,通过在诺伦矩阵的输出端口添加补偿移相器(C-PS),可将带内相位偏差误差降至最低。本文给出了基于信号流图和复指数信号的分析设计方法,以获得诺伦矩阵中耦合和相移的严格关系。此外,还提供了输出端口相位斜率补偿的详细方法。为进行验证,设计并制造了一个以 5.8 GHz 为中心的原型。测量结果与模拟结果十分吻合。对于诺伦矩阵的每个输入激励,只需使用一个电压来控制 90° 范围内的 T-PS 相移,就能通过切换四个输入端口来实现 360° 范围内的渐进相位差。在 10 dB 回波损耗和隔离度条件下,端口 1-4 的带内 ±1.5 dB 振幅不平衡和 ±15° 相位偏差误差的测量分数带宽大于 24.5%。此外,对于更严格的 ±1 dB 振幅不平衡和 10° 相位偏差误差标准,所有端口激励的测量带宽均大于 15%。
Wideband 4 × 4 Nolen Matrix with 360° Continuously Tuned Differential Phase and Low In-Band Phase Deviation Error
In the paper, a wideband tunable 4 × 4 Nolen matrix is proposed. By using the presented topology of the Nolen matrix, tunable output port phase differences can be realized by inserting one type of tunable phase shifters (T-PS). Besides, the in-band phase deviation error is minimized by adding compensation phase shifters (C-PSs) to the output ports of the Nolen matrix. Analytical design methods based on signal flow graphs and complex exponential signal are given to obtain the rigorous relationships of the coupling and phase shifts in the Nolen matrix. Besides, a detailed method for output ports phase slope compensation is provided. For validation, a prototype centered at 5.8 GHz is designed and fabricated. Measurement results agree well with the simulated ones. By using only one voltage to control the phase shifts of the T-PS in a 90° range for each input excitation of the Nolen matrix, a full 360° range of the progressive phase difference is realized by switching four input ports. The measured fractional bandwidth under 10 dB return loss and isolation is larger than 24.5% with the in − band ± 1.5 dB amplitude imbalance and ±15° phase deviation error for ports 1-4 excitations. Besides, for a more strict criterion of ±1 dB amplitude imbalance and 10° phase deviation error, the measured bandwidths are larger than 15% for all port excitations.
期刊介绍:
International Journal of RF and Microwave Computer-Aided Engineering provides a common forum for the dissemination of research and development results in the areas of computer-aided design and engineering of RF, microwave, and millimeter-wave components, circuits, subsystems, and antennas. The journal is intended to be a single source of valuable information for all engineers and technicians, RF/microwave/mm-wave CAD tool vendors, researchers in industry, government and academia, professors and students, and systems engineers involved in RF/microwave/mm-wave technology.
Multidisciplinary in scope, the journal publishes peer-reviewed articles and short papers on topics that include, but are not limited to. . .
-Computer-Aided Modeling
-Computer-Aided Analysis
-Computer-Aided Optimization
-Software and Manufacturing Techniques
-Computer-Aided Measurements
-Measurements Interfaced with CAD Systems
In addition, the scope of the journal includes features such as software reviews, RF/microwave/mm-wave CAD related news, including brief reviews of CAD papers published elsewhere and a "Letters to the Editor" section.
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