Yinyi Zhao;Udara De Silva;Satheesh B. Venkatakrishnan;Dimitra Psychogiou;Grover Larkins;Arjuna Madanayake
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引用次数: 0
摘要
带内全双工(IBFD)通信系统通过在同一带宽上同时进行发射和接收(STAR),能够将频谱效率提高一倍,因此备受关注。现代通信技术必须进行调整,以满足对现有无线电信道容量的持续高需求。本文提出了一种基于物理对称性的系统级方法,以改善 3 端口环行器的电磁性能。本文提出了一种由两个以差分配置连接的匹配环行器组成的系统级设计,以消除在 STAR 前端造成自干扰的残余射频散射和泄漏。使用基于微带技术定制设计的微波环行器对该方法进行了验证,该环行器构成了一个在 3-8 GHz 频段工作、隔离度为 20 dB 的构件。拟议的射频前端可在 3-8 GHz 的扩展频带内工作,同时 STAR 系统的发射器和接收器端口之间的隔离度提高了约 10 dB(隔离度为 $30\pm 4$ dB)。
STAR Front-End Using Two Circulators in a Differential Connection
In-band full duplex (IBFD) communication systems have attracted much interest due to their ability to double the spectrum efficiency by simultaneously transmitting and receiving (STAR) over the same bandwidth. Modern communication technologies have to adapt to be able to meet the ongoing high demand capacity over existing radio channels. This paper proposes a system-level approach based on physical symmetry to improve the electromagnetic performance of a 3-port circulator. A system-level design consisting of two matched circulators connected in a differential configuration is proposed to cancel out residual RF scattering and leakage that causes self-interference in a STAR front-end. The method is validated using a custom designed microwave circulator based on microstrip technology, which forms a building block that operates in the 3–8 GHz band with 20 dB isolation. The proposed RF front-end operates within an extended band of 3–8 GHz while simultaneously exhibiting improvement in isolation by about 10 dB (isolation
$30\pm 4$
dB) between the transmitter and the receiver ports of the STAR system.
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