A Self-Mixing Receiver for Wireless Frequency Synchronization in Coherent Distributed Arrays

2020 IEEE/MTT-S International Microwave Symposium (IMS) Pub Date : 2020-08-01 DOI:10.1109/IMS30576.2020.9223809

Serge R. Mghabghab, J. Nanzer

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引用次数: 7

Abstract

A self-mixing receiver support distributed frequency locking in coherent distributed antenna arrays is presented. Coherent distributed antenna arrays require accurate phase, frequency, and time alignment. However, each node in the distributed array generates its frequency using independent oscillators, and thus without appropriate frequency synchronization the emitted signals will not appropriately cohere. In this paper, we present a one-way frequency transfer approach that uses a self-mixing circuit architecture in a master-slave synchronization architecture. The master node transmits a multi-tone signal that consists of two tones separated by a 10 MHz frequency reference. The self-mixing circuit receives and demodulates this signal by splitting it and then passing it to the radio-frequency (RF) and local oscillator (LO) terminals of a mixer. The resulting signal is filtered to retain only the 10 MHz modulation, which is used to discipline the oscillator on the slave node. We present experimental results using software-defined radio, showing wireless synchronization via a cabled distributed beamforming experiment at 1.5 GHz.

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一种用于相干分布阵列无线频率同步的自混频接收机

提出了一种在相干分布式天线阵列中支持分布式频率锁定的自混频接收机。相干分布式天线阵列需要精确的相位、频率和时间对准。然而，分布式阵列中的每个节点使用独立的振荡器产生其频率，因此如果没有适当的频率同步，则发射的信号将无法适当地相干。在本文中，我们提出了一种单向频率传输方法，该方法在主从同步架构中使用自混合电路架构。主节点发送多音信号，该信号由以10mhz频率基准分隔的两个音组成。自混频电路接收并解调该信号，将其分离，然后将其传递给混频器的射频(RF)和本振(LO)端子。产生的信号被过滤以仅保留10mhz调制，用于约束从节点上的振荡器。我们展示了使用软件定义无线电的实验结果，展示了通过1.5 GHz的电缆分布式波束形成实验实现的无线同步。

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2020 IEEE/MTT-S International Microwave Symposium (IMS)

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