Wireless Distributed Frequency and Phase Synchronization for Mobile Platforms in Cooperative Digital Radar Networks

IEEE Transactions on Radar Systems Pub Date : 2024-02-22 DOI:10.1109/TRS.2024.3369043

Russell H. Kenney;Justin G. Metcalf;Jay W. McDaniel

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Abstract

To continue improving the performance of modern communications and radar remote sensing systems, the implementation of distributed radio frequency (RF) systems has become an increasingly active area of research. One major obstacle to implementing such a distributed network is achieving highly accurate synchronization of all RF electrical states – time, carrier phase, and carrier frequency – as without such synchronization, coherent operation amongst all systems in the network is impossible. Many techniques for achieving synchronization are not accurate enough for application in RF phase and frequency synchronization and thus cannot be applied in such networks. Others are hardware-based, making them difficult to apply to legacy systems. Moreover, many synchronization procedures require external references for establishing synchronization of one or more of the RF electrical states, limiting their application to scenarios where such external references are unavailable. Finally, many techniques are not tolerant of relative motion between platforms, making them less useful for systems such as distributed synthetic aperture radar (SAR) systems. In this paper, an RF synchronization procedure is proposed. Though its intended application is distributed radar sensor networks, it is applicable to any distributed network requiring RF coordination, such as distributed RF communication systems. The technique is capable of achieving synchronization of time, carrier phase, and carrier frequency, and can do so without external references or additional hardware. Moreover, the technique is scalable to large networks and is capable of compensating for relative motion-induced synchronization errors. The proposed technique is validated in simulations for a wide variety of operating conditions, and a three-sensor distributed SAR simulation is provided to demonstrate the effectiveness of the proposed technique in a mobile distributed radar scenario.

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合作数字雷达网络中移动平台的无线分布式频率和相位同步

为了不断提高现代通信和雷达遥感系统的性能，分布式射频（RF）系统的实施已成为一个日益活跃的研究领域。实现这种分布式网络的一个主要障碍是实现所有射频电状态（时间、载波相位和载波频率）的高精度同步，因为没有这种同步，网络中所有系统之间就不可能实现一致运行。许多实现同步的技术不够精确，无法应用于射频相位和频率同步，因此无法应用于此类网络。还有一些技术是基于硬件的，因此很难应用于传统系统。此外，许多同步程序需要外部基准来建立一个或多个射频电气状态的同步，这就限制了它们在没有外部基准的情况下的应用。最后，许多技术不能容忍平台之间的相对运动，因此对分布式合成孔径雷达 (SAR) 系统等系统的作用较小。本文提出了一种射频同步程序。虽然其目标应用是分布式雷达传感器网络，但它适用于任何需要射频协调的分布式网络，如分布式射频通信系统。该技术能够实现时间、载波相位和载波频率的同步，而且无需外部参考或额外硬件。此外，该技术还可扩展到大型网络，并能补偿相对运动引起的同步误差。该技术在各种工作条件下进行了模拟验证，并提供了一个三传感器分布式合成孔径雷达模拟，以证明该技术在移动分布式雷达场景中的有效性。

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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IEEE Transactions on Radar Systems

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