Mitigation of correlated non-linearities in digital phased arrays using channel-dependent phase shifts

IEEE MTT-S International Microwave Symposium Digest, 2003 Pub Date : 2003-06-08 DOI:10.1109/MWSYM.2003.1210426

L. Howard, N.K. Simon, D. Rabideau

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引用次数: 16

Abstract

In an active phased array, each Transmitter/Receiver Module (TRM) performs a set of approximately linear functions (e.g., amplification, mixing, etc.) with the resulting signals later combined via beamforming techniques. Since these nearly-linear functions are performed prior to beamforming, it is theoretically possible to improve upon the dynamic range (DR) of each TRM through post-module array integration gain. It has been demonstrated, however, that DR enhancement may be limited by correlated nonlinear distortion (i.e., correlated from module to module). A general technique that ensures nonlinearities do not add constructively from module to module has been proposed recently, and verified experimentally for a special case. Another special case of the general technique has been described analytically, but with no experimental verification. In this paper, we correct a flaw in this analysis, and extend it. Measurements on a thirteen channel digital phased array demonstrate that introducing random phase shifts into an array can substantially mitigate nonlinear distortion, thus improving DR over the array.

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利用信道相关相移缓解数字相控阵中的相关非线性

在有源相控阵中，每个发送/接收模块(TRM)执行一组近似线性函数(例如，放大，混合等)，然后通过波束形成技术将产生的信号组合在一起。由于这些近线性函数是在波束形成之前执行的，因此理论上可以通过模块后阵列集成增益来提高每个TRM的动态范围(DR)。然而，已经证明，DR增强可能受到相关非线性失真(即从模块到模块相关)的限制。最近提出了一种通用的技术，以确保非线性不会在模块之间建设性地增加，并在一个特殊情况下进行了实验验证。一般技术的另一个特殊情况已被分析描述，但没有实验验证。在本文中，我们修正了这一分析中的一个缺陷，并对其进行了扩展。对13通道数字相控阵的测量表明，在阵列中引入随机相移可以大大减轻非线性失真，从而提高阵列的DR。

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 MTT-S International Microwave Symposium Digest, 2003

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