DOA Estimation With Nested Arrays in Impulsive Noise Scenario: An Adaptive Order Moment Strategy

IF 2.9 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE open journal of signal processing Pub Date : 2024-01-31 DOI:10.1109/OJSP.2024.3360896

Xudong Dong;Jun Zhao;Jingjing Pan;Meng Sun;Xiaofei Zhang;Peihao Dong;Yide Wang

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引用次数: 0

Abstract

Most of the existing direction of arrival (DOA) estimation methods in impulsive noise scenario are based on the fractional low-order moment statistics (FLOSs), such as the robust covariation-based (ROC), fractional low-order moment (FLOM), and phased fractional low-order moment (PFLOM). However, an unknown order moment parameter

$p$

needs to be selected in these approaches, which inevitably increases the computational load if the optimal value of the parameter

$p$

is determined by a large number of Monte Carlo experiments. To address this issue, we propose the adaptive order moment function (AOMF) and improved AOMF (IAOMF), which are applicable to the existing FLOSs-based methods and can also be extended to the case of sparse arrays. Moreover, we analyze the performance of AOMF and IAOMF, and simulation experiments verify the effectiveness of proposed methods.

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脉冲噪声场景下嵌套阵列的 DOA 估计：自适应阶矩策略

现有的脉冲噪声场景下的到达方向（DOA）估计方法大多基于分数低阶矩统计（FLOS），如基于鲁棒协方差（ROC）、分数低阶矩（FLOM）和相位分数低阶矩（PFLOM）。然而，在这些方法中，需要选择一个未知的阶矩参数 $p$，如果参数 $p$ 的最优值是通过大量蒙特卡罗实验确定的，则不可避免地会增加计算负荷。为了解决这个问题，我们提出了自适应阶矩函数（AOMF）和改进的自适应阶矩函数（IAOMF），它们适用于现有的基于 FLOSs 的方法，也可以扩展到稀疏阵列的情况。此外，我们还分析了 AOMF 和 IAOMF 的性能，并通过仿真实验验证了所提方法的有效性。

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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