基于小波域SVD的探地雷达数据直接耦合去波

IF 0.5 4区工程技术 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

Radioengineering Pub Date : 2022-12-01 DOI:10.13164/re.2022.0564

D. Chen, A. Xiang, S. Xiong, L. Wang, L. Guo

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引用次数: 1

摘要

．提出了一种用于探地雷达去除直接耦合波的小波域奇异值分解(SVD)算法。事实上，直接耦合波通常会干扰来自地下目标的反射波。此外，直接耦合波的振幅和能量较大，降低了图像对目标的分辨率，对后续的图像解译工作产生不利影响。对探地雷达信号进行小波分解，得到每一级的近似分量和详细分量。目标信息包含在细节分量的大特征值中，而直接耦合波包含在小特征值中。因此，小波域奇异值分解可以减少对有效信号的误判，提高探地雷达信号的信噪比。仿真和现场探地雷达数据表明，小波域奇异值分解降噪方法对直接耦合波的去除效果优于传统降噪方法，验证了所提降噪方法的有效性。

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Direct Coupled Wave Removal for GPR Data Based on SVD in the Wavelet Domain

. This paper presents a new algorithm of the singular value decomposition (SVD) in the wavelet domain for ground penetrating radar (GPR) to remove direct coupled waves. In fact, direct coupled waves commonly disturb the reﬂecting waves from underground targets. Besides, the amplitude and energy of direct coupled waves are large, which reduces the resolution of the images to the targets and ad-versely aﬀects the subsequent image interpretation work. The GPR signal is decomposed into several levels by Wavelet to obtain approximation components and detailed components of each level. The information of targets is contained in big eigenvalues of detail components, while the direct coupled waves are contained in small ones. Therefore, the SVD in the wavelet domain can reduce the misjudgment of eﬀective signals and improve the signal to noise ratio (SNR) of GPR signals. The simulated and ﬁeld GPR data show that the SVD in the wavelet domain denoising method has better results for direct coupled wave removal than the traditional methods, which validates the eﬀectiveness of the proposed denoising method.

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来源期刊

Radioengineering 工程技术-工程：电子与电气

CiteScore

2.00

自引率

9.10%

发文量

审稿时长

5.7 months

期刊介绍： Since 1992, the Radioengineering Journal has been publishing original scientific and engineering papers from the area of wireless communication and application of wireless technologies. The submitted papers are expected to deal with electromagnetics (antennas, propagation, microwaves), signals, circuits, optics and related fields. Each issue of the Radioengineering Journal is started by a feature article. Feature articles are organized by members of the Editorial Board to present the latest development in the selected areas of radio engineering. The Radioengineering Journal makes a maximum effort to publish submitted papers as quickly as possible. The first round of reviews should be completed within two months. Then, authors are expected to improve their manuscript within one month. If substantial changes are recommended and further reviews are requested by the reviewers, the publication time is prolonged.