Advanced frequency or/and phase modulated excitation waveforms for enhanced depth resolvability of thermal wave radar

2021 IEEE Far East NDT New Technology & Application Forum (FENDT) Pub Date : 2021-12-14 DOI:10.1109/FENDT54151.2021.9749680

Zhitao Luo, Sheng Wang, Xin Wu, Zihao Su, Fei-Long Mao, Hui Zhang

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Abstract

In this paper, a detailed investigation of the depth resolvability performance of thermal wave radar (TWR) in the inspection of composites through advanced frequency or/and phase modulated excitation waveforms is presented. In addition to conventional linear frequency modulated waveform (LFM) and Baker phase modulated waveform, two advanced excitation waveforms, i.e., orthogonal phase-coded linear frequency modulated waveform (OPCLFM) and nonlinear frequency modulated waveform (NLFM), are introduced to enhance depth resolvability of TWR. To evaluate fairly their performance, all aforementioned excitation waveforms are formulated based on the same central frequency. Moreover, both phase contrast and delay time contrast are obtained to quantitatively characterize the depth resolvability of these excitation waveforms by a one-dimensional photothermal diffusion wave model of carbon fiber reinforced polymer (CFRP) laminate. Finally, we demonstrate that a proper window function can further significantly enhance the depth resolvability of TWR.

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提高热波雷达深度分辨率的先进频率或/和相位调制激励波形

本文详细研究了热波雷达(TWR)在复合材料检测中的深度分辨性能，该技术采用先进的频率或/和相位调制激励波形。在常规线性调频波形(LFM)和Baker相位调制波形的基础上，引入正交相位编码线性调频波形(OPCLFM)和非线性调频波形(NLFM)两种先进的激励波形，提高了TWR的深度可分辨性。为了公平地评价它们的性能，上述所有激励波形都是基于相同的中心频率制定的。此外，利用碳纤维增强聚合物(CFRP)层合板的一维光热扩散波模型，获得了相位对比和延迟时间对比，定量表征了这些激励波形的深度可分辨性。最后，我们证明了适当的窗函数可以进一步显著提高TWR的深度可分辨性。

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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2021 IEEE Far East NDT New Technology & Application Forum (FENDT)

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