First steps towards an innovative compressive sampling based-THz imaging system for early crack detection on aereospace plates

2014 IEEE Metrology for Aerospace (MetroAeroSpace) Pub Date : 2014-05-29 DOI:10.1109/METROAEROSPACE.2014.6865974

L. Angrisani, F. Bonavolontã, R. S. L. Moriello, A. Andreone, R. Casini, G. Papari, D. Accardo

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引用次数: 20

Abstract

The paper deals with the problem of early detecting cracks in composite materials for avionic applications. In particular, the authors present a THz imaging system that exploits compressive sampling (CS) to detect submillimeter cracks with a reduced measurement burden. Traditional methods for THz imaging usually involve raster scan of the issue of interest by means of highly collimated radiations and the corresponding image is achieved by measuring the received THz power in different positions (pixels) of the desired image. As it can be expected, the higher the required resolution, the longer the measurement time. On the contrary, two different approaches for THz imaging (namely, continuous wave and time domain spectroscopy) combined with a proper CS solution are used to assure as good results as those granted by traditional raster scan; a proper set of masks (each of which characterized by a specific random pattern) are defined to the purpose. A number of tests conducted on simulated data highlighted the promising performance of the proposed method thus suggesting its implementation in an actual measurement setup.

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迈向创新的基于压缩采样的太赫兹成像系统的第一步，用于航空航天板材的早期裂纹检测

本文研究了航空电子用复合材料裂纹的早期检测问题。特别是，作者提出了一种太赫兹成像系统，该系统利用压缩采样(CS)来检测亚毫米裂纹，同时减少了测量负担。传统的太赫兹成像方法通常涉及通过高度准直辐射对感兴趣的问题进行光栅扫描，并通过测量所需图像的不同位置(像素)的接收太赫兹功率来获得相应的图像。可以预见的是，要求的分辨率越高，测量时间越长。相反，两种不同的太赫兹成像方法(即连续波和时域光谱)与适当的CS解决方案相结合，可以确保与传统光栅扫描一样好的结果;为了达到这个目的，定义了一组适当的掩码(每个掩码都具有特定的随机模式)。在模拟数据上进行的一些测试突出了所提出的方法的良好性能，从而建议在实际测量设置中实施。

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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2014 IEEE Metrology for Aerospace (MetroAeroSpace)

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