Impact Damage Characterization of Composite Materials Based on Independent Component Analysis for Infrared Sequences

YUAN Lihua; HONG Kang; ZHU Yanzhen; XI Tengyan; LI Zhe

doi:10.16080/j.issn1671-833x.2022.20.083

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Impact Damage Characterization of Composite Materials Based on Independent Component Analysis for Infrared Sequences

更新时间：2025-10-30

- Impact Damage Characterization of Composite Materials Based on Independent Component Analysis for Infrared Sequences
- Aeronautical Manufacturing Technology Vol. 65, Issue 20, Pages: 83-91(2022)
- 作者机构：
  
  1. 南昌航空大学无损检测教育部重点实验室,南昌,330063
  2. 中国航发沈阳黎明航空发动机有限责任公司,沈阳,110043
- 作者简介：
- 基金信息：
- DOI：10.16080/j.issn1671-833x.2022.20.083
  CLC：
- Published：2022
- 稿件说明：
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袁丽华，洪康，朱言瑧，习腾彦，李喆. 基于红外序列独立成分分析的复合材料冲击损伤缺陷表征[J]. 航空制造技术, 2022, 65(20): 83-91.

YUAN Lihua, HONG Kang, ZHU Yanzhen, XI Tengyan, LI Zhe. Impact Damage Characterization of Composite Materials Based on Independent Component Analysis for Infrared Sequences[J]. Aeronautical Manufacturing Technology, 2022, 65(20): 83-91.
袁丽华，洪康，朱言瑧，习腾彦，李喆. 基于红外序列独立成分分析的复合材料冲击损伤缺陷表征[J]. 航空制造技术, 2022, 65(20): 83-91. DOI： 10.16080/j.issn1671-833x.2022.20.083.

YUAN Lihua, HONG Kang, ZHU Yanzhen, XI Tengyan, LI Zhe. Impact Damage Characterization of Composite Materials Based on Independent Component Analysis for Infrared Sequences[J]. Aeronautical Manufacturing Technology, 2022, 65(20): 83-91. DOI： 10.16080/j.issn1671-833x.2022.20.083.

摘要

采用独立成分分析方法研究了基于脉冲红外图像的复合材料冲击损伤的缺陷表征问题。首先依据试块脉冲红外试验的先验知识和缺陷与非缺陷之间的温差特性为红外序列图像选取合适的区间段；然后对构建的数据矩阵进行中心化与白化预处理，采用梯度下降法进行独立成分分析，由重构矩阵可得到独立成分特征图像；最后，选择合适的图像分割方法可以获得最大损伤长径和损伤短径的缺陷表征量。以两块不同厚度的碳纤维增强型复合层合板分别在30 J 和40 J 的冲击能量下的损伤缺陷为例，成功提取了冲击损伤的最大损伤长径和损伤短径，并与超声F扫描的结果进行对比，误差在可接受的范围内，尤其是厚度为2 mm 的层合板，误差在5% 以内。研究结果表明，独立成分分析能够有效区分噪声与缺陷，并且获得的特征图像比原始图像的信噪比更高、对比度更大以及图像质量更好，有利于缺陷的提取和表征。

Abstract

The independent component analysis method was used to study the defect characterization problem of composite impact damage based on pulsed infrared images. First

according to the prior knowledge of pulse infrared experiment of test block and the temperature difference between defect and non-defect

the appropriate interval segment was selected for infrared sequence image. Then

centering preprocessing and whitening preprocessing were performed on the constructed data matrix

independent component analysis was performed by gradient descent method

and the independent component feature image can be obtained by reconstructing the matrix. Finally

by choosing an appropriate image segmentation method

the defect characterization quantities of the maximum damage long diameter and damage short diameter can be obtained. Taking the damage defect extraction of two carbon fiber reinforced composite laminates with different thicknesses under the impact energy of 30 J and 40 J

as an example

the maximum damage long diameter and damage short diameter of impact damage were successfully extracted and compared with the results of ultrasonic F-scan. For comparison

the errors are within an acceptable range

especially for the laminate with a thickness of 2 mm

which errors are within 5%. The research results showed that independent component analysis can effectively distinguish noise from defects

and the obtained feature image has higher signal-to-noise ratio

greater contrast and better image quality than the original image

which is beneficial to the extraction and characterization of defects.

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