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Time-frequency optimal feature extraction method
based on SFFS algorithm for defects recognition |
| CHE Hong-kun, LV Fu-zai, XIANG Zhan-qin |
| Institute of Modern Manufacturing Engineering, Zhejiang University, Hangzhou 310027, China |
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Abstract A new time-frequency optimal feature extraction method based on wavelet packet decomposition and sequential forward floating selection (SFFS) algorithm was presented in order to improve the correct rate and generalization in defects recognition through ultrasonic inspection. This method composes supervised and unsupervised feature extraction technologies to achieve better recognition performance by partial using prior classificatory information of samples. Theories evolved in the new method were introduced, including wavelet packet transform, Fisher criterion and SFFS algorithm. In order to verify the effectiveness of the new method in defect recognition, tests were carried out with four kinds of typical defects on oil casing pipes. Three traditional feature extraction methods from time domain, frequency and wavelet packet domain were employed respectively for performance comparison,and all the feature sets obtained by different methods were classified with support machine algorithm. The experimental results of 10 groups of random selected samples show that the new method can identify the defects effectively with a best recognition rate of 93.3% and an average rate of 89.5%.Compared to the three traditional methods mentioned above, the new method can achieve higher recognition rate and better generalization performance and is less sensitive to the selection of training samples.
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Published: 01 December 2011
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基于顺序向前浮动搜索时频优选特征的缺陷识别
为提高超声检测缺陷识别的正确率和泛化能力,提出一种基于小波包分解和顺序向前浮动搜索(SFFS)算法的时频最优特征提取方法.该方法结合了无监督和有监督特征提取方法的优点,局部利用样本的先验分类信息以期达到更好的识别效果.介绍上述特征提取方法中的相关理论,包括小波包变换、Fisher判据以及SFFS搜索算法.为了验证新方法的在缺陷识别方面的有效性,对石油套管上的4种典型缺陷进行识别实验.分别采用3种传统的特征提取方法,从时域、频域和小波包域提取特征用于对比实验,并采用支持向量机算法对上述不同途径获取的特征集进行识别.10组随机抽样的识别实验表明:采用小波包时频SFFS优选特征能够对上述缺陷进行有效识别,最高识别率达到93.3%,平均识别率达到89.5%.与上述3种传统的特征提取方法相比,该新方法识别率高、泛化性好,对训练样本选的选择敏感性小.
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