Title :
Ultrasonic nondestructive evaluation of highly scattering materials using adaptive filtering and detection
Author :
Zhu, Yong ; Weight, John P.
Author_Institution :
Dept. of Electr. Electron. & Inf. Eng., City Univ., London, UK
Abstract :
Adaptive filtering and detection has been applied to the problem of detecting ultrasonic echo signals from test targets where the wanted signals are masked by coherent scattering from grain boundaries present in highly scattering materials. The filter is based on the normalized least mean square (LMS) error algorithm, and can be operated with either an independent reference signal or by using the delayed input signal as the reference. Tests made on a collection of 64 ultrasonic A-scans using the same processing parameters show that an up to 10 dB improvement in signal-to-noise ratio can typically be obtained. A cell-averaging constant false alarm rate (CFAR) detector is used to detect the signals automatically. The performance of the method is compared to that of split spectrum processing, both with and without polarity thresholding.<>
Keywords :
acoustic filters; acoustic signal processing; adaptive filters; flaw detection; grain boundaries; signal detection; ultrasonic materials testing; ultrasonic scattering; adaptive filtering; cell-averaging constant false alarm rate; coherent scattering; delayed input signal; detection; grain boundaries; highly scattering material; highly scattering materials; normalized least mean square error algorithm; polarity thresholding; processing parameters; reference signal; signal-to-noise ratio; test targets; ultrasonic A-scans; ultrasonic echo signals; ultrasonic nondestructive evaluation; Adaptive filters; Adaptive signal detection; Delay; Detectors; Grain boundaries; Least squares approximation; Materials testing; Scattering; Signal detection; Signal to noise ratio;
Journal_Title :
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
