DocumentCode
3098133
Title
Higher-order statistics-based deconvolution of ultrasonic nondestructive testing signals
Author
Yamani, Ahmed ; Bettayeb, Maamar ; Ghouti, Lahouari
Author_Institution
King Fahd Univ. of Pet. & Miner., Dhahran, Saudi Arabia
fYear
1997
fDate
21-23 Jul 1997
Firstpage
214
Lastpage
218
Abstract
Pulse-echo reflection techniques are used for ultrasonic flaw detection in most commercial instruments. As the measured pulse echo signal is assumed to be the result of linearly convolving the defect impulse response (IR) with the measurement system response the objective is thus, to remove the effect of the measurement system through a deconvolution operation and extract the defect impulse response. The major drawback of conventional second-order statistics (SOS)-based deconvolution techniques are their inability to identify non-minimum phase systems, and their sensitivity to additive Gaussian noise. Our contribution is to show that higher-order statistics (HOS)-based deconvolution techniques are more suitable to unravel the effects of the measurement systems and the additive Gaussian noise. Synthetic as well as real ultrasonic signals are used to support this claim
Keywords
Gaussian noise; acoustic convolution; deconvolution; higher order statistics; interference suppression; transient response; ultrasonic materials testing; ultrasonic reflection; additive Gaussian noise; defect impulse response; higher-order statistics-based deconvolution; measurement system response; nonminimum phase systems; pulse-echo reflection techniques; ultrasonic flaw detection; ultrasonic nondestructive testing signals; Additive noise; Deconvolution; Displays; Gaussian noise; Instruments; Noise measurement; Nondestructive testing; Pulse measurements; Signal processing; Ultrasonic variables measurement;
fLanguage
English
Publisher
ieee
Conference_Titel
Higher-Order Statistics, 1997., Proceedings of the IEEE Signal Processing Workshop on
Conference_Location
Banff, Alta.
Print_ISBN
0-8186-8005-9
Type
conf
DOI
10.1109/HOST.1997.613518
Filename
613518
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