Numerical evaluation of ultrasonic pulse-echo subwavelength defect detection

Abstract

The ultrasonic pulse-echo Backscattered Amplitude Integral (BAI)-mode imaging technique [UFFC Trans, 45:30, 1998] has been developed to detect small channel defects in flexible food package seals. This technique detects 38-/spl mu/m-diameter channels reliably and 6-/spl mu/m-diameter channels occasionally using a 17.3-MHz focused transducer in water (20/spl deg/C, /spl lambda/ /spl ap/ 86 /spl mu/m, total sample thickness 22 /spl mu/m). However, interaction between ultrasound and sample microstructure - the underlying detection mechanism is poorly understood. Experimental evidence showed at the subwavelength channel was fused inside the two binding trilaminate plastic package films. Each trilaminate film a three sublayers. Package sample impedance profiles along the ultrasound beam axis were examined. Although identical in nominal impedance properties before sealing, the two binding films showed an asymmetric impedance profile after sealing. A generalized impedance profile model was proposed. The defect detection behavior of the echo signal was investigated by solving the 2D linear acoustic wave equations in fluid with finite-difference time-domain method and the perfectly matched layer absorbing boundary. The normalized correlation coefficients between the simulated and the measured RF echo waveforms were greater than 95% for this generalized model.