Abstract
Laser ultrasonics1 offers a technique for nondestructive, noncontact ultrasonic inspection. Progress has been made,2,3 which may enable this novel diagnostic to find its way into the manufacturing arena. However, the technology has yet to be cost-effective for most industrial end-users. In particular, the need to compensate for workpiece vibrations, relative platform motion, and optical distortions has driven up the system cost, including active stabilization and costly optics. Compensation techniques including optical phase conjugation4,5 and two-wave mixing6 can potentially enhance the performance of laser ultrasonic diagnostics. These schemes enable wavefront-matching of the beams to be coherently detected. However, in some cases, expensive electronic post-processing are required to track out residual mechanical vibrations.
© 1996 Optical Society of America
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