论文信息 - Inspection of Flip-Chip Epoxy Underfill in Microelectronic Assemblies Using Compensated Laser-Based Ultrasonic Receivers

Inspection of Flip-Chip Epoxy Underfill in Microelectronic Assemblies Using Compensated Laser-Based Ultrasonic Receivers

In the industrial community, there is a need for process control and inspection tools that can improve the efficiency, yield and performance of various manufacturing processes including bonds, surface treatments, case hardening, composites, metallurgy, microcrack detection, adhesion, remote temperature and thickness measurements. By performing the inspection on-line and in real-time, the possibility exists for closed-loop, in-process control. This can lead to reducing cost, labor, scrap, and machine downtime. Conventional ultrasonic methods can be employed to diagnose many materials, in that their acoustic properties are typically functions of the parameters to be ascertained. Present techniques, such as liquid immersion, jet-spray approaches, air-coupled and direct transducer contacting may be of limited use in many process-control applications, including those involving vacuums, high temperatures, plasmas, and workpieces with highly structured and complex surfaces.

[1] G. J. Dunning,et al. Characterization of the photo-EMF response for laser-based ultrasonic sensing under simulated industrial conditions , 1998 .

[2] Gilmore J. Dunning,et al. Double-Pumped Conjugators and Photo-Induced EMF Sensors: Two Novel, High-Bandwidth, Auto-Compensating, Laser-Based Ultrasound Detectors , 1996 .

[3] Gilmore J. Dunning,et al. Compensated laser-based ultrasonic receiver for industrial applications , 1997 .

[4] Gilmore J. Dunning,et al. Remote Laser-Based Ultrasonic Inspection of Weld Joints for High Volume Industrial Applications , 1996 .

[5] Gilmore J. Dunning,et al. A New Concept for a Laser-Based Ultrasonic Phased Array Receiver Using Photo-emf Detection , 1998 .

[6] Gilmore J. Dunning,et al. Materials inspection and process control using compensated laser ultrasound evaluation (CLUE): demonstration of a low-cost laser ultrasonic sensor , 1996, Photonics West.

[7] Jean F. Bussière,et al. Nondestructive Characterization of Materials II , 1987 .

[8] L. Drain,et al. Laser Ultrasonics Techniques and Applications , 1990 .

[9] A. Blouin,et al. Heterodyne Detection of Ultrasound from Rough Surfaces Using a Double Phase Conjugate Mirror , 1995 .

[10] J. Monchalin. Optical Detection of Ultrasound , 1986, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.