Author_Institution :
Arizona Univ., Tucson, AZ, USA
Abstract :
Chip scale packaging (CSP) is emerging as a major player within the semiconductor packaging market. Processing in the back-end requires optimizing the use of intermediate carrier configurations such as tape-in-carrier and strip-based substrates. This optimization of carrier configurations must occur in all processes related to CSP assembly, including die attach, wire bond, encapsulation, ball attach, laser mark, singulate, inspect, and test. CSP is considered an SMT and, as such, can be processed using existing lines. However, CSP is different from SMT and has its own assembly problems. One of the critical problems is that, with thinner package profile requirement, thinner substrate is necessary. Another important problem that should be considered is the failure of solder joints because of the coefficient of thermal expansion mismatch among the substrate, lead packages, and the board when the thermal load is severe. To address this point, several studies using moire interferometry have been conducted to measure thermal deformations that accumulate during thermal cycles.
Keywords :
ball grid arrays; chip scale packaging; encapsulation; interferometry; lead bonding; semiconductor device packaging; surface mount technology; thermal expansion; Moire interferometry; SMT; automated assembly process; ball attach; ball grid array; carrier configurations optimization; die attach; encapsulation; high-volume chip scale packaging; laser mark; semiconductor packaging market; solder joints; strip-based substrates; surface mount technology; tape-in-carrier; thermal deformations; thermal expansion mismatch coefficient; thinner package profile requirement; wire bond; Assembly; Chip scale packaging; Microassembly; Semiconductor device packaging; Substrates; Surface-mount technology; Thermal conductivity; Thermal expansion; Thermal loading; Wire;
