Title :
Metal trace impact life prediction model for stress-buffer-enhanced package
Author :
Chou, C.Y. ; Huang, C.J. ; Sano, M. ; Chiang, K.N.
Author_Institution :
Adv. Packaging Res. Center, Nat. Tsing Hua Univ., Hsinchu, Taiwan
Abstract :
In this study, the objective is to develop a proper impact life prediction model for stress-buffer-enhanced package which has a specific failure mode, the broken metal trace, during board level drop test. The so called stress-buffer-enhanced package applies a thick and soft buffer layer to protect solder joints; however, metal traces embedded inside the buffer layer are instead broken. The broken metal trace is not common for board level drop test, and there are few life prediction models to predict the performance of the package. Unlike thermal cycle test, the dynamic response of drop impact is irregular and not cyclic; therefore, the concept of cumulative damage is considered in the life prediction model. The results showed that the cumulative plastic strain of metal trace could accurately predict impact life.
Keywords :
failure analysis; impact testing; integrated circuit packaging; integrated circuit reliability; integrated circuit testing; solders; thermal analysis; board level drop test; broken metal trace; cumulative plastic strain; metal trace impact life prediction model; soft buffer layer; solder joint protection; specific failure mode; stress-buffer-enhanced package; surface mounted IC package; thermal cycle test; thick buffer layer; Adhesives; Consumer electronics; Electronics packaging; Lamination; Predictive models; Protection; Resists; Shape; Temperature; Thermal resistance; drop test; fatigue; life prediction; trace failure;
Conference_Titel :
Microelectronics and Packaging Conference, 2009. EMPC 2009. European
Conference_Location :
Rimini
Print_ISBN :
978-1-4244-4722-0
Electronic_ISBN :
978-0-6152-9868-9
