Development of Empirical Equations for Metal Trace Failure Prediction of Wafer Level Package Under Board Level Drop Test

Accompanying the increasing popularity of portable and handheld products, high reliability for board level drop test becomes a great concern for semiconductor and electronic product manufacturers. Meanwhile, for design purpose, a reliable impact life prediction model is also a must in estimating the...

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Veröffentlicht in:	IEEE transactions on advanced packaging 2010-08, Vol.33 (3), p.681-689
Hauptverfasser:	CHOU, Chan-Yen, HUNG, Tuan-Yu, HUANG, Chao-Jen, CHIANG, Kuo-Ning
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied sciences Capacitive sensors Computer simulation Design. Technologies. Operation analysis. Testing Drop test Drop tests Dynamic response Electronic equipment testing Electronics Electronics packaging Equations Exact sciences and technology finite element analysis impact impact life prediction Impact tests Integrated circuits Life prediction Mathematical models Packages Plastic deformation Plastics Predictive models Semiconductor device packaging Semiconductor device reliability Semiconductor device testing Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices Semiconductors Testing, measurement, noise and reliability Wafer scale integration
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container_title	IEEE transactions on advanced packaging
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creator	CHOU, Chan-Yen HUNG, Tuan-Yu HUANG, Chao-Jen CHIANG, Kuo-Ning
description	Accompanying the increasing popularity of portable and handheld products, high reliability for board level drop test becomes a great concern for semiconductor and electronic product manufacturers. Meanwhile, for design purpose, a reliable impact life prediction model is also a must in estimating the performance of packages subjected to drop impact. In this study, a stress-buffer-enhanced package is proposed to meet the high drop test performance requirement. Both the drop test experiment and numerical simulation were performed. The experimental drop test results showed that a different failure mode, the broken metal trace at package side, was observed in the stress-buffer-enhanced package. Several drop test simulations were conducted to elucidate the mechanical behavior of the test board and packages during the blink of impact. Based on the simulation results, a metal trace impact life prediction model is then developed for the novel stress-buffer-enhanced package to forecast the number of drops. Unlike the thermal cycle test, the dynamic response of the drop impact is irregular and not cyclic. As such, the concept of cumulative damage is considered in the life prediction model. Several characteristics of the metal trace dynamic response, the cumulative fatigue life, the cumulative plastic strain, and the cumulative effective plastic deformation, were studied during the development of the life prediction model. The results showed that the cumulative plastic strain of the metal trace could accurately predict impact life.
doi_str_mv	10.1109/TADVP.2010.2042447
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Meanwhile, for design purpose, a reliable impact life prediction model is also a must in estimating the performance of packages subjected to drop impact. In this study, a stress-buffer-enhanced package is proposed to meet the high drop test performance requirement. Both the drop test experiment and numerical simulation were performed. The experimental drop test results showed that a different failure mode, the broken metal trace at package side, was observed in the stress-buffer-enhanced package. Several drop test simulations were conducted to elucidate the mechanical behavior of the test board and packages during the blink of impact. Based on the simulation results, a metal trace impact life prediction model is then developed for the novel stress-buffer-enhanced package to forecast the number of drops. Unlike the thermal cycle test, the dynamic response of the drop impact is irregular and not cyclic. As such, the concept of cumulative damage is considered in the life prediction model. Several characteristics of the metal trace dynamic response, the cumulative fatigue life, the cumulative plastic strain, and the cumulative effective plastic deformation, were studied during the development of the life prediction model. The results showed that the cumulative plastic strain of the metal trace could accurately predict impact life.</description><identifier>ISSN: 1521-3323</identifier><identifier>EISSN: 1557-9980</identifier><identifier>DOI: 10.1109/TADVP.2010.2042447</identifier><identifier>CODEN: ITAPFZ</identifier><language>eng</language><publisher>Piscataway, NJ: IEEE</publisher><subject>Applied sciences ; Capacitive sensors ; Computer simulation ; Design. Technologies. Operation analysis. Testing ; Drop test ; Drop tests ; Dynamic response ; Electronic equipment testing ; Electronics ; Electronics packaging ; Equations ; Exact sciences and technology ; finite element analysis ; impact ; impact life prediction ; Impact tests ; Integrated circuits ; Life prediction ; Mathematical models ; Packages ; Plastic deformation ; Plastics ; Predictive models ; Semiconductor device packaging ; Semiconductor device reliability ; Semiconductor device testing ; Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices ; Semiconductors ; Testing, measurement, noise and reliability ; Wafer scale integration</subject><ispartof>IEEE transactions on advanced packaging, 2010-08, Vol.33 (3), p.681-689</ispartof><rights>2015 INIST-CNRS</rights><rights>Copyright The Institute of Electrical and Electronics Engineers, Inc. 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Meanwhile, for design purpose, a reliable impact life prediction model is also a must in estimating the performance of packages subjected to drop impact. In this study, a stress-buffer-enhanced package is proposed to meet the high drop test performance requirement. Both the drop test experiment and numerical simulation were performed. The experimental drop test results showed that a different failure mode, the broken metal trace at package side, was observed in the stress-buffer-enhanced package. Several drop test simulations were conducted to elucidate the mechanical behavior of the test board and packages during the blink of impact. Based on the simulation results, a metal trace impact life prediction model is then developed for the novel stress-buffer-enhanced package to forecast the number of drops. Unlike the thermal cycle test, the dynamic response of the drop impact is irregular and not cyclic. As such, the concept of cumulative damage is considered in the life prediction model. Several characteristics of the metal trace dynamic response, the cumulative fatigue life, the cumulative plastic strain, and the cumulative effective plastic deformation, were studied during the development of the life prediction model. The results showed that the cumulative plastic strain of the metal trace could accurately predict impact life.</description><subject>Applied sciences</subject><subject>Capacitive sensors</subject><subject>Computer simulation</subject><subject>Design. Technologies. Operation analysis. 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subjects	Applied sciences Capacitive sensors Computer simulation Design. Technologies. Operation analysis. Testing Drop test Drop tests Dynamic response Electronic equipment testing Electronics Electronics packaging Equations Exact sciences and technology finite element analysis impact impact life prediction Impact tests Integrated circuits Life prediction Mathematical models Packages Plastic deformation Plastics Predictive models Semiconductor device packaging Semiconductor device reliability Semiconductor device testing Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices Semiconductors Testing, measurement, noise and reliability Wafer scale integration
title	Development of Empirical Equations for Metal Trace Failure Prediction of Wafer Level Package Under Board Level Drop Test
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