Title :
Accurate prediction of PQFP warpage
Author :
Kelly, G. ; Lyden, C. ; Lawton, W. ; Barrett, J. ; Saboui, A. ; Exposito, J. ; Lamourelle, F.
Author_Institution :
Nat. Microelectron. Res. Centre, Univ. Coll. Cork, Ireland
Abstract :
This paper addresses the use of finite element techniques to predict warpage in plastic encapsulated IC´s. A basic modeling assumption adopted in such analyses is that after ejection from the mold, warpage occurs due to the contraction of the molding compound as the package cools to room temperature. It is shown that this basic starting assumption can lead to incorrect predictions of the package warpage. Measurements of the warpage of a plastic power package with temperature indicate that the package is significantly deformed at the molding temperature. This is attributed to chemical shrinkage of the molding compound. A new F.E. model of package warpage after encapsulation is proposed which considers both the TCE shrinkage and chemical shrinkage of the molding compound. This leads to accurate predictions of warpage, particularly where heat spreaders make the package asymmetric. Measurements of a 208 lead power PQFP are used to verify this improved model
Keywords :
encapsulation; finite element analysis; integrated circuit packaging; plastic packaging; shrinkage; FE model; PQFP warpage; TCE shrinkage; chemical shrinkage; contraction; encapsulation; finite element techniques; heat spreaders; molding compound; molding temperature; plastic encapsulated ICs; plastic quad flat package; power package; Adhesives; Conducting materials; Electronic packaging thermal management; Encapsulation; Lead; Microelectronics; Plastic packaging; Power measurement; Stress; Temperature;
Conference_Titel :
Electronic Components and Technology Conference, 1994. Proceedings., 44th
Conference_Location :
Washington, DC
Print_ISBN :
0-7803-0914-6
DOI :
10.1109/ECTC.1994.367644
