Numerical simulation of the electrical performance of printed circuit boards under cyclic thermal loads

Different Printed Circuit Board (PCB) designs were tested in an Interconnection Stress Test. In such a test, PCBs were subjected to temperature cycles alternating between two extremes (e.g. −40°C to 160°C). The electrical resistance was measured on-line during these tests. If the resistance rose by...

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Veröffentlicht in:	Microelectronics and reliability 2016-07, Vol.62, p.148-155
Hauptverfasser:	Fellner, Klaus, Antretter, Thomas, Fuchs, Peter F., Tao, Qi
Format:	Artikel
Sprache:	eng
Schlagworte:	Boards Circuit boards Computer simulation Copper Cyclic plasticity Cyclic thermal loads Decoupled mechanical-electrical simulation Finite element method Mathematical models Pore growth Porosity Printed Circuit Board Printed circuits Volume fraction
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creator	Fellner, Klaus Antretter, Thomas Fuchs, Peter F. Tao, Qi
description	Different Printed Circuit Board (PCB) designs were tested in an Interconnection Stress Test. In such a test, PCBs were subjected to temperature cycles alternating between two extremes (e.g. −40°C to 160°C). The electrical resistance was measured on-line during these tests. If the resistance rose by more than 10% of the initial value at the highest temperature, the test was terminated. The PCB structures were modeled by means of the Finite Element Analysis (FEA) Software Abaqus using a viscoplastic material model extended by a mean backstress memorization for the domain representing the copper interconnections. The stress/strain states computed by Abaqus served as input to a pore growth model which eventually allowed working out an indicator for the electrical performance loss. Subsequently, electrical FEA were conducted to obtain a correlation between the pore volume fraction distributed over the structure and the electrical resistance increase. The results of the simulations were compared to experimental results to determine parameters for the pore growth model. A well calibrated pore fraction evolution law allowed reliably predicting the electrical performance of various PCB designs as well as drawing some conclusions on the initial pore volume fraction in the PCB prior to operation. •Different Printed Circuit Board (PCB) designs were tested in a thermal cycle test.•PCBs were modeled by finite element analysis using a viscoplastic material model.•Damage assessment through pore growth model•Decoupled mechanical – electrical simulation•Modeling of the electrical resistance and comparison to experimental results
doi_str_mv	10.1016/j.microrel.2016.03.034
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source	ScienceDirect Journals (5 years ago - present)
subjects	Boards Circuit boards Computer simulation Copper Cyclic plasticity Cyclic thermal loads Decoupled mechanical-electrical simulation Finite element method Mathematical models Pore growth Porosity Printed Circuit Board Printed circuits Volume fraction
title	Numerical simulation of the electrical performance of printed circuit boards under cyclic thermal loads
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