Abstract
This article combines the sequential artificial neural network (NN) machine learning with finite element (FE) modeling to assess the solder joint thermal cycling performance. A glass wafer-level chip-scale package (G-WLCSP) is used for this study. This article investigates the network structure that can achieve prediction capability both inside and outside the design domain with the minimal required training dataset. First, a detailed FE model for G-WLCSP is developed to obtain the accumulated plastic strain per cycle for thermal-cycling loading. Three critical input parameters are defined to generate a dataset based on finite element analysis. Then, applying the supervised machine learning procedure, both the recurrent neural network (RNN) and the gate-network long short-term memory (LSTM) architecture are used to train the obtained dataset. The network complexity of the sequential NN model is carefully controlled to prevent numerical overfitting. Among the total 81 FE generated data pairs, only 27 data pairs have been applied to the sequential NN learning. These 27 data pairs are carefully selected to evenly distributed among the design domain. The average error norms after the learning are 1.213 · 10 -4 and 1.190 · 10 -4 of RNN and LSTM, respectively. The prediction capability of the well-trained sequential NN model against the rest 54 data pairs has been tested and a similar scale has been obtained. Furthermore, the prediction capability is tested against the parameters outside the design domain. Approximately one order average error norm increased for both the well-trained RNN and LSTM model.
Highlights
Solder joint reliability is one of the most critical issues for most ball-grid array packaging types
Because of the mechanical characteristics, the nonlinear finite element (FE) method has been often applied to predict the solder joint reliability when the structure is subject to the cyclic thermal loading [2]
There only 27 data points will be applied for the sequential neural network (NN) training, and the remaining 54 data points will be used to validate the accuracy of the recurrent neural network (RNN) and long short-term memory (LSTM) model
Summary
Solder joint reliability is one of the most critical issues for most ball-grid array packaging types. Chou et al [15], [16] developed the basic framework of the combination of machine learning and finite element modeling, and has been applied the model the long-term reliability of wafer level packaging using rather large artificial neural network architecture with multiple key design features. A complicated NN structure with large number of neurons and hidden layers would be able to capture the nonlinearity nature, it is required enormous training datasets to prevent the numerical overfitting This vicious cycle limits the application of the NN due to the training sample size and long training time. This article applies two sequential NN methods to model the solder joint risk of glass wafer level chip-scale packaging. This research selects the sequential NN method to build the solder joint regression model
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