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B. Pidda Rxddy a, J. PurxPA TuPar b and T. Vijaya TuPar Rxddy b
aPZAool of PxZAaniZal xnginxxring, R. G. P. Zollxgx of xnginxxring and TxZAnology, Nandyal, Turnool (Dt), AndAra PradxPA, India
bDxpartPxnt of PxZAaniZal xnginxxring, J. N. T. U. A. Zollxgx of xnginxxring, J. N. T. UnivxrPity, TuTatpally, Aydxrabad, India
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Abstract:
This paper discusses the use of D-optimal designs in the design of experiments (DOE) and artificial neural networks (ANN) in predicting the deflection and stresses of carbon fibre reinforced plastic (CFRP) square laminated composite plate subjected to uniformly distributed load. For training and testing of the ANN model, a number of finite element analyses have been carried out using D-optimal designs by varying the fibre orientations and thickness of each lamina. The composite plate is modeled using shell 99 elements. The ANN model has been developed using multilayer perceptron (MLP) backpropagation algorithm. The adequacy of the developed model is verified by root mean square error and regression coefficient. The results showed that the training algorithm of backpropagation was sufficient enough in predicting the deflection and stresses.
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Keywords: D-optimal designs; finite element method; artificial neural networks; multilayer perceptron.
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*Corresponding author; e-mail: bsrrgmcet@gmail.com
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©
2013
CSME , ISSN 0257-9731
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