TY - JOUR
T1 - Prediction of Reactivity Ratios in Free Radical Copolymerization from Monomer Resonance-Polarity (Q-e) Parameters
T2 - Genetic Programming-Based Models
AU - Shrinivas, K.
AU - Kulkarni, Rahul P.
AU - Shaikh, Saif
AU - Ghorpade, Ravindra V.
AU - Vyas, Renu
AU - Tambe, Sanjeev S.
AU - Ponrathnam, S.
AU - Kulkarni, Bhaskar D.
N1 - Publisher Copyright:
© 2016 by De Gruyter 2016.
PY - 2016/2/1
Y1 - 2016/2/1
N2 - The principal deficiency of the widely utilized Alfrey-Price (AP) scheme for computing reactivity ratios in the widely used free radical copolymerization is that it ignores important factors, such as the steric effects. This often leads to inaccurate reactivity ratio predictions by AP model. Accordingly, in this study, exclusively data-driven, Q-e parameter-based new models have been developed for the reactivity ratio prediction in free radical copolymerization. In the model development, a novel artificial intelligence formalism known as "genetic programming (GP)" that performs symbolic regression has been employed. The GP-based models possess a different functional form than AP model. Further, parameters of GP-based models were fine-tuned using Levenberg-Marquardt (LM) nonlinear regression method. A comparison of AP, GP and GP-LM as well as artificial neural network (ANN)-based models indicates that GP and GP-LM models exhibit superior reactivity ratio prediction accuracy and generalization performance (with correlation coefficient magnitudes close to or greater than 0.9) when compared with AP and ANN models. The GP-based reactivity ratio prediction models developed here due to their higher accuracy and generalization capability have the potential of replacing the widely used AP models.
AB - The principal deficiency of the widely utilized Alfrey-Price (AP) scheme for computing reactivity ratios in the widely used free radical copolymerization is that it ignores important factors, such as the steric effects. This often leads to inaccurate reactivity ratio predictions by AP model. Accordingly, in this study, exclusively data-driven, Q-e parameter-based new models have been developed for the reactivity ratio prediction in free radical copolymerization. In the model development, a novel artificial intelligence formalism known as "genetic programming (GP)" that performs symbolic regression has been employed. The GP-based models possess a different functional form than AP model. Further, parameters of GP-based models were fine-tuned using Levenberg-Marquardt (LM) nonlinear regression method. A comparison of AP, GP and GP-LM as well as artificial neural network (ANN)-based models indicates that GP and GP-LM models exhibit superior reactivity ratio prediction accuracy and generalization performance (with correlation coefficient magnitudes close to or greater than 0.9) when compared with AP and ANN models. The GP-based reactivity ratio prediction models developed here due to their higher accuracy and generalization capability have the potential of replacing the widely used AP models.
KW - Alfrey-Price scheme
KW - free radical copolymerization
KW - genetic programming
KW - reactivity ratio
KW - symbolic regression
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U2 - 10.1515/ijcre-2014-0039
DO - 10.1515/ijcre-2014-0039
M3 - Article
AN - SCOPUS:84959306299
SN - 2194-5748
VL - 14
SP - 361
EP - 372
JO - International Journal of Chemical Reactor Engineering
JF - International Journal of Chemical Reactor Engineering
IS - 1
ER -