Determination of Antoine Equation Parameters for Methane and Isopropyl Alcohol using Differential Evolution
DOI:
https://doi.org/10.19180/1809-2667.v24n12022p168-180Keywords:
Thermodynamic Model, Inverse Problems, Statistical Inference, OptimizationAbstract
Differential Evolution is an optimization method, from the class of Evolutionary Algorithms, inspired by the principles of biological evolution and it uses the operators of mutation, crossover, and selection of individuals from the same population to carry out the search for the optimal solution. Some thermodynamic models such as the Antoine equation relate saturated vapor pressure to temperature through an analytical mathematical relationship. In this article, the Differential Evolution algorithm was used to determine the coefficients of the Antoine equation for Methane and Isopropyl Alcohol in order to be compared with the parameters found in the literature. For this purpose, experimental data available from the Dortmund Data Bank were used. It was observed that the pressure predictions calculated using the parameters obtained by the Differential Evolution presented a greater agreement with the experimental data when compared with the predictions obtained through the parameters consulted in the literature.Downloads
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