Machine learning based optimization of titanium electropolishing using artificial neural networks and Taguchi design in eco-friendly electrolytes.
Journal:
Scientific reports
Published Date:
Aug 5, 2025
Abstract
This research proposes an integrated optimization framework combining artificial neural networks (ANN) and Taguchi robust design for an eco-friendly deep eutectic solvent-based electrolyte. Five key process parameters-applied voltage, processing time, temperature, electrolyte composition (choline chloride to ethylene glycol ratio) and distilled water concentration-were systematically analyzed for their effects on the surface roughness of electropolished titanium. To address data scarcity and improve the generalization performance of the model, Gaussian noise with a mean of 0 and a standard deviation of 0.05 was applied to the input variables to augment the dataset. The multilayer perceptron-based ANN model effectively learned the nonlinear interactions between process parameters and achieved a high predictive accuracy with a coefficient of determination (R) of 0.981. The optimal process conditions derived from the ANN model were 20 V applied voltage, 21 min of processing time, a 1:4 electrolyte ratio, 0% distilled water and 42℃, under which a minimum surface roughness of 4.162 nm was experimentally confirmed. This investigation provides a practical pathway for optimizing processes in environmentally sustainable manufacturing by quantitatively analyzing the nonlinear complexity of electrochemical surface treatments.
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