A novel physics-informed neural networks approach (PINN-MT) to solve mass transfer in plant cells during drying

“…They further assessed the feasibility of using PINN to predict cellular-level mass loss and subsequent moisture variations during low-temperature drying. It was found that compared to benchmark finite element analysis results, the prediction percentage errors of mass loss and moisture distribution remained below 0.23% and 0.33%, respectively, indicating that PINN is an effective computational approach for solving the mass transfer model for a plant cell during drying . Xuan et al introduced an approach that combines physics-informed learning with a residual points-adding optimization method for refrigerant filling mass flow metering.…”

“…It was found that compared to benchmark finite element analysis results, the prediction percentage errors of mass loss and moisture distribution remained below 0.23% and 0.33%, respectively, indicating that PINN is an effective computational approach for solving the mass transfer model for a plant cell during drying. 155 Xuan et al 156 introduced an approach that combines physics-informed learning with a residual pointsadding optimization method for refrigerant filling mass flow metering. The results of their study showed the accuracy of the PINN in predicting crucial parameters, such as mass flow rate, pressure, and velocity during refrigerant filling.…”

The Application of Physics-Informed Machine Learning in Multiphysics Modeling in Chemical Engineering

“…They further assessed the feasibility of using PINN to predict cellular-level mass loss and subsequent moisture variations during low-temperature drying. It was found that compared to benchmark finite element analysis results, the prediction percentage errors of mass loss and moisture distribution remained below 0.23% and 0.33%, respectively, indicating that PINN is an effective computational approach for solving the mass transfer model for a plant cell during drying . Xuan et al introduced an approach that combines physics-informed learning with a residual points-adding optimization method for refrigerant filling mass flow metering.…”

“…It was found that compared to benchmark finite element analysis results, the prediction percentage errors of mass loss and moisture distribution remained below 0.23% and 0.33%, respectively, indicating that PINN is an effective computational approach for solving the mass transfer model for a plant cell during drying. 155 Xuan et al 156 introduced an approach that combines physics-informed learning with a residual pointsadding optimization method for refrigerant filling mass flow metering. The results of their study showed the accuracy of the PINN in predicting crucial parameters, such as mass flow rate, pressure, and velocity during refrigerant filling.…”

The Application of Physics-Informed Machine Learning in Multiphysics Modeling in Chemical Engineering

Physics-Informed Machine Learning: the Next Big Trend in Food Process Modelling?

A complete Physics-Informed Neural Network-based framework for structural topology optimization