A novel predictive architecture for microwave-assisted drying processes based on neural networks
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Pedreño Molina, Juan Luis; Monzó Cabrera, Juan; Toledo Moreo, Ana Belén; Sánchez Hernández, David AgapitoGrupo de investigación
Grupo de Electromagnetismo y Materia (GEM); División de Sistemas e Ingeniería Electrónica (DSIE); Grupo de Ingeniería de Microondas, Radiocomunicaciones y Electromagnetismo (GIMRE)Área de conocimiento
Teoría de la Señal y las ComunicacionesPatrocinadores
This work was supported in part by the SENECA Fundation (Spain) PCMC75/ 00078/FS/02, and the Spanish Science & Technology Ministry (MCYT) under TIC 2003-08164-C03-03 research project.Fecha de publicación
2005-08Editorial
ElsevierCita bibliográfica
PEDREÑO MOLINA, J.L., MONZÓ CABRERA, J., TOLEDO MOREO, A., SÁNCHEZ HERNÁNDEZ, D. A novel predictive architecture for microwave-assisted drying processes based on neural networks. International Communications in Heat and Mass Transfer, 32 (8): 1026-1033, Agosto 2005. ISSN 0735-1933Revisión por pares
SíPalabras clave
Predictive systemNeural network modelling
Microwave-heating applications
Sistema predictivo
Modelos de redes neuronales
Aplicaciones de calentamiento por microondas
Resumen
In this contribution, a novel learning architecture based on the interconnection of two different learning-based neural networks has been used to both predict temperature and drying curves and solve inverse modelling equations in microwave-assisted drying processes. In this way, a neural model that combines the accuracy of neural networks based on Radial Basis Functions (RBF) and the algebraic capabilities of the matrix polynomial structures is presented and validated. The architecture has been trained by temperature (Tc(t)) and moisture content (Xt(t)) curves, which have been generated by a previously validated drying model. The results show that the neural model is able to very accurately predict both kind of curves for any combination of the considered input variables (electric field and air temperature) provided that an appropriate training process is performed. The proposed configuration also permits the solution of the inverse problem in the drying process by finding the optimal ...
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