A general methodology for gray-box, or semi-physical, modeling is presented. This technique is intended to combine the best of two worlds: knowledge-based modeling, whereby mathematical equations are derived in order to describe a process, based on a physical (or chemical, biological, etc.) analysis, and black-box modeling, whereby a parameterized model is designed, whose parameters are estimated solely from measurements made on the process. The gray-box modeling technique is very valuable whenever a knowledge-based model exists, but is not fully satisfactory and cannot be improved by further analysis (or can only be improved at a very large computational cost). We describe the design methodology of a gray-box model, and illustrate it on a didactic example. We emphasize the importance of the choice of the discretization scheme used for transforming the differential equations of the knowledge- based model into a set of discrete-time recurrent equations. Finally, an application to a real, complex industrial process is presented.
[1]
Peter E. Price,et al.
Extracting effective diffusion parameters from drying experiments
,
1997
.
[2]
Yacine Oussar,et al.
Reseaux d'ondelettes et reseaux de neurones pour la modelisation statique et dynamique de processus
,
1998
.
[3]
Pierre Roussel-Ragot,et al.
Neural Networks and Nonlinear Adaptive Filtering: Unifying Concepts and New Algorithms
,
1993,
Neural Computation.
[4]
F. A. Seiler,et al.
Numerical Recipes in C: The Art of Scientific Computing
,
1989
.
[5]
J. Ploix.
EARLY FAULT DETECTION IN A DISTILLATION COLUMN : AN INDUSTRIAL APPLICATION OF KNOWLEDGE-BASED NEURAL MODELLING
,
2000
.
[6]
Gérard Dreyfus.
EARLY FAULT DETECTION IN A DISTILLATION COLUMN: AN INDUSTRIAL APPLICATION OF KNOWLEDGE-BASED NEURAL MODELLING
,
1997
.