Title :
An identification scheme combining first principle knowledge, neural networks, and the likelihood function
Author :
Vilim, Richard B. ; Garcia, Humberto E. ; Chen, Frederick W.
Author_Institution :
Argonne Nat. Lab., IL, USA
fDate :
1/1/2001 12:00:00 AM
Abstract :
An identification scheme is described for modeling uncertain systems. The method combines a physics-based model with a nonlinear mapping for capturing unmodeled physics and a statistical estimation procedure for quantifying any remaining process uncertainty. The technique has been used in predictive maintenance applications to detect operational changes of mechanical equipment by comparing the model output with the actual process output. Tests conducted on a peristaltic pump to detect incipient failure are described. The inclusion of unmodeled physics and a statistical representation of uncertainties results in lower false alarm and missed detection rates than other methods
Keywords :
condition monitoring; identification; maintenance engineering; neural nets; process monitoring; state estimation; uncertain systems; false alarm rates; first principle knowledge; identification scheme; incipient failure; likelihood function; mechanical equipment; missed detection rates; nonlinear mapping; operational changes; peristaltic pump; physics-based model; predictive maintenance; process uncertainty; statistical estimation procedure; Artificial neural networks; Equations; Feedforward neural networks; Fitting; Multi-layer neural network; Neural networks; Physics; System identification; Uncertain systems; Uncertainty;
Journal_Title :
Control Systems Technology, IEEE Transactions on
