Title :
Inference of helicopter airframe condition
Author :
Gill, Waljinder S. ; Nabney, I.T. ; Wells, Daniel
Author_Institution :
Nonlinearity & Complexity Res. Group, Aston Univ., Birmingham, UK
Abstract :
The goal of this paper is to model normal airframe conditions for helicopters in order to detect changes. This is done by inferring the flying state using a selection of sensors and frequency bands that are best for discriminating between different states. We used non-linear state-space models (NLSSM) for modelling flight conditions based on short-time frequency analysis of the vibration data and embedded the models in a switching framework to detect transitions between states. We then created a density model (using a Gaussian mixture model) for the NLSSM innovations: this provides a model for normal operation. To validate our approach, we used data with added synthetic abnormalities which was detected as low-probability periods. The model of normality gave good indications of faults during the flight, in the form of low probabilities under the model, with high accuracy (>92 %).
Keywords :
condition monitoring; fault diagnosis; helicopters; vibrations; Gaussian mixture model; NLSSM innovations; faults; frequency bands; helicopter airframe condition monitoring; low-probability periods; nonlinear state space models; sensors; short time frequency analysis; synthetic abnormalities; vibration data; Atmospheric modeling; Data models; Hidden Markov models; Kalman filters; Sensors; Switches; Vibrations; Condition monitoring; flight condition; non-linear model; signal processing; switching state space; vibration;
Conference_Titel :
Machine Learning for Signal Processing (MLSP), 2013 IEEE International Workshop on
Conference_Location :
Southampton
DOI :
10.1109/MLSP.2013.6661960
