Learning the representation of raw acoustic emission signals by direct generative modelling and its use in chronology-based clusters identification

Learning the representation of raw acoustic emission signals by direct generative modelling and its use in chronology-based clusters identification

Acoustic emission (AE) is a passive monitoring technique used for learning about the behaviour of an engineered system. The streaming obtained by continuously recording AE transient signals is treated by a four steps procedure: 1) The detection of salient AE signals by distinguishing noise against n...

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Bibliographic Details
Published in:Engineering applications of artificial intelligence Vol. 90; p. 103478
Main Authors: Ramasso, Emmanuel, Butaud, Pauline, Jeannin, Thomas, Sarasini, Fabrizio, Placet, Vincent, Godin, Nathalie, Tirillò, Jacopo, Gabrion, Xavier
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-04-2020
Elsevier
Subjects:
Acoustic emission
Mechanics
Model-based clustering
Novelty detection
Physics
Raw waveform
Representation learning
Representation learning
Acoustic emission
Raw waveform
Novelty detection
Model-based clustering
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Description
Summary:Acoustic emission (AE) is a passive monitoring technique used for learning about the behaviour of an engineered system. The streaming obtained by continuously recording AE transient signals is treated by a four steps procedure: 1) The detection of salient AE signals by distinguishing noise against non-noise signals using wavelet denoising, 2) the statistical representation of randomly selected AE signals using Autoregressive Weakly Hidden Markov Models, 3) an inference phase by applying those models to unknown AE signals and generating a set of novelty scores reflecting differences between signals, 4) the clustering of novelty scores using constraint-based consensus clustering. Compared to the standard way relying on the transformation of all AE signals by manual feature engineering (MFE) before clustering, the main breaktrough proposed in this paper holds in the use of the raw AE signals, with different lengths and various scales, to build high level information and organise the low level streaming data. Validated first on simulated data, we show the potential of this methodology for interpreting acoustic emission streaming originating from composite materials.
ISSN:0952-1976
1873-6769
DOI:10.1016/j.engappai.2020.103478