Abstract
In recent years, research has proposed several deep learning (DL) approaches to providing reliable remaining useful life (RUL) predictions in Prognostics and Health Management (PHM) applications. Although supervised DL techniques, such as Convolutional Neural Network and Long-Short Term Memory, have outperformed traditional prognosis algorithms, they are still dependent on large labeled training datasets. With respect to real-life PHM applications, high-quality labeled training data might be both challenging and time-consuming to acquire. Alternatively, unsupervised DL techniques introduce an initial pre-training stage to extract degradation related features from raw unlabeled training data automatically. Thus, the combination of unsupervised and supervised (semi-supervised) learning has the potential to provide high RUL prediction accuracy even with reduced amounts of labeled training data. This paper investigates the effect of unsupervised pre-training in RUL predictions utilizing a semi-supervised setup. Additionally, a Genetic Algorithm (GA) approach is applied in order to tune the diverse amount of hyper-parameters in the training procedure. The advantages of the proposed semi-supervised setup have been verified on the popular C-MAPSS dataset. The experimental study, compares this approach to purely supervised training, both when the training data is completely labeled and when the labeled training data is reduced, and to the most robust results in the literature. The results suggest that unsupervised pre-training is a promising feature in RUL predictions subjected to multiple operating conditions and fault modes.
Highlights
The remaining useful life (RUL) is a technical term used to describe the progression of faults in Prognostics and Health Management (PHM) applications [1]
The proposed approach indicated improved accuracy compared to the Multilayer Perceptron (MLP), Support Vector Machine (SVM), and Relevance Vector Machine
The aim of this paper is to show increased RUL prediction accuracy in multivariate time series data subjected to several operating conditions and fault modes utilizing a semi-supervised setup
Summary
The remaining useful life (RUL) is a technical term used to describe the progression of faults in Prognostics and Health Management (PHM) applications [1]. Prognosis algorithms tend ideally to achieve the ideal maintenance policy through predictions of the available time before a failure occurs within a component or sub-component, that is RUL [2]. In this way, RUL predictions have the potential to prevent critical failures, and becomes an important measurement to achieve the ultimate goal of zero-downtime performance in industrial systems. Deep learning (DL) has emerged as a potent area to process highly non-linear and varying sequential data with minimal human input within the PHM domain [3]. Deep architectures introduce many diverse hyper-parameters, which are challenging to optimize in the training process. This study proposes a Genetic Algorithm (GA) approach in order to optimize the hyper-parameters in an efficient manner
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