A new intelligent fault identification method based on transfer locality preserving projection for actual diagnosis scenario of rotating machinery

Abstract

Abstract Intelligent fault diagnosis methods have been widely developed in recent years due to the ability in learning diagnosis knowledge from monitoring data automatically. However, for many diagnosis methods based on traditional machine learning algorithms, how to collect massive data under the same distribution with test data is a difficult problem in real world industrial applications. Aiming at this data dilemma of conventional intelligent diagnosis methods, this paper proposes a Transfer Locality Preserving Projection based Intelligent Fault Identification (TLPPIFI) method, which can construct diagnosis model using historical data collected from different operating conditions or other same-type machines. Based on a relevance assumption, TLPPIFI first embeds the data to a subspace through preserving a priori distribution structure properties of training data and minimizing the distribution discrepancy between different datasets simultaneously. By this means, the samples with same category in different datasets could cluster together in the new space. Finally, a classifier is trained to identify the condition of target machine by the historical data and the normal data of target machine together. The effectiveness of the proposed method is validated by three real-life diagnosis cases. The experimental results demonstrate that TLPPIFI can achieve superior diagnosis performance than several supervised learning methods and transfer learning methods. In addition, empirical analysis about distribution distance between domains and parameter sensitivity are also investigated.