Novel direct remaining useful life estimation of aero-engines with randomly assigned hidden nodes

This paper aims to improve data-driven prognostics by presenting a novel approach of directly estimating the remaining useful life (RUL) of aero-engines without requiring setting any failure threshold information or estimating degradation states. Specifically, based on the sensory data, RUL estimations are directly obtained through the universal function approximation capability of the extreme learning machine (ELM) algorithm. To achieve this, the features related with the RUL are first extracted from the sensory data as the inputs of the ELM model. Besides, to optimize the number of observed sensors, three evaluation metrics of correlation, monotonicity and robustness are defined and combined to automatically select the most relevant sensor values for more effective and efficient remaining useful life predictions. The validity and superiority of the proposed approach is evaluated by the widely used turbofan engine datasets from NASA Ames prognostics data repository. The proposed approach shows improved RUL estimation applicability at any time instant of the degradation process without determining the failure thresholds. This also simplifies the RUL estimation procedure. Moreover, the random properties of hidden nodes in the ELM learning mechanisms ensures the simplification and efficiency for real-time implementation. Therefore, the proposed approach suits to real-world applications in which prognostics estimations are required to be fast.

[1]  Noureddine Zerhouni,et al.  A New Multivariate Approach for Prognostics Based on Extreme Learning Machine and Fuzzy Clustering , 2015, IEEE Transactions on Cybernetics.

[2]  Nam H. Kim,et al.  Options for Prognostics Methods: A review of data-driven and physics-based prognostics , 2013 .

[3]  Ayca Altay,et al.  Prediction of Aircraft Failure Times Using Artificial Neural Networks and Genetic Algorithms , 2014 .

[4]  Kunde Yang,et al.  Unsupervised Classification of Hydrophone Signals With an Improved Mel-Frequency Cepstral Coefficient Based on Measured Data Analysis , 2019, IEEE Access.

[5]  Sundaram Suresh,et al.  Stable indirect adaptive neural controller for a class of nonlinear system , 2011, Neurocomputing.

[6]  Abhinav Saxena,et al.  Damage propagation modeling for aircraft engine run-to-failure simulation , 2008, 2008 International Conference on Prognostics and Health Management.

[7]  Noureddine Zerhouni,et al.  Novel failure prognostics approach with dynamic thresholds for machine degradation , 2013, IECON 2013 - 39th Annual Conference of the IEEE Industrial Electronics Society.

[8]  Max A. Little,et al.  Highly comparative time-series analysis: the empirical structure of time series and their methods , 2013, Journal of The Royal Society Interface.

[9]  Bernie MacIsaac,et al.  Prognostics and Health Monitoring Systems , 2011 .

[10]  Sundaram Suresh,et al.  Performance enhancement of extreme learning machine for multi-category sparse data classification problems , 2010, Eng. Appl. Artif. Intell..

[11]  Brigitte Chebel-Morello,et al.  RUL prediction based on a new similarity-instance based approach , 2014, 2014 IEEE 23rd International Symposium on Industrial Electronics (ISIE).

[12]  Narasimhan Sundararajan,et al.  Classification of Mental Tasks from Eeg Signals Using Extreme Learning Machine , 2006, Int. J. Neural Syst..

[13]  Jing Yang,et al.  Sparse Recursive Least Mean p-Power Extreme Learning Machine for Regression , 2018, IEEE Access.

[14]  Seungdeog Choi,et al.  Auxiliary Particle Filtering-Based Estimation of Remaining Useful Life of IGBT , 2018, IEEE Transactions on Industrial Electronics.

[15]  W. Cleveland Robust Locally Weighted Regression and Smoothing Scatterplots , 1979 .

[16]  Wei Wang,et al.  Internal Model Approach for Gait Modeling and Classification , 2005, 2005 IEEE Engineering in Medicine and Biology 27th Annual Conference.

[17]  Linxia Liao,et al.  Discovering Prognostic Features Using Genetic Programming in Remaining Useful Life Prediction , 2014, IEEE Transactions on Industrial Electronics.

[18]  Tianyou Zhang,et al.  Health Index-Based Prognostics for Remaining Useful Life Predictions in Electrical Machines , 2016, IEEE Transactions on Industrial Electronics.

[19]  Elizabeth A. Peck,et al.  Introduction to Linear Regression Analysis , 2001 .

[20]  M.G. Pecht,et al.  Prognostics and health management of electronics , 2008, IEEE Transactions on Components and Packaging Technologies.

[21]  Noureddine Zerhouni,et al.  Joint Prediction of Continuous and Discrete States in Time-Series Based on Belief Functions , 2013, IEEE Transactions on Cybernetics.

[22]  Hongming Zhou,et al.  Extreme Learning Machine for Regression and Multiclass Classification , 2012, IEEE Transactions on Systems, Man, and Cybernetics, Part B (Cybernetics).

[23]  Emmanuel Ramasso,et al.  Investigating Computational Geometry for Failure Prognostics in Presence of Imprecise Health Indicator: Results and Comparisons on C-MAPSS Datasets , 2014 .

[24]  Narasimhan Sundararajan,et al.  Online Sequential Fuzzy Extreme Learning Machine for Function Approximation and Classification Problems , 2009, IEEE Transactions on Systems, Man, and Cybernetics, Part B (Cybernetics).

[25]  Badong Chen,et al.  Recursive least mean p-power Extreme Learning Machine , 2017, Neural Networks.

[26]  Bhaskar Saha,et al.  Requirements Flowdown for Prognostics and Health Management , 2012, Infotech@Aerospace.

[27]  F.O. Heimes,et al.  Recurrent neural networks for remaining useful life estimation , 2008, 2008 International Conference on Prognostics and Health Management.

[28]  Hai-Jun Rong,et al.  Direct adaptive neural control of nonlinear systems with extreme learning machine , 2011, Neural Computing and Applications.

[29]  Liang Guo,et al.  Remaining Useful Life Prediction Based on a General Expression of Stochastic Process Models , 2017, IEEE Transactions on Industrial Electronics.

[30]  Kunpeng Zhu,et al.  Online Tool Wear Monitoring Via Hidden Semi-Markov Model With Dependent Durations , 2018, IEEE Transactions on Industrial Informatics.

[31]  Lovekesh Vig,et al.  Predicting Remaining Useful Life using Time Series Embeddings based on Recurrent Neural Networks , 2017, International Journal of Prognostics and Health Management.

[32]  Steven X. Ding,et al.  A Review on Basic Data-Driven Approaches for Industrial Process Monitoring , 2014, IEEE Transactions on Industrial Electronics.

[33]  Takehisa Yairi,et al.  A review on the application of deep learning in system health management , 2018, Mechanical Systems and Signal Processing.

[34]  K. S. Banerjee Generalized Inverse of Matrices and Its Applications , 1973 .

[35]  Junyou Shi,et al.  Quantum Assimilation-Based State-of-Health Assessment and Remaining Useful Life Estimation for Electronic Systems , 2016, IEEE Transactions on Industrial Electronics.

[36]  Bin Zhang,et al.  Degradation Feature Selection for Remaining Useful Life Prediction of Rolling Element Bearings , 2016, Qual. Reliab. Eng. Int..

[37]  Amit Agarwal,et al.  A new machine learning paradigm for terrain reconstruction , 2006, IEEE Geoscience and Remote Sensing Letters.

[38]  Enrico Zio,et al.  A data-driven fuzzy approach for predicting the remaining useful life in dynamic failure scenarios of a nuclear system , 2010, Reliab. Eng. Syst. Saf..

[39]  Ryan Mackey,et al.  General Purpose Data-Driven Monitoring for Space Operations , 2012, J. Aerosp. Comput. Inf. Commun..

[40]  Chee Kheong Siew,et al.  Real-time learning capability of neural networks , 2006, IEEE Trans. Neural Networks.

[41]  Daniel Hissel,et al.  Wavelet-Based Approach for Online Fuel Cell Remaining Useful Lifetime Prediction , 2016, IEEE Transactions on Industrial Electronics.

[42]  Guang-Bin Huang,et al.  Learning capability and storage capacity of two-hidden-layer feedforward networks , 2003, IEEE Trans. Neural Networks.

[43]  Zhi-Sheng Ye,et al.  RUL Prediction of Deteriorating Products Using an Adaptive Wiener Process Model , 2017, IEEE Transactions on Industrial Informatics.

[44]  Rafael Gouriveau,et al.  Prognostics in switching systems: Evidential markovian classification of real-time neuro-fuzzy predictions , 2010, 2010 Prognostics and System Health Management Conference.

[45]  Alaa Mohamed Riad,et al.  Prognostics: a literature review , 2016, Complex & Intelligent Systems.

[46]  Abhinav Saxena,et al.  Performance Benchmarking and Analysis of Prognostic Methods for CMAPSS Datasets , 2020, International Journal of Prognostics and Health Management.

[47]  Xiaoli Li,et al.  Deep Convolutional Neural Network Based Regression Approach for Estimation of Remaining Useful Life , 2016, DASFAA.

[48]  Brigitte Chebel-Morello,et al.  Direct Remaining Useful Life Estimation Based on Support Vector Regression , 2017, IEEE Transactions on Industrial Electronics.

[49]  Guang-Bin Huang,et al.  Upper bounds on the number of hidden neurons in feedforward networks with arbitrary bounded nonlinear activation functions , 1998, IEEE Trans. Neural Networks.

[50]  Chee Keong Kwoh,et al.  Extreme Learning Machine for Predicting HLA-Peptide Binding , 2006, ISNN.

[51]  Sankalita Saha,et al.  Requirements Specifications for Prognostics: An Overview , 2010 .

[52]  Cheng Yang,et al.  Prognostics and Health Management of Bearings Based on Logarithmic Linear Recursive Least-Squares and Recursive Maximum Likelihood Estimation , 2018, IEEE Transactions on Industrial Electronics.

[53]  Sankalita Saha,et al.  Requirements Specification for Prognostics Performance - An Overview , 2010 .

[54]  Daming Lin,et al.  A review on machinery diagnostics and prognostics implementing condition-based maintenance , 2006 .

[55]  Yaguo Lei,et al.  An Improved Exponential Model for Predicting Remaining Useful Life of Rolling Element Bearings , 2015, IEEE Transactions on Industrial Electronics.

[56]  Hai-Jun Rong,et al.  Adaptive neural control for a class of MIMO nonlinear systems with extreme learning machine , 2015, Neurocomputing.

[57]  Carl Ott,et al.  Prognostic Health-Management System Development for Electromechanical Actuators , 2015, J. Aerosp. Inf. Syst..