Two Birds with One Network: Unifying Failure Event Prediction and Time-to-failure Modeling

Aggarwal, Karan; Atan, Onur; Farahat, Ahmed K.; Zhang, Chi; Ristovski, Kosta; Gupta, Chetan

doi:10.1109/bigdata.2018.8622431

Cited by 25 publications

(24 citation statements)

References 30 publications

(50 reference statements)

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“…In this section, we apply functional MLP ('FMLP') to conduct RUL estimation task for a widely-used benchmark data set called NASA C-MAPSS (Commercial Modular Aero-Propulsion System Simulation) data [28]. We compare the performance of functional MLP with a variety of state-of-the-art deep learning approaches, including the Convolutional Neural Network model ('CNN') in [10], the Deep Weibull network ('DW-RNN') and the multi-task learning network ('MTL-RNN') in [6], the Long Short-Term Memory method ('LSTM') [3], and the bootstrapping based Long Short-Term Memory method ('LSTMBS') [11]. As shown by the experimental results, the proposed functional MLP approach significantly outperforms all these alternative methods.…”

Section: Experiments On C-mapss Data Setmentioning

confidence: 99%

Remaining Useful Life Estimation Using Functional Data Analysis

Wang

Zheng

Farahat

et al. 2019

2019 IEEE International Conference on Prognostics and Health Management (ICPHM)

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Remaining Useful Life (RUL) of an equipment or one of its components is defined as the time left until the equipment or component reaches its end of useful life. Accurate RUL estimation is exceptionally beneficial to Predictive Maintenance, and Prognostics and Health Management (PHM). Data driven approaches which leverage the power of algorithms for RUL estimation using sensor and operational time series data are gaining popularity. Existing algorithms, such as linear regression, Convolutional Neural Network (CNN), Hidden Markov Models (HMMs), and Long Short-Term Memory (LSTM), have their own limitations for the RUL estimation task. In this work, we propose a novel Functional Data Analysis (FDA) method called functional Multilayer Perceptron (functional MLP) for RUL estimation. Functional MLP treats time series data from multiple equipment as a sample of random continuous processes over time. FDA explicitly incorporates both the correlations within the same equipment and the random variations across different equipment's sensor time series into the model. FDA also has the benefit of allowing the relationship between RUL and sensor variables to vary over time. We implement functional MLP on the benchmark NASA C-MAPSS data and evaluate the performance using two popularly-used metrics. Results show the superiority of our algorithm over all the other state-of-the-art methods.

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Section: Experiments On C-mapss Data Setmentioning

confidence: 99%

Remaining Useful Life Estimation Using Functional Data Analysis

Wang

Zheng

Farahat

et al. 2019

2019 IEEE International Conference on Prognostics and Health Management (ICPHM)

Self Cite

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“…Therefore, it is better to learn temporal features from the slow inherently long-term degradation process by combing those two structures. Recent paper proposed a deep neural network structure using both LSTM and CNN which can be combined in a serial or parallel manner to improve the accuracy of the RUL prediction of the equipment [34,35].…”

Section: Related Workmentioning

confidence: 99%

“…If the variance is large, it is hard to have confidence on the predicted result. The RUL prediction problem is also similar to the survival analysis which is commonly used to model time-to-death events in the healthcare domain [34]. For example, the model predicts the failure will happen in 8 days with 80% probability is much better than predict 10 days until the failure.…”

Section: Related Workmentioning

confidence: 99%

“…Martinsson proposed the Weibull time-to-event recurrent neural network, which is a simple framework for time series prediction of the time to the next event applicable [36]. Aggarwal et al used the Weibull distribution assumption on the time-to-failure event with a linear hazard rate corresponding to the linear degradation model that most of the literature makes [34].…”

Section: Related Workmentioning

confidence: 99%

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Developing Deep Survival Model for Remaining Useful Life Estimation Based on Convolutional and Long Short-Term Memory Neural Networks

Chu

Lee

Yeh

2020

Wireless Communications and Mobile Computing

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The application of mechanical equipment in manufacturing is becoming more and more complicated with technology development and adoption. In order to keep the high reliability and stability of the production line, reducing the downtime to repair and the frequency of routine maintenance is necessary. Since machine and components’ degradations are inevitable, accurately estimating the remaining useful life of them is crucial. We propose an integrated deep learning approach with convolutional neural networks and long short-term memory networks to learn the latent features and estimate remaining useful life value with deep survival model based on the discrete Weibull distribution. We conduct the turbofan engine degradation simulation dataset from Commercial Modular Aero-Propulsion System Simulation dataset provided by NASA to validate our approach. The improved results have proven that our proposed model can capture the degradation trend of a fault and has superior performance under complex conditions compared with existing state-of-the-art methods. Our study provides an efficient feature extraction scheme and offers a promising prediction approach to make better maintenance strategies.

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“…In contrast to Ranganath et al [19] deep exponential families model, this work will limit itself to Weibull distribution's only. Yang et al [23] and Aggarwal et al [24] developed similar Weibull based NNs and RNNs, respectively, but focus amongst others on different disciplines than wind turbine monitoring.…”

Section: Introductionmentioning

confidence: 99%

Assessment of Early Stopping through Statistical Health Prognostic Models for Empirical RUL Estimation in Wind Turbine Main Bearing Failure Monitoring

2019

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Details about a fault’s progression, including the remaining-useful-lifetime (RUL), are key features in monitoring, industrial operation and maintenance (O&M) planning. In order to avoid increases in O&M costs through subjective human involvement and over-conservative control strategies, this work presents models to estimate the RUL for wind turbine main bearing failures. The prediction of the RUL is estimated from a likelihood function based on concepts from prognostics and health management, and survival analysis. The RUL is estimated by training the model on run-to-failure wind turbines, extracting a parametrization of a probability density function. In order to ensure analytical moments, a Weibull distribution is assumed. Alongside the RUL model, the fault’s progression is abstracted as discrete states following the bearing stages from damage detection, through overtemperature warnings, to over overtemperature alarms and failure, and are integrated in a separate assessment model. Assuming a naïve O&M plan (wind turbines are run as close to failure as possible without regards for infrastructure or supply chain constrains), 67 non run-to-failure wind turbines are assessed with respect to their early stopping, revealing the potential RUL lost. These are turbines that have been stopped by the operator prior to their failure. On average it was found that wind turbines are stopped 13 days prior to their failure, accumulating 786 days of potentially lost operations across the 67 wind turbines.

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Two Birds with One Network: Unifying Failure Event Prediction and Time-to-failure Modeling

Cited by 25 publications

References 30 publications

Remaining Useful Life Estimation Using Functional Data Analysis

Remaining Useful Life Estimation Using Functional Data Analysis

Developing Deep Survival Model for Remaining Useful Life Estimation Based on Convolutional and Long Short-Term Memory Neural Networks

Assessment of Early Stopping through Statistical Health Prognostic Models for Empirical RUL Estimation in Wind Turbine Main Bearing Failure Monitoring

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