Deep Unsupervised Learning for Condition Monitoring and Prediction of High Dimensional Data with Application on Windfarm SCADA Data

Mylonas, Charilaos; Abdallah, Imad; Chatzi, Eleni

doi:10.1007/978-3-030-12075-7_21

Cited by 13 publications

(14 citation statements)

References 3 publications

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“…In the offered case study, we demonstrated this idea on short‐term fatigue damage equivalent loads for wind turbines. Other wind‐energy related problems where CVAEs may find application are, for instance, wind farm level SCADA data modeling 48 or turbulence modeling 84,85 where finer turbulence scales are resolved in a data‐driven manner in place of the mostly empirical and mathematically simplified standard classical approaches.…”

Section: Discussionmentioning

confidence: 99%

“…The VAE is used as a means of learning features from the monitoring data. In Mylonas et al 48 we have applied conditional variational autoencoders n the problem of modeling the SCADA summary statistics data, on a simulated wind farm, with the purpose of establishing VAEs as a tool for condition monitoring.…”

Section: Prior Related Work On Machine Learning and Probabilistic Techniques For Damage Monitoring And Remaining Useful Life Predictionmentioning

confidence: 99%

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Conditional variational autoencoders for probabilistic wind turbine blade fatigue estimation using Supervisory, Control, and Data Acquisition data

2021

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Wind turbine fatigue estimation is based on time‐consuming Monte Carlo simulations for various wind conditions, followed by cycle‐counting procedures and the application of engineering damage models. The outputs of the fatigue simulations are large in volume and of high dimensionality, as they typically consist of estimates on finite‐element computational meshes. The strain and stress tensor time series, which are the primary quantities of interest when considering the problem of fatigue estimation, are dictated by complex vibration characteristics due to the coupled effect of aerodynamics, structural dynamics, geometrically non‐linear mechanics, and control. A Variational Auto‐Encoder (VAE) is trained in order to model the probability distribution of the accumulated fatigue on the root cross‐section of a simulated wind turbine blade. The VAE is conditioned on historical data that correspond to coarse wind‐field measurement statistics, such as mean hub‐height wind speed, standard deviation of hub‐height wind speed and shear exponent. In the absence of direct measurements of structural loads, the proposed technique finds applications in making long‐term probabilistic deterioration predictions from historical Supervisory, Control, and Data Acquisition (SCADA) data, while capturing the inherent aleatoric uncertainty due to the incomplete information on strain time series of the wind turbine structure, when only SCADA data statistics are available.

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Section: Discussionmentioning

confidence: 99%

Section: Prior Related Work On Machine Learning and Probabilistic Techniques For Damage Monitoring And Remaining Useful Life Predictionmentioning

confidence: 99%

Conditional variational autoencoders for probabilistic wind turbine blade fatigue estimation using Supervisory, Control, and Data Acquisition data

2021

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“…A very recent methodology StatFEM (Duffin et al, 2021;Girolami et al, 2021), provides an elegant Bayesian framework for both building and updating generative FE models. In terms of generative black-box models, GANs are by no means the only option; in fact, one alternative-the variational auto-encoder (Kingma and Welling, 2014)-has already proved to be generally useful in engineering problems; particularly in condition monitoring problems (e.g., Mylonas et al, 2020). Another versatile generative framework is provided by Gaussian processes (GPs) (Rasmussen and Williams, 2005).…”

Section: Introductionmentioning

confidence: 99%

On generative models as the basis for digital twins

Tsialiamanis

Wagg

Dervilis

et al. 2021

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A framework is proposed for generative models as a basis for digital twins or mirrors of structures. The proposal is based on the premise that deterministic models cannot account for the uncertainty present in most structural modeling applications. Two different types of generative models are considered here. The first is a physics-based model based on the stochastic finite element (SFE) method, which is widely used when modeling structures that have material and loading uncertainties imposed. Such models can be calibrated according to data from the structure and would be expected to outperform any other model if the modeling accurately captures the true underlying physics of the structure. The potential use of SFE models as digital mirrors is illustrated via application to a linear structure with stochastic material properties. For situations where the physical formulation of such models does not suffice, a data-driven framework is proposed, using machine learning and conditional generative adversarial networks (cGANs). The latter algorithm is used to learn the distribution of the quantity of interest in a structure with material nonlinearities and uncertainties. For the examples considered in this work, the data-driven cGANs model outperforms the physics-based approach. Finally, an example is shown where the two methods are coupled such that a hybrid model approach is demonstrated.

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“…At a supervisory control system, the major task of SCADA systems is to monitor a system's processes and apply the appropriate controls accordingly. SCADA systems are basically CPSs used in industries which included in a wide number of application areas [1][2][3][4].This solution present in the industry is Web SCADA, which provides multiple benefits that include anywhere/anytime accessibility to the system through a secure web browser connection. When the future Internet is considered, new technologies replace old technologies, hence, we can say that the integration of industrial business systems and the cloud concept has made the integrated SCADA systems more vulnerable compared with classical SCADA systems.…”

Section: Introductionmentioning

confidence: 99%