Abstract
This paper investigates a use case of robust anomaly detection applied to the scenario of a photovoltaic production factory—namely, Enel Green Power’s 3SUN solar cell production plant in Catania, Italy—by considering a Monte Carlo based pre-processing technique as a valid alternative to other typically used methods. In particular, the proposed method exhibits the following advantages: (i) Outlier replacement, by contrast with traditional methods which are limited to outlier detection only, and (ii) the preservation of temporal locality with respect to the training dataset. After pre-processing, the authors trained an anomaly detection model based on principal component analysis and defined a suitable key performance indicator for each sensor in the production line based on the model errors. In this way, by running the algorithm on unseen data streams, it is possible to isolate anomalous conditions by monitoring the above-mentioned indicators and virtually trigger an alarm when exceeding a reference threshold. The proposed approach was tested on both standard operating conditions and an anomalous scenario. With respect to the considered use case, it successfully anticipated a fault in the equipment with an advance of almost two weeks, but also demonstrated its robustness to false alarms during normal conditions.
Highlights
In recent years, predictive maintenance has been receiving an ever increasing attention and has been considered fundamental in industrial applications
This paper investigates a use case of robust anomaly detection applied to the scenario of a photovoltaic production factory—namely, Enel Green Power’s 3SUN solar cell production plant in Catania, Italy—by considering a Monte Carlo based pre-processing technique as a valid alternative to other typically used methods
The relevant data were collected from the Manufacturing Execution System (MES) of the 3SUN Factory and a set of normal behaviour samples was defined for training the Principal Component Analysis (PCA) model
Summary
Predictive maintenance has been receiving an ever increasing attention and has been considered fundamental in industrial applications. It contributes to guaranteeing healthy, safe and reliable systems, as well as to avoiding breakdowns that could potentially lead to a whole system shutdown. The main benefit of Principal Component Analysis (PCA) lies in its capability to reduce the dimensionality of data by selecting the most important features that are responsible for the highest variability in the input dataset. PCA allows to concentrate the analysis on a compressed version of the original dataset without compromising the reliability and the robustness of a predictive model. PCA formed a field of choice in predictive analytics in several use cases, e.g., maritime and transport applications, as well as decision support systems in healthcare [1,2]
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