Criticality of Prognostics in the Operations of Autonomous Aircraft

Vachtsevanos, George; Rajamani, Ravi

doi:10.4271/01-16-03-0022

Cited by 2 publications

References 18 publications

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Predictive Maintenance System for Screw Compressors Using Machine Learning: A Comparative Study

DAOUDI,

ZAKI,

ABOUSSALEH

2024

Preprint

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Maintaining operational efficiency and reliability of any industrial system is mandatory to minimize downtime and preventing failures. For this purpose, forecasting the evolution of key operational parameters such as temperature is essential. Hence, for this work, we have considered the temperature at the compressor’s screw element outlet. Given its criticality, this parameter is continuously monitored, as beside its operational role, it is considered as a safety indicator enabling to avoid thermal events, moreover it doesn’t require any significant investment. In this paper, we will present a comparison between four machine learning models for predicting this parameter. We have considered using regression models, i.e. Linear Regression, K-Nearest Neighbors, Support Vector Machine and Gradient Boosting Machine (GBM). After the first steps which include data cleaning and preprocessing, feature selection using the correlation analysis and feature importance techniques, the models were trained and evaluated using key metrics: Mean Squared Error (MSE), Root Mean Squared Error (RMSE), Mean Absolute Error (MAE), R-squared (R²), and Mean Absolute Percentage Error (MAPE). Among the tested models, the GBM has proven a superior performance, explaining, and forecasting 92% of the variance in the temperature at the screw element outlet and achieving the lowest error. Furthermore, A residual analysis confirmed the robustness of the GBM, highlighting its ability to make accurate predictions with minimal bias. This level of accuracy is considered as sufficient through academic as well as industrial lenses. Accurately predicting the outlet temperature is crucial for developing an effective predictive maintenance system, which can proactively prevent failures and optimize compressor performance. Future work focuses on hyperparameter tuning and advanced feature engineering to improve model accuracy and robustness for real-time industrial applications. Additionally, extending the scope of this approach to integrate other equipment, as the compressor is not an isolated machine in the industry but live in an Ecosystem under the utility room and with this, we can ensure the scalability, the integration, and the real-time processing capabilities.

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Predictive Maintenance System for Screw Compressors Using Machine Learning: A Comparative Study

DAOUDI,

ZAKI,

ABOUSSALEH

2024

Preprint

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Navigating Complexity

Komalasari

2024

Advances in Medical Technologies and Clinical Practice

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This chapter aims to establish an approach for IVHM requirements elucidation. A meticulous literature study served as the bedrock of this research, offering critical insights into existing methodologies and challenges in IVHM for UAS. Leveraging this knowledge, the study innovatively introduced the IVHM-RD method, a culmination of extensive data analysis. This approach not only grounded the study in established theories but also pushed the boundaries of understanding in IVHM, ushering in transformative possibilities for UAS design. This method consolidates diverse stakeholder demands through extensive data analysis, resulting in a prioritized set of IVHM requirements. The study's innovative approach, bridging the gap between theory and practice, promises transformative implications for UAS design processes.

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Criticality of Prognostics in the Operations of Autonomous Aircraft

Cited by 2 publications

References 18 publications

Predictive Maintenance System for Screw Compressors Using Machine Learning: A Comparative Study

Predictive Maintenance System for Screw Compressors Using Machine Learning: A Comparative Study

Navigating Complexity

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