Data-Driven Exhaust Gas Temperature Baseline Predictions for Aeroengine Based on Machine Learning Algorithms

Wang, Zepeng; Zhao, Yongjun

doi:10.3390/aerospace10010017

Cited by 7 publications

(6 citation statements)

References 36 publications

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“…A careful selection of parameters was made from the extensive pool of over 200, focusing on those most indicative of gas path performance in the engine, as referenced in prior studies [13,21,29]. Scenario descriptors, including ALT, MN, PLA, and T0, are crucial in determining the flying state and are imperative for accurate Exhaust Gas Temperature (EGT) prediction.…”

Section: Data Descriptionmentioning

confidence: 99%

“…With the boom in the development of machine learning and deep learning techniques, as well as the progress of sensor technology and real-time databases, the data-driven prediction of engine state parameters has attracted wide attention from academia and industry [12]. In their study on EGT prediction, Wang et al [13] established basic frameworks and employed several common machine learning methods. The analysis included the use of the Generalized Regression Neural Network (GRNN) network [14], the Radial Basis Function (RBF) network [15], Support Vector Regression (SVR) [16], and Random Forest (RF) [17].…”

Section: Introductionmentioning

confidence: 99%

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Exhaust Gas Temperature Prediction of Aero-Engine via Enhanced Scale-Aware Efficient Transformer

Liu,

Zhou,

Song

et al. 2024

Aerospace

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This research introduces the Enhanced Scale-Aware efficient Transformer (ESAE-Transformer), a novel and advanced model dedicated to predicting Exhaust Gas Temperature (EGT). The ESAE-Transformer merges the Multi-Head ProbSparse Attention mechanism with the established Transformer architecture, significantly optimizing computational efficiency and effectively discerning key temporal patterns. The incorporation of the Multi-Scale Feature Aggregation Module (MSFAM) further refines 2 s input and output timeframe. A detailed investigation into the feature dimensionality was undertaken, leading to an optimized configuration of the model, thereby improving its overall performance. The efficacy of the ESAE-Transformer was rigorously evaluated through an exhaustive ablation study, focusing on the contribution of each constituent module. The findings showcase a mean absolute prediction error of 3.47∘R, demonstrating strong alignment with real-world environmental scenarios and confirming the model’s accuracy and relevance. The ESAE-Transformer not only excels in predictive accuracy but also sheds light on the underlying physical processes, thus enhancing its practical application in real-world settings. The model stands out as a robust tool for critical parameter prediction in aero-engine systems, paving the way for future advancements in engine prognostics and diagnostics.

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Section: Data Descriptionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Exhaust Gas Temperature Prediction of Aero-Engine via Enhanced Scale-Aware Efficient Transformer

Liu,

Zhou,

Song

et al. 2024

Aerospace

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“…The paper [61] proposes four data-driven frameworks for estimating the baseline exhaust gas temperature of aeroengines, a critical factor for engine health monitoring and flight safety. Among the tested machine learning models, the Generalized Regression Neural Network was highlighted for its superior accuracy and efficiency, suggesting its suitability for real-world airline deployment.…”

Section: Ai For Aircraft Maintenancementioning

confidence: 99%

Ecosystem of Aviation Maintenance: Transition from Aircraft Health Monitoring to Health Management Based on IoT and AI Synergy

Kabashkin,

Perekrestov

2024

Applied Sciences

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This paper presents an in-depth exploration of the transformative impact of integrating the Internet of Things (IoT), cloud computing, and artificial intelligence (AI) within the domain of aviation maintenance. It articulates the transition from conventional health monitoring practices to a more advanced, comprehensive health management approach, leveraging these modern technologies. This paper emphasizes the pivotal shift from reactive maintenance strategies to proactive and predictive maintenance paradigms, facilitated by the real-time data collection capabilities of IoT devices and the analytical prowess of AI. This transition not only enhances the safety and reliability of flight operations but also optimizes maintenance procedures, thereby reducing operational costs and improving efficiency. This paper meticulously outlines the implementation challenges, including technological integration, regulatory compliance, and security concerns, while proposing a future research agenda to address these issues and further harness the potential of these technologies in revolutionizing aviation maintenance.

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“…The four data-driven frameworks to predict the exhaust gas temperature baseline of aeroengines, essential for engine health analysis and flight safety, are proposed in [23]. Using data from the real engine, machine learning methods were trained, with the Generalized Regression Neural Network model showing the highest accuracy and efficiency, making it suitable for practical airline applications.…”

Section: Ai In Aviation Maintenancementioning

confidence: 99%

Artificial Intelligence in Aviation: New Professionals for New Technologies

Kabashkin,

Misnevs,

Zervina

2023

Applied Sciences

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Major aviation organizations have highlighted the need to adopt artificial intelligence (AI) to transform operations and improve efficiency and safety. However, the aviation industry requires qualified graduates with relevant AI competencies to meet this demand. This study analyzed aviation engineering bachelor’s programs at European universities to determine if they are preparing students for AI integration in aviation by incorporating AI-related topics. The analysis focused on program descriptions and syllabi using semantic annotation. The results showed a limited focus on AI and machine learning competencies, with more emphasis on foundational digital skills. Reasons include the newness of aviation AI, its specialized nature, and implementation challenges. As the industry evolves, dedicated AI programs may emerge. But currently, curricula appear misaligned with stated industry goals for AI adoption. The study provides an analytical methodology and competency framework to help educators address this gap. Producing graduates equipped with AI literacy and collaboration skills will be key to aviation’s intelligent future.

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Data-Driven Exhaust Gas Temperature Baseline Predictions for Aeroengine Based on Machine Learning Algorithms

Cited by 7 publications

References 36 publications

Exhaust Gas Temperature Prediction of Aero-Engine via Enhanced Scale-Aware Efficient Transformer

Exhaust Gas Temperature Prediction of Aero-Engine via Enhanced Scale-Aware Efficient Transformer

Ecosystem of Aviation Maintenance: Transition from Aircraft Health Monitoring to Health Management Based on IoT and AI Synergy

Artificial Intelligence in Aviation: New Professionals for New Technologies

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