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Main Authors: Noroozi, Amin, Sethunge, Sandaruwan K., Norouzi, Elham, Phan, Phat T., Waduge, Kavinda U., Rahman, Md. Arafatur
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.14618
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author Noroozi, Amin
Sethunge, Sandaruwan K.
Norouzi, Elham
Phan, Phat T.
Waduge, Kavinda U.
Rahman, Md. Arafatur
author_facet Noroozi, Amin
Sethunge, Sandaruwan K.
Norouzi, Elham
Phan, Phat T.
Waduge, Kavinda U.
Rahman, Md. Arafatur
contents Continuous Descent Operations (CDO) involve smooth, idle-thrust descents that avoid level-offs, reducing fuel burn, emissions, and noise while improving efficiency and passenger comfort. Despite its operational and environmental benefits, limited research has systematically examined the factors influencing CDO performance. Moreover, many existing methods in related areas, such as trajectory optimization, lack the transparency required in aviation, where explainability is critical for safety and stakeholder trust. This study addresses these gaps by proposing a Fuzzy-Enhanced Explainable AI (FEXAI) framework that integrates fuzzy logic with machine learning and SHapley Additive exPlanations (SHAP) analysis. For this purpose, a comprehensive dataset of 29 features, including 11 operational and 18 weather-related features, was collected from 1,094 flights using Automatic Dependent Surveillance-Broadcast (ADS-B) data. Machine learning models and SHAP were then applied to classify flights' CDO adherence levels and rank features by importance. The three most influential features, as identified by SHAP scores, were then used to construct a fuzzy rule-based classifier, enabling the extraction of interpretable fuzzy rules. All models achieved classification accuracies above 90%, with FEXAI providing meaningful, human-readable rules for operational users. Results indicated that the average descent rate within the arrival route, the number of descent segments, and the average change in directional heading during descent were the strongest predictors of CDO performance. The FEXAI method proposed in this study presents a novel pathway for operational decision support and could be integrated into aviation tools to enable real-time advisories that maintain CDO adherence under varying operational conditions.
format Preprint
id arxiv_https___arxiv_org_abs_2508_14618
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A Fuzzy-Enhanced Explainable AI Framework for Flight Continuous Descent Operations Classification
Noroozi, Amin
Sethunge, Sandaruwan K.
Norouzi, Elham
Phan, Phat T.
Waduge, Kavinda U.
Rahman, Md. Arafatur
Machine Learning
Continuous Descent Operations (CDO) involve smooth, idle-thrust descents that avoid level-offs, reducing fuel burn, emissions, and noise while improving efficiency and passenger comfort. Despite its operational and environmental benefits, limited research has systematically examined the factors influencing CDO performance. Moreover, many existing methods in related areas, such as trajectory optimization, lack the transparency required in aviation, where explainability is critical for safety and stakeholder trust. This study addresses these gaps by proposing a Fuzzy-Enhanced Explainable AI (FEXAI) framework that integrates fuzzy logic with machine learning and SHapley Additive exPlanations (SHAP) analysis. For this purpose, a comprehensive dataset of 29 features, including 11 operational and 18 weather-related features, was collected from 1,094 flights using Automatic Dependent Surveillance-Broadcast (ADS-B) data. Machine learning models and SHAP were then applied to classify flights' CDO adherence levels and rank features by importance. The three most influential features, as identified by SHAP scores, were then used to construct a fuzzy rule-based classifier, enabling the extraction of interpretable fuzzy rules. All models achieved classification accuracies above 90%, with FEXAI providing meaningful, human-readable rules for operational users. Results indicated that the average descent rate within the arrival route, the number of descent segments, and the average change in directional heading during descent were the strongest predictors of CDO performance. The FEXAI method proposed in this study presents a novel pathway for operational decision support and could be integrated into aviation tools to enable real-time advisories that maintain CDO adherence under varying operational conditions.
title A Fuzzy-Enhanced Explainable AI Framework for Flight Continuous Descent Operations Classification
topic Machine Learning
url https://arxiv.org/abs/2508.14618