Probabilistic conflict detection using heteroscedastic gaussian process and bayesian optimization
Conflict detection plays a crucial role in ensuring flight safety and efficiency and is a critical component of an air traffic control system. Despite the availability of tools to support air traffic controllers in identifying potential conflicts, their quality and accuracy remain limited due to the...
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sg-ntu-dr.10356-1711772023-10-17T15:31:09Z Probabilistic conflict detection using heteroscedastic gaussian process and bayesian optimization Pham, Duc-Thinh Guleria, Yash Alam, Sameer Duong, Vu Air Traffic Management Research Institute Engineering::Computer science and engineering::Computing methodologies::Artificial intelligence Engineering::Aeronautical engineering::Aviation Probabilistic Conflict Detection Bayesian Optimization Uncertainty Modeling Conflict detection plays a crucial role in ensuring flight safety and efficiency and is a critical component of an air traffic control system. Despite the availability of tools to support air traffic controllers in identifying potential conflicts, their quality and accuracy remain limited due to the challenge of accurately accounting for uncertainty when predicting flight trajectories. To tackle this issue, researchers have explored various studies focused on using probabilistic techniques to model aircraft dynamics and trajectory uncertainty. However, these approaches share several common shortcomings, including their assumptions about uncertainty distributions and the high computational costs of detecting and calculating the risk of conflicts. In response to these challenges, we propose a data-driven approach combining a multi-output generative model with a Bayesian Optimization algorithm to effectively model the uncertainty of aircraft trajectories and rapidly identify the probability of a conflict. Our approach employs the Heteroscedastic Gaussian Process to capture complex trajectory patterns and uncertainty from historical data directly. The proposed predictive model can effectively capture heteroscedastic noise from real data, leading to improved predictions. It achieves Kullback-Leibler divergence around 1 to 1.3 for all dimensions which reduces by >45% for latitude, >24% for longitude, and 4% for altitude compared to the classical homoscedastic GP approach. The method also boasts high-performance predictions for 4D trajectories, including descending, climbing, and en-route phases. To pinpoint when two aircraft are most likely to experience a conflict, the Bayesian Optimization algorithm is adopted, which shows good performance in terms of computational efficiency and flexibility for probabilistic conflict detection. The proposed model achieves a percentage error <0.25% in estimating the conflict probability with computational cost <14s. By addressing the challenges of uncertainty and computational complexity, our method demonstrates great potential to enhance flight safety and efficiency. Civil Aviation Authority of Singapore (CAAS) National Research Foundation (NRF) Published version This research was supported by the National Research Foundation (NRF), Singapore, and the Civil Aviation Authority of Singapore (CAAS), under the Aviation Transformation Program. 2023-10-17T02:12:48Z 2023-10-17T02:12:48Z 2023 Journal Article Pham, D., Guleria, Y., Alam, S. & Duong, V. (2023). Probabilistic conflict detection using heteroscedastic gaussian process and bayesian optimization. IEEE Access, 11, 109341-109352. https://dx.doi.org/10.1109/ACCESS.2023.3321146 2169-3536 https://hdl.handle.net/10356/171177 10.1109/ACCESS.2023.3321146 11 109341 109352 en IEEE Access © 2023 The Authors. This work is licensed under a Creative Commons Attribution 4.0 License. For more information, see https://creativecommons.org/licenses/by/4.0/. application/pdf |
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Engineering::Computer science and engineering::Computing methodologies::Artificial intelligence Engineering::Aeronautical engineering::Aviation Probabilistic Conflict Detection Bayesian Optimization Uncertainty Modeling |
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Engineering::Computer science and engineering::Computing methodologies::Artificial intelligence Engineering::Aeronautical engineering::Aviation Probabilistic Conflict Detection Bayesian Optimization Uncertainty Modeling Pham, Duc-Thinh Guleria, Yash Alam, Sameer Duong, Vu Probabilistic conflict detection using heteroscedastic gaussian process and bayesian optimization |
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Conflict detection plays a crucial role in ensuring flight safety and efficiency and is a critical component of an air traffic control system. Despite the availability of tools to support air traffic controllers in identifying potential conflicts, their quality and accuracy remain limited due to the challenge of accurately accounting for uncertainty when predicting flight trajectories. To tackle this issue, researchers have explored various studies focused on using probabilistic techniques to model aircraft dynamics and trajectory uncertainty. However, these approaches share several common shortcomings, including their assumptions about uncertainty distributions and the high computational costs of detecting and calculating the risk of conflicts. In response to these challenges, we propose a data-driven approach combining a multi-output generative model with a Bayesian Optimization algorithm to effectively model the uncertainty of aircraft trajectories and rapidly identify the probability of a conflict. Our approach employs the Heteroscedastic Gaussian Process to capture complex trajectory patterns and uncertainty from historical data directly. The proposed predictive model can effectively capture heteroscedastic noise from real data, leading to improved predictions. It achieves Kullback-Leibler divergence around 1 to 1.3 for all dimensions which reduces by >45% for latitude, >24% for longitude, and 4% for altitude compared to the classical homoscedastic GP approach. The method also boasts high-performance predictions for 4D trajectories, including descending, climbing, and en-route phases. To pinpoint when two aircraft are most likely to experience a conflict, the Bayesian Optimization algorithm is adopted, which shows good performance in terms of computational efficiency and flexibility for probabilistic conflict detection. The proposed model achieves a percentage error <0.25% in estimating the conflict probability with computational cost <14s. By addressing the challenges of uncertainty and computational complexity, our method demonstrates great potential to enhance flight safety and efficiency. |
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Air Traffic Management Research Institute |
| author_facet |
Air Traffic Management Research Institute Pham, Duc-Thinh Guleria, Yash Alam, Sameer Duong, Vu |
| format |
Article |
| author |
Pham, Duc-Thinh Guleria, Yash Alam, Sameer Duong, Vu |
| author_sort |
Pham, Duc-Thinh |
| title |
Probabilistic conflict detection using heteroscedastic gaussian process and bayesian optimization |
| title_short |
Probabilistic conflict detection using heteroscedastic gaussian process and bayesian optimization |
| title_full |
Probabilistic conflict detection using heteroscedastic gaussian process and bayesian optimization |
| title_fullStr |
Probabilistic conflict detection using heteroscedastic gaussian process and bayesian optimization |
| title_full_unstemmed |
Probabilistic conflict detection using heteroscedastic gaussian process and bayesian optimization |
| title_sort |
probabilistic conflict detection using heteroscedastic gaussian process and bayesian optimization |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/171177 |
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1781793705632464896 |