Incorporating Pitching Moment Observation in Reinforcement Learning for Enhanced Thermal Updraft Exploitation by Fixed-Wing UAVs

Chengju Zhang; Hongfei Wu; Guanquan Wei; Wenjuan Li; Jiayang Wang; Haobo Liu; Ke Li; Biao Zhang

doi:10.1109/ISAES66870.2025.11274374

Incorporating Pitching Moment Observation in Reinforcement Learning for Enhanced Thermal Updraft Exploitation by Fixed-Wing UAVs

Chengju Zhang
, Hongfei Wu
, Guanquan Wei
, Wenjuan Li
, Jiayang Wang
, Haobo Liu^*
, Ke Li
, Biao Zhang

^*Corresponding author for this work

School of Aeronautic Science and Engineering

Aerospace Times Feihong Technology Company Limited
Beihang University

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Fixed-wing UAVs can extend endurance by exploiting atmospheric thermals. Prior reinforcement learning (RL) methods used vertical acceleration and roll moments as state inputs. However, when flying straight through a thermal core, roll cues are weak, making it hard for RL agents to anticipate circling. This can delay thermal centering and waste potential energy gain. We propose adding pitching moment as an additional observation. Pitching moment reflects vertical airflow gradients along the fuselage, providing early cues of strong up-drafts. We design a deep RL agent with three-layer neural network and discrete bank angle actions. Simulations use a stationary Gaussian thermal model and glider dynamics. Results show that the pitchaugmented agent recognizes thermals earlier and begins circling sooner. Compared to baseline models, it gains up to ∼ 8% more altitude in head-on approaches and achieves better centering stability. This confirms that pitching moment sensing enhances autonomous soaring. Future work will explore moving thermals and real-world flight tests.

Original language	English
Title of host publication	2025 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025
Publisher	Institute of Electrical and Electronics Engineers Inc.
Pages	409-413
Number of pages	5
ISBN (Electronic)	9798331566098
DOIs	https://doi.org/10.1109/ISAES66870.2025.11274374
State	Published - 2025
Event	4th International Symposium on Aerospace Engineering and Systems, ISAES 2025 - Nanjing, China Duration: 25 Jul 2025 → 27 Jul 2025

Publication series

Name	2025 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025

Conference

Conference	4th International Symposium on Aerospace Engineering and Systems, ISAES 2025
Country/Territory	China
City	Nanjing
Period	25/07/25 → 27/07/25

Keywords

Gaussian model
Thermal updraft
UAV
pitch moment
reinforcement learning
state estimation

Access to Document

10.1109/ISAES66870.2025.11274374

Cite this

Zhang, C., Wu, H., Wei, G., Li, W., Wang, J., Liu, H., Li, K., & Zhang, B. (2025). Incorporating Pitching Moment Observation in Reinforcement Learning for Enhanced Thermal Updraft Exploitation by Fixed-Wing UAVs. In 2025 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025 (pp. 409-413). (2025 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/ISAES66870.2025.11274374

Zhang, Chengju ; Wu, Hongfei ; Wei, Guanquan et al. / Incorporating Pitching Moment Observation in Reinforcement Learning for Enhanced Thermal Updraft Exploitation by Fixed-Wing UAVs. 2025 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025. Institute of Electrical and Electronics Engineers Inc., 2025. pp. 409-413 (2025 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025).

@inproceedings{651483ba9fb3495c845a635b05aaa0ac,

title = "Incorporating Pitching Moment Observation in Reinforcement Learning for Enhanced Thermal Updraft Exploitation by Fixed-Wing UAVs",

abstract = "Fixed-wing UAVs can extend endurance by exploiting atmospheric thermals. Prior reinforcement learning (RL) methods used vertical acceleration and roll moments as state inputs. However, when flying straight through a thermal core, roll cues are weak, making it hard for RL agents to anticipate circling. This can delay thermal centering and waste potential energy gain. We propose adding pitching moment as an additional observation. Pitching moment reflects vertical airflow gradients along the fuselage, providing early cues of strong up-drafts. We design a deep RL agent with three-layer neural network and discrete bank angle actions. Simulations use a stationary Gaussian thermal model and glider dynamics. Results show that the pitchaugmented agent recognizes thermals earlier and begins circling sooner. Compared to baseline models, it gains up to ∼ 8\% more altitude in head-on approaches and achieves better centering stability. This confirms that pitching moment sensing enhances autonomous soaring. Future work will explore moving thermals and real-world flight tests.",

keywords = "Gaussian model, Thermal updraft, UAV, pitch moment, reinforcement learning, state estimation",

author = "Chengju Zhang and Hongfei Wu and Guanquan Wei and Wenjuan Li and Jiayang Wang and Haobo Liu and Ke Li and Biao Zhang",

note = "Publisher Copyright: {\textcopyright} 2025 IEEE.; 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025 ; Conference date: 25-07-2025 Through 27-07-2025",

year = "2025",

doi = "10.1109/ISAES66870.2025.11274374",

language = "英语",

series = "2025 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

pages = "409--413",

booktitle = "2025 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025",

address = "美国",

}

Zhang, C, Wu, H, Wei, G, Li, W, Wang, J, Liu, H, Li, K & Zhang, B 2025, Incorporating Pitching Moment Observation in Reinforcement Learning for Enhanced Thermal Updraft Exploitation by Fixed-Wing UAVs. in 2025 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025. 2025 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025, Institute of Electrical and Electronics Engineers Inc., pp. 409-413, 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025, Nanjing, China, 25/07/25. https://doi.org/10.1109/ISAES66870.2025.11274374

Incorporating Pitching Moment Observation in Reinforcement Learning for Enhanced Thermal Updraft Exploitation by Fixed-Wing UAVs. / Zhang, Chengju; Wu, Hongfei; Wei, Guanquan et al.
2025 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025. Institute of Electrical and Electronics Engineers Inc., 2025. p. 409-413 (2025 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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T1 - Incorporating Pitching Moment Observation in Reinforcement Learning for Enhanced Thermal Updraft Exploitation by Fixed-Wing UAVs

AU - Zhang, Chengju

AU - Wu, Hongfei

AU - Wei, Guanquan

AU - Li, Wenjuan

AU - Wang, Jiayang

AU - Liu, Haobo

AU - Li, Ke

AU - Zhang, Biao

PY - 2025

Y1 - 2025

N2 - Fixed-wing UAVs can extend endurance by exploiting atmospheric thermals. Prior reinforcement learning (RL) methods used vertical acceleration and roll moments as state inputs. However, when flying straight through a thermal core, roll cues are weak, making it hard for RL agents to anticipate circling. This can delay thermal centering and waste potential energy gain. We propose adding pitching moment as an additional observation. Pitching moment reflects vertical airflow gradients along the fuselage, providing early cues of strong up-drafts. We design a deep RL agent with three-layer neural network and discrete bank angle actions. Simulations use a stationary Gaussian thermal model and glider dynamics. Results show that the pitchaugmented agent recognizes thermals earlier and begins circling sooner. Compared to baseline models, it gains up to ∼ 8% more altitude in head-on approaches and achieves better centering stability. This confirms that pitching moment sensing enhances autonomous soaring. Future work will explore moving thermals and real-world flight tests.

AB - Fixed-wing UAVs can extend endurance by exploiting atmospheric thermals. Prior reinforcement learning (RL) methods used vertical acceleration and roll moments as state inputs. However, when flying straight through a thermal core, roll cues are weak, making it hard for RL agents to anticipate circling. This can delay thermal centering and waste potential energy gain. We propose adding pitching moment as an additional observation. Pitching moment reflects vertical airflow gradients along the fuselage, providing early cues of strong up-drafts. We design a deep RL agent with three-layer neural network and discrete bank angle actions. Simulations use a stationary Gaussian thermal model and glider dynamics. Results show that the pitchaugmented agent recognizes thermals earlier and begins circling sooner. Compared to baseline models, it gains up to ∼ 8% more altitude in head-on approaches and achieves better centering stability. This confirms that pitching moment sensing enhances autonomous soaring. Future work will explore moving thermals and real-world flight tests.

KW - Gaussian model

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KW - pitch moment

KW - reinforcement learning

KW - state estimation

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M3 - 会议稿件

AN - SCOPUS:105031083561

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BT - 2025 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025

PB - Institute of Electrical and Electronics Engineers Inc.

T2 - 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025

Y2 - 25 July 2025 through 27 July 2025

ER -

Zhang C, Wu H, Wei G, Li W, Wang J, Liu H et al. Incorporating Pitching Moment Observation in Reinforcement Learning for Enhanced Thermal Updraft Exploitation by Fixed-Wing UAVs. In 2025 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025. Institute of Electrical and Electronics Engineers Inc. 2025. p. 409-413. (2025 4th International Symposium on Aerospace Engineering and Systems, ISAES 2025). doi: 10.1109/ISAES66870.2025.11274374

Incorporating Pitching Moment Observation in Reinforcement Learning for Enhanced Thermal Updraft Exploitation by Fixed-Wing UAVs

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