Interpretability Analysis and Combined Prediction of the Coupled Relationship Between Pilot Fatigue and Situational Awareness

Xinggang Hou; Yuan Feng; Bingchen Gou; Dengkai Chen; Jianjie Chu; Lin Ma

doi:10.1007/978-3-031-92977-9_18

Interpretability Analysis and Combined Prediction of the Coupled Relationship Between Pilot Fatigue and Situational Awareness

Xinggang Hou, Yuan Feng, Bingchen Gou, Dengkai Chen, Jianjie Chu, Lin Ma

School of Mechanical Engineering

Northwestern Polytechnical University Xian

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

Abstract

Fatigue and situational awareness are key risk factors for pilot effectiveness in automatic cruise. In order to explore the nonlinear coupling relationship between pilot fatigue and situational awareness in automatic cruise and to reduce the multiple covariance between the predictive features, a comprehensive analysis based on machine learning interpretable techniques is performed in the spatial and temporal dimensions to improve the prediction accuracy. First, multidimensional time series were constructed from multimodal physiological data, and high-precision prediction models for both were built separately. The Shapley additive explanations were utilized in the spatial dimension to visualize the contribution of predictive features, identify the key features, and explain the unique attributes of physiological activities at different levels of efficacy. Second, we reconstruct the predictive model and analyze the evolution logic of fatigue and situational awareness in the time dimension and elucidate their coupling through correlation analysis. Finally, we fused the key features of fatigue and situational awareness, dynamically weighted the performance states, and constructed a comprehensive prediction model of pilot performance under auto-cruise. A total of 40 subjects’ physiological data of 90 min each were collected for analysis, and the prediction model was constructed with XGboost to demonstrate the feasibility of the proposed method. In contrast, the proposed method produces more accurate and interpretable prediction results, which can effectively contribute to the development of human-machine ergonomics in aviation.

Original language	English
Title of host publication	Distributed, Ambient and Pervasive Interactions - 13th International Conference, DAPI 2025, Held as Part of the 27th HCI International Conference, HCII 2025, Proceedings
Editors	Norbert A. Streitz, Shinichi Konomi
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	288-302
Number of pages	15
ISBN (Print)	9783031929762
DOIs	https://doi.org/10.1007/978-3-031-92977-9_18
State	Published - 2025
Event	13th International Conference on Distributed, Ambient and Pervasive Interactions, DAPI 2025, held as part of the 27th HCI International Conference, HCII 2025 - Gothenburg, Sweden Duration: 22 Jun 2025 → 27 Jun 2025

Publication series

Name	Lecture Notes in Computer Science
Volume	15802 LNCS
ISSN (Print)	0302-9743
ISSN (Electronic)	1611-3349

Conference

Conference	13th International Conference on Distributed, Ambient and Pervasive Interactions, DAPI 2025, held as part of the 27th HCI International Conference, HCII 2025
Country/Territory	Sweden
City	Gothenburg
Period	22/06/25 → 27/06/25

Keywords

Automatic Cruise
Comprehensive Ergonomics
Fatigue
Key Features
Situational Awareness

Access to Document

10.1007/978-3-031-92977-9_18

Cite this

Hou, X., Feng, Y., Gou, B., Chen, D., Chu, J., & Ma, L. (2025). Interpretability Analysis and Combined Prediction of the Coupled Relationship Between Pilot Fatigue and Situational Awareness. In N. A. Streitz, & S. Konomi (Eds.), Distributed, Ambient and Pervasive Interactions - 13th International Conference, DAPI 2025, Held as Part of the 27th HCI International Conference, HCII 2025, Proceedings (pp. 288-302). (Lecture Notes in Computer Science; Vol. 15802 LNCS). Springer Science and Business Media Deutschland GmbH. https://doi.org/10.1007/978-3-031-92977-9_18

Hou, Xinggang ; Feng, Yuan ; Gou, Bingchen et al. / Interpretability Analysis and Combined Prediction of the Coupled Relationship Between Pilot Fatigue and Situational Awareness. Distributed, Ambient and Pervasive Interactions - 13th International Conference, DAPI 2025, Held as Part of the 27th HCI International Conference, HCII 2025, Proceedings. editor / Norbert A. Streitz ; Shinichi Konomi. Springer Science and Business Media Deutschland GmbH, 2025. pp. 288-302 (Lecture Notes in Computer Science).

@inproceedings{1b98c94e8781401ab2f0dba1d2222249,

title = "Interpretability Analysis and Combined Prediction of the Coupled Relationship Between Pilot Fatigue and Situational Awareness",

abstract = "Fatigue and situational awareness are key risk factors for pilot effectiveness in automatic cruise. In order to explore the nonlinear coupling relationship between pilot fatigue and situational awareness in automatic cruise and to reduce the multiple covariance between the predictive features, a comprehensive analysis based on machine learning interpretable techniques is performed in the spatial and temporal dimensions to improve the prediction accuracy. First, multidimensional time series were constructed from multimodal physiological data, and high-precision prediction models for both were built separately. The Shapley additive explanations were utilized in the spatial dimension to visualize the contribution of predictive features, identify the key features, and explain the unique attributes of physiological activities at different levels of efficacy. Second, we reconstruct the predictive model and analyze the evolution logic of fatigue and situational awareness in the time dimension and elucidate their coupling through correlation analysis. Finally, we fused the key features of fatigue and situational awareness, dynamically weighted the performance states, and constructed a comprehensive prediction model of pilot performance under auto-cruise. A total of 40 subjects{\textquoteright} physiological data of 90 min each were collected for analysis, and the prediction model was constructed with XGboost to demonstrate the feasibility of the proposed method. In contrast, the proposed method produces more accurate and interpretable prediction results, which can effectively contribute to the development of human-machine ergonomics in aviation.",

keywords = "Automatic Cruise, Comprehensive Ergonomics, Fatigue, Key Features, Situational Awareness",

author = "Xinggang Hou and Yuan Feng and Bingchen Gou and Dengkai Chen and Jianjie Chu and Lin Ma",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive license to Springer Nature Switzerland AG 2025.; 13th International Conference on Distributed, Ambient and Pervasive Interactions, DAPI 2025, held as part of the 27th HCI International Conference, HCII 2025 ; Conference date: 22-06-2025 Through 27-06-2025",

year = "2025",

doi = "10.1007/978-3-031-92977-9_18",

language = "英语",

isbn = "9783031929762",

series = "Lecture Notes in Computer Science",

publisher = "Springer Science and Business Media Deutschland GmbH",

pages = "288--302",

editor = "Streitz, {Norbert A.} and Shinichi Konomi",

booktitle = "Distributed, Ambient and Pervasive Interactions - 13th International Conference, DAPI 2025, Held as Part of the 27th HCI International Conference, HCII 2025, Proceedings",

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Hou, X, Feng, Y, Gou, B, Chen, D, Chu, J & Ma, L 2025, Interpretability Analysis and Combined Prediction of the Coupled Relationship Between Pilot Fatigue and Situational Awareness. in NA Streitz & S Konomi (eds), Distributed, Ambient and Pervasive Interactions - 13th International Conference, DAPI 2025, Held as Part of the 27th HCI International Conference, HCII 2025, Proceedings. Lecture Notes in Computer Science, vol. 15802 LNCS, Springer Science and Business Media Deutschland GmbH, pp. 288-302, 13th International Conference on Distributed, Ambient and Pervasive Interactions, DAPI 2025, held as part of the 27th HCI International Conference, HCII 2025, Gothenburg, Sweden, 22/06/25. https://doi.org/10.1007/978-3-031-92977-9_18

Interpretability Analysis and Combined Prediction of the Coupled Relationship Between Pilot Fatigue and Situational Awareness. / Hou, Xinggang; Feng, Yuan; Gou, Bingchen et al.
Distributed, Ambient and Pervasive Interactions - 13th International Conference, DAPI 2025, Held as Part of the 27th HCI International Conference, HCII 2025, Proceedings. ed. / Norbert A. Streitz; Shinichi Konomi. Springer Science and Business Media Deutschland GmbH, 2025. p. 288-302 (Lecture Notes in Computer Science; Vol. 15802 LNCS).

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

TY - GEN

T1 - Interpretability Analysis and Combined Prediction of the Coupled Relationship Between Pilot Fatigue and Situational Awareness

AU - Hou, Xinggang

AU - Feng, Yuan

AU - Gou, Bingchen

AU - Chen, Dengkai

AU - Chu, Jianjie

AU - Ma, Lin

N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Nature Switzerland AG 2025.

PY - 2025

Y1 - 2025

N2 - Fatigue and situational awareness are key risk factors for pilot effectiveness in automatic cruise. In order to explore the nonlinear coupling relationship between pilot fatigue and situational awareness in automatic cruise and to reduce the multiple covariance between the predictive features, a comprehensive analysis based on machine learning interpretable techniques is performed in the spatial and temporal dimensions to improve the prediction accuracy. First, multidimensional time series were constructed from multimodal physiological data, and high-precision prediction models for both were built separately. The Shapley additive explanations were utilized in the spatial dimension to visualize the contribution of predictive features, identify the key features, and explain the unique attributes of physiological activities at different levels of efficacy. Second, we reconstruct the predictive model and analyze the evolution logic of fatigue and situational awareness in the time dimension and elucidate their coupling through correlation analysis. Finally, we fused the key features of fatigue and situational awareness, dynamically weighted the performance states, and constructed a comprehensive prediction model of pilot performance under auto-cruise. A total of 40 subjects’ physiological data of 90 min each were collected for analysis, and the prediction model was constructed with XGboost to demonstrate the feasibility of the proposed method. In contrast, the proposed method produces more accurate and interpretable prediction results, which can effectively contribute to the development of human-machine ergonomics in aviation.

AB - Fatigue and situational awareness are key risk factors for pilot effectiveness in automatic cruise. In order to explore the nonlinear coupling relationship between pilot fatigue and situational awareness in automatic cruise and to reduce the multiple covariance between the predictive features, a comprehensive analysis based on machine learning interpretable techniques is performed in the spatial and temporal dimensions to improve the prediction accuracy. First, multidimensional time series were constructed from multimodal physiological data, and high-precision prediction models for both were built separately. The Shapley additive explanations were utilized in the spatial dimension to visualize the contribution of predictive features, identify the key features, and explain the unique attributes of physiological activities at different levels of efficacy. Second, we reconstruct the predictive model and analyze the evolution logic of fatigue and situational awareness in the time dimension and elucidate their coupling through correlation analysis. Finally, we fused the key features of fatigue and situational awareness, dynamically weighted the performance states, and constructed a comprehensive prediction model of pilot performance under auto-cruise. A total of 40 subjects’ physiological data of 90 min each were collected for analysis, and the prediction model was constructed with XGboost to demonstrate the feasibility of the proposed method. In contrast, the proposed method produces more accurate and interpretable prediction results, which can effectively contribute to the development of human-machine ergonomics in aviation.

KW - Automatic Cruise

KW - Comprehensive Ergonomics

KW - Fatigue

KW - Key Features

KW - Situational Awareness

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DO - 10.1007/978-3-031-92977-9_18

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SN - 9783031929762

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BT - Distributed, Ambient and Pervasive Interactions - 13th International Conference, DAPI 2025, Held as Part of the 27th HCI International Conference, HCII 2025, Proceedings

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Hou X, Feng Y, Gou B, Chen D, Chu J, Ma L. Interpretability Analysis and Combined Prediction of the Coupled Relationship Between Pilot Fatigue and Situational Awareness. In Streitz NA, Konomi S, editors, Distributed, Ambient and Pervasive Interactions - 13th International Conference, DAPI 2025, Held as Part of the 27th HCI International Conference, HCII 2025, Proceedings. Springer Science and Business Media Deutschland GmbH. 2025. p. 288-302. (Lecture Notes in Computer Science). doi: 10.1007/978-3-031-92977-9_18

Interpretability Analysis and Combined Prediction of the Coupled Relationship Between Pilot Fatigue and Situational Awareness

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