A LOAD UNCERTAINTY QUANTIFICATION-BASED METHOD FOR LOADING RELIABILITY ASSESSMENT OF FULL-SCALE STRUCTURAL TEST

Yuhang Cui; Yunwen Feng; Qian He; Xiaofeng Xue; Jun Lu

doi:10.1049/icp.2025.3749

A LOAD UNCERTAINTY QUANTIFICATION-BASED METHOD FOR LOADING RELIABILITY ASSESSMENT OF FULL-SCALE STRUCTURAL TEST

Yuhang Cui
, Yunwen Feng
, Qian He
, Xiaofeng Xue
, Jun Lu

航空学院

Northwestern Polytechnical University Xian
Chinese Flight Test Establishment
Commercial Aircraft Corporation of China, Ltd.

科研成果: 期刊稿件 › 会议文章 › 同行评审

摘要

In full-scale structural testing, applied loads are subject to the influence of multiple interacting factors, resulting in complex nonlinear relationships and inherent uncertainty. To evaluate the impact of such uncertainty on loading reliability, a reliability assessment framework based on Load Uncertainty Quantification (LUQ) is proposed. A piecewise machine learning modeling strategy is first utilized to construct a predictive model for load uncertainty parameters derived from historical load data. Quantification of load uncertainty is subsequently performed by integrating specific test input conditions. In order to account for both permissible load deviation thresholds and the statistical dependencies among uncertainties at various loading points, a Copula-based method is adopted for evaluating loading reliability. A case study focused on a Full-Scale Structural Test (FSST) is used to verify the proposed methodology, demonstrating its accuracy, effectiveness, and applicability. The findings offer meaningful insights for reliability assessment in other complex structural testing contexts.

源语言	英语
页（从-至）	1627-1634
页数	8
期刊	IET Conference Proceedings
卷	2025
期	35
DOI	https://doi.org/10.1049/icp.2025.3749
出版状态	已出版 - 1 12月 2025
活动	15th International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering, QR2MSE 2025 - Hohhot, 中国期限: 23 7月 2025 → 26 7月 2025

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title = "A LOAD UNCERTAINTY QUANTIFICATION-BASED METHOD FOR LOADING RELIABILITY ASSESSMENT OF FULL-SCALE STRUCTURAL TEST",

abstract = "In full-scale structural testing, applied loads are subject to the influence of multiple interacting factors, resulting in complex nonlinear relationships and inherent uncertainty. To evaluate the impact of such uncertainty on loading reliability, a reliability assessment framework based on Load Uncertainty Quantification (LUQ) is proposed. A piecewise machine learning modeling strategy is first utilized to construct a predictive model for load uncertainty parameters derived from historical load data. Quantification of load uncertainty is subsequently performed by integrating specific test input conditions. In order to account for both permissible load deviation thresholds and the statistical dependencies among uncertainties at various loading points, a Copula-based method is adopted for evaluating loading reliability. A case study focused on a Full-Scale Structural Test (FSST) is used to verify the proposed methodology, demonstrating its accuracy, effectiveness, and applicability. The findings offer meaningful insights for reliability assessment in other complex structural testing contexts.",

keywords = "FULL-SCALE STRUCTURAL TEST, MACHINE LEARNING, PIECEWISE MODELING STRATEGY, RELIABILITY ASSESSMENT, UNCERTAINTY QUANTIFICATION",

author = "Yuhang Cui and Yunwen Feng and Qian He and Xiaofeng Xue and Jun Lu",

note = "Publisher Copyright: {\textcopyright} The Institution of Engineering \& Technology 2025.; 15th International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering, QR2MSE 2025 ; Conference date: 23-07-2025 Through 26-07-2025",

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T1 - A LOAD UNCERTAINTY QUANTIFICATION-BASED METHOD FOR LOADING RELIABILITY ASSESSMENT OF FULL-SCALE STRUCTURAL TEST

AU - Cui, Yuhang

AU - Feng, Yunwen

AU - He, Qian

AU - Xue, Xiaofeng

AU - Lu, Jun

N1 - Publisher Copyright: © The Institution of Engineering & Technology 2025.

PY - 2025/12/1

Y1 - 2025/12/1

N2 - In full-scale structural testing, applied loads are subject to the influence of multiple interacting factors, resulting in complex nonlinear relationships and inherent uncertainty. To evaluate the impact of such uncertainty on loading reliability, a reliability assessment framework based on Load Uncertainty Quantification (LUQ) is proposed. A piecewise machine learning modeling strategy is first utilized to construct a predictive model for load uncertainty parameters derived from historical load data. Quantification of load uncertainty is subsequently performed by integrating specific test input conditions. In order to account for both permissible load deviation thresholds and the statistical dependencies among uncertainties at various loading points, a Copula-based method is adopted for evaluating loading reliability. A case study focused on a Full-Scale Structural Test (FSST) is used to verify the proposed methodology, demonstrating its accuracy, effectiveness, and applicability. The findings offer meaningful insights for reliability assessment in other complex structural testing contexts.

AB - In full-scale structural testing, applied loads are subject to the influence of multiple interacting factors, resulting in complex nonlinear relationships and inherent uncertainty. To evaluate the impact of such uncertainty on loading reliability, a reliability assessment framework based on Load Uncertainty Quantification (LUQ) is proposed. A piecewise machine learning modeling strategy is first utilized to construct a predictive model for load uncertainty parameters derived from historical load data. Quantification of load uncertainty is subsequently performed by integrating specific test input conditions. In order to account for both permissible load deviation thresholds and the statistical dependencies among uncertainties at various loading points, a Copula-based method is adopted for evaluating loading reliability. A case study focused on a Full-Scale Structural Test (FSST) is used to verify the proposed methodology, demonstrating its accuracy, effectiveness, and applicability. The findings offer meaningful insights for reliability assessment in other complex structural testing contexts.

KW - FULL-SCALE STRUCTURAL TEST

KW - MACHINE LEARNING

KW - PIECEWISE MODELING STRATEGY

KW - RELIABILITY ASSESSMENT

KW - UNCERTAINTY QUANTIFICATION

UR - https://www.scopus.com/pages/publications/105038572849

U2 - 10.1049/icp.2025.3749

DO - 10.1049/icp.2025.3749

M3 - 会议文章

AN - SCOPUS:105038572849

SN - 2732-4494

VL - 2025

SP - 1627

EP - 1634

JO - IET Conference Proceedings

JF - IET Conference Proceedings

IS - 35

T2 - 15th International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering, QR2MSE 2025

Y2 - 23 July 2025 through 26 July 2025

ER -

A LOAD UNCERTAINTY QUANTIFICATION-BASED METHOD FOR LOADING RELIABILITY ASSESSMENT OF FULL-SCALE STRUCTURAL TEST

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