Probability Density Evolution for Time-Varying Reliability Assessment of Wing Structures

Afshari, Sajad Saraygord; Pourtakdoust, Seid H.

doi:10.3846/aviation.2018.6010

Cited by 12 publications

(6 citation statements)

References 18 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…They presented the PDEM formula according to the principle of probability preservation, which allowed for randomness propagations in dynamic structures. The PDEM has received increasing attention during the recent decade and has been verified via several theoretical and experimental investigations 41,42 . The applicability of the PDEM has also been validated through comparisons with other methods, such as the Monte Carlo simulation of the reliability assessment of complex structures 43 .…”

Section: Introductionmentioning

confidence: 95%

“…The PDEM has received increasing attention during the recent decade and has been verified via several theoretical and experimental investigations. 41,42 The applicability of the PDEM has also been validated through comparisons with other methods, such as the Monte Carlo simulation of the reliability assessment of complex structures. 43 Although the PDEM has facilitated the analysis of complex and nonlinear stochastic structures, it still requires an efficient method to solve the equations of motion of structural systems to predict the time-varying derivative of the structural response, which is the PDEM input.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Time‐varying reliability analysis based on hybrid Kalman filtering and probability density evolution

Ghorbani,

Afshari,

Svecova

et al. 2023

Earthq Engng Struct Dyn

View full text Add to dashboard Cite

The study introduces a novel approach for time‐varying reliability analysis of structures called “hybrid UKF‐PDEM” by integrating the unscented Kalman filter (UKF) and the probability density evolution method (PDEM). The UKF estimates the displacement, velocity, stiffness, and damping parameters of a structure at each time step subjected to dynamic loading for structural damage quantification. The estimated parameters at each time step are then input into the PDEM to calculate the time‐varying probability density function (PDF) of the estimated states. The estimated PDF is used to update the uncertainty matrix of the estimated states in each iteration and to determine the time‐varying reliability curves of the structure. To demonstrate the effectiveness of the proposed method, we applied it to a numerical model of a three‐degree‐of‐freedom system and a full‐scale seven‐story building with different damage scenarios. The method is used to estimate the level of damage and calculate the corresponding reliability curve of the system over time for each damage scenario, utilizing the estimated structural responses and stiffness values. The extracted reliability values for each damage scenario follow the level of damage over time. This study shows that the newly developed method is computationally efficient for building a digital twin and enables real‐time damage identification and reliability analysis in various structural systems. The method's applicability to different types of structures highlights its versatility and potential for widespread use in assessing the integrity of buildings and infrastructure.

show abstract

Section: Introductionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Time‐varying reliability analysis based on hybrid Kalman filtering and probability density evolution

Ghorbani,

Afshari,

Svecova

et al. 2023

Earthq Engng Struct Dyn

View full text Add to dashboard Cite

show abstract

“…The accuracy and effectiveness of PDEM have been rigorously examined through theoretical investigations and numerical validations, 41–43 demonstrating its capability to capture intricate probabilistic behaviors of complex systems. Furthermore, PDEM has found wide applications in various engineering domains, facilitating studies on uncertainty propagation 44–46 and reliability analysis 47–49 . Recent advancements 50 suggest that joint PDFs of multiple response quantities can be realized through the solution of decoupled one‐dimensional Li‐Chen equations, further reducing the computational complexity of time‐variant joint PDF analysis.…”

Section: Introductionmentioning

confidence: 99%

“…Furthermore, PDEM has found wide applications in various engineering domains, facilitating studies on uncertainty propagation [44][45][46] and reliability analysis. [47][48][49] Recent advancements 50 suggest that joint PDFs of multiple response quantities can be realized through the solution of decoupled one-dimensional Li-Chen equations, further reducing the computational complexity of time-variant joint PDF analysis.…”

Section: Introductionmentioning

confidence: 99%

A full‐probabilistic cloud analysis for structural seismic fragility via decoupled M‐PDEM

Lyu,

Feng,

Cao

et al. 2024

Earthq Engng Struct Dyn

View full text Add to dashboard Cite

Performance‐based earthquake engineering (PBEE) is essential for ensuring engineering safety. Conducting seismic fragility analysis within this framework is imperative. Existing methods for seismic fragility analysis often rely heavily on double loop reanalysis and empirical data fitting, leading to challenges in obtaining high‐precision results with a limited number of representative structural analysis instances. In this context, a new methodology for seismic fragility based on a full‐probabilistic cloud analysis is proposed via the decoupled multi‐probability density evolution method (M‐PDEM). In the proposed method, the assumption of a log‐normal distribution is not required. According to the random event description of the principle of preservation of probability, the transient probability density functions (PDFs) of intensity measure (IM) and engineering demand parameter (EDP), as key response quantities of the seismic‐structural system, are governed by one‐dimensional Li‐Chen equations, where the physics‐driven forces are determined by representative analysis data of the stochastic dynamic system. By generating ground motions based on representative points of basic random variables and performing structural dynamic analysis, the decoupled M‐PDEM is employed to solve the one‐dimensional Li‐Chen equations. This yields the joint PDF of IM and EDP, as well as the conditional PDF of EDP given IM, resulting in seismic fragility analysis outcomes. The numerical implementation procedure is elaborated in detail, and validation is performed using a six‐story nonlinear reinforced concrete (RC) frame subjected to non‐stationary stochastic ground motions. Comparative analysis against Monte Carlo simulation (MCS) and traditional cloud analysis based on least squares regression (LSR) reveals that the proposed method achieves higher computational precision at comparable structural analysis costs. By directly solving the physics‐driven Li‐Chen equations, the method provides the full‐probabilistic joint information of IM and EDP required for cloud analysis, surpassing the accuracy achieved by traditional methods based on statistical moment fitting and empirical distribution assumptions.

show abstract

“…In addition, by deriving the General Density Evolution Equation (GDEE) they proved that in stochastic structural systems, the equations governing the evolution of the probability density can be decoupled by introducing the physical solution of the system [3]. Over the past decade, PDEM has been used successfully in many numerical studies on the stochastic behavior of the structures [4][5][6] and has been validated in experimental studies [7,8]. Although PDEM decouples the probability density evolution PDE in the probability space [9], numerical treatment of the governing equations is still stringent and impractical for real-time applications.…”

Section: Introductionmentioning

confidence: 99%

A deep learning approach for the solution of probability density evolution of stochastic systems

Pourtakdoust

Khodabakhsh²

2022

Structural Safety

Self Cite

View full text Add to dashboard Cite

Probability Density Evolution for Time-Varying Reliability Assessment of Wing Structures

Cited by 12 publications

References 18 publications

Time‐varying reliability analysis based on hybrid Kalman filtering and probability density evolution

Time‐varying reliability analysis based on hybrid Kalman filtering and probability density evolution

A full‐probabilistic cloud analysis for structural seismic fragility via decoupled M‐PDEM

A deep learning approach for the solution of probability density evolution of stochastic systems

Contact Info

Product

Resources

About