BAYESIAN OPTIMAL SENSOR PLACEMENT FOR VIRTUAL SENSING AND STRAIN RECONSTRUCTION

Tulay Ercan; Omid Sedehi; Costas Papadimitriou; Lambros S. Katafgyiotis

doi:10.23967/eccomas.2022.058

BAYESIAN OPTIMAL SENSOR PLACEMENT FOR VIRTUAL SENSING AND STRAIN RECONSTRUCTION

Tulay Ercan
, Omid Sedehi
, Costas Papadimitriou
, Lambros S. Katafgyiotis

Department of Civil and Environmental Engineering

Research output: Contribution to journal › Conference article published in journal › peer-review

Abstract

A Bayesian optimal sensor placement (OSP) framework is presented for virtual sensing in structures using output-only vibration measurements. Particularly, this probabilistic OSP scheme aims to enhance the reconstruction of dynamical responses (e.g., accelerations, displacements, strain, stresses) for updating structural reliability and safety, as well as fatigue lifetime prognosis. The OSP framework is formulated using information theory. The information gained from a sensor configuration is defined as the Kullback-Liebler divergence (KL-div) between the prior and posterior distributions of the response quantities of interest (QoI). The Gaussian nature of the response estimate for linear models of structures is employed, and the information gain is characterized in terms of the reconstruction error covariance matrix. A Kalman-based input-state estimation technique is integrated within an existing OSP strategy, aiming to obtain estimates of response QoI and their uncertainties. The design variables include the location, type and number of sensors. Heuristic algorithms are used to solve optimization problem and provide computationally efficient solutions. The effectiveness of the method is demonstrated using an example from structural dynamics.

Original language	English
Journal	World Congress in Computational Mechanics and ECCOMAS Congress
DOIs	https://doi.org/10.23967/eccomas.2022.058
Publication status	Published - 2022
Event	8th European Congress on Computational Methods in Applied Sciences and Engineering, ECCOMAS Congress 2022 - Oslo, Norway Duration: 5 Jun 2022 → 9 Jun 2022

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Publisher Copyright:
© 2022, Scipedia S.L. All rights reserved.

Keywords

Augmented Kalman Filter
Bayesian Inference
Kullback-Liebler Divergence
Structural Health Monitoring
Virtual Sensing

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10.23967/eccomas.2022.058

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@article{c324ffb4f79142d1abf96863ebd8f189,

title = "BAYESIAN OPTIMAL SENSOR PLACEMENT FOR VIRTUAL SENSING AND STRAIN RECONSTRUCTION",

abstract = "A Bayesian optimal sensor placement (OSP) framework is presented for virtual sensing in structures using output-only vibration measurements. Particularly, this probabilistic OSP scheme aims to enhance the reconstruction of dynamical responses (e.g., accelerations, displacements, strain, stresses) for updating structural reliability and safety, as well as fatigue lifetime prognosis. The OSP framework is formulated using information theory. The information gained from a sensor configuration is defined as the Kullback-Liebler divergence (KL-div) between the prior and posterior distributions of the response quantities of interest (QoI). The Gaussian nature of the response estimate for linear models of structures is employed, and the information gain is characterized in terms of the reconstruction error covariance matrix. A Kalman-based input-state estimation technique is integrated within an existing OSP strategy, aiming to obtain estimates of response QoI and their uncertainties. The design variables include the location, type and number of sensors. Heuristic algorithms are used to solve optimization problem and provide computationally efficient solutions. The effectiveness of the method is demonstrated using an example from structural dynamics.",

keywords = "Augmented Kalman Filter, Bayesian Inference, Kullback-Liebler Divergence, Structural Health Monitoring, Virtual Sensing",

author = "Tulay Ercan and Omid Sedehi and Costas Papadimitriou and Katafgyiotis, \{Lambros S.\}",

note = "Publisher Copyright: {\textcopyright} 2022, Scipedia S.L. All rights reserved.; 8th European Congress on Computational Methods in Applied Sciences and Engineering, ECCOMAS Congress 2022 ; Conference date: 05-06-2022 Through 09-06-2022",

year = "2022",

doi = "10.23967/eccomas.2022.058",

language = "English",

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T1 - BAYESIAN OPTIMAL SENSOR PLACEMENT FOR VIRTUAL SENSING AND STRAIN RECONSTRUCTION

AU - Ercan, Tulay

AU - Sedehi, Omid

AU - Papadimitriou, Costas

AU - Katafgyiotis, Lambros S.

PY - 2022

Y1 - 2022

N2 - A Bayesian optimal sensor placement (OSP) framework is presented for virtual sensing in structures using output-only vibration measurements. Particularly, this probabilistic OSP scheme aims to enhance the reconstruction of dynamical responses (e.g., accelerations, displacements, strain, stresses) for updating structural reliability and safety, as well as fatigue lifetime prognosis. The OSP framework is formulated using information theory. The information gained from a sensor configuration is defined as the Kullback-Liebler divergence (KL-div) between the prior and posterior distributions of the response quantities of interest (QoI). The Gaussian nature of the response estimate for linear models of structures is employed, and the information gain is characterized in terms of the reconstruction error covariance matrix. A Kalman-based input-state estimation technique is integrated within an existing OSP strategy, aiming to obtain estimates of response QoI and their uncertainties. The design variables include the location, type and number of sensors. Heuristic algorithms are used to solve optimization problem and provide computationally efficient solutions. The effectiveness of the method is demonstrated using an example from structural dynamics.

AB - A Bayesian optimal sensor placement (OSP) framework is presented for virtual sensing in structures using output-only vibration measurements. Particularly, this probabilistic OSP scheme aims to enhance the reconstruction of dynamical responses (e.g., accelerations, displacements, strain, stresses) for updating structural reliability and safety, as well as fatigue lifetime prognosis. The OSP framework is formulated using information theory. The information gained from a sensor configuration is defined as the Kullback-Liebler divergence (KL-div) between the prior and posterior distributions of the response quantities of interest (QoI). The Gaussian nature of the response estimate for linear models of structures is employed, and the information gain is characterized in terms of the reconstruction error covariance matrix. A Kalman-based input-state estimation technique is integrated within an existing OSP strategy, aiming to obtain estimates of response QoI and their uncertainties. The design variables include the location, type and number of sensors. Heuristic algorithms are used to solve optimization problem and provide computationally efficient solutions. The effectiveness of the method is demonstrated using an example from structural dynamics.

KW - Augmented Kalman Filter

KW - Bayesian Inference

KW - Kullback-Liebler Divergence

KW - Structural Health Monitoring

KW - Virtual Sensing

UR - https://www.scopus.com/pages/publications/85146945057

UR - https://openalex.org/W4312258068

U2 - 10.23967/eccomas.2022.058

DO - 10.23967/eccomas.2022.058

M3 - Conference article published in journal

AN - SCOPUS:85146945057

SN - 2696-6999

JO - World Congress in Computational Mechanics and ECCOMAS Congress

JF - World Congress in Computational Mechanics and ECCOMAS Congress

T2 - 8th European Congress on Computational Methods in Applied Sciences and Engineering, ECCOMAS Congress 2022

Y2 - 5 June 2022 through 9 June 2022

ER -

BAYESIAN OPTIMAL SENSOR PLACEMENT FOR VIRTUAL SENSING AND STRAIN RECONSTRUCTION

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