Treatment of arbitrarily autocorrelated load functions in the scope of parameter identification

Katrin Runtemund; Giulio Cottone; Gerhard Müller

doi:10.1016/j.compstruc.2012.11.021

Treatment of arbitrarily autocorrelated load functions in the scope of parameter identification

Katrin Runtemund, Giulio Cottone, Gerhard Müller

Chair of Structural Mechanics

Technical University of Munich

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

Ambient vibration tests are output-only tests based on the structural response recorded under natural excitation, such as wind or traffic loads. In contrast to forced vibration test, they do not require service interruption and expensive devices to excite the structure. To this aim, we combine the recently proposed H-fractional spectral moments representation of stationary processes with a modification of the Kalman filter to the scope of structural parameter identification. This paper shows that the method is particularly suited to dealing with long-correlated loads, i.e. stochastic processes with inverse power-law correlation, where many existing methods are not applicable or insufficiently accurate.

Original language	English
Pages (from-to)	29-40
Number of pages	12
Journal	Computers and Structures
Volume	126
Issue number	1
DOIs	https://doi.org/10.1016/j.compstruc.2012.11.021
State	Published - 2013

Keywords

Ambient vibration tests
Extended kalman filter
Fractional spectral moments
Gaussian stationary noises
Parameter identification
Spectral factorization

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10.1016/j.compstruc.2012.11.021

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abstract = "Ambient vibration tests are output-only tests based on the structural response recorded under natural excitation, such as wind or traffic loads. In contrast to forced vibration test, they do not require service interruption and expensive devices to excite the structure. To this aim, we combine the recently proposed H-fractional spectral moments representation of stationary processes with a modification of the Kalman filter to the scope of structural parameter identification. This paper shows that the method is particularly suited to dealing with long-correlated loads, i.e. stochastic processes with inverse power-law correlation, where many existing methods are not applicable or insufficiently accurate.",

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AB - Ambient vibration tests are output-only tests based on the structural response recorded under natural excitation, such as wind or traffic loads. In contrast to forced vibration test, they do not require service interruption and expensive devices to excite the structure. To this aim, we combine the recently proposed H-fractional spectral moments representation of stationary processes with a modification of the Kalman filter to the scope of structural parameter identification. This paper shows that the method is particularly suited to dealing with long-correlated loads, i.e. stochastic processes with inverse power-law correlation, where many existing methods are not applicable or insufficiently accurate.

KW - Ambient vibration tests

KW - Extended kalman filter

KW - Fractional spectral moments

KW - Gaussian stationary noises

KW - Parameter identification

KW - Spectral factorization

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JO - Computers and Structures

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IS - 1

ER -

Treatment of arbitrarily autocorrelated load functions in the scope of parameter identification

Abstract

Keywords

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