Your search keyword '"Chamoin, L."' showing total 3 results

1. Merging experimental design and structural identification around the concept of modified Constitutive Relation Error in low-frequency dynamics for enhanced structural monitoring.

Author

Diaz, M., Charbonnel, P.-É., and Chamoin, L.

Subjects

*STRUCTURAL health monitoring, *SENSOR placement, *STRUCTURAL design, *STRUCTURAL frames, *GROUND motion, *EXPERIMENTAL design, *STRUCTURAL dynamics

Abstract

This paper presents a novel Optimal Sensor Placement (OSP) strategy that is dedicated to model updating problems based on the modified Constitutive Relation Error (mCRE) functional in low-frequency dynamics. The mCRE is a credible alternative to model updating functionals that stands out by searching structural parameters alongside mechanical fields as the best trade-off between all available information from measured data, without any further a priori assumption. Considering damage detection problems, due to possible discrepancies in terms of parameters sensitivity with respect to mCRE, sensor locations provided by standard OSP algorithms may be irrelevant. The proposed approach uses the concept of Information Entropy by formulating a modified Fisher information matrix, in which the sensitivity of the mCRE mechanical fields with respect to the updated parameters is involved. The approach is legitimated by the strong connection between mCRE and Bayesian inference. A proof-of-concept involving an earthquake engineering inspired academic case study, where accelerometers are positioned on a two-story frame structure subjected to random ground motion, permits to illustrate the soundness and efficiency of the proposed methodology compared to other classical OSP techniques. The influence of critical mCRE parameters is shown, as well as the benefits of taking multiple scenarios into account so as to get an OSP that is relevant for a wider range of possible damage occurrences. • A new sensor placement technique is proposed for structural monitoring in dynamics. • It aims to improve model updating based on the modified Constitutive Relation Error. • The sensor placement criterion is obtained by coupling mCRE and information entropy. • The proposed approach is compared to classical techniques on a 3D example. • The relevance of the approach for mCRE-based model updating is illustrated. [ABSTRACT FROM AUTHOR]

Published

2023

2. A new Kalman filter approach for structural parameter tracking: Application to the monitoring of damaging structures tested on shaking-tables.

Author

Diaz, M., Charbonnel, P.-É., and Chamoin, L.

Subjects

*KALMAN filtering, *STRUCTURAL health monitoring, *EARTHQUAKE engineering, *FINITE element method, *ADAPTIVE control systems

Abstract

In this paper, a new data assimilation framework for correcting finite element models from datasets acquired on-the-fly in low-frequency dynamics is presented. An Unscented Kalman filter algorithm is coupled with a modified Constitutive Relation Error (mCRE) observer, leading to a Modified Dual Kalman Filter algorithm (MDKF). Built as a Hermitian data-to-model distance written in the frequency domain enriched with a CRE residual accounting for model bias, the mCRE functional has shown interesting assets for model updating purposes, in particular enhanced convexity and robustness to measurement noise. The proposed data assimilation strategy integrates the latter through a metric change in the measurement update equation. It thus differs from classical nonlinear Kalman filtering for parameter estimation as the comparison between measurements and model predictions is achieved through the mCRE functional itself. Besides, the calibration of MDKF internal parameters is facilitated by a set of general guidelines that ensure the performance of the algorithm. The methodology is applied to two earthquake engineering examples. The performances of MDKF are first assessed using synthetic measurements from a plane frame subjected to random ground acceleration. Actual measurements from the SMART2013 benchmark are then assimilated in a real-time context to monitor the eigenfrequency drop of a reinforced-concrete structure submitted to a sequence of gradually damaging shaking-table tests. The nice correlation with (i) data-driven identification results, and (ii) sequential mCRE-based model updating results, illustrates the relevance of this new approach and suggests promising use of MDKF for on-the-fly adaptive control prospects and applications involving data-to-model interaction. • A new Kalman Filter approach is proposed for structural monitoring in dynamics. • The mCRE functional is integrated as observer in a Dual Unscented Kalman Filter. • General guidelines are provided for easy calibration of decisive internal parameters. • The robustness of the methodology is assessed from highly noisy synthetic data. • Actual measurements of the SMART2013 project are processed in a real-time context. [ABSTRACT FROM AUTHOR]

Published

2023

3. Robust energy-based model updating framework for random processes in dynamics: Application to shaking-table experiments.

Author

Diaz, M., Charbonnel, P.-É., and Chamoin, L.

Subjects

*EARTHQUAKE engineering, *SIGNAL-to-noise ratio

Published

2022