A validated robust and automatic procedure for vibration analysis of bridge structures using MEMS accelerometers

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Mohammad Omidalizarandi
  • Ralf Herrmann
  • Boris Kargoll
  • Steffen Marx
  • Jens-André Paffenholz
  • Ingo Neumann

External Research Organisations

  • BAM Federal Institute for Materials Research and Testing
  • Anhalt University of Applied Sciences
  • Clausthal University of Technology
View graph of relations

Details

Original languageEnglish
Pages (from-to)327–354
Number of pages28
JournalJournal of Applied Geodesy
Volume14
Issue number3
Early online date9 Jun 2020
Publication statusPublished - 26 Jul 2020

Abstract

Today, short- and long-term structural health monitoring (SHM) of bridge infrastructures and their safe, reliable and cost-effective maintenance has received considerable attention. From a surveying or civil engineer’s point of view, vibration-based SHM can be conducted by inspecting the changes in the global dynamic behaviour of a structure, such as natural frequencies (i. e. eigenfrequencies), mode shapes (i. e. eigenforms) and modal damping, which are known as modal parameters. This research work aims to propose a robust and automatic vibration analysis procedure that is so-called robust time domain modal parameter identification (RT-MPI) technique. It is novel in the sense of automatic and reliable identification of initial eigenfrequencies even closely spaced ones as well as robustly and accurately estimating the modal parameters of a bridge structure using low numbers of cost-effective micro-electro-mechanical systems (MEMS) accelerometers. To estimate amplitude, frequency, phase shift and damping ratio coefficients, an observation model consisting of: (1) a damped harmonic oscillation model, (2) an autoregressive model of coloured measurement noise and (3) a stochastic model in the form of the heavy-tailed family of scaled t-distributions is employed and jointly adjusted by means of a generalised expectation maximisation algorithm. Multiple MEMS as part of a geo-sensor network were mounted at different positions of a bridge structure which is precalculated by means of a finite element model (FEM) analysis. At the end, the estimated eigenfrequencies and eigenforms are compared and validated by the estimated parameters obtained from acceleration measurements of high-end accelerometers of type PCB ICP quartz, velocity measurements from a geophone and the FEM analysis. Additionally, the estimated eigenfrequencies and modal damping are compared with a well-known covariance driven stochastic subspace identification approach, which reveals the superiority of our proposed approach. We performed an experiment in two case studies with simulated data and real applications of a footbridge structure and a synthetic bridge. The results show that MEMS accelerometers are suitable for detecting all occurring eigenfrequencies depending on a sampling frequency specified. Moreover, the vibration analysis procedure demonstrates that amplitudes can be estimated in submillimetre range accuracy, frequencies with an accuracy better than 0.1 Hz and damping ratio coefficients with an accuracy better than 0.1 and 0.2 % for modal and system damping, respectively.

Keywords

    : Vibration analysis, Automatic modal parameters identifcation, MEMS accelerometer, Robust parameter estimation, EM algorithm, Double integration, FEM analysis, Bridge monitoring, Automatic modal parameters identification, Vibration analysis

ASJC Scopus subject areas

Cite this

A validated robust and automatic procedure for vibration analysis of bridge structures using MEMS accelerometers. / Omidalizarandi, Mohammad; Herrmann, Ralf; Kargoll, Boris et al.
In: Journal of Applied Geodesy, Vol. 14, No. 3, 26.07.2020, p. 327–354.

Research output: Contribution to journalArticleResearchpeer review

Omidalizarandi, M, Herrmann, R, Kargoll, B, Marx, S, Paffenholz, J-A & Neumann, I 2020, 'A validated robust and automatic procedure for vibration analysis of bridge structures using MEMS accelerometers', Journal of Applied Geodesy, vol. 14, no. 3, pp. 327–354. https://doi.org/10.1515/jag-2020-0010
Omidalizarandi, M., Herrmann, R., Kargoll, B., Marx, S., Paffenholz, J.-A., & Neumann, I. (2020). A validated robust and automatic procedure for vibration analysis of bridge structures using MEMS accelerometers. Journal of Applied Geodesy, 14(3), 327–354. https://doi.org/10.1515/jag-2020-0010
Omidalizarandi M, Herrmann R, Kargoll B, Marx S, Paffenholz JA, Neumann I. A validated robust and automatic procedure for vibration analysis of bridge structures using MEMS accelerometers. Journal of Applied Geodesy. 2020 Jul 26;14(3):327–354. Epub 2020 Jun 9. doi: 10.1515/jag-2020-0010
Omidalizarandi, Mohammad ; Herrmann, Ralf ; Kargoll, Boris et al. / A validated robust and automatic procedure for vibration analysis of bridge structures using MEMS accelerometers. In: Journal of Applied Geodesy. 2020 ; Vol. 14, No. 3. pp. 327–354.
Download
@article{32a38ea6b48c48b18462b6b6ceef8b7f,
title = "A validated robust and automatic procedure for vibration analysis of bridge structures using MEMS accelerometers",
abstract = "Today, short- and long-term structural health monitoring (SHM) of bridge infrastructures and their safe, reliable and cost-effective maintenance has received considerable attention. From a surveying or civil engineer{\textquoteright}s point of view, vibration-based SHM can be conducted by inspecting the changes in the global dynamic behaviour of a structure, such as natural frequencies (i. e. eigenfrequencies), mode shapes (i. e. eigenforms) and modal damping, which are known as modal parameters. This research work aims to propose a robust and automatic vibration analysis procedure that is so-called robust time domain modal parameter identification (RT-MPI) technique. It is novel in the sense of automatic and reliable identification of initial eigenfrequencies even closely spaced ones as well as robustly and accurately estimating the modal parameters of a bridge structure using low numbers of cost-effective micro-electro-mechanical systems (MEMS) accelerometers. To estimate amplitude, frequency, phase shift and damping ratio coefficients, an observation model consisting of: (1) a damped harmonic oscillation model, (2) an autoregressive model of coloured measurement noise and (3) a stochastic model in the form of the heavy-tailed family of scaled t-distributions is employed and jointly adjusted by means of a generalised expectation maximisation algorithm. Multiple MEMS as part of a geo-sensor network were mounted at different positions of a bridge structure which is precalculated by means of a finite element model (FEM) analysis. At the end, the estimated eigenfrequencies and eigenforms are compared and validated by the estimated parameters obtained from acceleration measurements of high-end accelerometers of type PCB ICP quartz, velocity measurements from a geophone and the FEM analysis. Additionally, the estimated eigenfrequencies and modal damping are compared with a well-known covariance driven stochastic subspace identification approach, which reveals the superiority of our proposed approach. We performed an experiment in two case studies with simulated data and real applications of a footbridge structure and a synthetic bridge. The results show that MEMS accelerometers are suitable for detecting all occurring eigenfrequencies depending on a sampling frequency specified. Moreover, the vibration analysis procedure demonstrates that amplitudes can be estimated in submillimetre range accuracy, frequencies with an accuracy better than 0.1 Hz and damping ratio coefficients with an accuracy better than 0.1 and 0.2 % for modal and system damping, respectively.",
keywords = ": Vibration analysis, Automatic modal parameters identifcation, MEMS accelerometer, Robust parameter estimation, EM algorithm, Double integration, FEM analysis, Bridge monitoring, Automatic modal parameters identification, Vibration analysis",
author = "Mohammad Omidalizarandi and Ralf Herrmann and Boris Kargoll and Steffen Marx and Jens-Andr{\'e} Paffenholz and Ingo Neumann",
year = "2020",
month = jul,
day = "26",
doi = "10.1515/jag-2020-0010",
language = "English",
volume = "14",
pages = "327–354",
number = "3",

}

Download

TY - JOUR

T1 - A validated robust and automatic procedure for vibration analysis of bridge structures using MEMS accelerometers

AU - Omidalizarandi, Mohammad

AU - Herrmann, Ralf

AU - Kargoll, Boris

AU - Marx, Steffen

AU - Paffenholz, Jens-André

AU - Neumann, Ingo

PY - 2020/7/26

Y1 - 2020/7/26

N2 - Today, short- and long-term structural health monitoring (SHM) of bridge infrastructures and their safe, reliable and cost-effective maintenance has received considerable attention. From a surveying or civil engineer’s point of view, vibration-based SHM can be conducted by inspecting the changes in the global dynamic behaviour of a structure, such as natural frequencies (i. e. eigenfrequencies), mode shapes (i. e. eigenforms) and modal damping, which are known as modal parameters. This research work aims to propose a robust and automatic vibration analysis procedure that is so-called robust time domain modal parameter identification (RT-MPI) technique. It is novel in the sense of automatic and reliable identification of initial eigenfrequencies even closely spaced ones as well as robustly and accurately estimating the modal parameters of a bridge structure using low numbers of cost-effective micro-electro-mechanical systems (MEMS) accelerometers. To estimate amplitude, frequency, phase shift and damping ratio coefficients, an observation model consisting of: (1) a damped harmonic oscillation model, (2) an autoregressive model of coloured measurement noise and (3) a stochastic model in the form of the heavy-tailed family of scaled t-distributions is employed and jointly adjusted by means of a generalised expectation maximisation algorithm. Multiple MEMS as part of a geo-sensor network were mounted at different positions of a bridge structure which is precalculated by means of a finite element model (FEM) analysis. At the end, the estimated eigenfrequencies and eigenforms are compared and validated by the estimated parameters obtained from acceleration measurements of high-end accelerometers of type PCB ICP quartz, velocity measurements from a geophone and the FEM analysis. Additionally, the estimated eigenfrequencies and modal damping are compared with a well-known covariance driven stochastic subspace identification approach, which reveals the superiority of our proposed approach. We performed an experiment in two case studies with simulated data and real applications of a footbridge structure and a synthetic bridge. The results show that MEMS accelerometers are suitable for detecting all occurring eigenfrequencies depending on a sampling frequency specified. Moreover, the vibration analysis procedure demonstrates that amplitudes can be estimated in submillimetre range accuracy, frequencies with an accuracy better than 0.1 Hz and damping ratio coefficients with an accuracy better than 0.1 and 0.2 % for modal and system damping, respectively.

AB - Today, short- and long-term structural health monitoring (SHM) of bridge infrastructures and their safe, reliable and cost-effective maintenance has received considerable attention. From a surveying or civil engineer’s point of view, vibration-based SHM can be conducted by inspecting the changes in the global dynamic behaviour of a structure, such as natural frequencies (i. e. eigenfrequencies), mode shapes (i. e. eigenforms) and modal damping, which are known as modal parameters. This research work aims to propose a robust and automatic vibration analysis procedure that is so-called robust time domain modal parameter identification (RT-MPI) technique. It is novel in the sense of automatic and reliable identification of initial eigenfrequencies even closely spaced ones as well as robustly and accurately estimating the modal parameters of a bridge structure using low numbers of cost-effective micro-electro-mechanical systems (MEMS) accelerometers. To estimate amplitude, frequency, phase shift and damping ratio coefficients, an observation model consisting of: (1) a damped harmonic oscillation model, (2) an autoregressive model of coloured measurement noise and (3) a stochastic model in the form of the heavy-tailed family of scaled t-distributions is employed and jointly adjusted by means of a generalised expectation maximisation algorithm. Multiple MEMS as part of a geo-sensor network were mounted at different positions of a bridge structure which is precalculated by means of a finite element model (FEM) analysis. At the end, the estimated eigenfrequencies and eigenforms are compared and validated by the estimated parameters obtained from acceleration measurements of high-end accelerometers of type PCB ICP quartz, velocity measurements from a geophone and the FEM analysis. Additionally, the estimated eigenfrequencies and modal damping are compared with a well-known covariance driven stochastic subspace identification approach, which reveals the superiority of our proposed approach. We performed an experiment in two case studies with simulated data and real applications of a footbridge structure and a synthetic bridge. The results show that MEMS accelerometers are suitable for detecting all occurring eigenfrequencies depending on a sampling frequency specified. Moreover, the vibration analysis procedure demonstrates that amplitudes can be estimated in submillimetre range accuracy, frequencies with an accuracy better than 0.1 Hz and damping ratio coefficients with an accuracy better than 0.1 and 0.2 % for modal and system damping, respectively.

KW - : Vibration analysis

KW - Automatic modal parameters identifcation

KW - MEMS accelerometer

KW - Robust parameter estimation

KW - EM algorithm

KW - Double integration

KW - FEM analysis

KW - Bridge monitoring

KW - Automatic modal parameters identification

KW - Vibration analysis

UR - http://www.scopus.com/inward/record.url?scp=85086926742&partnerID=8YFLogxK

U2 - 10.1515/jag-2020-0010

DO - 10.1515/jag-2020-0010

M3 - Article

VL - 14

SP - 327

EP - 354

JO - Journal of Applied Geodesy

JF - Journal of Applied Geodesy

SN - 1862-9016

IS - 3

ER -

By the same author(s)