Variability of updated finite element models and their predictions consistent with vibration measurements

Abstract: Abstract:A case study on a small-scale laboratory vehicle frame is used to investigate the variability of the updated finite element (FE) models that arises from model and measurement errors and demonstrate the effect of this variability on response predictions. Conventional weighted modal residuals and recently introduced multi-objective identification methods for structural model updating are used to provide the entire spectrum of Pareto optimal FE models consistent with the measured modal data. Similarities… Show more

“…Minimizing at global minimum the following single objective, traditionally solves the parameter estimation problem: w [6,20,23].…”

Finite Element Model Developed and Modal Analysis of Large Scale Steam Turbine Rotor: Quantification of Uncertainties and Model Updating

“…Minimizing at global minimum the following single objective, traditionally solves the parameter estimation problem: w [6,20,23].…”

Finite Element Model Developed and Modal Analysis of Large Scale Steam Turbine Rotor: Quantification of Uncertainties and Model Updating

“…The proposed computational framework is now applied to the laboratory structure of Fig.4, that has been designed for small-scale simulations of vehicle frames [3,4]. The frame structure is characterized by predominantly linear response and high modal density and it is supported to four "suspension" systems with strongly nonlinear behavior.…”

“…A main challenge involved in the updating procedures pertains to the oftentimes large number of degrees of freedom (DOFs) involved. To tackle with this problem, appropriate substructuring methods in either the time or the frequency domain have been developed and are commonly employed [2][3][4].…”

Model Updating of a Nonlinear Experimental Vehicle Using Substructuring and Unscented Kalman Filtering

“…The system was tested in fixed-free boundary condition. First, all the necessary elements of the FRF matrix required for determining the response of the frame substructure were determined by imposing impulsive loading [1,2,8,9]. The measured frequency range was 0-2048 Hz, which includes the analytical frequency range of interest, 0-400 Hz.…”

Optimum Design, Finite Element Model Updating and Dynamic Analysis of a Full Laminated Glass Panoramic Car Elevator