An inverse identification strategy for the mechanical parameters of a phenomenological hysteretic constitutive model

An inverse identification strategy for the mechanical parameters of a phenomenological hysteretic constitutive model

•We present an algorithm for the identification of experimental hysteresis loops.•The algorithm uses a previously investigated and very versatile constitutive model.•It proved to be robust, stable and accurate in analyzing four experimental loops. An inverse strategy is developed for identifying the...

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Bibliographic Details
Published in:Mechanical systems and signal processing Vol. 139; p. 106622
Main Authors: Sessa, Salvatore, Vaiana, Nicoló, Paradiso, Massimo, Rosati, Luciano
Format: Journal Article
Language:English
Published: Berlin Elsevier Ltd 01-05-2020
Elsevier BV
Subjects:
Bouc Wen model
Constitutive models
Hysteresis
Hysteretic materials
Inverse identification
Iterative algorithms
Iterative methods
Mathematical models
Mechanical properties
Optimization
Parameter identification
Robustness (mathematics)
Strategy
Hysteretic materials
Bouc Wen model
Inverse identification
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Summary:•We present an algorithm for the identification of experimental hysteresis loops.•The algorithm uses a previously investigated and very versatile constitutive model.•It proved to be robust, stable and accurate in analyzing four experimental loops. An inverse strategy is developed for identifying the parameters of the hysteretic phenomenological constitutive model presented in Vaiana et al. (2019) and belonging to a wider class of hysteretic models. The model, differently from the celebrated Bouc-Wen one, permits the definition of either stress-strain or load-displacement relationships by closed-form expressions that do not require any iterative algorithm for the complete characterization of its response. The identification strategy is based on two optimization procedures performed in sequence in which a mean-square residual between a target and a computed response is minimized. The computation of suitable first trials is shown to represent an essential step of the procedure and is performed by taking advantage of the fact that its parameters correspond to physical quantities characterizing the experimental hysteretic loop. The procedure has been tested by identifying the mechanical parameters of two theoretical and four experimental responses for which numerical results prove the robustness and effectiveness of the proposed identification strategy.
ISSN:0888-3270
1096-1216
DOI:10.1016/j.ymssp.2020.106622