The Virtual Fields Method for Extracting Constitutive Parameters From Full-Field Measurements: a Review

This paper presents a short overview of the state of the art and future challenges of the use of full-field measurements and inverse procedures to identify the constitutive mechanical parameters of a wide range of materials. It concentrates on the so-called Virtual Fields Method (VFM) which is a tool fully dedicated to the processing of full-field measurements. Some of the future challenges are briefly covered here, namely the design of test configurations and the application to damage assessment, high strain rate testing and biomaterials. Some examples are given and the main scientific issues briefly discussed.

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Stress Analysis and Identification with Full-Field Measurements

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.3-4.9 ◽

2006 ◽

Vol 3-4 ◽

pp. 9-16 ◽

Cited By ~ 1

Author(s):

M. Grédiac

Keyword(s):

Model Updating ◽

Measurement Techniques ◽

Field Measurements ◽

Element Model ◽

Finite Element Model Updating ◽

Strain Fields ◽

Full Field ◽

Full Field Measurement ◽

Constitutive Parameters ◽

The Finite Element Model

The wealth of information provided by full-field measurement techniques is very useful in experimental mechanics. Among different possible applications, full-field measurements can be used to identify parameters governing constitutive equations from heterogeneous strain fields. This keynote lecture first describes the different possible uses of such measurements. It then focuses on the virtual fields method which has been proposed to extract constitutive parameters from full-field measurements. Finally, the method is compared with the finite element model updating technique which is usually used for solving such a problem.

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Identification of a macroscopic anisotropic damage model using digital image correlation and the equilibrium gap method

European Journal of Computational Mechanics ◽

10.13052/ejcm.19.229-240 ◽

2010 ◽

pp. 229-240

Author(s):

Laurent Crouzeix ◽

Jean-Noël Périé ◽

Francis Collombet ◽

Bernard Douchin

Keyword(s):

Digital Image Correlation ◽

Digital Image ◽

Damage Model ◽

Field Measurements ◽

Image Correlation ◽

Anisotropic Damage ◽

Biaxial Test ◽

Displacement Fields ◽

Full Field ◽

Constitutive Parameters

The aim of the work is to demonstrate how an anisotropic damage model may be identified from full field measurements retrieved during a heterogeneous test. The example of a biaxial test performed on a 3D C / C composite is used. In a first step, the displacement fields measured by classical Digital Image Correlation are used as input data of a finite difference version of the Equilibrium Gap Method. A benefit from unloadings (assumed to be elastic) is shown to retrieve a damage law. In a second step, inelastic strains can be assessed from the total measured strain and the elastic estimated strains. The constitutive parameters relative to the inelastic part of the model are then identified.

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Identification of the Through-Thickness Orthotropic Stiffness of Composite Tubes from Full-Field Measurements

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.3-4.161 ◽

2006 ◽

Vol 3-4 ◽

pp. 161-166 ◽

Cited By ~ 1

Author(s):

Raphaël Moulart ◽

Stephane Avril ◽

Fabrice Pierron

Keyword(s):

Simultaneous Measurement ◽

Strain Field ◽

Grid Method ◽

Field Measurements ◽

Virtual Fields Method ◽

Inhomogeneous Distribution ◽

Epoxy Ring ◽

Full Field ◽

Simultaneous Identification ◽

Diametral Compression Test

This paper deals with the simultaneous identification of the four through-thickness orthotropic rigidities of a thick composite tube. A diametral compression test has been carried out on a glass/epoxy ring cut from the tube. The full strain field has been measured over one face of the sample with the grid method. The measured fields have been processed with the Virtual Fields Method to identify the rigidities of the material. At the beginning, discrepancies and significant variations occurred in the identified moduli due to inhomogeneous distribution of the strains through the thickness. A method based on a simultaneous measurement on both sides of the ring has been adopted. Very satisfactory results have been obtained using this methodology.

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Computation of Elastic Constants of Functionally Graded Materials Using Eigenfunction Virtual Fields Method

Volume 9: Mechanics of Solids, Structures and Fluids ◽

10.1115/imece2013-64584 ◽

2013 ◽

Author(s):

Nigamaa Nayakanti ◽

S. J. Subramanian

Keyword(s):

Elastic Modulus ◽

Functionally Graded ◽

System Of Nonlinear Equations ◽

Strain Component ◽

Virtual Fields Method ◽

Full Field ◽

Linear Elastic ◽

Property Evaluation ◽

Material Length Scale ◽

Constitutive Parameters

The Virtual Fields Method (VFM) is a technique for computing material properties from full-field data. Recently, a variant of this technique, called Eigenfunction Virtual Fields Method (EVFM) has been proposed and applied to homogeneous linear elastic property evaluation. In this work, we extend this technique to heterogeneous materials by applying it to linear elastic material with exponentially varying elastic modulus. For such materials, there are three constitutive parameters to be evaluated: an elastic modulus, the Poisson’s ratio and a material length scale parameter β that controls spatial variation of the elastic modulus. We consider a plate made of such a material, with a circular hole, subjected to uni-axial tension in this study. The elasticity solution to this problem is synthesized using FEM, and strain fields in the vicinity of the hole are obtained on a rectangular grid. These strain component fields are assembled into an augmented strain matrix, whose eigenfunctions are obtained through Principal Components Analysis (PCA). EVFM is then performed using these eigenfunctions as virtual fields and solution of the resulting system of nonlinear equations yields values for the material parameters that are in excellent agreement with the true values.

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A full-field image conversion method for the inverse conductivity problem with internal measurements

Proceedings of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rspa.2015.0488 ◽

2016 ◽

Vol 472 (2187) ◽

pp. 20150488 ◽

Cited By ~ 3

Author(s):

Cédric Bellis ◽

Hervé Moulinec

Keyword(s):

Heterogeneous Material ◽

Field Measurements ◽

Direct Conversion ◽

Full Field ◽

Inverse Conductivity Problem ◽

Approximation Quality ◽

Image Conversion ◽

Full Intensity ◽

Fixed Point Iterations ◽

Constitutive Parameters

This article investigates a Fourier-based algorithm for computing heterogeneous material parameter distributions from internal measurements of physical fields. Within the framework of the periodic scalar conductivity model, a pair of dual Lippmann–Schwinger integral equations is derived for the sought constitutive parameters based on full intensity or current density field measurements. A numerical method based on the fast Fourier transform and fixed-point iterations is proposed. Convergence, stability and approximation quality of the method are analysed. For materials with small contrast, a first-order Born-like approximation is also obtained. Overall, the proposed reconstruction approach enables a direct conversion of full-field measurement images, possibly noisy, into maps of material conductivity. A set of numerical results is presented to illustrate the performance of the method.

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