How to use the Constitutive Law class

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The constitutive law behaviour is dealt with in kratos by the use of the class "ConstitutiveLaw", with a public interface defined in the file

  kratos/kratos/includes/constitutive_law.h

which also provides some rather extensive inline documentation (in the form of comments in the code).

By design such file aims to provide a very flexible interface to constitutive law modelling, with the specific goal of maximizing the flexibility in the implementation of complex constitutive behaviours. While such approach provide obvious advantages, it also implies that the API is more complex than what would be strictly needed for very simple constitutive laws.

The objective of current HowTo is to provide a brief introduction to the interface

Conventions

Through the whole section, the following convenctions will be employed:

voigt notation: - 3D case:

 STRAIN Voigt Notation:  e00 e11 e22 2*e01 2*e12 2*e02
 STRESS Voigt Notation:  s00 s11 s22   s01   s12   s02
        

- 2D plane strain/axisymmetric case (4 stress components)

 STRAIN Voigt Notation:  e00 e11 e22 2*e01 
 STRESS Voigt Notation:  s00 s11 s22   s01   

- 2D plane stress

 STRAIN Voigt Notation:  e00 e11 2*e01 
 STRESS Voigt Notation:  s00 s11   s01

The constitutive law works on the basis of the total deformation gradient F, defined as

  F  := D(X) / D(X0) 

that is, as the deformation gradient connecting the original and deformed configuration

where the initial position X0 is the one obtained by

  const array_1d<double,3>& X0 = node->GetInitialPosition()

and the deformed one by

  const array_1d<double,3>& X = node->Coordinates() 
  //must coincide with      X = node->GetInitialPosition() + node.FastGetSolutionStepValue(DISPLACEMENT);

The ConstitutiveLaw always returns the total stress. Formulations expressed in terms of strain increments shall store internally the strain stresses from which the increment shall be computed

API

The constitutive law API is based on the use of an auxiliary "Parameters" data structure, designed to encapsulate the data to be passed to the CL and received from it. The parameters data structure should be initialized using the following constructor:

     Parameters (const GeometryType& rElementGeometry

,const Properties& rMaterialProperties ,const ProcessInfo& rCurrentProcessInfo) Thus allowing to encapsulate the pointer to the elemental properties, to the element geometry and to the process info.

The data structure does not contain any internal storage and should be initialized with pointers to memory owned by the caller element. Full documentation of the code can be found in the file constitutive_law.hpp [[https://kratos.cimne.upc.es/projects/kratos/repository/entry/kratos/kratos/includes/constitutive_law.h ]]. For ease, the getter interface, returning a reference to the encapsulated data, is reported here

     GetOptions() //returns a reference to a flag container, to be employed in passing options to the CL
     GetDeterminantF()   
     GetDeformationGradientF() 
     GetShapeFunctionsValues() 
     GetShapeFunctionsDerivatives() 
     GetStrainVector() //INPUT/OUTPUT -- note that F will be used preferentially instead of the input strain
     GetStressVector() 
     GetConstitutiveMatrix() 
     GetProcessInfo() 
     GetMaterialProperties() 
     GetElementGeometry()
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