int
M1Material :: giveIPValue(FloatArray &answer, GaussPoint *gp, InternalStateType type, TimeStep *tStep)
{
M1MaterialStatus *status = static_cast< M1MaterialStatus * >( this->giveStatus(gp) );
if ( type == IST_PlasticStrainTensor ) {
FloatArray plasticStrain(3);
plasticStrain.zero();
FloatArray sigmaN = status->giveTempNormalMplaneStresses();
FloatArray strain = status->giveTempStrainVector();
double Exx, Eyy, Gamma;
Exx = Eyy = Gamma = 0.;
if ( sigmaN.giveSize() == nmp ) {
for ( int imp = 1; imp <= nmp; imp++ ) {
double epsN = 0.;
for ( int i = 1; i <= 3; i++ ) {
epsN += strain.at(i) * N.at(imp, i);
}
double epsNpl = epsN - sigmaN.at(imp) / EN;
double aux = epsNpl * mw.at(imp);
Exx += aux * N.at(imp, 1);
Eyy += aux * N.at(imp, 2);
Gamma += aux * N.at(imp, 3);
}
}
plasticStrain.at(1) = 1.5 * Exx - 0.5 * Eyy;
plasticStrain.at(2) = -0.5 * Exx + 1.5 * Eyy;
plasticStrain.at(3) = 4. * Gamma;
StructuralMaterial :: giveFullSymVectorForm( answer, plasticStrain, gp->giveMaterialMode() );
return 1;
} else {
return StructuralMaterial :: giveIPValue(answer, gp, type, tStep);
}
}
void
M1Material :: giveRealStressVector_3d(FloatArray &answer,
GaussPoint *gp,
const FloatArray &totalStrain,
TimeStep *tStep)
{
answer.resize(6);
answer.zero();
// get the status at the beginning
M1MaterialStatus *status = static_cast< M1MaterialStatus * >( this->giveStatus(gp) );
// prepare status at the end
this->initTempStatus(gp);
// get the initial values of plastic strains on microplanes (set to zero in the first step)
FloatArray epspN = status->giveNormalMplanePlasticStrains();
if ( epspN.giveSize() < numberOfMicroplanes ) {
epspN.resize(numberOfMicroplanes);
epspN.zero();
}
// loop over microplanes
FloatArray sigN(numberOfMicroplanes);
IntArray plState(numberOfMicroplanes);
for ( int imp = 1; imp <= numberOfMicroplanes; imp++ ) {
Microplane *mPlane = this->giveMicroplane(imp - 1, gp);
//IntegrationPointStatus *mPlaneStatus = this->giveMicroplaneStatus(mPlane);
double epsN = computeNormalStrainComponent(mPlane, totalStrain);
// evaluate trial stress on the microplane
double sigTrial = EN * ( epsN - epspN.at(imp) );
// evaluate the yield stress (from total microplane strain, not from its plastic part)
double sigYield = EN * ( s0 + HN * epsN ) / ( EN + HN );
if ( sigYield < 0. ) {
sigYield = 0.;
}
// check whether the yield stress is exceeded and set the microplane stress
if ( sigTrial > sigYield ) { //plastic yielding
sigN.at(imp) = sigYield;
epspN.at(imp) = epsN - sigYield / EN;
plState.at(imp) = 1;
} else {
sigN.at(imp) = sigTrial;
plState.at(imp) = 0;
}
// add the contribution of the microplane to macroscopic stresses
for ( int i = 1; i <= 6; i++ ) {
answer.at(i) += N [ imp - 1 ] [ i - 1 ] * sigN.at(imp) * microplaneWeights [ imp - 1 ];
}
}
// multiply the integral over unit hemisphere by 6
answer.times(6);
// update status
status->letTempStrainVectorBe(totalStrain);
status->letTempStressVectorBe(answer);
status->letTempNormalMplaneStressesBe(sigN);
status->letTempNormalMplanePlasticStrainsBe(epspN);
status->letPlasticStateIndicatorsBe(plState);
}
void
M1Material :: givePlaneStressStiffMtrx(FloatMatrix &answer, MatResponseMode rMode, GaussPoint *gp, TimeStep *tStep)
{
answer.resize(3, 3);
if ( rMode == ElasticStiffness ) {
giveElasticPlaneStressStiffMtrx(answer);
return;
}
M1MaterialStatus *status = static_cast< M1MaterialStatus * >( this->giveStatus(gp) );
FloatArray sigmaN = status->giveTempNormalMplaneStresses();
if ( sigmaN.giveSize() != nmp ) {
sigmaN = status->giveNormalMplaneStresses();
if ( sigmaN.giveSize() != nmp ) {
giveElasticPlaneStressStiffMtrx(answer);
return;
}
}
FloatArray sigmaNyield = status->giveNormalMplaneYieldStresses();
double D11, D12, D13, D22, D23, aux;
D11 = D12 = D13 = D22 = D23 = 0.;
for ( int imp = 1; imp <= nmp; imp++ ) {
if ( sigmaN.at(imp) < sigmaNyield.at(imp) ) { // otherwise the plane is yielding
aux = mw.at(imp) * EN;
} else if ( sigmaNyield.at(imp) > 0. ) {
aux = mw.at(imp) * EN * HN / ( EN + HN );
} else {
aux = 0.;
}
D11 += aux * NN.at(imp, 1);
D12 += aux * NN.at(imp, 3);
D13 += aux * NN.at(imp, 2);
D22 += aux * NN.at(imp, 5);
D23 += aux * NN.at(imp, 4);
}
answer.at(1, 1) = D11;
answer.at(1, 2) = answer.at(2, 1) = answer.at(3, 3) = D12;
answer.at(1, 3) = answer.at(3, 1) = D13;
answer.at(2, 2) = D22;
answer.at(2, 3) = answer.at(3, 2) = D23;
}
int
M1Material :: giveIPValue(FloatArray &answer, GaussPoint *gp, InternalStateType type, TimeStep *tStep)
{
M1MaterialStatus *status = static_cast< M1MaterialStatus * >( this->giveStatus(gp) );
if ( type == IST_PlasticStrainTensor ) {
// plastic strain is computed as total strain minus elastic strain
// (note that integration of microplane plastic strains would give a different result)
answer = status->giveStrainVector();
FloatArray sig = status->giveStressVector();
double aux = nu * ( sig.at(1) + sig.at(2) + sig.at(3) );
double G = E / ( 2. * ( 1. + nu ) );
answer.at(1) -= ( ( 1. + nu ) * sig.at(1) - aux ) / E;
answer.at(2) -= ( ( 1. + nu ) * sig.at(2) - aux ) / E;
answer.at(3) -= ( ( 1. + nu ) * sig.at(3) - aux ) / E;
answer.at(4) -= sig.at(4) / G;
answer.at(5) -= sig.at(5) / G;
answer.at(6) -= sig.at(6) / G;
return 1;
} else {
return StructuralMaterial :: giveIPValue(answer, gp, type, tStep);
}
}
void
M1Material :: giveRealStressVector_PlaneStress(FloatArray &answer,
GaussPoint *gp,
const FloatArray &totalStrain,
TimeStep *tStep)
{
int i, imp;
FloatArray sigmaN, deps, sigmaNyield;
double depsN, epsN;
answer.resize(3);
answer.zero();
sigmaNyield.resize(nmp);
sigmaNyield.zero();
M1MaterialStatus *status = static_cast< M1MaterialStatus * >( this->giveStatus(gp) );
this->initTempStatus(gp);
sigmaN = status->giveNormalMplaneStresses();
if ( sigmaN.giveSize() < nmp ) {
sigmaN.resize(nmp);
sigmaN.zero();
}
deps.beDifferenceOf( totalStrain, status->giveStrainVector() );
for ( imp = 1; imp <= nmp; imp++ ) {
depsN = N.at(imp, 1) * deps.at(1) + N.at(imp, 2) * deps.at(2) + N.at(imp, 3) * deps.at(3);
epsN = N.at(imp, 1) * totalStrain.at(1) + N.at(imp, 2) * totalStrain.at(2) + N.at(imp, 3) * totalStrain.at(3);
sigmaN.at(imp) += EN * depsN;
double sy = EN * ( s0 + HN * epsN ) / ( EN + HN ); // current microplane yield stress
if ( sy < 0. ) {
sy = 0.;
}
if ( sigmaN.at(imp) > sy ) {
sigmaN.at(imp) = sy;
}
sigmaNyield.at(imp) = sy;
for ( i = 1; i <= 3; i++ ) {
answer.at(i) += N.at(imp, i) * sigmaN.at(imp) * mw.at(imp);
}
}
// update status
status->letTempStrainVectorBe(totalStrain);
status->letTempNormalMplaneStressesBe(sigmaN);
status->letNormalMplaneYieldStressesBe(sigmaNyield);
status->letTempStressVectorBe(answer);
}
void
M1Material :: give3dMaterialStiffnessMatrix(FloatMatrix &answer,
MatResponseMode mode,
GaussPoint *gp,
TimeStep *tStep)
{
answer.resize(6, 6);
answer.zero();
// elastic stiffness matrix
if ( mode == ElasticStiffness ) {
MicroplaneMaterial :: give3dMaterialStiffnessMatrix(answer, mode, gp, tStep);
return;
}
M1MaterialStatus *status = static_cast< M1MaterialStatus * >( this->giveStatus(gp) );
IntArray plasticState = status->givePlasticStateIndicators();
if ( plasticState.giveSize() != numberOfMicroplanes ) {
MicroplaneMaterial :: give3dMaterialStiffnessMatrix(answer, mode, gp, tStep);
return;
}
// tangent stiffness matrix
double aux, D11 = 0., D12 = 0., D13 = 0., D14 = 0., D15 = 0., D16 = 0., D22 = 0., D23 = 0., D24 = 0., D25 = 0., D26 = 0., D33 = 0., D34 = 0., D35 = 0., D36 = 0.;
// loop over microplanes
for ( int im = 0; im < numberOfMicroplanes; im++ ) {
if ( plasticState.at(im + 1) ) {
aux = ENtan * microplaneWeights [ im ];
} else {
aux = EN * microplaneWeights [ im ];
}
D11 += aux * N [ im ] [ 0 ] * N [ im ] [ 0 ];
D12 += aux * N [ im ] [ 0 ] * N [ im ] [ 1 ];
D13 += aux * N [ im ] [ 0 ] * N [ im ] [ 2 ];
D14 += aux * N [ im ] [ 0 ] * N [ im ] [ 3 ];
D15 += aux * N [ im ] [ 0 ] * N [ im ] [ 4 ];
D16 += aux * N [ im ] [ 0 ] * N [ im ] [ 5 ];
D22 += aux * N [ im ] [ 1 ] * N [ im ] [ 1 ];
D23 += aux * N [ im ] [ 1 ] * N [ im ] [ 2 ];
D24 += aux * N [ im ] [ 1 ] * N [ im ] [ 3 ];
D25 += aux * N [ im ] [ 1 ] * N [ im ] [ 4 ];
D26 += aux * N [ im ] [ 1 ] * N [ im ] [ 5 ];
D33 += aux * N [ im ] [ 2 ] * N [ im ] [ 2 ];
D34 += aux * N [ im ] [ 2 ] * N [ im ] [ 3 ];
D35 += aux * N [ im ] [ 2 ] * N [ im ] [ 4 ];
D36 += aux * N [ im ] [ 2 ] * N [ im ] [ 5 ];
}
answer.at(1, 1) = D11;
answer.at(1, 2) = answer.at(2, 1) = answer.at(6, 6) = D12;
answer.at(1, 3) = answer.at(3, 1) = answer.at(5, 5) = D13;
answer.at(1, 4) = answer.at(4, 1) = answer.at(5, 6) = answer.at(6, 5) = D14;
answer.at(1, 5) = answer.at(5, 1) = D15;
answer.at(1, 6) = answer.at(6, 1) = D16;
answer.at(2, 2) = D22;
answer.at(2, 3) = answer.at(3, 2) = answer.at(4, 4) = D23;
answer.at(2, 4) = answer.at(4, 2) = D24;
answer.at(2, 5) = answer.at(5, 2) = answer.at(4, 6) = answer.at(6, 4) = D25;
answer.at(2, 6) = answer.at(6, 2) = D26;
answer.at(3, 3) = answer.at(3, 3) = D33;
answer.at(3, 4) = answer.at(4, 3) = D34;
answer.at(3, 5) = answer.at(5, 3) = D35;
answer.at(3, 6) = answer.at(6, 3) = answer.at(4, 5) = answer.at(5, 4) = D36;
answer.times(6.);
}
