Beispiel #1
0
tensor DPYieldSurface01::xi_t1( const EPState *EPS) const {
    tensor dFoverds( 2, def_dim_2, 0.0);
    tensor I2("I", 2, def_dim_2);

    stresstensor S = EPS->getStress().deviator();

    double p = EPS->getStress().p_hydrostatic();
    p = p - Pc;

    stresstensor alpha = EPS->getTensorVar( 1 ); // getting alpha_ij from EPState

    stresstensor r = S * (1.0 / p); //for p = sig_kk/3
    stresstensor r_bar = r - alpha;
    stresstensor norm2 = r_bar("ij") * r_bar("ij");
    double norm = sqrt( norm2.trace() );

    stresstensor n;
    if ( norm >= d_macheps() ) {
        n = r_bar *(1.0 / norm );
    }
    else {
        opserr << "DPYieldSurface01::dFods  |n_ij| = 0, divide by zero! Program exits.\n";
        exit(-1);
    }

    return (-1.0) * n * p;
}
Beispiel #2
0
tensor DPYieldSurface01::dFods(const EPState *EPS) const {

    tensor dFoverds( 2, def_dim_2, 0.0);
    tensor I2("I", 2, def_dim_2);

    stresstensor S = EPS->getStress().deviator();
    //S.reportshort("S");

    double p = EPS->getStress().p_hydrostatic();
    p = p - Pc;
    //printf("Here we go!  p %f\n", p);

    stresstensor alpha = EPS->getTensorVar( 1 ); // getting alpha_ij from EPState
    //alpha.reportshort("alpha");

    //stresstensor n = EPS->getTensorVar( 3 );     // getting n_ij from EPState
    //n.reportshort("n");

    //-------------------------------------------------
    // might be moved to Evolution Law
    stresstensor r = S * (1.0 / p);
    //r.reportshort("r");
    stresstensor r_bar = r - alpha;
    //r_bar.reportshort("r_bar");
    stresstensor norm2 = r_bar("ij") * r_bar("ij");
    double norm = sqrt( norm2.trace() );

    //opserr << "d_macheps " << d_macheps() << endlnn;

    stresstensor n;
    if ( norm >= d_macheps() ) {
        n =  r_bar*(1.0 / norm );
    }
    else {
        opserr << "DPYieldSurface01::dFods  |n_ij| = 0, divide by zero! Program exits.\n";
        exit(-1);
    }
    //EPS->setTensorVar( 3, n); //update n_ij//
    //-------------------------------------------------


    double m = EPS->getScalarVar( 1 );


    //tensorial multiplication produces 1st-order tensor
    //tensor temp = n("ij") * n("ij");
    //double temp1 = temp.trace();
    //printf("==== n_ij*n_ij %e\n", temp1);

    //!!Very important:  N = n_pq * alpha_pq +sqrt(2/3)*m (always) = n_pq*r_pq(not hold when not on the yield surface)
    tensor temp = n("ij") * alpha("ij");
    double N = temp.trace() + sqrt(2.0/3.0)*m;
    //printf("    N =  %e\n", N);

    dFoverds =  n - N *I2 *(1.0/3.0);

    return dFoverds;

}
Beispiel #3
0
Datei: MD_EL.cpp Projekt: lcpt/xc
double XC::MDEvolutionLaw::getKp( EPState *EPS , double dummy) {

    //clog << "el-pl EPS: " <<  *EPS ;
    
    //=========================================================================
    //calculate  n_ij
    XC::stresstensor S = EPS->getStress().deviator();
    double p = EPS->getStress().p_hydrostatic();
    XC::stresstensor alpha = EPS->getTensorVar( 1 );  // alpha_ij
   
    XC::stresstensor r = S * (1.0 / p);
    //r.reportshort("r");
    XC::stresstensor r_bar = r - alpha;
    XC::stresstensor norm2 = r_bar("ij") * r_bar("ij");
    double norm = sqrt( norm2.trace() );
    
    XC::stresstensor n;
    if ( norm >= d_macheps() ){ 
      n = ( r  - alpha ) *(1.0 / norm );
    }
    else {
      ::printf(" \n\n n_ij not defined!!!! Program exits\n");
      exit(1);
    }
    
    //=========================================================================
    //calculating b_ij

    //Calculate the state parameters xi 
    double e = EPS->getScalarVar(3);
    double ec = getec_ref() - getLambda() * log( p/getp_ref() );
    double xi = e - ec;

    //Calculating the lode angle theta
    double J2_bar = r_bar.Jinvariant2();
    double J3_bar = r_bar.Jinvariant3();

    double tempd = 3.0*pow(3.0, 0.5)/2.0*J3_bar/ pow( J2_bar, 1.5);
    if (tempd > 1.0 ) tempd = 1.0; //bug. if tempd = 1.00000000003, acos gives nan
    if (tempd < -1.0 ) tempd = -1.0;
    double theta = acos( tempd ) / 3.0;

    
    //calculate the alpha_theta_b and alpha_theta_d
    double m = EPS->getScalarVar(1);
    double c = getMe() / getMc();

    double cd = getke_d() / getkc_d();
    XC::stresstensor alpha_theta_d = n("ij") * (g_WW(theta, c) * Mc + g_WW(theta, cd) * kc_d * xi - m) * pow(2.0/3.0, 0.5);


    double cb = getke_b() / getkc_b();
    if ( xi > 0.0 ) xi = 0.0;  // < -xi >
    XC::stresstensor alpha_theta_b = n("ij") * (g_WW(theta, c) * Mc - g_WW(theta, cb) * kc_b * xi - m) * pow(2.0/3.0, 0.5);
    alpha_theta_b.null_indices();

    //=========================================================================
    // calculating h
    XC::stresstensor b;
    b =  alpha_theta_b - alpha;
    b.null_indices();
    XC::stresstensor d;
    d =  alpha_theta_d - alpha;
    d.null_indices();

    double alpha_c_b = g_WW(0.0, c) * Mc + g_WW(0.0, cb) * kc_b * (-xi) - m;
    double b_ref = 2.0 * pow(2.0/3.0, 0.5) * alpha_c_b;
    

    BJtensor temp1 = b("ij") * n("ij");
    double bn = temp1.trace();

    temp1 = d("ij") * n("ij");
    double dn = temp1.trace();


    // Calculating A
    XC::stresstensor F = EPS->getTensorVar( 2 );   // getting  F_ij from XC::EPState
    temp1 = F("ij") * n("ij");
    double temp = temp1.trace();
    if (temp < 0)   temp = 0;
    double A = Ao*(1.0 + temp);

    double h = getho() * fabs(bn) / ( b_ref - fabs(bn) ); 
    clog << "ho =" << getho()  << "   h =" << h << std::endl;


    //=========================================================================

    double Kp = h * bn + pow(2.0/3.0, 0.5) * getCm() * ( 1.0 + geteo() ) * A * dn;
    //double Kp = pow(2.0/3.0, 0.5) * getCm() * ( 1.0 + geteo() ) * A * dn;
    Kp = Kp * p;

    return Kp;

}
Beispiel #4
0
Datei: MD_EL.cpp Projekt: lcpt/xc
void XC::MDEvolutionLaw::UpdateAllVars( EPState *EPS, double dlamda) {
   
    //=========================================================================
    //calculate  n_ij
    XC::stresstensor S = EPS->getStress().deviator();
    double p = EPS->getStress().p_hydrostatic();
    XC::stresstensor alpha = EPS->getTensorVar( 1 );  // alpha_ij

    // Find the norm of alpha
    BJtensor norm_alphat = alpha("ij") * alpha("ij");
    double norm_alpha = sqrt( norm_alphat.trace() );
   
    XC::stresstensor r = S * (1.0 / p);
    //r.reportshort("r");
    XC::stresstensor r_bar = r - alpha;
    XC::stresstensor norm2 = r_bar("ij") * r_bar("ij");
    double norm = sqrt( norm2.trace() );
    
    XC::stresstensor n;
    if ( norm >= d_macheps() ){ 
      n = ( r  - alpha ) *(1.0 / norm );
    }
    else {
      ::printf(" \n\n n_ij not defined!!!! Program exits\n");
      exit(1);
    }
    //EPS->setTensorVar( 3, n); //update n_ij//

    // Update E_Young corresponding to current stress state
    double p_atm = 100.0; //Kpa, atmospheric pressure
    double E = EPS->getE();  // old E_Young
    double E_new = EPS->getEo() * pow( (p/p_atm), geta() ); 
    EPS->setE( E_new );

    // Update void ratio
    
    double e = EPS->getScalarVar(3);
    double D = EPS->getScalarVar(2);
    double elastic_strain_vol = EPS->getdElasticStrain().Iinvariant1();
    double plastic_strain_vol = EPS->getdPlasticStrain().Iinvariant1();

    double de_p = -( 1.0 + e ) * plastic_strain_vol; // plastic change of void ratio ?? e or eo?
    double de_e = -( 1.0 + e ) * elastic_strain_vol; // elastic change of void ratio ????
    clog << "get dPlasticStrain-vol" << plastic_strain_vol << std::endl;
    clog << "get dElasticStrain-vol" << elastic_strain_vol << std::endl;

    clog << "^^^^^^^^^^^ de_e = " << de_e << " de_p = " << de_p << std::endl; 
    double new_e = e + de_p + de_e;

    EPS->setScalarVar( 3, new_e ); // Updating e


    //Calculate the state parameters xi 
    double ec = getec_ref() - getLambda() * log( p/getp_ref() );

    double xi = e - ec;

    // Update D 
       
    double m = EPS->getScalarVar(1);
    XC::stresstensor F = EPS->getTensorVar( 2 );   // getting  F_ij from XC::EPState
    BJtensor temp_tensor = F("ij") * n("ij");
    double temp = temp_tensor.trace();
    if (temp < 0)   temp = 0;
    double A = Ao*(1.0 + temp);

    //Calculating the lode angle theta
    double J2_bar = r_bar.Jinvariant2();
    double J3_bar = r_bar.Jinvariant3();
    double tempd = 3.0*pow(3.0, 0.5)/2.0*J3_bar/ pow( J2_bar, 1.5);

    if (tempd > 1.0 ) tempd = 1.0; //bug. if tempd = 1.00000000003, acos gives nan
    if (tempd < -1.0 ) tempd = -1.0;

    double theta = acos( tempd ) / 3.0;
    
    //=========================================================================
    //calculate the alpha_theta_b and alpha_theta_d
    double c = getMe() / getMc();

    double cd = getke_d() / getkc_d();
    double alpha_theta_dd = (g_WW(theta, c) * Mc + g_WW(theta, cd) * kc_d * xi - m);
    XC::stresstensor alpha_theta_d = n("ij") * alpha_theta_dd * pow(2.0/3.0, 0.5);

    double cb = getke_b() / getkc_b();
    if ( xi > 0 ) xi = 0.0;  // < -xi >
    double alpha_theta_bd = (g_WW(theta, c) * Mc + g_WW(theta, cb) * kc_b * (-xi) - m);
    XC::stresstensor alpha_theta_b = n("ij") *alpha_theta_bd * pow(2.0/3.0, 0.5);
    alpha_theta_b.null_indices();

    XC::stresstensor b;
    b =  alpha_theta_b - alpha;
    b.null_indices();
    XC::stresstensor d;
    d =  alpha_theta_d - alpha;
    d.null_indices();

    BJtensor temp1 = d("ij") * n("ij");
    temp1.null_indices();
    double D_new = temp1.trace() * A;
    //Check the restrictions on D
    if ( (xi > 0.0) && ( D_new < 0.0) )
       D_new = 0.0;  

    EPS->setScalarVar(2, D_new);  // Updating D
    //EPS->setScalarVar(2, 0.0);  // Updating D
    
 
    //=========================================================================
    // Update m
    double dm = dlamda * getCm() * ( 1.0 + e ) * D;
    EPS->setScalarVar(1, m + dm); // Updating m
    clog  << std::endl << "dm = " << dm << std::endl;

    //=========================================================================
    // Update alpha

    //calculate b_ref
    double alpha_c_b = g_WW(0.0, c) * Mc + g_WW(0.0, cb) * kc_b * (-xi) - m;
    double b_ref = 2.0 * pow(2.0/3.0, 0.5) * alpha_c_b;
    
    temp1 = b("ij") * n("ij");
    double bn = temp1.trace();
    clog << "xxxxxxxxxxxxxxxxxxx  bn " << bn << std::endl;


    double h = getho() * fabs(bn) / ( b_ref - fabs(bn) );
    //h = h + pow(2.0/3.0, 0.5) * getCm() * ( 1.0 + geteo() ) * A * bn;

    clog << " ||b|| " << (alpha_theta_bd - norm_alpha) << std::endl;
    clog << " dlamda " << dlamda << " h = " << h << std::endl;

    XC::stresstensor dalpha;
    dalpha = dlamda * h * b("ij");
    //dalpha.null_indices();
    clog << "delta alpha =" << dalpha << std::endl;
    
    //dalpha.reportshortpqtheta("\n dalpha ");
    alpha = alpha + dalpha;
    alpha.null_indices();
    //alpha.reportshort("Alpha");
    EPS->setTensorVar(1, alpha);

    //=========================================================================
    // Update F
    XC::stresstensor dF;
    if ( D > 0.0 ) D = 0.0;
    dF =  dlamda * getCf() * (-D) * ( getFmax() * n("ij") + F("ij") );
    //clog << "dF" << dF;
    
    F = F - dF;
    EPS->setTensorVar(2, F);

}
Beispiel #5
0
Datei: MD_EL.cpp Projekt: lcpt/xc
void XC::MDEvolutionLaw::setInitD(EPState  *EPS) {

    //=========================================================================
    //calculate  n_ij
    XC::stresstensor S = EPS->getStress().deviator();
    double p = EPS->getStress().p_hydrostatic();
    XC::stresstensor alpha = EPS->getTensorVar( 1 );  // alpha_ij

    // Find the norm of alpha
    BJtensor norm_alphat = alpha("ij") * alpha("ij");
    double norm_alpha = sqrt( norm_alphat.trace() );
   
    XC::stresstensor r = S * (1.0 / p);
    //r.reportshort("r");
    XC::stresstensor r_bar = r - alpha;
    XC::stresstensor norm2 = r_bar("ij") * r_bar("ij");
    double norm = sqrt( norm2.trace() );
    
    XC::stresstensor n;
    if ( norm >= d_macheps() ){ 
      n = ( r  - alpha ) *(1.0 / norm );
    }
    else {
      ::printf(" \n\n n_ij not defined!!!! Program exits\n");
      exit(1);
    }

    //Calculate the state parameters xi 
    double e = EPS->getScalarVar(3);
    double ec = getec_ref() - getLambda() * log( p/getp_ref() );
    double xi = e - ec;

    //calculating A
    double m = EPS->getScalarVar(1);
    XC::stresstensor F = EPS->getTensorVar( 2 );   // getting  F_ij from XC::EPState
    BJtensor temp_tensor = F("ij") * n("ij");
    double temp = temp_tensor.trace();
    if (temp < 0)   temp = 0;
    double A = Ao*(1.0 + temp);

    //Calculating the lode angle theta
    double J2_bar = r_bar.Jinvariant2();
    double J3_bar = r_bar.Jinvariant3();
    double tempd = 3.0*pow(3.0, 0.5)/2.0*J3_bar/ pow( J2_bar, 1.5);

    if (tempd > 1.0 ) tempd = 1.0; //bug. if tempd = 1.00000000003, acos gives nan
    if (tempd < -1.0 ) tempd = -1.0;

    double theta = acos( tempd ) / 3.0;
    
    //=========================================================================
    //calculate the alpha_theta_b and alpha_theta_d
    double c = getMe() / getMc();

    double cd = getke_d() / getkc_d();
    double alpha_theta_dd = (g_WW(theta, c) * Mc + g_WW(theta, cd) * kc_d * xi - m);
    XC::stresstensor alpha_theta_d = n("ij") * alpha_theta_dd * pow(2.0/3.0, 0.5);

    XC::stresstensor d;
    d =  alpha_theta_d - alpha;
    d.null_indices();

    BJtensor temp1 = d("ij") * n("ij");
    temp1.null_indices();
    double D_new = temp1.trace() * A;
    //Check the restrictions on D
    if ( (xi > 0.0) && ( D_new < 0.0) )
       D_new = 0.0;  

    EPS->setScalarVar(2, D_new);  // Updating D
    
}