Esempi in C++ (Cpp) per paw_Def_Integr

Linguaggio di programmazione: C++ (Cpp)

Metodo/funzione: paw_Def_Integr

Esempi su hotexamples.com: 2

paw_Def_Integr in C++ (Cpp): 2 esempi trovati. Questi sono i migliori esempi reali in C++ (Cpp) per paw_Def_Integr, estratti da progetti open source. Li puoi valutare, per aiutarci a migliorare la qualità dei nostri esempi.

Esempio n. 1

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File: paw_potential.c Progetto: drhaney/nwchem

/****************************************
 Function name    : paw_update_paw_potential
 Description        :
 Return type              : void
 Argument         : int conv_status
 Argument         : int i
 Argument         : double *w
 Author                   : Marat Valiev
 Date & Time              : 1/10/99 6:27:44 PM
****************************************/
void paw_update_paw_potential(int *conv_status, int i, double eig, double eig_ps,double *w)
{

    int     k;
    int Ngrid;
    double  sv;
    double  dcl;
    double  eps;
    double  *tmp;

    eps = 1.0e-7;

    Ngrid = paw_N_LogGrid();
    tmp   = paw_scratch_LogGrid();

    for (k = 0; k <= Ngrid-1; k++)
    {
        tmp[k]= fcut[i][k] * w[k] * w[k];
    }

    sv = paw_Def_Integr(0.0,tmp,0.0,Ngrid-1);

    dcl = (eig - eig_ps) / sv;

    /*In case of the overflow rescale dcl*/

    if (fabs(dcl)>100)
        dcl = 10*fabs(dcl)/dcl;


    c[i] = c[i] + dcl;
    *conv_status = (fabs(dcl) <= eps);


    /*Form new paw potential if necessary*/
    if (!(*conv_status))
        for (k = 0; k <= Ngrid-1; k++)
            V_paw[i][k] = V_ref[k] + c[i] * fcut[i][k];

}

Esempio n. 2

Mostra file

File: paw_basis.c Progetto: wadejong/NWChem-Json

/****************************************
 Function name	  : solve_pseudo_orbitals
 Description	    :
 Return type		  : void
 Author     		  : Marat Valiev
 Date & Time		  : 4/7/99 2:31:16 PM
****************************************/
void paw_generate_pseudo_orbitals()
{
    int     i;
    int     k;
    int Ngrid;
    int     max_iter;
    int     converged;
    int     iteration;
    int     match;
    int     status;
    double log_amesh;
    double f1,f2;
    double  *V;
    double  *rgrid;
    double  *f;
    double norm;

    char    output[300];
    FILE   *fp;

    Ngrid     = paw_N_LogGrid();
    rgrid     = paw_r_LogGrid();
    log_amesh = paw_log_amesh_LogGrid();

    /*set maximum number of iterations*/
    max_iter = 600;

    for (i = 0; i <= nbasis-1; i++)
    {
        iteration = 0;
        converged = False;
        status    = False;
        match = i_r_orbital[i];

        /*Start the selfconsistent loop over given ps state */

        while ((iteration <= max_iter) && (!converged))
        {
            ++iteration;

            /* get pseudopotential*/
            V = paw_get_paw_potential(i);

            /*
            if(orb_type[i]==bound || orb_type[i]==virt)
            {
              status = paw_R_Schrodinger(prin_n_ps[i], 
                orb_l[i], 
                V, 
                &e_ps[i], 
                phi_ps[i], 
                phi_ps_prime[i]);
              
            }
            else if(orb_type[i]==scattering)
            {
              status = paw_R_Schrodinger_Fixed_Logderiv(prin_n_ps[i], 
                orb_l[i], 
                V, 
                match,      
                log_deriv[i],
                &e_ps[i], 
                phi_ps[i], 
                phi_ps_prime[i]);
                  
            }
            else
            {
              printf("unknown orbital type\n");
              exit(1);
            }
            */

            status = paw_R_Schrodinger_Fixed_Logderiv(prin_n_ps[i],
                     orb_l[i],
                     V,
                     match,
                     log_deriv[i],
                     &e_ps[i],
                     phi_ps[i],
                     phi_ps_prime[i]);

            /*Update pseudopotential potential*/
            paw_update_paw_potential(&converged, i, e[i], e_ps[i],phi_ps[i]);

        }

        /*report on convergence status*/
        if (converged && (status))
        {
            if (paw_debug()) printf("\n%d%d pseudo orbital with the eigenvalue=%f has been found\n",
                                        prin_n[i], orb_l[i], e_ps[i]);
        }
        else
        {
            if (paw_debug()) printf("Unable to find %d%d orbital\n ",
                                        prin_n[i], orb_l[i]);
        }

        norm = phi[i][match]/phi_ps[i][match];

        /*scale ps orbital */
        for (k=0;k<=match;k++)
        {
            phi_ps[i][k]=phi_ps[i][k]*norm;
            phi_ps_prime[i][k]=phi_ps_prime[i][k]*norm;
        }


        for (k=match+1;k<=Ngrid-1;k++)
        {
            phi_ps[i][k]=phi[i][k];
            phi_ps_prime[i][k]=phi_prime[i][k];
        }


    }





    if (paw_debug())
    {
        for (i = 0; i <= nbasis-1; ++i)
        {
            sprintf(output, "%s%s%d%d", paw_sdir(),"test",prin_n[i],orb_l[i]);
            fp = fopen(output, "w+");
            for (k = 0; k < Ngrid; k++)
            {
                fprintf(fp, "%f\t%f\t%f\n", rgrid[k], phi[i][k],phi_ps[i][k]);

            }
            fclose(fp);
        }
    }

    pseudo_orbitals_done = True;

    /* save original basis functions */
    for (i=0;i<=nbasis-1;i++)
    {
        for (k = 0; k <= Ngrid-1; k++)
        {
            phi0[i][k] = phi[i][k];
            phi0_prime[i][k] = phi_prime[i][k];
            phi_ps0[i][k] = phi_ps[i][k];
            phi_ps0_prime[i][k] = phi_ps_prime[i][k];
        }

    }

    /* calculate densities */
    paw_Zero_LogGrid(rho);
    paw_Zero_LogGrid(rho_ps);

    for (i = 0; i <= nbasis-1; i++)
    {
        for (k = 0; k <= Ngrid-1; k++)
        {
            rho[k] += fill[i]*pow((phi0[i][k]/rgrid[k]),2.0);
            rho_ps[k] += fill[i]*pow((phi_ps0[i][k]/rgrid[k]),2.0);
        }
    }

    /*calculate kinetic energy*/
    ekin    = paw_get_kinetic_energy(nbasis, orb_l, fill, phi, phi_prime);

    f = paw_alloc_LogGrid();

    for (i = 0; i <= nbasis-1; i++)
    {

        for (k=0; k<=Ngrid-1; k++)
        {
            f[k] = 0.5*phi_prime[i][k]/(rgrid[k]*log_amesh)*
                   phi_prime[i][k]/(rgrid[k]*log_amesh) -
                   0.5*phi_ps_prime[i][k]/(rgrid[k]*log_amesh)*
                   phi_ps_prime[i][k]/(rgrid[k]*log_amesh);
        }

        f1 = paw_Def_Integr(0.0,f,0.0,Ngrid-1);

        for (k=0; k<=Ngrid-1; k++)
        {
            f[k] = 0.5*phi_prime[i][k]/(rgrid[k]*log_amesh)*
                   phi_prime[i][k]/(rgrid[k]*log_amesh);
        }

        f2 = paw_Def_Integr(0.0,f,0.0,Ngrid-1);

        delta_ekin[i] = (int)(100*f1/f2);

        if (paw_debug())
            printf("kinetic energy of the %d%s orbital was reduced by %d%s\n",
                   prin_n[i],paw_spd_Name(orb_l[i]),delta_ekin[i],"%");
    }

    paw_dealloc_LogGrid(f);

}