/* DFT++ is a density functional package developed by the research group of Professor Tomas Arias Copyright 1996-2003 Sohrab Ismail-Beigi This file is part of DFT++. DFT++ is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. DFT++ is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with DFT++; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA Please see the file CREDITS for a list of authors. For academic users, we request that publications using results obtained with this software reference "New algebraic formulation of density functional calculation," by Sohrab Ismail-Beigi and T.A. Arias, Computer Physics Communications 128:1-2, 1-45 (June 2000). and, if using the wavelet basis, further reference "Multiresolution analysis of electronic structure: semicardinal and wavelet bases," T.A. Arias, Reviews of Modern Physics 71:1, 267-311 (January 1999). and "Robust ab initio calculation of condensed matter: transparent convergence through semicardinal multiresolution analysis,'' I.P. Daykov, T.A. Arias, and Torkel D. Engeness, Physical Review Letters, 90:21, 216402 (May 2003). For your convenience, preprints of the above articles may be obtained from http://arXiv.org/abs/cond-mat/9909130, 9805262, and 0204411, respectively. */ /* * Sohrab Ismail-Beigi June 10th, 1999 * * written originally by Tairan Wang * * Control.c -- the control structure for convergence; some * member functions needed for it to work * */ #include "header.h" int Control::if_e_converged(real E) { if ( ( fabs(E - Etot) < E_tolerance ) && converged ) { Etot_old_old = Etot_old; Etot_old = Etot; Etot = E; return 1; } if ( ( fabs(E - Etot) < E_tolerance ) && ( fabs(Etot - Etot_old) < E_tolerance ) ) converged = 1; else converged = 0; Etot_old_old = Etot_old; Etot_old = Etot; Etot = E; return 0; } /* HACK */ int Control::if_force_diff_converged(Everything &e) { return 1; } /* int Control::if_force_diff_converged(Everything &e) { Ioninfo &io = e.ioninfo; calc_ionic_forces(e); e.iondyninfo.print_force(dft_global_log, e); int sp, i; for(sp = 0; sp < io.nspecies; sp++) for(i = 0; i < io.species[sp].natoms; i++) if(abs((io.species[sp].forces[i]-io.species[sp].old_forces[i])/ io.species[sp].forces[i]) > e.cntrl.force_diff_tolerance){ dft_log("*** Force differences have not yet converged ***\n\n\n"); return 0; } dft_log("Force differences converged to better than %e\n", e.cntrl.force_diff_tolerance); return 1; } */ void Control::print(int iter) { // print out the converged status. if (converged == 1) dft_log("Energy converged to %e Hartree after %d iters :\n", E_tolerance, iter); else dft_log("Energy not yet converged to %e Hartree after %d iters : \n", E_tolerance, iter); dft_log("\t%e\n\t%e %e\n\t%e %e\n", Etot, Etot_old, fabs(Etot - Etot_old), Etot_old_old, fabs(Etot_old - Etot_old_old)); } void Control::reset_converge() { // reset the convergence counter; // reset Etot, Etot_old, and Etot_old_old to 0. Etot = Etot_old = Etot_old_old = 0.0; }