/*
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.
*/
/*--------------------------- Basis -----------------------------------*
* *
* Master structure defining the basis set used for the calculation *
* One Basis object each is needed for every k-point. *
* And an additional Basis object is used for charge-density-FFT. *
* *
* (operated on in setup.c , setup_basis.c) *
* *
*-----------------------------------------------------------------------*/
#ifndef DFT_PW_BASIS_H
#define DFT_PW_BASIS_H
class PW_BasisSpec
{
public:
// Plane-wave cutoff energy in Hartrees
real Ecut;
Lattice *lattice;
// sizes for real-space grid and their product (i.e. FFT box size)
// this is used to store the initial values, if they are given
int size_realgrid;
int Nx,Ny,Nz,NxNyNz;
// Whether fft box size is computed manually or automatically
int auto_fftbox;
// What kind of basis we have (read from parser, passed to setup)
int basis_flag; // 0 = centered at gamma
// 1 = kpoint dependent
void setup(Everything &e);
int kpt_fold[3];
PW_BasisSpec();
};
class PW_Basis
{
public:
PW_BasisSpec *basis_spec; // points to global BasisSpec
QuantumNumber *qnum;
int nbasis; /* number of basis elements (i.e. G-vectors) */
/* Minimum and maximum values of each G-direction (inclusive) */
int Gxmin,Gxmax,Gymin,Gymax,Gzmin,Gzmax;
int *Gx,*Gy,*Gz; /* the G-vectors for the basis in recip. lattice coords */
int *index; /* indices of the basis functions in the FFT boxes used */
// These are auxiliary column-sized arrays to store precomputed
// values. eg. they are used in PHLO operators.
real *kplusG2;
real *kplusGx,*kplusGy,*kplusGz;
real *invLkernel;
PW_Basis();
~PW_Basis();
void operator=(PW_Basis &);
// Sets up the real-space grid
void setup_template(PW_BasisSpec &);
// Figures out the G vectors for a given k vector
void setup(const vector3 &kvec);
void init(){printf("Initializing PW_Basis\n");}
};
#endif // DFT_PW_BASIS_H
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