mirror of
https://github.com/triqs/dft_tools
synced 2024-11-07 06:33:48 +01:00
914 lines
44 KiB
Python
914 lines
44 KiB
Python
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################################################################################
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#
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# TRIQS: a Toolbox for Research in Interacting Quantum Systems
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#
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# Copyright (C) 2011 by M. Aichhorn, L. Pourovskii, V. Vildosola
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#
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# TRIQS is free software: you can redistribute it and/or modify it under the
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# terms of the GNU General Public License as published by the Free Software
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# Foundation, either version 3 of the License, or (at your option) any later
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# version.
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#
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# TRIQS is distributed in the hope that it will be useful, but WITHOUT ANY
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# WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
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# FOR A PARTICULAR PURPOSE. See the GNU General Public License for more
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# details.
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#
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# You should have received a copy of the GNU General Public License along with
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# TRIQS. If not, see <http://www.gnu.org/licenses/>.
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#
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################################################################################
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from types import *
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import numpy
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import pytriqs.utility.dichotomy as dichotomy
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from pytriqs.gf.local import *
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import pytriqs.utility.mpi as mpi
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from pytriqs.archive import *
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from symmetry import *
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class SumkDFT:
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"""This class provides a general SumK method for combining ab-initio code and pytriqs."""
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def __init__(self, hdf_file, h_field = 0.0, use_dft_blocks = False,
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dft_data = 'dft_input', symmcorr_data = 'dft_symmcorr_input', parproj_data = 'dft_parproj_input',
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symmpar_data = 'dft_symmpar_input', bands_data = 'dft_bands_input', transp_data = 'dft_transp_input',
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misc_data = 'dft_misc_input'):
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"""
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Initialises the class from data previously stored into an HDF5
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"""
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if not type(hdf_file) == StringType:
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mpi.report("Give a string for the HDF5 filename to read the input!")
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else:
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self.hdf_file = hdf_file
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self.dft_data = dft_data
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self.symmcorr_data = symmcorr_data
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self.parproj_data = parproj_data
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self.symmpar_data = symmpar_data
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self.bands_data = bands_data
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self.transp_data = transp_data
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self.misc_data = misc_data
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self.h_field = h_field
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# Read input from HDF:
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things_to_read = ['energy_unit','n_k','k_dep_projection','SP','SO','charge_below','density_required',
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'symm_op','n_shells','shells','n_corr_shells','corr_shells','use_rotations','rot_mat',
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'rot_mat_time_inv','n_reps','dim_reps','T','n_orbitals','proj_mat','bz_weights','hopping',
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'n_inequiv_shells', 'corr_to_inequiv', 'inequiv_to_corr']
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self.subgroup_present, self.value_read = self.read_input_from_hdf(subgrp = self.dft_data, things_to_read = things_to_read)
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if self.symm_op: self.symmcorr = Symmetry(hdf_file,subgroup=self.symmcorr_data)
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if self.SO and (abs(self.h_field) > 0.000001):
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self.h_field = 0.0
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mpi.report("For SO, the external magnetic field is not implemented, setting it to 0!")
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self.spin_block_names = [ ['up','down'], ['ud'] ]
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self.n_spin_blocks = [2,1]
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# Convert spin_block_names to indices -- if spin polarized, differentiate up and down blocks
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self.spin_names_to_ind = [{}, {}]
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for iso in range(2): # SO = 0 or 1
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for isp in range(self.n_spin_blocks[iso]):
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self.spin_names_to_ind[iso][self.spin_block_names[iso][isp]] = isp * self.SP
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# GF structure used for the local things in the k sums
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# Most general form allowing for all hybridisation, i.e. largest blocks possible
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self.gf_struct_sumk = [ [ (sp, range( self.corr_shells[icrsh]['dim'])) for sp in self.spin_block_names[self.corr_shells[icrsh]['SO']] ]
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for icrsh in range(self.n_corr_shells) ]
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# First set a standard gf_struct solver:
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self.gf_struct_solver = [ dict([ (sp, range(self.corr_shells[self.inequiv_to_corr[ish]]['dim']) )
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for sp in self.spin_block_names[self.corr_shells[self.inequiv_to_corr[ish]]['SO']] ])
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for ish in range(self.n_inequiv_shells) ]
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# Set standard (identity) maps from gf_struct_sumk <-> gf_struct_solver
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self.sumk_to_solver = [ {} for ish in range(self.n_inequiv_shells) ]
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self.solver_to_sumk = [ {} for ish in range(self.n_inequiv_shells) ]
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self.solver_to_sumk_block = [ {} for ish in range(self.n_inequiv_shells) ]
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for ish in range(self.n_inequiv_shells):
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for block,inner_list in self.gf_struct_sumk[self.inequiv_to_corr[ish]]:
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self.solver_to_sumk_block[ish][block] = block
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for inner in inner_list:
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self.sumk_to_solver[ish][(block,inner)] = (block,inner)
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self.solver_to_sumk[ish][(block,inner)] = (block,inner)
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self.deg_shells = [ [] for ish in range(self.n_inequiv_shells) ] # assume no shells are degenerate
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self.chemical_potential = 0.0 # initialise mu
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self.init_dc() # initialise the double counting
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# Analyse the block structure and determine the smallest gf_struct blocks and maps, if desired
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if use_dft_blocks: self.analyse_block_structure()
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################
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# HDF5 FUNCTIONS
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################
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def read_input_from_hdf(self, subgrp, things_to_read):
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"""
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Reads data from the HDF file
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"""
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value_read = True
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# initialise variables on all nodes to ensure mpi broadcast works at the end
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for it in things_to_read: setattr(self,it,0)
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subgroup_present = 0
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if mpi.is_master_node():
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ar = HDFArchive(self.hdf_file,'a')
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if subgrp in ar:
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subgroup_present = True
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# first read the necessary things:
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for it in things_to_read:
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if it in ar[subgrp]:
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setattr(self,it,ar[subgrp][it])
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else:
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mpi.report("Loading %s failed!"%it)
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value_read = False
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else:
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if (len(things_to_read) != 0): mpi.report("Loading failed: No %s subgroup in HDF5!"%subgrp)
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subgroup_present = False
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value_read = False
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del ar
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# now do the broadcasting:
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for it in things_to_read: setattr(self,it,mpi.bcast(getattr(self,it)))
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subgroup_present = mpi.bcast(subgroup_present)
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value_read = mpi.bcast(value_read)
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return subgroup_present, value_read
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def save(self, things_to_save, subgrp='user_data'):
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"""Saves given quantities into the subgroup ('user_data' by default) of the HDF5 archive"""
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if not (mpi.is_master_node()): return # do nothing on nodes
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ar = HDFArchive(self.hdf_file,'a')
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if not subgrp in ar: ar.create_group(subgrp)
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for it in things_to_save:
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try:
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ar[subgrp][it] = getattr(self,it)
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except:
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mpi.report("%s not found, and so not saved."%it)
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del ar
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def load(self, things_to_load, subgrp='user_data'):
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"""Loads given quantities from the subgroup ('user_data' by default) of the HDF5 archive"""
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if not (mpi.is_master_node()): return # do nothing on nodes
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ar = HDFArchive(self.hdf_file,'a')
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if not subgrp in ar: mpi.report("Loading %s failed!"%subgrp)
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list_to_return = []
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for it in things_to_load:
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try:
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list_to_return.append(ar[subgrp][it])
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except:
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raise ValueError, "load: %s not found, and so not loaded."%it
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del ar
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return list_to_return
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################
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# CORE FUNCTIONS
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################
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def downfold(self,ik,ish,bname,gf_to_downfold,gf_inp,shells='corr',ir=None):
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"""Downfolding a block of the Greens function"""
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gf_downfolded = gf_inp.copy()
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isp = self.spin_names_to_ind[self.SO][bname] # get spin index for proj. matrices
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n_orb = self.n_orbitals[ik,isp]
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if shells == 'corr':
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dim = self.corr_shells[ish]['dim']
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projmat = self.proj_mat[ik,isp,ish,0:dim,0:n_orb]
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elif shells == 'all':
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if ir is None: raise ValueError, "downfold: provide ir if treating all shells."
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dim = self.shells[ish]['dim']
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projmat = self.proj_mat_all[ik,isp,ish,ir,0:dim,0:n_orb]
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gf_downfolded.from_L_G_R(projmat,gf_to_downfold,projmat.conjugate().transpose())
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return gf_downfolded
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def upfold(self,ik,ish,bname,gf_to_upfold,gf_inp,shells='corr',ir=None):
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"""Upfolding a block of the Greens function"""
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gf_upfolded = gf_inp.copy()
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isp = self.spin_names_to_ind[self.SO][bname] # get spin index for proj. matrices
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n_orb = self.n_orbitals[ik,isp]
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if shells == 'corr':
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dim = self.corr_shells[ish]['dim']
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projmat = self.proj_mat[ik,isp,ish,0:dim,0:n_orb]
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elif shells == 'all':
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if ir is None: raise ValueError, "upfold: provide ir if treating all shells."
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dim = self.shells[ish]['dim']
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projmat = self.proj_mat_all[ik,isp,ish,ir,0:dim,0:n_orb]
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gf_upfolded.from_L_G_R(projmat.conjugate().transpose(),gf_to_upfold,projmat)
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return gf_upfolded
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def rotloc(self,ish,gf_to_rotate,direction,shells='corr'):
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"""Local <-> Global rotation of a GF block.
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direction: 'toLocal' / 'toGlobal' """
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assert ((direction == 'toLocal') or (direction == 'toGlobal')),"rotloc: Give direction 'toLocal' or 'toGlobal'."
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gf_rotated = gf_to_rotate.copy()
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if shells == 'corr':
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rot_mat_time_inv = self.rot_mat_time_inv
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rot_mat = self.rot_mat
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elif shells == 'all':
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rot_mat_time_inv = self.rot_mat_all_time_inv
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rot_mat = self.rot_mat_all
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if direction == 'toGlobal':
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if (rot_mat_time_inv[ish] == 1) and self.SO:
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gf_rotated << gf_rotated.transpose()
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gf_rotated.from_L_G_R(rot_mat[ish].conjugate(),gf_rotated,rot_mat[ish].transpose())
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else:
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gf_rotated.from_L_G_R(rot_mat[ish],gf_rotated,rot_mat[ish].conjugate().transpose())
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elif direction == 'toLocal':
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if (rot_mat_time_inv[ish] == 1) and self.SO:
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gf_rotated << gf_rotated.transpose()
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gf_rotated.from_L_G_R(rot_mat[ish].transpose(),gf_rotated,rot_mat[ish].conjugate())
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else:
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gf_rotated.from_L_G_R(rot_mat[ish].conjugate().transpose(),gf_rotated,rot_mat[ish])
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return gf_rotated
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def lattice_gf(self, ik, mu=None, iw_or_w="iw", beta=40, broadening=None, mesh=None, with_Sigma=True, with_dc=True):
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"""Calculates the lattice Green function from the DFT hopping and the self energy at k-point number ik
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and chemical potential mu."""
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if mu is None: mu = self.chemical_potential
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ntoi = self.spin_names_to_ind[self.SO]
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spn = self.spin_block_names[self.SO]
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if (iw_or_w != "iw") and (iw_or_w != "w"): raise ValueError, "lattice_gf: Implemented only for Re/Im frequency functions."
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if not hasattr(self,"Sigma_imp_"+iw_or_w): with_Sigma = False
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if broadening is None:
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if mesh is None:
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broadening = 0.01
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else: # broadening = 2 * \Delta omega, where \Delta omega is the spacing of omega points
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broadening = 2.0 * ( (mesh[1]-mesh[0])/(mesh[2]-1) )
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# Are we including Sigma?
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if with_Sigma:
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if with_dc: sigma_minus_dc = self.add_dc(iw_or_w)
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Sigma_imp = getattr(self,"Sigma_imp_"+iw_or_w)
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if iw_or_w == "iw": beta = Sigma_imp[0].mesh.beta # override beta if Sigma_iw is present
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else:
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if (iw_or_w == "w") and (mesh is None):
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raise ValueError, "lattice_gf: Give the mesh=(om_min,om_max,n_points) for the lattice GfReFreq."
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# Check if G_latt is present
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set_up_G_latt = False # Assume not
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if not hasattr(self,"G_latt_"+iw_or_w):
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set_up_G_latt = True # Need to create G_latt_(i)w
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else: # Check that existing GF is consistent
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G_latt = getattr(self,"G_latt_"+iw_or_w)
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GFsize = [ gf.N1 for bname,gf in G_latt]
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unchangedsize = all( [ self.n_orbitals[ik,ntoi[spn[isp]]]==GFsize[isp] for isp in range(self.n_spin_blocks[self.SO]) ] )
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if not unchangedsize: set_up_G_latt = True
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if (iw_or_w == "iw") and (self.G_latt_iw.mesh.beta != beta): set_up_G_latt = True # additional check for ImFreq
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# Set up G_latt
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if set_up_G_latt:
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block_structure = [ range(self.n_orbitals[ik,ntoi[sp]]) for sp in spn ]
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gf_struct = [ (spn[isp], block_structure[isp]) for isp in range(self.n_spin_blocks[self.SO]) ]
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block_ind_list = [block for block,inner in gf_struct]
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if iw_or_w == "iw":
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glist = lambda : [ GfImFreq(indices=inner,beta=beta) for block,inner in gf_struct]
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elif iw_or_w == "w":
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if with_Sigma:
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glist = lambda : [ GfReFreq(indices=inner,mesh=Sigma_imp[0].mesh) for block,inner in gf_struct]
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else:
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glist = lambda : [ GfReFreq(indices=inner,window=(mesh[0],mesh[1]),n_points=mesh[2]) for block,inner in gf_struct]
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G_latt = BlockGf(name_list = block_ind_list, block_list = glist(), make_copies = False)
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G_latt.zero()
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if iw_or_w == "iw":
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G_latt << iOmega_n
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elif iw_or_w == "w":
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G_latt << Omega + 1j*broadening
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idmat = [numpy.identity(self.n_orbitals[ik,ntoi[sp]],numpy.complex_) for sp in spn]
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M = copy.deepcopy(idmat)
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for ibl in range(self.n_spin_blocks[self.SO]):
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ind = ntoi[spn[ibl]]
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n_orb = self.n_orbitals[ik,ind]
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M[ibl] = self.hopping[ik,ind,0:n_orb,0:n_orb] - (idmat[ibl]*mu) - (idmat[ibl] * self.h_field * (1-2*ibl))
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G_latt -= M
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if with_Sigma:
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for icrsh in range(self.n_corr_shells):
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for bname,gf in G_latt: gf -= self.upfold(ik,icrsh,bname,sigma_minus_dc[icrsh][bname],gf)
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G_latt.invert()
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setattr(self,"G_latt_"+iw_or_w,G_latt)
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return G_latt
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def put_Sigma(self, Sigma_imp):
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"""Sets the impurity self energies for inequivalent atoms into the class, respects the multiplicity of the atoms."""
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assert isinstance(Sigma_imp,list), "put_Sigma: Sigma_imp has to be a list of Sigmas for the correlated shells, even if it is of length 1!"
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assert len(Sigma_imp) == self.n_inequiv_shells, "put_Sigma: give exactly one Sigma for each inequivalent corr. shell!"
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# init self.Sigma_imp_(i)w:
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if all(type(gf) == GfImFreq for bname,gf in Sigma_imp[0]):
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# Imaginary frequency Sigma:
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self.Sigma_imp_iw = [ BlockGf( name_block_generator = [ (block,GfImFreq(indices = inner, mesh = Sigma_imp[0].mesh))
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for block,inner in self.gf_struct_sumk[icrsh] ], make_copies = False)
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for icrsh in range(self.n_corr_shells) ]
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SK_Sigma_imp = self.Sigma_imp_iw
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elif all(type(gf) == GfReFreq for bname,gf in Sigma_imp[0]):
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# Real frequency Sigma:
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self.Sigma_imp_w = [ BlockGf( name_block_generator = [ (block,GfReFreq(indices = inner, mesh = Sigma_imp[0].mesh))
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for block,inner in self.gf_struct_sumk[icrsh] ], make_copies = False)
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for icrsh in range(self.n_corr_shells) ]
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SK_Sigma_imp = self.Sigma_imp_w
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else:
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raise ValueError, "put_Sigma: This type of Sigma is not handled."
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# transform the CTQMC blocks to the full matrix:
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for icrsh in range(self.n_corr_shells):
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ish = self.corr_to_inequiv[icrsh] # ish is the index of the inequivalent shell corresponding to icrsh
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for block,inner in self.gf_struct_solver[ish].iteritems():
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for ind1 in inner:
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for ind2 in inner:
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block_sumk,ind1_sumk = self.solver_to_sumk[ish][(block,ind1)]
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block_sumk,ind2_sumk = self.solver_to_sumk[ish][(block,ind2)]
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SK_Sigma_imp[icrsh][block_sumk][ind1_sumk,ind2_sumk] << Sigma_imp[ish][block][ind1,ind2]
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# rotation from local to global coordinate system:
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if self.use_rotations:
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for icrsh in range(self.n_corr_shells):
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for bname,gf in SK_Sigma_imp[icrsh]: gf << self.rotloc(icrsh,gf,direction='toGlobal')
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def extract_G_loc(self, mu=None, with_Sigma=True, with_dc=True):
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"""
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Extracts the local downfolded Green function at the chemical potential of the class.
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At the end, the local G is rotated from the global coordinate system to the local system.
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if with_Sigma = False: Sigma is not included => non-interacting local GF
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"""
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if mu is None: mu = self.chemical_potential
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G_loc = [ self.Sigma_imp_iw[icrsh].copy() for icrsh in range(self.n_corr_shells) ] # this list will be returned
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for icrsh in range(self.n_corr_shells): G_loc[icrsh].zero() # initialize to zero
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beta = G_loc[0].mesh.beta
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ikarray = numpy.array(range(self.n_k))
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for ik in mpi.slice_array(ikarray):
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G_latt_iw = self.lattice_gf(ik=ik, mu=mu, iw_or_w="iw", with_Sigma=with_Sigma, with_dc=with_dc, beta=beta)
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G_latt_iw *= self.bz_weights[ik]
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for icrsh in range(self.n_corr_shells):
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tmp = G_loc[icrsh].copy() # init temporary storage
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for bname,gf in tmp: tmp[bname] << self.downfold(ik,icrsh,bname,G_latt_iw[bname],gf)
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G_loc[icrsh] += tmp
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# Collect data from mpi
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for icrsh in range(self.n_corr_shells):
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G_loc[icrsh] << mpi.all_reduce(mpi.world, G_loc[icrsh], lambda x,y : x+y)
|
|
mpi.barrier()
|
|
|
|
# G_loc[:] is now the sum over k projected to the local orbitals.
|
|
# here comes the symmetrisation, if needed:
|
|
if self.symm_op != 0: G_loc = self.symmcorr.symmetrize(G_loc)
|
|
|
|
# G_loc is rotated to the local coordinate system:
|
|
if self.use_rotations:
|
|
for icrsh in range(self.n_corr_shells):
|
|
for bname,gf in G_loc[icrsh]: G_loc[icrsh][bname] << self.rotloc(icrsh,gf,direction='toLocal')
|
|
|
|
# transform to CTQMC blocks:
|
|
G_loc_inequiv = [ BlockGf( name_block_generator = [ (block,GfImFreq(indices = inner, mesh = G_loc[0].mesh)) for block,inner in self.gf_struct_solver[ish].iteritems() ],
|
|
make_copies = False) for ish in range(self.n_inequiv_shells) ]
|
|
for ish in range(self.n_inequiv_shells):
|
|
for block,inner in self.gf_struct_solver[ish].iteritems():
|
|
for ind1 in inner:
|
|
for ind2 in inner:
|
|
block_sumk,ind1_sumk = self.solver_to_sumk[ish][(block,ind1)]
|
|
block_sumk,ind2_sumk = self.solver_to_sumk[ish][(block,ind2)]
|
|
G_loc_inequiv[ish][block][ind1,ind2] << G_loc[self.inequiv_to_corr[ish]][block_sumk][ind1_sumk,ind2_sumk]
|
|
|
|
# return only the inequivalent shells:
|
|
return G_loc_inequiv
|
|
|
|
|
|
def analyse_block_structure(self, threshold = 0.00001, include_shells = None, dm = None):
|
|
""" Determines the Green's function block structure from simple point integration."""
|
|
|
|
self.gf_struct_solver = [ {} for ish in range(self.n_inequiv_shells) ]
|
|
self.sumk_to_solver = [ {} for ish in range(self.n_inequiv_shells) ]
|
|
self.solver_to_sumk = [ {} for ish in range(self.n_inequiv_shells) ]
|
|
self.solver_to_sumk_block = [ {} for ish in range(self.n_inequiv_shells) ]
|
|
|
|
if dm is None: dm = self.density_matrix(method = 'using_point_integration')
|
|
dens_mat = [ dm[self.inequiv_to_corr[ish]] for ish in range(self.n_inequiv_shells) ]
|
|
|
|
if include_shells is None: include_shells = range(self.n_inequiv_shells)
|
|
for ish in include_shells:
|
|
|
|
|
|
for sp in self.spin_block_names[self.corr_shells[self.inequiv_to_corr[ish]]['SO']]:
|
|
dmbool = (abs(dens_mat[ish][sp]) > threshold) # gives an index list of entries larger that threshold
|
|
|
|
# Determine off-diagonal entries in upper triangular part of density matrix
|
|
offdiag = []
|
|
for i in range(len(dmbool)):
|
|
for j in range(i+1,len(dmbool)):
|
|
if dmbool[i,j]: offdiag.append([i,j])
|
|
|
|
# Determine the number of non-hybridising blocks in the gf
|
|
num_blocs = len(dmbool)
|
|
blocs = [ [i] for i in range(num_blocs) ]
|
|
for i in range(len(offdiag)):
|
|
for j in range(len(blocs[offdiag[i][1]])): blocs[offdiag[i][0]].append(blocs[offdiag[i][1]][j])
|
|
del blocs[offdiag[i][1]]
|
|
for j in range(i+1,len(offdiag)):
|
|
if offdiag[j][0] == offdiag[i][1]: offdiag[j][0] = offdiag[i][0]
|
|
if offdiag[j][1] == offdiag[i][1]: offdiag[j][1] = offdiag[i][0]
|
|
if offdiag[j][0] > offdiag[i][1]: offdiag[j][0] -= 1
|
|
if offdiag[j][1] > offdiag[i][1]: offdiag[j][1] -= 1
|
|
offdiag[j].sort()
|
|
num_blocs -= 1
|
|
|
|
# Set the gf_struct for the solver accordingly
|
|
for i in range(num_blocs):
|
|
blocs[i].sort()
|
|
self.gf_struct_solver[ish].update( [('%s_%s'%(sp,i),range(len(blocs[i])))] )
|
|
|
|
# Construct sumk_to_solver taking (sumk_block, sumk_index) --> (solver_block, solver_inner)
|
|
# and solver_to_sumk taking (solver_block, solver_inner) --> (sumk_block, sumk_index)
|
|
for i in range(num_blocs):
|
|
for j in range(len(blocs[i])):
|
|
block_sumk = sp
|
|
inner_sumk = blocs[i][j]
|
|
block_solv = '%s_%s'%(sp,i)
|
|
inner_solv = j
|
|
self.sumk_to_solver[ish][(block_sumk,inner_sumk)] = (block_solv,inner_solv)
|
|
self.solver_to_sumk[ish][(block_solv,inner_solv)] = (block_sumk,inner_sumk)
|
|
self.solver_to_sumk_block[ish][block_solv] = block_sumk
|
|
|
|
# Now calculate degeneracies of orbitals
|
|
dm = {}
|
|
for block,inner in self.gf_struct_solver[ish].iteritems():
|
|
# get dm for the blocks:
|
|
dm[block] = numpy.zeros([len(inner),len(inner)],numpy.complex_)
|
|
for ind1 in inner:
|
|
for ind2 in inner:
|
|
block_sumk,ind1_sumk = self.solver_to_sumk[ish][(block,ind1)]
|
|
block_sumk,ind2_sumk = self.solver_to_sumk[ish][(block,ind2)]
|
|
dm[block][ind1,ind2] = dens_mat[ish][block_sumk][ind1_sumk,ind2_sumk]
|
|
|
|
for block1 in self.gf_struct_solver[ish].iterkeys():
|
|
for block2 in self.gf_struct_solver[ish].iterkeys():
|
|
if dm[block1].shape == dm[block2].shape:
|
|
if ( (abs(dm[block1] - dm[block2]) < threshold).all() ) and (block1 != block2):
|
|
ind1 = -1
|
|
ind2 = -2
|
|
# check if it was already there:
|
|
for n,ind in enumerate(self.deg_shells[ish]):
|
|
if block1 in ind: ind1 = n
|
|
if block2 in ind: ind2 = n
|
|
if (ind1 < 0) and (ind2 >= 0):
|
|
self.deg_shells[ish][ind2].append(block1)
|
|
elif (ind1 >= 0) and (ind2 < 0):
|
|
self.deg_shells[ish][ind1].append(block2)
|
|
elif (ind1 < 0) and (ind2 < 0):
|
|
self.deg_shells[ish].append([block1,block2])
|
|
|
|
|
|
def density_matrix(self, method = 'using_gf', beta = 40.0):
|
|
"""Calculate density matrices in one of two ways:
|
|
if 'using_gf': First get lattice gf (g_loc is not set up), then density matrix.
|
|
It is useful for Hubbard I, and very quick.
|
|
No assumption on the hopping structure is made (ie diagonal or not).
|
|
if 'using_point_integration': Only works for diagonal hopping matrix (true in wien2k).
|
|
"""
|
|
dens_mat = [ {} for icrsh in range(self.n_corr_shells)]
|
|
for icrsh in range(self.n_corr_shells):
|
|
for sp in self.spin_block_names[self.corr_shells[icrsh]['SO']]:
|
|
dens_mat[icrsh][sp] = numpy.zeros([self.corr_shells[icrsh]['dim'],self.corr_shells[icrsh]['dim']], numpy.complex_)
|
|
|
|
ikarray = numpy.array(range(self.n_k))
|
|
for ik in mpi.slice_array(ikarray):
|
|
|
|
if method == "using_gf":
|
|
|
|
G_latt_iw = self.lattice_gf(ik = ik, mu = self.chemical_potential, iw_or_w = "iw", beta = beta)
|
|
G_latt_iw *= self.bz_weights[ik]
|
|
dm = G_latt_iw.density()
|
|
MMat = [dm[sp] for sp in self.spin_block_names[self.SO]]
|
|
|
|
elif method == "using_point_integration":
|
|
|
|
ntoi = self.spin_names_to_ind[self.SO]
|
|
spn = self.spin_block_names[self.SO]
|
|
unchangedsize = all( [self.n_orbitals[ik,ntoi[sp]] == self.n_orbitals[0,ntoi[sp]] for sp in spn] )
|
|
if unchangedsize:
|
|
dim = self.n_orbitals[0,ntoi[sp]]
|
|
else:
|
|
dim = self.n_orbitals[ik,ntoi[sp]]
|
|
MMat = [numpy.zeros( [dim,dim], numpy.complex_) for sp in spn]
|
|
|
|
for isp, sp in enumerate(spn):
|
|
ind = ntoi[sp]
|
|
for inu in range(self.n_orbitals[ik,ind]):
|
|
if (self.hopping[ik,ind,inu,inu] - self.h_field*(1-2*isp)) < 0.0: # only works for diagonal hopping matrix (true in wien2k)
|
|
MMat[isp][inu,inu] = 1.0
|
|
else:
|
|
MMat[isp][inu,inu] = 0.0
|
|
|
|
else: raise ValueError, "density_matrix: the method '%s' is not supported."%method
|
|
|
|
for icrsh in range(self.n_corr_shells):
|
|
for isp, sp in enumerate(self.spin_block_names[self.corr_shells[icrsh]['SO']]):
|
|
ind = self.spin_names_to_ind[self.corr_shells[icrsh]['SO']][sp]
|
|
dim = self.corr_shells[icrsh]['dim']
|
|
n_orb = self.n_orbitals[ik,ind]
|
|
projmat = self.proj_mat[ik,ind,icrsh,0:dim,0:n_orb]
|
|
if method == "using_gf":
|
|
dens_mat[icrsh][sp] += numpy.dot( numpy.dot(projmat,MMat[isp]),
|
|
projmat.transpose().conjugate() )
|
|
elif method == "using_point_integration":
|
|
dens_mat[icrsh][sp] += self.bz_weights[ik] * numpy.dot( numpy.dot(projmat,MMat[isp]) ,
|
|
projmat.transpose().conjugate() )
|
|
|
|
# get data from nodes:
|
|
for icrsh in range(self.n_corr_shells):
|
|
for sp in dens_mat[icrsh]:
|
|
dens_mat[icrsh][sp] = mpi.all_reduce(mpi.world, dens_mat[icrsh][sp], lambda x,y : x+y)
|
|
mpi.barrier()
|
|
|
|
if self.symm_op != 0: dens_mat = self.symmcorr.symmetrize(dens_mat)
|
|
|
|
# Rotate to local coordinate system:
|
|
if self.use_rotations:
|
|
for icrsh in range(self.n_corr_shells):
|
|
for sp in dens_mat[icrsh]:
|
|
if self.rot_mat_time_inv[icrsh] == 1: dens_mat[icrsh][sp] = dens_mat[icrsh][sp].conjugate()
|
|
dens_mat[icrsh][sp] = numpy.dot( numpy.dot(self.rot_mat[icrsh].conjugate().transpose(),dens_mat[icrsh][sp]),
|
|
self.rot_mat[icrsh] )
|
|
|
|
return dens_mat
|
|
|
|
|
|
# For simple dft input, get crystal field splittings.
|
|
def eff_atomic_levels(self):
|
|
"""Calculates the effective atomic levels needed as input for the Hubbard I Solver."""
|
|
|
|
# define matrices for inequivalent shells:
|
|
eff_atlevels = [ {} for ish in range(self.n_inequiv_shells) ]
|
|
for ish in range(self.n_inequiv_shells):
|
|
for sp in self.spin_block_names[self.corr_shells[self.inequiv_to_corr[ish]]['SO']]:
|
|
eff_atlevels[ish][sp] = numpy.identity(self.corr_shells[self.inequiv_to_corr[ish]]['dim'], numpy.complex_)
|
|
eff_atlevels[ish][sp] *= -self.chemical_potential
|
|
eff_atlevels[ish][sp] -= self.dc_imp[self.inequiv_to_corr[ish]][sp]
|
|
|
|
# sum over k:
|
|
if not hasattr(self,"Hsumk"):
|
|
# calculate the sum over k. Does not depend on mu, so do it only once:
|
|
self.Hsumk = [ {} for icrsh in range(self.n_corr_shells) ]
|
|
for icrsh in range(self.n_corr_shells):
|
|
dim = self.corr_shells[icrsh]['dim']
|
|
for sp in self.spin_block_names[self.corr_shells[icrsh]['SO']]:
|
|
self.Hsumk[icrsh][sp] = numpy.zeros([dim,dim],numpy.complex_)
|
|
for isp, sp in enumerate(self.spin_block_names[self.corr_shells[icrsh]['SO']]):
|
|
ind = self.spin_names_to_ind[self.corr_shells[icrsh]['SO']][sp]
|
|
for ik in range(self.n_k):
|
|
n_orb = self.n_orbitals[ik,ind]
|
|
MMat = numpy.identity(n_orb, numpy.complex_)
|
|
MMat = self.hopping[ik,ind,0:n_orb,0:n_orb] - (1-2*isp) * self.h_field * MMat
|
|
projmat = self.proj_mat[ik,ind,icrsh,0:dim,0:n_orb]
|
|
self.Hsumk[icrsh][sp] += self.bz_weights[ik] * numpy.dot( numpy.dot(projmat,MMat),
|
|
projmat.conjugate().transpose() )
|
|
# symmetrisation:
|
|
if self.symm_op != 0: self.Hsumk = self.symmcorr.symmetrize(self.Hsumk)
|
|
|
|
# Rotate to local coordinate system:
|
|
if self.use_rotations:
|
|
for icrsh in range(self.n_corr_shells):
|
|
for sp in self.Hsumk[icrsh]:
|
|
if self.rot_mat_time_inv[icrsh] == 1: self.Hsumk[icrsh][sp] = self.Hsumk[icrsh][sp].conjugate()
|
|
self.Hsumk[icrsh][sp] = numpy.dot( numpy.dot(self.rot_mat[icrsh].conjugate().transpose(),self.Hsumk[icrsh][sp]) ,
|
|
self.rot_mat[icrsh] )
|
|
|
|
# add to matrix:
|
|
for ish in range(self.n_inequiv_shells):
|
|
for sp in eff_atlevels[ish]:
|
|
eff_atlevels[ish][sp] += self.Hsumk[self.inequiv_to_corr[ish]][sp]
|
|
|
|
|
|
return eff_atlevels
|
|
|
|
|
|
def init_dc(self):
|
|
""" Initialise the double counting terms to have the correct shape."""
|
|
|
|
self.dc_imp = [ {} for icrsh in range(self.n_corr_shells)]
|
|
for icrsh in range(self.n_corr_shells):
|
|
dim = self.corr_shells[icrsh]['dim']
|
|
spn = self.spin_block_names[self.corr_shells[icrsh]['SO']]
|
|
for sp in spn: self.dc_imp[icrsh][sp] = numpy.zeros([dim,dim],numpy.float_)
|
|
self.dc_energ = [0.0 for icrsh in range(self.n_corr_shells)]
|
|
|
|
|
|
def set_dc(self,dc_imp,dc_energ):
|
|
"""Sets double counting terms dc_imp and dc_energ to known values."""
|
|
|
|
self.dc_imp = dc_imp
|
|
self.dc_energ = dc_energ
|
|
|
|
|
|
def calc_dc(self,dens_mat,orb=0,U_interact=None,J_hund=None,use_dc_formula=0,use_dc_value=None):
|
|
"""Sets the double counting corrections in the correct form for inequiv orbital orb:
|
|
1) either using U_interact, J_hund and
|
|
use_dc_formula = 0: fully-localised limit (FLL),
|
|
use_dc_formula = 1: Held's formula,
|
|
use_dc_formula = 2: around mean-field (AMF).
|
|
2) or using a given dc value in use_dc_value.
|
|
Be sure that you are using the correct interaction Hamiltonian!"""
|
|
|
|
for icrsh in range(self.n_corr_shells):
|
|
|
|
ish = self.corr_to_inequiv[icrsh] # ish is the index of the inequivalent shell corresponding to icrsh
|
|
if ish != orb: continue # ignore this orbital
|
|
dim = self.corr_shells[icrsh]['dim'] #*(1+self.corr_shells[icrsh]['SO'])
|
|
spn = self.spin_block_names[self.corr_shells[icrsh]['SO']]
|
|
|
|
Ncr = { sp: 0.0 for sp in spn }
|
|
for block,inner in self.gf_struct_solver[ish].iteritems():
|
|
bl = self.solver_to_sumk_block[ish][block]
|
|
Ncr[bl] += dens_mat[block].real.trace()
|
|
Ncrtot = sum(Ncr.itervalues())
|
|
for sp in spn:
|
|
self.dc_imp[icrsh][sp] = numpy.identity(dim,numpy.float_)
|
|
if self.SP == 0: # average the densities if there is no SP:
|
|
Ncr[sp] = Ncrtot / len(spn)
|
|
elif self.SP == 1 and self.SO == 1: # correction for SO: we have only one block in this case, but in DC we need N/2
|
|
Ncr[sp] = Ncrtot / 2.0
|
|
|
|
if use_dc_value is None:
|
|
|
|
if U_interact is None and J_hund is None: raise ValueError, "set_dc: either provide U_interact and J_hund or set use_dc_value to dc value."
|
|
|
|
if use_dc_formula == 0: # FLL
|
|
|
|
self.dc_energ[icrsh] = U_interact / 2.0 * Ncrtot * (Ncrtot-1.0)
|
|
for sp in spn:
|
|
Uav = U_interact*(Ncrtot-0.5) - J_hund*(Ncr[sp] - 0.5)
|
|
self.dc_imp[icrsh][sp] *= Uav
|
|
self.dc_energ[icrsh] -= J_hund / 2.0 * (Ncr[sp]) * (Ncr[sp]-1.0)
|
|
mpi.report("DC for shell %(icrsh)i and block %(sp)s = %(Uav)f"%locals())
|
|
|
|
elif use_dc_formula == 1: # Held's formula, with U_interact the interorbital onsite interaction
|
|
|
|
self.dc_energ[icrsh] = (U_interact + (dim-1)*(U_interact-2.0*J_hund) + (dim-1)*(U_interact-3.0*J_hund))/(2*dim-1) / 2.0 * Ncrtot * (Ncrtot-1.0)
|
|
for sp in spn:
|
|
Uav =(U_interact + (dim-1)*(U_interact-2.0*J_hund) + (dim-1)*(U_interact-3.0*J_hund))/(2*dim-1) * (Ncrtot-0.5)
|
|
self.dc_imp[icrsh][sp] *= Uav
|
|
mpi.report("DC for shell %(icrsh)i and block %(sp)s = %(Uav)f"%locals())
|
|
|
|
elif use_dc_formula == 2: # AMF
|
|
|
|
self.dc_energ[icrsh] = 0.5 * U_interact * Ncrtot * Ncrtot
|
|
for sp in spn:
|
|
Uav = U_interact*(Ncrtot - Ncr[sp]/dim) - J_hund * (Ncr[sp] - Ncr[sp]/dim)
|
|
self.dc_imp[icrsh][sp] *= Uav
|
|
self.dc_energ[icrsh] -= (U_interact + (dim-1)*J_hund)/dim * 0.5 * Ncr[sp] * Ncr[sp]
|
|
mpi.report("DC for shell %(icrsh)i and block %(sp)s = %(Uav)f"%locals())
|
|
|
|
mpi.report("DC energy for shell %s = %s"%(icrsh,self.dc_energ[icrsh]))
|
|
|
|
else: # use value provided for user to determine dc_energ and dc_imp
|
|
|
|
self.dc_energ[icrsh] = use_dc_value * Ncrtot
|
|
for sp in spn: self.dc_imp[icrsh][sp] *= use_dc_value
|
|
|
|
mpi.report("DC for shell %(icrsh)i = %(use_dc_value)f"%locals())
|
|
mpi.report("DC energy = %s"%self.dc_energ[icrsh])
|
|
|
|
|
|
def add_dc(self,iw_or_w="iw"):
|
|
"""Substracts the double counting term from the impurity self energy."""
|
|
|
|
# Be careful: Sigma_imp is already in the global coordinate system!!
|
|
sigma_minus_dc = [s.copy() for s in getattr(self,"Sigma_imp_"+iw_or_w)]
|
|
for icrsh in range(self.n_corr_shells):
|
|
for bname,gf in sigma_minus_dc[icrsh]:
|
|
# Transform dc_imp to global coordinate system
|
|
dccont = numpy.dot(self.rot_mat[icrsh],numpy.dot(self.dc_imp[icrsh][bname],self.rot_mat[icrsh].conjugate().transpose()))
|
|
sigma_minus_dc[icrsh][bname] -= dccont
|
|
|
|
return sigma_minus_dc
|
|
|
|
|
|
def symm_deg_gf(self,gf_to_symm,orb):
|
|
"""Symmetrises a GF for the given degenerate shells self.deg_shells"""
|
|
|
|
for degsh in self.deg_shells[orb]:
|
|
ss = gf_to_symm[degsh[0]].copy()
|
|
ss.zero()
|
|
n_deg = len(degsh)
|
|
for bl in degsh: ss += gf_to_symm[bl] / (1.0*n_deg)
|
|
for bl in degsh: gf_to_symm[bl] << ss
|
|
|
|
|
|
def total_density(self, mu=None, with_Sigma=True, with_dc=True):
|
|
"""
|
|
Calculates the total charge for the energy window for a given chemical potential mu.
|
|
Since in general n_orbitals depends on k, the calculation is done in the following order:
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G_aa'(k,iw) -> n(k) = Tr G_aa'(k,iw) -> sum_k n_k
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|
|
The calculation is done in the global coordinate system, if distinction is made between local/global!
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"""
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if mu is None: mu = self.chemical_potential
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dens = 0.0
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ikarray = numpy.array(range(self.n_k))
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for ik in mpi.slice_array(ikarray):
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G_latt_iw = self.lattice_gf(ik=ik, mu=mu, iw_or_w="iw", with_Sigma=with_Sigma, with_dc=with_dc)
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dens += self.bz_weights[ik] * G_latt_iw.total_density()
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# collect data from mpi:
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dens = mpi.all_reduce(mpi.world, dens, lambda x,y : x+y)
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mpi.barrier()
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|
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return dens
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|
|
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def set_mu(self,mu):
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"""Sets a new chemical potential"""
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|
|
|
self.chemical_potential = mu
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|
|
|
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def calc_mu(self, precision = 0.01):
|
|
"""
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|
Searches for mu in order to give the desired charge
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|
A desired precision can be specified in precision.
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|
"""
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|
|
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F = lambda mu : self.total_density(mu = mu)
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density = self.density_required - self.charge_below
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|
|
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self.chemical_potential = dichotomy.dichotomy(function = F,
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x_init = self.chemical_potential, y_value = density,
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|
precision_on_y = precision, delta_x = 0.5, max_loops = 100,
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|
x_name = "Chemical Potential", y_name = "Total Density",
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|
verbosity = 3)[0]
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|
|
|
return self.chemical_potential
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|
|
|
|
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def calc_density_correction(self,filename = 'dens_mat.dat'):
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|
""" Calculates the density correction in order to feed it back to the DFT calculations."""
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|
|
|
assert type(filename) == StringType, "calc_density_correction: filename has to be a string!"
|
|
|
|
ntoi = self.spin_names_to_ind[self.SO]
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|
spn = self.spin_block_names[self.SO]
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|
dens = {sp: 0.0 for sp in spn}
|
|
|
|
# Set up deltaN:
|
|
deltaN = {}
|
|
for sp in spn:
|
|
deltaN[sp] = [numpy.zeros([self.n_orbitals[ik,ntoi[sp]],self.n_orbitals[ik,ntoi[sp]]], numpy.complex_) for ik in range(self.n_k)]
|
|
|
|
ikarray = numpy.array(range(self.n_k))
|
|
for ik in mpi.slice_array(ikarray):
|
|
G_latt_iw = self.lattice_gf(ik = ik, mu = self.chemical_potential, iw_or_w = "iw")
|
|
for bname,gf in G_latt_iw:
|
|
deltaN[bname][ik] = G_latt_iw[bname].density()
|
|
dens[bname] += self.bz_weights[ik] * G_latt_iw[bname].total_density()
|
|
|
|
# mpi reduce:
|
|
for bname in deltaN:
|
|
for ik in range(self.n_k):
|
|
deltaN[bname][ik] = mpi.all_reduce(mpi.world, deltaN[bname][ik], lambda x,y : x+y)
|
|
dens[bname] = mpi.all_reduce(mpi.world, dens[bname], lambda x,y : x+y)
|
|
mpi.barrier()
|
|
|
|
# now save to file:
|
|
if mpi.is_master_node():
|
|
if self.SP == 0:
|
|
f = open(filename,'w')
|
|
else:
|
|
f = open(filename+'up','w')
|
|
f1 = open(filename+'dn','w')
|
|
# write chemical potential (in Rydberg):
|
|
f.write("%.14f\n"%(self.chemical_potential/self.energy_unit))
|
|
if self.SP != 0: f1.write("%.14f\n"%(self.chemical_potential/self.energy_unit))
|
|
# write beta in rydberg-1
|
|
f.write("%.14f\n"%(G_latt_iw.mesh.beta*self.energy_unit))
|
|
if self.SP != 0: f1.write("%.14f\n"%(G_latt_iw.mesh.beta*self.energy_unit))
|
|
|
|
if self.SP == 0: # no spin-polarization
|
|
|
|
for ik in range(self.n_k):
|
|
f.write("%s\n"%self.n_orbitals[ik,0])
|
|
for inu in range(self.n_orbitals[ik,0]):
|
|
for imu in range(self.n_orbitals[ik,0]):
|
|
valre = (deltaN['up'][ik][inu,imu].real + deltaN['down'][ik][inu,imu].real) / 2.0
|
|
valim = (deltaN['up'][ik][inu,imu].imag + deltaN['down'][ik][inu,imu].imag) / 2.0
|
|
f.write("%.14f %.14f "%(valre,valim))
|
|
f.write("\n")
|
|
f.write("\n")
|
|
f.close()
|
|
|
|
elif self.SP == 1: # with spin-polarization
|
|
|
|
# dict of filename: (spin index, block_name)
|
|
if self.SO == 0: to_write = {f: (0, 'up'), f1: (1, 'down')}
|
|
if self.SO == 1: to_write = {f: (0, 'ud'), f1: (0, 'ud')}
|
|
for fout in to_write.iterkeys():
|
|
isp, sp = to_write[fout]
|
|
for ik in range(self.n_k):
|
|
fout.write("%s\n"%self.n_orbitals[ik,isp])
|
|
for inu in range(self.n_orbitals[ik,isp]):
|
|
for imu in range(self.n_orbitals[ik,isp]):
|
|
fout.write("%.14f %.14f "%(deltaN[bn][ik][inu,imu].real,deltaN[bn][ik][inu,imu].imag))
|
|
fout.write("\n")
|
|
fout.write("\n")
|
|
fout.close()
|
|
|
|
return deltaN, dens
|
|
|
|
################
|
|
# FIXME LEAVE UNDOCUMENTED
|
|
################
|
|
|
|
def calc_dc_for_density(self,orb,dc_init,dens_mat,density=None,precision=0.01):
|
|
"""Searches for DC in order to fulfill charge neutrality.
|
|
If density is given, then DC is set such that the LOCAL charge of orbital
|
|
orb coincides with the given density."""
|
|
|
|
def F(dc):
|
|
self.calc_dc(dens_mat = dens_mat, U_interact = 0, J_hund = 0, orb = orb, use_dc_value = dc)
|
|
if dens_req is None:
|
|
return self.total_density(mu = mu)
|
|
else:
|
|
return self.extract_G_loc()[orb].total_density()
|
|
|
|
if density is None: density = self.density_required - self.charge_below
|
|
|
|
dc = dichotomy.dichotomy(function = F,
|
|
x_init = dc_init, y_value = density,
|
|
precision_on_y = precision, delta_x = 0.5,
|
|
max_loops = 100, x_name = "Double Counting", y_name= "Total Density",
|
|
verbosity = 3)[0]
|
|
|
|
return dc
|
|
|
|
|
|
def check_projectors(self):
|
|
"""Calculated the density matrix from projectors (DM = P Pdagger) to check that it is correct and
|
|
specifically that it matches DFT."""
|
|
dens_mat = [numpy.zeros([self.corr_shells[icrsh]['dim'],self.corr_shells[icrsh]['dim']],numpy.complex_)
|
|
for icrsh in range(self.n_corr_shells)]
|
|
|
|
for ik in range(self.n_k):
|
|
for icrsh in range(self.n_corr_shells):
|
|
dim = self.corr_shells[icrsh]['dim']
|
|
n_orb = self.n_orbitals[ik,0]
|
|
projmat = self.proj_mat[ik,0,icrsh,0:dim,0:n_orb]
|
|
dens_mat[icrsh][:,:] += numpy.dot(projmat, projmat.transpose().conjugate()) * self.bz_weights[ik]
|
|
|
|
if self.symm_op != 0: dens_mat = self.symmcorr.symmetrize(dens_mat)
|
|
|
|
# Rotate to local coordinate system:
|
|
if self.use_rotations:
|
|
for icrsh in range(self.n_corr_shells):
|
|
if self.rot_mat_time_inv[icrsh] == 1: dens_mat[icrsh] = dens_mat[icrsh].conjugate()
|
|
dens_mat[icrsh] = numpy.dot( numpy.dot(self.rot_mat[icrsh].conjugate().transpose(),dens_mat[icrsh]),
|
|
self.rot_mat[icrsh] )
|
|
|
|
return dens_mat
|
|
|
|
|
|
def sorts_of_atoms(self,shells):
|
|
"""
|
|
Determine the number of inequivalent sorts.
|
|
"""
|
|
sortlst = [ shells[i]['sort'] for i in range(len(shells)) ]
|
|
n_sorts = len(set(sortlst))
|
|
return n_sorts
|
|
|
|
|
|
def number_of_atoms(self,shells):
|
|
"""
|
|
Determine the number of inequivalent atoms.
|
|
"""
|
|
atomlst = [ shells[i]['atom'] for i in range(len(shells)) ]
|
|
n_atoms = len(set(atomlst))
|
|
return n_atoms
|