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dft_tools/fortran/dmftproj/orthogonal.f

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2013-07-23 19:49:42 +02:00
c ******************************************************************************
c
c TRIQS: a Toolbox for Research in Interacting Quantum Systems
c
c Copyright (C) 2011 by L. Pourovskii, V. Vildosola, C. Martins, M. Aichhorn
c
c TRIQS is free software: you can redistribute it and/or modify it under the
c terms of the GNU General Public License as published by the Free Software
c Foundation, either version 3 of the License, or (at your option) any later
c version.
c
c TRIQS is distributed in the hope that it will be useful, but WITHOUT ANY
c WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
c FOR A PARTICULAR PURPOSE. See the GNU General Public License for more
c details.
c
c You should have received a copy of the GNU General Public License along with
c TRIQS. If not, see <http://www.gnu.org/licenses/>.
c
c *****************************************************************************/
SUBROUTINE orthogonal_h(s1,ndim,inv)
C %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
C %% %%
C %% This subroutine computes : %%
C %% - if inv = .FALSE. the square root of the Hermitian matrix s1 %%
C %% - if inv = .TRUE. the inverse of the square root of the %%
C %% Hermitian matrix s1 %%
C %% %%
C %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
C Definiton of the variables :
C ----------------------------
USE prnt
IMPLICIT NONE
INTEGER :: ndim, INFO, lm, lm1
COMPLEX(KIND=8), DIMENSION(ndim) :: WORK
COMPLEX(KIND=8), DIMENSION(ndim,ndim) :: s1
INTEGER, DIMENSION(ndim,ndim) :: IPIV
LOGICAL :: inv
C
C Calculation of S1^(1/2) or S1^(-1/2):
C -------------------------------------
CALL sqrtm(s1,ndim,inv)
C The resulting matrix is stored in s1.
RETURN
END
SUBROUTINE orthogonal_r(s2,ndim,inv)
C %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
C %% %%
C %% This subroutine computes : %%
C %% - if inv = .FALSE. the square root of s1 %%
C %% - if inv = .TRUE. the inverse of the square root of s2 %%
C %% where s2 is a real symmetric matrix. %%
C %% %%
C %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
C Definiton of the variables :
C ----------------------------
USE prnt
IMPLICIT NONE
INTEGER :: ndim, INFO, lm, lm1
COMPLEX(KIND=8), DIMENSION(ndim) :: WORK
COMPLEX(KIND=8), DIMENSION(ndim,ndim) :: s1
REAL(KIND=8), DIMENSION(ndim,ndim) :: s2
INTEGER, DIMENSION(ndim,ndim) :: IPIV
LOGICAL :: inv
C
C Calculation of S2^(1/2) or S2^(-1/2):
C -------------------------------------
s1=s2
CALL sqrtm(s1,ndim,inv)
s2=REAL(s1)
C The resulting matrix is stored in s2.
RETURN
END
SUBROUTINE sqrtm(cmat,m,inv)
C %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
C %% %%
C %% This subroutine calculates the square root of a positively %%
C %% defined Hermitian matrix A=cmat using the decomposition %%
C %% A=Z*D*Z^H %%
C %% where D is a diagonal matrix of eigenvalues of A, %%
C %% Z is matrix of orthonormal eigenvectors of A, %%
C %% Z^H is its Hermitian conjugate. %%
C %% Then A^(1/2)=Z*D^(1/2)*Z^H. %%
C %% Correction: the matrix A is allowed to be negatively defined. %%
C %% %%
C %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
C Definiton of the variables :
C ----------------------------
IMPLICIT NONE
INTEGER :: m
COMPLEX(KIND=8), DIMENSION(m,m):: cmat, D, D1
LOGICAL :: inv
C Calculation of Z*D^(1/2):
C -------------------------
CALL sqrt_eigenvec(cmat,D1,m,inv)
WRITE(95,*) cmat
WRITE(95,*) ' '
WRITE(95,*) D1
WRITE(95,*) ' '
C Calculation of A^(1/2)=Z*D^(1/2)*Z^H:
C -------------------------------------
D=CONJG(cmat)
call ZGEMM('N','T',m,m,m,DCMPLX(1.D0,0.D0),D1,
& m,D,m,DCMPLX(0.D0,0.D0),cmat,m)
C The resulting matrix is stored in cmat.
RETURN
END
SUBROUTINE sqrt_eigenvec(cmat,D1,m,inv)
C %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
C %% %%
C %% This subroutine computes : %%
C %% - if inv = .FALSE. Z*D^(1/2) %%
C %% - if inv = .TRUE. Z*D^(-1/2) %%
C %% where Z is a matrix of orthonormal eigenvectors of cmat and %%
C %% D is the diagonal matrix of cmat's eigenvalues. %%
C %% %%
C %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
C Definiton of the variables :
C ----------------------------
USE prnt
IMPLICIT NONE
LOGICAL :: inv, ifwrite
INTEGER :: m, INFO, i, j
INTEGER, PARAMETER :: nwork=40
C
COMPLEX(KIND=8), allocatable, DIMENSION(:) :: WORK
COMPLEX(KIND=8), DIMENSION(m,m) :: cmat, D1
REAL(KIND=8), DIMENSION(m) :: W
COMPLEX(KIND=8), DIMENSION(m) :: W_comp
REAL(KIND=8), allocatable, DIMENSION(:) :: RWORK
C
C Finding the eigenvalues and the eigenvectors of cmat :
C ------------------------------------------------------
ALLOCATE(rwork(3*m-2))
ALLOCATE(work(2*m-1))
CALL ZHEEV('V', 'U', m, cmat, m, W, WORK,2*m-1,RWORK,INFO)
IF (info.ne.0) THEN
WRITE(buf,'(a)')
& 'The subroutine zheev ends with info = ',info
CALL printout(0)
WRITE(buf,'(a)')'In sqrt_eigenvec, a pbm occurs in zheev.'
CALL printout(0)
WRITE(buf,'(a)')'END OF THE PRGM'
CALL printout(0)
STOP
ENDIF
C W contains the eigenvalues of cmat.
W_comp=CMPLX(W,0d0)
C
C Checking of the validity of the computation :
C ---------------------------------------------
ifwrite=.FALSE.
DO j=1,m
C The warning is written only once in the file case.outdmftpr
IF (ifwrite) EXIT
C Checking if the eigenvalues are not negative.
IF (W(j).lt.0.d0) THEN
WRITE(buf,'(a,i2,a,a)')
& 'WARNING : An eigenvalue (',j,') of the ',
& 'overlap matrix is negative.'
CALL printout(0)
WRITE(buf,'(a,a)')' The result ',
& 'of the calculation may thus be wrong.'
CALL printout(1)
ifwrite=.TRUE.
ENDIF
IF (ABS(W(j)).lt.1.d-12) THEN
WRITE(buf,'(a,i2,a,a)')
& 'WARNING : An eigenvalue (',j,') of the ',
& 'overlap matrix is almost zero.'
CALL printout(0)
WRITE(buf,'(a,a)')' The result ',
& 'of the calculation may thus be wrong.'
CALL printout(1)
ifwrite=.TRUE.
ENDIF
ENDDO
C
C Calculation of Z*D^(1/2) :
C --------------------------
C The result is stored in D1.
IF(.NOT.inv) THEN
DO i=1,m
DO j=1,m
D1(i,j)=cmat(i,j)*SQRT(W_comp(j))
ENDDO
ENDDO
ELSE
C Calculation of Z*D^(-1/2) :
C ---------------------------
C The result is stored in D1.
DO i=1,m
DO j=1,m
IF (ABS(W(j))==0.d0) THEN
WRITE(buf,'(a,i2,a)')
& 'An eigenvalue (',j,') of the ',
& 'overlap matrix has the value 0.'
CALL printout(0)
WRITE(buf,'(a)')
& 'The calculation can not be performed further.'
CALL printout(0)
CALL printout(0)
WRITE(buf,'(a)')'END OF THE PRGM'
CALL printout(0)
STOP
ENDIF
D1(i,j)=cmat(i,j)/SQRT(W_comp(j))
ENDDO
ENDDO
ENDIF
C The resulting matrix is stored in D1 and cmat is now Z.
RETURN
END