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deri1.f
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SUBROUTINE DERI1(C,NORBS,COORD,NUMBER,WORK,GRAD
1 ,F,MINEAR,FD,WMAT,HMAT,FMAT)
IMPLICIT DOUBLE PRECISION (A-H,O-Z)
INCLUDE 'SIZES'
DIMENSION WMAT(MPACK),HMAT(MPACK*2),FMAT(MPACK*2)
*********************************************************************
*
* DERI1 COMPUTE THE NON-RELAXED DERIVATIVE OF THE NON-VARIATIONALLY
* OPTIMIZED WAVEFUNCTION ENERGY WITH RESPECT TO ONE CARTESIAN
* COORDINATE AT A TIME
* AND
* COMPUTE THE NON-RELAXED FOCK MATRIX DERIVATIVE IN M.O BASIS AS
* REQUIRED IN THE RELAXATION SECTION (ROUTINE 'DERI2').
*
* INPUT
* C(NORBS,NORBS) : M.O. COEFFICIENTS.
* COORD : CARTESIAN COORDINATES ARRAY.
* NUMBER : LOCATION OF THE REQUIRED VARIABLE IN COORD.
* WORK : WORK ARRAY OF SIZE N*N.
* WMAT : WORK ARRAYS FOR d<PQ|RS> (2-CENTERS A.O)
* OUTPUT
* C,COORD,NUMBER : NOT MODIFIED.
* GRAD : DERIVATIVE OF THE HEAT OF FORMATION WITH RESPECT TO
* COORD(NUMBER), WITHOUT RELAXATION CORRECTION.
* F(MINEAR) : NON-RELAXED FOCK MATRIX DERIVATIVE WITH RESPECT TO
* COORD(NUMBER), EXPRESSED IN M.O BASIS, SCALED AND
* PACKED, OFF-DIAGONAL BLOCKS ONLY.
* FD : IDEM BUT UNSCALED, DIAGONAL BLOCKS, C.I-ACTIVE ONLY.
*
************************************************************************
COMMON /MOLKST/ NUMAT,NAT(NUMATM),NFIRST(NUMATM),NMIDLE(NUMATM)
1 ,NLAST(NUMATM), NDUMY1, NELECS,NALPHA,NBETA
2 ,NCLOSE,NOPEN,NDUMY,FRACT
3 /VECTOR/ CDUM(MORB2),EIGS(MAXORB),WDUM(MORB2),EIGB(MAXORB)
4 /DENSTY/ P(MPACK), PA(MPACK), PB(MPACK)
COMMON /CIBITS/ NMOS,LAB,NELEC,NBO(3)
1 /HMATRX/ H(MPACK)
2 /XYIJKL/ XY(NMECI,NMECI,NMECI,NMECI)
3 /CIVECT/ CONF(NMECI**4+NMECI**2+1)
COMMON /FOKMAT/ FDUMY(MPACK), SCALAR(MPACK)
COMMON /NVOMAT/ DIAG(MPACK/2)
1 /KEYWRD/ KEYWRD
COMMON /NUMCAL/ NUMCAL
DIMENSION COORD(*),C(NORBS,NORBS),WORK(NORBS,NORBS),F(*),FD(*)
CHARACTER KEYWRD*241
LOGICAL DEBUG
DATA ICALCN /0/
C
IF(ICALCN.NE.NUMCAL) THEN
DEBUG=INDEX(KEYWRD,'DERI1').NE.0
IPRT=6
LINEAR=NORBS*(NORBS+1)/2
ICALCN=NUMCAL
ENDIF
IF(DEBUG) CALL TIMER('BEFORE DERI1')
STEP=1.D-3
C
C 2 POINTS FINITE DIFFERENCE TO GET THE INTEGRAL DERIVATIVES
C ----------------------------------------------------------
C STORED IN HMAT AND WMAT, WITHOUT DIVIDING BY THE STEP SIZE.
C
NATI=(NUMBER-1)/3+1
NATX=NUMBER-3*(NATI-1)
CALL DHCORE (COORD,HMAT,WMAT,ENUCL2,NATI,NATX,STEP)
C
C HMAT HOLDS THE ONE-ELECTRON DERIVATIVES OF ATOM NATI FOR DIRECTION
C NATX W.R.T. ALL OTHER ATOMS
C WMAT HOLDS THE TWO-ELECTRON DERIVATIVES OF ATOM NATI FOR DIRECTION
C NATX W.R.T. ALL OTHER ATOMS
STEP=0.5D0/STEP
C
C NON-RELAXED FOCK MATRIX DERIVATIVE IN A.O BASIS.
C ------------------------------------------------
C STORED IN FMAT, DIVIDED BY STEP.
C
CALL SCOPY (LINEAR,HMAT,1,FMAT,1)
CALL DFOCK2 (FMAT,P,PA,WMAT,NUMAT,NFIRST,NMIDLE,NLAST,NATI)
C
C FMAT HOLDS THE ONE PLUS TWO - ELECTRON DERIVATIVES OF ATOM NATI FOR
C DIRECTION NATX W.R.T. ALL OTHER ATOMS
C
C DERIVATIVE OF THE SCF-ONLY ENERGY (I.E BEFORE C.I CORRECTION)
C
GRAD=(HELECT(NORBS,P,HMAT,FMAT)+ENUCL2)*STEP
C TAKE STEP INTO ACCOUNT IN FMAT
DO 10 I=1,LINEAR
10 FMAT(I)=FMAT(I)*STEP
C
C RIGHT-HAND SIDE SUPER-VECTOR F = C' FMAT C USED IN RELAXATION
C -----------------------------------------------------------
C STORED IN NON-STANDARD PACKED FORM IN F(MINEAR) AND FD.
C THE SUPERVECTOR IS THE NON-RELAXED FOCK MATRIX DERIVATIVE IN
C M.O BASIS: F(IJ)= ( (C' * FOCK * C)(I,J) ) WITH I.GT.J .
C F IS SCALED AND PACKED IN SUPERVECTOR FORM WITH
C THE CONSECUTIVE FOLLOWING OFF-DIAGONAL BLOCKS:
C 1) OPEN-CLOSED I.E. F(IJ)=F(I,J) WITH I OPEN & J CLOSED
C AND I RUNNING FASTER THAN J,
C 2) VIRTUAL-CLOSED SAME RULE OF ORDERING,
C 3) VIRTUAL-OPEN SAME RULE OF ORDERING.
C FD IS PACKED OVER THE C.I-ACTIVE M.O WITH
C THE CONSECUTIVE DIAGONAL BLOCKS:
C 1) CLOSED-CLOSED IN CANONICAL ORDER, WITHOUT THE
C DIAGONAL ELEMENTS,
C 2) OPEN-OPEN SAME RULE OF ORDERING,
C 3) VIRTUAL-VIRTUAL SAME RULE OF ORDERING.
C
C PART 1 : WORK(N,N) = FMAT(N,N) * C(N,N)
DO 20 I=1,NORBS
20 CALL SUPDOT (WORK(1,I),FMAT,C(1,I),NORBS,1)
C
C PART 2 : F(IJ) = (C' * WORK)(I,J) ... OFF-DIAGONAL BLOCKS.
L=1
IF(NBO(2).NE.0 .AND. NBO(1).NE.0) THEN
C OPEN-CLOSED
CALL MTXM (C(1,NBO(1)+1),NBO(2),WORK,NORBS,F(L),NBO(1))
L=L+NBO(2)*NBO(1)
ENDIF
IF(NBO(3).NE.0 .AND. NBO(1).NE.0) THEN
C VIRTUAL-CLOSED
CALL MTXM (C(1,NOPEN+1),NBO(3),WORK,NORBS,F(L),NBO(1))
L=L+NBO(3)*NBO(1)
ENDIF
IF(NBO(3).NE.0 .AND. NBO(2).NE.0) THEN
C VIRTUAL-OPEN
CALL MTXM (C(1,NOPEN+1),NBO(3),WORK(1,NBO(1)+1),NORBS,F(L),NBO(
12))
ENDIF
C SCALE F ACCORDING TO THE DIAGONAL METRIC TENSOR 'SCALAR '.
DO 30 I=1,MINEAR
30 F(I)=F(I)*SCALAR(I)
IF(DEBUG)THEN
WRITE(6,*)' F IN DERI1'
J=MIN(20,MINEAR)
WRITE(6,'(5F12.6)')(F(I),I=1,J)
ENDIF
C
C PART 3 : SUPER-VECTOR FD, C.I-ACTIVE DIAGONAL BLOCKS, UNSCALED.
L=1
NEND=0
DO 50 LOOP=1,3
NINIT=NEND+1
NEND =NEND+NBO(LOOP)
N1=MAX(NINIT,NELEC+1 )
N2=MIN(NEND ,NELEC+NMOS)
IF(N2.LT.N1) GO TO 50
DO 40 I=N1,N2
IF(I.GT.NINIT) THEN
CALL MXM (C(1,I),1,WORK(1,NINIT),NORBS,FD(L),I-NINIT)
L=L+I-NINIT
ENDIF
40 CONTINUE
50 CONTINUE
C
C NON-RELAXED C.I CORRECTION TO THE ENERGY DERIVATIVE.
C ----------------------------------------------------
C
C C.I-ACTIVE FOCK EIGENVALUES DERIVATIVES, STORED IN FD(CONTINUED).
LCUT=L
DO 60 I=NELEC+1,NELEC+NMOS
FD(L)=DOT(C(1,I),WORK(1,I),NORBS)
60 L=L+1
C
C C.I-ACTIVE 2-ELECTRONS INTEGRALS DERIVATIVES. STORED IN XY.
C FMAT IS USED HERE AS SCRATCH SPACE
C
CALL DIJKL1 (C(1,NELEC+1),NORBS,NATI,WMAT,FMAT,HMAT,FMAT)
DO 70 I=1,NMOS
DO 70 J=1,NMOS
DO 70 K=1,NMOS
DO 70 L=1,NMOS
70 XY(I,J,K,L)=XY(I,J,K,L)*STEP
C
C BUILD THE C.I MATRIX DERIVATIVE, STORED IN WMAT.
CALL MECID (FD(LCUT-NELEC),GSE,EIGB,WORK)
IF(DEBUG)THEN
WRITE(6,*)' GSE:',GSE
C# WRITE(6,*)' EIGB:',(EIGB(I),I=1,10)
C# WRITE(6,*)' WORK:',(WORK(I,1),I=1,10)
ENDIF
CALL MECIH (WORK,WMAT,NMOS,LAB)
C
C NON-RELAXED C.I CONTRIBUTION TO THE ENERGY DERIVATIVE.
CALL SUPDOT (WORK,WMAT,CONF,LAB,1)
GRAD=(GRAD+DOT(CONF,WORK,LAB))*23.061D0
IF(DEBUG) THEN
WRITE(IPRT,'('' * * * GRADIENT COMPONENT NUMBER'',I4)')NUMBER
WRITE(IPRT,'('' NON-RELAXED C.I-ACTIVE FOCK EIGENVALUES '',
1 ''DERIVATIVES (E.V.)'')')
WRITE(IPRT,'(8F10.4)')(FD(LCUT-1+I),I=1,NMOS)
WRITE(IPRT,'('' NON-RELAXED 2-ELECTRONS DERIVATIVES (E.V.)''/
1'' I J K L d<I(1)J(1)|K(2)L(2)>'')')
DO 80 I=1,NMOS
DO 80 J=1,I
DO 80 K=1,I
LL=K
IF(K.EQ.I) LL=J
DO 80 L=1,LL
80 WRITE(IPRT,'(4I5,F20.10)')
1 NELEC+I,NELEC+J,NELEC+K,NELEC+L,XY(I,J,K,L)
WRITE(IPRT,'('' NON-RELAXED GRADIENT COMPONENT'',F10.4,
1'' KCAL/MOLE'')')GRAD
CALL TIMER('AFTER DERI1')
ENDIF
RETURN
END
SUBROUTINE DHCORE (COORD,H,W,ENUCLR,NATI,NATX,STEP)
IMPLICIT DOUBLE PRECISION (A-H,O-Z)
INCLUDE 'SIZES'
DIMENSION COORD(3,*),H(*),W(*)
C
C DHCORE GENERATES THE 1-ELECTRON AND 2-ELECTRON INTEGRALS DERIVATIVES
C WITH RESPECT TO THE CARTESIAN COORDINATE COORD (NATX,NATI).
C
C INPUT
C COORD : CARTESIAN COORDINATES OF THE MOLECULE.
C NATI,NATX : INDICES OF THE MOVING COORDINATE.
C STEP : STEP SIZE OF THE 2-POINTS FINITE DIFFERENCE.
C OUTPUT
C H : 1-ELECTRON INTEGRALS DERIVATIVES (PACKED CANONICAL).
C W : 2-ELECTRON INTEGRALS DERIVATIVES (ORDERED AS REQUIRED
C IN DFOCK2 AND DIJKL1).
C ENUCLR : NUCLEAR ENERGY DERIVATIVE.
C
COMMON /MOLKST/ NUMAT,NAT(NUMATM),NFIRST(NUMATM),NMIDLE(NUMATM),
1 NLAST(NUMATM), NORBS, NELECS,NALPHA,NBETA,
2 NCLOSE,NOPEN,NDUMY,FRACT
3 /MOLORB/ USPD(MAXORB),DUMY(MAXORB)
4 /KEYWRD/ KEYWRD
5 /WMATRX/ WDUMMY(N2ELEC*2)
CHARACTER*241 KEYWRD
LOGICAL FIRST,MINDO
DIMENSION E1B(10),DE1B(10),E2A(10),DE2A(10)
1 ,DI(9,9),DDI(9,9),WJD(101),DWJD(101)
2,NB(0:8)
DATA NB/1,0,0,10,0,0,0,0,45/
DATA FIRST/.TRUE./
IF (FIRST) THEN
CUTOFF=1.D10
FIRST=.FALSE.
MINDO=INDEX(KEYWRD,'MINDO') .NE. 0
ENDIF
DO 10 I=1,(NORBS*(NORBS+1))/2
10 H(I)=0
ENUCLR=0.D0
KR=1
NROW=0
I=NATI
CSAVE=COORD(NATX,NATI)
IA=NFIRST(NATI)
IB=NLAST(NATI)
IC=NMIDLE(NATI)
NI=NAT(NATI)
NROW=-NB(IB-IA)
DO 20 J=1,NUMAT
20 NROW=NROW+NB(NLAST(J)-NFIRST(J))
C# NCOL=NB(NLAST(NATI)-NFIRST(NATI))
NBAND2=0
DO 120 J=1,NUMAT
IF (J.EQ.NATI) GO TO 120
JA=NFIRST(J)
JB=NLAST(J)
JC=NMIDLE(J)
NJ=NAT(J)
COORD(NATX,NATI)=CSAVE+STEP
CALL H1ELEC(NI,NJ,COORD(1,NATI),COORD(1,J),DI)
C
C THE FOLLOWING STYLE WAS NECESSARY TO GET ROUND A BUG IN THE
C GOULD COMPILER
C
COORD(NATX,NATI)=CSAVE+STEP*(-1.D0)
CALL H1ELEC(NI,NJ,COORD(1,NATI),COORD(1,J),DDI)
C
C FILL THE ATOM-OTHER ATOM ONE-ELECTRON MATRIX.
C
I2=0
IF (IA.GT.JA) THEN
DO 30 I1=IA,IB
IJ=I1*(I1-1)/2+JA-1
I2=I2+1
J2=0
DO 30 J1=JA,JB
IJ=IJ+1
J2=J2+1
30 H(IJ)=H(IJ)+(DI(I2,J2)-DDI(I2,J2))
ELSE
DO 40 I1=JA,JB
IJ=I1*(I1-1)/2+IA-1
I2=I2+1
J2=0
DO 40 J1=IA,IB
IJ=IJ+1
J2=J2+1
40 H(IJ)=H(IJ)+(DI(J2,I2)-DDI(J2,I2))
ENDIF
C
C CALCULATE THE TWO-ELECTRON INTEGRALS, W; THE ELECTRON NUCLEAR TERM
C E1B AND E2A; AND THE NUCLEAR-NUCLEAR TERM ENUC.
C
KRO=KR
NBAND2=NBAND2+NB(NLAST(J)-NFIRST(J))
IF (MINDO) THEN
COORD(NATX,NATI)=CSAVE+STEP
CALL ROTATE (NI,NJ,COORD(1,NATI),COORD(1,J)
1 ,WJD,KR,E1B,E2A,ENUC,CUTOFF)
KR=KRO
COORD(NATX,NATI)=CSAVE+STEP*(-1.D0)
CALL ROTATE (NI,NJ,COORD(1,NATI),COORD(1,J)
1 ,DWJD,KR,DE1B,DE2A,DENUC,CUTOFF)
IF (KR.GT.KRO) THEN
DO 50 K=1,KR-KRO+1
50 W(KRO+K-1)=WJD(K)-DWJD(K)
ENDIF
ELSE
COORD(NATX,NATI)=CSAVE+STEP
CALL ROTATE (NI,NJ,COORD(1,NATI),COORD(1,J)
1 ,WJD,KR,E1B,E2A,ENUC,CUTOFF)
KR=KRO
COORD(NATX,NATI)=CSAVE+STEP*(-1.D0)
CALL ROTATE (NI,NJ,COORD(1,NATI),COORD(1,J)
1 ,DWJD,KR,DE1B,DE2A,DENUC,CUTOFF)
IF (KR.GT.KRO) THEN
DO 60 K=1,KR-KRO+1
60 WJD(K)=WJD(K)-DWJD(K)
J7=0
DO 70 I1=KRO,KR
J7=J7+1
70 W(I1)=WJD(J7)
ENDIF
ENDIF
COORD(NATX,NATI)=CSAVE
ENUCLR = ENUCLR + ENUC-DENUC
C
C ADD ON THE ELECTRON-NUCLEAR ATTRACTION TERM FOR ATOM I.
C
I2=0
DO 80 I1=IA,IC
II=I1*(I1-1)/2+IA-1
DO 80 J1=IA,I1
II=II+1
I2=I2+1
80 H(II)=H(II)+E1B(I2)-DE1B(I2)
C CONTRIB D, CNDO.
DO 90 I1=IC+1,IB
II=(I1*(I1+1))/2
90 H(II)=H(II)+E1B(1)-DE1B(1)
C
C ADD ON THE ELECTRON-NUCLEAR ATTRACTION TERM FOR ATOM J.
C
I2=0
DO 100 I1=JA,JC
II=I1*(I1-1)/2+JA-1
DO 100 J1=JA,I1
II=II+1
I2=I2+1
100 H(II)=H(II)+E2A(I2)-DE2A(I2)
C CONTRIB D, CNDO.
DO 110 I1=JC+1,JB
II=(I1*(I1+1))/2
110 H(II)=H(II)+E2A(1)-DE2A(1)
120 CONTINUE
C
C 'SIZE' OF H IS NROW * NCOL
C
RETURN
END