if (ntwe.ne.0) then
if (mod(itime,ntwe).eq.0) then
call statout(itime)
- call enerprint(potEcomp)
+C call enerprint(potEcomp)
C print *,itime,'AFM',Eafmforc,etot
endif
#ifdef VOUT
endif
if (rattle) call rattle2
totT=totT+d_time
+ totTafm=totT
+C print *,totTafm,"TU?"
if (d_time.ne.d_time0) then
d_time=d_time0
#ifndef LANG0
potE=potEcomp(0)-potEcomp(20)
c potE=energia_short(0)+energia_long(0)
totT=totT+d_time
+ totTafm=totT
c Calculate the kinetic and the total energy and the kinetic temperature
call kinetic(EK)
totE=EK+potE
endif
call random_vel
totT=0.0d0
+ totTafm=totT
endif
else
c Generate initial velocities
& write(iout,*) "Initial velocities randomly generated"
call random_vel
totT=0.0d0
+CtotTafm is the variable for AFM time which eclipsed during
+ totTafm=totT
endif
c rest2name = prefix(:ilen(prefix))//'.rst'
if(me.eq.king.or..not.out1file)then
& "Time step reduced to",d_time,
& " because of too large initial acceleration."
endif
- if(me.eq.king.or..not.out1file)then
- write(iout,*) "Potential energy and its components"
- call enerprint(potEcomp)
+C if(me.eq.king.or..not.out1file)then
+C write(iout,*) "Potential energy and its components"
+C call enerprint(potEcomp)
c write(iout,*) (potEcomp(i),i=0,n_ene)
- endif
+C endif
potE=potEcomp(0)-potEcomp(20)
totE=EK+potE
itime=0
include 'COMMON.IOUNITS'
include 'COMMON.NAMES'
include 'COMMON.TIME1'
- double precision xv,sigv,lowb,highb
+ double precision xv,sigv,lowb,highb,vec_afm(3)
c Generate random velocities from Gaussian distribution of mean 0 and std of KT/m
c First generate velocities in the eigenspace of the G matrix
c write (iout,*) "Calling random_vel dimen dimen3",dimen,dimen3
lowb=-5*sigv
highb=5*sigv
d_t_work_new(ii)=anorm_distr(xv,sigv,lowb,highb)
+
c write (iout,*) "i",i," ii",ii," geigen",geigen(i),
c & " d_t_work_new",d_t_work_new(ii)
enddo
enddo
+C if (SELFGUIDE.gt.0) then
+C distance=0.0
+C do j=1,3
+C vec_afm(j)=c(j,afmend)-c(j,afmbeg)
+C distance=distance+vec_afm(j)**2
+C enddo
+C distance=dsqrt(distance)
+C do j=1,3
+C d_t_work_new(j+(afmbeg-1)*3)=-velAFMconst*vec_afm(j)/distance
+C d_t_work_new(j+(afmend-1)*3)=velAFMconst*vec_afm(j)/distance
+C write(iout,*) "myvel",d_t_work_new(j+(afmbeg-1)*3),
+C & d_t_work_new(j+(afmend-1)*3)
+C enddo
+
+C endif
+
c diagnostics
c Ek1=0.0d0
c ii=0