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|
program FourLevelPulseProp_v3_Double
!
! Written by: Dr. Frank A. Narducci
! Written on: May 12, 2008
!
! This program calculates the propagation of a pulse of arbitrary strength
! through a two level medium. The equations used are the full equations
! based on the Risken-Numedal discretization technique.
!
! This program only "watches" the evolution of the pulse in the cell. This is
! due to the constraint that the cell is very small relative to the pulse lengths
! that we want to use. If we watched the pulse outside the cell and then increased the
! resolution within the cell, the increased burden outside the cell because huge.
!
! v2 Notes: This program is based on the dimensionless equatiosn derived on 5/16
implicit none
!
! Double Notes: This program is the same as TwoLevelPulseProp_v2 but with double precision
complex ci
!
! ThreeLevel Notes: This program is the same as TwoLevelPulseProp_v2_Double but now for a
! three level system
!
! Four Level Notes: Valid to first order in dt
!
! Version 3: Make a step function in the coupling field.
character*150 fname
integer nmat,npts,Nfrac,Nframe,Nframemax,NSkip,NWrite,tpts,zpts
parameter (nmat=3,npts=100) !matrix size, number of detuning points in dispersion curve
!REMEMBER TO CHANGE NMAT IN LMatConstruct Routine
parameter (tpts=10,zpts=tpts+1) !Caution: funny things happened when tpts=200 (and presumably greater)
!tpts is the number of temporal points in the cell
parameter (Nframemax=2000000)
parameter ( NWrite=100) !number of frames to actually write
integer i,j,k,m,n
complex*16 a1,a2,a3,a4,a5,a6
complex*16 b1,b2,b3,b4,b5,b6,b7
complex*16 c1,c2,c3,c4,c5,c6
complex*16 d1,d2,d3,d4,d5,d6,d7
complex*16 e1,e2,e3,e4,e5
complex*16 f1,f2,f3,f4,f5
complex*16 g1,g2,g3,g4,g5,g6,g7
complex*16 h1,h2,h3,h4,h5
complex*16 i1,i2,i3,i4,i5,i6,i7
complex*16 j1,j2,j3,j4,j5,j6,j7,j8
complex*16 k1,k2,k3,k4,k5,k6,k7,k8,k9,k10
complex*16 l1,l2,l3,l4,l5
complex *16 Omold, Omold_vac
real*8 alpha1,alpha2,alpha1tilde,alpha2tilde,alphac,alphactilde,beta,c,delmax,del1_prop,del2_prop,delc_prop
real*8 dt,dz,eta
real*8 W12,W21,W31,W32,W41,W42,W43,W34,ga12,ga13,ga14,ga23,ga24,ga34
real*8 Ga2,Ga4,Om_crit
real*8 Lcell,Om1peak,Om2peak,Omcpeak,pi,tmax,tp,tshift,t_end,t_start,t_elapsed
real*8 tpeak,tpeak_vac
real*8 epsil,hbar,lambda
real*8 del(npts)
real*8 t,z(zpts)
complex*16 yplot(nmat,npts)
complex*16 Imat(nmat)
complex*16 Om1(zpts),Om2(zpts),Omc(zpts),Om_vac(zpts)
complex*16 rho11(zpts),rho12(zpts),rho13(zpts),rho14(zpts),rho21(zpts),rho22(zpts),rho23(zpts),rho24(zpts)
complex*16 rho31(zpts),rho32(zpts),rho33(zpts),rho34(zpts),rho41(zpts),rho42(zpts),rho43(zpts),rho44(zpts)
complex*16 rho11_last(zpts),rho12_last(zpts),rho13_last(zpts),rho14_last(zpts)
complex*16 rho21_last(zpts),rho22_last(zpts),rho23_last(zpts),rho24_last(zpts)
complex*16 rho31_last(zpts),rho32_last(zpts),rho33_last(zpts),rho34_last(zpts)
complex*16 rho41_last(zpts),rho42_last(zpts),rho43_last(zpts),rho44_last(zpts)
!No Om_last because we never need the previous spatial point
complex*16 L(nmat,nmat),Linv(nmat,nmat),Ltemp(nmat,nmat)
common/para/ga12,W21
real*8 d !used by NR Routines
integer indx(nmat)
!
! Fundamental numbers
!
ci=cmplx(0.,1.)
pi=acos(-1.0)
c=3e8
hbar=1.055e-34
epsil=8.85e-12
!
! Atomic numbers (based on Rubidium 85)
!
beta=2*pi*3e6 !in Hz
W41=0
W42=0.
W43=0
W32=1.
W31=1.
W21=.001
W12=W21
W34=0
ga12=0.5*(W21+W12)
ga13=0.5*(W31+W12+W32)
ga14=0.5*(W41+W42+W12)
ga23=0.5*(W32+W31+W21)
ga24=0.5*(W21+W41+W42+W43)
ga34=0.5*(W31+W41+W32+W42+W43)
lambda=780.24e-9
!
! Atomic parameters
!
write (*,*)'New version from moved folder'
! write (*,*)'Enter density in m^-1'
! read (*,*)eta
eta=6.9e11
alpha1=3*eta*lambda*lambda/(2*pi)
alpha1tilde=alpha1*c/beta
alpha2=3*eta*lambda*lambda/(2*pi)
alpha2tilde=alpha2*c/beta
alphac=3*eta*lambda*lambda/(2*pi)
alphactilde=alphac*c/beta
!
! Initialize matrices and set up Identity Matrix
!
do 20 i=1,nmat
do 10 j=1,nmat
L(i,j)=cmplx(0.,0.)
Linv(i,j)=cmplx(0.,0.)
10 continue !j loop
Imat(i)=cmplx(0.,0.)
Linv(i,i)=cmplx(1.,0.) !contains identity matrix
20 continue
!
! User defined numbers
!
! write (*,*)'Enter peak scaled Rabi frequency for the pump at entrance of cell'
! read (*,*)Om1peak
Om1peak=1
! write (*,*)'Enter peak scaled Rabi frequency for the probe at entrance of cell'
! read (*,*)Om2peak
Om2peak=1e-2
! write (*,*)'Enter maximum detuning in MHz for dispersion lineshape plot'
! read (*,*) delmax
delmax=0
Ga4=(W41+W42+W43)
Ga2=W21
Om_crit=sqrt(Om1peak**4+4*Om1peak*Om1peak*(Ga4*Ga4+Ga2*Ga4))
Om_crit=Om_crit-Om1peak*Om1peak-2*Ga2*Ga4
Om_crit=sqrt(Om_crit/2)
write (*,*)'Om_crit = ',Om_crit
! write (*,*)'Enter peak scaled Rabi frequency for the coupling field at entrance of cell'
! read (*,*)Omcpeak
Omcpeak=0.
!
! First plot the dispersion lineshape
!
! do 40 n=1,npts
! del(n)=-delmax+2*float(n)*delmax/npts
! call LMatConstruct(Ompeak,del(n),L) !construct the L matrix
! call LMatConstruct(Ompeak,del(n),Ltemp) !Need a temporary because L gets destroyed
! call ImatConstruct(Ompeak,Imat) !Need to call in loop because it gets destroyed
! !See also note in subroutine
! call ludcmp(L,nmat,nmat,indx,d)
! call lubksb(L,nmat,nmat,indx,Imat) !Imat now contains psi
! do 35 i=1,nmat
! yplot(i,n)=Imat(i)
!35 continue
! if (.false.) call MatCheck(Ltemp,Linv)
!40 continue
! call plotit(del,yplot,nmat,npts)
!
! Now that the user has an idea of the dispersion, do the full propagation problem
! write (*,*)'Enter detuning of center frequency of the coupling pulse in MHz'
! read (*,*)delc_prop !del_prop is the detuning used for the propagation
delc_prop=0
delc_prop=2*pi*1e6*delc_prop/beta !Now dimensionless
! write (*,*)'Enter detuning of center frequency of the pump pulse in MHz'
! read (*,*)del2_prop !del_prop is the detuning used for the propagation
del2_prop=0;
del2_prop=2*pi*1e6*del2_prop/beta !Now dimensionless
! write (*,*)'Enter detuning of center frequency of the probe pulse in MHz'
! read (*,*)del1_prop !del_prop is the detuning used for the propagation
del1_prop=0.
del1_prop=2*pi*1e6*del1_prop/beta !Now dimensionless
! write (*,*) 'Enter pulse width in nsec'
! read (*,*)tp
tp=1e-6
tp=beta*tp !Now dimensionless
! write (*,*)'Enter length of cell in m'
! read (*,*)Lcell
Lcell=100;
Lcell=beta*Lcell/c !Now dimensionless
t_start=secnds(0.E0)
write (*,*)'t_start = ',t_start
! XXXXXXX
!
! Set up initial pulse.
!
tshift=2*tp
tmax=Lcell !Length of time to pass cell (no c because we're dimensionless)
dt=tmax/tpts
dz=dt !(no c because we're dimensionless)
! write (*,*)'tp = ',tp
Nframe=zpts+int(6*tp/dt)+1 !Change the number 4 to anything you want to see longer pulse evolution
if (Nframe.ge.Nframemax) write (*,*)'Error!!!!Nframe>Nframemax'
! write (*,*)'Nframe,tpts = ',Nframe,tpts
!
! Initialize matrices
!
Omold=cmplx(0.,0.)
Omold_vac=cmplx(0.,0.)
tpeak=-1
tpeak_vac=-1
write (*,*)'Nframe= ', Nframe
! pause
! do 110 n=1,Nframe
do 100 m=1,zpts
Om1(m)=cmplx(0.,0.)
Om2(m)=cmplx(0.,0.)
Omc(m)=cmplx(0.,0.)
Om_vac(m)=cmplx(0.,0.)
rho11(m)=cmplx(1.,0.) !Change this to change the initial condition
rho12(m)=cmplx(0.,0.)
rho13(m)=cmplx(0.,0.)
rho14(m)=cmplx(0.,0.)
rho21(m)=cmplx(0.,0.)
rho22(m)=cmplx(0.,0.)
rho23(m)=cmplx(0.,0.)
rho24(m)=cmplx(0.,0.)
rho31(m)=cmplx(0.,0.)
rho32(m)=cmplx(0.,0.)
rho33(m)=cmplx(0.,0.)
rho34(m)=cmplx(0.,0.)
rho41(m)=cmplx(0.,0.)
rho42(m)=cmplx(0.,0.)
rho43(m)=cmplx(0.,0.)
rho44(m)=cmplx(0.,0.)
100 continue
!110 continue
! Propagation co-efficients
!
a1=1.
a2=0.5*ci*alpha1tilde*dt
a3=0.5*ci*alpha1tilde*dt
a4=0.
a5=0.
a6=0.
b1=1.
b2=0.5*ci*alpha2tilde*dt
b2=0.5*ci*alpha2tilde*dt
b4=0.
b5=0.
b6=0.
b7=0.
c1=1.
c2=0.5*ci*alphactilde*dt
c3=0.5*ci*alphactilde*dt
c4=0.
c5=0.
c6=0.
d1=1-(ga12-ci*(del2_prop-del1_prop))*dt
d2=0.25*ci*dt
d3=-0.25*ci*dt
d4=-0.25*ci*dt
d5=0.25*ci*dt
d6=-0.25*ci*dt
d7=-0.25*ci*dt
e1=1-(ga13+ci*del1_prop)*dt
e2=0.25*ci*dt
e3=-0.25*ci*dt
e4=0.25*ci*dt
e5=-0.25*ci*dt
f1=1-(ga14-ci*(del2_prop-del1_prop-delc_prop))*dt
f2=0.25*ci*dt
f3=-0.25*ci*dt
f4=0.25*ci*dt
f5=-0.25*ci*dt
g1=1-(ga23+ci*del1_prop)*dt
g2=-0.25*ci*dt
g3=0.25*ci*dt
g4=0.25*ci*dt
g5=-0.25*ci*dt
g6=0.25*ci*dt
g7=0.25*ci*dt
h1=1-(ga24+ci*delc_prop)*dt
h2=0.25*ci*dt
h3=0.25*ci*dt
h4=0.25*ci*dt
h5=0.25*ci*dt
i1=1-(ga34-ci*(del2_prop-delc_prop))*dt
i2=-0.25*ci*dt
i3=0.25*ci*dt
i4=0.25*ci*dt
i5=-0.25*ci*dt
i6=0.25*ci*dt
i7=0.25*ci*dt
j1=1-W12*dt
j2=W21*dt
j3=W31*dt
j4=0.25*ci*dt
j5=-0.25*ci*dt
j6=0.25*ci*dt
j7=-0.25*ci*dt
j8=W41*dt
k1=1-(W32+W31)*dt
k2=W43*dt
k3=-0.25*ci*dt
k4=-0.25*ci*dt
k5=0.25*ci*dt
k6=0.25*ci*dt
k7=-0.25*ci*dt
k8=-0.25*ci*dt
k9=0.25*ci*dt
k10=0.25*ci*dt
l1=1-(W43+W42+W41)*dt
l2=-0.25*ci*dt
l3=0.25*ci*dt
l4=-0.25*ci*dt
l5=0.25*ci*dt
NSkip=int(NFrame/NWrite)
fname='MovieParameters4level_v2.txt'
! write (*,*)'Enter file name to save parameters'
! read (*,3)fname
3 format(a150)
open(9,file=fname)
write (9,133)Nframe,zpts,beta,NSkip,dt
! write (*,*)'Nframe,zpts,beta,NSkip,dt'
! write (*,133)Nframe,zpts,beta,NSkip,dt
133 format(1x,i10,',',i5,',',f12.2,',',i5,',',f12.2)
close (9)
fname='Movie4level_v2.dat'
! write (*,*)'Enter file name to save movie'
! read (*,3)fname
open(9,file=fname)
fname='Movie4level_EndPoints_v2.dat'
! write (*,*)'Enter file name to save endpoints'
! read (*,3)fname
open(10,file=fname)
do 60 n=1,Nframe
! write (*,*)'n = ',n
t=float(n-1)*dt
Om1(1)=Om1peak
Om2(1)=Om2peak*exp(-(t-tshift)**2/(tp*tp))
Omc(1)=Omcpeak
Om_vac(1)=Om2(1)
if (int(n/10).eq.0) write(fname,130)'Movie',n
if (int(n/10).ge.1.and.int(n/100).eq.0) write (fname,131)'Movie',n
if (int(n/10).ge.1.and.int(n/100).gt.0) write (fname,132)'Movie',n
130 format(a5,i1)
131 format(a5,i2)
132 format(a5,i3)
! write (*,125)fname
125 format(1x,a12)
! open(9,file=fname)
do 345 m=1,zpts
rho11_last(m)=rho11(m)
rho12_last(m)=rho12(m)
rho13_last(m)=rho13(m)
rho14_last(m)=rho14(m)
rho21_last(m)=rho21(m)
rho22_last(m)=rho22(m)
rho23_last(m)=rho23(m)
rho24_last(m)=rho24(m)
rho31_last(m)=rho31(m)
rho32_last(m)=rho32(m)
rho33_last(m)=rho33(m)
rho34_last(m)=rho34(m)
rho41_last(m)=rho41(m)
rho42_last(m)=rho42(m)
rho43_last(m)=rho43(m)
rho44_last(m)=rho44(m)
345 continue
do 50 m=zpts,2,-1
z(m)=float(m)*dz
Om1(m)=a1*Om1(m-1)+a2*rho31_last(m)+a3*rho31_last(m-1)
Om2(m)=b1*Om2(m-1)+b2*rho32_last(m)+b3*rho32_last(m-1)
Omc(m)=c1*Omc(m-1)+c2*rho42_last(m)+c3*rho42_last(m-1)
rho11(m)=j1*rho11_last(m)+j2*rho22_last(m)+j3*rho33_last(m)+j4*conjg(Om1(m))*rho31_last(m)
rho11(m)=rho11(m)+j5*Om1(m)*rho13_last(m)+j6*conjg(Om1(m-1))*rho31_last(m)+j7*Om1(m-1)*rho13_last(m)
rho11(m)=rho11(m)+j8*rho44_last(m)
rho12(m)=d1*rho12_last(m)+d2*conjg(Om1(m))*rho32_last(m)+d3*Om2(m)*rho13_last(m)
rho12(m)=rho12(m)+d4*Omc(m)*rho14_last(m)+d5*conjg(Om1(m-1))*rho32_last(m)
rho12(m)=rho12(m)+d6*Om2(m-1)*rho13_last(m)+d7*Omc(m-1)*rho14_last(m)
rho13(m)=e1*rho13_last(m)+e2*conjg(Om1(m))*(rho33_last(m)-rho11_last(m))
rho13(m)=rho13(m)+e3*conjg(Om2(m))*rho12_last(m)+e4*conjg(Om1(m-1))*(rho33_last(m)-rho11_last(m))
rho13(m)=rho13(m)+e5*conjg(Om2(m-1))*rho12_last(m)
rho14(m)=f1*rho14_last(m)+f2*conjg(Om1(m))*rho34_last(m)+f3*conjg(Omc(m))*rho12_last(m)
rho14(m)=rho14(m)+f4*conjg(Om1(m-1))*rho34_last(m)+f5*conjg(Omc(m-1))*rho12_last(m)
rho21(m)=conjg(rho12(m))
! rho22(m) needs to be calculated lower down
rho23(m)=g1*rho23_last(m)+g2*conjg(Om1(m))*rho21_last(m)+g3*conjg(Om2(m))*(rho33_last(m)-rho22_last(m))
rho23(m)=rho23(m)+g4*conjg(Omc(m))*rho43_last(m)+g5*conjg(Om1(m-1))*rho21_last(m)
rho23(m)=rho23(m)+g6*conjg(Om2(m-1))*(rho33_last(m)-rho22_last(m))+g7*conjg(Omc(m-1))*rho43_last(m)
rho24(m)=h1*rho24_last(m)+h2*conjg(Om2(m))*rho34_last(m)+h3*conjg(Omc(m))*(rho44_last(m)-rho22_last(m))
rho24(m)=rho24(m)+h4*conjg(Om2(m-1))*rho34_last(m)+h5*conjg(Omc(m-1))*(rho44_last(m)-rho22_last(m))
rho31(m)=conjg(rho13(m))
rho32(m)=conjg(rho23(m))
rho33(m)=k1*rho33_last(m)+k2*rho44_last(m)+k3*conjg(Om1(m))*rho31_last(m)+k4*conjg(Om2(m))*rho32_last(m)
rho33(m)=rho33(m)+k5*Om1(m)*rho13_last(m)+k6*Om2(m)*rho23_last(m)+k7*conjg(Om1(m-1))*rho31_last(m)
rho33(m)=rho33(m)+k8*conjg(Om2(m-1))*rho32_last(m)+k9*Om1(m-1)*rho13_last(m)+k10*Om2(m-1)*rho23_last(m)
rho34(m)=i1*rho34_last(m)+i2*conjg(Omc(m))*rho32_last(m)+i3*Om1(m)*rho14_last(m)+i4*Om2(m)*rho24_last(m)
rho34(m)=rho34(m)+i5*conjg(Omc(m-1))*rho32_last(m)+i6*Om1(m-1)*rho14_last(m)+i7*Om2(m-1)*rho24_last(m)
rho41(m)=conjg(rho14(m))
rho42(m)=conjg(rho24(m))
rho43(m)=conjg(rho34(m))
rho44(m)=l1*rho44_last(m)+l2*conjg(Omc(m))*rho42_last(m)+l3*Omc(m)*rho24_last(m)
rho44(m)=rho44(m)+l4*conjg(Omc(m-1))*rho42_last(m)+l5*Omc(m-1)*rho24(m)
rho22(m)=1-rho11(m)-rho33(m)-rho44(m)
rho11_last(m)=rho11(m)
rho12_last(m)=rho12(m)
rho13_last(m)=rho13(m)
rho14_last(m)=rho14(m)
rho21_last(m)=rho21(m)
rho22_last(m)=rho22(m)
rho23_last(m)=rho23(m)
rho24_last(m)=rho24(m)
rho31_last(m)=rho31(m)
rho32_last(m)=rho32(m)
rho33_last(m)=rho33(m)
rho34_last(m)=rho34(m)
rho41_last(m)=rho41(m)
rho42_last(m)=rho42(m)
rho43_last(m)=rho43(m)
rho44_last(m)=rho44(m)
Om_vac(m)=a1*Om_vac(m-1)
if (mod(n,Nskip).eq.0) write (9,120)z(m),Om2(m),Om_vac(m),Omc(m)
50 continue
if (cdabs(Om2(zpts)).gt.cdabs(Omold)) tpeak=t
if (cdabs(Om_vac(zpts)).gt.cdabs(Omold_vac)) tpeak_vac=t
write (10,139) t,cdabs(Om2(zpts)),cdabs(Om_vac(zpts)) !EndPoint File
Omold=Om2(zpts)
Omold_vac=Om_vac(zpts)
60 continue
close(9)
close(10)
139 format(1x,f12.6,',',F12.6,',',F12.6)
! write (*,*)'Medium pulse out at ',tpeak/(beta*1e-6),' microseconds'
! write (*,*)'Vacuum pulse out at ',tpeak_vac/(beta*1e-6),' microseconds'
write (*,*)Omcpeak,(tpeak-tpeak_vac)/(beta*1e-9)
120 format(1x,f12.6,',',f12.6,',',f12.6,',',f12.6,',',f12.6,',',f12.6,',',f12.6)
t_end=secnds(0.E0)
t_elapsed=t_end-t_start
write(*,*)'T elapsed = ',t_elapsed
stop
end
!
subroutine IMatConstruct(Om,Imat)
!
! NOTE: This subroutine actually calculates -Imat because we need to solve LPsi=-Imat.
implicit none
integer i,nmat
parameter (nmat=3)
real*8 Om
complex*8 Imat(nmat)
Imat(1)=-cmplx(0.,-0.5*Om)
Imat(2)=-cmplx(0.,0.5*Om)
Imat(3)=cmplx(0.,0.)
return
end
!
subroutine LMatConstruct(Om,del,L)
!
implicit none
integer nmat
parameter (nmat=3)
real*8 del,ga12,Om,W21
complex*8 L(nmat,nmat)
common/para/ga12,W21
L(1,1)=cmplx (-ga12,-del)
L(1,3)=cmplx(0.,Om)
L(2,2)=cmplx(-ga12,del)
L(2,3)=cmplx(0.,-Om)
L(3,1)=cmplx(0.,0.5*Om)
L(3,2)=cmplx(0.,-0.5*Om)
L(3,3)=cmplx(-W21,0.)
return
end
!
subroutine MatCheck(L,Linv)
!
implicit none
integer i,j,k,nmat
parameter (nmat=3)
complex*8 L(nmat,nmat),Linv(nmat,nmat),Res(nmat,nmat)
write (*,*)'L = '
do 10 i=1,nmat
write (*,120)(L(i,j),j=1,nmat)
10 continue
write (*,*)'Linv = '
do 20 i=1,nmat
write (*,120)(Linv(i,j),j=1,nmat)
20 continue
write (*,*)'Res = '
do 50 i=1,nmat
do 40 j=1,nmat
Res(i,j)=cmplx(0.,0.)
do 30 k=1,nmat
Res(i,j)=Res(i,j)+Linv(i,k)*L(k,j)
30 continue
40 continue
write (*,120)(Res(i,j),j=1,nmat)
50 continue
120 format(1x,3(f8.4,'+i',f8.4,' '))
return
end
!
subroutine plotit(x,y,nmat,npts)
!
! See MATLAB routine that will do this plotting.
implicit none
integer i,n,nmat,npts
real*8 x(npts)
complex*8 y(nmat,npts)
write (*,*)'For now, we are just going to write the file'
open(9, FILE='TwoLevelPulseProp.txt')
do 10 n=1,npts
write (9,100)x(n),(y(i,n),i=1,3)
! write(*,100)x(n),(y(i,n),i=1,3)
10 continue
100 format(1x,f9.6,',',3(f9.6,',',f9.6,','))
return
end
!********************************************************
! Numerical Recipes
!********************************************************
SUBROUTINE ludcmp(a,n,np,indx,d)
implicit none
INTEGER n,np,indx(n),NMAX
REAL*8 d,TINY
PARAMETER (NMAX=500,TINY=1.0e-20)
INTEGER i,imax,j,k
REAL aamax,dum,vv(NMAX)
! My changed variables
complex*8 sum,dum2
complex*8 a(np,np)
d=1.
do 12 i=1,n
aamax=0.
do 11 j=1,n
if (cabs(a(i,j)).gt.aamax) aamax=cabs(a(i,j))
11 continue
if (aamax.eq.0.) pause 'singular matrix in ludcmp'
vv(i)=1./aamax
12 continue
do 19 j=1,n
do 14 i=1,j-1
sum=a(i,j)
do 13 k=1,i-1
sum=sum-a(i,k)*a(k,j)
13 continue
a(i,j)=sum
14 continue
aamax=0.
do 16 i=j,n
sum=a(i,j)
do 15 k=1,j-1
sum=sum-a(i,k)*a(k,j)
15 continue
a(i,j)=sum
dum=vv(i)*cabs(sum)
if (dum.ge.aamax) then
imax=i
aamax=dum
endif
16 continue
if (j.ne.imax)then
do 17 k=1,n
dum2=a(imax,k)
a(imax,k)=a(j,k)
a(j,k)=dum2
17 continue
d=-d
vv(imax)=vv(j)
endif
indx(j)=imax
if (cabs(a(j,j)).eq.0.) a(j,j)=cmplx(TINY,TINY)
if(j.ne.n)then
dum2=1./a(j,j)
do 18 i=j+1,n
a(i,j)=a(i,j)*dum2
18 continue
endif
19 continue
return
END
SUBROUTINE lubksb(a,n,np,indx,b)
implicit none
INTEGER n,np,indx(n)
INTEGER i,ii,j,ll
! My changed variables
complex*8 sum
complex*8 b(n)
complex*8 a(np,np)
ii=0
do 12 i=1,n
ll=indx(i)
sum=b(ll)
b(ll)=b(i)
if (ii.ne.0)then
do 11 j=ii,i-1
sum=sum-a(i,j)*b(j)
11 continue
else if (sum.ne.0.) then
ii=i
endif
b(i)=sum
12 continue
do 14 i=n,1,-1
sum=b(i)
do 13 j=i+1,n
sum=sum-a(i,j)*b(j)
13 continue
b(i)=sum/a(i,i)
14 continue
return
END
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