SUBROUTINE solcor(britin,i4time,satlon,rlat,rlon,britout),7
IMPLICIT NONE
!
INTEGER :: britin
INTEGER :: i4time
REAL :: satlon
REAL :: rlat
REAL :: rlon
INTEGER :: britout
!
! Satellite and sun position variables
!
REAL :: latsat,lonsat,rangesat
REAL :: pi,halfpi,dtr,rtd
REAL :: solx,soly,solz
REAL :: satx,saty,satz
SAVE pi,halfpi,dtr,rtd
SAVE solx,soly,solz
SAVE satx,saty,satz
!
! Constants used in photometric correction
!
REAL :: s1,s2
SAVE s1,s2
!
REAL :: wfactor
PARAMETER (wfactor=18.)
REAL :: r01,rinf1,da1,r02,rinf2,da2,r31,r41,r32,r42
PARAMETER (da1=12., &
r01=0., &
rinf1=71., &
da2=0., &
r02=80., &
rinf2=230., &
r31=68., &
r41=220., &
r32=272., &
r42=880.)
REAL :: r41mr31,r42mr32,a1,a2
PARAMETER (r41mr31=r41-r31, &
r42mr32=r42-r32, &
a1=rinf1-r01, &
a2=rinf2-r02)
!
! Physical constants
!
! au mean earth to sun distance (m)
! eradius mean earth radius (m)
! aunor earth-to-sun distance normalized by earth radius
!
REAL :: au,eradius,aunor
PARAMETER (au = 1.4956E11, &
eradius = 6.371E06, &
aunor = au/eradius)
!
! Misc local variables
!
REAL :: alt,dec,hrangle
REAL :: decrad,hrangrad,latrad,lonrad,altrad
REAL :: pixx,pixy,pixz
REAL :: rnor,delta,emiss,phase,ph2,phcor
REAL :: r1,r2,rin11,rin12,rin21,rin22,rout1,rout2
!
! Statement function
!
REAL :: arctanh,x
arctanh(x) = 0.5*LOG((1.+x)/(1.-x))
!
CALL solar_pos
(rlat,rlon,i4time,alt,dec,hrangle)
IF(alt > 0.) THEN
!
! Find position of pixel in cartesian coordinate
! centered at center of earth, x axis to lat=0., lon=0.,
! and zaxis to the north pole.
! Earth's radius is used as unit length
! so distance is unity for this calculation.
!
latrad=dtr*rlat
lonrad=dtr*rlon
pixx=COS(lonrad)*COS(latrad)
pixy=SIN(lonrad)*COS(latrad)
pixz=SIN(latrad)
!
! Find angle between vectors
! satellite-to-pixel and center-of-earth-to-pixel
!
CALL deltaang((satx-pixx),(saty-pixy),(satz-pixz), &
pixx,pixy,pixz,delta)
emiss=halfpi-delta
!
! Find angle between vectors
! pixel-to-satellite and pixel-to-sun
!
CALL deltaang((pixx-satx),(pixy-saty),(pixz-satz), &
(pixx-solx),(pixy-soly),(pixz-solz),delta)
phase=AMAX1(AMIN1(halfpi,delta),0.)
!
! Phase angle correction term
!
altrad=dtr*alt
ph2=COS(phase)
ph2=ph2*ph2
phcor=20.*(ph2*ph2*ph2)*SQRT(COS(emiss))*(SIN(altrad))**0.25
!
! Stretching parameters
!
r1=r01+a1*TANH(s1*dtr*(alt+da1))+phcor
r2=r02+a2*TANH(s2*dtr*(alt+da2))+phcor
!
! Apply stretching
!
britout=nint(r1+(FLOAT(britin)-r1)*r41mr31/(r2-r1))
britout=MIN(britout,255)
britout=MAX(britout,0)
ELSE
britout=britin
END IF
!
RETURN
!
ENTRY solr1r2(i4time,satlon,rlat,rlon,rout1,rout2)
CALL solar_pos(rlat,rlon,i4time,alt,dec,hrangle)
IF(alt > 0.) THEN
!
! Find position of pixel in cartesian coordinate
! centered at center of earth, x axis to lat=0., lon=0.,
! and zaxis to the north pole.
! Earth's radius is used as unit length
! so distance is unity for this calculation.
!
latrad=dtr*rlat
lonrad=dtr*rlon
pixx=COS(lonrad)*COS(latrad)
pixy=SIN(lonrad)*COS(latrad)
pixz=SIN(latrad)
!
! Find angle between vectors
! satellite-to-pixel and center-of-earth-to-pixel
!
CALL deltaang((satx-pixx),(saty-pixy),(satz-pixz), &
pixx,pixy,pixz,delta)
emiss=halfpi-delta
!
! Find angle between vectors
! pixel-to-satellite and pixel-to-sun
!
CALL deltaang((pixx-satx),(pixy-saty),(pixz-satz), &
(pixx-solx),(pixy-soly),(pixz-solz),delta)
phase=AMAX1(AMIN1(halfpi,delta),0.)
!
! Phase angle correction term
!
altrad=dtr*alt
ph2=COS(phase)
ph2=ph2*ph2
phcor=20.*(ph2*ph2*ph2)*SQRT(COS(emiss))*(SIN(altrad))**0.25
!
! Stretching parameters
!
rout1=r01+a1*TANH(s1*dtr*(alt+da1))+phcor
rout2=r02+a2*TANH(s2*dtr*(alt+da2))+phcor
ELSE
rout1=r31
rout2=r41
END IF
RETURN
ENTRY solrsc1(britin,rin11,rin21,britout)
britout=nint(r31+(FLOAT(britin)-rin11)*r41mr31/(rin21-rin11))
britout=MIN(britout,255)
britout=MAX(britout,0)
RETURN
ENTRY solrsc2(britin,rin12,rin22,britout)
britout= &
nint(r32+(FLOAT(britin)-4*rin12)*r42mr32/(4*(rin22-rin12)))
britout=MIN(britout,1023)
britout=MAX(britout,0)
RETURN
!
ENTRY solcorset(i4time,latsat,lonsat,rangesat)
!
pi=4.*ATAN(1.)
dtr=pi/180.
rtd=180./pi
halfpi=0.5*pi
s1=arctanh((r31-r01)/a1)/(dtr*(58.+da1))
s2=arctanh((r41-r02)/a2)/(dtr*(58.+da2))
PRINT *, ' Solcorset s1= ',s1,' s2= ',s2
!
CALL solar_pos(0.,0.,i4time,alt,dec,hrangle)
decrad=dtr*dec
hrangrad=dtr*hrangle
solx=COS(-hrangrad)*COS(decrad)*aunor
soly=SIN(-hrangrad)*COS(decrad)*aunor
solz=SIN(decrad)*aunor
!
latrad=dtr*latsat
lonrad=dtr*lonsat
rnor=rangesat/eradius
satx=COS(lonrad)*COS(latrad)*rnor
saty=SIN(lonrad)*COS(latrad)*rnor
satz=SIN(latrad)*rnor
RETURN
END SUBROUTINE solcor
!
SUBROUTINE deltaang(x1,y1,z1,x2,y2,z2,delta) 4
IMPLICIT NONE
REAL :: x1,y1,z1,x2,y2,z2,delta
!
REAL :: vmag1,vmag2,vmag3,x3,y3,z3
REAL :: dotp,sindel,cosdel
!
vmag1=x1*x1+y1*y1+z1*z1
vmag2=x2*x2+y2*y2+z2*z2
x3=y1*z2 - z1*y2
y3=z1*x2 - x1*z2
z3=x1*y2 - y1*x2
vmag3=x3*x3+y3*y3+z3*z3
dotp=x1*x2+y1*y2+z1*z2
sindel=vmag3/(vmag1*vmag2)
cosdel=dotp/(vmag1*vmag2)
delta=ATAN2(sindel,cosdel)
RETURN
END SUBROUTINE deltaang