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element6.for
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element6.for
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c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c ELEMENT6.FOR (ErikSoft 5 June 2001)
c
c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c Author: John E. Chambers
c
c Makes output files containing Keplerian orbital elements from data created
c by Mercury6 and higher.
c
c The user specifies the names of the required objects in the file elements.in
c See subroutine M_FORMAT for the identities of each element in the EL array
c e.g. el(1)=a, el(2)=e etc.
c
c------------------------------------------------------------------------------
c
implicit none
include 'mercury.inc'
c
integer itmp,i,j,k,l,iback(NMAX),precision,lenin
integer nmaster,nopen,nwait,nbig,nsml,nbod,nsub,lim(2,100)
integer year,month,timestyle,line_num,lenhead,lmem(NMESS)
integer nchar,algor,centre,allflag,firstflag,ninfile,nel,iel(22)
integer nbod1,nbig1,unit(NMAX),code(NMAX),master_unit(NMAX)
real*8 time,teval,t0,t1,tprevious,rmax,rcen,rfac,rhocgs,temp
real*8 mcen,jcen(3),el(22,NMAX),s(3),is(NMAX),ns(NMAX),a(NMAX)
real*8 mio_c2re, mio_c2fl,fr,theta,phi,fv,vtheta,vphi,gm
real*8 x(3,NMAX),v(3,NMAX),xh(3,NMAX),vh(3,NMAX),m(NMAX)
logical test
character*250 string,fout,header,infile(50)
character*80 mem(NMESS),cc,c(NMAX)
character*8 master_id(NMAX),id(NMAX)
character*5 fin
character*1 check,style,type,c1
character*2 c2
c
c------------------------------------------------------------------------------
c
allflag = 0
tprevious = 0.d0
rhocgs = AU * AU * AU * K2 / MSUN
c
c Read in output messages
inquire (file='message.in', exist=test)
if (.not.test) then
write (*,'(/,2a)') ' ERROR: This file is needed to continue: ',
% ' message.in'
stop
end if
open (14, file='message.in', status='old')
10 continue
read (14,'(i3,1x,i2,1x,a80)',end=20) j,lmem(j),mem(j)
goto 10
20 close (14)
c
c Open file containing parameters for this programme
inquire (file='element.in', exist=test)
if (test) then
open (10, file='element.in', status='old')
else
call mio_err (6,mem(81),lmem(81),mem(88),lmem(88),' ',1,
% 'element.in',9)
end if
c
c Read number of input files
30 read (10,'(a250)') string
if (string(1:1).eq.')') goto 30
call mio_spl (250,string,nsub,lim)
read (string(lim(1,nsub):lim(2,nsub)),*) ninfile
c
c Make sure all the input files exist
do j = 1, ninfile
40 read (10,'(a250)') string
if (string(1:1).eq.')') goto 40
call mio_spl (250,string,nsub,lim)
infile(j)(1:(lim(2,1)-lim(1,1)+1)) = string(lim(1,1):lim(2,1))
inquire (file=infile(j), exist=test)
if (.not.test) call mio_err (6,mem(81),lmem(81),mem(88),
% lmem(88),' ',1,infile(j),80)
end do
c
c What type elements does the user want?
centre = 0
45 read (10,'(a250)') string
if (string(1:1).eq.')') goto 45
call mio_spl (250,string,nsub,lim)
c2 = string(lim(1,nsub):(lim(1,nsub)+1))
if (c2.eq.'ce'.or.c2.eq.'CE'.or.c2.eq.'Ce') then
centre = 0
else if (c2.eq.'ba'.or.c2.eq.'BA'.or.c2.eq.'Ba') then
centre = 1
else if (c2.eq.'ja'.or.c2.eq.'JA'.or.c2.eq.'Ja') then
centre = 2
else
call mio_err (6,mem(81),lmem(81),mem(107),lmem(107),' ',1,
% ' Check element.in',23)
end if
c
c Read parameters used by this programme
timestyle = 1
do j = 1, 4
50 read (10,'(a250)') string
if (string(1:1).eq.')') goto 50
call mio_spl (250,string,nsub,lim)
c1 = string(lim(1,nsub):lim(2,nsub))
if (j.eq.1) read (string(lim(1,nsub):lim(2,nsub)),*) teval
teval = abs(teval) * .999d0
if (j.eq.2.and.(c1.eq.'d'.or.c1.eq.'D')) timestyle = 0
if (j.eq.3.and.(c1.eq.'y'.or.c1.eq.'Y')) timestyle = timestyle+2
if (j.eq.4) call m_format (string,timestyle,nel,iel,fout,header,
% lenhead)
end do
c
c Read in the names of the objects for which orbital elements are required
nopen = 0
nwait = 0
nmaster = 0
60 continue
read (10,'(a250)',end=70) string
call mio_spl (250,string,nsub,lim)
if (string(1:1).eq.')'.or.lim(1,1).eq.-1) goto 60
c
c Either open an aei file for this object or put it on the waiting list
nmaster = nmaster + 1
itmp = min(7,lim(2,1)-lim(1,1))
master_id(nmaster)=' '
master_id(nmaster)(1:itmp+1) = string(lim(1,1):lim(1,1)+itmp)
if (nopen.lt.NFILES) then
nopen = nopen + 1
master_unit(nmaster) = 10 + nopen
call mio_aei (master_id(nmaster),'.aei',master_unit(nmaster),
% header,lenhead,mem,lmem)
else
nwait = nwait + 1
master_unit(nmaster) = -2
end if
goto 60
c
70 continue
c If no objects are listed in ELEMENT.IN assume that all objects are required
if (nopen.eq.0) allflag = 1
close (10)
c
c------------------------------------------------------------------------------
c
c LOOP OVER EACH INPUT FILE CONTAINING INTEGRATION DATA
c
90 continue
firstflag = 0
do i = 1, ninfile
line_num = 0
open (10, file=infile(i), status='old')
c
c Loop over each time slice
100 continue
line_num = line_num + 1
read (10,'(3a1)',end=900,err=666) check,style,type
line_num = line_num - 1
backspace 10
c
c Check if this is an old style input file
if (ichar(check).eq.12.and.(style.eq.'0'.or.style.eq.'1'.or.
% style.eq.'2'.or.style.eq.'3'.or.style.eq.'4')) then
write (*,'(/,2a)') ' ERROR: This is an old style data file',
% ' Try running m_elem5.for instead.'
stop
end if
if (ichar(check).ne.12) goto 666
c
c------------------------------------------------------------------------------
c
c IF SPECIAL INPUT, READ TIME, PARAMETERS, NAMES, MASSES ETC.
c
if (type.eq.'a') then
line_num = line_num + 1
read (10,'(3x,i2,a62,i1)') algor,cc(1:62),precision
c
c Decompress the time, number of objects, central mass and J components etc.
time = mio_c2fl (cc(1:8))
nbig = int(.5d0 + mio_c2re(cc(9:16), 0.d0, 11239424.d0, 3))
nsml = int(.5d0 + mio_c2re(cc(12:19),0.d0, 11239424.d0, 3))
mcen = mio_c2fl (cc(15:22))
jcen(1) = mio_c2fl (cc(23:30))
jcen(2) = mio_c2fl (cc(31:38))
jcen(3) = mio_c2fl (cc(39:46))
rcen = mio_c2fl (cc(47:54))
rmax = mio_c2fl (cc(55:62))
rfac = log10 (rmax / rcen)
c
c Read in strings containing compressed data for each object
do j = 1, nbig + nsml
line_num = line_num + 1
read (10,'(a)',err=666) c(j)(1:51)
end do
c
c Create input format list
if (precision.eq.1) nchar = 2
if (precision.eq.2) nchar = 4
if (precision.eq.3) nchar = 7
lenin = 3 + 6 * nchar
fin(1:5) = '(a00)'
write (fin(3:4),'(i2)') lenin
c
c For each object decompress its name, code number, mass, spin and density
do j = 1, nbig + nsml
k = int(.5d0 + mio_c2re(c(j)(1:8),0.d0,11239424.d0,3))
id(k) = c(j)(4:11)
el(18,k) = mio_c2fl (c(j)(12:19))
s(1) = mio_c2fl (c(j)(20:27))
s(2) = mio_c2fl (c(j)(28:35))
s(3) = mio_c2fl (c(j)(36:43))
el(21,k) = mio_c2fl (c(j)(44:51))
c
c Calculate spin rate and longitude & inclination of spin vector
temp = sqrt(s(1)*s(1) + s(2)*s(2) + s(3)*s(3))
if (temp.gt.0) then
call mce_spin (1.d0,el(18,k)*K2,temp*K2,el(21,k)*
% rhocgs,el(20,k))
temp = s(3) / temp
if (abs(temp).lt.1) then
is(k) = acos (temp)
ns(k) = atan2 (s(1), -s(2))
else
if (temp.gt.0) is(k) = 0.d0
if (temp.lt.0) is(k) = PI
ns(k) = 0.d0
end if
else
el(20,k) = 0.d0
is(k) = 0.d0
ns(k) = 0.d0
end if
c
c Find the object on the master list
unit(k) = 0
do l = 1, nmaster
if (id(k).eq.master_id(l)) unit(k) = master_unit(l)
end do
c
c If object is not on the master list, add it to the list now
if (unit(k).eq.0) then
nmaster = nmaster + 1
master_id(nmaster) = id(k)
c
c Either open an aei file for this object or put it on the waiting list
if (allflag.eq.1) then
if (nopen.lt.NFILES) then
nopen = nopen + 1
master_unit(nmaster) = 10 + nopen
call mio_aei (master_id(nmaster),'.aei',
% master_unit(nmaster),header,lenhead,mem,lmem)
else
nwait = nwait + 1
master_unit(nmaster) = -2
end if
else
master_unit(nmaster) = -1
end if
unit(k) = master_unit(nmaster)
end if
end do
c
c------------------------------------------------------------------------------
c
c IF NORMAL INPUT, READ COMPRESSED ORBITAL VARIABLES FOR ALL OBJECTS
c
else if (type.eq.'b') then
line_num = line_num + 1
read (10,'(3x,a14)',err=666) cc(1:14)
c
c Decompress the time and the number of objects
time = mio_c2fl (cc(1:8))
nbig = int(.5d0 + mio_c2re(cc(9:16), 0.d0, 11239424.d0, 3))
nsml = int(.5d0 + mio_c2re(cc(12:19), 0.d0, 11239424.d0, 3))
nbod = nbig + nsml
if (firstflag.eq.0) t0 = time
c
c Read in strings containing compressed data for each object
do j = 1, nbod
line_num = line_num + 1
read (10,fin,err=666) c(j)(1:lenin)
end do
c
c Look for objects for which orbital elements are required
m(1) = mcen * K2
do j = 1, nbod
code(j) = int(.5d0 + mio_c2re(c(j)(1:8), 0.d0,
% 11239424.d0, 3))
if (code(j).gt.NMAX) then
write (*,'(/,2a)') mem(81)(1:lmem(81)),
% mem(90)(1:lmem(90))
stop
end if
c
c Decompress orbital variables for each object
l = j + 1
m(l) = el(18,code(j)) * K2
fr = mio_c2re (c(j)(4:11), 0.d0, rfac, nchar)
theta = mio_c2re (c(j)(4+ nchar:11+ nchar), 0.d0, PI,
% nchar)
phi = mio_c2re (c(j)(4+2*nchar:11+2*nchar), 0.d0, TWOPI,
% nchar)
fv = mio_c2re (c(j)(4+3*nchar:11+3*nchar), 0.d0, 1.d0,
% nchar)
vtheta = mio_c2re (c(j)(4+4*nchar:11+4*nchar), 0.d0, PI,
% nchar)
vphi = mio_c2re (c(j)(4+5*nchar:11+5*nchar), 0.d0, TWOPI,
% nchar)
call mco_ov2x (rcen,rmax,m(1),m(l),fr,theta,phi,fv,
% vtheta,vphi,x(1,l),x(2,l),x(3,l),v(1,l),v(2,l),v(3,l))
el(16,code(j)) = sqrt(x(1,l)*x(1,l) + x(2,l)*x(2,l)
% + x(3,l)*x(3,l))
end do
c
c Convert to barycentric, Jacobi or close-binary coordinates if desired
nbod1 = nbod + 1
nbig1 = nbig + 1
call mco_iden (jcen,nbod1,nbig1,temp,m,x,v,xh,vh)
if (centre.eq.1) call mco_h2b (jcen,nbod1,nbig1,temp,m,xh,vh,
% x,v)
if (centre.eq.2) call mco_h2j (jcen,nbod1,nbig1,temp,m,xh,vh,
% x,v)
if (centre.eq.0.and.algor.eq.11) call mco_h2cb (jcen,nbod1,
% nbig1,temp,m,xh,vh,x,v)
c
c Put Cartesian coordinates into element arrays
do j = 1, nbod
k = code(j)
l = j + 1
el(10,k) = x(1,l)
el(11,k) = x(2,l)
el(12,k) = x(3,l)
el(13,k) = v(1,l)
el(14,k) = v(2,l)
el(15,k) = v(3,l)
c
c Convert to Keplerian orbital elements
gm = (mcen + el(18,k)) * K2
call mco_x2el (gm,el(10,k),el(11,k),el(12,k),el(13,k),
% el(14,k),el(15,k),el(8,k),el(2,k),el(3,k),el(7,k),
% el(5,k),el(6,k))
el(1,k) = el(8,k) / (1.d0 - el(2,k))
el(9,k) = el(1,k) * (1.d0 + el(2,k))
el(4,k) = mod(el(7,k) - el(5,k) + TWOPI, TWOPI)
c Calculate true anomaly
if (el(2,k).eq.0) then
el(17,k) = el(6,k)
else
temp = (el(8,k)*(1.d0 + el(2,k))/el(16,k) - 1.d0) /el(2,k)
temp = sign (min(abs(temp), 1.d0), temp)
el(17,k) = acos(temp)
if (sin(el(6,k)).lt.0) el(17,k) = TWOPI - el(17,k)
end if
c Calculate obliquity
el(19,k) = acos (cos(el(3,k))*cos(is(k))
% + sin(el(3,k))*sin(is(k))*cos(ns(k) - el(5,k)))
c
c Convert angular elements from radians to degrees
do l = 3, 7
el(l,k) = mod(el(l,k) / DR, 360.d0)
end do
el(17,k) = el(17,k) / DR
el(19,k) = el(19,k) / DR
end do
c
c Convert time to desired format
if (timestyle.eq.0) t1 = time
if (timestyle.eq.1) call mio_jd_y (time,year,month,t1)
if (timestyle.eq.2) t1 = time - t0
if (timestyle.eq.3) t1 = (time - t0) / 365.25d0
c
c If output is required at this epoch, write elements to appropriate files
if (firstflag.eq.0.or.abs(time-tprevious).ge.teval) then
firstflag = 1
tprevious = time
c
c Write required elements to the appropriate aei file
do j = 1, nbod
k = code(j)
if (unit(k).ge.10) then
if (timestyle.eq.1) then
write (unit(k),fout) year,month,t1,(el(iel(l),k),l=1,
% nel)
else
write (unit(k),fout) t1,(el(iel(l),k),l=1,nel)
end if
end if
end do
end if
c
c------------------------------------------------------------------------------
c
c IF TYPE IS NOT 'a' OR 'b', THE INPUT FILE IS CORRUPTED
c
else
goto 666
end if
c
c Move on to the next time slice
goto 100
c
c If input file is corrupted, try to continue from next uncorrupted time slice
666 continue
write (*,'(2a,/,a,i10)') mem(121)(1:lmem(121)),
% infile(i)(1:60),mem(104)(1:lmem(104)),line_num
c1 = ' '
do while (ichar(c1).ne.12)
line_num = line_num + 1
read (10,'(a1)',end=900) c1
end do
line_num = line_num - 1
backspace 10
c
c Move on to the next file containing integration data
900 continue
close (10)
end do
c
c Close aei files
do j = 1, nopen
close (10+j)
end do
nopen = 0
c
c If some objects remain on waiting list, read through input files again
if (nwait.gt.0) then
do j = 1, nmaster
if (master_unit(j).ge.10) master_unit(j) = -1
if (master_unit(j).eq.-2.and.nopen.lt.NFILES) then
nopen = nopen + 1
nwait = nwait - 1
master_unit(j) = 10 + nopen
call mio_aei (master_id(j),'.aei',master_unit(j),header,
% lenhead,mem,lmem)
end if
end do
goto 90
end if
c
c------------------------------------------------------------------------------
c
c CREATE A SUMMARY OF FINAL MASSES AND ELEMENTS
c
open (10, file='element.out', status='unknown')
rewind 10
c
if (timestyle.eq.0.or.timestyle.eq.2) then
write (10,'(/,a,f18.5,/)') ' Time (days): ',t1
else if (timestyle.eq.1) then
write (10,'(/,a,i10,1x,i2,1x,f8.5,/)') ' Date: ',year,month,t1
else if (timestyle.eq.3) then
write (10,'(/,a,f18.7,/)') ' Time (years): ',t1
end if
write (10,'(2a,/)') ' a e i mass',
% ' Rot/day Obl'
c
c Sort surviving objects in order of increasing semi-major axis
do j = 1, nbod
k = code(j)
a(j) = el(1,k)
end do
call mxx_sort (nbod,a,iback)
c
c Write values of a, e, i and m for surviving objects in an output file
do j = 1, nbod
k = code(iback(j))
write (10,213) id(k),el(1,k),el(2,k),el(3,k),el(18,k),el(20,k),
% el(19,k)
end do
c
c------------------------------------------------------------------------------
c
c Format statements
213 format (1x,a8,1x,f8.4,1x,f7.5,1x,f7.3,1p,e11.4,0p,1x,f6.3,1x,f6.2)
c
end
c
c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c MCO_OV2X.FOR (ErikSoft 28 February 2001)
c
c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c Author: John E. Chambers
c
c Converts output variables for an object to coordinates and velocities.
c The output variables are:
c r = the radial distance
c theta = polar angle
c phi = azimuthal angle
c fv = 1 / [1 + 2(ke/be)^2], where be and ke are the object's binding and
c kinetic energies. (Note that 0 < fv < 1).
c vtheta = polar angle of velocity vector
c vphi = azimuthal angle of the velocity vector
c
c------------------------------------------------------------------------------
c
subroutine mco_ov2x (rcen,rmax,mcen,m,fr,theta,phi,fv,vtheta,
% vphi,x,y,z,u,v,w)
c
implicit none
include 'mercury.inc'
c
c Input/Output
real*8 rcen,rmax,mcen,m,x,y,z,u,v,w,fr,theta,phi,fv,vtheta,vphi
c
c Local
real*8 r,v1,temp
c
c------------------------------------------------------------------------------
c
r = rcen * 10.d0**fr
temp = sqrt(.5d0*(1.d0/fv - 1.d0))
v1 = sqrt(2.d0 * temp * (mcen + m) / r)
c
x = r * sin(theta) * cos(phi)
y = r * sin(theta) * sin(phi)
z = r * cos(theta)
u = v1 * sin(vtheta) * cos(vphi)
v = v1 * sin(vtheta) * sin(vphi)
w = v1 * cos(vtheta)
c
c------------------------------------------------------------------------------
c
return
end
c
c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c MCE_SPIN.FOR (ErikSoft 2 December 1999)
c
c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c Author: John E. Chambers
c
c Calculates the spin rate (in rotations per day) for a fluid body given
c its mass, spin angular momentum and density. The routine assumes the
c body is a MacClaurin ellipsoid, whose axis ratio is defined by the
c quantity SS = SQRT(A^2/C^2 - 1), where A and C are the
c major and minor axes.
c
c------------------------------------------------------------------------------
c
subroutine mce_spin (g,mass,spin,rho,rote)
c
implicit none
include 'mercury.inc'
c
c Input/Output
real*8 g,mass,spin,rho,rote
c
c Local
integer k
real*8 ss,s2,f,df,z,dz,tmp0,tmp1,t23
c
c------------------------------------------------------------------------------
c
t23 = 2.d0 / 3.d0
tmp1 = spin * spin / (2.d0 * PI * rho * g)
% * ( 250.d0*PI*PI*rho*rho / (9.d0*mass**5) )**t23
c
c Calculate SS using Newton's method
ss = 1.d0
do k = 1, 20
s2 = ss * ss
tmp0 = (1.d0 + s2)**t23
call m_sfunc (ss,z,dz)
f = z * tmp0 - tmp1
df = tmp0 * ( dz + 4.d0 * ss * z / (3.d0*(1.d0 + s2)) )
ss = ss - f/df
end do
c
rote = sqrt(TWOPI * g * rho * z) / TWOPI
c
c------------------------------------------------------------------------------
c
return
end
c
c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c MCO_EL2X.FOR (ErikSoft 7 July 1999)
c
c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c Author: John E. Chambers
c
c Calculates Cartesian coordinates and velocities given Keplerian orbital
c elements (for elliptical, parabolic or hyperbolic orbits).
c
c Based on a routine from Levison and Duncan's SWIFT integrator.
c
c mu = grav const * (central + secondary mass)
c q = perihelion distance
c e = eccentricity
c i = inclination )
c p = longitude of perihelion !!! ) in
c n = longitude of ascending node ) radians
c l = mean anomaly )
c
c x,y,z = Cartesian positions ( units the same as a )
c u,v,w = " velocities ( units the same as sqrt(mu/a) )
c
c------------------------------------------------------------------------------
c
subroutine mco_el2x (mu,q,e,i,p,n,l,x,y,z,u,v,w)
c
implicit none
include 'mercury.inc'
c
c Input/Output
real*8 mu,q,e,i,p,n,l,x,y,z,u,v,w
c
c Local
real*8 g,a,ci,si,cn,sn,cg,sg,ce,se,romes,temp
real*8 z1,z2,z3,z4,d11,d12,d13,d21,d22,d23
real*8 mco_kep, orbel_fhybrid, orbel_zget
c
c------------------------------------------------------------------------------
c
c Change from longitude of perihelion to argument of perihelion
g = p - n
c
c Rotation factors
call mco_sine (i,si,ci)
call mco_sine (g,sg,cg)
call mco_sine (n,sn,cn)
z1 = cg * cn
z2 = cg * sn
z3 = sg * cn
z4 = sg * sn
d11 = z1 - z4*ci
d12 = z2 + z3*ci
d13 = sg * si
d21 = -z3 - z2*ci
d22 = -z4 + z1*ci
d23 = cg * si
c
c Semi-major axis
a = q / (1.d0 - e)
c
c Ellipse
if (e.lt.1.d0) then
romes = sqrt(1.d0 - e*e)
temp = mco_kep (e,l)
call mco_sine (temp,se,ce)
z1 = a * (ce - e)
z2 = a * romes * se
temp = sqrt(mu/a) / (1.d0 - e*ce)
z3 = -se * temp
z4 = romes * ce * temp
else
c Parabola
if (e.eq.1.d0) then
ce = orbel_zget(l)
z1 = q * (1.d0 - ce*ce)
z2 = 2.d0 * q * ce
z4 = sqrt(2.d0*mu/q) / (1.d0 + ce*ce)
z3 = -ce * z4
else
c Hyperbola
romes = sqrt(e*e - 1.d0)
temp = orbel_fhybrid(e,l)
call mco_sinh (temp,se,ce)
z1 = a * (ce - e)
z2 = -a * romes * se
temp = sqrt(mu/abs(a)) / (e*ce - 1.d0)
z3 = -se * temp
z4 = romes * ce * temp
end if
endif
c
x = d11*z1 + d21*z2
y = d12*z1 + d22*z2
z = d13*z1 + d23*z2
u = d11*z3 + d21*z4
v = d12*z3 + d22*z4
w = d13*z3 + d23*z4
c
c------------------------------------------------------------------------------
c
return
end
c
c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c MCO_KEP.FOR (ErikSoft 7 July 1999)
c
c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c Author: John E. Chambers
c
c Solves Kepler's equation for eccentricities less than one.
c Algorithm from A. Nijenhuis (1991) Cel. Mech. Dyn. Astron. 51, 319-330.
c
c e = eccentricity
c l = mean anomaly (radians)
c u = eccentric anomaly ( " )
c
c------------------------------------------------------------------------------
c
function mco_kep (e,oldl)
implicit none
c
c Input/Outout
real*8 oldl,e,mco_kep
c
c Local
real*8 l,pi,twopi,piby2,u1,u2,ome,sign
real*8 x,x2,sn,dsn,z1,z2,z3,f0,f1,f2,f3
real*8 p,q,p2,ss,cc
logical flag,big,bigg
c
c------------------------------------------------------------------------------
c
pi = 3.141592653589793d0
twopi = 2.d0 * pi
piby2 = .5d0 * pi
c
c Reduce mean anomaly to lie in the range 0 < l < pi
if (oldl.ge.0) then
l = mod(oldl, twopi)
else
l = mod(oldl, twopi) + twopi
end if
sign = 1.d0
if (l.gt.pi) then
l = twopi - l
sign = -1.d0
end if
c
ome = 1.d0 - e
c
if (l.ge..45d0.or.e.lt..55d0) then
c
c Regions A,B or C in Nijenhuis
c -----------------------------
c
c Rough starting value for eccentric anomaly
if (l.lt.ome) then
u1 = ome
else
if (l.gt.(pi-1.d0-e)) then
u1 = (l+e*pi)/(1.d0+e)
else
u1 = l + e
end if
end if
c
c Improved value using Halley's method
flag = u1.gt.piby2
if (flag) then
x = pi - u1
else
x = u1
end if
x2 = x*x
sn = x*(1.d0 + x2*(-.16605 + x2*.00761) )
dsn = 1.d0 + x2*(-.49815 + x2*.03805)
if (flag) dsn = -dsn
f2 = e*sn
f0 = u1 - f2 - l
f1 = 1.d0 - e*dsn
u2 = u1 - f0/(f1 - .5d0*f0*f2/f1)
else
c
c Region D in Nijenhuis
c ---------------------
c
c Rough starting value for eccentric anomaly
z1 = 4.d0*e + .5d0
p = ome / z1
q = .5d0 * l / z1
p2 = p*p
z2 = exp( log( dsqrt( p2*p + q*q ) + q )/1.5 )
u1 = 2.d0*q / ( z2 + p + p2/z2 )
c
c Improved value using Newton's method
z2 = u1*u1
z3 = z2*z2
u2 = u1 - .075d0*u1*z3 / (ome + z1*z2 + .375d0*z3)
u2 = l + e*u2*( 3.d0 - 4.d0*u2*u2 )
end if
c
c Accurate value using 3rd-order version of Newton's method
c N.B. Keep cos(u2) rather than sqrt( 1-sin^2(u2) ) to maintain accuracy!
c
c First get accurate values for u2 - sin(u2) and 1 - cos(u2)
bigg = (u2.gt.piby2)
if (bigg) then
z3 = pi - u2
else
z3 = u2
end if
c
big = (z3.gt.(.5d0*piby2))
if (big) then
x = piby2 - z3
else
x = z3
end if
c
x2 = x*x
ss = 1.d0
cc = 1.d0
c
ss = x*x2/6.*(1. - x2/20.*(1. - x2/42.*(1. - x2/72.*(1. -
% x2/110.*(1. - x2/156.*(1. - x2/210.*(1. - x2/272.)))))))
cc = x2/2.*(1. - x2/12.*(1. - x2/30.*(1. - x2/56.*(1. -
% x2/ 90.*(1. - x2/132.*(1. - x2/182.*(1. - x2/240.*(1. -
% x2/306.))))))))
c
if (big) then
z1 = cc + z3 - 1.d0
z2 = ss + z3 + 1.d0 - piby2
else
z1 = ss
z2 = cc
end if
c
if (bigg) then
z1 = 2.d0*u2 + z1 - pi
z2 = 2.d0 - z2
end if
c
f0 = l - u2*ome - e*z1
f1 = ome + e*z2
f2 = .5d0*e*(u2-z1)
f3 = e/6.d0*(1.d0-z2)
z1 = f0/f1
z2 = f0/(f2*z1+f1)
mco_kep = sign*( u2 + f0/((f3*z1+f2)*z2+f1) )
c
c------------------------------------------------------------------------------
c
return
end
c
c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c MCO_SINE.FOR (ErikSoft 17 April 1997)
c
c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c Author: John E. Chambers
c
c Calculates sin and cos of an angle X (in radians).
c
c------------------------------------------------------------------------------
c
subroutine mco_sine (x,sx,cx)
c
implicit none
c
c Input/Output
real*8 x,sx,cx
c
c Local
real*8 pi,twopi
c
c------------------------------------------------------------------------------
c
pi = 3.141592653589793d0
twopi = 2.d0 * pi
c
if (x.gt.0) then
x = mod(x,twopi)
else
x = mod(x,twopi) + twopi
end if
c
cx = cos(x)
c
if (x.gt.pi) then
sx = -sqrt(1.d0 - cx*cx)
else
sx = sqrt(1.d0 - cx*cx)
end if
c
c------------------------------------------------------------------------------
c
return
end
c
c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c MCO_SINH.FOR (ErikSoft 12 June 1998)
c
c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c Calculates sinh and cosh of an angle X (in radians)
c
c------------------------------------------------------------------------------
c
subroutine mco_sinh (x,sx,cx)
c
implicit none
c
c Input/Output
real*8 x,sx,cx
c
c------------------------------------------------------------------------------
c
sx = sinh(x)
cx = sqrt (1.d0 + sx*sx)
c
c------------------------------------------------------------------------------
c
return
end
c
c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c MIO_AEI.FOR (ErikSoft 31 January 2001)
c
c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c Author: John E. Chambers
c
c Creates a filename and opens a file to store aei information for an object.
c The filename is based on the name of the object.
c
c------------------------------------------------------------------------------
c
subroutine mio_aei (id,extn,unitnum,header,lenhead,mem,lmem)
c
implicit none
include 'mercury.inc'
c
c Input/Output
integer unitnum,lenhead,lmem(NMESS)
character*4 extn
character*8 id
character*250 header
character*80 mem(NMESS)
c
c Local
integer j,k,itmp,nsub,lim(2,4)
logical test
character*1 bad(5)
character*250 filename
c
c------------------------------------------------------------------------------
c
data bad/ '*', '/', '.', ':', '&'/
c
c Create a filename based on the object's name
call mio_spl (8,id,nsub,lim)
itmp = min(7,lim(2,1)-lim(1,1))
filename(1:itmp+1) = id(1:itmp+1)
filename(itmp+2:itmp+5) = extn
do j = itmp + 6, 250
filename(j:j) = ' '
end do
c
c Check for inappropriate characters in the filename
do j = 1, itmp + 1
do k = 1, 5
if (filename(j:j).eq.bad(k)) filename(j:j) = '_'
end do
end do
c
c If the file exists already, give a warning and don't overwrite it
inquire (file=filename, exist=test)
if (test) then
write (*,'(/,3a)') mem(121)(1:lmem(121)),mem(87)(1:lmem(87)),
% filename(1:80)
unitnum = -1
else
open (unitnum, file=filename, status='new')
write (unitnum, '(/,30x,a8,//,a)') id,header(1:lenhead)
end if
c
c------------------------------------------------------------------------------
c
return
end
c
c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c MIO_C2FL.FOR (ErikSoft 5 June 2001)
c
c%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
c
c CHARACTER*8 ASCII string into a REAL*8 variable.
c
c N.B. X will lie in the range -1.e112 < X < 1.e112
c ===
c
c------------------------------------------------------------------------------
c
function mio_c2fl (c)
c
implicit none
c
c Input/Output
real*8 mio_c2fl
character*8 c
c