From 42edf57945938aaa5c9e5001d597ae0d876d1fac Mon Sep 17 00:00:00 2001
From: git archive service user <gitarchive@PangLong.dragons>
Date: Sun, 29 Dec 2019 19:04:03 +0100
Subject: [PATCH 1/1] Initial commit by marcello Galli

---
 LICENSE             |    1 +
 README.md           |   42 +
 code/a93_poster.pdf |  Bin 0 -> 50830 bytes
 code/a93sait.pdf    |  Bin 0 -> 121135 bytes
 code/cbs.exe        |  Bin 0 -> 89088 bytes
 code/cbs.for        | 6256 +++++++++++++++++++++++++++++++++++++++++++
 code/f.tex          |  203 ++
 code/missfont.log   |    8 +
 code/test1.com      |   44 +
 code/test2.com      |   71 +
 code/test3.com      |   51 +
 code/test4.com      |   58 +
 code/test5.com      |   94 +
 code/test6.com      |   99 +
 code/test7.com      |  107 +
 code/test9.com      |  149 ++
 code/test9.log      |  556 ++++
 code/vt3.com        |  114 +
 code/vt3.log        |  759 ++++++
 codemeta.json       |   36 +
 20 files changed, 8648 insertions(+)
 create mode 100644 LICENSE
 create mode 100644 README.md
 create mode 100644 code/a93_poster.pdf
 create mode 100644 code/a93sait.pdf
 create mode 100755 code/cbs.exe
 create mode 100755 code/cbs.for
 create mode 100755 code/f.tex
 create mode 100644 code/missfont.log
 create mode 100755 code/test1.com
 create mode 100755 code/test2.com
 create mode 100755 code/test3.com
 create mode 100755 code/test4.com
 create mode 100755 code/test5.com
 create mode 100755 code/test6.com
 create mode 100755 code/test7.com
 create mode 100755 code/test9.com
 create mode 100755 code/test9.log
 create mode 100755 code/vt3.com
 create mode 100755 code/vt3.log
 create mode 100644 codemeta.json

diff --git a/LICENSE b/LICENSE
new file mode 100644
index 0000000..f9c9132
--- /dev/null
+++ b/LICENSE
@@ -0,0 +1 @@
+This software is in the public domain. 
diff --git a/README.md b/README.md
new file mode 100644
index 0000000..653f12b
--- /dev/null
+++ b/README.md
@@ -0,0 +1,42 @@
+cbs
+===
+
+Close Binary System Light Curve Analysis Program
+---------------------------------------------------
+
+This is a VAX FORTRAN code, written between 1991 and 1993,
+for close binary system light curve simulation.
+It consider many effects; the Roche lobe shapes 
+where carefully drawn and a tiny accretion disk is accounted for.
+
+The program was written between 1991 and 1993,
+by Marcello Galli, it consists of about six thousand lines, 
+and run on a VAX/VMS mini computer.  
+
+It was presented at the poster section of the 
+1993 Italian Astronet Meeting in Trieste,
+(see Mem. Sait. vol XX,1993), but hadn't
+many users.
+ 
+The program needed 40 or 60 MBytes of RAM;
+it was a big number for that days, more than
+available on many VMS workstations. 
+The trick was to alter the the page file quota
+for a single process, sometimes  causing 
+a computer crash.
+
+
+In the code folder we have:
+
+- cbs.for : the source code
+- cbs.exe : executable for VAX/VMS
+- some input for tests (.com files)
+- test9.log,vt3.log: examples of an interactive sessions.
+ 
+- a93sait.pdf : the paper on "Memorie della SAIT" 
+- a93_poster.pdf : the text for the poster (without figures)
+
+
+It is here as an example of VAX FORTRAN usage,
+to be included in the collection of the 
+[*Software Heritage*] project (https://www.softwareheritage.org/). 
diff --git a/code/a93_poster.pdf b/code/a93_poster.pdf
new file mode 100644
index 0000000000000000000000000000000000000000..99f0ee8fe4fb24f9a015eae9aefd340f63624add
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diff --git a/code/a93sait.pdf b/code/a93sait.pdf
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diff --git a/code/cbs.exe b/code/cbs.exe
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diff --git a/code/cbs.for b/code/cbs.for
new file mode 100755
index 0000000..699b79d
--- /dev/null
+++ b/code/cbs.for
@@ -0,0 +1,6256 @@
+C        Last update:  8-4-1993    ore 17:20
+C             -  Version 0.0 - Debbugging in progress
+C      Stato attuale:
+C      -  Questa versione ha un disco e 2 sfere o roche,
+C        senza grafica, limb darkening non testato, senza common envelope.
+C        Debbugging in corso.
+C       -------------------------------------------------------------
+C       History: 
+C       february 1993 : performing test 8 - test 9 
+C       1-3-1993      : changed omega definition to omega-q**2/2/(1+q)
+C       -------------------------------------------------------------
+C      ***********************************************************
+C
+C               CCCCCC       BBBBBB            SSSSS
+C               CC           BB    B          S
+C               CC           BBBBBB            SS
+C               CC           BB    B             S
+C               CCCCCC       BBBBBB         SSSSS
+C
+C
+C            C L O S E     B I N A R Y    S Y S T E M
+C             
+C      L I G T H    C U R V E   A N A L Y S I S    P R O G R A M
+C             
+C      ***********************************************************
+C                   Marcello Galli - Loretta Solmi
+C      ***********************************************************
+C
+C      Version 0.0 :   14-5-1991 : writing in progress
+C
+C      ***********************************************************
+C
+C      Given the parameters of the bynary system, this program
+C      computes the light  curve for given colors, accounting
+C      for limb darkening, gravity darkening and  reflection
+C      effects. 
+C      It is possible to simulate the presence of a disk around
+C      one component of the system.
+C
+C      *****************************************************************
+C      Units:   CGS, 
+C      For Roche model the unit distance is the distance between stars A-B
+C      Intensity : erg/sec/cm**2/sterad , 
+C                F = ca/4pi T**4 * area = erg/sec/sterad
+C                with c*a/(4*pi)=1.8065 erg/sec/cm**2/K**4/sterad
+C      to shorten calculations i should use adimensional units.
+C      -----------------------------------------------------------------
+C      Note per la messa a punto:
+C      -  Ci sono ridondanze nel common /allin/:
+C        Rxij,Ryij,Rzij, iaus usati solo fino a call CALCALL escluso;
+C        Xcosgi,fsour usati solo da CALCALL compresa in poi. 
+C      -   Qualcosa in LUCE1 puo' essere messo integer*2 (IGAINED,ilost)
+C      -  Il problema principale sono i tempi di esecuzione della riflessione
+C         sto cercando di usare un doppio grid (fine per eclisse, coarse per
+C         riflessione) in modo da abbreviare il tempo di calcolo della 
+C         riflessione. I path sono moltissimi, per una stella descritta
+C         da un 10000 surf.elem.,ove eclisse e' precisa piu' di qualche %,
+C         si va sul mezzo milione di paths,ci si sta a fatica anche come spazio.
+C         Poiche' la riflessione per 2 stelle eguali a contatto va sul
+C         3-4 % della luce dell'oggetto, diminuire il numero di punti
+C         per la riflessione di un ordine di grandezza potrebbe andare.
+C         Le subroutine di riflessione hanno tempo ed ingombro accettabile
+C         per oggetti descritti da circa un 100 surface elements.
+C         Altro modo di ridurre i punti e' usare surf. elements con 
+C         egual area uinvece che egual numero di fi per ogni theta.
+C         Questo riduce il numero di punti di circa 1/3, a parita'
+C         di precisione.
+C      -  L'inserimento in un metodo di minimo totale puo' consistere
+C        nel trasformare il main , dal 300 continue in poi,
+C        in una routine, chiamata dalla subroutine di minimo, che
+C        lo pilota tramite i flags e parametri, a seconda di cosa cambia
+C        nel modello; ma i parametri e flags non sono ben pensati
+C        per questo uso.
+C      - Benche' parte del programma sia predisposta per un calcolo
+C        su diverse bande di luce, la riflessione tratta per ora
+C        solo il bolometrico.
+C        qui non mi e' chiaro come procedere; ora con la riflessione
+C        potrei (ma non ancora c'e') aumentare o T e poi ricalcolare
+C         i flussi della banda; oppure,
+C        nel caso in cui do' in input il flusso di ogni banda, 
+C        divido il flusso bol.+riflesso bol. nelle bande secondo l'input.
+C        PER QUANTO RIGUARDA L'ALBEDO abbiamo una ALBEDO eguale per
+C        ogni oggetto (PAR(ippar(9))) che e' semplicemente un flag, che
+C        andando da 0 ad 1 attenua l'effetto della riflessione ed
+C        una albedo (PARS(12,IS)), definita per ogni oggetto,
+C        che fa la stessa cosa. Potra' essere comodo in input, ma
+C        averne 2 intruduce un conto in piu' in un punto critico del programma.
+C        Conviene fare una riflessione con albedo dipendente dall'oggetto
+C        e dal colore? Questo equivale ad  un modello
+C        di atmosfera e non ne so molto.
+C      - Gli elementi di superficie sono in una unica lista,
+C        indipendentemente dalla stella cui appartengono, a parte
+C        il risparmio di spazio, serve a qualcosa cio', visto che
+C        spesso tratto oggetto per oggetto e devo portarmi dietro
+C        una collezione di puntatori per sapere dove iniziano e finiscono? 
+C      - Spazi ausiliari probabilmente ridondanti:IAUS,NUMOBJ,AUS,AUS1
+C      - GC e' usato solo per rinormalizzare GCX,GCY,GCZ, si puo' non conservare
+C      -  Bisogna inserire controlli sulla possibilita' di avere
+C        oggetti intersecantisi. Il programma non se ne accorge e pasticcia
+C        riflessione ed eclissi.
+C      - Approssimazioni numeriche nei sin e cos fanno si che aree e
+C        distanze abbiano solo 4 cifre significative, qualcosa forse
+C        andra' messo in doppia precisione. In certi punti si rimedia a 
+C        questo mettendo =0 le cose sotto R4prec. Ma, per esempio in CYL,
+C        thin disk a spessore varabile, quando si usano sui 50000 punti
+C        le approssimazioni numeriche danno gia' nel calcolo area tot
+C        un errore circa del 0,04 %
+C      - Per come e' ora ALLSEL dimcx,y,z puo' essere abs(dimcx,y,z)
+C        con ovvio risparmio di tempo. 
+C      - Le routines lobesf1,lobesf2,lobesf2 sono da modificare,
+C        riscrivendo le espressioni in modo da eliminare le potenze
+C      - usare adimensional units per accorciare calcolo flussi da T**4
+C        mettendo: ac/4pi=AC4PI=1
+C      - ridondanze ed ineleganze in opzioni di stampe ed altre.
+C        la frazione di luce in una banda per un oggetto in PAR 
+C        andrebbe usata per metterci il valore calcolato , ora in
+C         /filtri/ .. compfrac(banda,object). Non si puo' finche'
+C        e' usata anche per segnalare che T usare nella plankiana.
+C        Anche i vari modflag delle bande di colore possono non essere OK.
+C      - Bisogna notare che il coefficiente di gravity darkening e',
+C        seguendo Wilson, g=4*beta. Beta e' la notazione di Lucey
+C      - Per finire: l'inglese dei commenti e' lievemente penoso.
+C       
+C      ***********************************************************
+C      ARRAYS AND VARIABLES DESCRIPTION
+C
+C      PARAMETER Statements  are  used for compile-time dimensioning:
+C      MAXPT= number of fine grid surface points describing the 3 objects
+C      MAXPTC= number of coarse grid surface points describing the 3 objects
+C      MAXALLIN= number of reflection paths
+C      MAXFASI= number of values for the phase
+C      maxbande= 5 usually UBVRI
+C      maxflags= number of flags defining the program run
+C      maxfval=number of flag value descriptors
+C      maxpar= number of parameters describing the system
+C      maxpars= number of parameters describing each object
+C      MAXCELL= number of grid points used in light integration
+C      maxtitle= number of max title line for printed output
+C      maxfilt= number of max colour bands
+C      maxlam= number of max lambda points describing a colour band 
+C
+C      COMMON/SURF/ fine grid description the surface elements of the system:
+C      NPNTMX=MAXPT=maximum number of surface elements used to describe
+C       the 3 objects of the system: the two stars and the disk.            
+C      NPNT=actual number of surface elements
+C      NPNT1= number of surface elements for object 1
+C      NPNT2,NPNT3= same for objects 2 and 3
+C      N1I,N1F= first and last surface element for object 1 in following arrays
+C      N2I,N2F,N3I,N3F= same for objects 2 and 3
+C      X,Y,Z= position of each surface element in the corotating system
+C      G= surface gravity 
+C      GX,GY,GZ=  component of the normal unit vector to the surface element
+C      FX,FY,FZ= components of the surf.element tangent vector (along phi)
+C      TX,TY,TZ= components of the surf.element tangent vector (along theta)
+C      T= temperature of the surface element
+C      A= area of the surface element
+C      FB=bolometric flux of the surface element (reflection excluded)
+C      F= flux for each color 
+C      FRIFL= flux reflected from the surface element 
+C      NUMOBJ= number of the object for each surface element
+C      XLIMB= limb darkening coefficient for each surf. element
+C      ALB= albedo for each surf. element
+C
+C      COMMON/SURFC/ describes the surface elements of the system:
+C      similar to /SURF/, but coarse grid, used for reflection computation.
+C      DIMCX,DIMCY,DIMCZ : lenght of the coarse surf.element
+C
+C      COMMON/ALLIN/ contains data used to compute reflection effects,
+C      namely a list of reflection paths (alignement's list) containig:
+C      IAUS is used as a logical  existence flag in subroutine ALLSEL
+C
+C      COMMON/LIGHT/ contains phases, observed and computed light
+C      for each phase and color. maxbande of this common is the
+C      same as maxfilt of common filtri, this duplication allow
+C      a more easy management of common dimension during test phases
+C      FASE= phase values
+C      O = observed flux for each colour band  and phase
+C      C= computed flux for each band and object and phase
+C      CT= C summed on objects
+C      CBOL = bolometric flux for each object and phase
+C      CBOLT = CBOL summen ob objects
+C      CBOLR = bolometric reflected flux for each object and phase
+C      CBOLT = CBOLR summen ob objects
+C      AREA= total surface area of the star
+C      FBOLTOT = flux norm factor : ( L norm.*FBOLTOT = true L )
+C      FBOL= bolometric tot. luminosity flux for the object without reflected 
+C      FBOLREF= bolometric tot luminosity reflected by the object
+C
+C      COMMON/VISUAL/ contains an array used to compute the light
+C      received by the observed, namely a grid of points on the
+C      plane perpendicular to the observer over which the image
+C      of the system is proiected
+C
+C      COMMON /ROCHE/ roche model Lagrange points and lobe'e dimension
+C      AL1,AL2,AL3 = x coord of lagrange points : 1,2,3
+C      XA1,XA2 = intersection of star A surface with X axis
+C      XB1,XB2 = same for star B (XB1,XA1 are near inner Lagr.point)
+C                XB2 near L2, XA2 near L3
+C      YA,YB = approx transverse dimesion of critical lobes(common L1)
+C              See: Plavec - BAC - Vol 15 :165 (1964)
+C      omegal1,omegal2,omegal3 = omega for critical lobes
+C      rpole,xpole,ypole,zpole,tpole,gxpole,gypole,gzpole = position, radius,
+C              temperature, surf. versor for pole surf.element
+C
+C      COMMON/FILTRI/ contains the colour bands description, filled in
+C      routine FILFILT. maxfilt of this common is the
+C      same as maxbande of common light , this duplication allow
+C      a more easy management of common dimension during test phases
+C      NLAMBDA = number of lambda value describing the band
+C      deltalam = constant step for lambda values
+C      alambda= lambda values (Anstrong)
+C      trasmiss= filter trasmission coefficients for the corresponding lambda
+C      compfrac=computed fraction of intensity for each object in each band
+C
+C      COMMON/PAR/ contains the calculation parameters, which
+C      can be modified by the user input
+C
+C      COMMON/TITLE/ some title lines to be printed on output
+C      
+C      -----------------------------------------------------------------
+C
+       PARAMETER (MAXPT=200000 )
+       PARAMETER (MAXPTC=50000 ,MAXALLIN=250000)
+       PARAMETER (MAXFASI=1000, MAXBANDE=5)
+       PARAMETER (MAXFLAG=21 , MAXPAR=128 , MAXPARS=20 )
+       PARAMETER (MAXCELL=1000 )
+       PARAMETER (MAXTITLE=5)
+       PARAMETER ( MAXFILT=5 , MAXLAM=15 )
+C
+       COMMON /SURF/ NPNTMX,NPNT,NPNT1,NPNT2,NPNT3,
+     A               N1I,N1F,N2I,N2F,N3I,N3F,
+     1               X(MAXPT),Y(MAXPT),Z(MAXPT),
+     2               G(MAXPT),GX(MAXPT),GY(MAXPT),GZ(MAXPT),
+     3               FX(MAXPT),FY(MAXPT),FZ(MAXPT),
+     4               TX(MAXPT),TY(MAXPT),TZ(MAXPT),
+     5               T(MAXPT),A(MAXPT),
+     6               FB(MAXPT),F(MAXPT,MAXBANDE),FRIFL(MAXPT),
+     7               XLIMB(MAXPT),NUMOBJ(MAXPT),ALB(MAXPT),
+     8               NUMCOARSE(MAXPT)
+      DIMENSION NP123(3)
+      DIMENSION NIF(2,3)
+      EQUIVALENCE (NP123(1),NPNT1),(NIF(1,1),N1I)
+C 
+       COMMON /SURFC/ NPNTMXC,NPNTC,NPNT1C,NPNT2C,NPNT3C,
+     A               N1IC,N1FC,N2IC,N2FC,N3IC,N3FC,
+     1               XC(MAXPTC),YC(MAXPTC),ZC(MAXPTC),
+     2               GC(MAXPTC),GXC(MAXPTC),GYC(MAXPTC),GZC(MAXPTC),
+     5               AC(MAXPTC),
+     6               DIMCX(MAXPTC),DIMCY(MAXPTC),DIMCZ(MAXPTC),
+     6               FBC(MAXPTC),FRIFLC(MAXPTC),
+     7               XLIMBC(MAXPTC),NUMOBJC(MAXPTC),ALBC(MAXPTC),
+     8               NUMFINI(MAXPTC)
+      DIMENSION NP123C(3)
+      DIMENSION NIFC(2,3)
+      EQUIVALENCE (NP123C(1),NPNT1C),(NIFC(1,1),N1IC)
+C 
+      COMMON /ALLIN/ NALLMX,NALL,ITERDONE,
+     1               ISOUR(MAXALLIN),JRIC(MAXALLIN),
+     2               TRANSFI(MAXALLIN),TRANSFJ(MAXALLIN),
+     3               FSOURI(MAXALLIN),FSOURJ(MAXALLIN),
+     4               FRICI(MAXALLIN),FRICJ(MAXALLIN),
+     5               RIJ(MAXALLIN),
+     6               RXIJ(MAXALLIN),RYIJ(MAXALLIN),RZIJ(MAXALLIN),
+     7               COSGI(MAXALLIN),COSGJ(MAXALLIN),
+     8               IAUS(MAXALLIN)
+C
+      COMMON /LIGHT/ NFASIMX,NFASI,NBANDE,
+     1               FASE(MAXFASI),O(MAXBANDE,MAXFASI),
+     2               C(3,MAXBANDE,MAXFASI),CT(MAXBANDE,MAXFASI),
+     3               CBOL(3,MAXFASI),CBOLT(MAXFASI),
+     4               CBOLR(3,MAXFASI),CBOLTR(MAXFASI),
+     5               AREA(3),FBOLTOT(3),FBOL(3),FBOLREF(3)
+C 
+      COMMON /VISUAL/ NCELL,CELLMAX,CELLMIN,DCELL,
+     1                XCELL(MAXCELL),YCELL(MAXCELL)
+      DIMENSION ICELL(MAXCELL,MAXCELL)
+C
+      COMMON /ROCHE/ AL1,AL2,AL3,XA1,XA2,XB1,XB2,YA,YB,
+     1               OMEGAL1,OMEGAL2,OMEGAL3,
+     2               RPOLE(3),XPOLE(3),YPOLE(3),ZPOLE(3),TPOLE(3),
+     3               GXPOLE(3),GYPOLE(3),GZPOLE(3)
+C
+       COMMON /FILTRI/ NFILT,NLAM, NLAMBDA(MAXFILT),DELTALAM(MAXLAM),
+     1     ALAMBDA(MAXLAM,MAXFILT),TRASMISS(MAXLAM,MAXFILT),
+     2     COMPFRAC(MAXFILT,3)
+C
+      COMMON /PAR/ NFLAG,IFLAG(MAXFLAG),NPAR,PAR(MAXPAR)
+      DIMENSION PARS(MAXPARS,3)
+      EQUIVALENCE (PARS(1,1),PAR(1))
+C
+      COMMON/TITLE/NTITLEMX,NTITLE,TITLE(MAXTITLE)      
+      CHARACTER*80 TITLE
+C     
+      DIMENSION IPPAR1(MAXFLAG),IPPAR2(MAXFLAG),MODFLAG(MAXFLAG)
+C
+      CHARACTER *10 NAMFLAG(MAXFLAG) 
+      CHARACTER *20 DESCFLAG(MAXFLAG)
+C
+      CHARACTER *10 NAMPAR(MAXPAR)   
+      CHARACTER *20 DESCPAR(MAXPAR)
+C
+      DIMENSION IFLAGDEF(MAXFLAG),PARDEF(MAXPAR)             
+C
+      DIMENSION AUS(MAXPT),AUS1(MAXPT),AUS2(MAXPT),AUS3(MAXPT)
+C     aus,aus1 used by subroutine sphere (where dimensioned nfi)
+C     aus,aus1,aus2,aus3 are used by subroutine luce 
+C                                       (where dimensioned maxpt)
+C     aus used in subroutine CYL (where dimensioned NTHF*5; NTHF=coarse factor)
+C     aus used in subroutine PRINTING (dim(MAXPT) to store radii to print
+C
+C     -------------------------------------------------------------
+      DATA PI /3.1415926/
+C     a*c/4/pi , flux=ac4pi T**4 = erg/cm**2/sec/sterad
+      DATA AC4PI /1.8065E-5/
+C
+      LOGICAL KTEST,STOP
+      LOGICAL PRINTFILE,PRINT6
+      LOGICAL PLOTFILE,PLOT6
+      EXTERNAL ROCHESF1,ROCHESF2 
+C
+C     The following data define defaults for parameters and flags
+C     along with a name and a descriptor for each of them.
+C     For each flag ippar1 and ippar2 are two pointers to the
+C     parameters, which identify the range of parameters belonging
+C     to the flag. Same parameters are hidden i.e. not referred to.
+C
+C     --------------------------------------------------------------
+      DATA (NAMFLAG(I),DESCFLAG(I),IFLAGDEF(I),
+     A                                IPPAR1(I),IPPAR2(I),I=1,MAXFLAG)
+     1 /'STARA     ',' Star A             ',  1,    1,20,    
+     2  'STARB     ',' Star B             ',  0,   21,40,
+     3  'DISK      ',' Disk               ',  0,   41,60,
+     4  'U         ',' U-color  band      ',  0,   61,65,
+     5  'B         ',' B-color  band      ',  0,   69,73,
+     6  'V         ',' V-color  band      ',  0,   77,81,
+     7  'R         ',' R-color  band      ',  0,   85,89,
+     8  'I         ',' I-color  band      ',  0,   93,97,
+     9  'REFLECTION',' Reflection comput. ',  1,  101,104,
+     A  'ZEROREFL  ',' Zero refl. source  ',  0,    0, 0,    
+     1  'ORBIT     ',' Orbital parameters ',  0,  105,108,
+     2  'PHASES    ','   Sets phases      ',  1,  111,113,
+     3  'GRID      ','   Sets project.grid',  1,  114,116,
+     4  'PARAMETER ','   Sets a parameter ',  0,    1,  MAXPAR,
+     5  'GO        ','   Program  runs    ',  0,    0, 0,  
+     6  'STOP      ','   Program stops    ',  0,    0, 0,
+     7  'EXIT      ','   Program stops    ',  0,    0, 0,
+     8  'FLAGS     ','   Sets a flag      ',  0,    0, 0,
+     9  'OFF       ',' Set next flags off ',  0,    0, 0, 
+     A  'PRINT     ',' Output is printed  ',  1,  117,122,
+     B  'PLOT      ',' Plot produced      ',  0,  123,127  /
+C
+      DATA (NAMPAR(I),DESCPAR(I),PARDEF(I),I=1,20)
+     1 /'SHAPEA    ' , ' sphere=1,roche=2   ' ,      2.0, 
+     2  'RA        ' , ' radius of star A   ' ,      0.0,
+     3  'X0A       ' , ' X position of A    ' ,      0.0, 
+     4  'Y0A       ' , ' Y position of A    ' ,      0.0, 
+     5  'Z0A       ' , ' Z position of A    ' ,      0.0, 
+     6  'OMEGAA    ' , ' potential of A     ' ,      0.0, 
+     7  'MESHA     ' , ' num. of theta mesh ' ,      5.0,
+     8  'NPHIA     ' , ' unused             ' ,      0.0, 
+     9  'GA        ' , ' gravity dark. of A ' ,      0.0,
+     O  'TEMPA     ' , ' pole temperature A ' ,      1.0, 
+     1  'BOLA      ' , ' bolometric lum.of A' ,      0.0, 
+     2  'ALBA      ' , ' bolometric albedo A' ,      1.0, 
+     3  'LIMBA     ' , ' limb darkening of A' ,      0.0,
+     4  'CORDA     ' , ' arch,cord,tang.seg.' ,      3.0, 
+     5  'RIA       ' , ' disk inner radius  ' ,      0.0, 
+     6  'HA        ' , ' disk height at R   ' ,      0.0,
+     7  'HIA       ' , ' disk height at RI  ' ,      0.0,
+     8  'INCLINA   ' , ' ang.z-z orbit.plane' ,      0.0, 
+     9  'ROTATEA   ' , ' ang.x-x orbit plane' ,      0.0,
+     O  'INNERA    ' , ' unused             ' ,      0.0 /
+      DATA (NAMPAR(I),DESCPAR(I),PARDEF(I),I=21,40) 
+     1 /'SHAPEB    ' , ' sphere=1,roche=2   ' ,      1.0, 
+     2  'RB        ' , ' radius of star B   ' ,      0.0,
+     3  'X0B       ' , ' X position of B    ' ,      0.0,
+     4  'Y0B       ' , ' Y position of B    ' ,      0.0, 
+     5  'Z0B       ' , ' Z position of B    ' ,      0.0, 
+     6  'OMEGAB    ' , ' potential of B     ' ,      0.0, 
+     7  'MESHB     ' , ' num. of theta mesh ' ,      5.0,
+     8  'NPHIB     ' , ' unused             ' ,      0.0, 
+     9  'GB        ' , ' gravity dark. of B ' ,      0.0,
+     O  'TEMPB     ' , ' pole temperature B ' ,      1.0,
+     1  'BOLB      ' , ' bolometric lum.of B' ,      0.0, 
+     2  'ALBB      ' , ' bolometric albedo B' ,      1.0, 
+     3  'LIMBB     ' , ' limb darkening of B' ,      0.0,
+     4  'CORDB     ' , ' arch,cord,tang.seg.' ,      3.0, 
+     5  'RIB       ' , ' disk inner radius  ' ,      0.0, 
+     6  'HB        ' , ' disk height at R   ' ,      0.0,
+     7  'HIB       ' , ' disk height at RI  ' ,      0.0,
+     8  'INCLINB   ' , ' ang.z-z orbit.plane' ,      0.0, 
+     9  'ROTATEB   ' , ' ang.x-x orbit plane' ,      0.0,
+     O  'INNERB    ' , ' unused             ' ,      0.0 /
+      DATA (NAMPAR(I),DESCPAR(I),PARDEF(I),I=41,60)
+     1 /'SHAPEC    ' , ' disk=3             ' ,      3.0, 
+     2  'RC        ' , ' radius of disk:C   ' ,      4.0, 
+     3  'X0C       ' , ' X position of disk ' ,      0.0, 
+     4  'Y0C       ' , ' Y position of disk ' ,      0.0, 
+     5  'Z0C       ' , ' Z position of disk ' ,      0.0, 
+     6  'OMEGAC    ' , ' potential of C     ' ,      0.0, 
+     7  'MESHC     ' , ' num. of theta mesh ' ,      4.0, 
+     8  'NPHIC     ' , ' unused             ' ,      0.0, 
+     9  'GC        ' , ' gravity dark. of C ' ,      0.0,
+     O  'TEMPC     ' , ' pole temperature C ' ,      1.0,
+     1  'BOLC      ' , ' bolometric lum.of C' ,      0.0, 
+     2  'ALBC      ' , ' bolometric albedo C' ,      1.0, 
+     3  'LIMBC     ' , ' limb darkening of C' ,      0.0,
+     4  'CORDC     ' , ' arch,cord,tang.seg.' ,      0.0,
+     5  'RIC       ' , ' disk inner radius  ' ,      0.0, 
+     6  'HC        ' , ' disk height at R   ' ,      0.0,
+     7  'HIC       ' , ' disk height at RI  ' ,      0.0,
+     8  'INCLINC   ' , ' ang.z-z orbit.plane' ,      0.0, 
+     9  'ROTATEC   ' , ' ang.x-x orbit plane' ,      0.0, 
+     O  'INNERC    ' , ' inner surf drawn   ' ,      0.0  / 
+C
+        DATA (NAMPAR(I),DESCPAR(I),PARDEF(I),I=61,100) 
+     1 /'ULAMB1    ' , ' U color lambda 1   ' ,   3300.0,
+     2  'ULAMB2    ' , ' U color lambda 2   ' ,   3700.0,
+     3  'ULUM_A    ' , ' frac. U lumin.for A' ,      0.0,
+     4  'ULUM_B    ' , ' frac. U lumin.for B' ,      0.0,
+     5  'ULUM_C    ' , ' frac. U lumin.for C' ,      0.0,
+     6  'UALB_A    ' , ' albedo U for A     ' ,      1.0,
+     7  'UALB_B    ' , ' albedo U for B     ' ,      1.0,
+     8  'UALB_C    ' , ' albedo U for C     ' ,      1.0,
+     1  'BLAMB1    ' , ' B color lambda 1   ' ,   4300.0,
+     2  'BLAMB2    ' , ' B color lambda 2   ' ,   4700.0,
+     3  'BLUM_A    ' , ' frac. B lumin.for A' ,      0.0,
+     4  'BLUM_B    ' , ' frac. B lumin.for B' ,      0.0,
+     5  'BLUM_C    ' , ' frac. B lumin.for C' ,      0.0,
+     6  'BALB_A    ' , ' albedo B for A     ' ,      1.0,
+     7  'BALB_B    ' , ' albedo B for B     ' ,      1.0,
+     8  'BALB_C    ' , ' albedo B for C     ' ,      1.0,
+     1  'VLAMB1    ' , ' V color lambda 1   ' ,   5300.0,
+     2  'VLAMB2    ' , ' V color lambda 2   ' ,   5700.0,
+     3  'VLUM_A    ' , ' frac. V lumin.for A' ,      0.0,
+     4  'VLUM_B    ' , ' frac. V lumin.for B' ,      0.0,
+     5  'VLUM_C    ' , ' frac. V lumin.for C' ,      0.0,
+     6  'VALB_A    ' , ' albedo V for A     ' ,      1.0,
+     7  'VALB_B    ' , ' albedo V for B     ' ,      1.0,
+     8  'VALB_C    ' , ' albedo V for C     ' ,      1.0,
+     1  'RLAMB1    ' , ' R color lambda 1   ' ,   6500.0,
+     2  'RLAMB2    ' , ' R color lambda 2   ' ,   7500.0,
+     3  'RLUM_A    ' , ' frac. R lumin.for A' ,      0.0,
+     4  'RLUM_B    ' , ' frac. R lumin.for B' ,      0.0,
+     5  'RLUM_C    ' , ' frac. R lumin.for C' ,      0.0,
+     6  'RALB_A    ' , ' albedo R for A     ' ,      1.0,
+     7  'RALB_B    ' , ' albedo R for B     ' ,      1.0,
+     8  'RALB_C    ' , ' albedo R for C     ' ,      1.0,
+     1  'ILAMB1    ' , ' I color lambda 1   ' ,   7500.0,
+     2  'ILAMB2    ' , ' I color lambda 2   ' ,   8500.0,
+     3  'ILUM_A    ' , ' frac. I lumin.for A' ,      0.0,
+     4  'ILUM_B    ' , ' frac. I lumin.for B' ,      0.0,
+     5  'ILUM_C    ' , ' frac. I lumin.for C' ,      0.0,
+     6  'IALB_A    ' , ' albedo I for A     ' ,      1.0,
+     7  'IALB_B    ' , ' albedo I for B     ' ,      1.0,
+     8  'IALB_C    ' , ' albedo I for C     ' ,      1.0  /
+        DATA (NAMPAR(I),DESCPAR(I),PARDEF(I),I=101,116) 
+     1 /'ALBEDO    ' , ' bolometric albedo  ' ,      1.0,
+     2  'MAXITER   ' , ' maximum iteration  ' ,      5.0,
+     3  'PRECISION ' , ' convergency  check ' ,      0.001,
+     4  'COARSE    ' , ' coarsing factor    ' ,      1.0,
+     1  'I         ' , ' incl.of orbit plane' ,     90.0, 
+     2  'MRATIO    ' , ' mass ratio Mb/Ma   ' ,      1.0, 
+     3  'ECC       ' , ' orbit eccentricity ' ,      0.0, 
+     4  'PREC      ' , ' Newton-Rapson prec.' ,    1.E-7,
+     5  'NULL      ' , ' Unused             ' ,      0.0,
+     6  'NULL      ' , ' Unused             ' ,      0.0,
+     1  'NUMPHASES ' , ' num.of equis.phases' ,      8.0,        
+     2  'PHASEUNIT ' , ' unit for input phas' ,      0.0,
+     3  'NORM      ' , ' Light curve norm.  ' ,      1.0,
+     1  'NUMCELLS  ' , ' num.of grid points ' ,    100.0,
+     2  'R4PREC    ' , ' sin,cos precision  ' ,     1.E-5,
+     3  'NULL      ' , ' Unused             ' ,      0.0  /
+C
+        DATA (NAMPAR(I),DESCPAR(I),PARDEF(I),I=117,MAXPAR)
+     1 /'AMOUNT    ' , ' Amount of printing ' ,     10.0,
+     2  'SCREEN    ' , ' Output on screen   ' ,      1.0,
+     3  'UNIT      ' , ' Output on this unit' ,     11.0,
+     4  'MAP       ' , ' Map print phas.step' ,      1.0,
+     5  'REFL      ' , ' Reflection details ' ,     10.0, 
+     6  'LIGHT     ' , ' Light curve details' ,      4.0,
+     1  'AMOUNT    ' , ' Amount of printing ' ,     10.0,
+     2  'SCREEN    ' , ' Output on screen   ' ,      1.0,
+     3  'UNIT      ' , ' Output on this unit' ,     11.0,
+     4  'MAP       ' , ' Map plot phase step' ,      1.0,
+     5  'FILE      ' , ' Output ASCII file  ' ,     12.0,
+     6  'NULL      ' , ' unused parameter   ' ,      0.0  / 
+C
+C     .......................................................
+      NPNTMX=MAXPT
+      NPNTMXC=MAXPTC
+      NALLMX=MAXALLIN
+      NFASIMX=MAXFASI
+      NBANDE=MAXBANDE
+      NPAR=MAXPAR
+      NFLAG=MAXFLAG
+      NTITLEMX=MAXTITLE
+      NFILT=MAXFILT
+      NLAM=MAXLAM
+C
+C     ..........................  elapsed time computation         
+      TEMPO0=SECNDS(0.0)           !  VAX VMS, NOT ANSI STANDARD
+      TEMPREC=0.0
+      TEMPIO=0.0
+      TEMPIOP=0.0
+      TEMPDRAW=0.0
+      TEMPREF=0.0
+      TEMPCOL=0.0
+      TEMPNORM=0.0
+      TEMPLUC=0.0
+C
+C     ..........................  Default setting
+      DO 3 I=1,MAXFLAG
+   3  IFLAG(I)=IFLAGDEF(I)
+      DO 4 I=1,MAXPAR
+   4  PAR(I)=PARDEF(I)
+C     ..........................  Colour band definitions
+      CALL FILFILT
+      DO 5 J=1,3
+      DO 5 I=1,MAXFILT
+   5  COMPFRAC(I,J)=0.0
+C     ..........................  At the beginning there aren't stars
+      NTITLE=0
+      NPNT=0
+      NPNT1=0
+      NPNT2=0
+      NPNT3=0
+      N1I=0
+      N1F=0
+      N2I=0
+      N2F=0
+      N3I=0
+      N3F=0     
+      NPNTC=0
+      NPNT1C=0
+      NPNT2C=0
+      NPNT3C=0
+      N1IC=0
+      N1FC=0
+      N2IC=0
+      N2FC=0
+      N3IC=0
+      N3FC=0     
+C     ...................... At the beginning there isn't project.grid
+      NCELL=0
+      DCELL=0
+C     ...................... Testing some internal dimension 
+       IF(NFILT.NE.NBANDE) THEN
+         WRITE(6,990) NFILT,NBANDE
+  990    FORMAT(' WARNING! The number of colour bands in commons ',
+     1          '  light and filtri is different:',2I5)
+       ENDIF
+C
+       WRITE(6,999)
+  999  FORMAT(1H1,20X,' CLOSE BINARY SYSTEM ANALYSIS PROGRAM'/
+     1        20X,' Version 0.0 ( debugging in progress )'//)
+C
+C                                                ------------
+C      =================================== =>    |   INPUT  |   
+C                                                ------------
+   12  CONTINUE
+       CALL INPUT(NAMFLAG,DESCFLAG,IFLAGDEF,NAMPAR,DESCPAR,PARDEF,
+     1            IPPAR1,IPPAR2,STOP)
+       IF(STOP) THEN 
+C      Elapsed time computation
+       IF(IFLAG(20).GT.0) THEN
+       TEMPO=SECNDS(TEMPO0)
+       IF(PRINT6)
+     1 WRITE(6,8010) TEMPIO,TEMPIOP,TEMPDRAW,TEMPREF,
+     2               TEMPCOL,TEMPNORM,TEMPLUC,TEMPO
+ 8010  FORMAT(///' Total elapsed time for I/O:              ',G20.5/
+     1        ' Total elapsed time for plotting:          ',G20.5/
+     2        ' Total elapsed time for surface drawing:   ',G20.5/
+     3        ' Total elapsed time for reflection     :   ',G20.5/
+     4        ' Total elapsed time for colour band flux:  ',G20.5/
+     4        ' Total elapsed time for flux normalization:',G20.5/
+     5        ' Total elapsed time for light to observer:',G20.5/
+     6        ' Total elapsed time for this run:         ',G20.5///) 
+       IF(PRINTFILE) 
+     1 WRITE(NFILE,8010) TEMPIO,TEMPIOP,TEMPDRAW,TEMPREF,
+     2                   TEMPCOL,TEMPNORM,TEMPLUC,TEMPO
+       ENDIF
+       STOP
+       ENDIF
+C                                                -----------------
+C      =================================== =>    |   RUN BEGINS  |
+C                                                -----------------
+ 300   CONTINUE          ! 300: unreferenced label
+C      MODFLAG is used to set off some flags after the corresponding comput.:
+C                run flag: n.15 - input phases: n.12 -
+C                stars and disk drawing: n.1,2,3
+C                reflection and zero reflection source n.9,10
+       MODFLAG(15)=1
+       MODFLAG(12)=0
+       MODFLAG(1)=0
+       MODFLAG(2)=0
+       MODFLAG(3)=0
+       MODFLAG(9)=0
+       MODFLAG(10)=0
+C             .......... sets print flags
+       IF(IFLAG(20).LE.0) THEN
+         NPRINT=0
+         NFILE=6
+         NPRINTR=0
+       ELSE
+         K1=IPPAR1(20)
+         AMOUNT=PAR(K1)
+C        Screen output
+         NFILE6=INT(PAR(K1+1))
+         IF(NFILE6.GT.0) THEN
+         PRINT6=.TRUE.
+         ELSE
+         PRINT6=.FALSE.
+         ENDIF         
+C        Output on unit NFILE
+         NFILE=INT(PAR(K1+2))  
+         IF(NFILE.GT.0.AND.NFILE.LE.99) THEN
+         PRINTFILE=.TRUE.
+         ELSE
+         PRINTFILE=.FALSE.
+         ENDIF
+C        Phase step for printing maps
+         NPRINT=INT(PAR(K1+3))
+C        Light curve details printing
+         NPRINTL=INT(PAR(K1+5))
+C        Reflection hystory printing
+         NPRINTR=INT(PAR(K1+4))
+         IF(PRINTFILE) WRITE(NFILE,999)
+       ENDIF
+C             .......... sets plot flags
+       IF(IFLAG(21).LE.0) THEN
+         NPLOT=0
+         NFILEP=6
+         NPRINTR=0
+       ELSE
+         K1=IPPAR1(21)
+         AMOUNTP=PAR(K1)
+C        Screen output
+         NFILE6P=INT(PAR(K1+1))
+         IF(NFILE6P.GT.0) THEN
+         PLOT6=.TRUE.
+         ELSE
+         PLOT6=.FALSE.
+         ENDIF         
+C        Output on unit NFILEP
+         NFILEP=INT(PAR(K1+2))  
+         IF(NFILEP.GT.0.AND.NFILEP.LE.99) THEN
+         PLOTFILE=.TRUE.
+         ELSE
+         PLOTFILE=.FALSE.
+         ENDIF
+C        Phase step for printing maps
+         NPLOT=INT(PAR(K1+3))
+C        Otput on ASCII file for external plotting
+         NASCIIP=INT(PAR(K1+4))
+       ENDIF
+C
+C             ..................... sin.cos precision parameter
+C      Sometimes sin,cos < r4prec is assumed 0, avoiding rounding error in
+C      computing sin and cos near zero, without using double precision.
+       K1=IPPAR1(13)+1
+       R4PREC=PAR(K1)
+C                                                 ---------------------
+C      .......................................... Input of phase values
+C                                                 ---------------------
+       IF(IFLAG(12).GT.0) THEN
+         K1=IPPAR1(12)
+         NFILEF=INT(PAR(K1+1))
+         IF(NFILEF.GT.0) THEN
+            CALL FASREAD(NFASI,NFILEF,NFILE,NFASIMX,FASE)
+            MODFLAG(12)=1
+            PAR(K1)=NFASI
+         ELSE
+            NFASI=INT(PAR(K1)) 
+            IF(NFASI.GT.0) THEN
+              IF(NFASI.GT.NFASIMX) THEN
+                 WRITE(6,3000) NFASIMX,NFASIMX
+                 IF(PRINTFILE)WRITE(NFILE,3000)NFASI,NFASIMX,NFASIMX
+ 3000    FORMAT(' ERROR! Too mutch phase values requested:',I5/
+     1    ' It is set to the maximum value :',I5/
+     2    ' If you need a greater value go into the FORTRAN list to',
+     3    ' change: MAXFASI=',I5)
+                 NFASI=NFASIMX
+                 PAR(K1)=NFASI
+              ENDIF
+              CALL FASGRID(NFASI,FASE)
+              MODFLAG(12)=1
+            ENDIF
+         ENDIF
+       ENDIF    
+C      ...............................................................
+C
+C      I/O Elapsed time computation
+       IF(IFLAG(20).GT.0) THEN
+       TEMPO=SECNDS(TEMPO0)
+       TEMPD=TEMPO-TEMPREC
+       TEMPREC=TEMPO
+       TEMPIO=TEMPIO+TEMPD
+       IF(PRINT6) WRITE(6,8001) TEMPD,TEMPIO
+C       IF(PRINTFILE) WRITE(NFILE,8001) TEMPD,TEMPIO
+ 8001  FORMAT(/' Elapsed time for I/O:',12X,G20.5,5X,' Total:',G20.5/)
+       ENDIF
+C
+C      ................ If Roche model computes Lagrange Points L1,L2,L3
+       IF(PARS(1,1).EQ.2..OR.PARS(2,1).EQ.2..OR.PARS(3,1).EQ.2.) THEN
+          K1=IPPAR1(11)
+          Q=PAR(K1+1)
+C          IF(Q.GT.1.) THEN           ! The following isn't true
+C            Q1=1./Q
+C            WRITE(6,3020)Q,Q1
+C            IF(PRINTFILE) WRITE(NFILE,3020)Q,Q1
+C 3020       FORMAT(/' ERROR ! For Roche model object A must be the'
+C     1              ' most massive'/' q:',G14.7,' changed to:',G14.7)
+C            Q=Q1
+C            PAR(K1+1)=Q
+C          ENDIF
+          PRECISION=PAR(IPPAR1(11)+3)
+          IF(PRECISION.LT.1.E-7) WRITE(6,3021) PRECISION
+ 3021     FORMAT(//' WARNING ! Requested Newton-Rapson precision ',
+     1    ' may be too small to be used with real*4 numbers:',G14.7//)
+          CALL LAGR(Q,PRECISION)
+          IF(PRINT6) WRITE(6,3022) AL1,OMEGAL1,AL2,OMEGAL2,AL3,OMEGAL3
+ 3022     FORMAT(/' Computed Lagrange points and potential for',
+     1    ' critical lobes:'/,5X,'L1=',G14.7,' omega=',G14.7/
+     2                        5X,'L2=',G14.7,' omega=',G14.7/
+     3                        5X,'L3=',G14.7,' omega=',G14.7/)
+       ENDIF
+C                                              -------------------
+C                                ========== => | SURFACE DRAWING |
+C                                              -------------------
+C
+C             ...............................................................
+C             |   The surface of each object (the 2 stars and the disk), is |
+C             |  represented by a number of "surface elements", which are   | 
+C             |  stored in common /surf/ as a list containing, for each     |
+C             |  element, the area, the temperature, the flux etc.          |
+C             ...............................................................
+C
+C      ------------------------------------------loop on stars and disk
+       DO 30 IS=1,3
+C                    If the object number IS is not to be drawn goes on
+       IF(IFLAG(IS).LE.0) GOTO 30
+       MODFLAG(IS)=1
+C           The reflection has to be recomputed with new grid
+       IF(IFLAG(9).LT.0) IFLAG(9)=1
+       IF(IFLAG(10).LT.0) IFLAG(10)=1
+C
+C              If the object had been drawn before, 
+C              deletes the old space, rearranging data.
+C              ALL data in common/surf/are mouved,also if not jet computed.
+C              Also /surfc/ is compressed.
+           IF(NP123(IS).GT.0.AND.NIF(1,IS).GT.0.AND.NIF(2,IS).GT.0) 
+     1           CALL CANCEL(IS,NFILE)
+C
+       NPS=NP123(IS)
+       NIS=NIF(1,IS)
+       NFS=NIF(2,IS)
+       IF(NIS.LE.0) NIS=NPNT+1
+       NPSC=NP123C(IS)
+       NISC=NIFC(1,IS)
+       NFSC=NIFC(2,IS)
+       IF(NISC.LE.0) NISC=NPNTC+1 
+C
+C      ......... for sphere or Roche model test and set number of intervals
+C
+       IF(PARS(1,IS).EQ.1..OR.PARS(1,IS).EQ.2.) THEN
+C         mesh parameter numtheta: number of fine mesh division.
+          NUMTHETA=INT(PARS(7,IS))
+C         Tests if numtheta is consistent, it must be odd > 3
+          IF(NUMTHETA.LT.4) NUMTHETA=5
+          IF(MOD(NUMTHETA,2).EQ.0) NUMTHETA=NUMTHETA+1
+C         Tests if the coarsing factor is consistent, it must be odd
+C             and a submultiple of numtheta-1 , if not so nthf and
+C             and numtheta are changed.
+          K1=IPPAR1(9)+3
+  301     NTHF=INT(PAR(K1))
+C         Makes NTHF odd > 0
+          IF(NTHF.EQ.0) NTHF=1
+          IF(MOD(NTHF,2).EQ.0) NTHF=NTHF+1 
+C         Makes numtheta consistent with NTHF
+   31     CONTINUE 
+          NTHRESTO=MOD(NUMTHETA-1,NTHF)
+C         This is equal to: MOD(NUMTHETA+2*INT(NTHF/2),NTHF)
+          IF(NTHRESTO.NE.0) THEN
+C            changes numtheta
+             NUMTHETA=NUMTHETA + NTHF - NTHRESTO
+C            If not so, numtheta is made odd (by adding nthf, odd):
+             IF(MOD(NUMTHETA,2).EQ.0) NUMTHETA=NUMTHETA+NTHF
+C            If numtheta too great
+             IF(NUMTHETA.GT.NPNTMX) THEN
+                 IF(NUMTHETA-NTHF.GT.5) THEN
+C                  decrease numtheta
+                   NUMTHETA=NUMTHETA-NTHF
+                 ELSE
+C                  NTHF is decreased by 2 (it's odd)
+                   NTHF=NTHF-2
+                   GOTO 31
+                 ENDIF
+             ENDIF 
+          ENDIF
+C            Warnng message and changes input coarsing factor 
+          IF(INT(PAR(K1)).NE.NTHF) THEN
+                   WRITE(6,3053) PAR(K1),NTHF,IS
+                   IF(PRINTFILE) WRITE(NFILE,3053) PAR(K1),NTHF,IS
+ 3053              FORMAT(/' WARNING! Coarsing factor:',G15.7,
+     1             ' has been changed to:',I6/' The coarsing factor',
+     2             ' must be odd > 0 and consistent with the mesh',
+     3             ' parameter.',5X,'Object:',I3)
+C          PAR(K1)=NTHF  lascio il valore precedente, mentre usa nthf in sfera
+          ENDIF       
+C            Warning message and changes input numtheta 
+          IF(INT(PARS(7,IS)).NE.NUMTHETA) THEN
+              WRITE(6,3054) PARS(7,IS),NUMTHETA,NTHF,IS
+              IF(PRINTFILE) WRITE(NFILE,3054) 
+     1                      PARS(7,IS),NUMTHETA,NTHF,IS
+ 3054         FORMAT(/' WARNING! MESH parameter:',G15.7,
+     1         ' changed to:',I6/
+     1         ' For spheres and Roche it must be odd > 4',
+     1         ' and MESH-1 multiple of coarsing factor:',I5,
+     2        3X,'Object:',I3)
+              PARS(7,IS)=NUMTHETA
+          ENDIF
+       ELSE IF(PARS(1,IS).EQ.0.0) THEN
+C      ........................... similar tests for rectangle
+          NUMTHETA=INT(PARS(7,IS))
+          IF(NUMTHETA.LT.0) NUMTHETA=1
+          K1=IPPAR1(9)+3
+          NTHF=INT(PAR(K1))
+C         Makes NTHF odd > 0
+          IF(NTHF.EQ.0) NTHF=1
+C         The coarsing factor must be a submultiple of theta
+          NTHRESTO=MOD(NUMTHETA,NTHF)
+          IF(NTHRESTO.NE.0) NUMTHETA=NUMTHETA+NTHF-NTHRESTO
+          IF(NUMTHETA.NE.INT(PARS(7,IS)) ) THEN
+             WRITE(6,3062) PARS(7,IS),NUMTHETA,IS
+             IF(PRINTFILE) WRITE(NFILE,3062) PARS(7,IS),NUMTHETA,IS
+             PARS(7,IS)=NUMTHETA 
+          ENDIF
+       ELSE IF(PARS(1,IS).EQ.3.0) THEN
+C      ..................... number of intervals for disk
+          NUMTHETA=INT(PARS(7,IS))
+          IF(NUMTHETA.LT.0) NUMTHETA=1
+          K1=IPPAR1(9)+3
+          NTHF=INT(PAR(K1))
+C         Makes NTHF odd > 0
+          IF(NTHF.EQ.0) NTHF=1
+C         IF(MOD(NTHF,2).EQ.0) THEN
+C             PAR(K1)=PAR(K1)+1
+C             WRITE(6,3052) NTHF,PAR(K1),IS
+C             IF(PRINTFILE) WRITE(NFILE,3052) NTHF,PAR(K1),IS
+C             NTHF=NTHF+1
+C3052         FORMAT(/' WARNING! The input coarsing factor:',
+C     1       I5,' has been changed to the odd value:',G15.7,
+C     2         2X,'Object:',I3)
+C         ENDIF
+C         The coarsing factor must be a submultiple of theta
+          NTHRESTO=MOD(NUMTHETA,NTHF)
+          IF(NTHRESTO.NE.0) NUMTHETA=NUMTHETA+NTHF-NTHRESTO
+          IF(NUMTHETA.NE.INT(PARS(7,IS)) ) THEN
+             WRITE(6,3062) PARS(7,IS),NUMTHETA,IS
+             IF(PRINTFILE) WRITE(NFILE,3062) PARS(7,IS),NUMTHETA,IS
+ 3062        FORMAT(/' WARNING! The mesh parameter :',
+     1       G15.7,' has been changed to the value:',I5/
+     2       ' Consistent with the coarsing factor',5X,'Object:',I3)
+             PARS(7,IS)=NUMTHETA 
+          ENDIF
+       ENDIF
+C                    ------------
+C      ............. SINGLE POINT ,in a rectangular interval
+C                    ------------
+       IF(PARS(1,IS).EQ.0.0) THEN
+C                      
+C
+C      Test other values: radius: i.e. X half-edge
+       RAGGIO=PARS(2,IS)
+       IF(RAGGIO.LT.0.0) THEN
+         RAGGIO=0.
+         WRITE(6,3010) IS,PARS(2,IS),RAGGIO
+         IF(PRINTFILE) WRITE(NFILE,3010) IS,PARS(2,IS),RAGGIO
+ 3010    FORMAT(' ERROR! : Object:',I3,' Absurd radius value:',G15.7,
+     1          ' changed to:',G15.7)
+         PARS(2,IS)=0.0
+       ENDIF
+C
+C      Y half-edge 
+       RAGGIOI=PARS(15,IS)
+       IF(RAGGIOI.LT.RAGGIO) THEN
+         RAGGIOI=RAGGIO
+         WRITE(6,3012) IS,PARS(15,IS),RAGGIOI
+         IF(PRINTFILE) WRITE(NFILE,3012) IS,PARS(15,IS),RAGGIOI
+ 3012    FORMAT(' Object:',I3,' Y Input radius ( < X radius):',G15.7,
+     1          ' changed to X radius:',G15.7)
+       ELSE IF(MOD(RAGGIOI,RAGGIO).GT.R4PREC) THEN
+         RAGGIOI=RAGGIO*INT(RAGGIOI/RAGGIO)
+         WRITE(6,3014) IS,PARS(15,IS),RAGGIOI
+         IF(PRINTFILE) WRITE(NFILE,3014) IS,PARS(15,IS),RAGGIOI
+ 3014    FORMAT(' WARNING! Object:',I3/' Y Input radius:',G15.7,
+     1          ' changed to :',G15.7,'  multiple of X radius')
+       ENDIF
+C
+C      NPSSC is the number of the first void coarse, it is updated
+C      by CYL, NPSS is computed by CYL as the number of fine made by CYL
+       NPSSC=NISC
+       NPNTMX1=NPNTMX-NIS+1
+       ALZO =(PI/180.)*PARS(18,IS)
+       ROTAZ=(PI/180.)*PARS(19,IS) 
+       PKRI=PARS(20,IS)
+C
+          CALL POINT(PRINT6,PRINTFILE,NFILE,NUMTHETA,NTHF,PKRI,IS,
+     1         NPSS,NPSSC,RAGGIO,RAGGIOI,
+     2         PARS(3,IS),PARS(4,IS),PARS(5,IS),
+     3         ALZO,ROTAZ,R4PREC,NPNTMX1,X(NIS),Y(NIS),Z(NIS),
+     4         G(NIS),GX(NIS),GY(NIS),GZ(NIS),
+     5         FX(NIS),FY(NIS),FZ(NIS),TX(NIS),TY(NIS),TZ(NIS),
+     6         AREA(IS),A(NIS),NUMCOARSE(NIS),NUMOBJ(NIS))
+C
+C         NUMOBJ is assigned into subroutine POINT; not outside, as in SFERA2.
+C
+C                    -----------------
+C      ............. SPHERICAL SURFACE, drawn by equi-area intervals
+C                    -----------------
+       ELSE IF( PARS(1,IS).EQ.1.0) THEN
+C
+C      Test other values
+       RAGGIO=PARS(2,IS)
+       IF(RAGGIO.LT.0) THEN
+         RAGGIO=0.
+         WRITE(6,3010) IS,PARS(2,IS),RAGGIO
+         IF(PRINTFILE) WRITE(NFILE,3010) IS,PARS(2,IS),RAGGIO
+         PARS(2,IS)=0.0
+       ENDIF
+C
+C         NPSSC is updated and NPSS is computed by sfera2:
+C         if you are drawing surfaces for the first time, then NPSSC
+C         is the next free coarse surf element (total number of coarse points
+C         (for all objects) +1 ).Otherwise the first coarse of next object.
+C         NPSS is the number of fine surf.interval for this object.
+C         NCORD is the cord option, NPNTMX1 the available space for surf.el.
+          NPSSC=NISC
+          NCORD=INT(PARS(14,IS))
+          NPNTMX1=NPNTMX-NIS+1
+C
+          CALL SFERA2(PRINT6,PRINTFILE,NFILE,NUMTHETA,NTHF,NCORD,NPSS,
+     1             NPSSC,RAGGIO,PARS(3,IS),PARS(4,IS),PARS(5,IS),
+     2             NPNTMX1,X(NIS),Y(NIS),Z(NIS),G(NIS),GX(NIS),
+     3             GY(NIS),GZ(NIS),FX(NIS),FY(NIS),FZ(NIS),
+     4             TX(NIS),TY(NIS),TZ(NIS),
+     5             AREA(IS),A(NIS),NUMCOARSE(NIS),AUS,AUS1 )
+C
+C         NUMOBJ, number of object for each surf. el., is used in LUCE1
+C         to distinguish between the surf.el. of different objects and printings
+          CALL FILL(NPSS,IS,NUMOBJ(NIS))
+C
+       ELSE IF (PARS(1,IS).EQ.2.) THEN
+C                                          ----------
+C      ................................... ROCHE LOBE drawing 
+C                                          ----------
+C                    The star A (main body) is drawn in (0,0,0) and 
+C                    the star B in (1,0,0) (The distance between the stars
+C                    acts as the distance unit measure). The stars can be
+C                    shifted to an input given x point: PARS(3,is), this
+C                    is equivalent to change Omega, and will be faster.
+C                    This option is't valid for object 3
+       IF(IS.EQ.3) THEN
+         WRITE(6,3073)
+ 3073    FORMAT(' ERROR! Roche model not allowed for object 3,',
+     1          ' object not drawn!')
+         GOTO 30
+       ENDIF
+C              .....Testing y and z for the body center
+       IF(PARS(4,IS).NE.0.0.OR.PARS(5,IS).NE.0.) THEN
+             WRITE(6,3074) IS
+ 3074        FORMAT(' WARNING! ,for Roche model the object:',I3,
+     1              ' must be in (X,0,0)')
+             PARS(4,IS)=0.0
+             PARS(5,IS)=0.0
+       ENDIF
+C
+       Q=PAR(IPPAR1(11)+1)
+       PRECISION=PAR(IPPAR1(11)+3)
+       IF(PRECISION.LT.1.E-7) WRITE(6,3021) PRECISION
+C      ... test lobes-x axis intersection, computes omega from R if not given
+       CALL LOBES(Q,PRECISION,PARS(6,IS),PARS(2,IS),IS)
+       XSHIFT=PARS(3,IS)
+C      for object 2 the star is drawn n (1,0,0) : sets the correct shift:
+       IF(IS.EQ.2) XSHIFT=XSHIFT-1.
+       OMEGA=PARS(6,IS)
+       NPSSC=NISC
+       NCORD=INT(PARS(14,IS))
+       NPNTMX1=NPNTMX-NIS+1
+       IF(IS.EQ.1) THEN
+C        the first point XA is near Lagr.point L1       
+         XA=XA1
+         XB=XA2  
+         RIS=0.0
+         IF(PRINT6) WRITE(6,3080) IS,XA1,XA2,XA
+ 3080    FORMAT(/' Surface-X axis intersection for object:',I2,
+     1           ' computed as:',G14.7,2X,G14.7/
+     2           ' Surface drawing starts from point:',G14.7/)
+C
+         CALL ROCHES(PRINT6,PRINTFILE,NFILE,NUMTHETA,NTHF,NCORD,NPSS,
+     1             NPSSC,XA,XB,XSHIFT,OMEGA,Q,RIS,PRECISION,
+     2             NPNTMX1,X(NIS),Y(NIS),Z(NIS),G(NIS),GX(NIS),
+     3             GY(NIS),GZ(NIS),FX(NIS),FY(NIS),FZ(NIS),
+     4             TX(NIS),TY(NIS),TZ(NIS),
+     5             AREA(IS),A(NIS),NUMCOARSE(NIS),AUS,AUS1,ROCHESF1)
+       ELSE
+C        the last point XB is near Lagr.point L1       
+         XA=XB2
+         XB=XB1
+         RIS=1.0
+         IF(PRINT6) WRITE(6,3080) IS,XB1,XB2,XA
+C
+         CALL ROCHES(PRINT6,PRINTFILE,NFILE,NUMTHETA,NTHF,NCORD,NPSS,
+     1             NPSSC,XA,XB,XSHIFT,OMEGA,Q,RIS,PRECISION,
+     2             NPNTMX1,X(NIS),Y(NIS),Z(NIS),G(NIS),GX(NIS),
+     3             GY(NIS),GZ(NIS),FX(NIS),FY(NIS),FZ(NIS),
+     4             TX(NIS),TY(NIS),TZ(NIS),
+     5             AREA(IS),A(NIS),NUMCOARSE(NIS),AUS,AUS1,ROCHESF2)
+       ENDIF
+C          Assign the object number to the surface elements
+       CALL FILL(NPSS,IS,NUMOBJ(NIS))        
+C
+C                                         ----
+C      .................................. DISK drawing
+C                                         ----
+       ELSE IF (PARS(1,IS).EQ.3.) THEN
+C                      
+C      Test other values
+       RAGGIO=PARS(2,IS)
+       IF(RAGGIO.LT.0) THEN
+         RAGGIO=0.
+         WRITE(6,3010) IS,PARS(2,IS),RAGGIO
+         IF(PRINTFILE) WRITE(NFILE,3010) IS,PARS(2,IS),RAGGIO
+         PARS(2,IS)=0.0
+       ENDIF
+       RAGGIOI=PARS(15,IS)
+       IF(RAGGIOI.LT.0.0) THEN
+         RAGGIOI=0.0
+         WRITE(6,3010) IS,PARS(15,IS),RAGGIOI
+         IF(PRINTFILE) WRITE(NFILE,3010) IS,PARS(15,IS),RAGGIOI
+         PARS(2,IS)=0.0
+       ENDIF
+C 
+C      NPSSC is the number of the first void coarse, it is updated
+C      by CYL, NPSS is computed by CYL as the number of fine made by CYL
+       NPSSC=NISC
+       NCORD=INT(PARS(14,IS))
+       NPNTMX1=NPNTMX-NIS+1
+       ALZO =(PI/180.)*PARS(18,IS)
+       ROTAZ=(PI/180.)*PARS(19,IS) 
+       PKRI=PARS(20,IS)
+C
+          CALL CYL(PRINT6,PRINTFILE,NFILE,NUMTHETA,NTHF,NCORD,PKRI,IS,
+     1           NPSS,NPSSC,RAGGIO,RAGGIOI,PARS(16,IS),
+     2           PARS(17,IS),PARS(3,IS),PARS(4,IS),PARS(5,IS),
+     3           ALZO,ROTAZ,R4PREC,NPNTMX1,X(NIS),Y(NIS),Z(NIS),
+     4           G(NIS),GX(NIS),GY(NIS),GZ(NIS),
+     5           FX(NIS),FY(NIS),FZ(NIS),TX(NIS),TY(NIS),TZ(NIS),
+     6           AREA(IS),A(NIS),NUMCOARSE(NIS),NUMOBJ(NIS),
+     7           AUS,AUS(NTHF+1),AUS(2*NTHF+1),AUS(3*NTHF+1),
+     8           AUS(4*NTHF+1)  )
+C
+C         NUMOBJ is assigned into subroutine CYL; not outside, as in SFERA2.
+C
+       ENDIF
+C                   Assign the parameters of the surface element list
+C                                              for the drawn object   
+       NIF(1,IS)=NIS
+       NIF(2,IS)=NIS+NPSS-1
+       NP123(IS)=NPSS
+       NPNT=NPNT+NPSS
+C      nifc(2,is)=0 means coarse map done, but NOT coarse surf elem.
+       NIFC(1,IS)=NISC
+       NIFC(2,IS)=0
+       NP123C(IS)=NPSSC-NISC
+       NPNTC=NPNTC+NP123C(IS)
+C
+C                     -----------------------------------------------------
+C     ................GRAVITY DARKENED TEMPERATURE PROFILE AND SURF.EL FLUX
+C                     -----------------------------------------------------
+C                                ( Sets FB(i),T(i),i=nis,nfs)  
+C
+C                   If g , gravity darkening parameter, is set
+       IF(PARS(9,IS).NE.0.0) THEN
+C      Computes gravity darkened temperature given by beta:
+C         Pars(9,is) is the g gravity dark. coeff. definition by Wilson 
+C         different from Lucey and Von Zeipel beta coefficient
+C         pars(10,is) is the input pole temperature= max T
+          BETA=PARS(9,IS)*0.25
+          CALL GRAVITY1(KK,NPSS,BETA,PARS(10,IS),G(NIS),T(NIS))
+C            Store pole values for printing
+          KK=NIS+KK-1
+          XPOLE(IS)=X(KK)
+          YPOLE(IS)=Y(KK)
+          ZPOLE(IS)=Z(KK)
+          TPOLE(IS)=T(KK)
+          RPOLE(IS)=SQRT((X(KK)-PARS(3,IS))**2 +(Y(KK)-PARS(4,IS))**2+
+     1                   (Z(KK)-PARS(5,IS))**2 )
+          GXPOLE(IS)=GX(KK)
+          GYPOLE(IS)=GY(KK)
+          GZPOLE(IS)=GZ(KK)
+C
+C            and bolometric flux is given by T**4 in each point 
+C            flux = caT**4/(4PI)=erg/cm**2/sec/sterad
+C            to shorten calculation we could assume  here c*a*T**4/(4*pi)=1 
+          CALL LBOLT(NPSS,FB(NIS),T(NIS),A(NIS))
+       ELSE
+C               uniform  temperature and flux in each surface element
+          EFFE=PARS(10,IS)**4        *AC4PI 
+          CALL FILL(NPSS,PARS(10,IS),T(NIS))
+          CALL FILL1(NPSS,EFFE,FB(NIS),A(NIS))
+       ENDIF
+C                                  --------------------------------
+C     .......................      LIMB DARKENING AND ALBEDO COEFF. 
+C                                  --------------------------------
+C                                  (Sets XLIMB(i),ALB(i),i=nis,nfs)
+C      eventually a T-dependence could be inserted here
+      DARKLIM=PARS(13,IS)
+      ALBIS=PARS(12,IS)
+      CALL LIMB(NPSS,DARKLIM,ALBIS,T(NIS),XLIMB(NIS),ALB(NIS))
+C
+C      Drawing elapsed time computation
+       IF(IFLAG(20).GT.0) THEN
+       TEMPO=SECNDS(TEMPO0)
+       TEMPD=TEMPO-TEMPREC
+       TEMPREC=TEMPO
+       TEMPDRAW=TEMPDRAW+TEMPD
+       IF(PRINT6) WRITE(6,8002) TEMPD,TEMPDRAW
+C       IF(PRINTFILE) WRITE(NFILE,8002) TEMPD,TEMPDRAW
+ 8002  FORMAT(/' Elapsed time for surface drawing:',
+     1          G20.5,5X,' Total:',G20.5/)       
+       ENDIF
+C
+   30  CONTINUE
+C     ---------------------------------------- end of loop on stars
+C
+C
+C
+C                                      --------------------------
+C                   ============== =>  |      REFLECTION        |
+C                                      --------------------------
+      IF(IFLAG(9).GT.0) THEN
+          MODFLAG(9)=1
+C             In this case only obtain frifl from friflc from previous run
+          IF(IFLAG(9).EQ.2) GOTO 320
+C
+C         Look if, for some object, the coarse map must be used
+C         to compute the coarse surf.elements in common /surfc/:
+          DO 32 IS=1,3
+          IF(NIFC(2,IS).LE.0.AND.NP123C(IS).GT.0) THEN
+             IF(NPNTC.GT.NPNTMXC) THEN
+             WRITE(6,3100) IS,NP123C(IS),NPNTMXC
+             IF( PRINTFILE) WRITE(NFILE,3100) IS,NP123C(IS),NPNTMXC
+ 3100        FORMAT(' ERROR: for object',I2,' I can''t use',I6,
+     1 ' coarse surface elements for reflection.'/
+     2 ' Reduce the number of coarse surface elements for some object,'/
+     3 ' or go into the FORTRAN list to change parameter MAXPTC, now:',
+     4   I6)
+             ENDIF
+             CALL COARSE(PRINT6,PRINTFILE,NFILE,IS)
+          ENDIF
+   32     CONTINUE
+C
+C         Bolometric reflection is used to compute a bolometric
+C         reflected flux for each surface element : FRIFL(NPNT)
+C         An albedo parameter (ALBEDO) which wheights the reflection 
+C         efficiency is used for all the objects; a similar input 
+C                             parameter exists for each object.
+         ALBEDO=PAR(IPPAR1(9))
+         MAXITER=INT(PAR(IPPAR1(9)+1))
+         PRECISION=PAR(IPPAR1(9)+2)
+C                  Computing reflected flux for each coarse surface elememt
+         CALL REFLECT(MAXITER,PRECISION,R4PREC,ALBEDO,NPRINTR,NFILE,
+     1                                                           AUS)
+C                  Computing total bolometric reflected lum. for each object
+  320    CALL SUMREFL(NPNTC,NIFC,FBOLREF,FRIFLC)
+C                  From coarse to fine surf.el.reflected flux(FRIFLC=>FRIFL)
+         CALL FINEFRIFL
+C                  if black body is used for any color or object to obtain
+C                  flux fraction from t for each surf. element
+C                  T must changed in each surf. element after reflection
+         DO 33 IS=1,3
+         IF(IFLAG(IS).LE.0) GOTO 33
+         DO 33 IB=1,NBANDE
+         IF(IFLAG(IB+3).LE.0) GOTO 33       
+         K1=IPPAR1(IB+3)+1
+         ALFRAC=PAR(K1+IS)
+         IF(ALFRAC.GE.0.0) GOTO 33
+C        in this case T of single surf element is used (see loop 44 below)
+         CALL TCHANGE(NPNT,FB,FRIFL,T,A)
+         GOTO 330
+   33    CONTINUE
+  330    CONTINUE        
+C             If a T dependent limb darkening is used you should
+C             iterate correcting  t and then returninig to compute 
+C             reflection with the new limb.dark. coefficient.
+C             This is not implemented being a too heavy computation.
+C
+C      Reflection elapsed time computation
+          IF(PRINT6) THEN
+          TEMPO=SECNDS(TEMPO0)
+          TEMPD=TEMPO-TEMPREC
+          TEMPREC=TEMPO
+          TEMPREF=TEMPREF+TEMPD
+          IF (PRINT6) WRITE(6,8003) TEMPD,TEMPREF
+C          IF (PRINTFILE) WRITE(NFILE,8003) TEMPD,TEMPREF
+ 8003  FORMAT(/' Elapsed time for reflection:',5X,G20.5,
+     1                                  5X,' Total:',G20.5/)
+          ENDIF
+C
+       ENDIF
+C              ........... Set reflection source to zero(Fbolref,frifl=0)
+       IF(IFLAG(10).GT.0) THEN
+          MODFLAG(10)=1
+          CALL NOREFL(NPNT,NIF,FBOLREF,FRIFL)             
+       ENDIF          
+C
+C                                 ---------------------
+C     ..........................  TOTAL BOLOMETRIC FLUX
+C                                 ---------------------
+C
+C      Computing FBOL : total bolometric flux for
+C      each object. 
+C      FBOLTOT, flux normalization factor is set =1.
+C      Flux normalization is performad after colour band computation
+C
+       DO 35 IS=1,3
+       NIS=NIF(1,IS)
+       IF(NIS.LE.0) GOTO 35
+       NPSS=NP123(IS)
+       IF(NPSS.LE.0) GOTO 35
+       CALL TOTALE(NPSS,FBOL(IS),FB(NIS))           
+       FBOLTOT(IS)=1.
+   35  CONTINUE
+C
+C                                           --------------------------
+C                      ================ =>  |  SETS COLOUR BAND FLUX |
+C                                           --------------------------
+C
+C      ------------------------------------------loop on stars and disk
+       DO 40 IS=1,3
+       NIS=NIF(1,IS)
+       IF(NIS.LE.0) GOTO 40
+       NPSS=NP123(IS)
+       IF(NPSS.LE.0) GOTO 40
+C      ............................ Sets the flux of each color band:
+C             F(surf.el,colour)=FB(surf.el) * flux fraction in the colour
+C             We have the following choices:
+C                a)- alfrac>0 alfrac is used, flux is not computed
+C                    indepentent on alam1=alam2, alam1<>alam2
+C                b)- alfrac<0 band flux is computed for each surf. element
+C                    T of single surf. el. is adjusted after reflection
+C                    in loop 33 
+C                c)- alfrac=0 colour band flux is computed from avarage T
+C                    (not corrected for reflection)
+C
+C                1   - monocromatic flux :alam1=alam2 
+C                2   - band flux by integrating planK*colour filter
+C      -----------------------------------------loop on colors
+       DO 44 IB=1,NBANDE
+C                      If the color band IB isn't requested goes on
+       IF(IFLAG(IB+3).LE.0) GOTO 44       
+       K1=IPPAR1(IB+3)+1
+       ALFRAC=PAR(K1+IS)
+       TEMPER=PARS(10,IS)
+       ALAM1=PAR(IPPAR1(IB+3))
+       ALAM2=PAR(IPPAR1(IB+3)+1)
+       IF(ALFRAC.GT.0.0) THEN
+C            input  given flux fraction in the band F=(FB+FRIFL)*ALFRAC
+             CALL BANDFIL(NPSS,ALFRAC,FB(NIS),FRIFL(NIS),F(NIS,IB))
+       ELSE IF(ALAM1.EQ.ALAM2) THEN
+C      monocromatic light curve
+             IF(ALFRAC.EQ.0.0) THEN
+C                monocromatic flux FRACTION from pole temperature   
+C                plankl=plank*deltal with deltal=1.E-8cm
+                 BANDL=PLANKL(ALAM1,TEMPER)/(AC4PI*TEMPER**4)
+C                fills F with (FB+FRIFL)*bandl (FB=flux*area)
+                 CALL BANDFIL(NPSS,BANDL,FB(NIS),FRIFL(NIS),F(NIS,IB))
+             ELSE IF(ALFRAC.LT.0.0) THEN
+C                monocromatic flux fraction from t of each surf el.
+                 CALL BANDATM(NPSS,ALAM1,T(NIS),F(NIS,IB),FB(NIS),
+     1                                                   FRIFL(NIS))
+C                bandl=sum(f*area) tot flux in band for object
+             ENDIF
+       ELSE 
+C      if (alam1.ne.alam2) : integrating flux over colour bands
+             IF(ALFRAC.EQ.0.0) THEN
+C            flux frac.by integrating plank( T pole) over the colour bands
+                 CALL BANDAC(TOTBAND,TEMPER,NLAMBDA(IB),DELTALAM(IB),
+     1               ALAMBDA(1,IB),TRASMISS(1,IB) )
+                 BANDL=TOTBAND/(AC4PI*TEMPER**4)
+                 CALL BANDFIL(NPSS,BANDL,FB(NIS),FRIFL(NIS),F(NIS,IB))
+             ELSE IF(ALFRAC.LT.0.0) THEN
+C            flux frac.by integrating plank( T for each surf.el.)over bands
+C            this can be a very heavy computation, don't use.
+                 CALL BANDAT(NPSS,T(NIS),F(NIS,IB),FB(NIS),FRIFL(NIS),
+     1           NLAMBDA(IB),DELTALAM(IB),ALAMBDA(1,IB),TRASMISS(1,IB))
+C                bandl=sum(f*A) flux in band for object
+             ENDIF
+       ENDIF           
+       CALL TOTALE(NPSS,TOTBAND,F(NIS,IB))
+       COMPFRAC(IB,IS)=TOTBAND
+C         
+C      Colour band flux elapsed time computation
+       IF(IFLAG(20).GT.0) THEN
+       TEMPO=SECNDS(TEMPO0)
+       TEMPD=TEMPO-TEMPREC
+       TEMPREC=TEMPO
+       TEMPCOL=TEMPCOL+TEMPD
+       IF(PRINT6) WRITE(6,8004) TEMPD,TEMPCOL
+C       IF(PRINTFILE) WRITE(NFILE,8004)TEMPD,TEMPCOL
+ 8004  FORMAT(/' Elapsed time for color band:',5X,G20.5,5X,
+     1                                          ' Total:',G20.5/)
+       ENDIF
+C
+   44  CONTINUE
+C      -------------------------------------- END of color loop
+   40  CONTINUE
+C      -------------------------------------- end of stars loop
+C
+C                                 ---------------------
+C     ..........................    FLUX NORMALIZATION
+C                                 ---------------------
+C
+C      If a flux is input given for the object, normalizes the 
+C      BOL.flux + REFLECTION  to the input  flux. 
+C      or to BOL.flux (without reflection)
+C      Reflection source is normalize in the same way. The colour
+C      band flux is also normalized in a consistent way.
+C
+       DO 45 IS=1,3
+       NIS=NIF(1,IS)
+       IF(NIS.LE.0) GOTO 45
+       NPSS=NP123(IS)
+       IF(NPSS.LE.0) GOTO 45
+C      .................... if normalization requested by input
+       IF(PARS(11,IS).LE.0.0) GOTO 45 
+C
+C      FACTOR=PARS(11,IS)/(FBOL(IS)+FBOLREF(IS))
+       FACTOR=PARS(11,IS)/FBOL(IS)
+C      ..............bolometric flux normalization
+       CALL NORM(NPSS,FACTOR,FB(NIS))
+       FBOL(IS)=PARS(11,IS)
+       FBOLTOT(IS)=1./FACTOR
+C      ..............reflected flux normalization ( if reflection is used )
+       IF(IFLAG(9).GT.0.AND.IFLAG(10).LE.0) 
+     1                    CALL NORM(NPSS,FACTOR,FRIFL(NIS))
+       FBOLREF(IS)=FBOLREF(IS)*FACTOR
+C          ..............color flux normalization ( only for used color bands)
+       DO 47 IB=1,NBANDE
+       IF(IFLAG(IB+3).LE.0) GOTO 47
+       CALL NORM(NPSS,FACTOR,F(NIS,IB))
+       COMPFRAC(IB,IS)=COMPFRAC(IB,IS)*FACTOR
+   47  CONTINUE           
+   45  CONTINUE
+C
+C      Normalization elapsed time computation
+       IF(IFLAG(20).GT.0) THEN
+          TEMPO=SECNDS(TEMPO0)
+          TEMPD=TEMPO-TEMPREC
+          TEMPREC=TEMPO
+          TEMPNORM=TEMPNORM+TEMPD
+          IF (PRINT6) WRITE(6,8015) TEMPD,TEMPNORM
+C          IF (PRINTFILE) WRITE(NFILE,8015) TEMPD,TEMPNORM
+ 8015  FORMAT(/' Elapsed time for flux normalization:',5X,G20.5,
+     1                                  5X,' Total:',G20.5/)
+       ENDIF
+C                                   -----------------------------------
+C            ================== =>  | COMPUTING LIGHT TO THE OBSERVER |
+C                                   -----------------------------------
+C
+C      ..if an object has been redrawn looks for new max and min x-y-z values
+       KTEST=.FALSE.
+       IF(IFLAG(1).GT.0.OR.IFLAG(2).GT.0.OR.IFLAG(3).GT.0) THEN
+C         Maximum absolute value for x,y and z, which is the maximum
+C         radius for the drawn system.
+          CALL MAXABS(CMAX1,NPNT,X)
+          CALL MAXABS(CMAX2,NPNT,Y)
+          CALL MAXABS(CMAX3,NPNT,Z)
+C         The maximum possible linear dimension is the diagonal of x,y,z box
+          CELLMAX=SQRT(CMAX1*CMAX1+CMAX2*CMAX2+CMAX3*CMAX3)
+          CELLMIN=-CELLMAX
+          KTEST=.TRUE.
+       ENDIF
+C
+C      ........................... Set grid points
+       K1=IPPAR1(13)
+       NGP=PAR(K1)
+       IF (NGP.LE.0.OR.NGP.GT.MAXCELL) THEN
+          NGP=MAXCELL
+          WRITE(6,3200) PAR(K1),NGP,NGP
+          IF(PRINTFILE) WRITE(NFILE,3200)  PAR(K1),NGP,NGP
+ 3200     FORMAT(/' WARNING! The input number of grid points:',G15.7,
+     1    ' can''t be greater than:',I5/
+     2    ' If you need a greater value go to the FORTRAN list to',
+     3    ' change MAXCELL=',I5)
+       ENDIF
+       IF (NCELL.NE.NGP.OR.KTEST) THEN
+       NCELL=NGP
+       DCELL=(CELLMAX-CELLMIN)/NCELL
+       CALL DOCELLS(NCELL,DCELL,CELLMIN,XCELL,YCELL)
+       ENDIF 
+C
+       ANGLEI=(PI/180.)*PAR(IPPAR1(11))
+       COSI=COS(ANGLEI)
+       SINI=SIN(ANGLEI)
+       IF(ABS(COSI).LT.R4PREC) COSI=0.0
+       IF(ABS(SINI).LT.R4PREC) SINI=0.0
+C
+       CALL LUCE1(NPRINT,PRINT6,PRINTFILE,NFILE,NPRINTL,COSI,SINI,
+     1           R4PREC,CELLMAX,CELLMIN,DCELL,NCELL,XCELL,YCELL,ICELL,
+     2           AUS,AUS1,AUS2,AUS3,IFLAG(4))
+C
+C      Normalizing to unit max. the light curve, 
+C       for bolometric flux and each used color band 
+       K1=IPPAR1(12)+2
+       ANORMC=PAR(K1)
+       IF(ANORMC.GT.0.0) CALL NORMC(ANORMC,IFLAG(4))
+C
+C      Light to observer elapsed time computation
+       IF(IFLAG(20).GT.0) THEN
+       TEMPO=SECNDS(TEMPO0)
+       TEMPD=TEMPO-TEMPREC
+       TEMPREC=TEMPO
+       TEMPLUC=TEMPLUC+TEMPD
+       IF(PRINT6) WRITE(6,8005) TEMPD,TEMPLUC
+C       IF(PRINTFILE) WRITE(NFILE,8005)TEMPD,TEMPLUC
+ 8005 FORMAT(/' Elapsed time for received ligth :',G20.5,5X,
+     1                                     ' Total:',G20.5/)
+       ENDIF
+C
+C                                     ------------
+C               =============== =>    | PRINTING |
+C                                     ------------
+       IF (IFLAG(20).GT.0) THEN
+C
+       CALL PRINTING(AMOUNT,NFILE6,NFILE,IPPAR1,IPPAR2,
+     1               NAMFLAG,DESCFLAG,NAMPAR,DESCPAR,AUS)
+C
+C      I/O Elapsed time computation
+       TEMPO=SECNDS(TEMPO0)
+       TEMPD=TEMPO-TEMPREC
+       TEMPREC=TEMPO
+       TEMPIO=TEMPIO+TEMPD
+       IF(PRINT6) WRITE(6,8001) TEMPD,TEMPIO
+C       IF(PRINTFILE) WRITE(NFILE,8001)TEMPD,TEMPIO
+C
+       ENDIF
+C                  
+C
+C                                     ------------
+C               =============== =>    | PLOTTING |
+C                                     ------------
+       IF (IFLAG(21).GT.0) THEN
+C
+       CALL PLOTTING(PRINTFILE,NFILE,PRINT6,
+     1                          AMOUNTP,NFILE6P,NFILEP,NASCIIP) 
+C
+C      I/O Elapsed time computation
+       TEMPO=SECNDS(TEMPO0)
+       TEMPD=TEMPO-TEMPREC
+       TEMPREC=TEMPO
+       TEMPIOP=TEMPIOP+TEMPD
+       IF(PRINT6) WRITE(6,8006) TEMPD,TEMPIOP
+C       IF(PRINTFILE) WRITE(NFILE,8006)TEMPD,TEMPIOP
+ 8006  FORMAT(/' Elapsed time for plot:',12X,G20.5,5X,' Total:',G20.5/)
+C
+       ENDIF
+C                  
+C
+      IFLAG(15)=-1
+      IF(MODFLAG(1).GT.0) IFLAG(1)=-1
+      IF(MODFLAG(2).GT.0) IFLAG(2)=-1
+      IF(MODFLAG(3).GT.0) IFLAG(3)=-1
+      IF(MODFLAG(12).GT.0) IFLAG(12)=-1
+      IF(MODFLAG(9).GT.0) IFLAG(9)=-1
+      IF(MODFLAG(10).GT.0) IFLAG(10)=-1
+C
+C     ...........................................Return to input
+      GOTO 12
+      END 
+C
+       SUBROUTINE ALLSEL(K3,NALL1,NALL2)
+C      ---------------------------------------------------------
+C      This routine, called by subroutine reflect, check the
+C      alignement list, from NALL1 to NALL2 ,deleting all alignement 
+C      passing throught the object K3.
+C      ---------------------------------------------------------
+       PARAMETER (MAXPT=200000 ,MAXALLIN=250000, MAXBANDE=5)
+       PARAMETER (MAXPTC=50000)
+C
+       COMMON /SURFC/ NPNTMXC,NPNTC,NPNT1C,NPNT2C,NPNT3C,
+     A               N1IC,N1FC,N2IC,N2FC,N3IC,N3FC,
+     1               XC(MAXPTC),YC(MAXPTC),ZC(MAXPTC),
+     2               GC(MAXPTC),GXC(MAXPTC),GYC(MAXPTC),GZC(MAXPTC),
+     5               AC(MAXPTC),
+     6               DIMCX(MAXPTC),DIMCY(MAXPTC),DIMCZ(MAXPTC),
+     6               FBC(MAXPTC),FRIFLC(MAXPTC),
+     7               XLIMBC(MAXPTC),NUMOBJC(MAXPTC),ALBC(MAXPTC),
+     8               NUMFINI(MAXPTC)
+      DIMENSION NP123C(3)
+      DIMENSION NIFC(2,3)
+      EQUIVALENCE (NP123C(1),NPNT1C),(NIFC(1,1),N1IC)
+C
+      COMMON /ALLIN/ NALLMX,NALL,ITERDONE,
+     1               ISOUR(MAXALLIN),JRIC(MAXALLIN),
+     2               TRANSFI(MAXALLIN),TRANSFJ(MAXALLIN),
+     3               FSOURI(MAXALLIN),FSOURJ(MAXALLIN),
+     4               FRICI(MAXALLIN),FRICJ(MAXALLIN),
+     5               RIJ(MAXALLIN),
+     6               RXIJ(MAXALLIN),RYIJ(MAXALLIN),RZIJ(MAXALLIN),
+     7               COSGI(MAXALLIN),COSGJ(MAXALLIN),
+     8               IAUS(MAXALLIN)
+C
+C      ..........................................................
+       LOGICAL IAUS,CONDX,CONDY,CONDZ
+C
+C        to avoid looping with no points (nifc(1,k3)=nifc(2,k3)=0)
+       IF(NP123C(K3).LE.0) RETURN
+       IF(NALL1.GT.NALL2) RETURN
+C
+       DO 5 I=NALL1,NALL2
+    5  IAUS(I)=.FALSE.
+C
+C          Loops on alignements, looking for poits in K3 belonging
+C          to the alignement line.
+       N1=NIFC(1,K3)
+       N2=NIFC(2,K3)
+C
+       DO 10 I=NALL1,NALL2
+       DO 20 K=N1,N2
+C
+C               ........ First test into or outside interval
+C         Si puo' semplificare questo groviglio di if ?
+       XIK=( XC(K) - XC(ISOUR(I)) ) 
+C           If X outside interval Rxij
+       ABSD=ABS(DIMCX(K))
+       IF(RXIJ(I).GE.0.) THEN
+           IF(XIK .GT. RXIJ(I)+ABSD .OR. XIK .LT. -ABSD)
+     1                                                  GOTO 20
+       ELSE
+           IF(XIK .LT. RXIJ(I)-ABSD .OR. XIK .GT.  ABSD)
+     1                                                  GOTO 20
+       ENDIF
+C           If Y outside interval  Ryij
+       YIK=( YC(K) - YC(ISOUR(I)) ) 
+       ABSD=ABS(DIMCY(K))
+       IF(RYIJ(I).GE.0.) THEN
+           IF(YIK .GT. RYIJ(I)+ABSD .OR. YIK .LT. -ABSD)
+     1                                                  GOTO 20
+       ELSE
+           IF(YIK .LT. RYIJ(I)-ABSD .OR. YIK .GT.  ABSD)
+     1                                                  GOTO 20
+       ENDIF
+C           If Z outside interval  Rzij
+       ZIK=( ZC(K) - ZC(ISOUR(I)) ) 
+       ABSD=ABS(DIMCZ(K))
+       IF(RZIJ(I).GE.0.0) THEN
+           IF(ZIK .GT. RZIJ(I)+ABSD .OR. ZIK .LT. -ABSD)
+     1                                                  GOTO 20
+       ELSE
+           IF(ZIK .LT. RZIJ(I)-ABSD .OR. ZIK .GT.  ABSD)
+     1                                                  GOTO 20
+       ENDIF
+C
+C       In these cases the x,y, or z condition hasn't been tested before
+       IF(ABS(RXIJ(I)).GT.0.0) THEN
+         CONDX=.TRUE.
+       ELSE
+         CONDX=.FALSE.
+       ENDIF
+       IF(ABS(RYIJ(I)).GT.0.0) THEN
+         CONDY=.TRUE.
+       ELSE
+         CONDY=.FALSE.
+       ENDIF
+       IF(ABS(RZIJ(I)).GT.0.0) THEN
+         CONDZ=.TRUE.
+       ELSE
+         CONDZ=.FALSE.
+       ENDIF
+C              ........ Then test if not on same line 
+       IF(CONDX) THEN
+          IF(CONDY) THEN
+            DUM =DIMCX(K)*RYIJ(I)
+            DUM1=DIMCY(K)*RXIJ(I)
+            AMX=MAX(ABS(DUM+DUM1),ABS(DUM-DUM1))
+            IF( ABS( RYIJ(I)*XIK-RXIJ(I)*YIK ) .GT. AMX ) GOTO 20
+          ENDIF
+          IF(CONDZ) THEN
+            DUM =DIMCX(K)*RZIJ(I)
+            DUM1=DIMCZ(K)*RXIJ(I)
+            AMX=MAX(ABS(DUM+DUM1),ABS(DUM-DUM1))
+            IF( ABS( RZIJ(I)*XIK-RXIJ(I)*ZIK ) .GT. AMX ) GOTO 20
+          ENDIF
+       ENDIF
+       IF(CONDY.AND.CONDZ) THEN
+            DUM =DIMCY(K)*RZIJ(I)
+            DUM1=DIMCZ(K)*RYIJ(I)
+            AMX=MAX(ABS(DUM+DUM1),ABS(DUM-DUM1))
+            IF( ABS( RZIJ(I)*YIK-RYIJ(I)*ZIK ) .GT. AMX ) GOTO 20
+       ENDIF
+C 
+C              ........ The remaining surf. el. are aligned 
+       IAUS(I)=.TRUE.
+C      go to examine the next alignement:
+       GOTO 10
+   20  CONTINUE
+   10  CONTINUE
+C
+C                Now alignements intercepted by K3 are deleted
+       K=NALL1-1
+       DO 30 I=NALL1,NALL2
+C          If true skips over the alignement
+       IF(IAUS(I)) GOTO 30
+       K=K+1   
+       IF(I.EQ.K) GOTO 30
+C         If same position just increases K,otherwise move I to K
+       ISOUR(K)=ISOUR(I)
+       JRIC(K)=JRIC(I)
+       RIJ(K)=RIJ(I)
+C        RXIJ,RYIJ,RZIJ are not mouved, they aren't used anymore
+       COSGI(K)=COSGI(I)
+       COSGJ(K)=COSGJ(I)
+   30  CONTINUE
+       NALL=K
+       RETURN
+       END
+C 
+       FUNCTION AMAX2(N,A)
+C      ----------------------------------------------------
+C      AMAX2=max(a(n))
+C      ----------------------------------------------------
+       DIMENSION A(N)
+       AMAX2=A(1)
+       DO 10 I=2,N
+       IF(A(I).GT.AMAX2) AMAX2=A(I)
+   10  CONTINUE
+       RETURN
+       END
+C
+       SUBROUTINE ASK(N1,N2,NAME,DESC,VALUE)
+C      ----------------------------------------------------
+C      Shows parameter's values and descriptors
+C      ----------------------------------------------------
+       CHARACTER*(*) NAME(N2),DESC(N2)
+       DIMENSION VALUE(N2)
+ 1000  FORMAT(/(1X,A10,5X,A20,'  =  ',G15.7))
+       WRITE(6,1000)(NAME(J),DESC(J),VALUE(J),J=N1,N2)
+       RETURN
+       END
+C
+       SUBROUTINE ASKI(N1,N2,NAME,DESC,IVALUE)
+C      ----------------------------------------------------
+C      Shows flag's values and descriptors
+C      ----------------------------------------------------
+       CHARACTER*(*) NAME(N2),DESC(N2)
+       DIMENSION IVALUE(N2)
+ 1000  FORMAT(/(1X,A10,5X,A20,'  =  ',I2))
+       WRITE(6,1000)(NAME(J),DESC(J),IVALUE(J),J=N1,N2)
+       RETURN
+       END
+C
+       SUBROUTINE BANDAC(BANDL,TEMPER,NL,DELTAL,ALAMBDA,TRASMISS)
+C      ----------------------------------------------------------------
+C      Computes the flux for photometric band , by integration
+C      over the lambda range of  (Plank function * filter transmission),
+C      transmission is defined in common/filtri/.
+C      Computed flux is: erg/cm**2/sec/sterad , 
+C      lambda in  Anstrong in /filtri/ , and in the flux computation.
+C      Simpson rule is used for integration
+C      BANDL= computed integral
+C      alam1,alam2= LAMBDA LIMITS (UNUSED )
+C      TEMPER=temperature
+C      ALAMBDA(NL),TRASMISS(NL)= lambda points and their transmission coeff.
+C      DELTAL=ALAMBDA(2)-ALAMBDA(1) ( Anstrong)
+C
+C      ----------------------------------------------------------------
+C
+       DIMENSION ALAMBDA(NL),TRASMISS(NL)
+C
+C            come e' fatta sotto e' piu' veloce
+C       BANDL=0.0
+C       PLAN3=PLANK(ALAMBDA(1),TEMPER)*TRASMISS(1)
+C       DO 20 J=1,NL-2,2
+C       PLAN1=PLAN3
+C       PLAN2=PLANK(ALAMBDA(J+1),TEMPER)*TRASMISS(J+1)
+C       PLAN3=PLANK(ALAMBDA(J+2),TEMPER)*TRASMISS(J+2)
+C       BANDL=BANDL+(1./3.)*PLAN1+(4./3.)*PLAN2+(1./3.)*PLAN3
+C
+C       DUM=+(1./3.)*PLAN1+(4./3.)*PLAN2+(1./3.)*PLAN3
+C       BANDL=BANDL+DUM
+C       BANDL=BANDL*DELTAL * 1.E-8
+C
+       BANDL=(1./3.)*PLANK(ALAMBDA(1),TEMPER)*TRASMISS(1)
+       DO 20 J=2,NL-3,2
+       BANDL=BANDL+(4./3.)*PLANK(ALAMBDA(J),TEMPER)*TRASMISS(J)+
+     1             (2./3.)*PLANK(ALAMBDA(J+1),TEMPER)*TRASMISS(J+1)       
+   20  CONTINUE
+       BANDL=DELTAL * 1.E-8 *
+     1      (BANDL+(4./3.)*PLANK(ALAMBDA(NL-1),TEMPER)*TRASMISS(NL-1)+
+     2             (1./3.)*PLANK(ALAMBDA(NL),TEMPER)*TRASMISS(NL) )
+       RETURN
+       END
+C
+       SUBROUTINE BANDAC1(TOTTOT,TEMPER,NL,DELTAL,ALAMBDA,TRASMISS)
+C      ----------------------------------------------------------------
+C      UNUSED ROUTINE, THIS SHOULD SUBSTITUTE BANDAC, BEING MORE
+C      PRECISE, BUT THE LINK BETWEEN PLANK LUMINOSITIES IN DIFFERENT
+C      BANDS AND MAGNITUDE IS NOT WELL ESTABLISHED, FOR THIS REASON
+C      YOU HAVE ALWAYS AN UNDEFINED MAG. ZERO POINT IN DIFFERENT COLORS
+C      AND A DETAILED INTEGRATION AVER PLANK FUNCTION IS UNUSEFUL
+C
+C      Computes the flux for photometric band , by integration
+C      over the lambda range of  (Plank function * filter transmission),
+C      transmission is defined in common/filtri/. for few lambda points.
+C      Simpson rule is used for integration, using many points and
+C      interpolating (linear) over the given transmission values 
+C      Computed flux is: erg/cm**2/sec/sterad , 
+C      lambda in  Anstrong in /filtri/ , but used in cm in the
+C      flux computation.
+C      TOTTOT= computed integral
+C      TEMPER=temperature
+C      ALAMBDA(NL),TRASMISS(NL)= lambda points and their transmission coeff.
+C      DELTAL = delta lambda for tabulated values in /filtri/ (UNUSED )
+C      ----------------------------------------------------------------
+C
+       PARAMETER NSTEPS=20
+       DIMENSION ALAMBDA(NL),TRASMISS(NL)
+C
+       TOTTOT=0.0
+       DO 10 I=1,NL-1
+       AL1=ALAMBDA(I)
+       AL2=ALAMBDA(I+1)
+       T1=TRASMISS(I)
+       T2=TRASMISS(I+1)
+       DL=(AL2-AL1)/NSTEPS 
+C      changing DL from Anstrong to cm
+       DL=DL*1.E-8      
+C
+       P1=PLANK(AL1,TEMPER)
+       P2=PLANK(AL2,TEMPER)
+       TOT=(1./3.)*T1*P1 + (1./3.)*T2*P2 
+       DO 20 J=2,NSTEPS-2,2
+       AL=AL1+(J-1)*DL
+       T=( (T2-T1)/(AL2-AL1) ) * (AL-AL1) + T1
+       TOT=TOT + (4./3.)*T* PLANK(AL,TEMPER)
+       AL=AL1+J*DL
+       T=( (T2-T1)/(AL2-AL1) ) * (AL-AL1) + T1
+       TOT=TOT + (2./3.)* PLANK(AL,TEMPER)*T
+  20   CONTINUE
+       AL=AL2-DL
+       T=( (T2-T1)/(AL2-AL1) ) * (AL-AL1) + T1
+       TOT=TOT + (4./3.)* PLANK(AL,TEMPER)*T
+       TOTTOT=TOTTOT+TOT*DL
+  10   CONTINUE
+       RETURN
+       END
+C
+       SUBROUTINE BANDAT(NPNT,T,F,FB,FR,NL,DELTAL,ALAMBDA,TRASMISS)
+C      -----------------------------------------------------------
+C      This routine integrates the black body spectrum over
+C      a given lambda interval for each surface element.
+C      -----------------------------------------------------------
+       DIMENSION   T(NPNT),F(NPNT),FB(NPNT),FR(NPNT)
+       DIMENSION ALAMBDA(NL),TRASMISS(NL)
+       PARAMETER AC4PI=1.8065E-5
+C
+       DO 10 I=1,NPNT
+       TEMPER=T(I)
+C      integration over colour band
+       CALL BANDAC(TOTBAND,TEMPER,NL,DELTAL,ALAMBDA,TRASMISS)
+       F(I)=TOTBAND/(AC4PI*TEMPER**4) * (FB(I)+FR(I))
+   10  CONTINUE
+C
+       RETURN
+       END      
+C
+       SUBROUTINE BANDATM(NPNT,ALAM,T,F,FB,FR)
+C      -----------------------------------------------------------
+C      This routine fills F with bolometric flux FB * flux fraction
+C      in a given lambda 
+C      FUNCTION PLANKL=PLANK*1.E-8cm = plank*delta lambda
+C      -----------------------------------------------------------
+       DIMENSION   T(NPNT),F(NPNT),FB(NPNT),FR(NPNT)
+       PARAMETER AC4PI=1.8065E-5
+C
+       DO 10 I=1,NPNT
+       F(I)=PLANKL(ALAM,T(I))/(AC4PI*T(I)**4) * (FB(I)+FR(I))
+   10  CONTINUE
+C
+       RETURN
+       END      
+C
+       SUBROUTINE BANDFIL(NPNT,B,FB,FR,FBANDA)
+C      -----------------------------------------------------------
+C      This routine assign a given fraction B of the bolometric
+C      flux B to the color band FBANDA.
+C      -----------------------------------------------------------
+       DIMENSION FB(NPNT),FBANDA(NPNT),FR(NPNT)
+       DO 10 I=1,NPNT
+   10  FBANDA(I)=(FB(I)+FR(I))*B       
+       RETURN
+       END
+C
+       SUBROUTINE CALCALL(ALBEDO)
+C      ----------------------------------------------------
+C      This routine, called by Reflect,  computes the 
+C      remaining data for each allignement, and, for each
+C      allignement I-J, inserts the inverse allignement J-I
+C      ----------------------------------------------------
+       PARAMETER (MAXPT=200000 ,MAXALLIN=250000, MAXBANDE=5)
+       PARAMETER (MAXPTC=50000)
+       PARAMETER (PI4=1./(3.1415926*4.))
+       PARAMETER PI=3.1415926
+C
+       COMMON /SURFC/ NPNTMXC,NPNTC,NPNT1C,NPNT2C,NPNT3C,
+     A               N1IC,N1FC,N2IC,N2FC,N3IC,N3FC,
+     1               XC(MAXPTC),YC(MAXPTC),ZC(MAXPTC),
+     2               GC(MAXPTC),GXC(MAXPTC),GYC(MAXPTC),GZC(MAXPTC),
+     5               AC(MAXPTC),
+     6               DIMCX(MAXPTC),DIMCY(MAXPTC),DIMCZ(MAXPTC),
+     6               FBC(MAXPTC),FRIFLC(MAXPTC),
+     7               XLIMBC(MAXPTC),NUMOBJC(MAXPTC),ALBC(MAXPTC),
+     8               NUMFINI(MAXPTC)
+      DIMENSION NP123C(3)
+      DIMENSION NIFC(2,3)
+      EQUIVALENCE (NP123C(1),NPNT1C),(NIFC(1,1),N1IC)
+C
+C 
+      COMMON /ALLIN/ NALLMX,NALL,ITERDONE,
+     1               ISOUR(MAXALLIN),JRIC(MAXALLIN),
+     2               TRANSFI(MAXALLIN),TRANSFJ(MAXALLIN),
+     3               FSOURI(MAXALLIN),FSOURJ(MAXALLIN),
+     4               FRICI(MAXALLIN),FRICJ(MAXALLIN),
+     5               RIJ(MAXALLIN),
+     6               RXIJ(MAXALLIN),RYIJ(MAXALLIN),RZIJ(MAXALLIN),
+     7               COSGI(MAXALLIN),COSGJ(MAXALLIN),
+     8               IAUS(MAXALLIN)
+C
+C      ...............................................................
+C         Computes limb darkening term, allignement transfer 
+C         function and and set the initial reflection source
+C         for each allignement 
+       DO 30 K=1,NALL
+C        DD= SQRT(RIJ**2)
+       DD=SQRT(RIJ(K))
+C        abs(<surf.norm,rij>) -> abs(<surf.norm,unit vector rij>)=abs(cos)
+       COSGI(K)= COSGI(K) /DD
+       COSGJ(K)=-COSGJ(K) /DD
+C        source and receiving surf. el. for reflection
+       KI=ISOUR(K)
+       KJ=JRIC(K)
+C        albedo for source and receiving surf.el.
+       XCOSGI=  1.0 - ( XLIMBC(KI) * (1.0-COSGI(K)) )
+       XCOSGJ=  1.0 - ( XLIMBC(KJ) * (1.0-COSGJ(K)) )
+       ALBI=ALBC(KI)
+       ALBJ=ALBC(KJ)
+C        transfer function from  I  to J  surf.el. 
+C       TRANSFI(K)=(ALBEDO*PI4)*ALBJ*XCOSGI *COSGJ(K)*
+C     1                                 AC(KJ)/RIJ(K)
+C       TRANSFI(K)=(ALBEDO)*ALBJ*XCOSGI *(COSGJ(K)*COSGI(K))* 
+C     1                                 AC(KJ)/RIJ(K)/PI
+       TRANSFI(K)=(ALBEDO)*ALBJ*XCOSGI *(COSGJ(K)*COSGI(K))* 
+     1           AC(KJ)/RIJ(K)/ (PI*(1.-XLIMBC(KJ)/3.) )
+C        inverse transfer from J to I
+C       TRANSFJ(K)=(ALBEDO*PI4)*ALBI*XCOSGJ *COSGI(K)*
+C     1                                 AC(KI)/RIJ(K)
+C       TRANSFJ(K)=(ALBEDO)*ALBI*XCOSGJ *(COSGJ(K)*COSGI(K))*
+C     1                                 AC(KI)/RIJ(K)/PI
+       TRANSFJ(K)=(ALBEDO)*ALBI*XCOSGJ *(COSGJ(K)*COSGI(K))*
+     1           AC(KI)/RIJ(K)/ (PI*(1.-XLIMBC(KI)/3.) )
+C        initial source for reflection from I to J and inverse path
+       FSOURI(K)=FBC(KI)
+       FSOURJ(K)=FBC(KJ)
+   30  CONTINUE   
+C
+       RETURN
+       END
+C      
+       SUBROUTINE CANCEL(K,NFILE)
+C      -----------------------------------------------------
+C      In the surface element list in common /surf/ 
+C      all the data of object K are deleted, by reordering
+C      of the list.
+C      ----------------------------------------------------
+       PARAMETER (MAXPT=200000 , MAXBANDE=5)
+       PARAMETER (MAXPTC=50000)
+       PARAMETER (NVECT=21+MAXBANDE)
+       PARAMETER (NVECTC=15)
+       COMMON /SURF/ NPNTMX,NPNT,NP(3),NLIM(2,3),
+     1                   VECT(MAXPT,NVECT)
+       COMMON /SURFC/ NPNTMXC,NPNTC,NPC(3),NLIMC(2,3),
+     1                   VECTC(MAXPTC,NVECTC) 
+C       COMMON /SURFC/ NPNTMXC,NPNTC,NPNT1C,NPNT2C,NPNT3C,
+C     A               N1IC,N1FC,N2IC,N2FC,N3IC,N3FC,
+C     1               XC(MAXPTC),YC(MAXPTC),ZC(MAXPTC),
+C     2               GC(MAXPTC),GXC(MAXPTC),GYC(MAXPTC),GZC(MAXPTC),
+C     5               AC(MAXPTC),
+C     6               DIMCX(MAXPTC),DIMCY(MAXPTC),DIMCZ(MAXPTC),
+C     6               FBC(MAXPTC),FRIFLC(MAXPTC),
+C     7               XLIMBC(MAXPTC),NUMOBJC(MAXPTC),ALBC(MAXPTC),
+C     8               NUMFINI(MAXPTC)
+C      DIMENSION NP123C(3)
+C      DIMENSION NIFC(2,3)
+C      EQUIVALENCE (NP123C(1),NPNT1C),(NIFC(1,1),N1IC)
+C
+C           Deleting object K in common /surf/
+C
+       N1=NLIM(1,K)
+       N2=NLIM(2,K)+1
+       NPNTK=N2-N1
+       IF(NPNTK.NE.NP(K)) THEN
+       WRITE(6,1000) K,NP,NLIM
+ 1000  FORMAT(' ERROR! The fine grid surface element list descriptors',
+     1        ' are inconsistent for object:',I5/' descriptors are:'/
+     2        ' number of points for each object:',3I5/
+     3        ' first and last element for each object:',6I5)
+       IF(NFILE.GT.0.AND.NFILE.LE.99) WRITE(NFILE,1000) K,NP,NLIM
+       ENDIF
+C       
+       IF(N2.LE.NPNT) THEN
+C      otherwise a simple change of dimension descriptors deletes the object
+         DO 10 I=1,NVECT
+         DO 10 J=N2,NPNT
+         VECT(J-NPNTK,I)=VECT(J,I)
+   10    CONTINUE
+         DO 20 I=1,3
+         IF(I.EQ.K.OR.NLIM(1,I).LT.N2) GOTO 20
+         NLIM(1,I)=NLIM(1,I)-NPNTK
+         NLIM(2,I)=NLIM(2,I)-NPNTK
+   20    CONTINUE
+       ENDIF
+       NLIM(1,K)=0
+       NLIM(2,K)=0
+       NP(K)=0
+       NPNT=NPNT-NPNTK
+C
+C                       Deleting object K in common /surfc/
+C 
+C       Here NLIMC(2,k) is not used, it can be zero if the
+C       coarse grid map has been computed, but not the coarse surf. elem.
+C       also in this case this common must be compressed; its space
+C       is allocated to object K in any case.
+C
+       N1=NLIMC(1,K)
+       N2=N1+NPC(K)
+       NPNTK=N2-N1
+       IF(N2.LT.N1.OR.N2.GT.NPNTC+1.OR.
+     1       (NLIMC(2,K).GT.0.AND.N2.NE.NLIMC(2,K)+1) ) THEN
+       WRITE(6,3000) K,NPC,NLIMC
+ 3000  FORMAT(' ERROR! The coarse grid surface element list descripto',
+     1        'rs are inconsistent for object:',I5/' descriptors are:'/
+     2        ' number of points for each object:',3I5/
+     3        ' first and last element for each object:',6I5)
+       IF(NFILE.GT.0.AND.NFILE.LE.99) WRITE(NFILE,3000) K,NPC,NLIMC
+       ENDIF
+C       
+       IF(N2.LE.NPNTC) THEN
+C      otherwise a simple change of dimension descriptors deletes the object
+         DO 30 I=1,NVECTC
+         DO 30 J=N2,NPNTC
+         VECTC(J-NPNTK,I)=VECTC(J,I)
+   30    CONTINUE
+         DO 40 I=1,3
+         IF(I.EQ.K.OR.NLIMC(1,I).LT.N2) GOTO 40
+         NLIMC(1,I)=NLIMC(1,I)-NPNTK
+         IF(NLIMC(2,I).GT.0) NLIMC(2,I)=NLIMC(2,I)-NPNTK
+   40    CONTINUE
+       ENDIF
+       NLIMC(1,K)=0
+       NLIMC(2,K)=0
+       NPC(K)=0
+       NPNTC=NPNTC-NPNTK
+       RETURN
+       END
+C
+       SUBROUTINE COARSE(PRINT6,PRINTFILE,NFILE,IS)
+C      ---------------------------------------------
+C      From the coarse map: NUMCOARSE, containig, for
+C      each fine surface element, the number of its
+C      coarse surf. elem., builts the coarse surf. elem.
+C      ------------------------------------------------
+C
+       PARAMETER (MAXPT=200000 , MAXBANDE=5 )
+       PARAMETER (MAXPTC=50000 )
+C
+       COMMON /SURF/ NPNTMX,NPNT,NPNT1,NPNT2,NPNT3,
+     A               N1I,N1F,N2I,N2F,N3I,N3F,
+     1               X(MAXPT),Y(MAXPT),Z(MAXPT),
+     2               G(MAXPT),GX(MAXPT),GY(MAXPT),GZ(MAXPT),
+     3               FX(MAXPT),FY(MAXPT),FZ(MAXPT),
+     4               TX(MAXPT),TY(MAXPT),TZ(MAXPT),
+     5               T(MAXPT),A(MAXPT),
+     6               FB(MAXPT),F(MAXPT,MAXBANDE),FRIFL(MAXPT),
+     7               XLIMB(MAXPT),NUMOBJ(MAXPT),ALB(MAXPT),
+     8               NUMCOARSE(MAXPT)
+      DIMENSION NP123(3)
+      DIMENSION NIF(2,3)
+      EQUIVALENCE (NP123(1),NPNT1),(NIF(1,1),N1I)
+C 
+       COMMON /SURFC/ NPNTMXC,NPNTC,NPNT1C,NPNT2C,NPNT3C,
+     A               N1IC,N1FC,N2IC,N2FC,N3IC,N3FC,
+     1               XC(MAXPTC),YC(MAXPTC),ZC(MAXPTC),
+     2               GC(MAXPTC),GXC(MAXPTC),GYC(MAXPTC),GZC(MAXPTC),
+     5               AC(MAXPTC),
+     6               DIMCX(MAXPTC),DIMCY(MAXPTC),DIMCZ(MAXPTC),
+     6               FBC(MAXPTC),FRIFLC(MAXPTC),
+     7               XLIMBC(MAXPTC),NUMOBJC(MAXPTC),ALBC(MAXPTC),
+     8               NUMFINI(MAXPTC)
+      DIMENSION NP123C(3)
+      DIMENSION NIFC(2,3)
+      EQUIVALENCE (NP123C(1),NPNT1C),(NIFC(1,1),N1IC)
+C 
+      LOGICAL PRINT6,PRINTFILE
+C
+      N1=NIF(1,IS)
+      N2=NIF(2,IS)
+C
+      N1C=NIFC(1,IS)
+      N2C=N1C+NP123C(IS)-1
+C     Nifc(2,.)=0 when coarse map NUMCOARSE exist, but NOT surf.el.     
+      NIFC(2,IS)=N2C
+C
+      DO 10 I=N1C,N2C
+      XC(I)=0.0
+      YC(I)=0.0
+      ZC(I)=0.0
+      GXC(I)=0.0
+      GYC(I)=0.0
+      GZC(I)=0.0
+      AC(I)=0.0
+      FBC(I)=0.0
+      FRIFLC(I)=0.0
+      XLIMBC(I)=0.0
+      ALBC(I)=0.0
+      DIMCX(I)=0.0
+      DIMCY(I)=0.0
+      DIMCZ(I)=0.0
+      NUMFINI(I)=0
+      NUMOBJC(I)=IS
+   10 CONTINUE
+C
+      DO 20 I=N1,N2
+      K=NUMCOARSE(I)
+      IF(K.GT.N2C.OR.K.LT.N1C) THEN
+        WRITE(6,1000) I,NUMOBJ(I),K,IS
+        IF(PRINTFILE) WRITE(NFILE,1000) I,NUMOBJ(I),K,IS
+ 1000   FORMAT(/' ERROR! , surface element:',I6,' belonging to the'
+     1       ' object:',I3/' assigned to coarse point:',I6,
+     2       ' belonging to the wrong object:',I3)
+        GOTO 20
+      ENDIF
+C     The coarse X,Y,Z etc are obtained by a weighted mean of
+C     their fine surf.interval (fine surf.el. areas are weights);
+C     to shorten the calculation you can simply sum The fine's x,y,z;
+C     then divide by NUMFINI. This could be a not too bad approximation.
+      NUMFINI(K)=NUMFINI(K)+1
+      XC(K)=XC(K)+X(I)    *A(I)
+      YC(K)=YC(K)+Y(I)    *A(I)
+      ZC(K)=ZC(K)+Z(I)    *A(I)
+      GXC(K)=GXC(K)+GX(I) *A(I)
+      GYC(K)=GYC(K)+GY(I) *A(I)
+      GZC(K)=GZC(K)+GZ(I) *A(I)
+      AC(K)=AC(K)+A(I)
+      FBC(K)=FBC(K)+FB(I)
+      XLIMBC(K)=XLIMBC(K)+XLIMB(I) *A(I)
+      ALBC(K)=ALBC(K)+ALB(I)       *A(I)
+      DIMCX(K)=DIMCX(K)+ FX(I)+TX(I)
+      DIMCY(K)=DIMCY(K)+ FY(I)+TY(I)
+      DIMCZ(K)=DIMCZ(K)+ FZ(I)+TZ(I)
+   20 CONTINUE
+C
+      DO 30 I=N1C,N2C
+      XC(I)=XC(I) /AC(I)
+      YC(I)=YC(I) /AC(I)
+      ZC(I)=ZC(I) /AC(I)
+      GXC(I)=GXC(I)/AC(I)
+      GYC(I)=GYC(I)/AC(I)
+      GZC(I)=GZC(I)/AC(I)
+      XLIMBC(I)=XLIMBC(I)/AC(I)
+      ALBC(I)=ALBC(I)    /AC(I)
+   30 CONTINUE
+C           renormalizing G
+      DO 35 I=N1C,N2C
+      GC(I)=SQRT(GXC(I)*GXC(I)+GYC(I)*GYC(I)+GZC(I)*GZC(I))
+      GXC(I)=GXC(I)/GC(I)
+      GYC(I)=GYC(I)/GC(I)
+      GZC(I)=GZC(I)/GC(I)
+   35 CONTINUE
+C      
+      RETURN
+      END
+C 
+       SUBROUTINE CYL(PRINT6,PRINTFILE,NFILE,NRF,NTHF,NCORD,PKRI,NOBJ,
+     1       NPUNT,NPUNTC,R,RI,H,HI,X0,Y0,Z0,ALZO,ROTAZ,R4PREC,
+     2       NPNTMX,X,Y,Z,G,GX,GY,GZ,FX,FY,FZ,TX,TY,TZ,AREA,A,NUMCOARSE,
+     3       NUMOBJ, R2,RR,RFACTOR,SINF,COSF)
+C      ----------------------------------------------------------------
+C      Drawn a cylindrica surface, see sfera2 for general comments.       
+C      NRF= number of fine r mesh in which R-RI is divided.
+C      NTHF= coarsing factor=number of fine for each coarse
+C      NRC= number of r coarse
+C      NFC= number of phi coarse (r dependent and >=4 )
+C      After drawing on the plane x-y the cylinder can be rotated:
+C      ROTAZ= anti-clockwise angle of rotazion on the plane (x-x'angle)
+C      ALZO= clockwise rotation around the y' axis (z-z" angle)
+C      Ater the rotation the disk is shifted from (0,0,0) in (x0,y0,z0)
+C
+C      NOBJ: number of this object, numobj(side surf.el)=nobj or nobj+3 
+C          if angle>r4prec ( to represent a concave obj. by two finctious ones,
+C          avoiding in this way disk transparency in luce1 )
+C      ######## se si abbandona la simmetria di rotazione per il disco 
+C      si devono aumentare il numero di oggetti che lo rappresentano, perche'
+C      non diventi trasparente ########################################
+C      ----------------------------------------------------------------
+       DIMENSION X(NPNTMX),Y(NPNTMX),Z(NPNTMX)
+       DIMENSION G(NPNTMX),GX(NPNTMX),GY(NPNTMX),GZ(NPNTMX)
+       DIMENSION FX(NPNTMX),FY(NPNTMX),FZ(NPNTMX)
+       DIMENSION TX(NPNTMX),TY(NPNTMX),TZ(NPNTMX)
+       DIMENSION A(NPNTMX)
+       DIMENSION NUMCOARSE(NPNTMX),NUMOBJ(NPNTMX)
+       DIMENSION R2(NTHF),RR(NTHF),RFACTOR(NTHF),SINF(NTHF),COSF(NTHF)
+       LOGICAL PRINTFILE,PRINT6
+       DATA PI /3.1415926/
+C       DATA PI /3.141592653589793/
+C       REAL*8 PI
+C
+       WIDTH5=(H-HI)*0.5
+       HI2=HI*0.5
+C         Disk thikening angle
+       ANGLE=ATAN2(WIDTH5,R-RI)
+       COSA=COS(ANGLE)
+       SINA=SIN(ANGLE)
+       IF(ABS(SINA).LT.R4PREC) SINA=0.0
+       TANA=TAN(ANGLE)
+       IF(ABS(TANA).LT.R4PREC) TANA=0.0
+       COSA1=1./COSA
+       NOBJ1=NOBJ
+       IF(ANGLE.GT.R4PREC) NOBJ1=NOBJ+3
+C
+C          Coarse mesh
+       NRC=NRF/NTHF
+       IF(MOD(NRF,NTHF).NE.0) THEN
+         WRITE(6,1000) NRF,NTHF
+ 1000    FORMAT(' ERROR! In drawing a cylinder the number of r mesh:',
+     1           I5,' is not consistent with the coarsing factor:',I5)
+       ENDIF
+C
+C      1/cosa isn't included here: meshing is done on the disk central plane 
+       DRC=(R-RI)/NRC
+       DRC5=DRC*0.5
+C         fine r mesh
+       DRF=DRC/NTHF
+       DRF5=DRF*0.5
+       DRF5TANA=DRF5*TANA
+C
+C      NPUNTC will be incremented below. (NPUNTC is the first void coarse)
+C      IC is instead the actual coarse, or the last filled one.
+C      NPUNT is the number of surf.el. generated by this routine 
+       IC=NPUNTC-2
+       NPUNT=0
+       AREA=0.0
+C
+C      ................... Coarse R loop ( from center RI to R)
+       DO 10 IRC=1,NRC
+       R1C=RI+(IRC-1)*DRC
+       R2C=R1C+DRC
+C      Number of phi coarse for this Radius
+       NFC=(2.*PI)*R2C/DRC
+       IF(NFC.LT.4) NFC=4
+       DFC=(2.*PI)/NFC
+C
+C      Radius fine for this R coarse
+       DUM=R1C
+       DO 15 I=1,NTHF
+       R1   =DUM
+       R2(I)=DUM+DRF
+       RR(I)=DUM+DRF5
+       RFACTOR(I)=COSA1 * (R2(I)-R1)*(R2(I)+R1)
+       DUM=DUM+DRF
+   15  CONTINUE
+C
+C      ...................... PHI coarse loop
+       DO 10 IFC=1,NFC
+       F1C=(IFC-1)*DFC
+       F2C=F1C+DFC
+C      coarse surf.el. number
+       IC=IC+2
+C      PHI  fine interval
+       DFF=DFC/NTHF      
+       DFF5=DFF*0.5
+C      Cord, arch or tangent value for surf el. extension
+       IF(NCORD.EQ.2) THEN
+         SINF5=SIN(DFF5)      
+       ELSE IF (NCORD.GE.3) THEN
+         TANF5=TAN(DFF5)
+       ENDIF
+C
+C      First phi fine value fi coarse refers to the interval boundaries, 
+C      fi fine is shifted at the interval center (+DFF5)
+       F=F1C-DFF5
+C      sin and cos(f) values for this range if phi fine
+       DO 35 I=1,NTHF
+       F=F+DFF
+       COSF(I)=COS(F)
+       SINF(I)=SIN(F)
+   35  CONTINUE
+C
+C      .................... LOOP on phi fine interv. of coarse
+       DO 10 IFF=1,NTHF
+C
+C      .................... LOOP on R fine interval of coarse
+       DO 10 IRF=1,NTHF
+C                
+       IF(NCORD.LE.1) THEN
+          CORDA=DFF5  * R2(IRF)
+       ELSE IF(NCORD.EQ.2) THEN
+          CORDA=SINF5 * R2(IRF)
+       ELSE
+          CORDA=TANF5 * R2(IRF)
+       ENDIF
+C
+C         Upper surface point
+       IF(NPUNT.GE.NPNTMX) THEN
+                           LOST=LOST+2
+                           GOTO 10
+                       ELSE
+                       NPUNT=NPUNT+1
+                       ENDIF
+       X(NPUNT)=        RR(IRF)*COSF(IFF) 
+       Y(NPUNT)=        RR(IRF)*SINF(IFF) 
+       Z(NPUNT)= HI2  + RR(IRF)*TANA      
+       GX(NPUNT)=-SINA*COSF(IFF)
+       GY(NPUNT)=-SINA*SINF(IFF)
+       GZ(NPUNT)= COSA
+       FX(NPUNT)=-CORDA*SINF(IFF)
+       FY(NPUNT)= CORDA*COSF(IFF)
+       FZ(NPUNT)=0.
+       TX(NPUNT)= DRF5*COSF(IFF)
+       TY(NPUNT)= DRF5*SINF(IFF) 
+       TZ(NPUNT)= DRF5TANA
+       A(NPUNT)=DFF5*RFACTOR(IRF)
+       NUMCOARSE(NPUNT)=IC
+       NUMOBJ(NPUNT)=NOBJ
+C      area computation
+       AREA=A(NPUNT)+AREA
+C
+C         Lower surface point
+       NPUNT1=NPUNT
+       NPUNT=NPUNT+1
+       X(NPUNT)= X(NPUNT1)
+       Y(NPUNT)= Y(NPUNT1)
+       Z(NPUNT)=-Z(NPUNT1)
+       GX(NPUNT)= GX(NPUNT1)
+       GY(NPUNT)= GY(NPUNT1)
+       GZ(NPUNT)=-GZ(NPUNT1)
+       FX(NPUNT)=FX(NPUNT1)
+       FY(NPUNT)=FY(NPUNT1)
+       FZ(NPUNT)=0.
+       TX(NPUNT)= TX(NPUNT1)
+       TY(NPUNT)= TY(NPUNT1)
+       TZ(NPUNT)= TZ(NPUNT1)
+       A(NPUNT)=A(NPUNT1)
+       NUMCOARSE(NPUNT)=IC+1
+       NUMOBJ(NPUNT)=NOBJ
+C      Total area computation
+       AREA=A(NPUNT)+AREA
+C
+   10  CONTINUE
+C
+C      The IC+1 coarse has been filled by loop 10
+       IC=IC+1
+C
+C      If this cylinder had a widht the side surface is drawn
+C
+       IF(H.LE.R4PREC) GOTO 400
+C
+C      coarse and fine h and fi interval definition
+       NHC=INT(H/DRC)
+       IF(NHC.LE.0) NHC=1
+       DHC=H/NHC
+       DHC5=DHC*0.5
+       DHF=DHC/NTHF
+       DHF5=DHF*0.5
+       NFC=(2.*PI)*R/DRC
+       IF(NFC.LT.4) NFC=4
+       DFC=(2.*PI)/NFC
+       DFF=DFC/NTHF
+       DFF5=DFF*0.5
+C
+       IF(NCORD.LE.1) THEN
+         CORDA=R*DFF5
+       ELSE IF(NCORD.EQ.2) THEN
+         CORDA=R*SIN(DFF5)
+       ELSE
+         CORDA=R*TAN(DFF5)
+       ENDIF
+C
+       AREAR=R*DFF*DHF
+C
+C      ........................ LOOP on phi coarse
+       DO 60 IFC=1,NFC
+       F1C=(IFC-1)*DFC
+C       sinf and cosf fine of this coarse
+       DUM=F1C-DFF5
+       DO 65 I=1,NTHF
+       DUM=DUM+DFF
+       COSF(I)=COS(DUM)
+       SINF(I)=SIN(DUM)
+   65  CONTINUE
+C
+C      ....................... Loop on H coarse
+       DO 60 IHC=1,NHC
+C      lower z value (going from -H to (h-dhc))
+       H1=-H*0.5-DHF5+(IHC-1)*DHC
+C
+       IC=IC+1
+C      
+C      ...................... LOOP on phi fine
+       DO 60 IFF=1,NTHF
+C
+C      ........................ LOOP on H fine
+       DO 60 IHF=1,NTHF
+       HF=H1 + IHF*DHF
+C
+       IF(NPUNT.GE.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 60
+                       ELSE
+                       NPUNT=NPUNT+1
+                       ENDIF
+       X(NPUNT)=R*COSF(IFF) 
+       Y(NPUNT)=R*SINF(IFF) 
+       Z(NPUNT)=HF
+       GX(NPUNT)=COSF(IFF)
+       GY(NPUNT)=SINF(IFF)
+       GZ(NPUNT)=0.0
+       FX(NPUNT)=-CORDA*SINF(IFF)
+       FY(NPUNT)= CORDA*COSF(IFF)
+       FZ(NPUNT)=0.
+       TX(NPUNT)=0.0 
+       TY(NPUNT)=0.0
+       TZ(NPUNT)= -DHF5 
+       A(NPUNT)=AREAR
+       NUMCOARSE(NPUNT)=IC
+       NUMOBJ(NPUNT)=NOBJ1
+C           Total area computation
+       AREA=AREA + A(NPUNT)
+C 
+   60  CONTINUE
+C 
+ 400   CONTINUE
+C         internal surface is drawn
+       IF(HI.LE.R4PREC.OR.RI.LE.R4PREC.OR.PKRI.LE.0) GOTO 500
+C
+C      coarse and fine height mesh
+       NHC=INT(HI/DRC)
+       IF(NHC.LE.0) NHC=1
+       DHC=HI/NHC
+       DHC5=DHC*0.5
+       DHF=DHC/NTHF
+       DHF5=DHF*0.5
+C      phi coarse mesh
+       NFC=(2.*PI)*RI/DRC
+       IF(NFC.LT.4) NFC=4
+       DFC=(2.*PI)/NFC
+       DFF=DFC/NTHF
+       DFF5=DFF*0.5
+C      Area for each fine interval
+       AREAR=RI*DFF*DHF
+C
+       IF(NCORD.LE.1) THEN
+         CORDA=RI*DFF5
+       ELSE IF(NCORD.EQ.2) THEN
+         CORDA=RI*SIN(DFF5)
+       ELSE
+         CORDA=RI*TAN(DFF5)
+       ENDIF
+C      ........................ LOOP on phi coarse
+       DO 70 IFC=1,NFC
+       F1C=(IFC-1)*DFC
+C       sinf and cosf fine of this coarse
+       DUM=F1C-DFF5
+       DO 75 I=1,NTHF
+       DUM=DUM+DFF
+       COSF(I)=COS(DUM)
+       SINF(I)=SIN(DUM)
+   75  CONTINUE
+C
+C      ....................... Loop on H coarse
+       DO 70 IHC=1,NHC
+C      lower z value (going from -Hi to (hi-dhc))
+       H1=-HI*0.5-DHF5 + (IHC-1)*DHC
+C
+       IC=IC+1
+C      
+C      ...................... LOOP on phi fine
+       DO 70 IFF=1,NTHF
+C
+C      ........................ LOOP on H fine
+       DO 70 IHF=1,NTHF
+       HF=H1+ IHF*DHF
+C
+       IF(NPUNT.GE.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 70
+                       ELSE
+                       NPUNT=NPUNT+1
+                       ENDIF
+       X(NPUNT)=RI*COSF(IFF) 
+       Y(NPUNT)=RI*SINF(IFF) 
+       Z(NPUNT)=HF
+       GX(NPUNT)=COSF(IFF)
+       GY(NPUNT)=SINF(IFF)
+       GZ(NPUNT)=0.0
+       FX(NPUNT)=-CORDA*SINF(IFF)
+       FY(NPUNT)= CORDA*COSF(IFF)
+       FZ(NPUNT)=0.
+       TX(NPUNT)=0.0
+       TY(NPUNT)=0.0
+       TZ(NPUNT)=DHF5
+       A(NPUNT)=AREAR
+       NUMCOARSE(NPUNT)=IC
+       NUMOBJ(NPUNT)=NOBJ1
+C           Total area computation
+       AREA=A(NPUNT)+AREA
+C 
+   70  CONTINUE
+C         ..................    END OF DISK SURFACE DRAWING !       
+ 500   CONTINUE
+       NPUNTC=IC+1
+C
+C                 Constant potential USEFUL FOR DISK ?
+       DO 59 I=1,NPUNT
+   59  G(I)=1.
+C
+       IF(LOST.GT.0) THEN
+         WRITE(6,2000) NPUNT,LOST
+         IF(PRINTFILE) WRITE(NFILE,1000) NPUNT,LOST
+ 2000    FORMAT(' ERROR! In Cyl:OBJECT NOT PROPERLY DRAWN! '/
+     1    ' space available for only:',I6,' surface points.',
+     2    ' lost points:',I6/
+     3    ' REDUCE THE NPHI PARAMETER OR GO INTO THE FORTRAN LIST TO',
+     4    ' INCREASE MAXPT')
+       ENDIF
+C
+C           ................ optional disk rotation .....
+C
+       IF(ALZO.EQ.0.0.AND.ROTAZ.EQ.0.0) GOTO 800
+C       The disk is rotated by rotaz around the z axis (anti-clockwise)
+C       then around the new Y axis (clockwise) by alzo
+       COSP=COS(ROTAZ)
+       SINP=SIN(ROTAZ)
+       COSI=COS(ALZO)
+       SINI=SIN(ALZO)
+C
+       IF(ABS(COSP).LT.R4PREC) COSP=0.0
+       IF(ABS(SINP).LT.R4PREC) SINP=0.0
+       IF(ABS(COSI).LT.R4PREC) COSI=0.0
+       IF(ABS(SINI).LT.R4PREC) SINI=0.0
+C
+       DO 80 I=1,NPUNT
+       X1= X(I)* (COSP*COSI) + Y(I) * SINP - Z(I) * (COSP*SINI)
+       Y1=-X(I)* (SINP*COSI) + Y(I) * COSP + Z(I) * (SINP*SINI)
+       Z1= X(I)*       SINI                + Z(I) *       COSI
+       X(I)=X1
+       Y(I)=Y1
+       Z(I)=Z1
+       X1= GX(I)* (COSP*COSI) + GY(I) * SINP - GZ(I) * (COSP*SINI)
+       Y1=-GX(I)* (SINP*COSI) + GY(I) * COSP + GZ(I) * (SINP*SINI)
+       Z1= GX(I)*       SINI                 + GZ(I) *       COSI
+       GX(I)=X1
+       GY(I)=Y1
+       GZ(I)=Z1
+       X1= TX(I)* (COSP*COSI) + TY(I) * SINP - TZ(I) * (COSP*SINI)
+       Y1=-TX(I)* (SINP*COSI) + TY(I) * COSP + TZ(I) * (SINP*SINI)
+       Z1= TX(I)*       SINI                 + TZ(I) *       COSI
+       TX(I)=X1
+       TY(I)=Y1
+       TZ(I)=Z1
+       X1= FX(I)* (COSP*COSI) + FY(I) * SINP - FZ(I) * (COSP*SINI)
+       Y1=-FX(I)* (SINP*COSI) + FY(I) * COSP + FZ(I) * (SINP*SINI)
+       Z1= FX(I)*       SINI                 + FZ(I) *       COSI
+       FX(I)=X1
+       FY(I)=Y1
+       FZ(I)=Z1
+C
+   80  CONTINUE
+C   
+  800  CONTINUE
+C        shifting the disk from the origin=(0,0,0) to x0,y0,z0
+       IF(X0.NE.0.0) THEN
+         DO 90 I=1,NPUNT
+   90    X(I)=X(I)+X0
+       ENDIF
+       IF(Y0.NE.0.0) THEN
+         DO 91 I=1,NPUNT
+   91    Y(I)=Y(I)+Y0
+       ENDIF
+       IF(Z0.NE.0.0) THEN
+         DO 92 I=1,NPUNT
+   92    Z(I)=Z(I)+Z0
+       ENDIF
+C
+       RETURN
+       END              
+C
+       SUBROUTINE DOCELLS(N,D,DMIN,X,Y)
+C      -----------------------------------------
+C      Computes the grid cell CENTERS for the
+C      projection plane 
+C      ----------------------------------------
+       DIMENSION X(N),Y(N)
+       DO 10 I=1,N
+       X(I)=(DMIN+D*0.5)+(I-1)*D
+       Y(I)=-X(I)
+   10  CONTINUE
+       RETURN
+       END
+C
+       SUBROUTINE FASGRID(N,FASE)
+C      -----------------------------------------------------
+C      Defines an equispaced set of phases at which the
+C      light to observer will be computed
+C      -----------------------------------------------------
+       DIMENSION FASE(N)
+       REAL*8 DEL
+       DEL=(6.283185307179586)/N
+       DO 10 I=1,N
+   10  FASE(I)=DEL*(I-1)
+       RETURN
+       END
+C
+       SUBROUTINE FASREAD(NFASI,NFILEF,NFILE,MAX,FASE)
+C      ---------------------------------------------------
+C      Reads fase values from unit NFILEF
+C      ---------------------------------------------------
+       DIMENSION FASE(MAX)
+       DATA PI2/6.2831853/
+       DO 10 I=1,MAX
+       READ(NFILEF,*,END=500) FASE(I)
+       IF(FASE(I).LT.0.0.OR.FASE(I).GT.1.0) GOTO 500
+   10  CONTINUE
+       WRITE(6,1000)MAX,MAX
+       IF(NFILE.GT.0.AND.NFILE.LE.99)WRITE(NFILE,1000)MAX,MAX
+ 1000  FORMAT(' WARNING! You have reached the maximum number of',
+     1        ' phases: ',I6/' If you need a grater value go into',
+     2        ' the fortran list to change MAXFASI=',I6)
+  500  CONTINUE
+       NFASI=I-1
+       IF(NFASI.LE.0) THEN
+         WRITE(6,1001) NFILEF
+         IF(NFILE.GT.0.AND.NFILE.LE.99)WRITE(NFILE,1001)NFILEF
+ 1001    FORMAT(' ERROR! Zero phase values read from unit:',I5)
+         RETURN
+       ENDIF
+       DO 20 I=1,NFASI
+   20  FASE(I)=FASE(I)*PI2
+       RETURN
+       END
+C
+       SUBROUTINE FILFILT
+C      ------------------------------------------------------
+C      filling common /FILTRI/ with lambda and transmission
+C      factors for Johnson bands UBVRI . 
+C      ( data from C.W.Allen - Astrophysical Quantities -
+C                  Athone Press - London 1976 - pg.201 )
+C      - - - - - - - - - - - - - - - - - -
+C      Lambda values must be equi-spaced
+C      - - - - - - - - - - - - - - - - - -
+C      Number of lambda values must be odd
+C      - - - - - - - - - - - - - - - - - - - - - - - - - - - - 
+C      PARAMETERS :=NU,NB,NV,NR,NI = num lambda for each filter,(<=MAXLAM)
+C      NLAMBDA(maxfilt)=NU,NB,NV,NR,NI = num lambda for each filter,
+C      NLAMBDA must be <= nfiltl
+C      DELTALAM= delta lambda for each filter
+C      U(nu),B(nb),..... are the light fraction tranmitted for lambdas
+C      in UL(nu),BL(nb) .... (in Anstrong ) , 
+C      LAMBDA in common /filtri/ are Anstrong, 
+C      ------------------------------------------------------
+C
+       PARAMETER (NU=9 , NB=11 , NV=13, NR=1, NI=1    )
+C
+       PARAMETER ( MAXFILT=5 , MAXLAM=15 )
+       COMMON /FILTRI/ NFILT,NLAM, NLAMBDA(MAXFILT),DELTALAM(MAXLAM),
+     1     ALAMBDA(MAXLAM,MAXFILT),TRASMISS(MAXLAM,MAXFILT),
+     2     COMPFRAC(MAXLAM,3)
+C
+       DIMENSION U(NU),B(NB),V(NV),R(NR),AI(NI) 
+       DIMENSION UL(NU),BL(NB),VL(NV),RL(NR),AIL(NI) 
+C
+       DATA U/0.0,0.13,0.6,0.92,1.,0.72,0.07,0.0,0.0/
+       DATA UL/2800.,3000.,3200.,3400.,3600.,3800.,4000.,4200.,4400./
+       DATA B/0.0,0.13,0.92,1.00,0.92,0.76,0.56,0.39,0.2,0.07,0.0/
+       DATA BL/3600.,3800.,4000.,4200.,4400.,4600.,4800.,5000.,
+     1         5200.,5400.,5600./
+       DATA V/0.0,0.01,0.36,0.91,0.98,0.8,0.59,0.39,0.22,0.09,
+     1        0.03,0.01,0.0/       
+       DATA VL/4600.,4800.,5000.,5200.,5400.,5600.,5800.,6000.,6200.,
+     1         6400.,6600.,6800.,7000./
+C
+C       NFILT=MAXFILT
+C       NLAM=MAXLAM
+C
+C        Number of lambda for each band
+C
+       NLAMBDA(1)=NU
+       NLAMBDA(2)=NB
+       NLAMBDA(3)=NV
+       NLAMBDA(4)=NR
+       NLAMBDA(5)=NI
+C
+       DELTALAM(1)=200.
+       DELTALAM(2)=200.
+       DELTALAM(3)=200.
+       DELTALAM(4)=200.
+       DELTALAM(5)=200.
+C
+C      .............................................................
+C      Filling of common /filtri/
+C      The following is not dependent on lambda and transmission
+C      .............................................................
+C
+C      following loop to avoid bad changes to this routine, 
+C      by inexpert users inserting their preferred photometric bands.
+       DO 5 I=1,NFILT
+       IF(NLAMBDA(I).GT.NLAM) THEN
+         WRITE(6,1000) NLAMBDA(I),I,NLAM
+ 1000    FORMAT(' ERROR ! : WRONG CHANGE IN SUBROUTINE FILFILT'/
+     1   1X,I5,'=NUMBER OF LAMBDA FOR BAND',I2,' > MAXLAM=',I5)
+         NLAMBDA(I)=NLAM
+       ENDIF
+    5  CONTINUE
+C
+C      U - BAND - Filter 1
+C
+       DO 10 I=1,NU
+       ALAMBDA(I,1)=UL(I)
+   10  TRASMISS(I,1)=U(I) 
+C
+C
+C      B - BAND - Filter 2
+C
+       DO 20 I=1,NB
+       ALAMBDA(I,2)=BL(I)
+   20  TRASMISS(I,2)=B(I) 
+C
+C
+C      V - BAND - Filter 3
+C
+       DO 30 I=1,NV
+       ALAMBDA(I,3)=VL(I)
+   30  TRASMISS(I,3)=V(I) 
+C
+C
+C      R - BAND - Filter 4
+C
+       DO 40 I=1,NR
+       ALAMBDA(I,4)=RL(I)
+   40  TRASMISS(I,4)=R(I) 
+C
+C
+C      I - BAND - Filter 5
+C
+       DO 50 I=1,NI 
+       ALAMBDA(I,5)=AIL(I)
+   50  TRASMISS(I,5)=AI(I) 
+C
+       RETURN
+       END
+C
+       SUBROUTINE FILL(N,A,B)
+C      -----------------------------
+C      Fills B(i) with A
+C      ----------------------------
+       DIMENSION B(N)
+       DO 10 I=1,N
+   10  B(I)=A
+       RETURN
+       END
+C
+       SUBROUTINE FILL1(N,A,B,C)
+C      ----------------------------
+C      Fills B(i) with A*C(i)
+C      ----------------------------
+       DIMENSION B(N),C(N)
+       DO 10 I=1,N
+   10  B(I)=C(I)*A
+       RETURN
+       END
+C
+       SUBROUTINE FINDALL(K1,K2,R4PREC)
+C      ----------------------------------------------
+C      Finds allignement between the objects K1 and K2.
+C        An allignement is a straight line between a
+C      surface element in k1 and one in k2 which 
+C      doesn't intersect the objects k1 or k2.
+C        This way of finding alignements doesn't work
+C      for complicated surfaces like ones with holes
+C      and mountains, but only when the outward normal 
+C      line to a surface element never meets the surface:
+C      here a path between the two object is
+C      recognized as an alignement when the two surface 
+C      elements at its ends look each other.
+C
+C      Sin and cos < r4prec are assumed 0 ( sin,cos(0) is not precise)
+C      r4prec is inserted to avoiding double precision here.
+C      ----------------------------------------------
+       PARAMETER (MAXPT=200000 ,MAXALLIN=250000, MAXBANDE=5)
+       PARAMETER (MAXPTC=50000)
+C
+       COMMON /SURFC/ NPNTMXC,NPNTC,NPNT1C,NPNT2C,NPNT3C,
+     A               N1IC,N1FC,N2IC,N2FC,N3IC,N3FC,
+     1               XC(MAXPTC),YC(MAXPTC),ZC(MAXPTC),
+     2               GC(MAXPTC),GXC(MAXPTC),GYC(MAXPTC),GZC(MAXPTC),
+     5               AC(MAXPTC),
+     6               DIMCX(MAXPTC),DIMCY(MAXPTC),DIMCZ(MAXPTC),
+     6               FBC(MAXPTC),FRIFLC(MAXPTC),
+     7               XLIMBC(MAXPTC),NUMOBJC(MAXPTC),ALBC(MAXPTC),
+     8               NUMFINI(MAXPTC)
+      DIMENSION NP123C(3)
+      DIMENSION NIFC(2,3)
+      EQUIVALENCE (NP123C(1),NPNT1C),(NIFC(1,1),N1IC)
+C
+C 
+      COMMON /ALLIN/ NALLMX,NALL,ITERDONE,
+     1               ISOUR(MAXALLIN),JRIC(MAXALLIN),
+     2               TRANSFI(MAXALLIN),TRANSFJ(MAXALLIN),
+     3               FSOURI(MAXALLIN),FSOURJ(MAXALLIN),
+     4               FRICI(MAXALLIN),FRICJ(MAXALLIN),
+     5               RIJ(MAXALLIN),
+     6               RXIJ(MAXALLIN),RYIJ(MAXALLIN),RZIJ(MAXALLIN),
+     7               COSGI(MAXALLIN),COSGJ(MAXALLIN),
+     8               IAUS(MAXALLIN)
+C
+C      ................................................................
+       N1=NIFC(1,K1)
+       N2=NIFC(2,K1)
+       N3=NIFC(1,K2)
+       N4=NIFC(2,K2)
+       LOST=0
+C              looks for alignements
+C      ----------------------------------- LOOP BEGINS
+       DO 10 I=N1,N2
+       DO 10 J=N3,N4
+C              Vector joining the two surface elements (from I to J)
+       RIJX=XC(J)-XC(I)
+       RIJY=YC(J)-YC(I)
+       RIJZ=ZC(J)-ZC(I)
+C              surface normal in I projected along this vector
+       COSGI1=GXC(I)*RIJX+GYC(I)*RIJY+GZC(I)*RIJZ
+C              If < 0 the surface element I doesn't look toward J
+       IF (COSGI1.LE.R4PREC) GOTO 10
+C       IF (COSGI1.LE.0.) GOTO 10
+C              surface normal in J projected along vector from I to J
+       COSGJ1=GXC(J)*RIJX+GYC(J)*RIJY+GZC(J)*RIJZ
+C              If > 0 the surface element J doesn't look toward I
+       IF (COSGJ1.GE.-R4PREC) GOTO 10
+C       IF (COSGJ1.GE.0.) GOTO 10
+C              Here the path is recognized as an alignement
+C              Test if the alignement list is full.         
+       IF(NALL.GT.NALLMX) THEN
+       LOST=LOST+1
+       GOTO 10
+       ENDIF
+C              Insert this path in the alignement list
+       NALL=NALL+1
+       ISOUR(NALL)=I
+       JRIC(NALL)=J
+       RIJ(NALL)=RIJX*RIJX+RIJY*RIJY+RIJZ*RIJZ
+       RXIJ(NALL)=RIJX
+       RYIJ(NALL)=RIJY
+       RZIJ(NALL)=RIJZ
+       COSGI(NALL)=COSGI1
+       COSGJ(NALL)=COSGJ1
+   10  CONTINUE
+C      ------------------------- LOOP ENDS
+       IF(LOST.GT.0) THEN
+       WRITE(6,1000) LOST
+ 1000  FORMAT(' ERROR: ',I6,' ALIGNEMENTS LOST IN REFLECTION   '/
+     1 ' Reduce the number of surface elements or go into the'/
+     2 ' FORTRAN list to change parameter MAXALLIN')
+       ENDIF
+       RETURN
+       END
+C
+       SUBROUTINE FINDCOMM(N1,N2,NAME,COMMAND,KF)
+C      -----------------------------------------------------
+C      Looks for "COMMAND" in a list of NAMEs,
+C      Returns KF = position of COMMAND in vector NAME
+C      returns KF=0 if COMMAND isn't found in NAME vactor
+C      -----------------------------------------------------
+       CHARACTER*(*) NAME(N2),COMMAND
+       DO 10 I=N1,N2
+       IF(NAME(I).NE.COMMAND) GOTO 10
+       KF=I
+       RETURN
+   10  CONTINUE
+       KF=0
+       RETURN
+       END 
+C
+       SUBROUTINE FINEFRIFL
+C      ------------------------------------------------
+C      From coarse grid surface elements reflection source
+C      computes fine grid surf. elem. rreflect. source
+C      ---------------------------------------------------
+C
+       PARAMETER (MAXPT=200000 , MAXBANDE=5 )
+       PARAMETER (MAXPTC=50000 )
+C
+       COMMON /SURF/ NPNTMX,NPNT,NPNT1,NPNT2,NPNT3,
+     A               N1I,N1F,N2I,N2F,N3I,N3F,
+     1               X(MAXPT),Y(MAXPT),Z(MAXPT),
+     2               G(MAXPT),GX(MAXPT),GY(MAXPT),GZ(MAXPT),
+     3               FX(MAXPT),FY(MAXPT),FZ(MAXPT),
+     4               TX(MAXPT),TY(MAXPT),TZ(MAXPT),
+     5               T(MAXPT),A(MAXPT),
+     6               FB(MAXPT),F(MAXPT,MAXBANDE),FRIFL(MAXPT),
+     7               XLIMB(MAXPT),NUMOBJ(MAXPT),ALB(MAXPT),
+     8               NUMCOARSE(MAXPT)
+      DIMENSION NP123(3)
+      DIMENSION NIF(2,3)
+      EQUIVALENCE (NP123(1),NPNT1),(NIF(1,1),N1I)
+C 
+       COMMON /SURFC/ NPNTMXC,NPNTC,NPNT1C,NPNT2C,NPNT3C,
+     A               N1IC,N1FC,N2IC,N2FC,N3IC,N3FC,
+     1               XC(MAXPTC),YC(MAXPTC),ZC(MAXPTC),
+     2               GC(MAXPTC),GXC(MAXPTC),GYC(MAXPTC),GZC(MAXPTC),
+     5               AC(MAXPTC),
+     6               DIMCX(MAXPTC),DIMCY(MAXPTC),DIMCZ(MAXPTC),
+     6               FBC(MAXPTC),FRIFLC(MAXPTC),
+     7               XLIMBC(MAXPTC),NUMOBJC(MAXPTC),ALBC(MAXPTC),
+     8               NUMFINI(MAXPTC)
+      DIMENSION NP123C(3)
+      DIMENSION NIFC(2,3)
+      EQUIVALENCE (NP123C(1),NPNT1C),(NIFC(1,1),N1IC)
+C
+      DO 10 I=1,NPNT
+      K=NUMCOARSE(I)
+      IF(FRIFLC(K).LE.0.0) THEN
+      FRIFL(I)=0.0
+      ELSE
+      FRIFL(I)=A(I)/AC(K)*FRIFLC(K)
+      ENDIF
+   10 CONTINUE
+      RETURN
+      END
+C
+       SUBROUTINE GRADOMEGA(X,Y,Z,GX,GY,GZ,G,Q)
+C      ---------------------------------------------------
+C      Used by subr. Roches : normalized omega gradient
+C      ---------------------------------------------------
+       SQ =1./(X*X+Y*Y+Z*Z)**1.5
+       SQ1=1./((1.-X)*(1.-X)+Y*Y+Z*Z)**1.5
+       A= SQ+SQ1*Q
+       B=   A     -1.-Q
+       GX= X * B + Q * (1.-SQ1)
+       GY= Y * B
+       GZ= Z * A
+       G=SQRT(GX*GX+GY*GY+GZ*GZ)
+       GX=GX/G
+       GY=GY/G
+       GZ=GZ/G
+       RETURN
+       END
+C
+       SUBROUTINE GRAVITY1(KK,NPNT,BETA,TINPUT,G,T)
+C      -------------------------------------------------
+C      Compute the star surface temperature variation
+C      due to the different gravity. (gravity darkening)
+C      BETA is the gravity darkening exponent
+C      TINPUT the max surface temperature of the star
+C      as given in input.(= pole temperature)
+C      -------------------------------------------------
+       DIMENSION G(NPNT),T(NPNT)
+C
+C      Temperature profile computation
+C      and max temperature of the computed profile
+       T(1)=1.
+       TMAX=1. 
+       KK=1
+       DO 10 I=2,NPNT
+       T(I)=(G(I)/G(1))**BETA
+       IF(T(I).GT.TMAX) THEN
+         TMAX=T(I)
+         KK=I
+       ENDIF
+   10  CONTINUE
+C      Renormalizes the  temp. profile to give the input medium temp.
+       DO 20 I=1,NPNT
+       T(I)=(TINPUT/TMAX)*T(I)
+   20  CONTINUE
+       RETURN
+       END
+C
+       SUBROUTINE INPUT(NAMFLAG,DESCFLAG,IFLAGDEF,NAMPAR,DESCPAR,
+     1                  PARDEF,IPPAR1,IPPAR2,STOP)
+C      ------------------------------------------------------------
+C      Reads input and sets flags and parameters
+C      ------------------------------------------------------------
+       PARAMETER (MAXFLAG=21 , MAXPAR=128 , MAXPARS=20 )
+       PARAMETER (MAXTITLE=5)
+       DIMENSION IPPAR1(MAXFLAG),IPPAR2(MAXFLAG),MODFLAG(MAXFLAG)
+       DIMENSION IFLAGDEF(MAXFLAG),PARDEF(MAXPAR)             
+       CHARACTER *10 NAMFLAG(MAXFLAG) 
+       CHARACTER *20 DESCFLAG(MAXFLAG)
+       CHARACTER *10 NAMPAR(MAXPAR)   
+       CHARACTER *20 DESCPAR(MAXPAR)
+       LOGICAL STOP
+C
+       CHARACTER*80 COMMAND,COMMAND1
+       CHARACTER  PROMPT *15, PROMPT1 *20
+       DATA PROMPT,PROMPT1/' INPUT FLAG >',' INPUT PARAMETER >'/
+C
+       COMMON /PAR/ NFLAG,IFLAG(MAXFLAG),NPAR,PAR(MAXPAR)
+C      DIMENSION PARS(MAXPARS,3)
+C      EQUIVALENCE (PARS(1,1),PAR(1))
+       COMMON/TITLE/NTITLEMX,NTITLE,TITLE(MAXTITLE)      
+       CHARACTER*80 TITLE
+C
+C      ------------------------------------------------ INPUT FLAG LOOP
+       GOTO 12
+C      ...........................  Loop entry for input: "?"
+   8   CALL ASKI(1,NFLAG,NAMFLAG,DESCFLAG,IFLAG)
+       GOTO 12
+C      ...........................  Loop entry for bad command
+  10   WRITE(6,1000) COMMAND
+1000   FORMAT(' FLAG NAME NOT RECOGNIZED: ',A10,'  Please  reenter')
+C      ...........................  Loop entry for normal reading
+  12   CALL UPPERC(COMMAND,PROMPT,KFLU)
+C                               If input "?" loops again
+       IF(KFLU.NE.0) GOTO 8
+C                               Looks for flag name
+       CALL FINDCOMM(1,NFLAG,NAMFLAG,COMMAND,KFL)
+C                                   If name not found loops again
+       IF(KFL.LE.0.OR.KFL.GT.NFLAG) GOTO 10
+C                                   If iflag(19)=1 set flag off
+       IF(IFLAG(19).EQ.1) THEN
+       IFLAG(KFL)=0
+       WRITE(6,1100) KFL,NAMFLAG(KFL),DESCFLAG(KFL)
+ 1100  FORMAT(' Set off: flag number:',I5,5x,A10,2X,A20)
+       GOTO 12
+       ENDIF
+C                                   Otherwise set flag on
+C      (16 is the entry from parameter loop)
+  16   IFLAG(KFL)=1 
+       WRITE(6,1110) KFL,NAMFLAG(KFL),DESCFLAG(KFL)
+ 1110  FORMAT(' Set on: flag number:',I5,5x,A10,2X,A20)
+C           Exits from input loops
+       IF(IFLAG(15).EQ.1) GOTO 300
+       IF(IFLAG(16).EQ.1.OR.IFLAG(17).EQ.1) GOTO 500
+C           If there aren't flag's parameters loops again
+       IF(IPPAR1(KFL).LE.0) GOTO 12
+C
+C      ------------------------------------------ INPUT PARAMETERS LOOP
+       GOTO 22
+C      ...........................  Loop entry for input: "?"
+  18   CALL ASK(IPPAR1(KFL),IPPAR2(KFL),NAMPAR,DESCPAR,PAR)
+       GOTO 22
+C      ...........................  Loop entry for bad command
+  20   WRITE(6,2000) COMMAND1
+2000   FORMAT(' PARAMETER NOT RECOGNIZED: ',A10,'  Please  reenter')
+C      ...........................  Loop entry for normal reading
+  22   CALL UPPERC(COMMAND1,PROMPT1,KFLU1)
+C                               If input "?" loops again
+       IF(KFLU1.NE.0) GOTO 18
+C                               Looks for parameter name
+       CALL FINDCOMM(IPPAR1(KFL),IPPAR2(KFL),NAMPAR,COMMAND1,KFL1)
+C                                   If name is found sets its value
+       IF(KFL1.GE.IPPAR1(KFL).AND.KFL1.LE.IPPAR2(KFL)) THEN
+           GOTO 24
+   23      WRITE(6,2001)
+ 2001      FORMAT(' INPUT ERROR! REENTER')
+   24      WRITE(6,2002) 
+C          Following format is not ANSI standard
+ 2002      FORMAT(' VALUE > ',$)
+           READ(5,*,ERR=23,END=23) COMM
+ 2003      FORMAT(E20.0)
+           PAR(KFL1)=COMM
+           WRITE(6,2100) KFL1,NAMPAR(KFL1),DESCPAR(KFL1),PAR(KFL1)
+ 2100      FORMAT(' Parameter number:',I5,5x,A10,2X,A20,' = ',G15.7)
+       ELSE
+C                                   If not found tests if it's a flag
+           CALL FINDCOMM(1,NFLAG,NAMFLAG,COMMAND1,KFL2)
+C                                        Not being a flag loops again
+           IF(KFL2.LE.0.OR.KFL2.GT.NFLAG) GOTO 20     
+C                                        Otherwise goes to flag loop
+           KFL=KFL2
+           GOTO 16
+       ENDIF
+       GOTO 22
+C      ------------------------------------------ END OF PARAMETER LOOP
+C      ------------------------------------------ END OF FLAG LOOP
+C
+ 300   STOP=.FALSE.
+       RETURN
+ 500   STOP=.TRUE.
+       RETURN
+       END
+C
+       SUBROUTINE INULL(N,IA)
+C      -----------------------
+C      Fills IA with 0 . 
+C      Depending on computers, 
+C      NULL could be also used.
+C      ----------------------
+       DIMENSION IA(N)
+       DO 10 I=1,N
+   10  IA(I)=0
+       RETURN
+       END
+C
+       SUBROUTINE LAGR(Q,PRECISION)
+C      ---------------------------------------------------------
+C      Lagrange point computation for the mass ratio Q
+C      the distance between the two body is the measure unit(=1)
+C      PRECISION = accurancy of Newton-Rapson algorithm,
+C      remember that you need 1.E-7 to have all the 7 digits of a real*4 number
+C      ---------------------------------------------------------
+       COMMON /ROCHE/ AL1,AL2,AL3,XA1,XA2,XB1,XB2,YA,YB,
+     1                OMEGAL1,OMEGAL2,OMEGAL3,
+     2               RPOLE(3),XPOLE(3),YPOLE(3),ZPOLE(3),TPOLE(3),
+     3               GXPOLE(3),GYPOLE(3),GZPOLE(3)
+C
+       EXTERNAL LAGRF1,LAGRF2,LAGRF3
+       OM(Q,XV)=1./ABS(XV)+Q/ABS(1.-XV)+(1.+Q)/2.*XV*XV-Q*XV
+C
+C      Initial values ( used if the computation below doesn't succeed)       
+C
+       AL1=0.0
+       AL2=0.0
+       AL3=0.0
+C       Approx transv. dimension for critical lobes(Plavec BAC,15:165(64))
+C       Plavec formula assume q<1 :
+       IF(Q.LE.1) THEN      
+          ALOGQ=LOG10(Q)
+       ELSE
+          ALOGQ=LOG10(1./Q)
+       ENDIF
+C
+       YA=10**(-0.4221-0.2084*ALOGQ)
+       YB=10**(-0.4236+0.2743*ALOGQ) 
+C         Lagrange points:     Inner point L1
+C         L2 (near minor body) R1,R2 are search limits for rtsafe routine
+C         L3 (near major body )
+       NERROR=0
+       R1=0.0
+       R2=1.0
+       AL1=RTSAFE(LAGRF1,R1,R2,PRECISION,Q,DUM,NERROR)
+       OMEGAL1=OM(Q,AL1)
+       R1=1.
+       R2=2.
+       AL2=RTSAFE(LAGRF2,R1,R2,PRECISION,Q,DUM,NERROR)
+       OMEGAL2=OM(Q,AL2)
+       R1=-1.
+       R2=0.
+       AL3=RTSAFE(LAGRF3,R1,R2,PRECISION,Q,DUM,NERROR)
+       OMEGAL3=OM(Q,AL3)
+C
+       IF(NERROR.GT.0) THEN
+         WRITE(6,1000)
+ 1000    FORMAT(/' ERROR In subr. LAGR, Incorrect Lagrange Points')
+       ENDIF
+       RETURN
+       END
+C
+       FUNCTION LAGRF1(X,F,DF,Q,DUM)
+C      -----------------------------------------------------------------
+C      Intersection x-axis <-> roche lobes for a given Q, called by LAGR     
+C      near L1 point
+C      -----------------------------------------------------------------
+C       F=    X**5*(1.+Q)-   X**4*(2.+3.*Q)+X**3*(1.+3.*Q)-X**2+X*2.-1.
+C       DF=5.*X**4*(1.+Q)-4.*X**3*(2.+3.*Q)+3.*X**2*(1.+3.*Q)-2.*X +2.
+       Q1=1.+Q
+       QXQ=X*Q1-Q
+       QXQ2=2.*QXQ
+       RX=1.-X
+       RX2=RX*RX
+       X2=X*X
+       F=RX2 *( X2 * QXQ  -1. ) + X2*Q
+       DF= RX* ( RX* X* (QXQ2 + X*Q1)  - X * (X*QXQ2) -2. ) +2.*X*Q
+       RETURN
+       END
+C
+       FUNCTION LAGRF2(X,F,DF,Q,DUM)
+C      -----------------------------------------------------------------
+C      Intersection x-axis <-> roche lobes for a given Q, called by LAGR     
+C      near L2 point
+C      -----------------------------------------------------------------
+       Q1=1.+Q
+       QXQ=X*Q1-Q
+       QXQ2=2.*QXQ
+       RX=X-1.
+       RX2=RX*RX
+       X2=X*X
+       F=RX2 *( X2 * QXQ  -1. ) - X2*Q
+       DF= RX* ( RX* X* (QXQ2 + X*Q1)  + X * (X*QXQ2) -2. ) -2.*X*Q
+       RETURN
+       END
+C
+       FUNCTION LAGRF3(X,F,DF,Q,DUM)
+C      -----------------------------------------------------------------
+C      Intersection x-axis <-> roche lobes for a given Q, called by LAGR     
+C      near L3 point
+C      -----------------------------------------------------------------
+       Q1=1.+Q
+       QXQ=X*Q1-Q
+       QXQ2=2.*QXQ
+       RX=1.-X
+       RX2=RX*RX
+       X2=X*X
+       F=RX2 *( X2 * QXQ  +1. ) + X2*Q
+       DF= RX* ( RX* X* (QXQ2 + X*Q1)  + X * (X*QXQ2) +2. ) +2.*X*Q
+       RETURN
+       END
+C
+       SUBROUTINE LBOLT(NPNT,F,T,A)
+C      -----------------------------------------------------------
+C      This routine computes the bolometric flux integrated over
+C      each surface element, assuming a black body emission
+C      flux=erg/cm**2/sec/sterad .=caT**4/(4 PI)
+C      F=FLUX*AREA=erg/sec/sterad
+C      we could set, to shorten calculation: flux=T**4, being a*c/(4*pi)=1.
+C      -----------------------------------------------------------
+       DIMENSION F(NPNT),T(NPNT),A(NPNT)
+       PARAMETER ( AC4PI=7.567E-15 *3.E10/4./3.1415926 )
+       DO 10 I=1,NPNT
+       F(I)=T(I)**4*A(I) * AC4PI
+   10  CONTINUE
+       RETURN
+       END
+C
+       SUBROUTINE LIMB(N,D,A,T,XLIMB,ALB)
+C      -----------------------------------------------
+C      D is the input given limb darkening; A the albedo
+C      A time dependece could be inserted here,
+C      but now this is the same as the Fill routine.
+C      -----------------------------------------------
+       DIMENSION T(N),XLIMB(N),ALB(N)
+       DO 10 I=1,N
+       ALB(I)=A
+   10  XLIMB(I)=D
+       RETURN
+       END
+C
+       SUBROUTINE LOBES(Q,PRECISION,OMEGA,R,IS)
+C      -----------------------------------------------------------------
+C      Given Q and a potential value (omega), computes the
+C      Intersections of the x-axis with Roche lobes with potential OMEGA
+C      and mass ratio Q : IS=1 for the major star, 2 for the minor one
+C      If Omega is not given (<= 0.0) then it is deduced from R : 
+C      intersection of lobe and X axis
+C      Precision= precision in Newton-Cotes routine. 1.E-7 to give all the 7
+C      digits of a real*4 number
+C      -----------------------------------------------------------------
+       COMMON/ROCHE/ AL1,AL2,AL3,XA1,XA2,XB1,XB2,YA,YB,
+     1                OMEGAL1,OMEGAL2,OMEGAL3,
+     2               RPOLE(3),XPOLE(3),YPOLE(3),ZPOLE(3),TPOLE(3),
+     3               GXPOLE(3),GYPOLE(3),GZPOLE(3)
+       EXTERNAL LOBESF1,LOBESF2,LOBESF3
+       LOGICAL PRIMO
+C
+C     OM(Q,XV)=1./XV+Q/(1.-XV)+(1.+Q)/2.*XV*XV-Q*XV+Q*Q/2./(1.+Q) old omega def.
+       OM(Q,XV)=1./ABS(XV)+Q/ABS(1.-XV)+(1.+Q)/2.*XV*XV-Q*XV
+C
+       PRIMO=.TRUE.
+       IF(IS.EQ.3) THEN
+         WRITE(6,1000)
+ 1000    FORMAT(' ERROR  ! In subroutine LOBES: object 3 can''t be a',
+     1        ' Roche model star!')
+         RETURN
+       ENDIF
+C
+   10  IF(OMEGA.LE.0.0) THEN
+         WRITE(6,2000) R
+ 2000    FORMAT(' WARNING ! : Subr.Lobes computes Omega from R:',
+     1          G15.7/' R is intended as the lobe radius at the ',
+     2          ' intersection with x axis, near L1' )
+         IF(R.LE.0..OR.R.GT.1.0) THEN
+             IF(IS.EQ.1) THEN 
+               WRITE(6,2010) R,AL1
+               R=AL1 
+             ELSE
+               WRITE(6,2010) R,1.-AL1
+               R=1.-AL1
+             ENDIF
+ 2010        FORMAT(' WARNING ! : Incorrect R :',G14.7,
+     1              ' Setting critical lobe: R=',G14.7)
+         ENDIF               
+         IF(IS.EQ.1.) THEN
+             OMEGA=OM(Q,R)
+         ELSE
+             OMEGA=OM(Q,1.-R)
+         ENDIF
+         WRITE(6,2020) OMEGA
+ 2020    FORMAT(' I set OMEGA=',G15.7)
+         PRIMO=.FALSE.
+       ENDIF
+C         R1,R2 =bounds for searching the inner lobe intersection
+C         R3,R4 for outher lobe intersetion
+C              For major star:
+         IF(IS.EQ.1) THEN
+   20    R1=0.0
+         R2=AL1
+         R3=-AL1
+         R4=0.
+C        Error counter :
+         NERROR=0
+         XA1=RTSAFE(LOBESF1,R1,R2,PRECISION,Q,OMEGA,NERROR)
+         XA2=RTSAFE(LOBESF3,R3,R4,PRECISION,Q,OMEGA,NERROR)
+C
+C          Error recovery: 1: try to compute omega from R ( if not done)
+C                          2: set R=critical lobe dimension (if not done)
+C                          3: as 2 and guess values for XA1,XA2=star bounds
+         IF(NERROR.GT.0.OR.XA1.GT.AL1.OR.XA2.LT.AL3) THEN
+             WRITE(6,3000) IS
+ 3000        FORMAT(' ERROR ! wrong Q or OMEGA ; object:',I3)
+             WRITE(6,4000)AL1,AL2,AL3,XA1,XA2,OMEGA
+ 4000        FORMAT(' Lagrange points:',3G15.7/
+     1       ' Surf.- X axis intersections:',2G14.7,'  Omega:',G14.7)
+C
+             IF(PRIMO) THEN 
+                IF(R.LE.0.) THEN 
+                   WRITE(6,2010) R,AL1
+                   R=AL1
+                ENDIF
+                OMEGA=OM(Q,R)
+                WRITE(6,2000) R
+                WRITE(6,2020) OMEGA
+                PRIMO=.FALSE. 
+                GOTO 20
+             ELSE IF(R.NE.AL1) THEN
+                WRITE(6,2010) R,AL1
+                R=AL1
+                OMEGA=OM(Q,R) 
+                WRITE(6,2000) R
+                WRITE(6,2020) OMEGA
+                GOTO 20
+             ELSE
+                WRITE(6,5000) XA1,XA2,AL1
+ 5000           FORMAT(' ERROR RECOVERY NOT POSSIBLE:',
+     1                 ' wrong intersections:',2G15.7/
+     2                 ' used L1:',G14.7)
+                XA1=AL1
+                XA2=-AL1
+             ENDIF 
+         ENDIF
+       ELSE
+C             Minor star
+   30    R1=AL1 
+         R2=1. 
+         R3=1.
+         R4=AL2
+C        Error counter reset
+         NERROR=0
+         XB1=RTSAFE(LOBESF1,R1,R2,PRECISION,Q,OMEGA,NERROR)
+         XB2=RTSAFE(LOBESF2,R3,R4,PRECISION,Q,OMEGA,NERROR)
+C             Error recovery
+         IF(NERROR.GT.0.OR.XB1.LT.AL1.OR.XB2.GT.AL2) THEN
+             WRITE(6,3000) IS
+             WRITE(6,4000)AL1,AL2,AL3,XB1,XB2,OMEGA
+C 
+             IF(PRIMO) THEN 
+               IF(R.LE.0.) THEN
+                  WRITE(6,2010) R,1.-AL1
+                  R=1.-AL1
+               ENDIF
+               OMEGA=OM(Q,1.-R)
+               WRITE(6,2000)R
+               WRITE(6,2020) OMEGA
+               PRIMO=.FALSE.
+               GOTO 30
+             ELSE IF(R.NE.1.-AL1) THEN
+               WRITE(6,2010) R,1.-AL1
+               R=1.-AL1
+               OMEGA=OM(Q,AL1) 
+               WRITE(6,2000)R
+               WRITE(6,2020) OMEGA
+               GOTO 20
+             ELSE
+               WRITE(6,5000) XB1,XB2,AL1
+               XB1=AL1
+               XB2=1.+AL1
+             ENDIF 
+         ENDIF
+       ENDIF       
+       RETURN
+       END         
+C    
+       SUBROUTINE LOBESF1(X,F,DF,Q,OMEGA)
+C      ------------------------------------------------
+C      used by lobes : intersection of roche lobe
+C      and X axis near L1 for a given omega and q
+C      ------------------------------------------------
+       A=(1.+Q)/2.
+       B=A+Q
+C       C=OMEGA-Q-   (Q**2/2./(1.+Q))  old omega definition
+C       D=Q-1.-OMEGA+(Q**2/2./(1.+Q))
+       C=OMEGA-Q
+       D=Q-1.-OMEGA
+       F=-A*X**4+B*X**3+C*X**2+D*X+1.
+       DF=-4.*A*X**3+3.*X**2*B+2.*C*X+D
+       RETURN
+       END 
+C
+       SUBROUTINE LOBESF2(X,F,DF,Q,OMEGA)
+C      ------------------------------------------------
+C      used by lobes : intersection of roche lobe
+C      and X axis near L2(after star B)for a given omega and q
+C      ------------------------------------------------
+       A=(1.+Q)/2.
+       B=A+Q
+C       C=OMEGA-Q-   (Q**2/2./(1.+Q))         old omega definition
+C       D= - Q-1.-OMEGA+(Q**2/2./(1.+Q))
+       C=OMEGA-Q
+       D= - Q-1.-OMEGA
+       F=-A*X**4+B*X**3+C*X**2+D*X+1.
+       DF=-4.*A*X**3+3.*X**2*B+2.*C*X+D
+       RETURN
+       END 
+C
+       SUBROUTINE LOBESF3(X,F,DF,Q,OMEGA)
+C      ------------------------------------------------
+C      used by lobes : intersection of roche lobe
+C      and X axis near L3(before star A)for a given omega and q
+C      ------------------------------------------------
+       A=(1.+Q)/2.
+       B=A+Q
+C       C=OMEGA-Q-   (Q**2/2./(1.+Q))     old omega definition
+C       D=Q+1.-OMEGA+(Q**2/2./(1.+Q))
+       C=OMEGA-Q
+       D=Q+1.-OMEGA
+       F=-A*X**4+B*X**3+C*X**2+D*X   -1.
+       DF=-4.*A*X**3+3.*X**2*B+2.*C*X+D
+       RETURN
+       END 
+C
+       SUBROUTINE LUCE1(NPRINT,PRINT6,PRINTFILE,NFILE,NPRINTL,
+     1            COSI,SINI,R4PREC,CELLMAX,CELLMIN,DCELL,NCELL,
+     2            XCELL,YCELL,ICELL,COSG,NEXT,ILOST,IGAINED,IBAND)
+C      ------------------------------------------------------------
+C      This routine computes the light received by the observer
+C      at each phase. The image of the system is projected
+C      onto a plane perpendicular to the observer at each phase.
+C      This plane is divided into a number of grid points.
+C        Two special cases are to be considered:
+C         a) overfill case: more surf. elements of the same object
+C            fall into the same grid cell,( this happens at the
+C            star disk boundary); in this case a linklist  is
+C            constructed with these points.
+C         b) underfill case: a surface element's projection is greater
+C            than the cell dimension. To account for this the projected
+C            surf.el. boundary are computed and the surf.el. is expanded
+C            over its cells on the grid.
+C      If two surface elements of different objects falls into the
+C      same cell, the further's light is decreased by the cell contribution,
+C      the part of its light falling into the cell being eclipsed.
+C
+C      Finally, an integration over the perpendicular plane gives
+C      the total received light for the phase.
+C
+C      COS < R4PREC is assumed 0, this shorten alittle bit the computations,
+C      by eliminating uneffective points, seen side-face. Points at 90 degrees
+C      are made visible by rounding errors in cos(about 90) whitout this trick.
+C
+C      XCELL,YCELL are the center of the cells, used only for printing
+C      The projection reference system is LEFT-HANDED (for better 
+C      vision of objects on the screen),the other systems are right-handed!
+C      YCELL is built in DOCELLS going from ymax to -ymax,
+C      making apparence of the printed projection plane right-handed again.
+C     #################################### NOTA #################
+C     La distanza dall'osservatore e' ricalcolata ogni volta;
+C     tenerla in un vettore dist risparmia di doverla ricalcolare quando 
+C     serve, ma ogni volta che si deve usare si deve fare un if per vedere 
+C     se e' gia' calcolata oppure si deve calcolare. Per questo l'uso
+C     di dist va provato in vari casi, per vedere se conviene.
+C     #############################################################
+C
+C      PRINTFILE : if true can print information on unit NFILE on each 
+C      NPRINT phase steps; NPRINTL defines the amount of printing
+C      PRINT6 : if true some log printing on unit 6
+C      -------------------------------------------------------------
+       PARAMETER (MAXPT=200000 , MAXFASI=1000, MAXBANDE=5)
+C
+       COMMON /SURF/ NPNTMX,NPNT,NPNT1,NPNT2,NPNT3,
+     A               N1I,N1F,N2I,N2F,N3I,N3F,
+     1               X(MAXPT),Y(MAXPT),Z(MAXPT),
+     2               G(MAXPT),GX(MAXPT),GY(MAXPT),GZ(MAXPT),
+     3               FX(MAXPT),FY(MAXPT),FZ(MAXPT),
+     4               TX(MAXPT),TY(MAXPT),TZ(MAXPT),
+     5               T(MAXPT),A(MAXPT),
+     6               FB(MAXPT),F(MAXPT,MAXBANDE),FRIFL(MAXPT),
+     7               XLIMB(MAXPT),NUMOBJ(MAXPT),ALB(MAXPT),
+     8               NUMCOARSE(MAXPT)
+      DIMENSION NP123(3)
+      DIMENSION NIF(2,3)
+      EQUIVALENCE (NP123(1),NPNT1),(NIF(1,1),N1I)
+C 
+      COMMON /LIGHT/ NFASIMX,NFASI,NBANDE,
+     1               FASE(MAXFASI),O(MAXBANDE,MAXFASI),
+     2               C(3,MAXBANDE,MAXFASI),CT(MAXBANDE,MAXFASI),
+     3               CBOL(3,MAXFASI),CBOLT(MAXFASI),
+     4               CBOLR(3,MAXFASI),CBOLTR(MAXFASI),
+     5               AREA(3),FBOLTOT(3),FBOL(3),FBOLREF(3)
+C 
+      DIMENSION XCELL(NCELL),YCELL(NCELL),ICELL(NCELL,NCELL)
+C
+      DIMENSION IBAND(MAXBANDE)
+      DIMENSION COSG(MAXPT),NEXT(MAXPT),IGAINED(MAXPT),ILOST(MAXPT)
+C     Print buffer, used to store data to be printed in the same line
+      PARAMETER (MAXBUF=20)
+      DIMENSION NBUF(MAXBUF)
+      LOGICAL PRINTFILE,PRINT6
+      DIMENSION XESP12(4)
+      EQUIVALENCE (XESP1,XESP12(1)),(XESP2,XESP12(2))
+      EQUIVALENCE (XESP3,XESP12(3)),(XESP4,XESP12(4))
+C     ............................................................
+      CALL NULL(MAXBANDE*MAXFASI*3,C)
+      CALL NULL(MAXBANDE*MAXFASI,CT)
+      CALL NULL(MAXFASI*3,CBOL)
+      CALL NULL(MAXFASI,CBOLT)
+      CALL NULL(MAXFASI*3,CBOLR)
+      CALL NULL(MAXFASI,CBOLTR)
+C     -------------------------------------  Loop on phases
+      IF(PRINT6) TEMPO0=SECNDS(0.0)
+      DO 10 IF=1,NFASI
+C      ................. time printing for previous phase
+      IF(PRINT6) THEN 
+        TEMPO2=SECNDS(TEMPO0) 
+        WRITE(6,8999) IF,FASE(IF),TEMPO2
+        TEMPO0=TEMPO0+TEMPO2
+ 8999   FORMAT(' Sub.LUCE1: beginning phase:',I5,' : ',G12.5,
+     1       ' elapsed time for last phase:',G15.7)
+      ENDIF
+C         .................. counters for statistic
+C         ######### poi da eliminare, sprecano tempo! ############
+      NCOUNTS=0         ! considered surf. el.
+      NCOUNTL=0         ! surf. el put in link list
+      NCOUNTE=0         ! cell expansions
+      NCOUNTV=0         !   "       "      over void cells
+      NCOUNTD=0         !   "       "      over different object's
+      NCOUNTD1=0        !   "       "      (of which eclipsing)
+      NCOUNTD2=0        !   "       "      (of which eclipsed )
+      NCOUNTF=0         !   "       "      over same object's
+      NCOUNTT=0         !  total remaining surf points
+      NCOUNTTL=0        !  remaining surf points in link lists      
+      NCOUNTL1=0        !  number of remaining link lists
+C
+      COSF=COS(FASE(IF))
+      SINF=SIN(FASE(IF))
+C          Components of the unit vector toward the observer Z0
+C          and of unit vectors of the perpendicular plane X0,Y0
+C         X0,Y0,Z0 = Y , -Z , X to make printing easier and nicer.
+C          In this way we have a left-handed projection reference system
+C         and a right-handed object reference system,
+C         but, when printing the projection plane, the Y coordinate
+C         is printed as -Y, making this printing right-handed again.
+      Y0X=COSI*COSF
+      Y0Y=-COSI*SINF
+      Y0Z=-SINI
+      X0X=SINF
+      X0Y=COSF
+      X0Z=0.0
+      Z0X=COSF*SINI
+      Z0Y=-SINF*SINI
+      Z0Z=COSI
+C
+C      tempo=secnds(0.0)
+      CALL INULL(NCELL*NCELL,ICELL)
+C      tempo1=secnds(tempo)
+C      write(6,9000) if,tempo1
+C     if(printfile) write(nfile,9000) if,tempo1
+ 9000 format(' Sub.luce1: phase:',I5,
+     1       ' elapsed time for grid initialization:',G15.7)
+C     
+C     ------------------------------------ Loop on surface elements
+      LOST=0
+      DO 30 I=1,NPNT
+C         Number of cells covered by the surf. elem.
+      IGAINED(I)=0  
+C         normal to the surface element projected toward the observer
+      DUM = Z0X*GX(I)+Z0Y*GY(I)+Z0Z*GZ(I)
+C         Skips the element if it doesn't look toward the observer       
+      IF(DUM.LE.R4PREC) GOTO 30
+C
+      NCOUNTS=NCOUNTS+1
+      COSG(I)=DUM
+      NEXT(I)=0
+C         Number of cells covered by the object, but lost being eclipsed
+      ILOST(I)=0    
+C
+C         Looks for the point of the plane in which the element falls
+C         In the following statement X0z=0. CAN BE is assumed ####
+      XX0=X(I)*X0X+Y(I)*X0Y+Z(I)*X0Z  -CELLMIN
+      YY0=X(I)*Y0X+Y(I)*Y0Y+Z(I)*Y0Z  -CELLMIN
+C         find the cell in which the point falls
+      IX=INT(XX0/DCELL)+1
+      IY=INT(YY0/DCELL)+1
+C            Set the upper boundary point (useful for xx0==cellmax)
+      IF(IX.EQ.NCELL+1) IX=NCELL
+      IF(IY.EQ.NCELL+1) IY=NCELL
+C            Safety test
+      IF(IX.LE.0.OR.IX.GT.NCELL.OR.IY.LE.0.OR.IY.GT.NCELL) THEN
+        LOST=LOST+1
+        GOTO 30
+      ENDIF
+C     ............... Expand each projected surf.point on the grid
+C                     to its projected dimension; decreasing light
+C                     of partially eclipsing surface elements if 
+C                     belonging to different objects.
+C       ################### nota #####################################
+C       FPX,FPY,TPX,TPY,YMIN,YMAX,YESP possono tutti essere shiftati
+C       di YY0, invece di partire da 0. Idem per XPX,XPY etc, si
+C       risparmia tempo
+C       ##############################################################
+C         Computing the projected dimensions for the i surf. element:
+C         F and T are projected onto the visual plane
+C        ( In the following statement X0z=0. CAN BE is assumed ####)
+      FPX= FX(I)*X0X + FY(I)*X0Y + FZ(I)*X0Z
+      FPY= FX(I)*Y0X + FY(I)*Y0Y + FZ(I)*Y0Z
+      TPX= TX(I)*X0X + TY(I)*X0Y + TZ(I)*X0Z
+      TPY= TX(I)*Y0X + TY(I)*Y0Y + TZ(I)*Y0Z
+C        To avoid rounding error in looking for expansion limits
+      DUM = ABS(FPY)
+      DUM1= ABS(TPY)
+      IF(DUM.LT.R4PREC)  FPY=0.0
+      IF(DUM1.LT.R4PREC) TPY=0.0
+      YMAX= DUM+DUM1 
+      YMIN=-YMAX
+C           ################ non serve loppando sulle celle e non sy yesp?##
+C        To avoid yesp value exactly on grid boundaries, which can cause
+C        the skipping of some cells. If on cell border is mouved a bit
+C        into the cell. (If expanded over the previous cell it doesn't
+C        find y intersection with projected surf.elem skipping this y cell)
+C      IF(MOD(YMIN+YY0,DCELL).LT.(DCELL/1000.)) YMIN=YMIN+(DCELL/1000.)
+C         YMAX can't be expanded to the cell boundary . In the last cell
+C         YESP must be <=YMAX or no y intersection will be found.
+C
+C         First and last Y cell covered by the surf. element, in which
+C         YMAX and YMIN falls; we have a little asimmetry here:
+C         if Ymin is on left cell boundary this doesn't expand 
+C         Y on the previous cell. But if Ymax is on the rigth cell 
+C         boundary then expand Y over the next cell. 
+      JYMAX=INT((YMAX+YY0)/DCELL)+1
+      JYMIN=INT((YMIN+YY0)/DCELL)+1
+C         Test if these two cells  are on the projection plane boundaries
+      IF(JYMIN.LE.0)  JYMIN=1
+      IF(JYMAX.GT.NCELL) THEN
+             JYMAX=NCELL
+             YMAX=CELLMAX-CELLMIN-YY0
+      ENDIF
+C
+C      ------------------- loop on y expansion grid range
+C 
+      DO 80 JY=JYMIN,JYMAX
+C        An Y value YESP is computed for each cell covered by the surf.el.
+C        then the intersections between the projected surf.el. boundary
+C        and the line Y=YESP are found: these are the X expansion limits
+C        for this JY row of proj. plane.  
+C         Potrebbe essere utile mettere YESP vicino al bordo della
+C        cella  piu' vicino al punto YY0 in cui cade l'elemento di 
+C        superficie, cioe' al bordo superiore sotto YY0 e a quello
+C        inferiore sopra. In questo modo ci si mette nelle condizioni
+C        di trovare le intersezioni X piu' distanti possibile fra loro 
+C        e quindi di espandersi sul massimo numero di celle, qui invece
+C        puo' capitare di avere YESP che supera l'espasione del surf. el.
+C        e quindi non trova intersezioni anche se in effetti il surf. el.
+C        entra un poco nella cella.
+C
+      IF(JY.NE.JYMAX) THEN
+         YESP=YMIN+(JY-JYMIN)*DCELL
+      ELSE
+C        If YESP is out of the plane boundary it's set on boundary
+         YESP=YMAX
+      ENDIF 
+C
+C        Intesecting the line  Y=yesp with the boundary of the proj.surf. el.
+      IXESP=1
+      IF(TPY.NE.0.) THEN
+         H=(YESP-FPY)/TPY
+         IF(ABS(H).LE.1.) THEN
+           XESP12(IXESP)=FPX+TPX*H
+           IXESP=IXESP+1
+         ENDIF
+         H=(YESP+FPY)/TPY
+         IF(ABS(H).LE.1.) THEN
+           XESP12(IXESP)=-FPX+TPX*H
+           IXESP=IXESP+1
+         ENDIF
+      ENDIF
+      IF(FPY.NE.0.) THEN
+         H=(YESP-TPY)/FPY
+         IF(ABS(H).LE.1.) THEN
+           XESP12(IXESP)=TPX+FPX*H
+           IXESP=IXESP+1
+         ENDIF
+         H=(YESP+TPY)/FPY
+         IF(ABS(H).LE.1.) THEN
+           XESP12(IXESP)=-TPX+FPX*H
+           IXESP=IXESP+1
+         ENDIF
+      ENDIF
+C
+      IF(IXESP.EQ.1) THEN
+C          No intersection, this can happen if the surf element is
+C          all into Dcell, this case is considered at the end of 
+C          the expansion loop. This can also happen at the Y proj.surf.el.
+C          boundary if YESP (about on cell boundary) falls is just outside 
+C          the cell it should represent.
+           GOTO 80
+      ELSE IF(IXESP.EQ.2) THEN
+C        Only one intersection, typically at y surf.el. boundary, when both 
+C        are at the edge of the surf.elem. In this case we should have 
+C        two intersection of equal value, but rounding errors can alter.
+           XMAX=XESP1
+           XMIN=XESP1
+           XESP2=XESP1
+      ELSE IF(IXESP.GT.3) THEN
+C        Four intersection are too mutch; this can happen if YESP falls
+C        EXACTELY on the proj.surf.el. diagonal, or when TPY or FPY are
+C        about 0, in this case rounding errors can give spurious intersections
+C        with H and YESP about 0.
+         WRITE(6,1997) IF,I,IXESP-1,(XESP12(J),J=1,IXESP-1)
+         IF(PRINTFILE) WRITE(NFILE,1997) 
+     1                 IF,I,IXESP-1,(XESP12(J),J=1,IXESP-1)
+ 1997    FORMAT(' WARINIG! : in light calculation, phase:',I4,' point:'
+     1   I6/' Too mutch expansion directions:',I3,1X,4E15.5)
+         IF(IXESP.EQ.4) THEN
+            XMAX=MAX(XESP1,XESP2,XESP3)
+            XMIN=MAX(XESP1,XESP2,XESP3)
+         ELSE
+            XMAX=MAX(XESP1,XESP2,XESP3,XESP4)
+            XMIN=MAX(XESP1,XESP2,XESP3,XESP4)
+         ENDIF            
+      ELSE
+C        IXESP=3 : two intersections, wich are the X expansion limits
+         XMAX=MAX(XESP1,XESP2)
+         XMIN=MIN(XESP1,XESP2)
+      ENDIF
+C
+      JXMIN=INT((XMIN+XX0)/DCELL)+1
+      JXMAX=INT((XMAX+XX0)/DCELL)+1
+      IF(JXMIN.LE.0) JXMIN=1
+      IF(JXMAX.GT.NCELL) JXMAX=NCELL 
+C
+C      ------------------- loop on X expansion grid range
+      DO 82 JX=JXMIN,JXMAX
+C
+      J=ICELL(JX,JY)
+      NCOUNTE=NCOUNTE+1
+C
+C     If the grid point JX,JY is void then expand the I point over it
+      IF(J.EQ.0) THEN
+             ICELL(JX,JY)=I
+             IGAINED(I)=IGAINED(I)+1
+             NCOUNTV=NCOUNTV+1
+C     If filled by a different object
+      ELSE IF(NUMOBJ(J).NE.NUMOBJ(I)) THEN
+             NCOUNTD=NCOUNTD+1
+             DISTI=X(I)*Z0X+Y(I)*Z0Y+Z(I)*Z0Z
+             DISTJ=X(J)*Z0X+Y(J)*Z0Y+Z(J)*Z0Z
+C            if this object is the nearer (the nearer has the greatest DIST)
+             IF(DISTI.GT.DISTJ)  THEN
+                    ICELL(JX,JY)=I        
+                    IGAINED(I)=IGAINED(I)+1
+                    ILOST(J)=ILOST(J)+1
+                    NCOUNTD1=NCOUNTD1+1
+             ELSE
+C            The other is the nearer
+                    IGAINED(I)=IGAINED(I)+1
+                    ILOST(I)=ILOST(I)+1
+                    NCOUNTD2=NCOUNTD2+1
+             ENDIF
+      ELSE
+C       filled by the same object 
+C       the cell remains assigned to the other object
+        NCOUNTF=NCOUNTF+1
+      ENDIF
+C
+   82  CONTINUE
+C     ------------------------------- END OF X EXPANSION LOOP  82
+   80  CONTINUE
+C     ------------------------------- END OF Y EXPANSION LOOP   80
+C
+C     Test if this point has some cell which is not eclipsed and in which
+C     there aren't other points of the same object
+      IF (IGAINED(I).GT.ILOST(I))  GOTO 30
+C     K is the surface element of the cell in which this point falls
+      K=ICELL(IX,IY)
+      IF(K.LE.0) THEN
+C     This is the case in which the surf.elem. << dcell has been jumped 
+C     by the loop. This can hapen when no interseciotn is found, being
+C     the surf.el. << dcell.
+             ICELL(IX,IY)=I
+             IGAINED(I)=IGAINED(I)+1
+             NCOUNTV=NCOUNTV+1
+C     If filled by a different object (could be if surf.el.<<dcell, as before)
+C     But generally this has been done before, we have redundancy here.
+      ELSE IF(NUMOBJ(K).NE.NUMOBJ(I)) THEN
+             NCOUNTD=NCOUNTD+1
+             DISTI=X(I)*Z0X+Y(I)*Z0Y+Z(I)*Z0Z
+             DISTK=X(K)*Z0X+Y(K)*Z0Y+Z(K)*Z0Z
+C            if this object is the nearer (the nearer has the greatest DIST)
+             IF(DISTI.GT.DISTK)  THEN
+                    ICELL(IX,IY)=I        
+                    IGAINED(I)=IGAINED(I)+1
+                    ILOST(K)=ILOST(K)+1
+                    NCOUNTD1=NCOUNTD1+1
+             ELSE
+C            The other is the nearer
+                    IGAINED(I)=IGAINED(I)+1
+                    ILOST(I)=ILOST(I)+1
+                    NCOUNTD2=NCOUNTD2+1
+             ENDIF
+      ELSE
+C     Else: last chance for this point: its cell is assigned to 
+C     a surf. el. of the same object, it enters into its linklist
+             NEXT(I)=NEXT(K)
+             NEXT(K)=I
+             NCOUNTL=NCOUNTL+1
+      ENDIF
+C
+  30  CONTINUE
+C     ---------------------------------- End of surf. elem. loop
+       IF(LOST.GT.0) THEN
+       WRITE(6,1000) LOST
+       IF(PRINTFILE) WRITE(NFILE,1000) LOST
+ 1000  FORMAT(' ERROR: ',I6,' LIGHT POINTS LOST IN PROJECTION '/
+     1 ' This is a real program bug, because you should never have'/
+     2 ' caused this error in subroutine LUCE')
+       ENDIF
+C     .........................Finally computes the ligth to the 
+C                              observer by integration over the grid
+C
+C     ---------------------------------- BEGIN LIGHT SUM LOOP 40
+      DO 40 I=1,NPNT
+      IF(IGAINED(I).LE.0) GOTO 40
+      IF(NEXT(I).GT.0) NCOUNTL1=NCOUNTL1+1
+C     not eclipsed fraction of surf.element
+      REMAINED=1.- REAL(ILOST(I))/REAL(IGAINED(I))
+      IF(REMAINED.LE.0.0) GOTO 40
+C       ----------- loop on the link list of point I 
+C       The eclipsed fraction of point I is used for the whole link list
+      K=I
+  45  CONTINUE
+      GEOMETRY=(1.0+XLIMB(K)*(COSG(K)-1.0))*COSG(K)   * REMAINED
+      ALUCE= GEOMETRY *(FB(K)+FRIFL(K)) 
+      ALUCER=GEOMETRY * FRIFL(K)
+C     A concave object is represented by a number of convex parts,
+C     each drawn as a different object and numbered: obj.num ,obj.num+3 ,..+6...
+C     KOBJ= 1 for first,2 for second, 3 for third object.
+      KOBJ=NUMOBJ(K)
+C     The following holds also for numobj<=3, but if instead of -/* saves time
+      IF(KOBJ.GT.3) KOBJ=KOBJ-((KOBJ-1)/3)*3
+      CBOL(KOBJ,IF) =CBOL(KOBJ,IF) +ALUCE
+      CBOLR(KOBJ,IF)=CBOLR(KOBJ,IF)+ALUCER
+      DO 50 IB=1,NBANDE
+      IF(IBAND(IB).LE.0) GOTO 50
+      ALUCE=GEOMETRY * F(K,IB)
+      C(KOBJ,IB,IF)=C(KOBJ,IB,IF)+ALUCE
+  50  CONTINUE
+      NCOUNTT=NCOUNTT+1
+      IF(NEXT(K).GT.0) THEN
+        K=NEXT(K)
+        NCOUNTTL=NCOUNTTL+1
+        GOTO 45
+      ENDIF
+C      --------------- end of loop on the link list
+  40  CONTINUE
+C     ------------------------------ END OF THE LIGHT LOOP 
+C
+      CBOLT(IF)=CBOL(1,IF)+CBOL(2,IF)+CBOL(3,IF)
+      CBOLTR(IF)=CBOLR(1,IF)+CBOLR(2,IF)+CBOLR(3,IF)
+      DO 60 IB=1,NBANDE
+      IF(IBAND(IB).GT.0)
+     1    CT(IB,IF)=C(1,IB,IF)+C(2,IB,IF)+C(3,IB,IF)
+  60  CONTINUE 
+C
+C     ----------------------------------------------  PRINTING GRID 
+C
+C        ............ printing the grid points at each nprint phases
+C            .................. Printing the object in each grid
+      IF(NPRINT.LE.0.OR..NOT.PRINTFILE) GOTO 100
+      IF(MOD(IF,NPRINT).EQ.0) THEN
+C        ............ printing statistical data
+      IF(NPRINTL.LT.1) GOTO 100
+      WRITE(NFILE,5900) IF,NCOUNTS,NCOUNTL,NCOUNTS-NCOUNTL,
+     1                 NCOUNTE,NCOUNTV,NCOUNTD,NCOUNTD1,NCOUNTD2,
+     2                 NCOUNTF,
+     3                 NCOUNTT,NCOUNTTL,NCOUNTT-NCOUNTTL,NCOUNTL1
+ 5900 FORMAT(/' Statistics summary for ligth computation in phase:',I5/
+     1/' Number of considered surface elements:',I10/
+     2'    of which: after the first in link lists:',I10/
+     2'    of which: not in link lists or first of a list:',I10/
+     4' Number of cell expansions:',I10/
+     4' Number of expansions over void cells:',I10/
+     4' Number of expansions over different object''s cells:',I10/
+     4'   of which resulting in other object''s eclipsing :',I10/
+     4'   of which resulting in this  object''s eclipsing :',I10/
+     4' Number of expansions on same object''s cells:',I10/
+     9' Total number of remaining surface elements:',I10/
+     1'                  of which:in linklists    :',I10/
+     1'                  of which:not in linklists    :',I10/
+     1' Total number of remaining linklists :',I10)
+C
+      IF(NPRINTL.LT.2) GOTO 100
+      WRITE(NFILE,5999) IF,FASE(IF),FASE(IF)/6.28318
+ 5999 FORMAT(/' Number of object in each grid point for fase n.',I5,
+     1                                          ' => ',2G15.7)
+      NPSTP=NCELL/100
+      NPINIT=1
+      DO 62 IXX=1,NPSTP
+      NPFIN=NPINIT+(100-1)
+      DO 63 IY=1,NCELL
+      WRITE(NFILE,6000)IY,YCELL(IY),
+     1          (NUMOBJ(ABS(ICELL(IX,IY))),IX=NPINIT,NPFIN)
+ 6000 FORMAT(1X,I3,1X,G12.3,' = ',100I1)
+  63  CONTINUE
+      NPINIT=NPFIN+1
+  62  CONTINUE
+      IF(NPINIT.LE.NCELL) THEN
+        DO 64 IY=1,NCELL
+        WRITE(NFILE,6000)IY,YCELL(IY),
+     1            (NUMOBJ(ABS(ICELL(IX,IY))),IX=NPINIT,NCELL)
+  64    CONTINUE
+        ENDIF
+C       .................. Prints surf. point for each grid point
+      IF(NPRINTL.LT.3) GOTO 100
+C     Format I5 can't contain numbers > 99999 ,in this case it doesn't print
+      IF(NPNT.GT.99999) GOTO 100
+      WRITE(NFILE,6001) IF,FASE(IF),FASE(IF)/6.283185
+ 6001 FORMAT(' Number of surf.element in each grid point for fase n.',
+     1                                   I5,' => ',2G15.7)
+      NPSTP=NCELL/20
+      NPINIT=1
+      DO 67 IXX=1,NPSTP
+      NPFIN=NPINIT+(20-1)
+      WRITE(NFILE,6004)
+      WRITE(NFILE,6002)(IX,IX=NPINIT,NPFIN)
+ 6002 FORMAT(' Cell grid numbers: ',20(1X,I4))
+      WRITE(NFILE,6003)(XCELL(IX),IX=NPINIT,NPFIN)
+ 6003 FORMAT(' Cell grid center  :',20(F5.2))
+      WRITE(NFILE,6004)
+ 6004 FORMAT(1X,119(1H-))
+      DO 68 IY=1,NCELL
+      WRITE(NFILE,6005) IY,YCELL(IY),
+     1                     (ICELL(IX,IY),IX=NPINIT,NPFIN)
+ 6005 FORMAT(1X,I3,1X,G12.3,' = ',20I5)
+  68  CONTINUE
+      NPINIT=NPFIN+1
+  67  CONTINUE
+      IF(NPINIT.LE.NCELL) THEN
+        WRITE(NFILE,6004)
+        WRITE(NFILE,6002)(IX,IX=NPINIT,NCELL)
+        WRITE(NFILE,6003)(XCELL(IX),IX=NPINIT,NCELL)
+        WRITE(NFILE,6004)
+        DO 69 IY=1,NCELL
+        WRITE(NFILE,6005) IY,YCELL(IY),
+     1                      (ICELL(IX,IY),IX=NPINIT,NCELL)
+  69    CONTINUE
+        ENDIF
+      WRITE(NFILE,6004)
+C
+C     ........................... Printing eclipse-suppressed points
+C     ############################# solo utili per test non devono esistere
+      IF(NPRINTL.LT.4) GOTO 100
+      WRITE(NFILE,6010)
+ 6010 FORMAT(' Surface points which appear in the grid, but aren''t',
+     1       ' considered, being eclipsed:')
+      K=0
+      NDEL=0
+      DO 90 IY=1,NCELL
+      DO 90 IX=1,NCELL
+      KK=ICELL(IX,IY)
+      IF(KK.LE.0) GOTO 90      
+      IF(IGAINED(KK).GT.ILOST(KK)) GOTO 90
+      NDEL=NDEL+1
+      K=K+1
+      NBUF(K)=KK
+      IF(K.EQ.MAXBUF) THEN
+         WRITE(NFILE,6015) (NBUF(J),J=1,MAXBUF)
+ 6015    FORMAT(1X,20I5)
+         K=0
+         ENDIF
+  90  CONTINUE
+      IF(K.GT.0) WRITE(NFILE,6015) (NBUF(J),J=1,K)
+      WRITE(NFILE,6017) NDEL
+ 6017 FORMAT(' total:',I5,' surf.points not considered in the grid') 
+C   
+C     ............................... Printing the link lists
+C
+      IF(NPRINTL.LT.5) GOTO 100
+      WRITE(NFILE,6020)
+ 6020 FORMAT(' Linklists for the surf.points in the grid:')
+      K=0
+      NLIST=0
+      DO 95 I=1,NPNT
+      KK=I
+      IF(KK.LE.0) GOTO 95      
+      IF(IGAINED(KK).LE.0) GOTO 95
+      IF(IGAINED(KK).LE.ILOST(KK) ) GOTO 95
+      IF(NEXT(KK).LE.0) GOTO 95
+C     A linklist has been found, loops on its points.
+      NLIST=NLIST+1
+      WRITE(NFILE,6025) NLIST,KK
+ 6025 FORMAT(' Linklist:',I5,' First surf.element:',I6)
+   96 K=K+1
+      NBUF(K)=KK
+      IF(K.EQ.MAXBUF) THEN      
+         WRITE(NFILE,6015) (NBUF(J),J=1,MAXBUF)
+         K=0
+         ENDIF
+      KK=NEXT(KK)      
+      IF(KK.GT.0) GOTO 96
+      IF(K.GT.0) THEN
+         WRITE(NFILE,6015) (NBUF(J),J=1,K)
+         K=0
+         ENDIF
+  95  CONTINUE
+      IF(NLIST.LE.0) WRITE(NFILE,6030)
+ 6030 FORMAT(' NONE')
+C   
+      ENDIF
+ 100  CONTINUE
+C     ---------------------------------------------- END OF PRINTING  
+C
+  10  CONTINUE
+C        ................................. end of loop on phases
+C
+       IF(LOST.GT.0) THEN
+       WRITE(6,1100) LOST
+       IF(PRINTFILE) WRITE(NFILE,1100) LOST
+ 1100  FORMAT(' ERROR: ',I6,' LIGHT POINTS LOST IN INTEGRATION   '/
+     1 ' This is a real program bug, because you should never have'/
+     2 ' caused this error in subroutine LUCE')
+       ENDIF
+C
+      RETURN
+      END
+C
+       SUBROUTINE MAXABS(XMAX,N,X)
+C      --------------------------------------------------------
+C      returns xmax, maximum absolute value of x(n)
+C      --------------------------------------------------------
+       DIMENSION X(N)
+       XMAX=ABS(X(1))
+       DO 10 I=2,N
+       XX=X(I)
+       IF(XX.LT.0.) XX=-XX
+       IF(XX.GT.XMAX) XMAX=XX  
+   10  CONTINUE
+       RETURN
+       END
+C
+C
+       SUBROUTINE MAXMIN(XMAX,XMIN,N,X)
+C      -----------------------------------------------------------
+C      This routine find the maximum and minimum values for X
+C       ROUTINE NOT USED!
+C      -----------------------------------------------------------
+       DIMENSION X(N)
+       XMAX=X(1)
+       XMIN=X(1)
+       DO 10 I=2,N
+       IF(XMAX.LT.X(I)) XMAX=X(I)
+       IF(XMIN.GT.X(I)) XMIN=X(I)
+   10  CONTINUE
+       RETURN
+       END
+C
+       SUBROUTINE NOREFL(NPNT,NIF,FBOLREF,FRIFL)
+C      --------------------------------------------------
+C      This routine sets the reflected flux to zero 
+C      REALLY, MAY BE SIMPLIFIED !!!
+C      ------------------------------------------------
+       DIMENSION FRIFL(NPNT),FBOLREF(3),NIF(2,3)
+C
+C      ..................... loop on objects
+       DO 10 I=1,3
+       N1=NIF(1,I)
+       N2=NIF(2,I)
+       FBOLREF(I)=0.0
+       IF(N1.LE.0.OR.N2.LE.0) GOTO 10
+       DO 20 J=N1,N2
+       FRIFL(J)=0.0
+   20  CONTINUE
+   10  CONTINUE
+       RETURN
+       END
+C
+       SUBROUTINE NORM(N,A,B)
+C      --------------------------
+C      Multiplies B(i) by A
+C      --------------------------
+       DIMENSION B(N)
+       DO 10 I=1,N
+   10  B(I)=B(I)*A
+       RETURN
+       END
+C
+       SUBROUTINE NORMC(ANORMC,IFLAG)
+C      ---------------------------------------------------------------
+C      Normalizes the light curve to have max value= ANORMC 
+C      This is done for bolometric flux CBOLT,
+C      and each requested color band CT,(requested bands have iflag>0)
+C      ---------------------------------------------------------------
+       PARAMETER (MAXFASI=1000, MAXBANDE=5)
+       COMMON /LIGHT/ NFASIMX,NFASI,NBANDE,
+     1               FASE(MAXFASI),O(MAXBANDE,MAXFASI),
+     2               C(3,MAXBANDE,MAXFASI),CT(MAXBANDE,MAXFASI),
+     3               CBOL(3,MAXFASI),CBOLT(MAXFASI),
+     4               CBOLR(3,MAXFASI),CBOLTR(MAXFASI),
+     5               AREA(3),FBOLTOT(3),FBOL(3),FBOLREF(3)
+C 
+       DIMENSION IFLAG(MAXBANDE)
+C
+C       normalizing bolometric flux, total and for each object
+C       also reflection sources are normalized
+       AMAX=AMAX2(NFASI,CBOLT)
+       IF(AMAX.EQ.0.0) GOTO 100 
+       DO 10 I=1,NFASI
+       CBOLT(I)=CBOLT(I)/AMAX*ANORMC
+       CBOL(1,I)=CBOL(1,I)/AMAX*ANORMC
+       CBOL(2,I)=CBOL(2,I)/AMAX*ANORMC
+       CBOL(3,I)=CBOL(3,I)/AMAX*ANORMC
+       CBOLTR(I)=CBOLTR(I)/AMAX*ANORMC
+       CBOLR(1,I)=CBOLR(1,I)/AMAX*ANORMC
+       CBOLR(2,I)=CBOLR(2,I)/AMAX*ANORMC
+       CBOLR(3,I)=CBOLR(3,I)/AMAX*ANORMC
+   10  CONTINUE
+  100  CONTINUE
+C
+C       normalizing color band flux, total and for each object
+        DO 20 I=1,NBANDE
+        IF(IFLAG(I).LE.0) GOTO 20
+        AMAXB=CT(I,1)
+        DO 30 J=2,NFASI
+        IF(CT(I,J).GT.AMAXB) AMAXB=CT(I,J)
+   30   CONTINUE
+        IF(AMAXB.EQ.0.0) GOTO 20
+        DO 40 J=1,NFASI
+        CT(I,J)=CT(I,J)/AMAXB*ANORMC
+        C(1,I,J)=C(1,I,J)/AMAXB*ANORMC
+        C(2,I,J)=C(2,I,J)/AMAXB*ANORMC
+        C(3,I,J)=C(3,I,J)/AMAXB*ANORMC
+   40   CONTINUE
+   20   CONTINUE
+        RETURN
+        END
+C
+       SUBROUTINE NORML(NPNT,FINPUT,TL,F)
+C      -----------------------------------------------------------
+C      Normalization routine. Normalizes the total flux to an
+C      input given value FINPUT. ( Here the flux of each surface
+C      element had been previously multiplied by the element area)
+C      -----------------------------------------------------------
+       DIMENSION F(NPNT)
+       TL=0.0
+       DO 10 I=1,NPNT
+   10  TL=TL+F(I)
+       DO 20 I=1,NPNT
+   20  F(I)=(FINPUT/TL)*F(I)
+       RETURN
+       END
+C
+       SUBROUTINE NULL(N,A)
+C      -----------------------
+C      Fills A with 0.0
+C      ----------------------
+       DIMENSION A(N)
+       DO 10 I=1,N
+   10  A(I)=0.0
+       RETURN
+       END
+C
+       FUNCTION PLANK(AL,TEMPER)
+C      -------------------------------------------------
+C      Value of Plank function, for lambda AL ( Anstrong )
+C      and temperature TEMPER ( K )
+C      PLANK= erg/cm**2/sec/sterad / lambda unit
+C      -------------------------------------------------
+C
+C       This is for lambda in Anstrong : 1 cm = 1.E8 Anstrong, may give overflow
+C       PLANK=1.1909D35 / 
+C     1   ( AL**5 * (DEXP (1.4398D+8/(DBLE(AL)*DBLE(TEMPER)) ) -1.D0) )
+C           This is for lambda in cm
+C       PLANK=1.1909D-5 / 
+C     1   ( AL**5 * (DEXP (1.4398D0/(DBLE(AL)*DBLE(TEMPER)) ) -1.D0) )
+C           This is for lambda in A/1000 and A
+        AL1=AL/1000.
+       PLANK=1.1909D20 / 
+     1   ( AL1**5 * (DEXP (1.4398D+8/(DBLE(AL)*DBLE(TEMPER)) ) -1.D0) )
+       RETURN
+       END
+C
+       FUNCTION PLANKL(AL,TEMPER)
+C      -------------------------------------------------
+C      Value of Plank function * delta lambda
+C      delta lambda =1 A 
+C      -------------------------------------------------
+C
+C           This is for lambda in Anstrong : 1 cm = 1.E8 Anstrong
+        AL1=AL/1000.
+        PLANKL=1.1909D12 / 
+     1   ( AL1**5 * (DEXP (1.4398D+8/(DBLE(AL)*DBLE(TEMPER)) ) -1.D0) )
+C       PLANKL=1.1909D27 / 
+C     1   ( AL**5 * (DEXP (1.4398D+8/(DBLE(AL)*DBLE(TEMPER)) ) -1.D0) )
+       RETURN
+       END
+C
+       SUBROUTINE PLOTTING(PRINTFILE,NFILE,PRINT6,
+     1                             AMOUNTP,NFILE6P,NFILEP,NASCIIP)
+C      ----------------------------------------------------------------
+C       Plotting routine : now only writes on unit nasciip,
+C       plots are done by an'other program.
+C      ----------------------------------------------------------------
+       PARAMETER (MAXFASI=1000, MAXBANDE=5)
+       COMMON /LIGHT/ NFASIMX,NFASI,NBANDE,
+     1               FASE(MAXFASI),O(MAXBANDE,MAXFASI),
+     2               C(3,MAXBANDE,MAXFASI),CT(MAXBANDE,MAXFASI),
+     3               CBOL(3,MAXFASI),CBOLT(MAXFASI),
+     4               CBOLR(3,MAXFASI),CBOLTR(MAXFASI),
+     5               AREA(3),FBOLTOT(3),FBOL(3),FBOLREF(3)
+C 
+      LOGICAL PRINTFILE,PRINT6
+      DIMENSION FASI01(MAXFASI)
+C
+      DO 10 I=1,NFASI
+   10 FASI01(I)=FASE(I)/(2.*3.141593)
+C
+      IF(NASCIIP.GT.0.AND.NASCIIP.LE.99) THEN
+         OPEN(UNIT=NASCIIP,FORM='FORMATTED',STATUS='NEW')
+         DO 20 I=1,NFASI
+         WRITE(NASCIIP,1000) I,FASI01(I),CBOLT(I),
+     1             (CT(J,I),J=1,NBANDE),(O(J1,I),J1=1,NBANDE)
+ 1000    FORMAT(1X,I5,1X,F6.4,11(1X,F9.6))
+   20    CONTINUE
+         CLOSE(UNIT=NASCIIP)
+         IF(PRINT6) WRITE(6,2000) NASCIIP,NFASI,NBANDE
+         IF(PRINTFILE) WRITE(NFILE,2000) NASCIIP,NFASI,NBANDE
+ 2000    FORMAT(/' Light curve written on unit:',I2,' Num.phases:',
+     1          I8,' Num. of colors:',I2)
+      ENDIF
+C
+      RETURN
+      END
+C
+       SUBROUTINE POINT(PRINT6,PRINTFILE,NFILE,NRF,NTHF,PKRI,NOBJ,
+     1       NPUNT,NPUNTC,R,RY,X0,Y0,Z0,ALZO,ROTAZ,R4PREC,
+     2       NPNTMX,X,Y,Z,G,GX,GY,GZ,FX,FY,FZ,TX,TY,TZ,AREA,A,NUMCOARSE,
+     3       NUMOBJ)
+C      ----------------------------------------------------------------
+C      Draws a bright point surface, in a rectangle
+C      R=x half-edge
+C      RY=y half-edge
+C      NRF= number of fine r mesh in which 2*R is divided.
+C      NTHF= coarsing factor=number of fine for each coarse
+C      NRC= number of r coarse
+C       if PKRI > 0.0 also the back surface of the rectangle is drawn.
+C
+C      After drawing on the plane x-y the cylinder can be rotated:
+C      ROTAZ= anti-clockwise angle of rotazion on the plane (x-x'angle)
+C      ALZO= clockwise rotation around the y' axis (z-z" angle)
+C
+C      ----------------------------------------------------------------
+       DIMENSION X(NPNTMX),Y(NPNTMX),Z(NPNTMX)
+       DIMENSION G(NPNTMX),GX(NPNTMX),GY(NPNTMX),GZ(NPNTMX)
+       DIMENSION FX(NPNTMX),FY(NPNTMX),FZ(NPNTMX)
+       DIMENSION TX(NPNTMX),TY(NPNTMX),TZ(NPNTMX)
+       DIMENSION A(NPNTMX)
+       DIMENSION NUMCOARSE(NPNTMX),NUMOBJ(NPNTMX)
+       LOGICAL PRINTFILE,PRINT6
+C
+C          Coarse mesh
+       NRC=NRF/NTHF
+       IF(MOD(NRF,NTHF).NE.0) THEN
+         WRITE(6,1000) NRF,NTHF
+ 1000    FORMAT(' ERROR! In drawing a rectangle the number of r mesh:',
+     1           I5,' is not consistent with the coarsing factor:',I5)
+       ENDIF
+C
+C          coarse mesh
+       EDGE=2.0*R
+       DRC=EDGE/NRC
+       DRC5=DRC*0.5
+C          fine r mesh
+       DRF=DRC/NTHF
+       DRF5=DRF*0.5
+C
+C      NPUNTC will be incremented below. (NPUNTC is the first void coarse)
+C      IC is instead the actual coarse, or the last filled one.
+C      NPUNT is the number of surf.el. generated by this routine 
+       IF(PKRI.GT.0.0) THEN
+         IC=NPUNTC-2
+       ELSE
+         IC=NPUNTC-1
+       ENDIF
+C
+C         Y coarse and fine mesh (Y must be a multiple of X: DRCY=DRC)
+       DRCY=DRC 
+       EDGEY=2.0*RY
+       NRCY=EDGEY/DRCY
+       DRCY5=DRCY*0.5
+       DRFY=DRCY/NTHF
+       DRFY5=DRFY*0.5
+C      ...............
+       NPUNT=0
+       AREA=0.0
+C
+C      ................... Coarse X loop ( from center -R to R)
+       DO 10 IXC=1,NRC
+       X1C=-R+(IXC-1)*DRC
+       X2C= X1C+DRC
+C
+C      ................... Coarse Y loop ( from center -R to R)
+       DO 10 IYC=1,NRCY
+       Y1C=-RY+(IYC-1)*DRCY
+       Y2C= Y1C+DRCY
+C
+       IF(PKRI.GT.0.0) THEN
+          IC=IC+2
+       ELSE
+          IC=IC+1
+       ENDIF       
+C
+C      ................... Fine X  loop ( from X1C to X2C )
+       DO 10 IXF=1,NTHF
+       XF=X1C+(IXF-1)* DRF +DRF5
+C
+C      ................... Fine Y  loop ( from Y1C to Y2C )
+       DO 10 IYF=1,NTHF
+       YF=Y1C+(IYF-1)* DRFY +DRFY5
+C
+C         Upper surface point
+       IF(NPUNT.GE.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 100
+                       ELSE
+                       NPUNT=NPUNT+1
+                       ENDIF
+       X(NPUNT)=   XF  
+       Y(NPUNT)=   YF  
+       Z(NPUNT)=   0.0    
+       GX(NPUNT)=  0.0 
+       GY(NPUNT)=  0.0 
+       GZ(NPUNT)=  1.0
+       FX(NPUNT)=  0.
+       FY(NPUNT)=  DRFY5
+       FZ(NPUNT)=  0.
+       TX(NPUNT)=  DRF5
+       TY(NPUNT)=  0.
+       TZ(NPUNT)=  0.
+       A(NPUNT) =  DRF*DRFY 
+       NUMCOARSE(NPUNT)=IC
+       NUMOBJ(NPUNT)=NOBJ
+C      area computation
+       AREA=A(NPUNT)+AREA
+C
+C         Lower surface point
+ 100   IF(PKRI.LE.0.0) GOTO 10
+       IF(NPUNT.GE.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 10
+                       ELSE
+                       NPUNT=NPUNT+1
+                       ENDIF
+       X(NPUNT)= XF 
+       Y(NPUNT)= YF 
+       Z(NPUNT)= 0.0
+       GX(NPUNT)=  0.0 
+       GY(NPUNT)=  0.0 
+       GZ(NPUNT)= -1.0 
+       FX(NPUNT)=  0.0
+       FY(NPUNT)=  DRFY5
+       FZ(NPUNT)=  0.0
+       TX(NPUNT)= -DRF5
+       TY(NPUNT)=  0.0
+       TZ(NPUNT)=  0.0
+       A(NPUNT) =  DRF*DRFY 
+       NUMCOARSE(NPUNT)=IC+1
+       NUMOBJ(NPUNT)=NOBJ
+C      Total area computation
+       AREA=A(NPUNT)+AREA
+C
+   10  CONTINUE
+C
+C      IF the IC+1 coarse has been filled by loop 10
+       IF(PKRI.GT.0.0) IC=IC+1
+C
+       NPUNTC=IC+1
+C
+C                 Constant potential USEFUL FOR POINT ?
+       DO 59 I=1,NPUNT
+   59  G(I)=1.
+C
+       IF(LOST.GT.0) THEN
+         WRITE(6,2000) NPUNT,LOST
+         IF(PRINTFILE) WRITE(NFILE,1000) NPUNT,LOST
+ 2000    FORMAT(' ERROR! In POINT:OBJECT NOT PROPERLY DRAWN! '/
+     1    ' space available for only:',I6,' surface points.',
+     2    ' lost points:',I6/
+     3    ' REDUCE THE MESH PARAMETER OR GO INTO THE FORTRAN LIST TO',
+     4    ' INCREASE MAXPT')
+       ENDIF
+C
+C           ................ optional rotation .....
+C
+       IF(ALZO.EQ.0.0.AND.ROTAZ.EQ.0.0) GOTO 800
+C       The disk is rotated by rotaz around the z axis (anti-clockwise)
+C       then around the new Y axis (clockwise) by alzo
+       COSP=COS(ROTAZ)
+       SINP=SIN(ROTAZ)
+       COSI=COS(ALZO)
+       SINI=SIN(ALZO)
+C
+C      To prevent precision broblems
+       IF(ABS(COSP).LT.R4PREC) COSP=0.0
+       IF(ABS(SINP).LT.R4PREC) SINP=0.0
+       IF(ABS(COSI).LT.R4PREC) COSI=0.0
+       IF(ABS(SINI).LT.R4PREC) SINI=0.0
+C
+       DO 80 I=1,NPUNT
+       X1= X(I)* (COSP*COSI) + Y(I) * SINP - Z(I) * (COSP*SINI)
+       Y1=-X(I)* (SINP*COSI) + Y(I) * COSP + Z(I) * (SINP*SINI)
+       Z1= X(I)*       SINI                + Z(I) *       COSI
+       X(I)=X1
+       Y(I)=Y1
+       Z(I)=Z1
+       X1= GX(I)* (COSP*COSI) + GY(I) * SINP - GZ(I) * (COSP*SINI)
+       Y1=-GX(I)* (SINP*COSI) + GY(I) * COSP + GZ(I) * (SINP*SINI)
+       Z1= GX(I)*       SINI                 + GZ(I) *       COSI
+       GX(I)=X1
+       GY(I)=Y1
+       GZ(I)=Z1
+       X1= TX(I)* (COSP*COSI) + TY(I) * SINP - TZ(I) * (COSP*SINI)
+       Y1=-TX(I)* (SINP*COSI) + TY(I) * COSP + TZ(I) * (SINP*SINI)
+       Z1= TX(I)*       SINI                 + TZ(I) *       COSI
+       TX(I)=X1
+       TY(I)=Y1
+       TZ(I)=Z1
+       X1= FX(I)* (COSP*COSI) + FY(I) * SINP - FZ(I) * (COSP*SINI)
+       Y1=-FX(I)* (SINP*COSI) + FY(I) * COSP + FZ(I) * (SINP*SINI)
+       Z1= FX(I)*       SINI                 + FZ(I) *       COSI
+       FX(I)=X1
+       FY(I)=Y1
+       FZ(I)=Z1
+C
+   80  CONTINUE
+C   
+  800  CONTINUE
+C        shifting the point from the origin=(0,0,0) to x0,y0,z0
+       IF(X0.NE.0.0) THEN
+         DO 90 I=1,NPUNT
+   90    X(I)=X(I)+X0
+       ENDIF
+       IF(Y0.NE.0.0) THEN
+         DO 91 I=1,NPUNT
+   91    Y(I)=Y(I)+Y0
+       ENDIF
+       IF(Z0.NE.0.0) THEN
+         DO 92 I=1,NPUNT
+   92    Z(I)=Z(I)+Z0
+       ENDIF
+C
+       RETURN
+       END              
+C
+      SUBROUTINE PRINTING(AMOUNT,NT6,NT,IPPAR1,IPPAR2,
+     1                    NAMFLAG,DESCFLAG,NAMPAR,DESCPAR,AUS)
+C     ----------------------------------
+C     Output printing routine
+C     ----------------------------------
+       PARAMETER (MAXPT=200000 ,MAXALLIN=250000)
+       PARAMETER (MAXPTC=50000)
+       PARAMETER ( MAXFASI=1000, MAXBANDE=5)
+       PARAMETER (MAXFLAG=21 , MAXPAR=128 , MAXPARS=20 )
+       PARAMETER (MAXCELL=1000 )
+       PARAMETER (MAXTITLE=5)
+       PARAMETER ( MAXFILT=5 , MAXLAM=15 )
+C
+       COMMON /SURF/ NPNTMX,NPNT,NPNT1,NPNT2,NPNT3,
+     A               N1I,N1F,N2I,N2F,N3I,N3F,
+     1               X(MAXPT),Y(MAXPT),Z(MAXPT),
+     2               G(MAXPT),GX(MAXPT),GY(MAXPT),GZ(MAXPT),
+     3               FX(MAXPT),FY(MAXPT),FZ(MAXPT),
+     4               TX(MAXPT),TY(MAXPT),TZ(MAXPT),
+     5               T(MAXPT),A(MAXPT),
+     6               FB(MAXPT),F(MAXPT,MAXBANDE),FRIFL(MAXPT),
+     7               XLIMB(MAXPT),NUMOBJ(MAXPT),ALB(MAXPT),
+     8               NUMCOARSE(MAXPT)
+C 
+      DIMENSION NP123(3)
+      DIMENSION NIF(2,3)
+      EQUIVALENCE (NP123(1),NPNT1),(NIF(1,1),N1I)
+       COMMON /SURFC/ NPNTMXC,NPNTC,NPNT1C,NPNT2C,NPNT3C,
+     A               N1IC,N1FC,N2IC,N2FC,N3IC,N3FC,
+     1               XC(MAXPTC),YC(MAXPTC),ZC(MAXPTC),
+     2               GC(MAXPTC),GXC(MAXPTC),GYC(MAXPTC),GZC(MAXPTC),
+     5               AC(MAXPTC),
+     6               DIMCX(MAXPTC),DIMCY(MAXPTC),DIMCZ(MAXPTC),
+     6               FBC(MAXPTC),FRIFLC(MAXPTC),
+     7               XLIMBC(MAXPTC),NUMOBJC(MAXPTC),ALBC(MAXPTC),
+     8               NUMFINI(MAXPTC)
+      DIMENSION NP123C(3)
+      DIMENSION NIFC(2,3)
+      EQUIVALENCE (NP123C(1),NPNT1C),(NIFC(1,1),N1IC)
+C 
+C 
+      COMMON /ALLIN/ NALLMX,NALL,ITERDONE,
+     1               ISOUR(MAXALLIN),JRIC(MAXALLIN),
+     2               TRANSFI(MAXALLIN),TRANSFJ(MAXALLIN),
+     3               FSOURI(MAXALLIN),FSOURJ(MAXALLIN),
+     4               FRICI(MAXALLIN),FRICJ(MAXALLIN),
+     5               RIJ(MAXALLIN),
+     6               RXIJ(MAXALLIN),RYIJ(MAXALLIN),RZIJ(MAXALLIN),
+     7               COSGI(MAXALLIN),COSGJ(MAXALLIN),
+     8               IAUS(MAXALLIN)
+C
+      COMMON /LIGHT/ NFASIMX,NFASI,NBANDE,
+     1               FASE(MAXFASI),O(MAXBANDE,MAXFASI),
+     2               C(3,MAXBANDE,MAXFASI),CT(MAXBANDE,MAXFASI),
+     3               CBOL(3,MAXFASI),CBOLT(MAXFASI),
+     4               CBOLR(3,MAXFASI),CBOLTR(MAXFASI),
+     5               AREA(3),FBOLTOT(3),FBOL(3),FBOLREF(3)
+C 
+      COMMON /VISUAL/ NCELL,CELLMAX,CELLMIN,DCELL,
+     1                    XCELL(MAXCELL),YCELL(MAXCELL)
+C
+      COMMON/TITLE/NTITLEMX,NTITLE,TITLE(MAXTITLE)      
+      CHARACTER*80 TITLE
+C
+      COMMON /ROCHE/ AL1,AL2,AL3,XA1,XA2,XB1,XB2,YA,YB,
+     1               OMEGAL1,OMEGAL2,OMEGAL3,
+     2               RPOLE(3),XPOLE(3),YPOLE(3),ZPOLE(3),TPOLE(3),
+     3               GXPOLE(3),GYPOLE(3),GZPOLE(3)
+C
+       COMMON /FILTRI/ NFILT,NLAM, NLAMBDA(MAXFILT),DELTALAM(MAXLAM),
+     1     ALAMBDA(MAXLAM,MAXFILT),TRASMISS(MAXLAM,MAXFILT),
+     2     COMPFRAC(MAXFILT,3)
+C
+      COMMON /PAR/ NFLAG,IFLAG(MAXFLAG),NPAR,PAR(MAXPAR)
+      DIMENSION PARS(MAXPARS,3)
+      EQUIVALENCE (PARS(1,1),PAR(1))
+      DIMENSION IPPAR1(MAXFLAG),IPPAR2(MAXFLAG)
+      CHARACTER*(*) NAMFLAG(MAXFLAG),DESCFLAG(MAXFLAG)
+      CHARACTER*(*) NAMPAR(MAXPAR),DESCPAR(MAXPAR)
+C
+      DIMENSION AUS(MAXPT)
+C
+      DIMENSION FASI01(MAXFASI)
+      CHARACTER*3 YESNO(-1:2)
+      DATA YESNO/'OLD','NO ','YES','NEW'/
+C     primo: flag used to know if some line has been printed
+      LOGICAL PRIMO 
+C     ............................................................
+C
+C     ............... phases from 0 to 1 for printing only
+      DO 10 I=1,NFASI
+   10 FASI01(I)=FASE(I)/(3.14159*2.)
+C       
+C     ............... computing radii for each surf element if needed
+      IF(AMOUNT.GE.6..AND.(NT6.GT.0.OR.(NT.GT.0.AND.NT.LE.99) )) THEN
+      DO 20 I=1,NPNT
+         NUMERO=NUMOBJ(I)
+         X000=PARS(3,NUMERO)
+         Y000=PARS(4,NUMERO)
+         Z000=PARS(5,NUMERO)
+         AUS(I)=SQRT( (X(I)-X000)*(X(I)-X000)+
+     1                (Y(I)-Y000)*(Y(I)-Y000)+
+     2                (Z(I)-Z000)*(Z(I)-Z000) )
+   20 CONTINUE
+      ENDIF 
+C
+C               ------------------------------ PRINTING ON UNIT 6     
+      IF(NT6.GT.0) THEN
+C
+      IF(AMOUNT.LT.1.0) GO TO 600
+C            ......................... general and input data
+      WRITE(6,5800)
+ 5800 FORMAT(1H1///,50X,29('-')/50X,' Ligth Curve Analysis Results'/
+     1       50X,29('-')// )
+      WRITE(6,5799) (TITLE(J),J=1,NTITLE)
+ 5799 FORMAT(20X,A80)
+      WRITE(6,5801)
+ 5801 FORMAT(//' OPTION SUMMARY:')
+      WRITE(6,5802) (NAMFLAG(J),DESCFLAG(J),YESNO(IFLAG(J)),J=1,10)
+ 5802 FORMAT(1X,A,A,4X,A)
+C     ....................   Printing orbital parameters
+      WRITE(6,5813)
+ 5813 FORMAT(//' ORBITAL AND GRID PARAMETERS:')
+      K1=IPPAR1(11)
+      K2=IPPAR2(11)
+      WRITE(6,5804) (NAMPAR(J),DESCPAR(J),PAR(J),J=K1,K2)
+      K1=IPPAR1(12)
+      K2=IPPAR2(12)
+      WRITE(6,5804) (NAMPAR(J),DESCPAR(J),PAR(J),J=K1,K2)
+      K1=IPPAR1(13)
+      K2=IPPAR2(13)
+      WRITE(6,5804) (NAMPAR(J),DESCPAR(J),PAR(J),J=K1,K2)
+ 5804 FORMAT(1X,A,A,4X,G15.7)
+C     .....................  Printing reflection parameters
+      IF(IFLAG(9).GT.0) THEN
+           WRITE(6,5805)
+ 5805      FORMAT(/' PARAMETERS FOR REFLECTION COMPUTATION')
+           K1=IPPAR1(9)
+           K2=IPPAR2(9)
+           WRITE(6,5804) (NAMPAR(J),DESCPAR(J),PAR(J),J=K1,K2)
+           ENDIF
+C     .......................... printing colour band parameter
+      DO 30 I=4,7
+      IF(IFLAG(I).LE.0) GOTO 30
+      K1=IPPAR1(I)
+      K2=IPPAR2(I)
+      WRITE(6,5830) I-3,(NAMPAR(J),DESCPAR(J),PAR(J),J=K1,K2)
+ 5830 FORMAT(/' INPUT PARAMETERS FOR COLOUR BAND: ',I2/
+     1  ((2X,A,2X,A,2X,G15.7)) )
+   30 CONTINUE
+C     .......................... printing print input parameters
+      K1=IPPAR1(20)
+      K2=IPPAR2(20)
+      WRITE(6,6015) (NAMPAR(J),DESCPAR(J),PAR(J),J=K1,K2)
+ 6015 FORMAT(//' PRINTED OUTPUT PARAMETERS:'/((2X,A,2X,A,2X,G15.7)))
+C
+C     .......................... printing plot input parameters
+      IF(IFLAG(21).GT.0) THEN
+        K1=IPPAR1(21)
+        K2=IPPAR2(21)
+        WRITE(6,6017) (NAMPAR(J),DESCPAR(J),PAR(J),J=K1,K2)
+ 6017 FORMAT(//' PLOTTING OUTPUT PARAMETERS:'/((2X,A,2X,A,2X,G15.7)))
+      ENDIF
+C
+C     .................. Printing stars and disk parameters
+      DO 60 I=1,3 
+      IF(NP123(I).LE.0) GOTO 60
+      K1=(I-1)*MAXPARS+1
+      K2=I*MAXPARS
+      WRITE(6,6000) I,(NAMPAR(J),DESCPAR(J),PAR(J),J=K1,K2)
+ 6000 FORMAT(/' INPUT PARAMETERS FOR OBJECT NUMBER: ',I2/
+     1  ((2X,A,2X,A,2X,G15.7)) )
+   60  CONTINUE
+C          .............. roche model parameters
+      IF(PARS(1,1).EQ.2..OR.PARS(1,2).EQ.2.) THEN
+        WRITE(6,6005) AL1,AL2,AL3,OMEGAL1,OMEGAL2,OMEGAL3,
+     1                XA1,XA2,XB1,XB2,YA,YB
+ 6005   FORMAT(/' ROCHE MODEL DATA:'/
+     1         '  L1,L2,L3 : lagrange points x position:',3G15.7/
+     2         '  potential for surfaces at L1,L2,L3   :',3G15.7/
+     3         '  XA1,XA2  : intersection star A-x axis:',2G15.7/    
+     4         '  XB1,XB2  : intersection star B-x axis:',2G15.7/    
+     5         '  approx. y dimension for critical lobe:',2G15.7)
+      PRIMO=.TRUE.
+      DO 62 I=1,3
+      IF(PARS(1,I).NE.2..OR.PARS(9,I).LE.0.0) GOTO 62
+C     Following data is computed  only for roche model and gravity dark.
+      IF(PRIMO) THEN
+        WRITE(6,6006)
+ 6006   FORMAT(//' Obj. ,pole: R',7X,'X',7X,7X,'Y',7X,7X,'Z',7X,
+     1       7X,'GX',6X,7X,'GY',6X,7X,'GZ',6X,10X,'T')
+        PRIMO=.FALSE.
+      ENDIF
+      WRITE(6,6007) I,RPOLE(I),XPOLE(I),YPOLE(I),ZPOLE(I),
+     2                GXPOLE(I),GYPOLE(I),GZPOLE(I),TPOLE(I)
+ 6007 FORMAT(1X,I2,1X,8G15.7)
+   62 CONTINUE
+      ENDIF    
+C           ........................... run data
+      K1=INT(PAR(IPPAR1(9)+3))
+      WRITE(6,5803) NPNT,NPNTMX,NPNT1,NPNT2,NPNT3,
+     1              NPNTC,NPNTMXC,K1,NPNT1C,NPNT2C,NPNT3C,
+     2              NALL,MAXALLIN,ITERDONE
+ 5803 FORMAT(/' RUN PARAMETERS:'//
+     1 10X,' Fine grid surface elements  :',I10,10X,' Max allowed :',
+     2 I10/48X,' For object 1:',I10/48X,' For object 2:',I10/
+     3 48X,' For object 3:',I10//
+     4 10X,' Coarse grid surface elements:',I10,10X,' Max allowed :',
+     5 I10,' Coarsing factor:',I5/
+     6 48X,' For object 1:',I10/48X,' For object 2:',I10/
+     6 48X,' For object 3:',I10/
+     7 10X,' Reflection paths:',I10,10X,' Max allowed :',I10,
+     8 10X,' Iterations done:',I5)
+C
+      WRITE(6,6010)
+ 6010 FORMAT(///'  BOLOMETRIC LUMINOSITY FOR EACH OBJECT :'/
+     1 '  object number, total surf.area,',
+     2 ' emitted lumin.,reflected lum.,'
+     3 ' total lum., input lum. value, lum.norm.factor')
+      DO 61 I=1,3
+      IF(NP123(I).LE.0) GOTO 61
+      FBOLTR=FBOL(I)+FBOLREF(I)
+      WRITE(6,6011) I,AREA(I),FBOL(I),FBOLREF(I),FBOLTR,
+     1              PARS(11,I),FBOLTOT(I)
+ 6011 FORMAT(I9,7X,6G15.7)
+   61 CONTINUE
+C
+      WRITE(6,6012)
+      WRITE(6,6013) (I,(COMPFRAC(IB,I),IB=1,NFILT),I=1,3)
+ 6012 FORMAT(//' Objectc ',7X,'U-band lum.',5X,'B-band lum.',5X,
+     1         'V-band lum.',5X,'R-band lum.',5X,'I-band lum.') 
+ 6013 FORMAT((1X,I4,5X,5(1X,G15.7)))
+C
+      IF(AMOUNT.LT.2.0) GOTO 600
+C           ......................  light received for each phase
+      WRITE(6,6020) NCELL,NCELL,DCELL,CELLMIN,CELLMAX
+ 6020 FORMAT(///' LIGHT CURVE PRODUCED:',8X,
+     1  '(grid used:',I4,' *',I4,5X,'; step:',G12.5,2X,' from:',
+     2  G12.5,5X,' to:',G12.5,' )'/5X,'Phase',5X,13X,
+     3 5X,'bol.lum.',6X,'from star A',4X,'from star B',5X,'from disk')
+      WRITE(6,6021) 
+     1 (J,FASE(J),FASI01(J),CBOLT(J),CBOL(1,J),CBOL(2,J),CBOL(3,J),
+     2                                                    J=1,NFASI)
+ 6021 FORMAT((I4,G12.5,1X,G12.5,4(1X,G14.7)))
+C
+      IF(AMOUNT.LT.2.5) GOTO 600
+C         .......................... reflected light for each fase
+      IF(IFLAG(9).GT.0) THEN
+      WRITE(6,6025) 
+ 6025 FORMAT(///' REFLECTED LIGHT:'/5X,'Phase',5X,13X,
+     3 4X,'refl.lum.',6X,'from star A',4X,'from star B',5X,'from disk')
+      WRITE(6,6021) 
+     1 (J,FASE(J),FASI01(J),CBOLTR(J),CBOLR(1,J),CBOLR(2,J),CBOLR(3,J),
+     2                                                    J=1,NFASI)
+C
+C         .......................... light curve without reflection
+      WRITE(6,6026) 
+ 6026 FORMAT(///' LIGHT CURVE WITHOUT REFLECTION:'/5X,'Phase',5X,13X,2X
+     3,'unrefl.lum.',6X,'from star A',4X,'from star B',5X,'from disk')
+      WRITE(6,6021) 
+     1 (J,FASE(J),FASI01(J),CBOLT(J)-CBOLTR(J),
+     2  CBOL(1,J)-CBOLR(1,J),CBOL(2,J)-CBOLR(2,J),
+     3  CBOL(3,J)-CBOLR(3,J),J=1,NFASI)
+      ENDIF 
+C
+      IF(AMOUNT.LT.3.0) GOTO 600
+C           ......................  Color band flux 
+      DO 65 IB=1,NBANDE
+      IF(IFLAG(3+IB).LE.0) GOTO 65
+      WRITE(6,6030) IB
+ 6030 FORMAT(///' LIGHT CURVE FOR COLOR ',I2,' :'/5X,'Phase',5X,13X,2X
+     3,'luminosity  ',6X,'from star A',4X,'from star B',5X,'from disk',
+     4 4X,' observed ')
+      WRITE(6,6031) 
+     1 (J,FASE(J),FASI01(J),CT(IB,J),C(1,IB,J),C(2,IB,J),C(3,IB,J),
+     2  O(IB,J),J=1,NFASI)
+ 6031 FORMAT((I4,G12.5,1X,G12.5,5(1X,G14.7) ))
+   65 CONTINUE
+C      
+      IF(AMOUNT.LT.5.0) GOTO 600
+C           .....................   Coarse grid description of surfaces
+      IF(IFLAG(9).GT.0) THEN
+      WRITE(6,6045)
+ 6045 FORMAT(///' COARSE GRID SURFACE ELEMENTS DESCRIBING OBJECTS:'
+     a  /' N. object',
+     1  4X,'x',13X,'y',12X,'z',11X,'area',
+     2  12X,'g',13X,'gx',11X,'gy',12X,'gz',11X,'num.fines'/)
+      WRITE(6,6046)
+     1 (J,NUMOBJC(J),XC(J),YC(J),ZC(J),AC(J),
+     2    GC(J),GXC(J),GYC(J),GZC(J),NUMFINI(J),J=1,NPNTC)
+ 6046 FORMAT((1X,2I3,8(1X,1PG13.6),1X,I9))
+      WRITE(6,6047)
+ 6047 FORMAT(///3X,'N. object',3X,' tot.bol.flux',
+     1     5X,'reflected',8X,'limb. dark.',7X,'albedo',
+     2     10X,' X-dim.',10X,' Y-dim.',10X,' Z-dim.')
+      WRITE(6,6048) 
+     1  (J,NUMOBJC(J),FBC(J),FRIFLC(J),XLIMBC(J),ALBC(J),
+     2     DIMCX(J),DIMCY(J),DIMCZ(J),J=1,NPNTC)
+ 6048 FORMAT((1X,2I4,7(2X,G15.7)))
+      ENDIF
+C
+      IF(AMOUNT.LT.6.0) GOTO 600
+C           .....................   Fine grid description of surfaces
+      WRITE(6,6050)
+ 6050 FORMAT(///' FINE GRID SURFACE ELEMENTS DESCRIBING OBJECTS:'
+     a  /' N. object',
+     1  3X,'x',13X,'y',12X,'z',11X,'area',3X,'coarse point'
+     2  6X,'g',13X,'gx',13X,'gy',10X,'gz'/)
+      WRITE(6,6051)
+     1 (J,NUMOBJ(J),X(J),Y(J),Z(J),A(J),NUMCOARSE(J),
+     2              G(J),GX(J),GY(J),GZ(J),J=1,NPNT)
+ 6051 FORMAT((1X,I6,I2,4(1X,1PG13.6),1X,I6,4(1X,1PG13.6)))
+      WRITE(6,6052)
+ 6052 FORMAT(///3X,'N. object',3X,'temperature',3X,' tot.bol.flux',
+     1     8X,'reflected',8X,'limb. dark.',7X,'albedo',10X,'radius')
+      WRITE(6,6053) 
+     1(J,NUMOBJ(J),T(J),FB(J),FRIFL(J),XLIMB(J),ALB(J),AUS(J),J=1,NPNT)
+ 6053 FORMAT((1X,I5,I3,6(2X,1PG15.7)))
+      WRITE(6,6054)
+ 6054 FORMAT(///5X,'  ESTENSION FOR EACH SURFACE ELEMENT:'//
+     1      3X,'N. object',8X,'Fx',13X,'Fy',17X,'Fz',
+     2     13X,'Tx',16X,'Ty',15X,'Tz')
+      WRITE(6,6055) 
+     1  (J,NUMOBJ(J),FX(J),FY(J),FZ(J),TX(J),TY(J),TZ(J),J=1,NPNT)
+ 6055 FORMAT((1X,I5,I3,6(2X,1PG15.7)))
+C           ......................  
+C                 flux for each band : omissis
+C
+      IF(AMOUNT.LT.7) GOTO 600
+C           .......................... Alignement for reflection
+      IF(IFLAG(9).LE.0) GOTO 600
+      WRITE(6,6070) ITERDONE,PAR(IPPAR1(9))
+ 6070 FORMAT(///' REFLECTION PATHS:'/
+     1     40X,' iterations:',I5,5X,' albedo:',G15.7/
+     2 ' path,sour-rec.coar.point,transf.func.,inv.trans,',
+     3 ' d**2',7X,'cosgi',7X,'cosgj',2x,'last iter.source from I,J',
+     4 ' last iter. received by I,J')
+      WRITE(6,6071) (J,ISOUR(J),JRIC(J),TRANSFI(J),TRANSFJ(J),RIJ(J),
+     1COSGI(J),COSGJ(J),FSOURI(J),FSOURJ(J),FRICI(J),FRICJ(J),J=1,NALL)
+ 6071 FORMAT((1X,I5,2I6,4X,9(1X,G11.4)))
+C
+      ENDIF
+  600 CONTINUE
+C
+C               ------------------------------ PRINTING ON UNIT NT     
+      IF(NT.GT.0.AND.NT.LE.99) THEN
+      IF(AMOUNT.LT.1.0) GO TO 700
+C            ......................... general and input data
+      WRITE(NT,5800)
+      WRITE(NT,5799) (TITLE(J),J=1,NTITLE)
+      WRITE(NT,5801)
+      WRITE(NT,5802) (NAMFLAG(J),DESCFLAG(J),YESNO(IFLAG(J)),J=1,10)
+C     Printing orbital parameters
+      WRITE(NT,5813)
+      K1=IPPAR1(11)
+      K2=IPPAR2(11)
+      WRITE(NT,5804) (NAMPAR(J),DESCPAR(J),PAR(J),J=K1,K2)
+      K1=IPPAR1(12)
+      K2=IPPAR2(12)
+      WRITE(NT,5804) (NAMPAR(J),DESCPAR(J),PAR(J),J=K1,K2)
+      K1=IPPAR1(13)
+      K2=IPPAR2(13)
+      WRITE(NT,5804) (NAMPAR(J),DESCPAR(J),PAR(J),J=K1,K2)
+C     ........................Printing reflection parameters
+      IF(IFLAG(9).GT.0) THEN
+           WRITE(NT,5805)
+           K1=IPPAR1(9)
+           K2=IPPAR2(9)
+           WRITE(NT,5804) (NAMPAR(J),DESCPAR(J),PAR(J),J=K1,K2)
+      ENDIF
+C     .......................... printing colour band parameter
+      DO 31 I=4,7
+      IF(IFLAG(I).LE.0) GOTO 31
+      K1=IPPAR1(I)
+      K2=IPPAR2(I)
+      WRITE(NT,5830) I-3,(NAMPAR(J),DESCPAR(J),PAR(J),J=K1,K2)
+   31 CONTINUE
+C     .......................... printing plot input parameters
+      IF(IFLAG(21).GT.0) THEN
+        K1=IPPAR1(21)
+        K2=IPPAR2(21)
+        WRITE(NT,6017) (NAMPAR(J),DESCPAR(J),PAR(J),J=K1,K2)
+      ENDIF
+C     .......................... printing print input parameters
+      K1=IPPAR1(20)
+      K2=IPPAR2(20)
+      WRITE(NT,6015) (NAMPAR(J),DESCPAR(J),PAR(J),J=K1,K2)
+C
+C     ........................Printing stars and disk parameters
+      DO 70 I=1,3 
+      IF(NP123(I).LE.0) GOTO 70
+      K1=(I-1)*MAXPARS+1
+      K2=I*MAXPARS
+      WRITE(NT,6000) I,(NAMPAR(J),DESCPAR(J),PAR(J),J=K1,K2)
+C      WRITE(NT,6000) I,(PARS(JJ,I),JJ=1,13)
+   70  CONTINUE
+C         ....................... roche model parameters
+      IF(PARS(1,1).EQ.2..OR.PARS(1,2).EQ.2.) THEN
+        WRITE(NT,6005) AL1,AL2,AL3,OMEGAL1,OMEGAL2,OMEGAL3,
+     1                XA1,XA2,XB1,XB2,YA,YB
+      PRIMO=.TRUE.
+      DO 72 I=1,3
+      IF(PARS(1,I).NE.2..OR.PARS(9,I).LE.0.0) GOTO 72
+C     Following data is computed  only for roche model and gravity dark.
+      IF(PRIMO) THEN
+        WRITE(NT,6006)
+        PRIMO=.FALSE.
+      ENDIF
+      WRITE(NT,6007) I,RPOLE(I),XPOLE(I),YPOLE(I),ZPOLE(I),
+     2                GXPOLE(I),GYPOLE(I),GZPOLE(I),TPOLE(I)
+   72 CONTINUE
+      ENDIF    
+C           ........................... run data
+      K1=INT(PAR(IPPAR1(9)+3))
+      WRITE(NT,5803) NPNT,NPNTMX,NPNT1,NPNT2,NPNT3,
+     1              NPNTC,NPNTMXC,K1,NPNT1C,NPNT2C,NPNT3C,
+     2              NALL,MAXALLIN,ITERDONE
+C
+      WRITE(NT,6010)
+      DO 71 I=1,3
+      IF(NP123(I).LE.0) GOTO 71
+      FBOLTR=FBOL(I)+FBOLREF(I)
+      WRITE(NT,6011) I,AREA(I),FBOL(I),FBOLREF(I),FBOLTR,
+     1              PARS(11,I),FBOLTOT(I)
+   71 CONTINUE
+C
+      WRITE(NT,6012)
+      WRITE(NT,6013) (I,(COMPFRAC(IB,I),IB=1,NFILT),I=1,3)
+C
+      IF(AMOUNT.LT.2.0) GOTO 700
+C           ......................  light received for each phase
+      WRITE(NT,6020) NCELL,NCELL,DCELL,CELLMIN,CELLMAX
+       WRITE(NT,6021) 
+     1 (J,FASE(J),FASI01(J),CBOLT(J),CBOL(1,J),CBOL(2,J),CBOL(3,J),
+     2                                                    J=1,NFASI)
+C
+      IF(AMOUNT.LT.2.5) GOTO 600
+C         .......................... reflected light for each fase
+      IF(IFLAG(9).GT.0) THEN
+      WRITE(NT,6025) 
+      WRITE(NT,6021) 
+     1 (J,FASE(J),FASI01(J),CBOLTR(J),CBOLR(1,J),CBOLR(2,J),CBOLR(3,J),
+     2                                                    J=1,NFASI)
+C         .......................... light curve without reflection
+      WRITE(NT,6026) 
+      WRITE(NT,6021) 
+     1 (J,FASE(J),FASI01(J),CBOLT(J)-CBOLTR(J),
+     2  CBOL(1,J)-CBOLR(1,J),CBOL(2,J)-CBOLR(2,J),
+     3  CBOL(3,J)-CBOLR(3,J),J=1,NFASI)
+      ENDIF
+C
+      IF(AMOUNT.LT.3.0) GOTO 700
+C           ......................  Color band flux 
+      DO 75 IB=1,NBANDE
+      IF(IFLAG(3+IB).LE.0) GOTO 75
+      WRITE(NT,6030) IB
+      WRITE(NT,6031) 
+     1 (J,FASE(J),FASI01(J),CT(IB,J),C(1,IB,J),C(2,IB,J),C(3,IB,J),
+     2  O(IB,J),J=1,NFASI)
+   75 CONTINUE
+C      
+      IF(AMOUNT.LT.5.0) GOTO 700
+C           .....................   Coarse grid description of surfaces
+      IF(IFLAG(9).GT.0) THEN
+      WRITE(NT,6045)
+      WRITE(NT,6046)
+     1 (J,NUMOBJC(J),XC(J),YC(J),ZC(J),AC(J),
+     2              GC(J),GXC(J),GYC(J),GZC(J),NUMFINI(J),J=1,NPNTC)
+      WRITE(NT,6047)
+      WRITE(NT,6048) 
+     1  (J,NUMOBJC(J),FBC(J),FRIFLC(J),XLIMBC(J),ALBC(J),
+     2     DIMCX(J),DIMCY(J),DIMCZ(J),J=1,NPNTC)
+      ENDIF
+C
+      IF(AMOUNT.LT.6.0) GOTO 700
+C           .....................   Fine grid Description of surfaces
+      WRITE(NT,6050)
+      WRITE(NT,6051)
+     1 (J,NUMOBJ(J),X(J),Y(J),Z(J),A(J),NUMCOARSE(J),
+     2              G(J),GX(J),GY(J),GZ(J),J=1,NPNT)
+      WRITE(NT,6052)
+      WRITE(NT,6053) 
+     1(J,NUMOBJ(J),T(J),FB(J),FRIFL(J),XLIMB(J),ALB(J),AUS(J),J=1,NPNT)
+      WRITE(NT,6054)
+      WRITE(NT,6055) 
+     1  (J,NUMOBJ(J),FX(J),FY(J),FZ(J),TX(J),TY(J),TZ(J),J=1,NPNT)
+C           ......................  
+C                 flux for each band : omissis
+C
+      IF(AMOUNT.LT.7) GOTO 700
+C           .......................... Alignement for reflection
+      IF(IFLAG(9).LE.0) GOTO 700
+      WRITE(NT,6070) ITERDONE,PAR(IPPAR1(9))
+      WRITE(NT,6071) (J,ISOUR(J),JRIC(J),TRANSFI(J),TRANSFJ(J),RIJ(J),
+     1COSGI(J),COSGJ(J),FSOURI(J),FSOURJ(J),FRICI(J),FRICJ(J),J=1,NALL)
+C
+      ENDIF
+  700 CONTINUE
+      RETURN
+      END
+C
+       SUBROUTINE REFLECT(NITER,PKCONV,R4PREC,ALBEDO,
+     1                                       NPRINTR,NFILE,FORDER)
+C      ------------------------------------------------
+C      Computes the light reflected by the 3 objects,
+C      accounting for the geometry of stars and disk.
+C      Reflection of increasing orders is computed,
+C      until the order NITER or if the convergence 
+C      criterion specified by PKCONV is met.
+C      ALBEDO is an input parameter specifing the
+C      efficiency of the reflection process
+C
+C      R4PREC: sin,cos < R4prec are assumed 0 to shorten computations
+C      and avoid rounding error in sin,cos whithout using double precision.
+C      ------------------------------------------------
+       PARAMETER (MAXPT=200000 ,MAXALLIN=250000, MAXBANDE=5)
+       PARAMETER (MAXPTC=50000)
+C
+       COMMON /SURFC/ NPNTMXC,NPNTC,NPNT1C,NPNT2C,NPNT3C,
+     A               N1IC,N1FC,N2IC,N2FC,N3IC,N3FC,
+     1               XC(MAXPTC),YC(MAXPTC),ZC(MAXPTC),
+     2               GC(MAXPTC),GXC(MAXPTC),GYC(MAXPTC),GZC(MAXPTC),
+     5               AC(MAXPTC),
+     6               DIMCX(MAXPTC),DIMCY(MAXPTC),DIMCZ(MAXPTC),
+     6               FBC(MAXPTC),FRIFLC(MAXPTC),
+     7               XLIMBC(MAXPTC),NUMOBJC(MAXPTC),ALBC(MAXPTC),
+     8               NUMFINI(MAXPTC)
+      DIMENSION NP123C(3)
+      DIMENSION NIFC(2,3)
+      EQUIVALENCE (NP123C(1),NPNT1C),(NIFC(1,1),N1IC)
+C
+      COMMON /ALLIN/ NALLMX,NALL,ITERDONE,
+     1               ISOUR(MAXALLIN),JRIC(MAXALLIN),
+     2               TRANSFI(MAXALLIN),TRANSFJ(MAXALLIN),
+     3               FSOURI(MAXALLIN),FSOURJ(MAXALLIN),
+     4               FRICI(MAXALLIN),FRICJ(MAXALLIN),
+     5               RIJ(MAXALLIN),
+     6               RXIJ(MAXALLIN),RYIJ(MAXALLIN),RZIJ(MAXALLIN),
+     7               COSGI(MAXALLIN),COSGJ(MAXALLIN),
+     8               IAUS(MAXALLIN)
+C
+       DIMENSION FORDER(MAXPTC)
+C       pi4=1/(4*pi)
+       PARAMETER PI4=0.07957747
+C      ...........................................................
+C                Zero alignements at the beginning
+       NALL=0       
+C                Find allignements (possible reflection paths) 
+C                between objects 1 and 2 ( star A and star B)   
+C                An alignement list is built in common /allin/
+       CALL FINDALL(1,2,R4PREC)
+C                First and last alignement betwenn object 1 and 2 (A and B)
+       NALLAB1=1
+       NALLAB2=NALL
+C                Eliminates allignements between stars A and B
+C                which are intercepted by the disk (object 3, or C)
+C                Common /allin/ is updated.       
+       CALL ALLSEL(3,NALLAB1,NALLAB2)
+       NALLAB2=NALL
+C                Find allignements between objects 1 and 3 
+C                ( star A and disk ), the alignement list 
+C                in common /allin/ is updated
+       CALL FINDALL(1,3,R4PREC)
+       NALLAC1=NALLAB2+1
+       NALLAC2=NALL
+C                Eliminates allignement between A and C intercepted by B
+       CALL ALLSEL(2,NALLAC1,NALLAC2)
+       NALLAC2=NALL
+C                Find allignements between objects 2 and 3 
+C                ( star B and disk ), the alignement list 
+C                in common /allin/ is updated
+       CALL FINDALL(2,3,R4PREC)
+       NALLBC1=NALLAC2+1
+       NALLBC2=NALL
+C                Eliminates the alignements between B and C intercepted by A
+       CALL ALLSEL(1,NALLBC1,NALLBC2)
+       NALLBC2=NALL
+C                Completing the data in the alignement list.
+C                computing FSOUR, initial alignement source
+       CALL CALCALL(ALBEDO)
+C                Zero reflection source for each surface element
+       CALL NULL(NPNTC,FRIFLC)
+C                Initial value for convergency checks
+       FMAX=0.0
+       DO 40 K=1,NALL
+       FMAX=FMAX+FSOURI(K)+FSOURJ(K)
+   40  CONTINUE
+C      -------------------------  LOOP ON REFLECTION ORDERS
+       DO 50 IT=1,NITER
+C
+C                Computes the light transmitted along each allignement
+       DO 60 K=1,NALL
+       FRICJ(K)=FSOURI(K)*TRANSFI(K)
+   60  FRICI(K)=FSOURJ(K)*TRANSFJ(K)
+C         Zeroes the light falling on on each coarse surf.elem. for this order
+       DO 55 K=1,NPNTC
+   55  FORDER(K)=0.0
+C             Computes the light received by each coarse surface element
+C             At this reflection order (forder) and the total FRIFLC
+C             Summing on all path from I to J and inverse (J to I)
+       DO 70 K=1,NALL
+       FORDER(JRIC(K)) =FORDER(JRIC(K)) +FRICJ(K)
+       FORDER(ISOUR(K))=FORDER(ISOUR(K))+FRICI(K)
+       FRIFLC(JRIC(K)) =FRIFLC(JRIC(K)) +FRICJ(K)  
+   70  FRIFLC(ISOUR(K))=FRIFLC(ISOUR(K))+FRICI(K)  
+C
+C                Convergence check
+       FMAX1=0.0
+       DO 90 K=1,NALL
+       FMAX1=FMAX1+FRICI(K)+FRICJ(K)
+   90  CONTINUE
+C
+C                Prints reflection interation data
+       IF(NPRINTR.GT.0.AND.NFILE.GT.0.AND.NFILE.LE.99) THEN
+          WRITE(NFILE,8000) IT,NITER,PKCONV,FMAX,FMAX1
+ 8000     FORMAT(//' Reflection hystory: iteration: ',I3,' max iter:',
+     1      I3,' conv.check:',G12.4,' initial,this iter refl.flux:',
+     2       2G12.4/' path,I:sour.,J:rec.,',
+     3    'flux from I, transf.func.I=>J,flux to J,'
+     4    'flux from J, transf.func.J=>I,flux to I,'
+     5    'Sum I:I=>J this iter.,all iter.')
+          DO 95 K=1,NALL
+          I=ISOUR(K)
+          J=JRIC(K)
+          WRITE(NFILE,8001) K,I,J,FSOURI(K),TRANSFI(K),FRICJ(K),
+     1                            FSOURJ(K),TRANSFJ(K),FRICJ(K),
+     2                            FORDER(K),FRIFLC(K)
+ 8001  FORMAT((1X,I5,2I6,8(1X,1P,G13.6)))
+   95  CONTINUE
+       ENDIF
+C               Convergency check continues:
+       IF(FMAX.NE.0.0) THEN
+         FFMAX=FMAX1/FMAX
+       ELSE
+         FFMAX=0.0
+       ENDIF
+C
+       IF(FFMAX.GT.1.)THEN
+              WRITE(6,1000) IT
+              IF(NFILE.GT.0.AND.NFILE.LE.99) WRITE(NFILE,1000) IT
+ 1000         FORMAT(' WARNING! Iteration:',I3,' REFLECTION DIVERGING')
+       ELSE IF(FFMAX.LT.PKCONV) THEN
+              ITERDONE=IT
+              GOTO 500
+       ENDIF
+C                Recomputes sources for the next order of reflection
+       IF(IT.EQ.NITER) GOTO 50
+       DO 80 K=1,NALL
+       FSOURI(K)=FORDER(ISOUR(K))
+   80  FSOURJ(K)=FORDER(JRIC(K))
+C
+   50  CONTINUE
+       ITERDONE=NITER
+  500  RETURN
+       END
+C
+       SUBROUTINE ROCHES(PRINT6,PRINTFILE,NFILE,NTH,NTHF,NCORD,NPUNT,
+     1       NPUNTC,     XA,XB,XSHIFT,OMEGA,Q,RIS,PRECISION,
+     2       NPNTMX,X,Y,Z,G,GX,GY,GZ,FX,FY,FZ,TX,TY,TZ,AREA,A,NUMCOARSE,
+     3       SINFI,COSFI,FUNCTION)
+C      ----------------------------------------------------------------
+C      Called for a Roche lobe star, fills the surface element list
+C      with the surface elements of a roche lobe of given Omega.
+C      The main star (object A) is build in (0,0,0) the star B in
+C      (1,0,0) the star is then shifted on the x axis by XSHIFT.
+C      RIS=0. for the main star A, otherwise 1.
+C      XA is the maximum X value, XB the minimum one for this star;
+C      for star A XA is near the L1 point, while for star B XB is near L1
+C      FUNCTION is rochesf1 for main star A, rochesf2 for star B,
+C      passed to RTNEWT, to compute the Radius value for a given angle
+C      in the roche model. Q is the mass ratio; 
+C      SINFI,COSFI are working spaces.
+C
+C      This routine has been structured in the same way as Sfera2;
+C      but, due to a lack in equatorial simmetry for the Roche model,
+C      the north part and the sud part are not treated togheter.
+C      The arch lenght has been approximated by the sphere value:
+C      NCORD=1:  Theta and phi arch extension for each surface element
+C      NCORD=2:  Theta and phi cord extension of each surface element
+C      NCORD=3:  Theta and phi tangent segment of each surface element
+C      T, and F tangent vectors are obtained in an approximate way
+C      from the spherical ones; to shorten calculations
+C      ----------------------------------------------------------------
+       COMMON /ROCHE/ AL1,AL2,AL3,XA1,XA2,XB1,XB2,YA,YB,
+     1                OMEGAL1,OMEGAL2,OMEGAL3,
+     2               RPOLE(3),XPOLE(3),YPOLE(3),ZPOLE(3),TPOLE(3),
+     3               GXPOLE(3),GYPOLE(3),GZPOLE(3)
+       DIMENSION X(NPNTMX),Y(NPNTMX),Z(NPNTMX)
+       DIMENSION G(NPNTMX),GX(NPNTMX),GY(NPNTMX),GZ(NPNTMX)
+       DIMENSION FX(NPNTMX),FY(NPNTMX),FZ(NPNTMX)
+       DIMENSION TX(NPNTMX),TY(NPNTMX),TZ(NPNTMX)
+       DIMENSION A(NPNTMX)
+       DIMENSION NUMCOARSE(NPNTMX)
+       DIMENSION SINFI(NPNTMX),COSFI(NPNTMX)
+       LOGICAL PRINTFILE,PRINT6
+       EXTERNAL FUNCTION
+       DATA PI /3.1415926/
+C      DATA PI /3.141592653589793/
+C
+C         Newton-Cotes Error Counter
+       NERROR=0
+C         Delta theta fine, number of phi fines (same as sfera2):
+       DTH=PI/(NTH-1)
+       DTH5=0.5*DTH
+C      at equator: DFI=(2.*PI)/NFIEQ;DFI5=0.5*DFI then decreases as sin theta
+       NFIEQ=2*(NTH-1)
+C         Theta coarse arc interval and number of coarse theta points
+       DTHC=DTH*NTHF
+       DTHC5=DTHC*0.5
+       NTHC=(NTH+(NTHF-1))/NTHF
+       IF(NTHC*NTHF.NE.NTH+NTHF-1) THEN
+           WRITE(6,900) NTH,NTHF
+           IF(PRINTFILE) WRITE(NFILE,900) NTH,NTHF
+  900      FORMAT(/,' ERRROR! The number of theta points:',I6,
+     1      ' is not consistent with the coarsing factor:',I6)
+       ENDIF
+C       RMAX:  Approximate max radius for cord calculation(for F and T):
+C       NOW THE R VALUE FOR EACH THE THETA PHI IS USED INSTEAD OF RMAX!
+C       RMAX=MAX(ABS(XA-RIS),ABS(XB-RIS))
+       IF(NCORD.LE.1) THEN
+C         RTCORDA=DTH5*RMAX
+         RTCORDA=DTH5
+       ELSE IF(NCORD.EQ.2) THEN
+C         RTCORDA=RMAX*SIN(DTH5)
+         RTCORDA=SIN(DTH5)
+       ELSE
+C         RTCORDA=RMAX*TAN(DTH5)
+         RTCORDA=TAN(DTH5)
+       ENDIF
+C       
+       NPUNT=0
+       ICT=NPUNTC
+       LOST=0
+       TH=0.0
+C        Limits for Newton Cotes R-Search (star radius)
+       IF(RIS.EQ.0.0) THEN
+C          Main star A
+           RLIM1=PRECISION
+           RLIM2=AL1
+       ELSE
+C          Minor star B (this work if the max radius of B is in L1)
+           RLIM1=PRECISION
+           RLIM2=1.-AL1       
+       ENDIF
+C                                        ---------------
+C      ................................  North polar cap
+C                                        ---------------
+                       IF(NPUNT.EQ.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 500
+                       ELSE
+                           NPUNT=NPUNT+1
+                       ENDIF
+C        the first r value is the intersection of the lobe with x axis
+       R=XA-RIS
+       X1=XA
+       Y1=0.
+       Z1=0.
+C      normal to the surf. in x1,y1,z1
+       IF(X1.NE.AL1.AND.X1.NE.AL2) THEN
+       CALL GRADOMEGA(X1,Y1,Z1,GX(NPUNT),GY(NPUNT),GZ(NPUNT),G(NPUNT),Q)
+       ELSE
+C       Singular gradient in lagrangian point
+       X1MOD=X1-10.*PRECISION
+       CALL GRADOMEGA(X1MOD,Y1,Z1,GX(NPUNT),GY(NPUNT),GZ(NPUNT),
+     1                                                  G(NPUNT),Q)
+       GX(NPUNT)=1. 
+       GY(NPUNT)=0.
+       GZ(NPUNT)=0.
+       ENDIF
+C      cosine of angle between (x,y,z) and normal vector
+       COSB=1.
+       A(NPUNT)=(2.*PI)*(1.-COS(DTH5))*R*(R/COSB)
+       AREA=A(NPUNT)
+       X(NPUNT)=X1
+       Y(NPUNT)=Y1
+       Z(NPUNT)=Z1 
+       FY(NPUNT)=0.
+       FZ(NPUNT)=RTCORDA*(R/COSB)
+       FX(NPUNT)=0.
+       TY(NPUNT)=RTCORDA*(R/COSB)
+       TZ(NPUNT)=0.
+       TX(NPUNT)=0.
+C        the T and F component along G are subtracted, making T and F
+C        perpendicular to G
+       CALL ROSUB(FX(NPUNT),FY(NPUNT),FZ(NPUNT),TX(NPUNT),TY(NPUNT),
+     1            TZ(NPUNT),GX(NPUNT),GY(NPUNT),GZ(NPUNT),COSB)
+       NUMCOARSE(NPUNT)=ICT
+C                                 ------------------------------       
+C      ...........................coarse cap: other theta points 
+C                                 ------------------------------       
+       COSTH2=COS(DTH5)
+       NTHF2=NTHF/2+1
+       DO 5 IT=2,NTHF2
+       TH=DTH*(IT-1)
+       SINTH=SIN(TH)
+       COSTH=COS(TH)
+       COSTH1=COSTH2
+       COSTH2=COS(TH+DTH5)
+C     .... Number of phi fines for this theta coarse
+       NFI=INT(NFIEQ*SINTH)
+       IF(NFI.LT.4) NFI=4
+       DFI=2.*PI/NFI
+       DFI5=DFI*0.5
+C     .... F tangent Interval extension for this theta value
+C     really i should use R instead of RMAX and put the following into loop 5
+            IF(NCORD.LE.1) THEN
+C               RFCORDA=DFI5*RMAX
+               RFCORDA=DFI5
+            ELSE IF(NCORD.EQ.2) THEN
+C               RFCORDA=RMAX*SIN(TH+DTH5)*SIN(DFI5)
+               RFCORDA=SIN(TH+DTH5)*SIN(DFI5)
+            ELSE
+C               RFCORDA=RMAX*SIN(TH+DTH5)*TAN(DFI5)/COS(DTH5)
+               RFCORDA=SIN(TH+DTH5)*TAN(DFI5)/COS(DTH5)
+            ENDIF
+C
+       DO 5 IF=1,NFI
+                       IF(NPUNT.EQ.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 5
+                       ELSE
+                           NPUNT=NPUNT+1
+                       ENDIF
+       FI=DFI * ( IF-1-INT(NTHF/2) )  
+       COSFII=COS(FI)
+       SINFII=SIN(FI)
+       SINCOS=SINTH*COSFII
+       SINSIN=SINTH*SINFII
+C      find r for this theta,fi; preceeding R is given as a guess value
+C      limits for r search are 0 and L1 (to avoid an r in the other object)
+       R=RTNEWT(FUNCTION,RLIM1,RLIM2,PRECISION,R,Q,OMEGA,COSTH,SINSIN,
+     1          NERROR)
+       X1=R*COSTH+RIS
+       Y1=R*SINCOS
+       Z1=R*SINSIN
+       CALL GRADOMEGA(X1,Y1,Z1,GX(NPUNT),GY(NPUNT),GZ(NPUNT),G(NPUNT),Q)
+C       for star B remember that cosb is the angle G-star center
+C       COSB=((X1-RIS)*GX(NPUNT)+Y1*GY(NPUNT)+Z1*GZ(NPUNT))/R
+       COSB=(COSTH*GX(NPUNT)+SINCOS*GY(NPUNT)+SINSIN*GZ(NPUNT))
+       X(NPUNT)=X1
+       Y(NPUNT)=Y1
+       Z(NPUNT)=Z1 
+       FY(NPUNT)=-SINFII*RFCORDA*(R/COSB)
+       FZ(NPUNT)= COSFII*RFCORDA*(R/COSB)
+       FX(NPUNT)=0.
+       TY(NPUNT)= (COSTH*RTCORDA)*COSFII*(R/COSB)
+       TZ(NPUNT)= (COSTH*RTCORDA)*SINFII*(R/COSB)
+       TX(NPUNT)=-(SINTH*RTCORDA)*(R/COSB)
+       CALL ROSUB(FX(NPUNT),FY(NPUNT),FZ(NPUNT),TX(NPUNT),TY(NPUNT),
+     1            TZ(NPUNT),GX(NPUNT),GY(NPUNT),GZ(NPUNT),COSB)
+       DFIRR=DFI*R*R
+       AREATH=DFIRR*(COSTH1-COSTH2)
+       A(NPUNT)=AREATH/COSB
+       AREA=AREA+A(NPUNT)
+       NUMCOARSE(NPUNT)=ICT
+    5  CONTINUE
+C                                            ------------------
+C      ....................................  other theta points
+C                                            ------------------
+C
+C      ------------------------------ Loop on theta values
+C                                     --------------------
+       NTH1=(NTHF/2)+2
+       NTH2=NTH-(NTHF/2)-1
+       TH1=(NTH1-1)*DTH
+       COSTH2=COS(TH1-DTH5)
+C      num.of phi coarse for this theta to increment ICT for first step below
+       NFIC=1
+C
+       DO 20 IT=NTH1,NTH2
+       TH=(IT-1)*DTH
+       SINTH=SIN(TH)
+       COSTH=COS(TH)
+       COSTH1=COSTH2
+       COSTH2=COS(TH+DTH5)
+C      ................ changing the theta coarse point each nthf fine points.
+       IF(MOD(IT+NTHF/2-1,NTHF).EQ.0) THEN
+            ICT=ICT+NFIC
+C         Number of phi coarse for this nthf interval
+            THMEDIO=DTH*(IT-1+NTHF/2)
+            NFIC=INT(2.*PI*SIN(THMEDIO)/DTHC)
+            IF(NFIC.LT.4) NFIC=4
+C         Number of phi fine for this coarse theta range
+            NFI=NFIC*NTHF
+            DFI=(2.*PI)/NFI
+            DFI5=DFI*0.5
+C         Cos and sin fi values for this theta range computed once
+            DO 25 IF=1,NFI
+            FI=DFI * ( IF-1-INT(NTHF/2) )  
+            COSFI(IF)=COS(FI)
+            SINFI(IF)=SIN(FI)
+  25        CONTINUE  
+       ENDIF
+C      ................................
+C         The first coarse num.in phi loop for this th. coar.is ICT
+       ICF=ICT
+C
+C     really i should use R instead of RMAX and put the following into loop 20
+       IF(NCORD.LE.1) THEN         
+C         RFCORDA=DFI5*RMAX
+         RFCORDA=DFI5
+       ELSE
+C         max diameter of sphere between TH+DTH5 and TH-DTH5: it is
+C         +DTH5 over and -DTH5 below equator
+          IF(TH.GT.PI/2.) THEN
+            SINMAX=SIN(TH-DTH5)
+          ELSE
+            SINMAX=SIN(TH+DTH5)
+          ENDIF
+          IF(NCORD.EQ.2) THEN
+            RFCORDA=SINMAX*SIN(DFI5)
+          ELSE
+            RFCORDA=SINMAX*TAN(DFI5)/COS(DTH5)
+          ENDIF
+       ENDIF
+C      ------------------------------------ Loop on phi values
+C                                          --------------------
+       DO 20 IF=1,NFI
+                       IF(NPUNT.EQ.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 20
+                       ELSE
+                            NPUNT=NPUNT+1
+                       ENDIF
+       SINCOS=SINTH*COSFI(IF)
+       SINSIN=SINTH*SINFI(IF)
+       R=RTNEWT(FUNCTION,RLIM1,RLIM2,PRECISION,R,Q,OMEGA,COSTH,SINSIN,
+     1          NERROR)
+       X1=R*COSTH+RIS
+       Y1=R*SINCOS
+       Z1=R*SINSIN
+       CALL GRADOMEGA(X1,Y1,Z1,GX(NPUNT),GY(NPUNT),GZ(NPUNT),G(NPUNT),Q)
+       COSB=(COSTH*GX(NPUNT)+SINCOS*GY(NPUNT)+SINSIN*GZ(NPUNT))
+C       COSB=((X1-RIS)*GX(NPUNT)+Y1*GY(NPUNT)+Z1*GZ(NPUNT))/R
+       X(NPUNT)=X1
+       Y(NPUNT)=Y1
+       Z(NPUNT)=Z1 
+       FY(NPUNT)=-SINFI(IF)*RFCORDA*(R/COSB)
+       FZ(NPUNT)= COSFI(IF)*RFCORDA*(R/COSB)
+       FX(NPUNT)=0.
+       TY(NPUNT)= (COSTH*RTCORDA)*COSFI(IF)*(R/COSB)
+       TZ(NPUNT)= (COSTH*RTCORDA)*SINFI(IF)*(R/COSB)
+       TX(NPUNT)=-(SINTH*RTCORDA)*(R/COSB)
+       CALL ROSUB(FX(NPUNT),FY(NPUNT),FZ(NPUNT),TX(NPUNT),TY(NPUNT),
+     1            TZ(NPUNT),GX(NPUNT),GY(NPUNT),GZ(NPUNT),COSB)
+       DFIRR=DFI*R*R
+       AREATH=DFIRR*(COSTH1-COSTH2)
+       A(NPUNT)=AREATH/COSB
+       AREA=AREA+A(NPUNT)
+       NUMCOARSE(NPUNT)=ICF
+C      AT each NTHF phi points change the coarse phi point
+C      Including the remainder of the division IF/NTHF in the last coarse
+       IF(MOD(IF,NTHF).EQ.0) ICF=ICF+1
+C
+   20  CONTINUE
+C         
+C      Next ICT to fill:
+       ICT=ICT+NFIC
+C                                            ---------------
+C      ....................................     South pole
+C                                            ---------------
+                       IF(NPUNT.EQ.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 500
+                       ELSE
+                           NPUNT=NPUNT+1
+                       ENDIF
+       R=RIS-XB
+       X1=XB
+       Y1=0.
+       Z1=0.
+C      normal to the surf. in x1,y1,z1
+       IF(X1.NE.AL1.AND.X1.NE.AL3) THEN
+       CALL GRADOMEGA(X1,Y1,Z1,GX(NPUNT),GY(NPUNT),GZ(NPUNT),G(NPUNT),Q)
+       ELSE
+C       Singular gradient in lagrangian point
+       X1MOD=X1+10.*PRECISION
+       CALL GRADOMEGA(X1MOD,Y1,Z1,GX(NPUNT),GY(NPUNT),GZ(NPUNT),
+     1                                                  G(NPUNT),Q)
+       GX(NPUNT)=-1.
+       GY(NPUNT)=0.
+       GZ(NPUNT)=0.
+       ENDIF
+C      cosine of angle between (x,y,z) and normal vector
+       COSB=1.
+       A(NPUNT)=(2.*PI)*(1.-COS(DTH5))*R*R/COSB
+       AREA=AREA+A(NPUNT)
+       X(NPUNT)=X1
+       Y(NPUNT)=Y1
+       Z(NPUNT)=Z1 
+       FY(NPUNT)=0.
+       FZ(NPUNT)=-RTCORDA*(R/COSB)
+       FX(NPUNT)=0.
+       TY(NPUNT)=RTCORDA*(R/COSB)
+       TZ(NPUNT)=0.
+       TX(NPUNT)=0.
+C        the T and F component along G are subtracted, making T and F
+C        perpendicular to G
+       CALL ROSUB(FX(NPUNT),FY(NPUNT),FZ(NPUNT),TX(NPUNT),TY(NPUNT),
+     1            TZ(NPUNT),GX(NPUNT),GY(NPUNT),GZ(NPUNT),COSB)
+       NUMCOARSE(NPUNT)=ICT
+C                                 ----------------------------------       
+C      ...........................sud coarse cap: other theta points 
+C                                 ----------------------------------       
+       NTH1=NTH2+1
+       NTH2=NTH-1
+       TH1=(NTH1-1.)*DTH
+       COSTH2=COS(TH1-DTH5)
+       DO 45 IT=NTH1,NTH2 
+       TH=DTH*(IT-1)
+       SINTH=SIN(TH)
+       COSTH=COS(TH)
+       COSTH1=COSTH2
+       COSTH2=COS(TH+DTH5)
+C     .... Number of phi fines for this theta coarse
+       NFI=INT(NFIEQ*SINTH)
+       IF(NFI.LT.4) NFI=4
+       DFI=2.*PI/NFI
+       DFI5=DFI*0.5
+C     .... F tangent Interval extension for this theta value
+C     really i should use R instead of RMAX and put the following into loop 45
+            IF(NCORD.LE.1) THEN
+C               RFCORDA=DFI5*R
+               RFCORDA=DFI5
+            ELSE IF(NCORD.EQ.2) THEN
+C               RFCORDA=R*SIN(TH-DTH5)*SIN(DFI5)
+               RFCORDA=SIN(TH-DTH5)*SIN(DFI5)
+            ELSE
+C               RFCORDA=R*SIN(TH-DTH5)*TAN(DFI5)/COS(DTH5)
+               RFCORDA=SIN(TH-DTH5)*TAN(DFI5)/COS(DTH5)
+            ENDIF
+C
+       DO 45 IF=1,NFI
+                       IF(NPUNT.EQ.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 5
+                       ELSE
+                           NPUNT=NPUNT+1
+                       ENDIF
+       FI=DFI * ( IF-1-INT(NTHF/2) )  
+       COSFII=COS(FI)
+       SINFII=SIN(FI)
+       SINCOS=SINTH*COSFII
+       SINSIN=SINTH*SINFII
+C      find r for this theta,fi; preceeding R is given as a guess value
+C      limits for r search are 0 and L1 (to avoid an r in the other object)
+       R=RTNEWT(FUNCTION,RLIM1,RLIM2,PRECISION,R,Q,OMEGA,COSTH,SINSIN,
+     1          NERROR)
+       X1=R*COSTH+RIS
+       Y1=R*SINCOS
+       Z1=R*SINSIN
+       CALL GRADOMEGA(X1,Y1,Z1,GX(NPUNT),GY(NPUNT),GZ(NPUNT),G(NPUNT),Q)
+       COSB=(COSTH*GX(NPUNT)+SINCOS*GY(NPUNT)+SINSIN*GZ(NPUNT))
+C       COSB=((X1-RIS)*GX(NPUNT)+Y1*GY(NPUNT)+Z1*GZ(NPUNT))/R
+       X(NPUNT)=X1
+       Y(NPUNT)=Y1
+       Z(NPUNT)=Z1 
+       FY(NPUNT)=-SINFII*RFCORDA*(R/COSB)
+       FZ(NPUNT)= COSFII*RFCORDA*(R/COSB)
+       FX(NPUNT)=0.
+       TY(NPUNT)= (COSTH*RTCORDA)*COSFII*(R/COSB)
+       TZ(NPUNT)= (COSTH*RTCORDA)*SINFII*(R/COSB)
+       TX(NPUNT)=-(SINTH*RTCORDA)*(R/COSB)
+       CALL ROSUB(FX(NPUNT),FY(NPUNT),FZ(NPUNT),TX(NPUNT),TY(NPUNT),
+     1            TZ(NPUNT),GX(NPUNT),GY(NPUNT),GZ(NPUNT),COSB)
+       DFIRR=DFI*R*R
+       AREATH=DFIRR*(COSTH1-COSTH2)
+       A(NPUNT)=AREATH/COSB
+       AREA=AREA+A(NPUNT) 
+       NUMCOARSE(NPUNT)=ICT
+   45  CONTINUE
+C
+       NPUNTC=ICT+1
+C
+C      Shifts star , if requested
+       IF(XSHIFT.NE.0.0) THEN
+         DO 50 J=1,NPUNT
+   50    X(J)=X(J)+XSHIFT
+       ENDIF
+C
+ 500   IF(LOST.GT.0) THEN
+         WRITE(6,1000) NPUNT,LOST
+         IF(PRINTFILE) WRITE(NFILE,1000) NPUNT,LOST
+ 1000    FORMAT(' ERROR! OBJECT NOT PROPERLY DRAWN! '/
+     1    ' space available for only:',I6,' surface points.',
+     2    ' lost points:',I6/
+     3    ' REDUCE THE NTHETA PARAMETER OR GO INTO THE FORTRAN LIST TO',
+     4    ' INCREASE MAXPT')
+       ENDIF
+C
+       IF(NERROR.GT.0) THEN
+         WRITE(6,1100) NERROR
+         IF(PRINTFILE) WRITE(NFILE,1100) NERROR
+ 1100    FORMAT(/' ERROR : In roche lobe drawing: r not found for',
+     1          I5,' surf.elements'/) 
+       ENDIF
+       RETURN
+       END              
+C
+       SUBROUTINE ROCHESF1(R,F,DF,Q,OMEGA,A,B)
+C      ---------------------------------------------------------------
+C      Used by Roches : lobe function and derivative for main object A
+C      ---------------------------------------------------------------
+       DUM=1.+R*R-2.*R*A
+       SQR3=DUM**(-3./2.)
+       SQR=1./SQRT(DUM)
+C      F=1./R-OMEGA+Q*SQR+0.5*(1.+Q)*R*R*(1.-B*B)-A*Q*R+0.5*Q*Q/(1.+Q)old def.
+C       F=1./R-OMEGA+Q*SQR+0.5*(1.+Q)*R*R*(1.-B*B)-A*Q*R
+       F=1./R -OMEGA+  0.5*(1.+Q)*(R*R)*(1.-B*B)+  Q*(SQR-A*R)
+       DF=(1.+Q)*R*(1.-B*B)  -1./(R*R)  -Q*( (R-A)*SQR3 + A)
+       RETURN
+       END
+C
+       SUBROUTINE ROCHESF2(R,F,DF,Q,OMEGA,A,B)
+C      ---------------------------------------------------------------
+C      Used by Roches : lobe function and derivative for minor object B
+C      ---------------------------------------------------------------
+       DUM=1.+R*R+2.*R*A 
+       SQR3=DUM**(-3./2.)
+       SQR=1./SQRT(DUM)
+C       F=SQR-OMEGA+Q/R+R*A+0.5*(1.+Q)* R*R*(A*A+G*G) +0.5/(1.+Q) old omega def.
+       F=SQR-OMEGA+Q/R+R*A+0.5*(1.+Q)* (R*R)*(1.-B*B) +0.5*(1.-Q) 
+       DF=A+(1.+Q)*R*(1.-B*B)-Q/(R*R)-(R+A)*SQR3
+       RETURN
+       END
+C
+       SUBROUTINE ROSUB(AX,AY,AZ,BX,BY,BZ,GX,GY,GZ,COSB)
+C      ---------------------------------------------------------
+C      Used by Roches: makes A and B vectors normal to G,
+C      by subtracting their G component, then multiplies by 1/cosb
+C      ---------------------------------------------------------
+       COSB1=1./COSB
+       A1=AX*GX+AY*GY+AZ*GZ
+       AX=(AX-GX*A1)*COSB1
+       AY=(AY-GY*A1)*COSB1
+       AZ=(AZ-GZ*A1)*COSB1
+       A1=BX*GX+BY*GY+BZ*GZ
+       BX=(BX-GX*A1)*COSB1
+       BY=(BY-GY*A1)*COSB1
+       BZ=(BZ-GZ*A1)*COSB1
+       RETURN
+       END
+C     
+      FUNCTION RTNEWT(FUNCD,X1,X2,XACC,XGUESS,Q,OMEGA,A,B,NERROR)
+C     -----------------------------------------------------------
+C     Newton-Cotes function's zeroes finder; modified from
+C     "Numerical Recipes" By Press,Teukolwsky,Flannery,Vetterling
+C     Cambridge University Press 1986
+C     -----------------------------------------------------------
+      PARAMETER (JMAX=20)
+C      RTNEWT=.5*(X1+X2)
+      RTNEWT=XGUESS
+      DO 11 J=1,JMAX
+        CALL FUNCD(RTNEWT,F,DF,Q,OMEGA,A,B)
+        DX=F/DF
+        RTNEWT=RTNEWT-DX
+        IF((X1-RTNEWT)*(RTNEWT-X2).LT.0.) THEN 
+           NERROR=NERROR+1
+           IF(NERROR.LE.10) THEN
+             WRITE(6,1000)
+ 1000        FORMAT(' ERROR ! : Subr. RTNEWT : zero out of bounds!')
+             IF(NERROR.EQ.10) WRITE(6,1100)
+ 1100        FORMAT(' 10 ERRORS !!, ERROR WARNING SUPPRESSED !')
+           ENDIF
+        ENDIF
+        IF(ABS(DX).LT.XACC) RETURN
+ 11   CONTINUE
+           NERROR=NERROR+1
+           IF(NERROR.LE.10) THEN
+             WRITE(6,2000)
+ 2000        FORMAT(' WARNING ! : Subr. RTNEWT : not converging!')
+             IF(NERROR.EQ.10) WRITE(6,1100)
+           ENDIF
+      RETURN
+      END
+C
+      FUNCTION RTSAFE(FUNCD,X1,X2,XACC,Q,DUM,NERROR)
+C     ----------------------------------------------------
+C     Zeroes for a function FUNCD, from "Numerical Recipes",
+C     By Press, Teukolwsky, Flannery, with minor changes
+C     ----------------------------------------------------
+      PARAMETER (MAXIT=100)
+      CALL FUNCD(X1,FL,DF,Q,DUM)
+C         test if root exactly on bound  
+      IF(ABS(FL).LT.XACC) THEN
+           RTSAFE=X1
+           RETURN
+      ENDIF
+      CALL FUNCD(X2,FH,DF,Q,DUM)
+      IF(ABS(FH).LT.XACC) THEN
+           RTSAFE=X2
+           RETURN
+      ENDIF
+      IF(FL*FH.GE.0.) THEN
+           NERROR=NERROR+1
+           IF(NERROR.LE.10) THEN
+             WRITE(6,1000)
+ 1000        FORMAT(' ERROR IN RTSAFE! :root must be bracketed')
+             IF(NERROR.EQ.10) WRITE(6,1100)
+ 1100        FORMAT(' 10 ERRORS !!, ERROR WARNING SUPPRESSED !')
+           ENDIF
+C           RTSAFE=0.0
+C           RETURN
+      ENDIF
+      IF(FL.LT.0.)THEN
+        XL=X1
+        XH=X2
+      ELSE
+        XH=X1
+        XL=X2
+        SWAP=FL
+        FL=FH
+        FH=SWAP
+      ENDIF
+      RTSAFE=.5*(X1+X2)
+      DXOLD=ABS(X2-X1)
+      DX=DXOLD
+      CALL FUNCD(RTSAFE,F,DF,Q,DUM)
+      DO 11 J=1,MAXIT
+        IF(((RTSAFE-XH)*DF-F)*((RTSAFE-XL)*DF-F).GE.0.
+     *      .OR. ABS(2.*F).GT.ABS(DXOLD*DF) ) THEN
+          DXOLD=DX
+          DX=0.5*(XH-XL)
+          RTSAFE=XL+DX
+          IF(XL.EQ.RTSAFE)RETURN
+        ELSE
+          DXOLD=DX
+          DX=F/DF
+          TEMP=RTSAFE
+          RTSAFE=RTSAFE-DX
+          IF(TEMP.EQ.RTSAFE)RETURN
+        ENDIF
+        IF(ABS(DX).LT.XACC) RETURN
+        CALL FUNCD(RTSAFE,F,DF,Q,DUM)
+        IF(F.LT.0.) THEN
+          XL=RTSAFE
+          FL=F
+        ELSE
+          XH=RTSAFE
+          FH=F
+        ENDIF
+ 11   CONTINUE
+      NERROR=NERROR+1
+      IF(NERROR.LE.10) THEN
+         WRITE (6,2000)
+ 2000    FORMAT(' ERROR IN RTSAFE !',
+     1     ' : Root not found:exceeding maximum iterations')
+         IF(NERROR.EQ.10) WRITE(6,1100)
+      ENDIF
+      RETURN
+      END
+C
+       SUBROUTINE SFERA2(PRINT6,PRINTFILE,NFILE,
+     1       NTH,NTHF,NCORD,NPUNT,NPUNTC,R,X0,Y0,Z0,
+     2       NPNTMX,X,Y,Z,G,GX,GY,GZ,FX,FY,FZ,TX,TY,TZ,AREA,A,NUMCOARSE,
+     3       SINFI,COSFI)
+C      ----------------------------------------------------------------
+C      Called for a spherical star, fills the surface element list
+C      with the surface elements of a sphere of radiur R and center
+C      in X0,Y0,Z0.   NTH is the number of theta points used to represent
+C      the sphere; NFI, the number of phi points, is 2(NTH-1), at equator,
+C      approx.: (NTH-1)*SIN(THETA) otherwise, to have equi-area surfaces.
+C        Points over and below equator are treated toghether to take
+C        advantage of simmetry and shorten computation.
+C
+C               COARSE MAP USED FOR REFLECTION COMPUTATION:
+C      A coarse map NUMCOARSE is built, containing, for each fine surf.el.
+C      the number of its coarse surf. element.
+C        To build the coarse map the fine theta points are divided
+C        into groups of NTHF points:
+C          Each group of NTHF theta values defines a region on the sphere:
+C        wide NTHF in theta and 0-2*PI in phi. This region is divided into
+C        a number of "PHI" coarse intervals, in such a way to have approx,
+C        the same area for coarse surf. elem. of different theta values.
+C          The phi values of each theta in this region are divided into
+C        this number of coarse intervals.
+C           For each theta, in the group of theta values, the coarse phi 
+C        interval are divided into NTHF fine "PHI" interval, in this way the 
+C        fine grid surf. element are only approx. equiarea, and each
+C        coarse surf. elem. consists of NTHF*NTHF fine elem.
+C        
+C        ICT is the number of the coarse el. for each fine, it is
+C        odd over and even below equator.
+C
+C        NFIC is the number of phi coarse for a range of theta
+C
+C        NFIF is the number of phi fine points for each coarse, it
+C        depends on theta coarse; diffenert theta coarse have a diffenent 
+C        number of phi.
+C
+C      ----------------------------------------------------------------
+       DIMENSION X(NPNTMX),Y(NPNTMX),Z(NPNTMX)
+       DIMENSION G(NPNTMX),GX(NPNTMX),GY(NPNTMX),GZ(NPNTMX)
+       DIMENSION FX(NPNTMX),FY(NPNTMX),FZ(NPNTMX)
+       DIMENSION TX(NPNTMX),TY(NPNTMX),TZ(NPNTMX)
+       DIMENSION A(NPNTMX)
+       DIMENSION NUMCOARSE(NPNTMX)
+       DIMENSION SINFI(NPNTMX),COSFI(NPNTMX)
+       LOGICAL PRINTFILE,PRINT6
+       DATA PI /3.1415926/
+C      DATA PI /3.141592653589793/
+C      REAL*8 PI,DFI,DTH,FI,TH
+C
+C      Delta theta fine: theta has bot end included (fi doesn't)
+       DTH=PI/(NTH-1)
+       DTH5=0.5*DTH
+C      Delta phi for equator ( nfi is chosen to have dfi=dth )
+C             DFI=(2.*PI)/NFIEQ  , DFI5=0.5*DFI
+       NFIEQ=2*(NTH-1)
+C
+C      ............... Polar and equatorial interval extension
+C      NCORD=1:  Theta and phi arch extension for each surface element
+C      NCORD=2:  Theta and phi cord extension of each surface element
+C      NCORD=3:  Theta and phi tangent segment of each surface element
+       IF(NCORD.LE.1) THEN
+         RTCORDA=DTH5*R
+       ELSE IF(NCORD.EQ.2) THEN
+         RTCORDA=R*SIN(DTH5)
+       ELSE
+         RTCORDA=R*TAN(DTH5)
+       ENDIF
+C       
+C        Theta coarse arc interval
+       DTHC=DTH*NTHF
+       DTHC5=DTHC*0.5
+C        Number of coarse theta points
+       NTHC=(NTH+(NTHF-1))/NTHF
+       IF(NTHC*NTHF.NE.NTH+NTHF-1) THEN
+           WRITE(6,900) NTH,NTHF
+           IF(PRINTFILE) WRITE(NFILE,900) NTH,NTHF
+  900      FORMAT(/,' ERRROR! The number of theta points:',I6,
+     1      ' is not consistent with the coarsing factor:',I6)
+       ENDIF
+C        In previous versions NFIF was recomputed at each FI
+C        ( Each theta had a different number of phi (fine equiarea)
+       NFIF=NTHF
+C
+       NPUNT=0
+       LOST=0
+       TH=0.0
+C        first coarse point number
+       ICT=NPUNTC
+C                                        ---------------
+C      ................................  North polar cap
+C                                        ---------------
+       IF(NPUNT.EQ.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 500
+                       ELSE
+                       NPUNT=NPUNT+1
+                       ENDIF
+       X(NPUNT)=0.0
+       Y(NPUNT)=0.0
+       Z(NPUNT)=R
+       GX(NPUNT)=0.0
+       GY(NPUNT)=0.0
+       GZ(NPUNT)=1.0
+       FX(NPUNT)=0.
+       FY(NPUNT)=RTCORDA
+       FZ(NPUNT)=0.
+       TX(NPUNT)=RTCORDA
+       TY(NPUNT)=0.
+       TZ(NPUNT)=0.
+       A(NPUNT)=(2.*PI)*(1.- COS(DTH5))*R*R
+       NUMCOARSE(NPUNT)=ICT
+C           Total area computation
+       AREA=A(NPUNT)
+C                                            ---------------
+C      ....................................  South polar cap
+C                                            ---------------
+       IF(NPUNT.EQ.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 500
+                       ELSE
+                       NPUNT=NPUNT+1
+                       ENDIF
+       X(NPUNT)=0.0
+       Y(NPUNT)=0.0
+       Z(NPUNT)=-R
+       GX(NPUNT)=0.0
+       GY(NPUNT)=0.0
+       GZ(NPUNT)=-1.0
+       FX(NPUNT)=0.
+       FY(NPUNT)=-RTCORDA
+       FZ(NPUNT)=0.
+       TX(NPUNT)=RTCORDA
+       TY(NPUNT)=0.
+       TZ(NPUNT)=0.
+       A(NPUNT)=A(NPUNT-1)
+       AREA=AREA+A(NPUNT)
+       NUMCOARSE(NPUNT)=ICT+1
+C
+C                                 ------------------------------       
+C      ...........................coarse cap: other theta points 
+C                                 ------------------------------       
+       COSTH2=COS(DTH5)
+       NTHF2=NTHF/2+1
+       DO 5 IT=2,NTHF2
+       TH=DTH*(IT-1)
+       SINTH=SIN(TH)
+       COSTH=COS(TH)
+       COSTH1=COSTH2
+       COSTH2=COS(TH+DTH5)
+C     .... Number of phi fines
+C       NFI=NINT(NFIEQ*SINTH)
+       NFI=INT(NFIEQ*SINTH)
+       IF(NFI.LT.4) NFI=4
+       DFI=2.*PI/NFI
+       DFI5=DFI*0.5
+       DFIRR=DFI*R*R
+       AREATH=DFIRR*(COSTH1-COSTH2)
+C     .... Interval extension for this theta value
+       IF(NCORD.LE.1) THEN
+          RFCORDA=DFI5*R
+C         RTCORDA=DTH5*R          ! not changing
+       ELSE IF(NCORD.EQ.2) THEN
+          RFCORDA=R*SIN(TH+DTH5)*SIN(DFI5)
+C         RTCORDA=R*SIN(DTH5) ! not changing
+       ELSE
+          RFCORDA=R*SIN(TH+DTH5)*TAN(DFI5)/COS(DTH5)
+C         RTCORDA=R*TAN(DTH5) ! not changing
+       ENDIF
+C
+       DO 5 IF=1,NFI
+C       FI=(IF-1)*DFI
+C          For testing purpose i shift phi: ==========================
+C       To make phi points consistent with a run: fine=coarse=this nthc
+       FI=DFI * ( IF-1-INT(NFIF/2) )  
+       COSFII=COS(FI)
+       SINFII=SIN(FI)
+C
+       IF(NPUNT.EQ.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 5
+                       ELSE
+                       NPUNT=NPUNT+1
+                       ENDIF
+       GX(NPUNT)=SINTH*COSFII
+       GY(NPUNT)=SINTH*SINFII
+       GZ(NPUNT)=COSTH
+       X(NPUNT)=R*GX(NPUNT)
+       Y(NPUNT)=R*GY(NPUNT)
+       Z(NPUNT)=R*GZ(NPUNT)
+       FX(NPUNT)=-SINFII*RFCORDA
+       FY(NPUNT)= COSFII*RFCORDA
+       FZ(NPUNT)=0.
+       TX(NPUNT)= (COSTH*RTCORDA)*COSFII
+       TY(NPUNT)= (COSTH*RTCORDA)*SINFII
+       TZ(NPUNT)=-(SINTH*RTCORDA)
+       A(NPUNT)=AREATH 
+       AREA=AREA+AREATH
+       NUMCOARSE(NPUNT)=ICT
+C      ........       Simmetric point with theta=pi-theta
+C                     ( cos(theta) -> - cos(theta) , z -> -z)
+       IF(NPUNT.EQ.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 5
+                       ELSE
+                       NPUNT=NPUNT+1
+                       ENDIF
+       X(NPUNT)= X(NPUNT-1)
+       Y(NPUNT)= Y(NPUNT-1)
+       Z(NPUNT)=-Z(NPUNT-1)
+       GX(NPUNT)= GX(NPUNT-1)
+       GY(NPUNT)= GY(NPUNT-1)
+       GZ(NPUNT)=-GZ(NPUNT-1)
+       FX(NPUNT)=-SINFII*RFCORDA
+       FY(NPUNT)= COSFII*RFCORDA
+       FZ(NPUNT)=0.
+       TX(NPUNT)=-(COSTH*RTCORDA)*COSFII
+       TY(NPUNT)=-(COSTH*RTCORDA)*SINFII
+       TZ(NPUNT)=-SINTH*RTCORDA
+       A(NPUNT)=AREATH
+       AREA=AREA+AREATH
+       NUMCOARSE(NPUNT)=ICT+1
+    5  CONTINUE
+C
+C                                            ------------------
+C      ....................................  other theta points
+C                                            ------------------
+C
+C      ------------------------------ Loop on theta values
+C                                     --------------------
+       NTH1=NTHF/2+2
+       NTH2=NTH/2-NTHF/2
+       TH1=(NTH1-1)*DTH
+       NFIC=1
+       COSTH2=COS(TH1-DTH5)
+C
+       DO 20 IT=NTH1,NTH2
+       TH=(IT-1)*DTH
+       SINTH=SIN(TH)
+       COSTH=COS(TH)
+       COSTH1=COSTH2
+       COSTH2=COS(TH+DTH5)
+C
+C      ................................
+C      ................ CHANGING THE THETA COARSE POINT EACH NTHF FINE POINTS.
+C              The first time change when it=nth1, then at each nthf values
+C              When NTHF=1 defines all data at each pass. (each IT value)
+C
+       IF(MOD(IT+NTHF/2-1,NTHF).EQ.0) THEN
+C
+C          First coarse for next theta group of nthf theta fine points
+C          ( by using the preceeding value for ICT)
+         ICT=ICT+NFIC*2
+C
+C          Number of phi coarse for this nthf interval
+C           THLAST=DTH*(IT-1+NTHF)
+C           NFIC=NINT(2.*PI*SIN(THLAST)/DTHC)
+            THMEDIO=DTH*(IT-1+NTHF/2)
+C            NFIC=NINT(2.*PI*SIN(THMEDIO)/DTHC)
+            NFIC=INT(2.*PI*SIN(THMEDIO)/DTHC)
+           IF(NFIC.LT.4) NFIC=4
+C
+C          Number of phi fine for this coarse theta range
+         NFI=NFIC*NTHF
+         DFI=(2.*PI)/NFI
+         DFI5=DFI*0.5
+         DFIRR=DFI*R*R
+         IF(NCORD.LE.1) THEN           
+           RDFI5=R*DFI5
+         ELSE IF(NCORD.EQ.2) THEN
+           RSINDFI5=R*SIN(DFI5)
+         ELSE
+           RTANDFI5=R*TAN(DFI5)
+         ENDIF
+C          Cos and sin fi values for this theta range
+         DO 25 IF=1,NFI
+C         FI=DFI*(IF-1)
+C          For testing purpose:   ==========================
+C         To make phi points consistent with a run: fine=coarse=this nthc
+         FI=DFI * ( IF-1-INT(NFIF/2) )  
+         COSFI(IF)=COS(FI)
+         SINFI(IF)=SIN(FI)
+  25     CONTINUE  
+       ENDIF
+C      ................................
+C
+C         Set first coarse for the phi loop
+       ICF=ICT
+C         Area for the following surface elements
+       AREATH=DFIRR*(COSTH1-COSTH2)
+C      ............... interval extension for this theta value
+       IF(NCORD.LE.1) THEN          
+         RFCORDA=RDFI5
+       ELSE IF(NCORD.EQ.2) THEN
+         RFCORDA=SIN(TH+DTH5)*RSINDFI5
+C        RFCORDA=RSINDFI5
+       ELSE
+         RFCORDA=SIN(TH+DTH5)*RTANDFI5/COS(DTH5)
+C        RFCORDA=RTANDFI5
+       ENDIF
+C
+C      ------------------------------------ Loop on phi values
+C                                          --------------------
+C
+       DO 20 IF=1,NFI
+C
+       IF(NPUNT.EQ.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 20
+                       ELSE
+                       NPUNT=NPUNT+1
+                       ENDIF
+       GX(NPUNT)=SINTH*COSFI(IF)
+       GY(NPUNT)=SINTH*SINFI(IF)
+       GZ(NPUNT)=COSTH
+       X(NPUNT)=R*GX(NPUNT)
+       Y(NPUNT)=R*GY(NPUNT)
+       Z(NPUNT)=R*GZ(NPUNT)
+       FX(NPUNT)=-SINFI(IF)*RFCORDA
+       FY(NPUNT)= COSFI(IF)*RFCORDA
+       FZ(NPUNT)=0.
+       TX(NPUNT)= (COSTH*RTCORDA)*COSFI(IF)
+       TY(NPUNT)= (COSTH*RTCORDA)*SINFI(IF)
+       TZ(NPUNT)=-(SINTH*RTCORDA)
+       A(NPUNT)=AREATH 
+       AREA=AREA+AREATH
+       NUMCOARSE(NPUNT)=ICF
+C      ........       Simmetric point with theta=pi-theta
+C                     ( cos(theta) -> - cos(theta) , z -> -z)
+       IF(NPUNT.EQ.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 20
+                       ELSE
+                       NPUNT=NPUNT+1
+                       ENDIF
+       X(NPUNT)= X(NPUNT-1)
+       Y(NPUNT)= Y(NPUNT-1)
+       Z(NPUNT)=-Z(NPUNT-1)
+       GX(NPUNT)= GX(NPUNT-1)
+       GY(NPUNT)= GY(NPUNT-1)
+       GZ(NPUNT)=-GZ(NPUNT-1)
+       FX(NPUNT)=-SINFI(IF)*RFCORDA
+       FY(NPUNT)= COSFI(IF)*RFCORDA
+       FZ(NPUNT)=0.
+       TX(NPUNT)=-(COSTH*RTCORDA)*COSFI(IF)
+       TY(NPUNT)=-(COSTH*RTCORDA)*SINFI(IF)
+       TZ(NPUNT)=-SINTH*RTCORDA
+       A(NPUNT)=AREATH
+       AREA=AREA+AREATH
+       NUMCOARSE(NPUNT)=ICF+1
+C
+C      AT each NFIF phi points change the coarse phi point
+C      Including the remainder of the division IF/NFIF in the last coarse
+       IF(MOD(IF,NFIF).EQ.0) ICF=ICF+2
+C                 
+   20  CONTINUE
+C
+C                                       ----------------
+C      ................................. Coarse equator
+C                                       ----------------
+       ICT=ICT+NFIC*2
+       NTH1=NTH/2-NTHF/2+1
+       NTH2=NTH/2
+       TH1=DTH*(NTH1-1)
+       COSTH2=COS(TH1-DTH5)
+C        Number of phi coarse for equator fine and coarse=NFIEQ 
+       NFIC=NINT(2.*PI/DTHC)
+C       NFIC=INT(2.*PI/DTHC)
+       IF(NFIC.LT.4) NFIC=4
+       NFI=NFIC*NFIF
+       IF(NFI.NE.NFIEQ) THEN
+         WRITE(6,2000) NFI,NFIEQ
+         IF(PRINTFILE) WRITE(NFILE,2000) NFI,NFIEQ
+ 2000    FORMAT(' ERROR IN SFERA2! NFI,NFIEQ INCONSISTENT!:',I5,1X,I5)
+       ENDIF
+       DFI=(2.*PI)/NFI
+       DFI5=DFI*0.5
+       DFIRR=DFI*R*R
+       DO 27 IF=1,NFI
+C       FI=DFI*(IF-1)
+C          For testing purpose: =========================
+C       To make phi points consistent with a run: fine=coarse=this nthc
+       FI=DFI * ( IF-1-INT(NFIF/2) )  
+       COSFI(IF)=COS(FI)
+       SINFI(IF)=SIN(FI)
+   27  CONTINUE
+C
+       DO 29 IT=NTH1,NTH2
+       TH=(IT-1)*DTH
+       SINTH=SIN(TH)
+       COSTH=COS(TH)
+       COSTH1=COSTH2
+       COSTH2=COS(TH+DTH5)
+C      ... Interval extension for this theta value #### QUALCOSA ESTRAIBILE
+       IF(NCORD.LE.1) THEN                   !          DAL LOOP
+         RFCORDA=DFI5*R
+       ELSE IF(NCORD.EQ.2) THEN
+         RFCORDA=R*SIN(TH+DTH5)*SIN(DFI5)
+C        RFCORDA=R*SIN(DFI5)
+       ELSE
+         RFCORDA=R*SIN(TH+DTH5)*TAN(DFI5)/COS(DTH5)
+C        RFCORDA=R*TAN(DFI5)
+       ENDIF
+C
+       ICF=ICT
+       AREATH=DFIRR*(COSTH1-COSTH2)
+C      ........................   Fi loop
+       DO 29 IF=1,NFI     
+       IF(NPUNT.EQ.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 29
+                       ELSE
+                       NPUNT=NPUNT+1
+                       ENDIF
+       GX(NPUNT)=SINTH*COSFI(IF)
+       GY(NPUNT)=SINTH*SINFI(IF)
+       GZ(NPUNT)=COSTH
+       X(NPUNT)=R*GX(NPUNT)
+       Y(NPUNT)=R*GY(NPUNT)
+       Z(NPUNT)=R*GZ(NPUNT)
+       FX(NPUNT)=-SINFI(IF)*RFCORDA
+       FY(NPUNT)= COSFI(IF)*RFCORDA
+       FZ(NPUNT)=0.
+       TX(NPUNT)= (COSTH*RTCORDA)*COSFI(IF)
+       TY(NPUNT)= (COSTH*RTCORDA)*SINFI(IF)
+       TZ(NPUNT)=-(SINTH*RTCORDA)
+       A(NPUNT)=AREATH 
+       AREA=AREA+AREATH
+       NUMCOARSE(NPUNT)=ICF
+C      ........       Simmetric point with theta=pi-theta
+C                     ( cos(theta) -> - cos(theta) , z -> -z)
+       IF(NPUNT.EQ.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 29
+                       ELSE
+                       NPUNT=NPUNT+1
+                       ENDIF
+       X(NPUNT)= X(NPUNT-1)
+       Y(NPUNT)= Y(NPUNT-1)
+       Z(NPUNT)=-Z(NPUNT-1)
+       GX(NPUNT)= GX(NPUNT-1)
+       GY(NPUNT)= GY(NPUNT-1)
+       GZ(NPUNT)=-GZ(NPUNT-1)
+       FX(NPUNT)=-SINFI(IF)*RFCORDA
+       FY(NPUNT)= COSFI(IF)*RFCORDA
+       FZ(NPUNT)=0.
+       TX(NPUNT)=-(COSTH*RTCORDA)*COSFI(IF)
+       TY(NPUNT)=-(COSTH*RTCORDA)*SINFI(IF)
+       TZ(NPUNT)=-SINTH*RTCORDA
+       A(NPUNT)=AREATH
+       AREA=AREA+AREATH
+       NUMCOARSE(NPUNT)=ICF
+C      ..... At each NFIF phi points change the coarse phi point
+       IF(MOD(IF,NFIF).EQ.0) ICF=ICF+1
+  29   CONTINUE
+C                                                ------------
+C      .........................................    Equator
+C                                                ------------
+       SINTH=1.0
+       COSTH=0.0
+       COSTH1=COS(0.5*PI-DTH5)
+       COSTH2=COS(0.5*PI+DTH5)
+C      Cord lenght from last theta value
+       ICF=ICT
+C  
+       DO 30 IF=1,NFI
+C
+       IF(NPUNT.EQ.NPNTMX) THEN
+                           LOST=LOST+1
+                           GOTO 30
+                       ELSE
+                       NPUNT=NPUNT+1
+                       ENDIF
+       GX(NPUNT)=SINTH*COSFI(IF)
+       GY(NPUNT)=SINTH*SINFI(IF)
+       GZ(NPUNT)=COSTH
+       X(NPUNT)=R*GX(NPUNT)
+       Y(NPUNT)=R*GY(NPUNT)
+       Z(NPUNT)=R*GZ(NPUNT)
+       FX(NPUNT)=-SINFI(IF)*RFCORDA
+       FY(NPUNT)= COSFI(IF)*RFCORDA
+       FZ(NPUNT)=0.
+       TX(NPUNT)=COSTH*COSFI(IF)*RTCORDA
+       TY(NPUNT)=COSTH*SINFI(IF)*RTCORDA
+       TZ(NPUNT)=-SINTH*RTCORDA
+       A(NPUNT)=DFI*(COSTH1-COSTH2)*(R*R)
+       AREA=AREA+A(NPUNT)
+       NUMCOARSE(NPUNT)=ICF
+C        Change the coarse point at each nfif fine points
+       IF(MOD(IF,NFIF).EQ.0)ICF=ICF+1 
+   30  CONTINUE
+       NPUNTC=ICT+NFIC
+C
+C                        all complications ended ! WHOW !
+C
+C      Shifts star , if requested
+       IF(X0.NE.0.0) THEN
+       DO 50 J=1,NPUNT
+   50  X(J)=X(J)+X0
+       ENDIF
+       IF(Y0.NE.0.0) THEN
+       DO 53 J=1,NPUNT
+   53  Y(J)=Y(J)+Y0
+       ENDIF
+       IF(Z0.NE.0.0) THEN
+       DO 56 J=1,NPUNT
+   56  Z(J)=Z(J)+Z0
+       ENDIF
+C                 Constant potential
+       DO 59 I=1,NPUNT
+   59  G(I)=1./R
+C
+ 500   IF(LOST.GT.0) THEN
+         WRITE(6,1000) NPUNT,LOST
+         IF(PRINTFILE) WRITE(NFILE,1000) NPUNT,LOST
+ 1000    FORMAT(' ERROR! OBJECT NOT PROPERLY DRAWN! '/
+     1    ' space available for only:',I6,' surface points.',
+     2    ' lost points:',I6/
+     3    ' REDUCE THE NTHETA PARAMETER OR GO INTO THE FORTRAN LIST TO',
+     4    ' INCREASE MAXPT')
+       ENDIF
+C
+       RETURN
+       END              
+C
+       SUBROUTINE SUMREFL(NPNT,NIF,FBOLREF,FRIFL)
+C      --------------------------------------------------
+C      This routine sums the reflected surface element flux
+C      obtaining the total light reflected by each object
+C      ------------------------------------------------
+       DIMENSION FRIFL(NPNT),FBOLREF(3),NIF(2,3)
+C
+C      ..................... loop on objects
+       DO 10 I=1,3
+       N1=NIF(1,I)
+       N2=NIF(2,I)
+       FBOLREF(I)=0.0
+       IF(N1.LE.0.OR.N2.LE.0) GOTO 10
+       DO 20 J=N1,N2
+       FBOLREF(I)=FBOLREF(I)+FRIFL(J)
+   20  CONTINUE
+   10  CONTINUE
+       RETURN
+       END
+C
+       SUBROUTINE TCHANGE(NPNT,FB,FRIFL,T,A)
+C      ----------------------------------------------------
+C      Given FB: bolometric flux * area A, computes T,
+C      assuming black body spectrum flux=Area*T**4 *ac/4pi
+C      ----------------------------------------------------
+       DIMENSION FB(NPNT),T(NPNT),A(NPNT),FRIFL(NPNT)
+       PARAMETER (AC4PI=1.8065E-5)
+       DO 10 I=1,NPNT
+  10   T(I)=( (FB(I)+FRIFL(I)) / (AC4PI*A(I)) )**0.25
+       RETURN
+       END
+C
+       SUBROUTINE TOTALE(N,T,A)
+C      -------------------------------------
+C      T=sum of A(i)
+C      -------------------------------------
+       DIMENSION A(N)
+       T=0
+       DO 10 I=1,N
+   10  T=T+A(I)
+       RETURN
+       END
+C
+       SUBROUTINE UPPERC(C,PROMPT,KF)
+C      -----------------------------------------------------------
+C      Reads an input command and transforms it to upcase letters
+C      adding 32 to the ascii character decimal value
+C      (32 is the offset between upcase and lowercase letters)
+C      This routines doesn't follows the ANSI FORTRAN standards
+C      If "?" is encountered the scanning stops and KF=1 is returned
+C      IF "$" in first position,the command is a DCL command, 
+C      and the routine "spawn" creating a subprocess.
+C      If "!" in first position the line is skipped being a comment
+C      If "!!" in first position this is a title line for printed outp.
+C      -----------------------------------------------------------
+       PARAMETER (MAXTITLE=5)
+       COMMON/TITLE/NTITLEMX,NTITLE,TITLE(MAXTITLE)      
+       CHARACTER*80 TITLE
+       CHARACTER*(*) C,PROMPT
+C
+       LENGTH=LEN(C)
+C                          
+   10  WRITE(6,1000) PROMPT
+ 1000  FORMAT(/A,$)
+C 1000 FORMAT(/' INPUT FLAG > ',$)
+C             note:"$": it's a "Vax Fortran Extension" way to give a prompt
+       READ(5,1100,ERR=500,END=600)C
+ 1100  FORMAT(A)
+C           ........... vax fortran way to create a subprocess
+       IF(C(1:1).EQ.'$') THEN
+          C=C(2:)
+          ISTATUS=LIB$SPAWN(C)
+          GOTO 10
+C           ............ the line is skipped as a comment
+       ELSE IF(C(1:1).EQ.'!') THEN
+C         Title line inserted in common
+          IF(C(2:2).EQ.'!'.AND.NTITLE.LT.NTITLEMX) THEN
+            NTITLE=NTITLE+1             
+            TITLE(NTITLE)=C(3:)
+          ENDIF
+          GOTO 10
+       ENDIF
+C
+       KF=0
+       DO 20 I=1,LENGTH
+       IF(C(I:I).EQ.'?') THEN
+                         KF=1
+                         RETURN
+       ENDIF
+       IF(C(I:I).GE.'a'.AND.C(I:I).LE.'z') THEN
+                                           IC=ICHAR(C(I:I))
+                                           IC=IC-32
+                                           C(I:I)=CHAR(IC)
+C     1      C(I:I)=CHAR(ICHAR(C(I:I))+32)
+C     1      C(I:I)=CHAR(IAND( ICHAR(C(I:I)) , '5F'X ) )  Maybe faster 
+       ENDIF
+  20   CONTINUE
+C
+       RETURN
+  600  WRITE(6,6000)
+ 6000  FORMAT(' ERROR: EOF ENCOUNTERED READING INPUT  ')
+       GOTO 10
+  500  WRITE(6,5000)
+ 5000  FORMAT(' ERROR READING INPUT!  Format is A80     Reenter.')  
+       GOTO 10
+       END
+C
diff --git a/code/f.tex b/code/f.tex
new file mode 100755
index 0000000..2ac36a8
--- /dev/null
+++ b/code/f.tex
@@ -0,0 +1,203 @@
+%  TEX - MACRO DI USO GENERALE - 23 - 8 -88 - M.GALLI
+%             DEFINIZIONE DEI FORMATI A 8-9-10-12 PUNTI 
+% ------------------------------------------------------------
+% Macros dal "The TeXbook"  (file tex$disk:[tex.texams.doc]manmac.tex)
+% con varianti introdotto per fonts tutti a 12 punti ,10-9-8
+
+\catcode`@=11 % borrow the private macros of PLAIN (with care)
+
+% fonts a dodici punti per il \twelvepoints
+\font\twelverm=cmr12
+\font\twelvei=cmmi12
+\font\twelvesy=cmsy10 scaled \magstep1       % at 12 pt  - scaled 1200 
+\font\twelveex=cmex10 scaled \magstep1
+\font\twelvebf=cmbx12
+\font\twelvesl=cmsl12
+\font\twelvett=cmtt12
+\font\twelveit=cmti12
+
+% fonts a nove punti per il \twelvepoints 
+%\font\nineex=cmtex9   % uso invece il 10 sotto
+
+% fonts a sette punti per il \twelvepionts
+\font\sevenei=cmmi7
+
+\font\tentex=cmtex10
+
+\font\inchhigh=cminch
+\font\titlefont=cmssdc10 at 40pt
+
+\font\ninerm=cmr9
+\font\eightrm=cmr8
+\font\sixrm=cmr6
+
+\font\ninei=cmmi9
+\font\eighti=cmmi8
+\font\sixi=cmmi6
+\skewchar\ninei='177 \skewchar\eighti='177 \skewchar\sixi='177
+
+\font\ninesy=cmsy9
+\font\eightsy=cmsy8
+\font\sixsy=cmsy6
+\skewchar\ninesy='60 \skewchar\eightsy='60 \skewchar\sixsy='60
+
+\font\eightss=cmssq8
+
+\font\eightssi=cmssqi8
+
+\font\ninebf=cmbx9
+\font\eightbf=cmbx8
+\font\sixbf=cmbx6
+
+\font\ninett=cmtt9
+\font\eighttt=cmtt8
+
+\hyphenchar\tentt=-1 % inhibit hyphenation in typewriter type
+\hyphenchar\ninett=-1
+\hyphenchar\eighttt=-1
+
+\font\ninesl=cmsl9
+\font\eightsl=cmsl8
+
+\font\nineit=cmti9
+\font\eightit=cmti8
+
+%\font\tenu=cmu10 % unslanted text italic
+%\font\magnifiedfiverm=cmr5 at 10pt
+%\font\manual=manfnt % font used for the METAFONT logo, etc.
+%\font\cmman=cmman % font used for miscellaneous Computer Modern variations
+
+\newskip\ttglue
+\def\twelvepoint{\def\rm{\fam0\twelverm}%
+  \textfont0=\twelverm \scriptfont0=\ninerm \scriptscriptfont0=\sevenrm
+  \textfont1=\twelvei \scriptfont1=\ninei \scriptscriptfont1=\sevenei
+  \textfont2=\twelvesy \scriptfont2=\ninesy \scriptscriptfont2=\sevensy
+  \textfont3=\twelveex \scriptfont3=\twelveex  \scriptscriptfont3=\twelveex
+  \def\it{\fam\itfam\twelveit}%
+  \textfont\itfam=\twelveit
+  \def\sl{\fam\slfam\twelvesl}%
+  \textfont\slfam=\twelvesl
+  \def\bf{\fam\bffam\twelvebf}%
+  \textfont\bffam=\twelvebf \scriptfont\bffam=\ninebf
+   \scriptscriptfont\bffam=\sevenbf
+  \def\tt{\fam\ttfam\twelvett}%
+  \textfont\ttfam=\twelvett
+  \tt \ttglue=.7em plus.27em minus.17em
+  \normalbaselineskip=16pt
+%  \def\MF{{\manual META}\-{\manual FONT}}%
+  \let\sc=\tenrm
+  \let\big=\twelvebig
+  \setbox\strutbox=\hbox{\vrule height9pt depth4pt width\z@}%
+  \normalbaselines\rm}
+
+\def\tenpoint{\def\rm{\fam0\tenrm}%
+  \textfont0=\tenrm \scriptfont0=\sevenrm \scriptscriptfont0=\fiverm
+  \textfont1=\teni \scriptfont1=\seveni \scriptscriptfont1=\fivei
+  \textfont2=\tensy \scriptfont2=\sevensy \scriptscriptfont2=\fivesy
+  \textfont3=\tenex \scriptfont3=\tenex \scriptscriptfont3=\tenex
+  \def\it{\fam\itfam\tenit}%
+  \textfont\itfam=\tenit
+  \def\sl{\fam\slfam\tensl}%
+  \textfont\slfam=\tensl
+  \def\bf{\fam\bffam\tenbf}%
+  \textfont\bffam=\tenbf \scriptfont\bffam=\sevenbf
+   \scriptscriptfont\bffam=\fivebf
+  \def\tt{\fam\ttfam\tentt}%
+  \textfont\ttfam=\tentt
+  \tt \ttglue=.5em plus.25em minus.15em
+  \normalbaselineskip=12pt
+  \def\MF{{\manual META}\-{\manual FONT}}%
+  \let\sc=\eightrm
+  \let\big=\tenbig
+  \setbox\strutbox=\hbox{\vrule height8.5pt depth3.5pt width\z@}%
+  \normalbaselines\rm}
+
+\def\ninepoint{\def\rm{\fam0\ninerm}%
+  \textfont0=\ninerm \scriptfont0=\sixrm \scriptscriptfont0=\fiverm
+  \textfont1=\ninei \scriptfont1=\sixi \scriptscriptfont1=\fivei
+  \textfont2=\ninesy \scriptfont2=\sixsy \scriptscriptfont2=\fivesy
+  \textfont3=\tenex \scriptfont3=\tenex \scriptscriptfont3=\tenex
+  \def\it{\fam\itfam\nineit}%
+  \textfont\itfam=\nineit
+  \def\sl{\fam\slfam\ninesl}%
+  \textfont\slfam=\ninesl
+  \def\bf{\fam\bffam\ninebf}%
+  \textfont\bffam=\ninebf \scriptfont\bffam=\sixbf
+   \scriptscriptfont\bffam=\fivebf
+  \def\tt{\fam\ttfam\ninett}%
+  \textfont\ttfam=\ninett
+  \tt \ttglue=.5em plus.25em minus.15em
+  \normalbaselineskip=11pt
+  \def\MF{{\manual hijk}\-{\manual lmnj}}%
+  \let\sc=\sevenrm
+  \let\big=\ninebig
+  \setbox\strutbox=\hbox{\vrule height8pt depth3pt width\z@}%
+  \normalbaselines\rm}
+
+\def\eightpoint{\def\rm{\fam0\eightrm}%
+  \textfont0=\eightrm \scriptfont0=\sixrm \scriptscriptfont0=\fiverm
+  \textfont1=\eighti \scriptfont1=\sixi \scriptscriptfont1=\fivei
+  \textfont2=\eightsy \scriptfont2=\sixsy \scriptscriptfont2=\fivesy
+  \textfont3=\tenex \scriptfont3=\tenex \scriptscriptfont3=\tenex
+  \def\it{\fam\itfam\eightit}%
+  \textfont\itfam=\eightit
+  \def\sl{\fam\slfam\eightsl}%
+  \textfont\slfam=\eightsl
+  \def\bf{\fam\bffam\eightbf}%
+  \textfont\bffam=\eightbf \scriptfont\bffam=\sixbf
+   \scriptscriptfont\bffam=\fivebf
+  \def\tt{\fam\ttfam\eighttt}%
+  \textfont\ttfam=\eighttt
+  \tt \ttglue=.5em plus.25em minus.15em
+  \normalbaselineskip=9pt
+  \def\MF{{\manual opqr}\-{\manual stuq}}%
+  \let\sc=\sixrm
+  \let\big=\eightbig
+  \setbox\strutbox=\hbox{\vrule height7pt depth2pt width\z@}%
+  \normalbaselines\rm}
+
+\def\tenmath{\tenpoint\fam-1 } % use after $ in ninepoint sections
+
+%  aggiungo il grande 12
+\def\twelvebig#1{{\hbox{$\left#1\vbox to9pt{}\right.\n@space$}}}
+
+\def\tenbig#1{{\hbox{$\left#1\vbox to8.5pt{}\right.\n@space$}}}
+\def\ninebig#1{{\hbox{$\textfont0=\tenrm\textfont2=\tensy
+  \left#1\vbox to7.25pt{}\right.\n@space$}}}
+\def\eightbig#1{{\hbox{$\textfont0=\ninerm\textfont2=\ninesy
+  \left#1\vbox to6.5pt{}\right.\n@space$}}}
+
+% fine macro del texbook
+% -------------------------------------------------------------
+%
+\font\ftit=CMr17          % titoli roman 17 punti
+\font\ftitp=cmr12        %   titoletti roman 12 punti
+%
+\font\fmain=CMR12          % testo in roman 12 punti
+\font\fmaing=CMBX12        % testo grassetto
+\font\fmainp=CMR9          %       roman 9 punti
+%
+%\font\fita=CMTI12          % italico
+%
+%\baselineskip=18pt 
+\hsize=5.5in               % 6.5in default
+%\vsize=7.9in               % 8.9in default
+%\voffset=1in
+\hoffset=0.5in
+%
+\nopagenumbers        % niente numerazione
+\raggedbottom         % tolleranza in basso
+%\topskip10pt plus90pt  minus90pt    %colla in alto per 3 righe di tolleranza 
+\topskip 2.5cm plus1cm minus0cm
+\hyphenpenalty=1000     % smettila di hyphennare in inglese!
+\pretolerance=400        % tollera righe bruttine prima di hyphennare
+\tolerance=1000          % tollera brutte righe prima di lamentarsi
+\raggedright          % tolleranza a destra
+\hfuzz=30pt           % le overfull fino a 30pt vanno bene lo stesso
+\overfullrule=0pt     % niente scarabocchio che segnala overfull
+%
+\def\fine{\par\vfill\end}
+\def\capo{\par\noindent}
+%
+%
+\endinput
diff --git a/code/missfont.log b/code/missfont.log
new file mode 100644
index 0000000..2b11d75
--- /dev/null
+++ b/code/missfont.log
@@ -0,0 +1,8 @@
+mktextfm CMr17
+mktextfm CMR12
+mktextfm CMBX12
+mktextfm CMR9
+mktextfm CMr17
+mktextfm CMR12
+mktextfm CMBX12
+mktextfm CMR9
diff --git a/code/test1.com b/code/test1.com
new file mode 100755
index 0000000..77f8a40
--- /dev/null
+++ b/code/test1.com
@@ -0,0 +1,44 @@
+$ set verify
+$!  TEST STANDARD NUMERO 1: 1 STELLA RAGGIO 1, T=1,X0=1 => L=PI
+$!  Not normalized !
+$!  CBS con ntheta=51-101 
+$ bin
+$ run cbs
+stara
+mesha
+51
+x0a
+0
+ra
+1
+TEMPA
+1
+BOLA
+0
+print
+amount
+4
+reflection
+0
+map
+100000
+unit 
+0
+phasegrid
+numcells
+50
+OFF
+starb
+reflection
+OFF
+go
+STARA
+mesha
+101
+GO
+stop
+$!
+$!  TEST STANDARD NUMERO 1: 1 STELLA RAGGIO 1, T=1,X0=1 => L=PI
+$!  Not normalized !
+$!  CBS con ntheta=51-101 
+$!
diff --git a/code/test2.com b/code/test2.com
new file mode 100755
index 0000000..8a423dc
--- /dev/null
+++ b/code/test2.com
@@ -0,0 +1,71 @@
+$ BIN
+$ run cbs
+!!                     TEST NUMERO 2:   
+!! STELLE SFERICHE RAGGI:  1,2  POSIZIONE CENTRI X0=-2,2 
+!! TEMPERATURA : T=1 => Luminosita' non normalizzate, = superfici: pi, 4*pi.
+!!  Con questi parametri si dovrebbe avere precisione migliore dell'1%
+STARA
+mesha
+100
+x0a
+-2.0
+y0a
+0.0
+z0a
+0.0
+ra
+1
+tempa
+1
+bola
+0
+corda
+3.
+alba
+1.
+STARB
+meshb
+200
+x0b
+2.0
+y0b
+0.0
+z0b
+0.0
+rb
+2
+tempb
+1
+bolb
+0
+albb
+1.
+cordb
+3.
+PRINT
+amount
+4
+refl
+0
+light
+0
+map
+100000
+unit 
+0
+GRID
+numcells
+1000
+REFLECTION
+coarse
+5
+maxiter
+5
+precision
+0.000001
+!OFF
+!reflection
+!OFF
+GO
+STOP
+$! FINE PROCEDURA
diff --git a/code/test3.com b/code/test3.com
new file mode 100755
index 0000000..0616918
--- /dev/null
+++ b/code/test3.com
@@ -0,0 +1,51 @@
+$ set verify
+$!  TEST STANDARD NUMERO 3 : 1 DISCO RAGGIO 1, T=1,X0=0, BOL=0 
+$!     => L=PI di faccia, luce=4 di bordo , (4+pi)*cos 45 a 45 gradi.
+$!   il disco e' inclinato e ruotato in modo da essere visto di 
+$!   taglio a fase 0, di faccia a fase 0.25.
+$ bin
+$ run cbs
+reflection
+coarse
+1
+off
+stara
+starb
+reflection
+off
+DISK
+meshc
+50
+ric
+0
+rc
+1
+hc
+2
+hic
+2
+bolc
+0
+inner
+0
+inclinc
+90
+rotatec
+90
+tempc
+1
+PRINT
+amount
+4
+map
+10000
+unit 
+0
+GRID
+numcells
+50
+GO
+stop
+$!
+$!  TEST STANDARD NUMERO 3 disco raggio 1 alto 2
+$!
diff --git a/code/test4.com b/code/test4.com
new file mode 100755
index 0000000..533a004
--- /dev/null
+++ b/code/test4.com
@@ -0,0 +1,58 @@
+$ set verify
+$!  TEST STANDARD NUMERO 4 : 1 DISCO RAGGIO 1, T=1,X0=0, BOL=0 
+$!                           SPESSO 2 AL BORDO, 0 AL CENTRO.
+$!     => L=PI/COS45 di faccia, luce=4 di bordo , (4)*cos 45+PI a 45 gradi.
+$!   il disco e' inclinato e ruotato in modo da essere visto di 
+$!   taglio a fase 0, di faccia a fase 0.25.
+$ bin
+$ run cbs
+!
+reflection
+coarse
+1
+!
+off
+stara
+starb
+reflection
+off
+!
+DISK
+meshc
+1
+ric
+0
+rc
+1
+hc
+2
+hic
+0
+bolc
+0
+inner
+0
+inclinc
+90
+rotatec
+90
+tempc
+1
+!
+GRID
+numcells
+50
+!
+PRINT
+amount
+4
+map
+10000
+unit 
+0
+!
+GO
+STOP
+$!
+$!  TEST STANDARD NUMERO 3 disco raggio 1 alto 2
+$!
diff --git a/code/test5.com b/code/test5.com
new file mode 100755
index 0000000..f214486
--- /dev/null
+++ b/code/test5.com
@@ -0,0 +1,94 @@
+$ set verify
+$!   2 QUADRATI di 4 punt1, lato 2, uno lucente, uno buio, a distanza 1.
+$!   1 RETTANGOLO DI 1 PUNTO, LATO 1 
+$ bin
+$ run cbs
+reflection
+coarse
+1
+maxiter
+5
+PRECISION
+0.00000001
+!
+STARA
+MESHA
+2
+SHAPEA
+0.
+RA
+1.0
+X0A
+1.0
+BOLA
+0
+TEMPA
+1
+INNERA
+1.
+INCLINA
+90.
+!
+STARB
+MESHB
+2
+SHAPEB
+0.
+RB
+1.
+X0B
+-1.0
+BOLB
+0
+TEMPB
+0
+INNERB
+1.
+INCLINB
+90
+!
+DISK
+shapec
+0.0
+meshc
+1.
+rc
+0.5
+x0c
+0.
+y0c
+-0.5
+z0c
+ 0.5 
+BOLc
+0
+TEMPc
+0
+INNERc
+1.
+INCLINc
+90
+!
+PRINT
+amount
+1000
+map
+1
+unit 
+11
+refl
+100
+light
+100
+!
+GRID
+numcells
+10
+!
+!OFF
+!disk
+!off
+!
+GO
+stop
+$EXIT
diff --git a/code/test6.com b/code/test6.com
new file mode 100755
index 0000000..07b2031
--- /dev/null
+++ b/code/test6.com
@@ -0,0 +1,99 @@
+
+$ set verify
+$!   2 STELLE EGUALI, ROCHE MODEL 
+$ bin
+$ run cbs
+!              Stella A in 0,0,0,
+STARA
+shapea
+2.
+RA
+0.5
+x0a
+0.
+y0a
+0.
+z0a
+0.
+omegaa
+0.
+mesha
+13.
+tempa
+1.
+bola
+0.
+corda
+3.
+!           Stella B in 1,0,0
+STARB
+shapeb
+2.
+RB
+0.5
+x0b
+1.
+y0b
+0.
+z0b
+0.
+omegab
+0.
+meshb
+13.
+tempb
+1.
+bolb
+0.
+cordb
+3.
+!             COARSE = num fini
+reflection
+coarse
+1.
+maxiter
+5.
+!
+ORBIT
+MRATIO
+1.
+PREC
+0.00001
+!
+GRID
+numcells
+20. 
+!
+OFF
+REFLECTION
+DISK
+OFF
+!
+!             full printing:
+PRINT
+amount
+1000
+map
+1
+unit 
+11
+refl
+100
+light
+100
+!
+GO
+!                little printing
+PRINT
+amount
+4
+map
+10000
+unit 
+11
+refl
+0
+light
+0 
+STOP
+$EXIT
diff --git a/code/test7.com b/code/test7.com
new file mode 100755
index 0000000..b65933c
--- /dev/null
+++ b/code/test7.com
@@ -0,0 +1,107 @@
+$ set verify
+$!!   CASO DI A.A. Suppl. 55 : 403 (84) 
+$!!     prova A : roche noreflection nogravity nolimb
+$ bin
+$ run cbs
+!              Stella A in 0,0,0, ( la h )
+STARA
+shapea
+2.
+RA
+0.18
+omegaa
+5.983
+!betaa
+!0.08
+tempa
+19000.
+!limba
+!0.36
+x0a
+0.
+y0a
+0.
+z0a
+0.
+mesha
+111.
+bola
+0.
+corda
+3.
+!           Stella B in 1,0,0
+STARB
+shapeb
+2.
+RB
+0.0
+!0.3
+x0b
+1.
+y0b
+0.
+z0b
+0.
+omegab
+2.738
+!betab
+!0.08
+!limbb
+!0.55
+meshb
+111.
+tempb
+10145.
+bolb
+0.
+cordb
+3.
+!             COARSE 
+REFLECTION
+coarse
+11.
+maxiter
+1.
+!
+ORBIT
+I
+77.3
+mratio
+0.43
+prec
+0.00001
+!
+PHASES
+numphases 
+100.
+norm
+1.
+GRID
+numcells
+1000. 
+!
+OFF
+REFLECTION
+DISK
+OFF
+!
+!             printing:
+PRINT
+amount
+4
+map
+0
+unit 
+11
+refl
+0 
+light
+0 
+!
+plot
+file
+12
+!
+GO
+STOP
+$EXIT
diff --git a/code/test9.com b/code/test9.com
new file mode 100755
index 0000000..5397544
--- /dev/null
+++ b/code/test9.com
@@ -0,0 +1,149 @@
+$ set verify
+$ bin
+$ run cbs
+!!   TEST 9 : IM aur - parametri da  J.B. Rafert - A.J. 100:1523(90) 
+!!            contro dati sperimentali di ?
+!              A Object in 0,0,0, 
+STARA
+mesha
+111.
+x0a
+0.
+y0a
+0.
+z0a
+0.
+shapea
+2.
+ra
+0.0
+omegaa
+3.103
+ga
+0.63
+tempa
+12000.
+limba
+0.75
+alba
+1.
+!bola
+!0.9427
+corda
+3.
+!           Stella B in 1,0,0 ( la 2 )
+STARB
+meshb
+111.
+x0b
+1.
+y0b
+0.
+z0b
+0.
+shapeb
+2.
+RB
+0.0
+omegab
+2.4913
+gb
+0.32
+limbb
+0.675
+tempb
+5954.
+albb
+0.8
+!bolb
+!0.0573
+cordb
+3.
+!            COLORS
+U
+Ulamb1
+3600.
+Ulamb2
+3600.
+Ulum_a
+-1.
+Ulum_b
+-1.
+B
+Blamb1
+4250.
+Blamb2
+4250.
+Blum_a
+-1.
+Blum_b
+-1.
+V
+Vlamb1
+5410.
+Vlamb2
+5410.
+vlum_a
+-1.
+vlum_b
+-1.
+R
+Rlamb1
+7000.
+Rlamb2
+7000.
+Rlum_a
+-1.
+Rlum_b
+-1.
+!             COARSE 
+REFLECTION
+coarse
+5.
+maxiter
+5.
+precision
+1.E-6
+!
+ORBIT
+I
+75.21
+mratio
+0.3114
+prec
+0.00001
+!
+PHASES
+numphases 
+100.
+norm
+1.
+GRID
+numcells
+200. 
+!
+OFF
+!REFLECTION
+DISK
+OFF
+!
+!             printing:
+PRINT
+amount
+4
+map
+0
+unit 
+11
+refl
+0 
+light
+0 
+!
+plot
+file
+12
+!
+GO
+STOP
+$EXIT
diff --git a/code/test9.log b/code/test9.log
new file mode 100755
index 0000000..cb947cf
--- /dev/null
+++ b/code/test9.log
@@ -0,0 +1,556 @@
+$!
+$!-------------------------------------------------------------------------
+$!                       SYLOGIN.COM    7-12-89
+$!-------------------------------------------------------------------------
+$ set noverify
+
+----------------------------------------------------------------------
+  ATTENZIONE !  ATTENZIONE !  ATTENZIONE !  ATTENZIONE !  ATTENZIONE !
+
+Il Microvax non ce la fa piu' a reggere il cluster ......
+
+Forse e' la fine.... ma forse no:
+stiamo lavorando con una configurazione di fortuna, che adesso va.
+
+Non e' attivo l'SNA per collegamento con IBM ( ma interlink va )
+Non e' attivo il Pathwork per collegare Personal MS-DOS e MAC.
+
+DA UN MOMENTO ALL'ALTRO SI PUO' BLOCCARE TUTTO, SENZA PREAVVISO !
+ AUGURI.....
+
+---------------------------------------------------------------------
+ 
+   5-MAY-1993 10:29:25
+ Now MARC login procedure executing ! 
+ 
+$ bin
+$ run cbs
+                     CLOSE BINARY SYSTEM ANALYSIS PROGRAM
+                    Version 0.0 ( debugging in progress )
+
+
+
+INPUT FLAG >  
+!!   TEST 9 : IM aur - parametri da  J.B. Rafert - A.J. 100:1523(90) 
+
+INPUT FLAG >  
+!!            contro dati sperimentali di ?
+
+INPUT FLAG >  
+!              A Object in 0,0,0, 
+
+INPUT FLAG >  
+STARA
+Set on: flag number:    1     STARA        Star A             
+
+INPUT PARAMETER >  
+mesha
+VALUE > 
+111.
+Parameter number:    7     MESHA        num. of theta mesh  =    111.0000    
+
+INPUT PARAMETER >  
+x0a
+VALUE > 
+0.
+Parameter number:    3     X0A          X position of A     =   0.0000000E+00
+
+INPUT PARAMETER >  
+y0a
+VALUE > 
+0.
+Parameter number:    4     Y0A          Y position of A     =   0.0000000E+00
+
+INPUT PARAMETER >  
+z0a
+VALUE > 
+0.
+Parameter number:    5     Z0A          Z position of A     =   0.0000000E+00
+
+INPUT PARAMETER >  
+shapea
+VALUE > 
+2.
+Parameter number:    1     SHAPEA       sphere=1,roche=2    =    2.000000    
+
+INPUT PARAMETER >  
+ra
+VALUE > 
+0.0
+Parameter number:    2     RA           radius of star A    =   0.0000000E+00
+
+INPUT PARAMETER >  
+omegaa
+VALUE > 
+3.103
+Parameter number:    6     OMEGAA       potential of A      =    3.103000    
+
+INPUT PARAMETER >  
+ga
+VALUE > 
+0.63
+Parameter number:    9     GA           gravity dark. of A  =   0.6300000    
+
+INPUT PARAMETER >  
+tempa
+VALUE > 
+12000.
+Parameter number:   10     TEMPA        pole temperature A  =    12000.00    
+
+INPUT PARAMETER >  
+limba
+VALUE > 
+0.75
+Parameter number:   13     LIMBA        limb darkening of A =   0.7500000    
+
+INPUT PARAMETER >  
+alba
+VALUE > 
+1.
+Parameter number:   12     ALBA         bolometric albedo A =    1.000000    
+
+INPUT PARAMETER >  
+!bola
+
+INPUT PARAMETER >  
+!0.9427
+
+INPUT PARAMETER >  
+corda
+VALUE > 
+3.
+Parameter number:   14     CORDA        arch,cord,tang.seg. =    3.000000    
+
+INPUT PARAMETER >  
+!           Stella B in 1,0,0 ( la 2 )
+
+INPUT PARAMETER >  
+STARB
+Set on: flag number:    2     STARB        Star B             
+
+INPUT PARAMETER >  
+meshb
+VALUE > 
+111.
+Parameter number:   27     MESHB        num. of theta mesh  =    111.0000    
+
+INPUT PARAMETER >  
+x0b
+VALUE > 
+1.
+Parameter number:   23     X0B          X position of B     =    1.000000    
+
+INPUT PARAMETER >  
+y0b
+VALUE > 
+0.
+Parameter number:   24     Y0B          Y position of B     =   0.0000000E+00
+
+INPUT PARAMETER >  
+z0b
+VALUE > 
+0.
+Parameter number:   25     Z0B          Z position of B     =   0.0000000E+00
+
+INPUT PARAMETER >  
+shapeb
+VALUE > 
+2.
+Parameter number:   21     SHAPEB       sphere=1,roche=2    =    2.000000    
+
+INPUT PARAMETER >  
+RB
+VALUE > 
+0.0
+Parameter number:   22     RB           radius of star B    =   0.0000000E+00
+
+INPUT PARAMETER >  
+omegab
+VALUE > 
+2.4913
+Parameter number:   26     OMEGAB       potential of B      =    2.491300    
+
+INPUT PARAMETER >  
+gb
+VALUE > 
+0.32
+Parameter number:   29     GB           gravity dark. of B  =   0.3200000    
+
+INPUT PARAMETER >  
+limbb
+VALUE > 
+0.675
+Parameter number:   33     LIMBB        limb darkening of B =   0.6750000    
+
+INPUT PARAMETER >  
+tempb
+VALUE > 
+5954.
+Parameter number:   30     TEMPB        pole temperature B  =    5954.000    
+
+INPUT PARAMETER >  
+albb
+VALUE > 
+0.8
+Parameter number:   32     ALBB         bolometric albedo B =   0.8000000    
+
+INPUT PARAMETER >  
+!bolb
+
+INPUT PARAMETER >  
+!0.0573
+
+INPUT PARAMETER >  
+cordb
+VALUE > 
+3.
+Parameter number:   34     CORDB        arch,cord,tang.seg. =    3.000000    
+
+INPUT PARAMETER >  
+!            COLORS
+
+INPUT PARAMETER >  
+U
+Set on: flag number:    4     U            U-color  band      
+
+INPUT PARAMETER >  
+Ulamb1
+VALUE > 
+3600.
+Parameter number:   61     ULAMB1       U color lambda 1    =    3600.000    
+
+INPUT PARAMETER >  
+Ulamb2
+VALUE > 
+3600.
+Parameter number:   62     ULAMB2       U color lambda 2    =    3600.000    
+
+INPUT PARAMETER >  
+Ulum_a
+VALUE > 
+-1.
+Parameter number:   63     ULUM_A       frac. U lumin.for A =   -1.000000    
+
+INPUT PARAMETER >  
+Ulum_b
+VALUE > 
+-1.
+Parameter number:   64     ULUM_B       frac. U lumin.for B =   -1.000000    
+
+INPUT PARAMETER >  
+B
+Set on: flag number:    5     B            B-color  band      
+
+INPUT PARAMETER >  
+Blamb1
+VALUE > 
+4250.
+Parameter number:   69     BLAMB1       B color lambda 1    =    4250.000    
+
+INPUT PARAMETER >  
+Blamb2
+VALUE > 
+4250.
+Parameter number:   70     BLAMB2       B color lambda 2    =    4250.000    
+
+INPUT PARAMETER >  
+Blum_a
+VALUE > 
+-1.
+Parameter number:   71     BLUM_A       frac. B lumin.for A =   -1.000000    
+
+INPUT PARAMETER >  
+Blum_b
+VALUE > 
+-1.
+Parameter number:   72     BLUM_B       frac. B lumin.for B =   -1.000000    
+
+INPUT PARAMETER >  
+V
+Set on: flag number:    6     V            V-color  band      
+
+INPUT PARAMETER >  
+Vlamb1
+VALUE > 
+5410.
+Parameter number:   77     VLAMB1       V color lambda 1    =    5410.000    
+
+INPUT PARAMETER >  
+Vlamb2
+VALUE > 
+5410.
+Parameter number:   78     VLAMB2       V color lambda 2    =    5410.000    
+
+INPUT PARAMETER >  
+vlum_a
+VALUE > 
+-1.
+Parameter number:   79     VLUM_A       frac. V lumin.for A =   -1.000000    
+
+INPUT PARAMETER >  
+vlum_b
+VALUE > 
+-1.
+Parameter number:   80     VLUM_B       frac. V lumin.for B =   -1.000000    
+
+INPUT PARAMETER >  
+R
+Set on: flag number:    7     R            R-color  band      
+
+INPUT PARAMETER >  
+Rlamb1
+VALUE > 
+7000.
+Parameter number:   85     RLAMB1       R color lambda 1    =    7000.000    
+
+INPUT PARAMETER >  
+Rlamb2
+VALUE > 
+7000.
+Parameter number:   86     RLAMB2       R color lambda 2    =    7000.000    
+
+INPUT PARAMETER >  
+Rlum_a
+VALUE > 
+-1.
+Parameter number:   87     RLUM_A       frac. R lumin.for A =   -1.000000    
+
+INPUT PARAMETER >  
+Rlum_b
+VALUE > 
+-1.
+Parameter number:   88     RLUM_B       frac. R lumin.for B =   -1.000000    
+
+INPUT PARAMETER >  
+!             COARSE 
+
+INPUT PARAMETER >  
+REFLECTION
+Set on: flag number:    9     REFLECTION   Reflection comput. 
+
+INPUT PARAMETER >  
+coarse
+VALUE > 
+5.
+Parameter number:  104     COARSE       coarsing factor     =    5.000000    
+
+INPUT PARAMETER >  
+maxiter
+VALUE > 
+5.
+Parameter number:  102     MAXITER      maximum iteration   =    5.000000    
+
+INPUT PARAMETER >  
+precision
+VALUE > 
+1.E-6
+Parameter number:  103     PRECISION    convergency  check  =   0.1000000E-05
+
+INPUT PARAMETER >  
+!
+
+INPUT PARAMETER >  
+ORBIT
+Set on: flag number:   11     ORBIT        Orbital parameters 
+
+INPUT PARAMETER >  
+I
+VALUE > 
+75.21
+Parameter number:  105     I            incl.of orbit plane =    75.21000    
+
+INPUT PARAMETER >  
+mratio
+VALUE > 
+0.3114
+Parameter number:  106     MRATIO       mass ratio Mb/Ma    =   0.3114000    
+
+INPUT PARAMETER >  
+prec
+VALUE > 
+0.00001
+Parameter number:  108     PREC         Newton-Rapson prec. =   0.1000000E-04
+
+INPUT PARAMETER >  
+!
+
+INPUT PARAMETER >  
+PHASES
+Set on: flag number:   12     PHASES         Sets phases      
+
+INPUT PARAMETER >  
+numphases 
+VALUE > 
+100.
+Parameter number:  111     NUMPHASES    num.of equis.phases =    100.0000    
+
+INPUT PARAMETER >  
+norm
+VALUE > 
+1.
+Parameter number:  113     NORM         Light curve norm.   =    1.000000    
+
+INPUT PARAMETER >  
+GRID
+Set on: flag number:   13     GRID           Sets project.grid
+
+INPUT PARAMETER >  
+numcells
+VALUE > 
+200. 
+Parameter number:  114     NUMCELLS     num.of grid points  =    200.0000    
+
+INPUT PARAMETER >  
+!
+
+INPUT PARAMETER >  
+OFF
+Set on: flag number:   19     OFF          Set next flags off 
+
+INPUT FLAG >  
+!REFLECTION
+
+INPUT FLAG >  
+DISK
+Set off: flag number:    3     DISK         Disk               
+
+INPUT FLAG >  
+OFF
+Set off: flag number:   19     OFF          Set next flags off 
+
+INPUT FLAG >  
+!
+
+INPUT FLAG >  
+!             printing:
+
+INPUT FLAG >  
+PRINT
+Set on: flag number:   20     PRINT        Output is printed  
+
+INPUT PARAMETER >  
+amount
+VALUE > 
+4
+Parameter number:  117     AMOUNT       Amount of printing  =    4.000000    
+
+INPUT PARAMETER >  
+map
+VALUE > 
+0
+Parameter number:  120     MAP          Map print phas.step =   0.0000000E+00
+
+INPUT PARAMETER >  
+unit 
+VALUE > 
+11
+Parameter number:  119     UNIT         Output on this unit =    11.00000    
+
+INPUT PARAMETER >  
+refl
+VALUE > 
+0 
+Parameter number:  121     REFL         Reflection details  =   0.0000000E+00
+
+INPUT PARAMETER >  
+light
+VALUE > 
+0 
+Parameter number:  122     LIGHT        Light curve details =   0.0000000E+00
+
+INPUT PARAMETER >  
+!
+
+INPUT PARAMETER >  
+plot
+Set on: flag number:   21     PLOT         Plot produced      
+
+INPUT PARAMETER >  
+file
+VALUE > 
+12
+Parameter number:  127     FILE         Output ASCII file   =    12.00000    
+
+INPUT PARAMETER >  
+!
+
+INPUT PARAMETER >  
+GO
+Set on: flag number:   15     GO             Program  runs    
+
+Elapsed time for I/O:                      2.7891          Total:          2.7891    
+
+
+Computed Lagrange points and potential for critical lobes:
+    L1= 0.6173010     omega=  2.491283    
+    L2=  1.505044     omega=  2.297606    
+    L3=-0.8606350     omega=  2.082969    
+
+
+Surface-X axis intersection for object: 1 computed as: 0.3812175      -0.3748645    
+Surface drawing starts from point: 0.3812175    
+
+
+Elapsed time for surface drawing:          54.270          Total:          54.270    
+
+
+Surface-X axis intersection for object: 2 computed as: 0.6173010        1.307500    
+Surface drawing starts from point:  1.307500    
+
+
+Elapsed time for surface drawing:          52.570          Total:          106.84    
+
+
+Elapsed time for reflection:               117.36          Total:          117.36    
+
+
+Elapsed time for color band:               10.371          Total:          10.371    
+
+
+Elapsed time for color band:               8.5000          Total:          18.871    
+
+
+Elapsed time for color band:               8.4102          Total:          27.281    
+
+
+Elapsed time for color band:               8.2109          Total:          35.492    
+
+
+Elapsed time for color band:               7.9688          Total:          43.461    
+
+
+Elapsed time for color band:               8.3281          Total:          51.789    
+
+
+Elapsed time for color band:               9.0625          Total:          60.852    
+
+
+Elapsed time for color band:               8.0703          Total:          68.922    
+
+
+Elapsed time for flux normalization:              0.58594E-01      Total:         0.58594E-01
+
+Sub.LUCE1: beginning phase:    1 :  0.00000E+00 elapsed time for last phase:  0.0000000E+00
+Sub.LUCE1: beginning phase:    2 :  0.62832E-01 elapsed time for last phase:   21.66016    
+Sub.LUCE1: beginning phase:    3 :  0.12566     elapsed time for last phase:   19.20313    
+Sub.LUCE1: beginning phase:    4 :  0.18850     elapsed time for last phase:   18.33984    
+Sub.LUCE1: beginning phase:    5 :  0.25133     elapsed time for last phase:   18.29688    
+Sub.LUCE1: beginning phase:    6 :  0.31416     elapsed time for last phase:   18.37109    
+Sub.LUCE1: beginning phase:    7 :  0.37699     elapsed time for last phase:   18.10156    
+Sub.LUCE1: beginning phase:    8 :  0.43982     elapsed time for last phase:   18.43750    
+Sub.LUCE1: beginning phase:    9 :  0.50265     elapsed time for last phase:   18.92969    
+Sub.LUCE1: beginning phase:   10 :  0.56549     elapsed time for last phase:   22.32031    
+Sub.LUCE1: beginning phase:   11 :  0.62832     elapsed time for last phase:   20.26172    
+Sub.LUCE1: beginning phase:   12 :  0.69115     elapsed time for last phase:   19.32813    
+Sub.LUCE1: beginning phase:   13 :  0.75398     elapsed time for last phase:   18.80078    
+Sub.LUCE1: beginning phase:   14 :  0.81681     elapsed time for last phase:   24.69141    
+Sub.LUCE1: beginning phase:   15 :  0.87965     elapsed time for last phase:   22.73828    
+Sub.LUCE1: beginning phase:   16 :  0.94248     elapsed time for last phase:   27.88281    
+Sub.LUCE1: beginning phase:   17 :   1.0053     elapsed time for last phase:   26.36719    
+Sub.LUCE1: beginning phase:   18 :   1.0681     elapsed time for last phase:   23.17188    
+Sub.LUCE1: beginning phase:   19 :   1.1310     elapsed time for last phase:   29.46094    
+Sub.LUCE1: beginning phase:   20 :   1.1938     elapsed time for last phase:   31.43750    
+Sub.LUCE1: beginning phase:   21 :   1.2566     elapsed time for last phase:   26.33984    
+Sub.LUCE1: beginning phase:   22 :   1.3195     elapsed time for last phase:   33.19141    
+Sub.LUCE1: beginning phase:   23 :   1.3823     elapsed time for last phase:   24.71875    
+Sub.LUCE1: beginning phase:   24 :   1.4451     elapsed time for last phase:   25.76953    
diff --git a/code/vt3.com b/code/vt3.com
new file mode 100755
index 0000000..42c5a34
--- /dev/null
+++ b/code/vt3.com
@@ -0,0 +1,114 @@
+$ set verify
+$!!   TEST 8 : CASO VT3 DI A.A. 197:347 (88) 
+$!!            Impongo lobi quasi critici
+$ bin
+$ run cbs
+!              A Object in 0,0,0, ( object 1 )
+STARA
+mesha
+111.
+x0a
+0.
+y0a
+0.
+z0a
+0.
+shapea
+2.
+ra
+0.0
+omegaa
+0.0
+!2.876 
+ga
+0.32
+tempa
+5000.
+limba
+0.66
+bola
+0.
+corda
+3.
+!           Stella B in 1,0,0 ( la 2 )
+STARB
+meshb
+111.
+x0b
+1.
+y0b
+0.
+z0b
+0.
+shapeb
+2.
+RB
+0.0
+omegab
+0.0
+!2.876
+!3.637 + 0.5 (q**2/(1+q)) 
+gb
+0.32
+limbb
+0.66
+tempb
+5362.
+bolb
+0.
+cordb
+3.
+U
+ulamb1
+5300
+ulamb2
+5300
+!             COARSE 
+REFLECTION
+coarse
+1
+maxiter
+1.
+!
+ORBIT
+I
+70.92
+mratio
+0.5 
+prec
+0.00001
+!
+PHASES
+numphases 
+100.
+norm
+1.
+GRID
+numcells
+200. 
+!
+OFF
+REFLECTION
+DISK
+OFF
+!
+!             printing:
+PRINT
+amount
+4
+map
+0
+unit 
+11
+refl
+0 
+light
+0 
+!
+plot
+file
+12
+!
+GO
+STOP
+$EXIT
diff --git a/code/vt3.log b/code/vt3.log
new file mode 100755
index 0000000..41de0da
--- /dev/null
+++ b/code/vt3.log
@@ -0,0 +1,759 @@
+$ set noverify
+ 
+      Sylogin.com executing, node ebo530
+ 
+ 
+   5-MAR-1992 12:05:08
+ Now MARC login procedure executing on EBO530 
+ 
+$!!   TEST 8 : CASO VT3 DI A.A. 197:347 (88) 
+$!!            Impongo lobi quasi critici
+$ bin
+$ run cbs
+                     CLOSE BINARY SYSTEM ANALYSIS PROGRAM
+                    Version 0.0 ( debugging in progress )
+
+
+
+INPUT FLAG >  
+!              A Object in 0,0,0, ( object 1 )
+
+INPUT FLAG >  
+STARA
+Set on: flag number:    1     STARA        Star A             
+
+INPUT PARAMETER >  
+mesha
+VALUE > 
+111.
+Parameter number:    7     MESHA        num. of theta mesh  =    111.0000    
+
+INPUT PARAMETER >  
+x0a
+VALUE > 
+0.
+Parameter number:    3     X0A          X position of A     =   0.0000000E+00
+
+INPUT PARAMETER >  
+y0a
+VALUE > 
+0.
+Parameter number:    4     Y0A          Y position of A     =   0.0000000E+00
+
+INPUT PARAMETER >  
+z0a
+VALUE > 
+0.
+Parameter number:    5     Z0A          Z position of A     =   0.0000000E+00
+
+INPUT PARAMETER >  
+shapea
+VALUE > 
+2.
+Parameter number:    1     SHAPEA       sphere=1,roche=2    =    2.000000    
+
+INPUT PARAMETER >  
+ra
+VALUE > 
+0.0
+Parameter number:    2     RA           radius of star A    =   0.0000000E+00
+
+INPUT PARAMETER >  
+omegaa
+VALUE > 
+2.876 
+Parameter number:    6     OMEGAA       potential of A      =    2.876000    
+
+INPUT PARAMETER >  
+ga
+VALUE > 
+0.32
+Parameter number:    9     GA           gravity dark. of A  =   0.3200000    
+
+INPUT PARAMETER >  
+tempa
+VALUE > 
+5000.
+Parameter number:   10     TEMPA        medium temp. of A   =    5000.000    
+
+INPUT PARAMETER >  
+limba
+VALUE > 
+0.66
+Parameter number:   13     LIMBA        limb darkening of A =   0.6600000    
+
+INPUT PARAMETER >  
+bola
+VALUE > 
+0.
+Parameter number:   11     BOLA         bolometric lum.of A =   0.0000000E+00
+
+INPUT PARAMETER >  
+corda
+VALUE > 
+3.
+Parameter number:   14     CORDA        arch,cord,tang.seg. =    3.000000    
+
+INPUT PARAMETER >  
+!           Stella B in 1,0,0 ( la 2 )
+
+INPUT PARAMETER >  
+STARB
+Set on: flag number:    2     STARB        Star B             
+
+INPUT PARAMETER >  
+meshb
+VALUE > 
+111.
+Parameter number:   27     MESHB        num. of theta mesh  =    111.0000    
+
+INPUT PARAMETER >  
+x0b
+VALUE > 
+1.
+Parameter number:   23     X0B          X position of B     =    1.000000    
+
+INPUT PARAMETER >  
+y0b
+VALUE > 
+0.
+Parameter number:   24     Y0B          Y position of B     =   0.0000000E+00
+
+INPUT PARAMETER >  
+z0b
+VALUE > 
+0.
+Parameter number:   25     Z0B          Z position of B     =   0.0000000E+00
+
+INPUT PARAMETER >  
+shapeb
+VALUE > 
+2.
+Parameter number:   21     SHAPEB       sphere=1,roche=2    =    2.000000    
+
+INPUT PARAMETER >  
+RB
+VALUE > 
+0.0
+Parameter number:   22     RB           radius of star B    =   0.0000000E+00
+
+INPUT PARAMETER >  
+omegab
+VALUE > 
+2.876
+Parameter number:   26     OMEGAB       potential of B      =    2.876000    
+
+INPUT PARAMETER >  
+!3.637 + 0.5 (q**2/(1+q)) 
+
+INPUT PARAMETER >  
+gb
+VALUE > 
+0.32
+Parameter number:   29     GB           gravity dark. of B  =   0.3200000    
+
+INPUT PARAMETER >  
+limbb
+VALUE > 
+0.66
+Parameter number:   33     LIMBB        limb darkening of B =   0.6600000    
+
+INPUT PARAMETER >  
+tempb
+VALUE > 
+5000.
+Parameter number:   30     TEMPB        medium temp. of B   =    5000.000    
+
+INPUT PARAMETER >  
+bolb
+VALUE > 
+0.
+Parameter number:   31     BOLB         bolometric lum.of B =   0.0000000E+00
+
+INPUT PARAMETER >  
+cordb
+VALUE > 
+3.
+Parameter number:   34     CORDB        arch,cord,tang.seg. =    3.000000    
+
+INPUT PARAMETER >  
+U
+Set on: flag number:    4     U            U-color  band      
+
+INPUT PARAMETER >  
+ulamb1
+VALUE > 
+5300
+Parameter number:   61     ULAMB1       U color lambda 1    =    5300.000    
+
+INPUT PARAMETER >  
+ulamb2
+VALUE > 
+5300
+Parameter number:   62     ULAMB2       U color lambda 2    =    5300.000    
+
+INPUT PARAMETER >  
+!             COARSE 
+
+INPUT PARAMETER >  
+REFLECTION
+Set on: flag number:    9     REFLECTION   Reflection comput. 
+
+INPUT PARAMETER >  
+coarse
+VALUE > 
+1
+Parameter number:  104     COARSE       coarsing factor     =    1.000000    
+
+INPUT PARAMETER >  
+maxiter
+VALUE > 
+1.
+Parameter number:  102     MAXITER      maximum iteration   =    1.000000    
+
+INPUT PARAMETER >  
+!
+
+INPUT PARAMETER >  
+ORBIT
+Set on: flag number:   11     ORBIT        Orbital parameters 
+
+INPUT PARAMETER >  
+I
+VALUE > 
+70.92
+Parameter number:  105     I            incl.of orbit plane =    70.92000    
+
+INPUT PARAMETER >  
+mratio
+VALUE > 
+0.5 
+Parameter number:  106     MRATIO       mass ratio Mb/Ma    =   0.5000000    
+
+INPUT PARAMETER >  
+prec
+VALUE > 
+0.00001
+Parameter number:  108     PREC         Newton-Rapson prec. =   0.1000000E-04
+
+INPUT PARAMETER >  
+!
+
+INPUT PARAMETER >  
+PHASES
+Set on: flag number:   12     PHASES         Sets phases      
+
+INPUT PARAMETER >  
+numphases 
+VALUE > 
+100.
+Parameter number:  111     NUMPHASES    num.of equis.phases =    100.0000    
+
+INPUT PARAMETER >  
+norm
+VALUE > 
+1.
+Parameter number:  113     NORM         Light curve norm.   =    1.000000    
+
+INPUT PARAMETER >  
+GRID
+Set on: flag number:   13     GRID           Sets project.grid
+
+INPUT PARAMETER >  
+numcells
+VALUE > 
+1000. 
+Parameter number:  114     NUMCELLS     num.of grid points  =    1000.000    
+
+INPUT PARAMETER >  
+!
+
+INPUT PARAMETER >  
+OFF
+Set on: flag number:   19     OFF          Set next flags off 
+
+INPUT FLAG >  
+REFLECTION
+Set off: flag number:    9     REFLECTION   Reflection comput. 
+
+INPUT FLAG >  
+DISK
+Set off: flag number:    3     DISK         Disk               
+
+INPUT FLAG >  
+OFF
+Set off: flag number:   19     OFF          Set next flags off 
+
+INPUT FLAG >  
+!
+
+INPUT FLAG >  
+!             printing:
+
+INPUT FLAG >  
+PRINT
+Set on: flag number:   20     PRINT        Output is printed  
+
+INPUT PARAMETER >  
+amount
+VALUE > 
+4
+Parameter number:  117     AMOUNT       Amount of printing  =    4.000000    
+
+INPUT PARAMETER >  
+map
+VALUE > 
+0
+Parameter number:  120     MAP          Map print phas.step =   0.0000000E+00
+
+INPUT PARAMETER >  
+unit 
+VALUE > 
+11
+Parameter number:  119     UNIT         Output on this unit =    11.00000    
+
+INPUT PARAMETER >  
+refl
+VALUE > 
+0 
+Parameter number:  121     REFL         Reflection details  =   0.0000000E+00
+
+INPUT PARAMETER >  
+light
+VALUE > 
+0 
+Parameter number:  122     LIGHT        Light curve details =   0.0000000E+00
+
+INPUT PARAMETER >  
+!
+
+INPUT PARAMETER >  
+plot
+Set on: flag number:   21     PLOT         Plot produced      
+
+INPUT PARAMETER >  
+file
+VALUE > 
+12
+Parameter number:  127     FILE         Output ASCII file   =    12.00000    
+
+INPUT PARAMETER >  
+!
+
+INPUT PARAMETER >  
+GO
+Set on: flag number:   15     GO             Program  runs    
+
+Elapsed time for I/O:                      2.7891          Total:          2.7891    
+
+
+Computed Lagrange points and potential for critical lobes:
+    L1= 0.5707528     omega=  2.875845    
+    L2=  1.582381     omega=  2.577260    
+    L3=-0.8030282     omega=  2.407752    
+
+
+Surface-X axis intersection for object: 1 computed as: 0.5672197      -0.4678943    
+Surface drawing starts from point: 0.5672197    
+
+
+Elapsed time for surface drawing:          15.090          Total:          15.090    
+
+
+Surface-X axis intersection for object: 2 computed as: 0.5742776        1.345321    
+Surface drawing starts from point:  1.345321    
+
+
+Elapsed time for surface drawing:          15.402          Total:          30.492    
+
+
+Elapsed time for color band:              0.89844E-01      Total:         0.89844E-01
+
+
+Elapsed time for color band:              0.14844          Total:         0.23828    
+
+Sub.luce1: phase:    1 elapsed time for grid initialization:   8.167969    
+Sub.luce1: phase:    2 elapsed time for grid initialization:   4.558594    
+Sub.luce1: phase:    3 elapsed time for grid initialization:   2.558594    
+Sub.luce1: phase:    4 elapsed time for grid initialization:  0.8085938    
+Sub.luce1: phase:    5 elapsed time for grid initialization:  0.6210938    
+Sub.luce1: phase:    6 elapsed time for grid initialization:  0.4687500    
+Sub.luce1: phase:    7 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:    8 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:    9 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   10 elapsed time for grid initialization:  0.4687500    
+Sub.luce1: phase:   11 elapsed time for grid initialization:  0.4179688    
+Sub.luce1: phase:   12 elapsed time for grid initialization:  0.4375000    
+Sub.luce1: phase:   13 elapsed time for grid initialization:  0.9882813    
+Sub.luce1: phase:   14 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   15 elapsed time for grid initialization:  0.4414063    
+Sub.luce1: phase:   16 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   17 elapsed time for grid initialization:  0.4335938    
+Sub.luce1: phase:   18 elapsed time for grid initialization:  0.4179688    
+Sub.luce1: phase:   19 elapsed time for grid initialization:  0.4335938    
+Sub.luce1: phase:   20 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   21 elapsed time for grid initialization:  0.4218750    
+Sub.luce1: phase:   22 elapsed time for grid initialization:  0.4375000    
+Sub.luce1: phase:   23 elapsed time for grid initialization:  0.4414063    
+Sub.luce1: phase:   24 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   25 elapsed time for grid initialization:  0.4335938    
+Sub.luce1: phase:   26 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   27 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   28 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   29 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   30 elapsed time for grid initialization:  0.4531250    
+Sub.luce1: phase:   31 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   32 elapsed time for grid initialization:  0.4179688    
+Sub.luce1: phase:   33 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   34 elapsed time for grid initialization:  0.4414063    
+Sub.luce1: phase:   35 elapsed time for grid initialization:  0.4335938    
+Sub.luce1: phase:   36 elapsed time for grid initialization:  0.4531250    
+Sub.luce1: phase:   37 elapsed time for grid initialization:  0.4414063    
+Sub.luce1: phase:   38 elapsed time for grid initialization:  0.4414063    
+Sub.luce1: phase:   39 elapsed time for grid initialization:  0.4179688    
+Sub.luce1: phase:   40 elapsed time for grid initialization:  0.4414063    
+Sub.luce1: phase:   41 elapsed time for grid initialization:  0.4218750    
+Sub.luce1: phase:   42 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   43 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   44 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   45 elapsed time for grid initialization:  0.4179688    
+Sub.luce1: phase:   46 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   47 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   48 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   49 elapsed time for grid initialization:  0.4570313    
+Sub.luce1: phase:   50 elapsed time for grid initialization:  0.5390625    
+Sub.luce1: phase:   51 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   52 elapsed time for grid initialization:  0.4179688    
+Sub.luce1: phase:   53 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   54 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   55 elapsed time for grid initialization:  0.4414063    
+Sub.luce1: phase:   56 elapsed time for grid initialization:  0.5117188    
+Sub.luce1: phase:   57 elapsed time for grid initialization:  0.5000000    
+Sub.luce1: phase:   58 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   59 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   60 elapsed time for grid initialization:  0.4414063    
+Sub.luce1: phase:   61 elapsed time for grid initialization:  0.4375000    
+Sub.luce1: phase:   62 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   63 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   64 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   65 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   66 elapsed time for grid initialization:  0.4726563    
+Sub.luce1: phase:   67 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   68 elapsed time for grid initialization:  0.6406250    
+Sub.luce1: phase:   69 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   70 elapsed time for grid initialization:  0.4882813    
+Sub.luce1: phase:   71 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   72 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   73 elapsed time for grid initialization:  0.5312500    
+Sub.luce1: phase:   74 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   75 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   76 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   77 elapsed time for grid initialization:  0.5390625    
+Sub.luce1: phase:   78 elapsed time for grid initialization:  0.4218750    
+Sub.luce1: phase:   79 elapsed time for grid initialization:  0.4179688    
+Sub.luce1: phase:   80 elapsed time for grid initialization:  0.4179688    
+Sub.luce1: phase:   81 elapsed time for grid initialization:  0.4218750    
+Sub.luce1: phase:   82 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   83 elapsed time for grid initialization:  0.4179688    
+Sub.luce1: phase:   84 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   85 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   86 elapsed time for grid initialization:  0.4687500    
+Sub.luce1: phase:   87 elapsed time for grid initialization:  0.4218750    
+Sub.luce1: phase:   88 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   89 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   90 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   91 elapsed time for grid initialization:  0.4179688    
+Sub.luce1: phase:   92 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   93 elapsed time for grid initialization:  0.4218750    
+Sub.luce1: phase:   94 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   95 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   96 elapsed time for grid initialization:  0.5898438    
+Sub.luce1: phase:   97 elapsed time for grid initialization:  0.4218750    
+Sub.luce1: phase:   98 elapsed time for grid initialization:  0.4296875    
+Sub.luce1: phase:   99 elapsed time for grid initialization:  0.4726563    
+Sub.luce1: phase:  100 elapsed time for grid initialization:  0.4296875    
+
+Elapsed time for received ligth :          1036.9          Total:          1036.9    
+
+
+
+
+                                                 -----------------------------
+                                                  Ligth Curve Analysis Results
+                                                 -----------------------------
+
+
+
+
+
+OPTION SUMMARY:
+STARA      Star A                 YES
+STARB      Star B                 YES
+DISK       Disk                   NO 
+U          U-color  band          YES
+B          B-color  band          NO 
+V          V-color  band          NO 
+R          R-color  band          NO 
+I          I-color  band          NO 
+REFLECTION Reflection comput.     NO 
+ZEROREFL   Zero refl. source      NO 
+
+
+ORBITAL AND GRID PARAMETERS:
+I          incl.of orbit plane       70.92000    
+MRATIO     mass ratio Mb/Ma         0.5000000    
+ECC        orbit eccentricity       0.0000000E+00
+PREC       Newton-Rapson prec.      0.1000000E-04
+NUMPHASES  num.of equis.phases       100.0000    
+PHASEUNIT  unit for input phas      0.0000000E+00
+NORM       Light curve norm.         1.000000    
+NUMCELLS   num.of grid points        1000.000    
+R4PREC     sin,cos precision        0.1000000E-04
+NULL       Unused                   0.0000000E+00
+
+INPUT PARAMETERS FOR COLOUR BAND:  4
+ ULAMB1       U color lambda 1        5300.000    
+ ULAMB2       U color lambda 2        5300.000    
+ ULUM_A       frac. U lumin.for A    0.0000000E+00
+ ULUM_B       frac. U lumin.for B    0.0000000E+00
+ ULUM_C       frac. U lumin.for C    0.0000000E+00
+
+
+PRINTED OUTPUT PARAMETERS:
+ AMOUNT       Amount of printing      4.000000    
+ SCREEN       Output on screen        1.000000    
+ UNIT         Output on this unit     11.00000    
+ MAP          Map print phas.step    0.0000000E+00
+ REFL         Reflection details     0.0000000E+00
+ LIGHT        Light curve details    0.0000000E+00
+
+
+PLOTTING OUTPUT PARAMETERS:
+ AMOUNT       Amount of printing      10.00000    
+ SCREEN       Output on screen        1.000000    
+ UNIT         Output on this unit     11.00000    
+ MAP          Map plot phase step     1.000000    
+ FILE         Output ASCII file       12.00000    
+
+INPUT PARAMETERS FOR OBJECT NUMBER:  1
+ SHAPEA       sphere=1,roche=2        2.000000    
+ RA           radius of star A       0.0000000E+00
+ X0A          X position of A        0.0000000E+00
+ Y0A          Y position of A        0.0000000E+00
+ Z0A          Z position of A        0.0000000E+00
+ OMEGAA       potential of A          2.876000    
+ MESHA        num. of theta mesh      111.0000    
+ NPHIA        unused                 0.0000000E+00
+ GA           gravity dark. of A     0.3200000    
+ TEMPA        medium temp. of A       5000.000    
+ BOLA         bolometric lum.of A    0.0000000E+00
+ ALBA         bolometric albedo A     1.000000    
+ LIMBA        limb darkening of A    0.6600000    
+ CORDA        arch,cord,tang.seg.     3.000000    
+ RIA          disk inner radius      0.0000000E+00
+ HA           disk height at R       0.0000000E+00
+ HIA          disk height at RI      0.0000000E+00
+ INCLINA      ang.z-z orbit.plane    0.0000000E+00
+ ROTATEA      ang.x-x orbit plane    0.0000000E+00
+ INNERA       unused                 0.0000000E+00
+
+INPUT PARAMETERS FOR OBJECT NUMBER:  2
+ SHAPEB       sphere=1,roche=2        2.000000    
+ RB           radius of star B       0.0000000E+00
+ X0B          X position of B         1.000000    
+ Y0B          Y position of B        0.0000000E+00
+ Z0B          Z position of B        0.0000000E+00
+ OMEGAB       potential of B          2.876000    
+ MESHB        num. of theta mesh      111.0000    
+ NPHIB        unused                 0.0000000E+00
+ GB           gravity dark. of B     0.3200000    
+ TEMPB        medium temp. of B       5000.000    
+ BOLB         bolometric lum.of B    0.0000000E+00
+ ALBB         bolometric albedo B     1.000000    
+ LIMBB        limb darkening of B    0.6600000    
+ CORDB        arch,cord,tang.seg.     3.000000    
+ RIB          disk inner radius      0.0000000E+00
+ HB           disk height at R       0.0000000E+00
+ HIB          disk height at RI      0.0000000E+00
+ INCLINB      ang.z-z orbit.plane    0.0000000E+00
+ ROTATEB      ang.x-x orbit plane    0.0000000E+00
+ INNERB       unused                 0.0000000E+00
+
+ROCHE MODEL DATA:
+ L1,L2,L3 : lagrange points x position:  0.5707528       1.582381     -0.8030282    
+ potential for surfaces at L1,L2,L3   :   2.875845       2.577260       2.407752    
+ XA1,XA2  : intersection star A-x axis:  0.5672197     -0.4678943    
+ XB1,XB2  : intersection star B-x axis:  0.5742776       1.345321    
+ approx. y dimension for critical lobe:  0.4371542      0.3117651    
+
+
+Obj. ,pole surf.el.R ,       X              Y              Z              GX             GY             GZ                T
+ 1   0.4138879      0.4717969E-01  0.5925476E-02  0.4111474       1.000000      0.0000000E+00  0.0000000E+00   3565.010    
+ 2    1.010642      0.9658665      0.4286953E-02  0.2974563      0.8713560      0.4906513      0.0000000E+00   3960.520    
+
+RUN PARAMETERS:
+
+          Fine grid surface elements  :     30708           Max allowed :    200000
+                                                For object 1:     15354
+                                                For object 2:     15354
+                                                For object 3:         0
+
+          Coarse grid surface elements:     30708           Max allowed :     50000 Coarsing factor:    1
+                                                For object 1:     15354
+                                                For object 2:     15354
+                                                For object 3:         0
+          Reflection paths:         0           Max allowed :    250000           Iterations done:    0
+
+
+
+ BOLOMETRIC LUMINOSITY FOR EACH OBJECT :
+ object number, total surf.area, emitted lumin.,reflected lum., total lum., input lum. value, lum.norm.factor
+       1          2.368121      0.2485914E+11  0.0000000E+00  0.2485914E+11  0.0000000E+00  0.0000000E+00
+       2          1.262773      0.1315058E+11  0.0000000E+00  0.1315058E+11  0.0000000E+00  0.0000000E+00
+
+
+Objectc,   U-band lum., B-band lum., V-band lum., R-band lum., I-band lum.
+   1      11067.96     .0000000E+00 .0000000E+00 .0000000E+00 .0000000E+00
+   2      11067.96     .0000000E+00 .0000000E+00 .0000000E+00 .0000000E+00
+   3      .0000000E+00 .0000000E+00 .0000000E+00 .0000000E+00 .0000000E+00
+
+
+
+LIGHT CURVE PRODUCED:                    (grid used:1000 *1000     ; step: 0.29347E-02   from: -1.4674          to:  1.4674     )
+    Phase                       bol.lum.     from star A   from star B   from disk
+  1 0.00000E+00  0.00000E+00  0.706791      0.406590      0.300201      0.000000E+00
+  2 0.62832E-01  0.10000E-01  0.710643      0.410308      0.300335      0.000000E+00
+  3 0.12566      0.20000E-01  0.720942      0.420204      0.300737      0.000000E+00
+  4 0.18850      0.30000E-01  0.737377      0.435973      0.301405      0.000000E+00
+  5 0.25133      0.40000E-01  0.756291      0.453956      0.302335      0.000000E+00
+  6 0.31416      0.50000E-01  0.777438      0.473916      0.303522      0.000000E+00
+  7 0.37699      0.60000E-01  0.799318      0.494356      0.304962      0.000000E+00
+  8 0.43982      0.70000E-01  0.821588      0.514940      0.306648      0.000000E+00
+  9 0.50265      0.80000E-01  0.843484      0.534911      0.308573      0.000000E+00
+ 10 0.56549      0.90000E-01  0.864418      0.553693      0.310725      0.000000E+00
+ 11 0.62832      0.10000      0.882917      0.569818      0.313099      0.000000E+00
+ 12 0.69115      0.11000      0.899240      0.583557      0.315684      0.000000E+00
+ 13 0.75398      0.12000      0.913368      0.594903      0.318465      0.000000E+00
+ 14 0.81681      0.13000      0.925860      0.604428      0.321432      0.000000E+00
+ 15 0.87965      0.14000      0.936893      0.612327      0.324566      0.000000E+00
+ 16 0.94248      0.15000      0.946804      0.618960      0.327845      0.000000E+00
+ 17  1.0053      0.16000      0.956139      0.624916      0.331223      0.000000E+00
+ 18  1.0681      0.17000      0.965069      0.630453      0.334616      0.000000E+00
+ 19  1.1310      0.18000      0.973278      0.635342      0.337936      0.000000E+00
+ 20  1.1938      0.19000      0.980596      0.639496      0.341101      0.000000E+00
+ 21  1.2566      0.20000      0.986869      0.642825      0.344044      0.000000E+00
+ 22  1.3195      0.21000      0.992002      0.645305      0.346696      0.000000E+00
+ 23  1.3823      0.22000      0.995916      0.646923      0.348994      0.000000E+00
+ 24  1.4451      0.23000      0.998558      0.647683      0.350875      0.000000E+00
+ 25  1.5080      0.24000      0.999920      0.647630      0.352290      0.000000E+00
+ 26  1.5708      0.25000       1.00000      0.646801      0.353199      0.000000E+00
+ 27  1.6336      0.26000      0.998801      0.645247      0.353554      0.000000E+00
+ 28  1.6965      0.27000      0.996381      0.643050      0.353331      0.000000E+00
+ 29  1.7593      0.28000      0.992799      0.640285      0.352514      0.000000E+00
+ 30  1.8221      0.29000      0.988132      0.637047      0.351085      0.000000E+00
+ 31  1.8850      0.30000      0.982474      0.633423      0.349051      0.000000E+00
+ 32  1.9478      0.31000      0.975938      0.629518      0.346420      0.000000E+00
+ 33  2.0106      0.32000      0.968659      0.625445      0.343214      0.000000E+00
+ 34  2.0735      0.33000      0.960810      0.621315      0.339495      0.000000E+00
+ 35  2.1363      0.34000      0.952557      0.617252      0.335305      0.000000E+00
+ 36  2.1991      0.35000      0.944181      0.613424      0.330757      0.000000E+00
+ 37  2.2619      0.36000      0.935523      0.609888      0.325635      0.000000E+00
+ 38  2.3248      0.37000      0.925887      0.606628      0.319259      0.000000E+00
+ 39  2.3876      0.38000      0.914734      0.603643      0.311091      0.000000E+00
+ 40  2.4504      0.39000      0.901574      0.600916      0.300658      0.000000E+00
+ 41  2.5133      0.40000      0.886028      0.598442      0.287585      0.000000E+00
+ 42  2.5761      0.41000      0.868229      0.596218      0.272011      0.000000E+00
+ 43  2.6389      0.42000      0.848059      0.594235      0.253825      0.000000E+00
+ 44  2.7018      0.43000      0.825613      0.592494      0.233118      0.000000E+00
+ 45  2.7646      0.44000      0.802054      0.590987      0.211066      0.000000E+00
+ 46  2.8274      0.45000      0.778506      0.589720      0.188786      0.000000E+00
+ 47  2.8903      0.46000      0.756779      0.588681      0.168098      0.000000E+00
+ 48  2.9531      0.47000      0.738736      0.587875      0.150861      0.000000E+00
+ 49  3.0159      0.48000      0.723859      0.587300      0.136559      0.000000E+00
+ 50  3.0788      0.49000      0.713884      0.586956      0.126927      0.000000E+00
+ 51  3.1416      0.50000      0.710648      0.586842      0.123806      0.000000E+00
+ 52  3.2044      0.51000      0.713989      0.586956      0.127033      0.000000E+00
+ 53  3.2673      0.52000      0.723726      0.587301      0.136425      0.000000E+00
+ 54  3.3301      0.53000      0.738300      0.587875      0.150425      0.000000E+00
+ 55  3.3929      0.54000      0.756560      0.588681      0.167879      0.000000E+00
+ 56  3.4558      0.55000      0.778144      0.589720      0.188424      0.000000E+00
+ 57  3.5186      0.56000      0.801613      0.590988      0.210626      0.000000E+00
+ 58  3.5814      0.57000      0.825342      0.592494      0.232847      0.000000E+00
+ 59  3.6442      0.58000      0.847714      0.594235      0.253479      0.000000E+00
+ 60  3.7071      0.59000      0.868067      0.596217      0.271850      0.000000E+00
+ 61  3.7699      0.60000      0.886007      0.598442      0.287565      0.000000E+00
+ 62  3.8327      0.61000      0.901494      0.600915      0.300580      0.000000E+00
+ 63  3.8956      0.62000      0.914719      0.603643      0.311076      0.000000E+00
+ 64  3.9584      0.63000      0.925848      0.606630      0.319219      0.000000E+00
+ 65  4.0212      0.64000      0.935526      0.609888      0.325638      0.000000E+00
+ 66  4.0841      0.65000      0.944184      0.613421      0.330763      0.000000E+00
+ 67  4.1469      0.66000      0.952552      0.617254      0.335297      0.000000E+00
+ 68  4.2097      0.67000      0.960803      0.621313      0.339490      0.000000E+00
+ 69  4.2726      0.68000      0.968666      0.625445      0.343222      0.000000E+00
+ 70  4.3354      0.69000      0.975934      0.629519      0.346415      0.000000E+00
+ 71  4.3982      0.70000      0.982472      0.633422      0.349050      0.000000E+00
+ 72  4.4611      0.71000      0.988132      0.637045      0.351087      0.000000E+00
+ 73  4.5239      0.72000      0.992800      0.640286      0.352514      0.000000E+00
+ 74  4.5867      0.73000      0.996378      0.643045      0.353333      0.000000E+00
+ 75  4.6496      0.74000      0.998799      0.645247      0.353552      0.000000E+00
+ 76  4.7124      0.75000       1.00000      0.646801      0.353199      0.000000E+00
+ 77  4.7752      0.76000      0.999917      0.647627      0.352290      0.000000E+00
+ 78  4.8381      0.77000      0.998558      0.647687      0.350871      0.000000E+00
+ 79  4.9009      0.78000      0.995915      0.646922      0.348993      0.000000E+00
+ 80  4.9637      0.79000      0.992002      0.645308      0.346694      0.000000E+00
+ 81  5.0265      0.80000      0.986870      0.642826      0.344044      0.000000E+00
+ 82  5.0894      0.81000      0.980588      0.639487      0.341102      0.000000E+00
+ 83  5.1522      0.82000      0.973270      0.635336      0.337934      0.000000E+00
+ 84  5.2150      0.83000      0.965064      0.630448      0.334616      0.000000E+00
+ 85  5.2779      0.84000      0.956135      0.624911      0.331224      0.000000E+00
+ 86  5.3407      0.85000      0.946790      0.618946      0.327844      0.000000E+00
+ 87  5.4035      0.86000      0.936893      0.612328      0.324565      0.000000E+00
+ 88  5.4664      0.87000      0.925735      0.604304      0.321432      0.000000E+00
+ 89  5.5292      0.88000      0.913237      0.594772      0.318465      0.000000E+00
+ 90  5.5920      0.89000      0.898948      0.583264      0.315684      0.000000E+00
+ 91  5.6549      0.90000      0.882531      0.569432      0.313099      0.000000E+00
+ 92  5.7177      0.91000      0.863851      0.553125      0.310725      0.000000E+00
+ 93  5.7805      0.92000      0.842906      0.534335      0.308571      0.000000E+00
+ 94  5.8434      0.93000      0.820920      0.514272      0.306648      0.000000E+00
+ 95  5.9062      0.94000      0.798523      0.493561      0.304962      0.000000E+00
+ 96  5.9690      0.95000      0.776806      0.473283      0.303522      0.000000E+00
+ 97  6.0319      0.96000      0.755854      0.453519      0.302335      0.000000E+00
+ 98  6.0947      0.97000      0.736788      0.435384      0.301404      0.000000E+00
+ 99  6.1575      0.98000      0.720845      0.420108      0.300737      0.000000E+00
+100  6.2204      0.99000      0.710454      0.410118      0.300335      0.000000E+00
+ 1   0.4138879      0.4717969E-01  0.5925476E-02  0.4111474       1.000000      0.0000000E+00  0.0000000E+00   3565.010    
+ 2    1.010642      0.9658665      0.4286953E-02  0.2974563      0.8713560      0.4906513      0.0000000E+00   3960.520    
+
+Elapsed time for I/O:                      4.2773          Total:          7.0664    
+
+
+Light curve written on unit:12 Num.phases:     100 Num. of colors: 5
+
+Elapsed time for plot:                      1.4023          Total:          1.4023    
+
+
+INPUT FLAG >  
+STOP
+Set on: flag number:   16     STOP           Program stops    
+
+
+
+Total elapsed time for I/O:                        7.0664    
+Total elapsed time for plotting:                   1.4023    
+Total elapsed time for surface drawing:            30.492    
+Total elapsed time for reflection     :           0.00000E+00
+Total elapsed time for colour band flux:          0.23828    
+Total elapsed time for light to observer:          1036.9    
+Total elapsed time for this run:                   1076.1    
+
+
+
+FORTRAN STOP
+$EXIT
+  MARC         job terminated at  5-MAR-1992 12:23:16.31
+
+  Accounting information:
+  Buffered I/O count:           94      Peak working set size: 14982
+  Direct I/O count:            203      Peak page file size:   93977
+  Page faults:               30200      Mounted volumes:           0
+  Charged CPU time:     0 00:16:46.30   Elapsed time:     0 00:18:10.30
diff --git a/codemeta.json b/codemeta.json
new file mode 100644
index 0000000..6b3e28b
--- /dev/null
+++ b/codemeta.json
@@ -0,0 +1,36 @@
+{
+  "@context": "https://doi.org/10.5063/schema/codemeta-2.0",
+  "@type": "SoftwareSourceCode",
+  "name": "cbs",
+  "description": "A VAX/VMS FORTRAN program for close binary system light curve simulation."
+  "codeRepository": "http://legacy.helldragon.eu/gitweb/cbs.git",
+  "downloadUrl": "git://legacy.helldragon.eu/cbs.git",  
+  "programmingLanguage": "VAX FORTRAN",
+  "operatingSystem": "VAX-VMS"
+  "license": "Public domain",
+  "dateCreated":"1993-12-01",
+  "datePublished":"2019-12-26",
+  "developmentStatus": "Unsupported",
+  "creativeWorkStatus": "Legacy software"
+  "keywords": [
+    "cbs",
+    "close binary sistem",
+    "photometry",
+    "roche lobes",
+  ],  
+  "author": [
+    {
+      "@type": "Person",
+      "givenName": "Marcello",
+      "familyName": "Galli",
+      "email": "marcello.galli@tiscali.it",
+      "web":"http://www.helldragon.eu",
+      "@id": "https://orcid.org/0000-0002-9135-3228"
+    },      
+    {
+      "@type": "Person",
+      "givenName": "Loretta",
+      "familyName": "Solmi"
+    }    
+  ]
+}
-- 
2.39.2