root / TrouNoir / trou_noir_MyFloat.c @ 233
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/*
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Programme original realise en Fortran 77 en mars 1994
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pour les Travaux Pratiques de Modelisation Numerique
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DEA d'astrophysique et techniques spatiales de Meudon
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par Herve Aussel et Emmanuel Quemener
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Conversion en C par Emmanuel Quemener en aout 1997
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Modification par Emmanuel Quemener en aout 2019
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Remerciements a :
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- Herve Aussel pour sa procedure sur le spectre de corps noir
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- Didier Pelat pour l'aide lors de ce travail
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- Jean-Pierre Luminet pour son article de 1979
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- Le Numerical Recipies pour ses recettes de calcul
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- Luc Blanchet pour sa disponibilite lors de mes interrogations en RG
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Compilation sous gcc ( Compilateur GNU sous Linux ) :
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gcc -O2 -o trou_noir trou_noir.c -lm
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*/
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#include <stdio.h> |
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#include <math.h> |
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#include <stdlib.h> |
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#include <string.h> |
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#include <sys/time.h> |
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#define nbr 256 /* Nombre de colonnes du spectre */ |
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#define PI 3.14159265359 |
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#define TRACKPOINTS 2048 |
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#if TYPE == FP32
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#define MYFLOAT float |
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#else
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#define MYFLOAT double |
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#endif
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MYFLOAT atanp(MYFLOAT x,MYFLOAT y) |
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{
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MYFLOAT angle; |
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angle=atan2(y,x); |
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if (angle<0) |
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{
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angle+=2*PI;
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} |
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return angle;
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} |
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MYFLOAT f(MYFLOAT v) |
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{
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return v;
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} |
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MYFLOAT g(MYFLOAT u,MYFLOAT m,MYFLOAT b) |
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{
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return (3.*m/b*pow(u,2)-u); |
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} |
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void calcul(MYFLOAT *us,MYFLOAT *vs,MYFLOAT up,MYFLOAT vp,
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MYFLOAT h,MYFLOAT m,MYFLOAT b) |
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{
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MYFLOAT c[4],d[4]; |
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c[0]=h*f(vp);
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c[1]=h*f(vp+c[0]/2.); |
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c[2]=h*f(vp+c[1]/2.); |
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c[3]=h*f(vp+c[2]); |
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d[0]=h*g(up,m,b);
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d[1]=h*g(up+d[0]/2.,m,b); |
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d[2]=h*g(up+d[1]/2.,m,b); |
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d[3]=h*g(up+d[2],m,b); |
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*us=up+(c[0]+2.*c[1]+2.*c[2]+c[3])/6.; |
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*vs=vp+(d[0]+2.*d[1]+2.*d[2]+d[3])/6.; |
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} |
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void rungekutta(MYFLOAT *ps,MYFLOAT *us,MYFLOAT *vs,
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MYFLOAT pp,MYFLOAT up,MYFLOAT vp, |
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MYFLOAT h,MYFLOAT m,MYFLOAT b) |
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{
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calcul(us,vs,up,vp,h,m,b); |
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*ps=pp+h; |
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} |
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MYFLOAT decalage_spectral(MYFLOAT r,MYFLOAT b,MYFLOAT phi, |
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MYFLOAT tho,MYFLOAT m) |
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{
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return (sqrt(1-3*m/r)/(1+sqrt(m/pow(r,3))*b*sin(tho)*sin(phi))); |
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} |
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MYFLOAT spectre(MYFLOAT rf,MYFLOAT q,MYFLOAT b,MYFLOAT db, |
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MYFLOAT h,MYFLOAT r,MYFLOAT m,MYFLOAT bss) |
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{
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MYFLOAT flx; |
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flx=exp(q*log(r/m))*pow(rf,4)*b*db*h;
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return(flx);
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} |
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MYFLOAT spectre_cn(MYFLOAT rf,MYFLOAT b,MYFLOAT db, |
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MYFLOAT h,MYFLOAT r,MYFLOAT m,MYFLOAT bss) |
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{
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MYFLOAT flx; |
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MYFLOAT nu_rec,nu_em,qu,temp_em,flux_int; |
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int fi,posfreq;
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#define planck 6.62e-34 |
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#define k 1.38e-23 |
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#define c2 9.e16 |
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#define temp 3.e7 |
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#define m_point 1. |
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#define lplanck (log(6.62)-34.*log(10.)) |
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#define lk (log(1.38)-23.*log(10.)) |
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#define lc2 (log(9.)+16.*log(10.)) |
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MYFLOAT v=1.-3./r; |
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qu=1./sqrt((1.-3./r)*r)*(sqrt(r)-sqrt(6.)+sqrt(3.)/2.*log((sqrt(r)+sqrt(3.))/(sqrt(r)-sqrt(3.))* 0.17157287525380988 )); |
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temp_em=temp*sqrt(m)*exp(0.25*log(m_point)-0.75*log(r)-0.125*log(v)+0.25*log(fabs(qu))); |
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flux_int=0.;
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flx=0.;
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for (fi=0;fi<nbr;fi++) |
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{
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nu_em=bss*(MYFLOAT)fi/(MYFLOAT)nbr; |
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nu_rec=nu_em*rf; |
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posfreq=(int)(nu_rec*(MYFLOAT)nbr/bss);
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if ((posfreq>0)&&(posfreq<nbr)) |
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{
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flux_int=2.*planck/c2*pow(nu_em,3)/(exp(planck*nu_em/(k*temp_em))-1.)*exp(3.*log(rf))*b*db*h; |
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flx+=flux_int; |
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} |
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} |
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return((MYFLOAT)flx);
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} |
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void impact(MYFLOAT d,MYFLOAT phi,int dim,MYFLOAT r,MYFLOAT b,MYFLOAT tho,MYFLOAT m, |
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MYFLOAT **zp,MYFLOAT **fp, |
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MYFLOAT q,MYFLOAT db, |
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MYFLOAT h,MYFLOAT bss,int raie)
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{
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MYFLOAT xe,ye; |
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int xi,yi;
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MYFLOAT flx,rf; |
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xe=d*sin(phi); |
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ye=-d*cos(phi); |
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xi=(int)xe+dim/2; |
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yi=(int)ye+dim/2; |
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rf=decalage_spectral(r,b,phi,tho,m); |
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if (raie==0) |
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{
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bss=1.e19;
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flx=spectre_cn(rf,b,db,h,r,m,bss); |
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} |
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else
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{
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bss=2.;
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flx=spectre(rf,q,b,db,h,r,m,bss); |
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} |
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if (zp[xi][yi]==0.) |
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{
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zp[xi][yi]=1./rf;
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} |
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if (fp[xi][yi]==0.) |
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{
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fp[xi][yi]=flx; |
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} |
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} |
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void sauvegarde_pgm(char nom[24],unsigned int **image,int dim) |
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{
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FILE *sortie; |
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unsigned long i,j; |
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sortie=fopen(nom,"w");
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fprintf(sortie,"P5\n");
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fprintf(sortie,"%i %i\n",dim,dim);
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fprintf(sortie,"255\n");
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for (j=0;j<dim;j++) for (i=0;i<dim;i++) |
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{
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fputc(image[i][j],sortie); |
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} |
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fclose(sortie); |
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} |
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int main(int argc,char *argv[]) |
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{
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MYFLOAT m,rs,ri,re,tho; |
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int q;
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MYFLOAT bss,stp; |
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int nmx,dim;
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MYFLOAT d,bmx,db,b,h; |
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MYFLOAT up,vp,pp; |
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MYFLOAT us,vs,ps; |
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MYFLOAT rp[TRACKPOINTS]; |
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MYFLOAT **zp,**fp; |
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unsigned int **izp,**ifp; |
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MYFLOAT zmx,fmx,zen,fen; |
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MYFLOAT flux_tot,impc_tot; |
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MYFLOAT phi,thi,thx,phd,php,nr,r; |
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int ni,ii,i,imx,j,n,tst,dist,raie,pc,fcl,zcl;
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MYFLOAT nh; |
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if (argc==2) |
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{
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if (strcmp(argv[1],"-aide")==0) |
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{
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printf("\nSimulation d'un disque d'accretion autour d'un trou noir\n");
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printf("\nParametres a definir :\n\n");
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printf(" 1) Dimension de l'Image\n");
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printf(" 2) Masse relative du trou noir\n");
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printf(" 3) Dimension du disque exterieur\n");
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printf(" 4) Inclinaison par rapport au disque (en degres)\n");
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printf(" 5) Rayonnement de disque MONOCHROMATIQUE ou CORPS_NOIR\n");
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printf(" 6) Impression des images NEGATIVE ou POSITIVE\n");
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printf(" 7) Nom de l'image des Flux\n");
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printf(" 8) Nom de l'image des decalages spectraux\n");
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printf("\nSi aucun parametre defini, parametres par defaut :\n\n");
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printf(" 1) Dimension de l'image : 1024 pixels de cote\n");
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printf(" 2) Masse relative du trou noir : 1\n");
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printf(" 3) Dimension du disque exterieur : 12 \n");
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printf(" 4) Inclinaison par rapport au disque (en degres) : 10\n");
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printf(" 5) Rayonnement de disque CORPS_NOIR\n");
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printf(" 6) Impression des images NEGATIVE ou POSITIVE\n");
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printf(" 7) Nom de l'image des flux : flux.pgm\n");
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printf(" 8) Nom de l'image des z : z.pgm\n");
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} |
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} |
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if (argc==9) |
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{
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printf("# Utilisation les valeurs definies par l'utilisateur\n");
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dim=atoi(argv[1]);
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m=atof(argv[2]);
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re=atof(argv[3]);
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tho=PI/180.*(90-atof(argv[4])); |
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rs=2.*m;
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ri=3.*rs;
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if (strcmp(argv[5],"CORPS_NOIR")==0) |
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{
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raie=0;
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} |
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else
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{
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raie=1;
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} |
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} |
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else
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{
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printf("# Utilisation les valeurs par defaut\n");
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dim=1024;
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m=1.;
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rs=2.*m;
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ri=3.*rs;
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re=12.; |
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tho=PI/180.*80; |
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// Corps noir
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raie=0;
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} |
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if (raie==1) |
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{
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bss=2.;
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q=-2;
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} |
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else
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{
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bss=1.e19;
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q=-0.75; |
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} |
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printf("# Dimension de l'image : %i\n",dim);
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printf("# Masse : %f\n",m);
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printf("# Rayon singularite : %f\n",rs);
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printf("# Rayon interne : %f\n",ri);
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printf("# Rayon externe : %f\n",re);
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printf("# Inclinaison a la normale en radian : %f\n",tho);
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zp=(MYFLOAT**)calloc(dim,sizeof(MYFLOAT*));
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zp[0]=(MYFLOAT*)calloc(dim*dim,sizeof(MYFLOAT)); |
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fp=(MYFLOAT**)calloc(dim,sizeof(MYFLOAT*));
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fp[0]=(MYFLOAT*)calloc(dim*dim,sizeof(MYFLOAT)); |
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izp=(unsigned int**)calloc(dim,sizeof(unsigned int*)); |
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izp[0]=(unsigned int*)calloc(dim*dim,sizeof(unsigned int)); |
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ifp=(unsigned int**)calloc(dim,sizeof(unsigned int*)); |
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ifp[0]=(unsigned int*)calloc(dim*dim,sizeof(unsigned int)); |
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for (i=1;i<dim;i++) |
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{
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zp[i]=zp[i-1]+dim;
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fp[i]=fp[i-1]+dim;
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izp[i]=izp[i-1]+dim;
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ifp[i]=ifp[i-1]+dim;
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} |
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nmx=dim; |
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stp=dim/(2.*nmx);
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bmx=1.25*re; |
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b=0.;
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pc=0;
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|
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struct timeval tv1,tv2;
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struct timezone tz;
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// Set start timer
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gettimeofday(&tv1, &tz); |
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for (n=1;n<=nmx;n++) |
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{
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h=4.*PI/(MYFLOAT)TRACKPOINTS;
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d=stp*n; |
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db=bmx/(MYFLOAT)nmx; |
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b=db*(MYFLOAT)n; |
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up=0.;
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vp=1.;
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pp=0.;
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nh=1;
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rungekutta(&ps,&us,&vs,pp,up,vp,h,m,b); |
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rp[(int)nh]=fabs(b/us);
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do
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{
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nh++; |
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pp=ps; |
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up=us; |
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vp=vs; |
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rungekutta(&ps,&us,&vs,pp,up,vp,h,m,b); |
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rp[(int)nh]=b/us;
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} while ((rp[(int)nh]>=rs)&&(rp[(int)nh]<=rp[1])); |
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|
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for (i=nh+1;i<TRACKPOINTS;i++) |
| 372 |
{
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rp[i]=0.;
|
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} |
| 375 |
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imx=(int)(8*d); |
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for (i=0;i<=imx;i++) |
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{
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phi=2.*PI/(MYFLOAT)imx*(MYFLOAT)i;
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phd=atanp(cos(phi)*sin(tho),cos(tho)); |
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phd=fmod(phd,PI); |
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ii=0;
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tst=0;
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|
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do
|
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{
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php=phd+(MYFLOAT)ii*PI; |
| 389 |
nr=php/h; |
| 390 |
ni=(int)nr;
|
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|
| 392 |
if ((MYFLOAT)ni<nh)
|
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{
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| 394 |
r=(rp[ni+1]-rp[ni])*(nr-ni*1.)+rp[ni]; |
| 395 |
} |
| 396 |
else
|
| 397 |
{
|
| 398 |
r=rp[ni]; |
| 399 |
} |
| 400 |
|
| 401 |
if ((r<=re)&&(r>=ri))
|
| 402 |
{
|
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tst=1;
|
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impact(d,phi,dim,r,b,tho,m,zp,fp,q,db,h,bss,raie); |
| 405 |
} |
| 406 |
|
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ii++; |
| 408 |
} while ((ii<=2)&&(tst==0)); |
| 409 |
} |
| 410 |
} |
| 411 |
|
| 412 |
// Set stop timer
|
| 413 |
gettimeofday(&tv2, &tz); |
| 414 |
|
| 415 |
double elapsed=(double)((tv2.tv_sec-tv1.tv_sec) * 1000000L + |
| 416 |
(tv2.tv_usec-tv1.tv_usec))/1000000;
|
| 417 |
|
| 418 |
fmx=fp[0][0]; |
| 419 |
zmx=zp[0][0]; |
| 420 |
|
| 421 |
int zimx=0,zjmx=0,fimx=0,fjmx=0; |
| 422 |
|
| 423 |
for (i=0;i<dim;i++) for (j=0;j<dim;j++) |
| 424 |
{
|
| 425 |
if (fmx<fp[i][j])
|
| 426 |
{
|
| 427 |
fimx=i; |
| 428 |
fjmx=j; |
| 429 |
fmx=fp[i][j]; |
| 430 |
} |
| 431 |
|
| 432 |
if (zmx<zp[i][j])
|
| 433 |
{
|
| 434 |
zimx=i; |
| 435 |
zjmx=j; |
| 436 |
zmx=zp[i][j]; |
| 437 |
} |
| 438 |
} |
| 439 |
|
| 440 |
printf("\nElapsed Time : %lf",(double)elapsed); |
| 441 |
printf("\nZ max @(%i,%i) : %f",zimx,zjmx,zmx);
|
| 442 |
printf("\nFlux max @(%i,%i) : %f\n\n",fimx,fjmx,fmx);
|
| 443 |
|
| 444 |
for (i=0;i<dim;i++) for (j=0;j<dim;j++) |
| 445 |
{
|
| 446 |
zcl=(int)(255/zmx*zp[i][dim-1-j]); |
| 447 |
fcl=(int)(255/fmx*fp[i][dim-1-j]); |
| 448 |
|
| 449 |
if (strcmp(argv[6],"NEGATIVE")==0) |
| 450 |
{
|
| 451 |
if (zcl>255) |
| 452 |
{
|
| 453 |
izp[i][j]=0;
|
| 454 |
} |
| 455 |
else
|
| 456 |
{
|
| 457 |
izp[i][j]=255-zcl;
|
| 458 |
} |
| 459 |
|
| 460 |
if (fcl>255) |
| 461 |
{
|
| 462 |
ifp[i][j]=0;
|
| 463 |
} |
| 464 |
else
|
| 465 |
{
|
| 466 |
ifp[i][j]=255-fcl;
|
| 467 |
} |
| 468 |
|
| 469 |
} |
| 470 |
else
|
| 471 |
{
|
| 472 |
if (zcl>255) |
| 473 |
{
|
| 474 |
izp[i][j]=255;
|
| 475 |
} |
| 476 |
else
|
| 477 |
{
|
| 478 |
izp[i][j]=zcl; |
| 479 |
} |
| 480 |
|
| 481 |
if (fcl>255) |
| 482 |
{
|
| 483 |
ifp[i][j]=255;
|
| 484 |
} |
| 485 |
else
|
| 486 |
{
|
| 487 |
ifp[i][j]=fcl; |
| 488 |
} |
| 489 |
|
| 490 |
} |
| 491 |
|
| 492 |
} |
| 493 |
|
| 494 |
if (argc==9) |
| 495 |
{
|
| 496 |
sauvegarde_pgm(argv[7],ifp,dim);
|
| 497 |
sauvegarde_pgm(argv[8],izp,dim);
|
| 498 |
} |
| 499 |
else
|
| 500 |
{
|
| 501 |
sauvegarde_pgm("z.pgm",izp,dim);
|
| 502 |
sauvegarde_pgm("flux.pgm",ifp,dim);
|
| 503 |
} |
| 504 |
|
| 505 |
free(zp[0]);
|
| 506 |
free(zp); |
| 507 |
free(fp[0]);
|
| 508 |
free(fp); |
| 509 |
|
| 510 |
free(izp[0]);
|
| 511 |
free(izp); |
| 512 |
free(ifp[0]);
|
| 513 |
free(ifp); |
| 514 |
|
| 515 |
} |
| 516 |
|
| 517 |
|