spacecruft
/
sattools
1
0
Fork 0
Code Releases Activity
sattools/faketle.c

302 lines
6.3 KiB
C
Raw Blame History

#include <stdio.h>
#include <string.h>
#include <math.h>
#include <stdlib.h>
#include <ctype.h>
#include "sgdp4h.h"
#include "satutl.h"
#include <getopt.h>
#define XKMPER 6378.135 /* Km per earth radii */
#define XMNPDA 1440.0 /* Minutes per day */
#define AE 1.0 /* Earth radius in "chosen units". */
#define XKE 0.743669161e-1
#define CK2 5.413080e-4 /* (0.5 * XJ2 * AE * AE) */
#define R2D 180.0/M_PI
#define D2R M_PI/180.0
extern double SGDP4_jd0;
void orbit(orbit_t orb,float *aodp,float *perigee,float *apogee,float *period);
void format_tle(orbit_t orb,char *line1,char *line2);
double mjd2doy(double mjd,int *yr);
double nfd2mjd(char *date);
double date2mjd(int year,int month,double day);
void mjd2date(double mjd,int *year,int *month,double *day);
double gmst(double mjd);
double modulo(double x,double y);
void usage(void)
{
printf("faketle q:Q:i:I:w:t:m:n:d:\n\n");
printf("-q Perigee altitude (km)\n");
printf("-Q Apogee altitude (km)\n");
printf("-I Orbital inclination (deg)\n");
printf("-n RA of the ascending node (deg)\n");
printf("-w Argument of perigee (deg)\n");
printf("-m Mean anomaly (deg)\n");
printf("-t Epoch (YYYY-mm-ddThh:mm:ss)\n");
printf("-i Satellite number\n");
printf("-d Time offset from epoch (s)\n");
return;
}
int main(int argc,char *argv[])
{
orbit_t orb;
float aodp,perigee,apogee,period,dt=0.0;
char line1[70],line2[70];
int arg=0;
double mjd,dh;
// Initialize
orb.satno=99999;
orb.eqinc=0.0;
orb.ascn=0.0;
orb.argp=0.0;
orb.mnan=0.0;
orb.bstar=0.5e-4;
orb.ep_day=1.000;
orb.ep_year=2013;
// Decode options
while ((arg=getopt(argc,argv,"q:Q:i:I:w:t:m:n:hd:"))!=-1) {
switch(arg) {
case 'q':
perigee=atof(optarg);
break;
case 'Q':
apogee=atof(optarg);
break;
case 'I':
orb.eqinc=atof(optarg)*D2R;
break;
case 'n':
orb.ascn=atof(optarg)*D2R;
break;
case 'i':
orb.satno=atoi(optarg);
break;
case 'w':
orb.argp=atof(optarg)*D2R;
break;
case 'm':
orb.mnan=atof(optarg)*D2R;
break;
case 't':
mjd=nfd2mjd(optarg);
break;
case 'd':
dt=atof(optarg);
break;
case 'h':
usage();
return 0;
default:
usage();
return 0;
}
}
orb.ep_day=mjd2doy(mjd+dt/86400.0,&orb.ep_year);
perigee+=XKMPER;
apogee+=XKMPER;
aodp=0.5*(perigee+apogee)/XKMPER;
orb.ecc=0.5*(apogee-perigee)/(aodp*XKMPER);
orb.rev=XKE*pow(aodp,-1.5)*XMNPDA/(2.0*M_PI);
if (orb.rev<10)
orb.bstar=0.0;
orbit(orb,&aodp,&perigee,&apogee,&period);
format_tle(orb,line1,line2);
printf("%s\n%s\n",line1,line2);
return 0;
}
void orbit(orbit_t orb,float *aodp,float *perigee,float *apogee,float *period)
{
float xno,eo,xincl;
float a1,betao2,betao,temp0,del1,a0,del0,xnodp;
xno=orb.rev*2.0*M_PI/XMNPDA;
eo=orb.ecc;
xincl=orb.eqinc;
a1 = pow(XKE / xno, 2.0/3.0);
betao2 = 1.0 - eo * eo;
betao = sqrt(betao2);
temp0 = (1.5 * CK2) * cos(xincl)*cos(xincl) / (betao * betao2);
del1 = temp0 / (a1 * a1);
a0 = a1 * (1.0 - del1 * (1.0/3.0 + del1 * (1.0 + del1 * 134.0/81.0)));
del0 = temp0 / (a0 * a0);
xnodp = xno / (1.0 + del0);
*aodp = (a0 / (1.0 - del0));
*perigee = (*aodp * (1.0 - eo) - 1) * XKMPER;
*apogee = (*aodp * (1.0 + eo) - 1) * XKMPER;
*period = (TWOPI * 1440.0 / XMNPDA) / xnodp;
*aodp=(*aodp-1)*XKMPER;
return;
}
// Format TLE
void format_tle(orbit_t orb,char *line1,char *line2)
{
int i,csum;
char sbstar[]=" 00000-0",bstar[13];
// Format Bstar term
if (fabs(orb.bstar)>1e-9) {
sprintf(bstar,"%11.4e",10*orb.bstar);
sbstar[0] = bstar[0]; sbstar[1] = bstar[1]; sbstar[2] = bstar[3]; sbstar[3] = bstar[4];
sbstar[4] = bstar[5]; sbstar[5] = bstar[6]; sbstar[6] = bstar[8]; sbstar[7] = bstar[10]; sbstar[8] = '\0';
}
// Print lines
sprintf(line1,"1 %05dU %2d%012.8f .00000000 00000-0 %8s 0 0",orb.satno,orb.ep_year-2000,orb.ep_day,sbstar);
sprintf(line2,"2 %05d %8.4f %8.4f %07.0f %8.4f %8.4f %11.8f 0",orb.satno,DEG(orb.eqinc),DEG(orb.ascn),1E7*orb.ecc,DEG(orb.argp),DEG(orb.mnan),orb.rev);
// Compute checksums
for (i=0,csum=0;i<strlen(line1);i++) {
if (isdigit(line1[i]))
csum+=line1[i]-'0';
else if (line1[i]=='-')
csum++;
}
sprintf(line1,"%s%d",line1,csum%10);
for (i=0,csum=0;i<strlen(line2);i++) {
if (isdigit(line2[i]))
csum+=line2[i]-'0';
else if (line2[i]=='-')
csum++;
}
sprintf(line2,"%s%d",line2,csum%10);
return;
}
// nfd2mjd
double nfd2mjd(char *date)
{
int year,month,day,hour,min,sec;
double mjd,dday;
sscanf(date,"%04d-%02d-%02dT%02d:%02d:%02d",&year,&month,&day,&hour,&min,&sec);
dday=day+hour/24.0+min/1440.0+sec/86400.0;
mjd=date2mjd(year,month,dday);
return mjd;
}
// Compute Julian Day from Date
double date2mjd(int year,int month,double day)
{
int a,b;
double jd;
if (month<3) {
year--;
month+=12;
}
a=floor(year/100.);
b=2.-a+floor(a/4.);
if (year<1582) b=0;
if (year==1582 && month<10) b=0;
if (year==1582 && month==10 && day<=4) b=0;
jd=floor(365.25*(year+4716))+floor(30.6001*(month+1))+day+b-1524.5;
return jd-2400000.5;
}
// MJD to DOY
double mjd2doy(double mjd,int *yr)
{
int year,month,k=2;
double day,doy;
mjd2date(mjd,&year,&month,&day);
if (year%4==0 && year%400!=0)
k=1;
doy=floor(275.0*month/9.0)-k*floor((month+9.0)/12.0)+day-30;
*yr=year;
return doy;
}
// Compute Date from Julian Day
void mjd2date(double mjd,int *year,int *month,double *day)
{
double f,jd;
int z,alpha,a,b,c,d,e;
jd=mjd+2400000.5;
jd+=0.5;
z=floor(jd);
f=fmod(jd,1.);
if (z<2299161)
a=z;
else {
alpha=floor((z-1867216.25)/36524.25);
a=z+1+alpha-floor(alpha/4.);
}
b=a+1524;
c=floor((b-122.1)/365.25);
d=floor(365.25*c);
e=floor((b-d)/30.6001);
*day=b-d-floor(30.6001*e)+f;
if (e<14)
*month=e-1;
else
*month=e-13;
if (*month>2)
*year=c-4716;
else
*year=c-4715;
return;
}
// Greenwich Mean Sidereal Time
double gmst(double mjd)
{
double t,gmst;
t=(mjd-51544.5)/36525.0;
gmst=modulo(280.46061837+360.98564736629*(mjd-51544.5)+t*t*(0.000387933-t/38710000),360.0);
return gmst;
}
// Return x modulo y [0,y)
double modulo(double x,double y)
{
x=fmod(x,y);
if (x<0.0) x+=y;
return x;
}
View Git Blame Copy Permalink