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Remove redefined functions

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Carles Fernandez 2018-10-04 23:06:38 +02:00
parent 78c0b76cb9
commit 98f5507fbb
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2 changed files with 0 additions and 286 deletions

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@ -673,277 +673,6 @@ void pppoutsolstat(rtk_t *rtk, int level, FILE *fp)
}
/* solar/lunar tides (ref [2] 7) ---------------------------------------------*/
void tide_pl(const double *eu, const double *rp, double GMp,
const double *pos, double *dr)
{
const double H3 = 0.292, L3 = 0.015;
double r, ep[3], latp, lonp, p, K2, K3, a, H2, L2, dp, du, cosp, sinl, cosl;
int i;
trace(4, "tide_pl : pos=%.3f %.3f\n", pos[0] * R2D, pos[1] * R2D);
if ((r = norm_rtk(rp, 3)) <= 0.0) return;
for (i = 0; i < 3; i++) ep[i] = rp[i] / r;
K2 = GMp / GME * std::pow(RE_WGS84, 2.0) * std::pow(RE_WGS84, 2.0) / (r * r * r);
K3 = K2 * RE_WGS84 / r;
latp = asin(ep[2]);
lonp = atan2(ep[1], ep[0]);
cosp = cos(latp);
sinl = sin(pos[0]);
cosl = cos(pos[0]);
/* step1 in phase (degree 2) */
p = (3.0 * sinl * sinl - 1.0) / 2.0;
H2 = 0.6078 - 0.0006 * p;
L2 = 0.0847 + 0.0002 * p;
a = dot(ep, eu, 3);
dp = K2 * 3.0 * L2 * a;
du = K2 * (H2 * (1.5 * a * a - 0.5) - 3.0 * L2 * a * a);
/* step1 in phase (degree 3) */
dp += K3 * L3 * (7.5 * a * a - 1.5);
du += K3 * (H3 * (2.5 * a * a * a - 1.5 * a) - L3 * (7.5 * a * a - 1.5) * a);
/* step1 out-of-phase (only radial) */
du += 3.0 / 4.0 * 0.0025 * K2 * sin(2.0 * latp) * sin(2.0 * pos[0]) * sin(pos[1] - lonp);
du += 3.0 / 4.0 * 0.0022 * K2 * cosp * cosp * cosl * cosl * sin(2.0 * (pos[1] - lonp));
dr[0] = dp * ep[0] + du * eu[0];
dr[1] = dp * ep[1] + du * eu[1];
dr[2] = dp * ep[2] + du * eu[2];
trace(5, "tide_pl : dr=%.3f %.3f %.3f\n", dr[0], dr[1], dr[2]);
}
/* displacement by solid earth tide (ref [2] 7) ------------------------------*/
void tide_solid(const double *rsun, const double *rmoon,
const double *pos, const double *E, double gmst, int opt,
double *dr)
{
double dr1[3], dr2[3], eu[3], du, dn, sinl, sin2l;
trace(3, "tide_solid: pos=%.3f %.3f opt=%d\n", pos[0] * R2D, pos[1] * R2D, opt);
/* step1: time domain */
eu[0] = E[2];
eu[1] = E[5];
eu[2] = E[8];
tide_pl(eu, rsun, GMS, pos, dr1);
tide_pl(eu, rmoon, GMM, pos, dr2);
/* step2: frequency domain, only K1 radial */
sin2l = sin(2.0 * pos[0]);
du = -0.012 * sin2l * sin(gmst + pos[1]);
dr[0] = dr1[0] + dr2[0] + du * E[2];
dr[1] = dr1[1] + dr2[1] + du * E[5];
dr[2] = dr1[2] + dr2[2] + du * E[8];
/* eliminate permanent deformation */
if (opt & 8)
{
sinl = sin(pos[0]);
du = 0.1196 * (1.5 * sinl * sinl - 0.5);
dn = 0.0247 * sin2l;
dr[0] += du * E[2] + dn * E[1];
dr[1] += du * E[5] + dn * E[4];
dr[2] += du * E[8] + dn * E[7];
}
trace(5, "tide_solid: dr=%.3f %.3f %.3f\n", dr[0], dr[1], dr[2]);
}
/* displacement by ocean tide loading (ref [2] 7) ----------------------------*/
void tide_oload(gtime_t tut, const double *odisp, double *denu)
{
const double args[][5] = {
{1.40519E-4, 2.0, -2.0, 0.0, 0.00}, /* M2 */
{1.45444E-4, 0.0, 0.0, 0.0, 0.00}, /* S2 */
{1.37880E-4, 2.0, -3.0, 1.0, 0.00}, /* N2 */
{1.45842E-4, 2.0, 0.0, 0.0, 0.00}, /* K2 */
{0.72921E-4, 1.0, 0.0, 0.0, 0.25}, /* K1 */
{0.67598E-4, 1.0, -2.0, 0.0, -0.25}, /* O1 */
{0.72523E-4, -1.0, 0.0, 0.0, -0.25}, /* P1 */
{0.64959E-4, 1.0, -3.0, 1.0, -0.25}, /* Q1 */
{0.53234E-5, 0.0, 2.0, 0.0, 0.00}, /* Mf */
{0.26392E-5, 0.0, 1.0, -1.0, 0.00}, /* Mm */
{0.03982E-5, 2.0, 0.0, 0.0, 0.00} /* Ssa */
};
const double ep1975[] = {1975, 1, 1, 0, 0, 0};
double ep[6], fday, days, t, t2, t3, a[5], ang, dp[3] = {0};
int i, j;
trace(3, "tide_oload:\n");
/* angular argument: see subroutine arg.f for reference [1] */
time2epoch(tut, ep);
fday = ep[3] * 3600.0 + ep[4] * 60.0 + ep[5];
ep[3] = ep[4] = ep[5] = 0.0;
days = timediff(epoch2time(ep), epoch2time(ep1975)) / 86400.0;
t = (27392.500528 + 1.000000035 * days) / 36525.0;
t2 = t * t;
t3 = t2 * t;
a[0] = fday;
a[1] = (279.69668 + 36000.768930485 * t + 3.03E-4 * t2) * D2R; /* H0 */
a[2] = (270.434358 + 481267.88314137 * t - 0.001133 * t2 + 1.9E-6 * t3) * D2R; /* S0 */
a[3] = (334.329653 + 4069.0340329577 * t - 0.010325 * t2 - 1.2E-5 * t3) * D2R; /* P0 */
a[4] = 2.0 * PI;
/* displacements by 11 constituents */
for (i = 0; i < 11; i++)
{
ang = 0.0;
for (j = 0; j < 5; j++) ang += a[j] * args[i][j];
for (j = 0; j < 3; j++) dp[j] += odisp[j + i * 6] * cos(ang - odisp[j + 3 + i * 6] * D2R);
}
denu[0] = -dp[1];
denu[1] = -dp[2];
denu[2] = dp[0];
trace(5, "tide_oload: denu=%.3f %.3f %.3f\n", denu[0], denu[1], denu[2]);
}
/* iers mean pole (ref [7] eq.7.25) ------------------------------------------*/
void iers_mean_pole(gtime_t tut, double *xp_bar, double *yp_bar)
{
const double ep2000[] = {2000, 1, 1, 0, 0, 0};
double y, y2, y3;
y = timediff(tut, epoch2time(ep2000)) / 86400.0 / 365.25;
if (y < 3653.0 / 365.25)
{ /* until 2010.0 */
y2 = y * y;
y3 = y2 * y;
*xp_bar = 55.974 + 1.8243 * y + 0.18413 * y2 + 0.007024 * y3; /* (mas) */
*yp_bar = 346.346 + 1.7896 * y - 0.10729 * y2 - 0.000908 * y3;
}
else
{ /* after 2010.0 */
*xp_bar = 23.513 + 7.6141 * y; /* (mas) */
*yp_bar = 358.891 - 0.6287 * y;
}
}
/* displacement by pole tide (ref [7] eq.7.26) --------------------------------*/
void tide_pole(gtime_t tut, const double *pos, const double *erpv,
double *denu)
{
double xp_bar, yp_bar, m1, m2, cosl, sinl;
trace(3, "tide_pole: pos=%.3f %.3f\n", pos[0] * R2D, pos[1] * R2D);
/* iers mean pole (mas) */
iers_mean_pole(tut, &xp_bar, &yp_bar);
/* ref [7] eq.7.24 */
m1 = erpv[0] / AS2R - xp_bar * 1E-3; /* (as) */
m2 = -erpv[1] / AS2R + yp_bar * 1E-3;
/* sin(2*theta) = sin(2*phi), cos(2*theta)=-cos(2*phi) */
cosl = cos(pos[1]);
sinl = sin(pos[1]);
denu[0] = 9E-3 * sin(pos[0]) * (m1 * sinl - m2 * cosl); /* de= Slambda (m) */
denu[1] = -9E-3 * cos(2.0 * pos[0]) * (m1 * cosl + m2 * sinl); /* dn=-Stheta (m) */
denu[2] = -33E-3 * sin(2.0 * pos[0]) * (m1 * cosl + m2 * sinl); /* du= Sr (m) */
trace(5, "tide_pole : denu=%.3f %.3f %.3f\n", denu[0], denu[1], denu[2]);
}
/* tidal displacement ----------------------------------------------------------
* displacements by earth tides
* args : gtime_t tutc I time in utc
* double *rr I site position (ecef) (m)
* int opt I options (or of the followings)
* 1: solid earth tide
* 2: ocean tide loading
* 4: pole tide
* 8: elimate permanent deformation
* double *erp I earth rotation parameters (NULL: not used)
* double *odisp I ocean loading parameters (NULL: not used)
* odisp[0+i*6]: consituent i amplitude radial(m)
* odisp[1+i*6]: consituent i amplitude west (m)
* odisp[2+i*6]: consituent i amplitude south (m)
* odisp[3+i*6]: consituent i phase radial (deg)
* odisp[4+i*6]: consituent i phase west (deg)
* odisp[5+i*6]: consituent i phase south (deg)
* (i=0:M2,1:S2,2:N2,3:K2,4:K1,5:O1,6:P1,7:Q1,
* 8:Mf,9:Mm,10:Ssa)
* double *dr O displacement by earth tides (ecef) (m)
* return : none
* notes : see ref [1], [2] chap 7
* see ref [4] 5.2.1, 5.2.2, 5.2.3
* ver.2.4.0 does not use ocean loading and pole tide corrections
*-----------------------------------------------------------------------------*/
void tidedisp(gtime_t tutc, const double *rr, int opt, const erp_t *erp,
const double *odisp, double *dr)
{
gtime_t tut;
double pos[2], E[9], drt[3], denu[3], rs[3], rm[3], gmst, erpv[5] = {0};
int i;
#ifdef IERS_MODEL
double ep[6], fhr;
int year, mon, day;
#endif
trace(3, "tidedisp: tutc=%s\n", time_str(tutc, 0));
if (erp) geterp(erp, tutc, erpv);
tut = timeadd(tutc, erpv[2]);
dr[0] = dr[1] = dr[2] = 0.0;
if (norm_rtk(rr, 3) <= 0.0) return;
pos[0] = asin(rr[2] / norm_rtk(rr, 3));
pos[1] = atan2(rr[1], rr[0]);
xyz2enu(pos, E);
if (opt & 1)
{ /* solid earth tides */
/* sun and moon position in ecef */
sunmoonpos(tutc, erpv, rs, rm, &gmst);
#ifdef IERS_MODEL
time2epoch(tutc, ep);
year = (int)ep[0];
mon = (int)ep[1];
day = (int)ep[2];
fhr = ep[3] + ep[4] / 60.0 + ep[5] / 3600.0;
/* call DEHANTTIDEINEL */
dehanttideinel_((double *)rr, &year, &mon, &day, &fhr, rs, rm, drt);
#else
tide_solid(rs, rm, pos, E, gmst, opt, drt);
#endif
for (i = 0; i < 3; i++) dr[i] += drt[i];
}
if ((opt & 2) && odisp)
{ /* ocean tide loading */
tide_oload(tut, odisp, denu);
matmul("TN", 3, 1, 3, 1.0, E, denu, 0.0, drt);
for (i = 0; i < 3; i++) dr[i] += drt[i];
}
if ((opt & 4) && erp)
{ /* pole tide */
tide_pole(tut, pos, erpv, denu);
matmul("TN", 3, 1, 3, 1.0, E, denu, 0.0, drt);
for (i = 0; i < 3; i++) dr[i] += drt[i];
}
trace(5, "tidedisp: dr=%.3f %.3f %.3f\n", dr[0], dr[1], dr[2]);
}
/* exclude meas of eclipsing satellite (block IIA) ---------------------------*/
void testeclipse(const obsd_t *obs, int n, const nav_t *nav, double *rs)
{

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@ -129,21 +129,6 @@ int pppamb(rtk_t *rtk, const obsd_t *obs, int n, const nav_t *nav, const double
/* functions originally included in RTKLIB/src/ppp.c v2.4.2 */
void pppoutsolstat(rtk_t *rtk, int level, FILE *fp);
void tide_pl(const double *eu, const double *rp, double GMp, const double *pos, double *dr);
void tide_solid(const double *rsun, const double *rmoon,
const double *pos, const double *E, double gmst, int opt,
double *dr);
void tide_oload(gtime_t tut, const double *odisp, double *denu);
void iers_mean_pole(gtime_t tut, double *xp_bar, double *yp_bar);
void tide_pole(gtime_t tut, const double *pos, const double *erpv, double *denu);
void tidedisp(gtime_t tutc, const double *rr, int opt, const erp_t *erp,
const double *odisp, double *dr);
void testeclipse(const obsd_t *obs, int n, const nav_t *nav, double *rs);
double varerr(int sat, int sys, double el, int type, const prcopt_t *opt);