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small_tel/Daemons/10micron_stellarium/angles.c
Edward Emelianov fd37853735 cont
2026-06-19 14:47:06 +03:00

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/*
* This file is part of the mountdaemon_10micron project.
* Copyright 2026 Edward V. Emelianov <edward.emelianoff@gmail.com>.
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include <erfa.h>
#include <erfam.h>
#include <math.h>
#include <time.h>
#include <usefull_macros.h>
#include "angles.h"
static placeData_t place = {.slong = 0.7232763200, .slat = 0.7618977414, .salt = 2070.};
static almDut_t AlmDut = {0};
// set/get polar/DUT1 data
bool setDUT(almDut_t *D){
if(!D){
WARNX("setDUT(): no args");
return false;
}
if(fabs(D->DUT1) > 1.){
WARNX("setDUT(): DUT1 too large (%g)", D->DUT1);
return false;
}
if(fabs(D->px) > 1000. || fabs(D->py) > 1000.){
WARNX("setDUT(): bad polar coordinates (%g, %g)", D->px, D->py);
return false;
}
AlmDut = *D;
return true;
}
void getDUT(almDut_t *D){
if(!D) return;
*D = AlmDut;
}
/**
* @brief setPlaceData - correct place data to given values
* @param longitude - degrees, (-180, 180], minus to west
* @param latitude - degrees, [-90, 90], minus to south
* @param altitude - meters
* @return false if some of data wrong
*/
bool setPlaceData(double longitude, double latitude, double altitude){
if(longitude <= -180. || longitude > 180.){
WARNX("setPlaceData(): bad longitude (%g)", longitude);
return false;
}
if(latitude < -90. || latitude > 90.){
WARNX("setPlaceData(): bad latitude (%g)", latitude);
return false;
}
if(altitude < -500. || altitude > 9000.){
WARNX("setPlaceData(): bad altitude (%g)", altitude);
return false;
}
place.salt = altitude;
place.slat = latitude;
place.slong = longitude;
return true;
}
void getPlaceData(placeData_t *pd){
if(!pd) return;
*pd = place;
}
/**
* convert RA/DEC to string in forman RA: HH:MM:SS.SS, DEC: DD:MM:SS.S
*/
char *radec2str(double ra, double dec, char buf[RADEC_STR_MAXLEN]){
char sign = '+';
if(dec < 0){
sign = '-';
dec = -dec;
}
int h = (int)ra;
ra -= h; ra *= 60.;
int m = (int)ra;
ra -= m; ra *= 60.;
int d = (int) dec;
dec -= d; dec *= 60.;
int dm = (int)dec;
dec -= dm; dec *= 60.;
snprintf(buf, RADEC_STR_MAXLEN, "%d:%d:%.2f %c%d:%d:%.1f", h,m,ra, sign,d,dm,dec);
buf[RADEC_STR_MAXLEN-1] = 0;
return buf;
}
// normalize RA/DEC to [0..24) for RA and [-90, 90] for DEC
void norm_RA(double *ra){
if(!ra) return;
if(*ra >= 0. && *ra < 24.) return;
double r = fmod(*ra, 24.);
if(r < 0.) r += 24.;
*ra = r;
}
void norm_RADEC(double *ra, double *dec){
if(!ra || !dec) return;
if(*dec >= -90. && *dec <= 90.){ // need only check RA
norm_RA(ra);
return;
}
// 1: convert to (-180..+180)
norm_angle180(dec);
// 2: fix dec & ra together
if(*dec > 90.) *dec = 180. - *dec;
else *dec = -180. - *dec;
*ra += 12.;
norm_RA(ra);
}
// normalize angle to (-180, 180]
void norm_angle180(double *a){
if(!a) return;
double d = fmod(*a + 180.0, 360.0);
if(d < 0.) d += 360.0;
else d -= 180;
*a = d;
}
/**
* @brief hor2eq - convert horizontal coordinates to polar
* @param h (i) - horizontal coordinates
* @param pc (o) - polar coordinates
* @param sidTime - sidereal time
*/
void hor2eq(horizCrds_t *h, polarCrds_t *pc, double sidTime){
if(!h || !pc) return;
eraAe2hd(h->az, ERFA_DPI/2. - h->zd, place.slat, &pc->ha, &pc->dec); // A,H -> HA,DEC; phi - site latitude
pc->ra = sidTime - pc->ha;
pc->eo = 0.;
}
/**
* @brief eq2horH - convert polar coordinates to horizontal
* @param pc (i) - polar coordinates (only HA used)
* @param h (o) - horizontal coordinates
* @param sidTime - sidereal time
*/
void eq2horH(polarCrds_t *pc, horizCrds_t *h){
if(!h || !pc) return;
double alt;
eraHd2ae(pc->ha, pc->dec, place.slat, &h->az, &alt);
h->zd = ERFA_DPI/2. - alt;
}
/**
* @brief eq2hor - convert polar coordinates to horizontal
* @param pc (i) - polar coordinates (only RA used)
* @param h (o) - horizontal coordinates
* @param sidTime - sidereal time
*/
void eq2hor(polarCrds_t *pc, horizCrds_t *h, double sidTime){
if(!h || !pc) return;
double ha = sidTime - pc->ra + pc->eo;
double alt;
eraHd2ae(ha, pc->dec, place.slat, &h->az, &alt);
h->zd = ERFA_DPI/2. - alt;
}
/**
* @brief r2sHMS - convert angle in radians into string "'HH:MM:SS.SS'"
* @param radians - angle
* @param hms (o) - string
* @param len - length of hms
*/
void r2sHMS(double radians, char *hms, int len){
char pm;
int i[4];
eraA2tf(2, radians, &pm, i);
snprintf(hms, len, "'%c%02d:%02d:%02d.%02d'", pm, i[0],i[1],i[2],i[3]);
}
/**
* @brief r2sDMS - convert angle in radians into string "'DD:MM:SS.S'"
* @param radians - angle
* @param dms (o) - string
* @param len - length of hms
*/
void r2sDMS(double radians, char *dms, int len){
char pm;
int i[4];
eraA2af(1, radians, &pm, i);
snprintf(dms, len, "'%c%02d:%02d:%02d.%d'", pm, i[0],i[1],i[2],i[3]);
}
/**
* @brief get_MJDt - calculate MJD of date from argument
* @param tval (i) - given date (or NULL for current)
* @param MJD (o) - time (or NULL just to check)
* @return true if all OK
*/
bool get_MJDt(struct timeval *tval, sMJD_t *MJD){
struct tm tms;
double tSeconds;
if(!MJD){
WARNX("get_MJDt(): no input data");
return false;
}
if(!tval){
struct timespec ts;
if(clock_gettime(CLOCK_REALTIME, &ts)){
WARN("clock_gettime()");
return false;
}
gmtime_r(&ts.tv_sec, &tms);
tSeconds = tms.tm_sec + ((double)ts.tv_nsec)/1e9;
}else{
gmtime_r(&tval->tv_sec, &tms);
tSeconds = tms.tm_sec + ((double)tval->tv_usec)/1e6;
}
int y, m, d;
y = 1900 + tms.tm_year;
m = tms.tm_mon + 1;
d = tms.tm_mday;
double utc1, utc2;
/* UTC date. */
if(eraDtf2d("UTC", y, m, d, tms.tm_hour, tms.tm_min, tSeconds, &utc1, &utc2) < 0){
WARNX("get_MJDt(): eraDtf2d() error");
return false;
}
MJD->MJD = utc1 - ERFA_DJM0 + utc2;
MJD->utc1 = utc1;
MJD->utc2 = utc2;
//DBG("UTC(m): %g, %.8f\n", utc1 - 2400000.5, utc2);
if(eraUtctai(utc1, utc2, &MJD->tai1, &MJD->tai2)){
WARNX("get_MJDt(): eraUtctai() error");
return false;
}
//DBG("TAI");
if(eraTaitt(MJD->tai1, MJD->tai2, &MJD->tt1, &MJD->tt2)){
WARNX("get_MJDt(): eraTaitt() error");
return false;
}
//DBG("TT");
return true;
}
/**
* @brief get_LST - calculate local siderial time
* @param mjd (i) - date/time for LST (utc1 & tt used)
* @param dUT1 - (UT1-UTC)
* @param slong - site longitude (radians)
* @param LST (o) - local sidereal time (radians)
* @return true if all OK
*/
bool get_LST(sMJD_t *mjd, double dUT1, double slong, double *LST){
double ut11, ut12;
sMJD_t Mjd;
if(!LST) return false;
if(!mjd){
if(!get_MJDt(NULL, &Mjd)) return false;
}else Mjd = *mjd;
if(eraUtcut1(Mjd.utc1, Mjd.utc2, dUT1, &ut11, &ut12)) return false;
double ST = eraGst06a(ut11, ut12, Mjd.tt1, Mjd.tt2);
ST += slong;
if(ST > ERFA_D2PI) ST -= ERFA_D2PI;
else if(ST < 0.) ST += ERFA_D2PI;
*LST = ST;
return 0;
}
/**
* @brief get_ObsPlace - calculate observed place (without PM etc) for given date @550nm
* @param tval (i) - time
* @param p2000 (i) - polar coordinates for J2000 (only ra/dec used), ICRS (catalog)
* @param pnow (o) - polar coordinates for given epoch (or NULL)
* @param hnow (o) - horizontal coordinates for given epoch (or NULL)
* @return true if all OK
*/
bool get_ObsPlace(struct timeval *tval, polarCrds_t *p2000, polarCrds_t *pnow, horizCrds_t *hnow){
double pr = 0.0; // RA proper motion (radians/year; Note 2)
double pd = 0.0; // Dec proper motion (radians/year)
double px = 0.0; // parallax (arcsec)
double rv = 0.0; // radial velocity (km/s, positive if receding)
sMJD_t MJD;
if(!p2000){
WARNX("get_ObsPlace(): no input coordinates");
return false;
}
if(!get_MJDt(tval, &MJD)) return false;
/* Effective wavelength (microns) */
double wl = 0.55;
/* ICRS to observed. */
double aob, zob, hob, dob, rob, eo;
double p = 1000., t = 0., h = place.salt;
weather_data_t weath;
if(get_weather_data(&weath)){
WARNX("Can't get weather - use default values");
}else{
p = 1.3332239 * weath.pressure;
t = weath.exttemp;
DBG("pressure=%.1fhPa, temperature=%.1fdegC", p, t);
}
if(eraAtco13(p2000->ra, p2000->dec,
pr, pd, px, rv,
MJD.utc1, MJD.utc2,
AlmDut.DUT1,
place.slong, place.slat, place.salt,
AlmDut.px, AlmDut.py,
p, t, h,
wl,
&aob, &zob,
&hob, &dob, &rob, &eo)) return false;
if(pnow){
pnow->eo = eo;
pnow->ha = hob;
pnow->ra = rob;
pnow->dec = dob;
}
if(hnow){
hnow->az = aob;
hnow->zd = zob;
}
return true;
}
/**
* convert geocentric coordinates (nowadays, CIRS) to mean (JD2000, ICRS)
* in, out - input and output coordinates
* @return false if failed
*/
bool JnowtoJ2000(const polarCrds_t *in, polarCrds_t *out){
bool ret = false;
DBG("appRa: %gdegr, appDecl: %gdegr", RAD2DEG(in->ra), RAD2DEG(in->dec));
#define ERFA(f, ...) do{if(f(__VA_ARGS__)){WARNX("Error in " #f); goto rtn;}}while(0)
sMJD_t MJD;
if(!get_MJDt(NULL, &MJD)) return false;
double ri = 0., di = 0., eo = 0.;
eraAtic13(in->ra, in->dec, MJD.tt1, MJD.tt2, &ri, &di, &eo);
if(out){
out->ha = 0.; out->eo = 0.;
out->ra = eraAnp(ri + eo);
out->dec = di;
DBG("JnowtoJ2000: ra=%gdeg, dec=%gdeg", RAD2DEG(out->ra), RAD2DEG(out->dec));
}
ret = true;
#undef ERFA
return ret;
}
/**
* @brief J2000toJnow - convert ra/dec between epochs
* @param in - J2000 (degrees)
* @param out - Jnow (degrees)
* @return false if failed
*/
bool J2000toJnow(const polarCrds_t *in, polarCrds_t *out){
DBG("J200RA: %gdegr, J200Dec: %gdegr", RAD2DEG(in->ra), RAD2DEG(in->dec));
sMJD_t MJD;
if(!in) return false;
if(!get_MJDt(NULL, &MJD)) return false;
// these values could be changed (e.g. by user's input)
double pr = 0.0; // RA proper motion (radians/year)
double pd = 0.0; // Dec proper motion (radians/year)
double px = 0.0; // parallax (arcsec)
double rv = 0.0; // radial velocity (km/s, positive if receding)
double ri, di, eo;
eraAtci13(in->ra, in->dec, pr, pd, px, rv, MJD.tt1, MJD.tt2, &ri, &di, &eo);
if(out){
out->ra = eraAnp(ri - eo);
out->dec = di;
}
return true;
}
#if 0
typedef enum {
WEATHER_GOOD = 0, // may start observations
WEATHER_BAD = 1, // cannot start but can continue if want
WEATHER_TERRIBLE = 2, // close & park: wind, precipitation, humidity etc.
WEATHER_PROHIBITED = 3, // force closing & parking; power off equipment, ready to power off computer
} weather_condition_t;
typedef struct {
weather_condition_t weather; // conditions: field "WEATHER"
float windmax; // maximal wind for last hour, m/s: "WINDMAX1"
float wind; // current wind speed, m/s: "WIND"
float clouds; // sky "quality" (>2500 - OK): "CLOUDS"
float exttemp; // external temperature, degC: "EXTTEMP"
float pressure; // atm. pressure, mmHg: "PRESSURE"
float humidity; // humidity, percents: "HUMIDITY"
int rain; // ==1 when rainy: "PRECIP"
int forceoff; // force power off (AC power lost or lightning)
time_t last_update; // value of "TMEAS"
} weather_data_t;
int get_weather_data(weather_data_t *data);
#endif
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