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f15b13e2a7
Developing FEATURE_SATELLITE_TRACKING. Yea. FEATURE_NEXTION_DISPLAY: call service_nextion_display() right after rebooting display at start up
138 lines
5.0 KiB
C++
Executable File
138 lines
5.0 KiB
C++
Executable File
// This file is available in electronic form at http://www.psa.es/sdg/sunpos.htm
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#include "sunpos.h"
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#include <math.h>
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void sunpos(cTime udtTime,cLocation udtLocation, cSunCoordinates *udtSunCoordinates)
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{
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// Main variables
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double dElapsedJulianDays;
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double dDecimalHours;
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double dEclipticLongitude;
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double dEclipticObliquity;
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double dRightAscension;
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double dDeclination;
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// Auxiliary variables
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double dY;
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double dX;
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// Calculate difference in days between the current Julian Day
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// and JD 2451545.0, which is noon 1 January 2000 Universal Time
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{
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double dJulianDate;
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long int liAux1;
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long int liAux2;
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// Calculate time of the day in UT decimal hours
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dDecimalHours = udtTime.dHours + (udtTime.dMinutes
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+ udtTime.dSeconds / 60.0 ) / 60.0;
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// Calculate current Julian Day
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liAux1 =(udtTime.iMonth-14)/12;
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liAux2=(1461*(udtTime.iYear + 4800 + liAux1))/4 + (367*(udtTime.iMonth
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- 2-12*liAux1))/12- (3*((udtTime.iYear + 4900
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+ liAux1)/100))/4+udtTime.iDay-32075;
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// dJulianDate=(double)(liAux2)-0.5+dDecimalHours/24.0;
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// Calculate difference between current Julian Day and JD 2451545.0
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// dElapsedJulianDays = dJulianDate-2451545.0;
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// 140113 VE5VA
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// The original way of calculating elapsed Julian days required
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// more precision than is possible in a 32-bit float, so change
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// the order of the calculation to preserve the significant digits.
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liAux2 -= 2451545L;
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dElapsedJulianDays = (double)liAux2-0.5+dDecimalHours/24.0;
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}
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/* old Julian day calculation
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// Calculate difference in days between the current Julian Day
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// and JD 2451545.0, which is noon 1 January 2000 Universal Time
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{
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double dJulianDate;
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long int liAux1;
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long int liAux2;
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// Calculate time of the day in UT decimal hours
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dDecimalHours = udtTime.dHours + (udtTime.dMinutes
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+ udtTime.dSeconds / 60.0 ) / 60.0;
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// Calculate current Julian Day
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liAux1 =(udtTime.iMonth-14)/12;
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liAux2=(1461*(udtTime.iYear + 4800 + liAux1))/4 + (367*(udtTime.iMonth
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- 2-12*liAux1))/12- (3*((udtTime.iYear + 4900
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+ liAux1)/100))/4+udtTime.iDay-32075;
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dJulianDate=(double)(liAux2)-0.5+dDecimalHours/24.0;
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// Calculate difference between current Julian Day and JD 2451545.0
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dElapsedJulianDays = dJulianDate-2451545.0;
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}
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*/
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// Calculate ecliptic coordinates (ecliptic longitude and obliquity of the
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// ecliptic in radians but without limiting the angle to be less than 2*Pi
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// (i.e., the result may be greater than 2*Pi)
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{
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double dMeanLongitude;
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double dMeanAnomaly;
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double dOmega;
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dOmega=2.1429-0.0010394594*dElapsedJulianDays;
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dMeanLongitude = 4.8950630+ 0.017202791698*dElapsedJulianDays; // Radians
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dMeanAnomaly = 6.2400600+ 0.0172019699*dElapsedJulianDays;
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dEclipticLongitude = dMeanLongitude + 0.03341607*sin( dMeanAnomaly )
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+ 0.00034894*sin( 2*dMeanAnomaly )-0.0001134
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-0.0000203*sin(dOmega);
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dEclipticObliquity = 0.4090928 - 6.2140e-9*dElapsedJulianDays
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+0.0000396*cos(dOmega);
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}
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// Calculate celestial coordinates ( right ascension and declination ) in radians
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// but without limiting the angle to be less than 2*Pi (i.e., the result may be
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// greater than 2*Pi)
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{
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double dSin_EclipticLongitude;
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dSin_EclipticLongitude= sin( dEclipticLongitude );
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dY = cos( dEclipticObliquity ) * dSin_EclipticLongitude;
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dX = cos( dEclipticLongitude );
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dRightAscension = atan2( dY,dX );
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if( dRightAscension < 0.0 ) dRightAscension = dRightAscension + TWOPI_SUNPOS;
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dDeclination = asin( sin( dEclipticObliquity )*dSin_EclipticLongitude );
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}
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// Calculate local coordinates ( azimuth and zenith angle ) in degrees
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{
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double dGreenwichMeanSiderealTime;
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double dLocalMeanSiderealTime;
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double dLatitudeInRadians;
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double dHourAngle;
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double dCos_Latitude;
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double dSin_Latitude;
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double dCos_HourAngle;
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double dParallax;
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dGreenwichMeanSiderealTime = 6.6974243242 +
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0.0657098283*dElapsedJulianDays
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+ dDecimalHours;
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dLocalMeanSiderealTime = (dGreenwichMeanSiderealTime*15
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+ udtLocation.dLongitude)*RAD_SUNPOS;
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dHourAngle = dLocalMeanSiderealTime - dRightAscension;
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dLatitudeInRadians = udtLocation.dLatitude*RAD_SUNPOS;
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dCos_Latitude = cos( dLatitudeInRadians );
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dSin_Latitude = sin( dLatitudeInRadians );
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dCos_HourAngle= cos( dHourAngle );
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udtSunCoordinates->dZenithAngle = (acos( dCos_Latitude*dCos_HourAngle
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*cos(dDeclination) + sin( dDeclination )*dSin_Latitude));
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dY = -sin( dHourAngle );
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dX = tan( dDeclination )*dCos_Latitude - dSin_Latitude*dCos_HourAngle;
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udtSunCoordinates->dAzimuth = atan2( dY, dX );
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if ( udtSunCoordinates->dAzimuth < 0.0 )
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udtSunCoordinates->dAzimuth = udtSunCoordinates->dAzimuth + TWOPI_SUNPOS;
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udtSunCoordinates->dAzimuth = udtSunCoordinates->dAzimuth/RAD_SUNPOS;
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// Parallax Correction
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dParallax=(dEarthMeanRadius/dAstronomicalUnit)
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*sin(udtSunCoordinates->dZenithAngle);
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udtSunCoordinates->dZenithAngle=(udtSunCoordinates->dZenithAngle
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+ dParallax)/RAD_SUNPOS;
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}
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}
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