/* SPDX-FileCopyrightText: 2009 Petri Damsten SPDX-License-Identifier: GPL-2.0-or-later */ #include "solarsystem.h" #include #include /* * Mathematics, ideas, public domain code used for these classes from: * https://www.stjarnhimlen.se/comp/tutorial.html * https://www.stjarnhimlen.se/comp/riset.html * https://www.esrl.noaa.gov/gmd/grad/solcalc/azel.html * https://www.esrl.noaa.gov/gmd/grad/solcalc/sunrise.html * http://web.archive.org/web/20080309162302/http://bodmas.org/astronomy/riset.html * moontool.c by John Walker * Wikipedia */ Sun::Sun() : SolarSystemObject() { } void Sun::calcForDateTime(const QDateTime &local, int offset) { SolarSystemObject::calcForDateTime(local, offset); N = 0.0; i = 0.0; w = rev(282.9404 + 4.70935E-5 * m_day); a = 1.0; e = rev(0.016709 - 1.151E-9 * m_day); M = rev(356.0470 + 0.9856002585 * m_day); calc(); } void Sun::rotate(double *y, double *z) { *y *= cosd(m_obliquity); *z *= sind(m_obliquity); } Moon::Moon(Sun *sun) : m_sun(sun) { } void Moon::calcForDateTime(const QDateTime &local, int offset) { if (m_sun->dateTime() != local) { m_sun->calcForDateTime(local, offset); } SolarSystemObject::calcForDateTime(local, offset); N = rev(125.1228 - 0.0529538083 * m_day); i = 5.1454; w = rev(318.0634 + 0.1643573223 * m_day); a = 60.2666; e = 0.054900; M = rev(115.3654 + 13.0649929509 * m_day); calc(); } bool Moon::calcPerturbations(double *lo, double *la, double *r) { double Ms = m_sun->meanAnomaly(); double D = L - m_sun->meanLongitude(); double F = L - N; // clang-format off *lo += -1.274 * sind(M - 2 * D) +0.658 * sind(2 * D) -0.186 * sind(Ms) -0.059 * sind(2 * M - 2 * D) -0.057 * sind(M - 2 * D + Ms) +0.053 * sind(M + 2 * D) +0.046 * sind(2 * D - Ms) +0.041 * sind(M - Ms) -0.035 * sind(D) -0.031 * sind(M + Ms) -0.015 * sind(2 * F - 2 * D) +0.011 * sind(M - 4 * D); *la += -0.173 * sind(F - 2 * D) -0.055 * sind(M - F - 2 * D) -0.046 * sind(M + F - 2 * D) +0.033 * sind(F + 2 * D) +0.017 * sind(2 * M + F); *r += -0.58 * cosd(M - 2 * D) -0.46 * cosd(2 * D); // clang-format on return true; } void Moon::topocentricCorrection(double *RA, double *dec) { double HA = rev(siderealTime() - *RA); double gclat = m_latitude - 0.1924 * sind(2 * m_latitude); double rho = 0.99833 + 0.00167 * cosd(2 * m_latitude); double mpar = asind(1 / rad); double g = atand(tand(gclat) / cosd(HA)); *RA -= mpar * rho * cosd(gclat) * sind(HA) / cosd(*dec); *dec -= mpar * rho * sind(gclat) * sind(g - *dec) / sind(g); } double Moon::phase() { return rev(m_eclipticLongitude - m_sun->lambda()); } void Moon::rotate(double *y, double *z) { double t = *y; *y = t * cosd(m_obliquity) - *z * sind(m_obliquity); *z = t * sind(m_obliquity) + *z * cosd(m_obliquity); } void SolarSystemObject::calc() { double x, y, z; double la, r; L = rev(N + w + M); double E0 = 720.0; double E = M + (180.0 / M_PI) * e * sind(M) * (1.0 + e * cosd(M)); for (int j = 0; fabs(E0 - E) > 0.005 && j < 10; ++j) { E0 = E; E = E0 - (E0 - (180.0 / M_PI) * e * sind(E0) - M) / (1 - e * cosd(E0)); } x = a * (cosd(E) - e); y = a * sind(E) * sqrt(1.0 - e * e); r = sqrt(x * x + y * y); double v = rev(atan2d(y, x)); m_lambda = rev(v + w); x = r * (cosd(N) * cosd(m_lambda) - sind(N) * sind(m_lambda) * cosd(i)); y = r * (sind(N) * cosd(m_lambda) + cosd(N) * sind(m_lambda) * cosd(i)); z = r * sind(m_lambda); if (!qFuzzyCompare(i, 0.0)) { z *= sind(i); } toSpherical(x, y, z, &m_eclipticLongitude, &la, &r); if (calcPerturbations(&m_eclipticLongitude, &la, &r)) { toRectangular(m_eclipticLongitude, la, r, &x, &y, &z); } rotate(&y, &z); toSpherical(x, y, z, &RA, &dec, &rad); topocentricCorrection(&RA, &dec); HA = rev(siderealTime() - RA); x = cosd(HA) * cosd(dec) * sind(m_latitude) - sind(dec) * cosd(m_latitude); y = sind(HA) * cosd(dec); z = cosd(HA) * cosd(dec) * cosd(m_latitude) + sind(dec) * sind(m_latitude); m_azimuth = atan2d(y, x) + 180.0; m_altitude = asind(z); } double SolarSystemObject::siderealTime() { double UT = m_utc.time().hour() + m_utc.time().minute() / 60.0 + m_utc.time().second() / 3600.0; double GMST0 = rev(282.9404 + 4.70935E-5 * m_day + 356.0470 + 0.9856002585 * m_day + 180.0); return GMST0 + UT * 15.0 + m_longitude; } void SolarSystemObject::calcForDateTime(const QDateTime &local, int offset) { m_local = local; m_utc = local.addSecs(-offset); m_day = 367 * m_utc.date().year() - (7 * (m_utc.date().year() + ((m_utc.date().month() + 9) / 12))) / 4 + (275 * m_utc.date().month()) / 9 + m_utc.date().day() - 730530; m_day += m_utc.time().hour() / 24.0 + m_utc.time().minute() / (24.0 * 60.0) + m_utc.time().second() / (24.0 * 60.0 * 60.0); m_obliquity = 23.4393 - 3.563E-7 * m_day; } SolarSystemObject::SolarSystemObject() : m_latitude(0.0) , m_longitude(0.0) { } SolarSystemObject::~SolarSystemObject() { } void SolarSystemObject::setPosition(double latitude, double longitude) { m_latitude = latitude; m_longitude = longitude; } double SolarSystemObject::rev(double x) { return x - floor(x / 360.0) * 360.0; } double SolarSystemObject::asind(double x) { return asin(x) * 180.0 / M_PI; } double SolarSystemObject::sind(double x) { return sin(x * M_PI / 180.0); } double SolarSystemObject::cosd(double x) { return cos(x * M_PI / 180.0); } double SolarSystemObject::tand(double x) { return tan(x * M_PI / 180.0); } double SolarSystemObject::atan2d(double y, double x) { return atan2(y, x) * 180.0 / M_PI; } double SolarSystemObject::atand(double x) { return atan(x) * 180.0 / M_PI; } void SolarSystemObject::toRectangular(double lo, double la, double r, double *x, double *y, double *z) { *x = r * cosd(lo) * cosd(la); *y = r * sind(lo) * cosd(la); *z = r * sind(la); } void SolarSystemObject::toSpherical(double x, double y, double z, double *lo, double *la, double *r) { *r = sqrt(x * x + y * y + z * z); *la = asind(z / *r); *lo = rev(atan2d(y, x)); } QPair SolarSystemObject::zeroPoints(QPointF p1, QPointF p2, QPointF p3) { double a = ((p2.y() - p1.y()) * (p1.x() - p3.x()) + (p3.y() - p1.y()) * (p2.x() - p1.x())) / ((p1.x() - p3.x()) * (p2.x() * p2.x() - p1.x() * p1.x()) + (p2.x() - p1.x()) * (p3.x() * p3.x() - p1.x() * p1.x())); double b = ((p2.y() - p1.y()) - a * (p2.x() * p2.x() - p1.x() * p1.x())) / (p2.x() - p1.x()); double c = p1.y() - a * p1.x() * p1.x() - b * p1.x(); double discriminant = b * b - 4.0 * a * c; double z1 = -1.0, z2 = -1.0; if (discriminant >= 0.0) { z1 = (-b + sqrt(discriminant)) / (2 * a); z2 = (-b - sqrt(discriminant)) / (2 * a); } return QPair(z1, z2); } QList> SolarSystemObject::timesForAngles(const QList &angles, const QDateTime &dt, int offset) { QList altitudes; QDate d = dt.date(); QDateTime local(d, QTime(0, 0)); for (int j = 0; j <= 25; ++j) { calcForDateTime(local, offset); altitudes.append(altitude()); local = local.addSecs(60 * 60); } QList> result; QTime rise, set; foreach (double angle, angles) { for (int j = 3; j <= 25; j += 2) { QPointF p1((j - 2) * 60 * 60, altitudes[j - 2] - angle); QPointF p2((j - 1) * 60 * 60, altitudes[j - 1] - angle); QPointF p3(j * 60 * 60, altitudes[j] - angle); QPair z = zeroPoints(p1, p2, p3); if (z.first > p1.x() && z.first < p3.x()) { if (p1.y() < 0.0) { rise = QTime(0, 0).addSecs(z.first); } else { set = QTime(0, 0).addSecs(z.first); } } if (z.second > p1.x() && z.second < p3.x()) { if (p3.y() < 0.0) { set = QTime(0, 0).addSecs(z.second); } else { rise = QTime(0, 0).addSecs(z.second); } } } result.append(QPair(QDateTime(d, rise), QDateTime(d, set))); } return result; } double SolarSystemObject::calcElevation() { double refractionCorrection; if (m_altitude > 85.0) { refractionCorrection = 0.0; } else { double te = tand(m_altitude); if (m_altitude > 5.0) { refractionCorrection = 58.1 / te - 0.07 / (te * te * te) + 0.000086 / (te * te * te * te * te); } else if (m_altitude > -0.575) { refractionCorrection = 1735.0 + m_altitude * (-518.2 + m_altitude * (103.4 + m_altitude * (-12.79 + m_altitude * 0.711))); } else { refractionCorrection = -20.774 / te; } refractionCorrection = refractionCorrection / 3600.0; } return m_altitude + refractionCorrection; }