public static AASBinaryStarDetails Calculate(double t, double P, double T, double e, double a, double i, double omega, double w)
{
double n = 360 / P;
double M = AASCoordinateTransformation.MapTo0To360Range(n * (t - T));
double E = AASKepler.Calculate(M, e);
E = AASCoordinateTransformation.DegreesToRadians(E);
i = AASCoordinateTransformation.DegreesToRadians(i);
w = AASCoordinateTransformation.DegreesToRadians(w);
omega = AASCoordinateTransformation.DegreesToRadians(omega);
AASBinaryStarDetails details = new AASBinaryStarDetails {
r = a * (1 - e * Math.Cos(E))
};
double v = Math.Atan(Math.Sqrt((1 + e) / (1 - e)) * Math.Tan(E / 2)) * 2;
details.Theta = Math.Atan2(Math.Sin(v + w) * Math.Cos(i), Math.Cos(v + w)) + omega;
details.Theta = AASCoordinateTransformation.MapTo0To360Range(AASCoordinateTransformation.RadiansToDegrees(details.Theta));
double sinvw = Math.Sin(v + w);
double cosvw = Math.Cos(v + w);
double cosi = Math.Cos(i);
details.Rho = details.r * Math.Sqrt((sinvw * sinvw * cosi * cosi) + (cosvw * cosvw));
return(details);
}
public static AASEllipticalObjectDetails Calculate(double JD, ref AASEllipticalObjectElements elements, bool bHighPrecision)
{
double Epsilon = AASNutation.MeanObliquityOfEcliptic(elements.JDEquinox);
double JD0 = JD;
//What will be the return value
AASEllipticalObjectDetails details = new AASEllipticalObjectDetails();
Epsilon = AASCoordinateTransformation.DegreesToRadians(Epsilon);
double omega = AASCoordinateTransformation.DegreesToRadians(elements.omega);
double w = AASCoordinateTransformation.DegreesToRadians(elements.w);
double i = AASCoordinateTransformation.DegreesToRadians(elements.i);
double sinEpsilon = Math.Sin(Epsilon);
double cosEpsilon = Math.Cos(Epsilon);
double sinOmega = Math.Sin(omega);
double cosOmega = Math.Cos(omega);
double cosi = Math.Cos(i);
double sini = Math.Sin(i);
double F = cosOmega;
double G = sinOmega * cosEpsilon;
double H = sinOmega * sinEpsilon;
double P = -sinOmega * cosi;
double Q = cosOmega * cosi * cosEpsilon - sini * sinEpsilon;
double R = cosOmega * cosi * sinEpsilon + sini * cosEpsilon;
double a = Math.Sqrt(F * F + P * P);
double b = Math.Sqrt(G * G + Q * Q);
double c = Math.Sqrt(H * H + R * R);
double A = Math.Atan2(F, P);
double B = Math.Atan2(G, Q);
double C = Math.Atan2(H, R);
double n = AASElliptical.MeanMotionFromSemiMajorAxis(elements.a);
AAS3DCoordinate SunCoord = AASSun.EquatorialRectangularCoordinatesAnyEquinox(JD, elements.JDEquinox, bHighPrecision);
for (int j = 0; j < 2; j++)
{
double M = n * (JD0 - elements.T);
double E = AASKepler.Calculate(M, elements.e);
E = AASCoordinateTransformation.DegreesToRadians(E);
double v = 2 * Math.Atan(Math.Sqrt((1 + elements.e) / (1 - elements.e)) * Math.Tan(E / 2));
double r = elements.a * (1 - elements.e * Math.Cos(E));
double x = r * a * Math.Sin(A + w + v);
double y = r * b * Math.Sin(B + w + v);
double z = r * c * Math.Sin(C + w + v);
if (j == 0)
{
details.HeliocentricRectangularEquatorial = new AAS3DCoordinate {
X = x, Y = y, Z = z
};
//Calculate the heliocentric ecliptic coordinates also
double u = w + v;
double cosu = Math.Cos(u);
double sinu = Math.Sin(u);
details.HeliocentricRectangularEcliptical = new AAS3DCoordinate
{
X = r * (cosOmega * cosu - sinOmega * sinu * cosi),
Y = r * (sinOmega * cosu + cosOmega * sinu * cosi),
Z = r * sini * sinu
};
details.HeliocentricEclipticLongitude = AASCoordinateTransformation.MapTo0To360Range(AASCoordinateTransformation.RadiansToDegrees(Math.Atan2(details.HeliocentricRectangularEcliptical.Y, details.HeliocentricRectangularEcliptical.X)));
details.HeliocentricEclipticLatitude = AASCoordinateTransformation.RadiansToDegrees(Math.Asin(details.HeliocentricRectangularEcliptical.Z / r));
}
double psi = SunCoord.X + x;
double nu = SunCoord.Y + y;
double sigma = SunCoord.Z + z;
double Alpha = Math.Atan2(nu, psi);
Alpha = AASCoordinateTransformation.RadiansToDegrees(Alpha);
double Delta = Math.Atan2(sigma, Math.Sqrt(psi * psi + nu * nu));
Delta = AASCoordinateTransformation.RadiansToDegrees(Delta);
double Distance = Math.Sqrt(psi * psi + nu * nu + sigma * sigma);
if (j == 0)
{
details.TrueGeocentricRA = AASCoordinateTransformation.MapTo0To24Range(Alpha / 15);
details.TrueGeocentricDeclination = Delta;
details.TrueGeocentricDistance = Distance;
details.TrueGeocentricLightTime = DistanceToLightTime(Distance);
}
else
{
details.AstrometricGeocentricRA = AASCoordinateTransformation.MapTo0To24Range(Alpha / 15);
details.AstrometricGeocentricDeclination = Delta;
details.AstrometricGeocentricDistance = Distance;
details.AstrometricGeocentricLightTime = DistanceToLightTime(Distance);
double RES = Math.Sqrt(SunCoord.X * SunCoord.X + SunCoord.Y * SunCoord.Y + SunCoord.Z * SunCoord.Z);
details.Elongation = Math.Acos((RES * RES + Distance * Distance - r * r) / (2 * RES * Distance));
details.Elongation = AASCoordinateTransformation.RadiansToDegrees(details.Elongation);
details.PhaseAngle = Math.Acos((r * r + Distance * Distance - RES * RES) / (2 * r * Distance));
details.PhaseAngle = AASCoordinateTransformation.RadiansToDegrees(details.PhaseAngle);
}
if (j == 0)
{
//Prepare for the next loop around
JD0 = JD - details.TrueGeocentricLightTime;
}
}
return(details);
}
