yodaUtility/sgp4/cEci.cpp

//
// cEci.cpp
//
// Copyright (c) 2002-2003 Michael F. Henry
//
#include "stdafx.h"

#include "cEci.h"
#include "globals.h"

//////////////////////////////////////////////////////////////////////
// cEci Class
//////////////////////////////////////////////////////////////////////
cEci::cEci(const cVector &pos, 
           const cVector &vel, 
           const cJulian &date,
           bool  IsAeUnits /* = true */)
{
   m_pos      = pos;
   m_vel      = vel;
   m_date     = date;
   m_VecUnits = (IsAeUnits ? UNITS_AE : UNITS_NONE);
}

//////////////////////////////////////////////////////////////////////
// cEci(cCoordGeo&, cJulian&)
// Calculate the ECI coordinates of the location "geo" at time "date".
// Assumes geo coordinates are km-based.
// Assumes the earth is an oblate spheroid as defined in WGS '72.
// Reference: The 1992 Astronomical Almanac, page K11
// Reference: www.celestrak.com (Dr. TS Kelso)
cEci::cEci(const cCoordGeo &geo, const cJulian &date)
{
   m_VecUnits = UNITS_KM;

   double mfactor = TWOPI * (OMEGA_E / SEC_PER_DAY);
   double lat = geo.m_Lat;
   double lon = geo.m_Lon;
   double alt = geo.m_Alt;

   // Calculate Local Mean Sidereal Time (theta)
   double theta = date.toLMST(lon);
   double c = 1.0 / sqrt(1.0 + F * (F - 2.0) * sqr(sin(lat)));
   double s = sqr(1.0 - F) * c;
   double achcp = (XKMPER_WGS72 * c + alt) * cos(lat);

   m_date = date;

   m_pos.m_x = achcp * cos(theta);               // km
   m_pos.m_y = achcp * sin(theta);               // km
   m_pos.m_z = (XKMPER_WGS72 * s + alt) * sin(lat);   // km
   m_pos.m_w = sqrt(sqr(m_pos.m_x) + 
                    sqr(m_pos.m_y) + 
                    sqr(m_pos.m_z));            // range, km

   m_vel.m_x = -mfactor * m_pos.m_y;            // km / sec
   m_vel.m_y =  mfactor * m_pos.m_x;
   m_vel.m_z = 0.0;
   m_vel.m_w = sqrt(sqr(m_vel.m_x) +            // range rate km/sec^2
                    sqr(m_vel.m_y));
}

//////////////////////////////////////////////////////////////////////////////
// toGeo()
// Return the corresponding geodetic position (based on the current ECI
// coordinates/Julian date).
// Assumes the earth is an oblate spheroid as defined in WGS '72.
// Side effects: Converts the position and velocity vectors to km-based units.
// Reference: The 1992 Astronomical Almanac, page K12. 
// Reference: www.celestrak.com (Dr. TS Kelso)
cCoordGeo cEci::toGeo()
{
   ae2km(); // Vectors must be in kilometer-based units

   double theta = AcTan(m_pos.m_y, m_pos.m_x);
   double lon   = fmod(theta - m_date.toGMST(), TWOPI);
   
   if (lon < 0.0) 
      lon += TWOPI;  // "wrap" negative modulo

   double r   = sqrt(sqr(m_pos.m_x) + sqr(m_pos.m_y));
   double e2  = F * (2.0 - F);
   double lat = AcTan(m_pos.m_z, r);

   const double delta = 1.0e-07;
   double phi;
   double c;

   do   
   {
      phi = lat;
      c   = 1.0 / sqrt(1.0 - e2 * sqr(sin(phi)));
      lat = AcTan(m_pos.m_z + XKMPER_WGS72 * c * e2 * sin(phi), r);
   }
   while (fabs(lat - phi) > delta);
   
   double alt = r / cos(lat) - XKMPER_WGS72 * c;

   return cCoordGeo(lat, lon, alt); // radians, radians, kilometers
}

//////////////////////////////////////////////////////////////////////////////
// ae2km()
// Convert the position and velocity vector units from AE-based units
// to kilometer based units.
void cEci::ae2km()
{
   if (UnitsAreAe())
   {
      MulPos(XKMPER_WGS72 / AE);                       // km
      MulVel((XKMPER_WGS72 / AE) * (MIN_PER_DAY / 86400));  // km/sec
      m_VecUnits = UNITS_KM;
   }
}
1	kusanagi	1.1	//
2			// cEci.cpp
3			//
4			// Copyright (c) 2002-2003 Michael F. Henry
5			//
6			#include "stdafx.h"
7
8			#include "cEci.h"
9			#include "globals.h"
10
11			//////////////////////////////////////////////////////////////////////
12			// cEci Class
13			//////////////////////////////////////////////////////////////////////
14			cEci::cEci(const cVector &pos,
15			const cVector &vel,
16			const cJulian &date,
17			bool IsAeUnits /* = true */)
18			{
19			m_pos = pos;
20			m_vel = vel;
21			m_date = date;
22			m_VecUnits = (IsAeUnits ? UNITS_AE : UNITS_NONE);
23			}
24
25			//////////////////////////////////////////////////////////////////////
26			// cEci(cCoordGeo&, cJulian&)
27			// Calculate the ECI coordinates of the location "geo" at time "date".
28			// Assumes geo coordinates are km-based.
29			// Assumes the earth is an oblate spheroid as defined in WGS '72.
30			// Reference: The 1992 Astronomical Almanac, page K11
31			// Reference: www.celestrak.com (Dr. TS Kelso)
32			cEci::cEci(const cCoordGeo &geo, const cJulian &date)
33			{
34			m_VecUnits = UNITS_KM;
35
36			double mfactor = TWOPI * (OMEGA_E / SEC_PER_DAY);
37			double lat = geo.m_Lat;
38			double lon = geo.m_Lon;
39			double alt = geo.m_Alt;
40
41			// Calculate Local Mean Sidereal Time (theta)
42			double theta = date.toLMST(lon);
43			double c = 1.0 / sqrt(1.0 + F * (F - 2.0) * sqr(sin(lat)));
44			double s = sqr(1.0 - F) * c;
45			double achcp = (XKMPER_WGS72 * c + alt) * cos(lat);
46
47			m_date = date;
48
49			m_pos.m_x = achcp * cos(theta); // km
50			m_pos.m_y = achcp * sin(theta); // km
51			m_pos.m_z = (XKMPER_WGS72 * s + alt) * sin(lat); // km
52			m_pos.m_w = sqrt(sqr(m_pos.m_x) +
53			sqr(m_pos.m_y) +
54			sqr(m_pos.m_z)); // range, km
55
56			m_vel.m_x = -mfactor * m_pos.m_y; // km / sec
57			m_vel.m_y = mfactor * m_pos.m_x;
58			m_vel.m_z = 0.0;
59			m_vel.m_w = sqrt(sqr(m_vel.m_x) + // range rate km/sec^2
60			sqr(m_vel.m_y));
61			}
62
63			//////////////////////////////////////////////////////////////////////////////
64			// toGeo()
65			// Return the corresponding geodetic position (based on the current ECI
66			// coordinates/Julian date).
67			// Assumes the earth is an oblate spheroid as defined in WGS '72.
68			// Side effects: Converts the position and velocity vectors to km-based units.
69			// Reference: The 1992 Astronomical Almanac, page K12.
70			// Reference: www.celestrak.com (Dr. TS Kelso)
71			cCoordGeo cEci::toGeo()
72			{
73			ae2km(); // Vectors must be in kilometer-based units
74
75			double theta = AcTan(m_pos.m_y, m_pos.m_x);
76			double lon = fmod(theta - m_date.toGMST(), TWOPI);
77
78			if (lon < 0.0)
79			lon += TWOPI; // "wrap" negative modulo
80
81			double r = sqrt(sqr(m_pos.m_x) + sqr(m_pos.m_y));
82			double e2 = F * (2.0 - F);
83			double lat = AcTan(m_pos.m_z, r);
84
85			const double delta = 1.0e-07;
86			double phi;
87			double c;
88
89			do
90			{
91			phi = lat;
92			c = 1.0 / sqrt(1.0 - e2 * sqr(sin(phi)));
93			lat = AcTan(m_pos.m_z + XKMPER_WGS72 * c * e2 * sin(phi), r);
94			}
95			while (fabs(lat - phi) > delta);
96
97			double alt = r / cos(lat) - XKMPER_WGS72 * c;
98
99			return cCoordGeo(lat, lon, alt); // radians, radians, kilometers
100			}
101
102			//////////////////////////////////////////////////////////////////////////////
103			// ae2km()
104			// Convert the position and velocity vector units from AE-based units
105			// to kilometer based units.
106			void cEci::ae2km()
107			{
108			if (UnitsAreAe())
109			{
110			MulPos(XKMPER_WGS72 / AE); // km
111			MulVel((XKMPER_WGS72 / AE) * (MIN_PER_DAY / 86400)); // km/sec
112			m_VecUnits = UNITS_KM;
113			}
114			}