#include <math.h>
#include <GL/glut.h>
+#include "../XGL/xgl.h"
#include "orbits.h"
#include "moon.h"
-#include "../general.h"
+#include "../Aircraft/aircraft.h"
+#include "../Include/general.h"
#include "../Main/views.h"
#include "../Time/fg_time.h"
struct CelestialCoord moonPos;
-float xMoon, yMoon, zMoon;
-GLint moon;
+static float xMoon, yMoon, zMoon;
+static GLint moon;
/*
static GLfloat vdata[12][3] =
void drawTriangle(float *v1, float *v2, float *v3)
{
- glBegin(GL_POLYGON);
- //glBegin(GL_POINTS);
- glNormal3fv(v1);
- glVertex3fv(v1);
- glNormal3fv(v2);
- glVertex3fv(v2);
- glNormal3fv(v3);
- glVertex3fv(v3);
- glEnd();
+ xglBegin(GL_POLYGON);
+ //xglBegin(GL_POINTS);
+ xglNormal3fv(v1);
+ xglVertex3fv(v1);
+ xglNormal3fv(v2);
+ xglVertex3fv(v2);
+ xglNormal3fv(v3);
+ xglVertex3fv(v3);
+ xglEnd();
}
void subdivide(float *v1, float *v2, float *v3, long depth)
void display(void)
{
int i;
- glClear(GL_COLOR_BUFFER_BIT);
- glPushMatrix();
- glRotatef(spin, 0.0, 0.0, 0.0);
- glColor3f(1.0, 1.0, 0.0);
-// glBegin(GL_LINE_LOOP);
+ xglClear(GL_COLOR_BUFFER_BIT);
+ xglPushMatrix();
+ xglRotatef(spin, 0.0, 0.0, 0.0);
+ xglColor3f(1.0, 1.0, 0.0);
+// xglBegin(GL_LINE_LOOP);
for (i = 0; i < 20; i++)
{
- //glVertex3fv(&vdata[tindices[i][0]][0]);
- //glVertex3fv(&vdata[tindices[i][1]][0]);
- //glVertex3fv(&vdata[tindices[i][2]][0]);
+ //xglVertex3fv(&vdata[tindices[i][0]][0]);
+ //xglVertex3fv(&vdata[tindices[i][1]][0]);
+ //xglVertex3fv(&vdata[tindices[i][2]][0]);
subdivide(&vdata[tindices[i][0]][0],
&vdata[tindices[i][1]][0],
}
-// glEnd();
- // glFlush();
- glPopMatrix();
+// xglEnd();
+ // xglFlush();
+ xglPopMatrix();
glutSwapBuffers();
} */
struct OrbElements sunParams,
struct fgTIME t)
{
- struct CelestialCoord
- result;
-
- double
- eccAnom, ecl, lonecl, latecl, actTime,
- xv, yv, v, r, xh, yh, zh, xg, yg, zg, xe, ye, ze,
- Ls, Lm, D, F;
-
- /* calculate the angle between ecliptic and equatorial coordinate system */
- actTime = fgCalcActTime(t);
- ecl = fgDegToRad(23.4393 - 3.563E-7 * actTime); // in radians of course
-
- /* calculate the eccentric anomaly */
- eccAnom = fgCalcEccAnom(params.M, params.e);
-
- /* calculate the moon's distance (d) and true anomaly (v) */
- xv = params.a * ( cos(eccAnom) - params.e);
- yv = params.a * ( sqrt(1.0 - params.e*params.e) * sin(eccAnom));
- v =atan2(yv, xv);
- r = sqrt(xv*xv + yv*yv);
-
- /* estimate the geocentric rectangular coordinates here */
- xh = r * (cos(params.N) * cos(v + params.w) - sin(params.N) * sin(v + params.w) * cos(params.i));
- yh = r * (sin(params.N) * cos(v + params.w) + cos(params.N) * sin(v + params.w) * cos(params.i));
- zh = r * (sin(v + params.w) * sin(params.i));
-
- /* calculate the ecliptic latitude and longitude here */
- lonecl = atan2( yh, xh);
- latecl = atan2( zh, sqrt( xh*xh + yh*yh));
-
- /* calculate a number of perturbations */
- Ls = sunParams.M + sunParams.w;
- Lm = params.M + params.w + params.N;
- D = Lm - Ls;
- F = Lm - params.N;
-
- lonecl += fgDegToRad(
- - 1.274 * sin (params.M - 2*D) // the Evection
- + 0.658 * sin (2 * D) // the Variation
- - 0.186 * sin (sunParams.M) // the yearly variation
- - 0.059 * sin (2*params.M - 2*D)
- - 0.057 * sin (params.M - 2*D + sunParams.M)
- + 0.053 * sin (params.M + 2*D)
- + 0.046 * sin (2*D - sunParams.M)
- + 0.041 * sin (params.M - sunParams.M)
- - 0.035 * sin (D) // the Parallactic Equation
- - 0.031 * sin (params.M + sunParams.M)
- - 0.015 * sin (2*F - 2*D)
- + 0.011 * sin (params.M - 4*D)
- ); /* Pheeuuwwww */
- latecl += fgDegToRad(
- - 0.173 * sin (F - 2*D)
- - 0.055 * sin (params.M - F - 2*D)
- - 0.046 * sin (params.M + F - 2*D)
- + 0.033 * sin (F + 2*D)
- + 0.017 * sin (2 * params.M + F)
- ); /* Yep */
-
- r += (
- - 0.58 * cos(params.M - 2*D)
- - 0.46 * cos(2*D)
- ); /* Ok! */
-
- xg = r * cos(lonecl) * cos(latecl);
- yg = r * sin(lonecl) * cos(latecl);
- zg = r * sin(latecl);
-
- xe = xg;
- ye = yg * cos(ecl) - zg * sin(ecl);
- ze = yg * sin(ecl) + zg * cos(ecl);
-
- result.RightAscension = atan2(ye, xe);
- result.Declination = atan2(ze, sqrt(xe*xe + ye*ye));
- return result;
+ struct CelestialCoord
+ geocCoord, topocCoord;
+
+
+ double
+ eccAnom, ecl, lonecl, latecl, actTime,
+ xv, yv, v, r, xh, yh, zh, xg, yg, zg, xe, ye, ze,
+ Ls, Lm, D, F, mpar, gclat, rho, HA, g;
+
+ struct fgAIRCRAFT *a;
+ struct fgFLIGHT *f;
+
+ a = ¤t_aircraft;
+ f = &a->flight;
+
+/* calculate the angle between ecliptic and equatorial coordinate system */
+ actTime = fgCalcActTime(t);
+ ecl = fgDegToRad(23.4393 - 3.563E-7 * actTime); // in radians of course
+
+ /* calculate the eccentric anomaly */
+ eccAnom = fgCalcEccAnom(params.M, params.e);
+
+ /* calculate the moon's distance (d) and true anomaly (v) */
+ xv = params.a * ( cos(eccAnom) - params.e);
+ yv = params.a * ( sqrt(1.0 - params.e*params.e) * sin(eccAnom));
+ v =atan2(yv, xv);
+ r = sqrt(xv*xv + yv*yv);
+
+ /* estimate the geocentric rectangular coordinates here */
+ xh = r * (cos(params.N) * cos(v + params.w) - sin(params.N) * sin(v + params.w) * cos(params.i));
+ yh = r * (sin(params.N) * cos(v + params.w) + cos(params.N) * sin(v + params.w) * cos(params.i));
+ zh = r * (sin(v + params.w) * sin(params.i));
+
+ /* calculate the ecliptic latitude and longitude here */
+ lonecl = atan2( yh, xh);
+ latecl = atan2( zh, sqrt( xh*xh + yh*yh));
+
+ /* calculate a number of perturbations */
+ Ls = sunParams.M + sunParams.w;
+ Lm = params.M + params.w + params.N;
+ D = Lm - Ls;
+ F = Lm - params.N;
+
+ lonecl += fgDegToRad(
+ - 1.274 * sin (params.M - 2*D) // the Evection
+ + 0.658 * sin (2 * D) // the Variation
+ - 0.186 * sin (sunParams.M) // the yearly variation
+ - 0.059 * sin (2*params.M - 2*D)
+ - 0.057 * sin (params.M - 2*D + sunParams.M)
+ + 0.053 * sin (params.M + 2*D)
+ + 0.046 * sin (2*D - sunParams.M)
+ + 0.041 * sin (params.M - sunParams.M)
+ - 0.035 * sin (D) // the Parallactic Equation
+ - 0.031 * sin (params.M + sunParams.M)
+ - 0.015 * sin (2*F - 2*D)
+ + 0.011 * sin (params.M - 4*D)
+ ); /* Pheeuuwwww */
+ latecl += fgDegToRad(
+ - 0.173 * sin (F - 2*D)
+ - 0.055 * sin (params.M - F - 2*D)
+ - 0.046 * sin (params.M + F - 2*D)
+ + 0.033 * sin (F + 2*D)
+ + 0.017 * sin (2 * params.M + F)
+ ); /* Yep */
+
+ r += (
+ - 0.58 * cos(params.M - 2*D)
+ - 0.46 * cos(2*D)
+ ); /* Ok! */
+
+ xg = r * cos(lonecl) * cos(latecl);
+ yg = r * sin(lonecl) * cos(latecl);
+ zg = r * sin(latecl);
+
+ xe = xg;
+ ye = yg * cos(ecl) - zg * sin(ecl);
+ ze = yg * sin(ecl) + zg * cos(ecl);
+
+
+
+
+ geocCoord.RightAscension = atan2(ye, xe);
+ geocCoord.Declination = atan2(ze, sqrt(xe*xe + ye*ye));
+
+ /* New since 25 december 1997 */
+ /* Calculate the moon's topocentric position instead of it's geocentric! */
+
+ mpar = asin( 1 / r); /* calculate the moon's parrallax, i.e. the apparent size of the
+ (equatorial) radius of the Earth, as seen from the moon */
+ gclat = FG_Latitude - 0.083358 * sin (2 * fgDegToRad( FG_Latitude));
+ rho = 0.99883 + 0.00167 * cos(2 * fgDegToRad(FG_Latitude));
+
+ if (geocCoord.RightAscension < 0)
+ geocCoord.RightAscension += (2*M_PI);
+
+ HA = t.lst - (3.8197186 * geocCoord.RightAscension);
+
+ g = atan (tan(gclat) / cos( (HA / 3.8197186)));
+
+
+
+ topocCoord.RightAscension = geocCoord.RightAscension - mpar * rho * cos(gclat) * sin(HA) / cos(geocCoord.Declination);
+ topocCoord.Declination = geocCoord.Declination - mpar * rho * sin(gclat) * sin(g - geocCoord.Declination) / sin(g);
+ return topocCoord;
}
void fgMoonInit() {
struct fgLIGHT *l;
-// int i;
+ static int dl_exists = 0;
- l = &cur_light_params;
-
- moon = glGenLists(1);
- glNewList(moon, GL_COMPILE );
+ printf("Initializing the Moon\n");
- /* glMaterialfv(GL_FRONT, GL_AMBIENT, l->scene_clear);
- glMaterialfv(GL_FRONT, GL_DIFFUSE, moon_color); */
+ l = &cur_light_params;
+ /* position the moon */
fgSolarSystemUpdate(&(pltOrbElements[1]), cur_time_params);
moonPos = fgCalculateMoon(pltOrbElements[1], pltOrbElements[0],
cur_time_params);
moonPos.Declination);
#endif
- /* xMoon = 90000.0 * cos(moonPos.RightAscension) * cos(moonPos.Declination);
- yMoon = 90000.0 * sin(moonPos.RightAscension) * cos(moonPos.Declination);
- zMoon = 90000.0 * sin(moonPos.Declination); */
+ if ( !dl_exists ) {
+ dl_exists = 1;
+
+ /* printf("First time through, creating moon display list\n"); */
+
+ moon = xglGenLists(1);
+ xglNewList(moon, GL_COMPILE );
+
+ /* xglMaterialfv(GL_FRONT, GL_AMBIENT, l->scene_clear);
+ xglMaterialfv(GL_FRONT, GL_DIFFUSE, moon_color); */
- xMoon = 60000.0 * cos(moonPos.RightAscension) * cos(moonPos.Declination);
- yMoon = 60000.0 * sin(moonPos.RightAscension) * cos(moonPos.Declination);
- zMoon = 60000.0 * sin(moonPos.Declination);
- glutSolidSphere(1.0, 15, 15);
+ xMoon = 60000.0 * cos(moonPos.RightAscension) *
+ cos(moonPos.Declination);
+ yMoon = 60000.0 * sin(moonPos.RightAscension) *
+ cos(moonPos.Declination);
+ zMoon = 60000.0 * sin(moonPos.Declination);
- glEndList();
+ glutSolidSphere(1.0, 10, 10);
+
+ xglEndList();
+ }
}
/* Draw the moon */
void fgMoonRender() {
struct fgLIGHT *l;
- GLfloat black[4] = { 0.0, 0.0, 0.0, 1.0 };
- GLfloat moon_color[4] = { 1.0, 1.0, 1.0, 1.0 };
+ GLfloat white[4] = { 1.0, 1.0, 1.0, 1.0 };
l = &cur_light_params;
- /* set lighting parameters */
- glLightfv(GL_LIGHT0, GL_AMBIENT, l->scene_clear );
- glLightfv(GL_LIGHT0, GL_DIFFUSE, moon_color );
-
- glMaterialfv(GL_FRONT, GL_AMBIENT, l->scene_clear );
- glMaterialfv(GL_FRONT, GL_AMBIENT, moon_color );
- glMaterialfv(GL_FRONT, GL_DIFFUSE, moon_color);
+ xglMaterialfv(GL_FRONT, GL_AMBIENT, l->sky_color );
+ xglMaterialfv(GL_FRONT, GL_DIFFUSE, white);
- glPushMatrix();
- glTranslatef(xMoon, yMoon, zMoon);
- glScalef(1400, 1400, 1400);
+ xglPushMatrix();
+ xglTranslatef(xMoon, yMoon, zMoon);
+ xglScalef(1400, 1400, 1400);
- glColor3fv(moon_color);
- /* glutSolidSphere(1.0, 25, 25); */
- glCallList(moon);
+ xglCallList(moon);
- glPopMatrix();
+ xglPopMatrix();
}
+
+/* $Log$
+/* Revision 1.14 1997/12/30 20:47:50 curt
+/* Integrated new event manager with subsystem initializations.
+/*
+ * Revision 1.13 1997/12/30 16:41:00 curt
+ * Added log at end of file.
+ *
+ */