use of org.orekit.propagation.conversion.FiniteDifferencePropagatorConverter in project Orekit by CS-SI.
the class EcksteinHechlerPropagatorTest method testInitializationCorrectness.
@Test
public void testInitializationCorrectness() throws OrekitException, IOException {
// Definition of initial conditions
AbsoluteDate date = AbsoluteDate.J2000_EPOCH.shiftedBy(154.);
Frame itrf = FramesFactory.getITRF(IERSConventions.IERS_2010, true);
Frame eme2000 = FramesFactory.getEME2000();
Vector3D pole = itrf.getTransformTo(eme2000, date).transformVector(Vector3D.PLUS_K);
Frame poleAligned = new Frame(FramesFactory.getEME2000(), new Transform(date, new Rotation(pole, Vector3D.PLUS_K)), "pole aligned", true);
CircularOrbit initial = new CircularOrbit(7208669.8179538045, 1.3740461966386876E-4, -3.2364250248363356E-5, FastMath.toRadians(97.40236024565775), FastMath.toRadians(166.15873160992115), FastMath.toRadians(90.1282370098961), PositionAngle.MEAN, poleAligned, date, provider.getMu());
// find the default Eckstein-Hechler propagator initialized from the initial orbit
EcksteinHechlerPropagator defaultEH = new EcksteinHechlerPropagator(initial, provider);
// the osculating parameters recomputed by the default Eckstein-Hechler propagator are quite different
// from initial orbit
CircularOrbit defaultOrbit = (CircularOrbit) OrbitType.CIRCULAR.convertType(defaultEH.propagateOrbit(initial.getDate()));
Assert.assertEquals(267.4, defaultOrbit.getA() - initial.getA(), 0.1);
// the position on the other hand match perfectly
Assert.assertEquals(0.0, Vector3D.distance(defaultOrbit.getPVCoordinates().getPosition(), initial.getPVCoordinates().getPosition()), 1.0e-8);
// set up a reference numerical propagator starting for the specified start orbit
// using the same force models (i.e. the first few zonal terms)
double[][] tol = NumericalPropagator.tolerances(0.1, initial, OrbitType.CIRCULAR);
AdaptiveStepsizeIntegrator integrator = new DormandPrince853Integrator(0.001, 1000, tol[0], tol[1]);
integrator.setInitialStepSize(60);
NumericalPropagator num = new NumericalPropagator(integrator);
num.addForceModel(new HolmesFeatherstoneAttractionModel(itrf, GravityFieldFactory.getNormalizedProvider(provider)));
num.setInitialState(new SpacecraftState(initial));
num.setOrbitType(OrbitType.CIRCULAR);
// find the best Eckstein-Hechler propagator that match the orbit evolution
PropagatorConverter converter = new FiniteDifferencePropagatorConverter(new EcksteinHechlerPropagatorBuilder(initial, provider, PositionAngle.TRUE, 1.0), 1.0e-6, 100);
EcksteinHechlerPropagator fittedEH = (EcksteinHechlerPropagator) converter.convert(num, 3 * initial.getKeplerianPeriod(), 300);
// the default Eckstein-Hechler propagator did however quite a good job, as it found
// an orbit close to the best fitting
CircularOrbit fittedOrbit = (CircularOrbit) OrbitType.CIRCULAR.convertType(fittedEH.propagateOrbit(initial.getDate()));
Assert.assertEquals(0.623, defaultOrbit.getA() - fittedOrbit.getA(), 0.1);
// the position on the other hand are slightly different
// because the fitted orbit minimizes the residuals over a complete time span,
// not on a single point
Assert.assertEquals(58.0, Vector3D.distance(defaultOrbit.getPVCoordinates().getPosition(), fittedOrbit.getPVCoordinates().getPosition()), 0.1);
}
use of org.orekit.propagation.conversion.FiniteDifferencePropagatorConverter in project Orekit by CS-SI.
the class PropagatorConversion method main.
/**
* Program entry point.
* @param args program arguments (unused here)
*/
public static void main(String[] args) {
try {
// configure Orekit
File home = new File(System.getProperty("user.home"));
File orekitData = new File(home, "orekit-data");
if (!orekitData.exists()) {
System.err.format(Locale.US, "Failed to find %s folder%n", orekitData.getAbsolutePath());
System.err.format(Locale.US, "You need to download %s from the %s page and unzip it in %s for this tutorial to work%n", "orekit-data.zip", "https://www.orekit.org/forge/projects/orekit/files", home.getAbsolutePath());
System.exit(1);
}
DataProvidersManager manager = DataProvidersManager.getInstance();
manager.addProvider(new DirectoryCrawler(orekitData));
// gravity field
NormalizedSphericalHarmonicsProvider provider = GravityFieldFactory.getNormalizedProvider(2, 0);
double mu = provider.getMu();
// inertial frame
Frame inertialFrame = FramesFactory.getEME2000();
// Initial date
AbsoluteDate initialDate = new AbsoluteDate(2004, 01, 01, 23, 30, 00.000, TimeScalesFactory.getUTC());
// Initial orbit (GTO)
// semi major axis in meters
final double a = 24396159;
// eccentricity
final double e = 0.72831215;
// inclination
final double i = FastMath.toRadians(7);
// perigee argument
final double omega = FastMath.toRadians(180);
// right ascention of ascending node
final double raan = FastMath.toRadians(261);
// mean anomaly
final double lM = 0;
Orbit initialOrbit = new KeplerianOrbit(a, e, i, omega, raan, lM, PositionAngle.MEAN, inertialFrame, initialDate, mu);
final double period = initialOrbit.getKeplerianPeriod();
// Initial state definition
final SpacecraftState initialState = new SpacecraftState(initialOrbit);
// Adaptive step integrator with a minimum step of 0.001 and a maximum step of 1000
final double minStep = 0.001;
final double maxStep = 1000.;
final double dP = 1.e-2;
final OrbitType orbType = OrbitType.CARTESIAN;
final double[][] tol = NumericalPropagator.tolerances(dP, initialOrbit, orbType);
final AbstractIntegrator integrator = new DormandPrince853Integrator(minStep, maxStep, tol[0], tol[1]);
// Propagator
NumericalPropagator numProp = new NumericalPropagator(integrator);
numProp.setInitialState(initialState);
numProp.setOrbitType(orbType);
// Force Models:
// 1 - Perturbing gravity field (only J2 is considered here)
ForceModel gravity = new HolmesFeatherstoneAttractionModel(FramesFactory.getITRF(IERSConventions.IERS_2010, true), provider);
// Add force models to the propagator
numProp.addForceModel(gravity);
// Propagator factory
PropagatorBuilder builder = new KeplerianPropagatorBuilder(initialOrbit, PositionAngle.TRUE, dP);
// Propagator converter
PropagatorConverter fitter = new FiniteDifferencePropagatorConverter(builder, 1.e-6, 5000);
// Resulting propagator
KeplerianPropagator kepProp = (KeplerianPropagator) fitter.convert(numProp, 2 * period, 251);
// Step handlers
StatesHandler numStepHandler = new StatesHandler();
StatesHandler kepStepHandler = new StatesHandler();
// Set up operating mode for the propagator as master mode
// with fixed step and specialized step handler
numProp.setMasterMode(60., numStepHandler);
kepProp.setMasterMode(60., kepStepHandler);
// Extrapolate from the initial to the final date
numProp.propagate(initialDate.shiftedBy(10. * period));
kepProp.propagate(initialDate.shiftedBy(10. * period));
// retrieve the states
List<SpacecraftState> numStates = numStepHandler.getStates();
List<SpacecraftState> kepStates = kepStepHandler.getStates();
// Print the results on the output file
File output = new File(new File(System.getProperty("user.home")), "elements.dat");
try (final PrintStream stream = new PrintStream(output, "UTF-8")) {
stream.println("# date Anum Akep Enum Ekep Inum Ikep LMnum LMkep");
for (SpacecraftState numState : numStates) {
for (SpacecraftState kepState : kepStates) {
if (numState.getDate().compareTo(kepState.getDate()) == 0) {
stream.println(numState.getDate() + " " + numState.getA() + " " + kepState.getA() + " " + numState.getE() + " " + kepState.getE() + " " + FastMath.toDegrees(numState.getI()) + " " + FastMath.toDegrees(kepState.getI()) + " " + FastMath.toDegrees(MathUtils.normalizeAngle(numState.getLM(), FastMath.PI)) + " " + FastMath.toDegrees(MathUtils.normalizeAngle(kepState.getLM(), FastMath.PI)));
break;
}
}
}
}
System.out.println("Results saved as file " + output);
File output1 = new File(new File(System.getProperty("user.home")), "elts_pv.dat");
try (final PrintStream stream = new PrintStream(output1, "UTF-8")) {
stream.println("# date pxn pyn pzn vxn vyn vzn pxk pyk pzk vxk vyk vzk");
for (SpacecraftState numState : numStates) {
for (SpacecraftState kepState : kepStates) {
if (numState.getDate().compareTo(kepState.getDate()) == 0) {
final double pxn = numState.getPVCoordinates().getPosition().getX();
final double pyn = numState.getPVCoordinates().getPosition().getY();
final double pzn = numState.getPVCoordinates().getPosition().getZ();
final double vxn = numState.getPVCoordinates().getVelocity().getX();
final double vyn = numState.getPVCoordinates().getVelocity().getY();
final double vzn = numState.getPVCoordinates().getVelocity().getZ();
final double pxk = kepState.getPVCoordinates().getPosition().getX();
final double pyk = kepState.getPVCoordinates().getPosition().getY();
final double pzk = kepState.getPVCoordinates().getPosition().getZ();
final double vxk = kepState.getPVCoordinates().getVelocity().getX();
final double vyk = kepState.getPVCoordinates().getVelocity().getY();
final double vzk = kepState.getPVCoordinates().getVelocity().getZ();
stream.println(numState.getDate() + " " + pxn + " " + pyn + " " + pzn + " " + vxn + " " + vyn + " " + vzn + " " + pxk + " " + pyk + " " + pzk + " " + vxk + " " + vyk + " " + vzk);
break;
}
}
}
}
System.out.println("Results saved as file " + output1);
} catch (OrekitException oe) {
System.err.println(oe.getLocalizedMessage());
System.exit(1);
} catch (IOException ioe) {
System.err.println(ioe.getLocalizedMessage());
System.exit(1);
}
}
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