LibrationOrbit.java
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package org.orekit.orbits;
import org.hipparchus.complex.Complex;
import org.hipparchus.geometry.euclidean.threed.Vector3D;
import org.hipparchus.linear.EigenDecompositionNonSymmetric;
import org.hipparchus.linear.FieldVector;
import org.hipparchus.linear.MatrixUtils;
import org.hipparchus.linear.RealMatrix;
import org.hipparchus.linear.RealVector;
import org.orekit.bodies.CR3BPSystem;
import org.orekit.propagation.SpacecraftState;
import org.orekit.propagation.numerical.cr3bp.STMEquations;
import org.orekit.utils.PVCoordinates;
/**
* Base class for libration orbits.
* @see HaloOrbit
* @see LyapunovOrbit
* @author Vincent Mouraux
* @author Bryan Cazabonne
* @since 10.2
*/
public abstract class LibrationOrbit {
/** CR3BP System of the libration Orbit. */
private final CR3BPSystem syst;
/** Position-Velocity initial position on a libration Orbit. */
private PVCoordinates initialPV;
/** Orbital Period of the libration Orbit. */
private double orbitalPeriod;
/**
* Constructor.
* @param system CR3BP System considered
* @param initialPV initial position on a libration Orbit
* @param orbitalPeriod initial orbital period of the libration Orbit
*/
protected LibrationOrbit(final CR3BPSystem system,
final PVCoordinates initialPV,
final double orbitalPeriod) {
this.syst = system;
this.initialPV = initialPV;
this.orbitalPeriod = orbitalPeriod;
}
/** Return the orbital period of the libration orbit.
* @return orbitalPeriod orbital period of the libration orbit
*/
public double getOrbitalPeriod() {
return orbitalPeriod;
}
/** Return the initialPV on the libration orbit.
* <p>
* This will return the exact initialPV only if you applied a prior
* differential correction. If you did not, you can use the method
* {@link #applyCorrectionOnPV(CR3BPDifferentialCorrection)}
* </p>
* @return initialPV initialPV on the libration orbit
*/
public PVCoordinates getInitialPV() {
return initialPV;
}
/** Apply differential correction.
* <p>
* This will update {@link #initialPV} and
* {@link #orbitalPeriod} parameters.
* </p>
*/
public void applyDifferentialCorrection() {
final CR3BPDifferentialCorrection diff = new CR3BPDifferentialCorrection(initialPV, syst, orbitalPeriod);
initialPV = applyCorrectionOnPV(diff);
orbitalPeriod = diff.getOrbitalPeriod();
}
/** Return a manifold direction from one position on a libration Orbit.
* @param s SpacecraftState with additional equations
* @param isStable true if the manifold is stable
* @return manifold first guess Position-Velocity of a point on the libration Orbit
*/
public PVCoordinates getManifolds(final SpacecraftState s, final boolean isStable) {
// Get the index of the eigen vector of the state transition matrix,
// depending on the stability or unstability of the manifold
final int eigenVectorIndex = isStable ? 1 : 0;
// Small delta, linked to the characteristic velocity of the CR3BP system
final double epsilon = syst.getVdim() * 1E2 / syst.getDdim();
// Get monodromy (i.e. state transition) matrix and its eigen decomposition
final RealMatrix phi = new STMEquations(syst).getStateTransitionMatrix(s);
final EigenDecompositionNonSymmetric eigen = new EigenDecompositionNonSymmetric(phi);
// Get normalized eigen vector linked to the stability of the manifold
final FieldVector<Complex> cv = eigen.getEigenvector(eigenVectorIndex);
// Get real vector value and normalize
final RealVector rv = MatrixUtils.createRealVector(cv.getDimension());
for (int i = 0; i < cv.getDimension(); ++i) {
rv.setEntry(i, cv.getEntry(i).getRealPart());
}
final RealVector eigenVector = rv.unitVector();
// New PVCoordinates following the manifold
return new PVCoordinates(s.getPosition().add(new Vector3D(eigenVector.getEntry(0),
eigenVector.getEntry(1),
eigenVector.getEntry(2)).scalarMultiply(epsilon)),
s.getPVCoordinates().getVelocity().add(new Vector3D(eigenVector.getEntry(3),
eigenVector.getEntry(4),
eigenVector.getEntry(5)).scalarMultiply(epsilon)));
}
/**
* Apply the differential correction to compute more accurate initial PV.
* @param diff cr3bp differential correction
* @return corrected PV coordinates
*/
protected abstract PVCoordinates applyCorrectionOnPV(CR3BPDifferentialCorrection diff);
}