Examples with TimeStampedPVCoordinates org.orekit.utils.TimeStampedPVCoordinates used on opensource projects

Example 76 with TimeStampedPVCoordinates

use of org.orekit.utils.TimeStampedPVCoordinates in project Orekit by CS-SI.

the class RangeAnalytic method theoreticalEvaluationValidation.

/**
 * Added for validation
 * Compares directly numeric and analytic computations
 * @param iteration
 * @param evaluation
 * @param state
 * @return
 * @throws OrekitException
 */
protected EstimatedMeasurement<Range> theoreticalEvaluationValidation(final int iteration, final int evaluation, final SpacecraftState state) throws OrekitException {
    // Station & DSFactory attributes from parent Range class
    final GroundStation groundStation = getStation();
    // get the number of parameters used for derivation
    int nbParams = 6;
    final Map<String, Integer> indices = new HashMap<>();
    for (ParameterDriver driver : getParametersDrivers()) {
        if (driver.isSelected()) {
            indices.put(driver.getName(), nbParams++);
        }
    }
    final DSFactory dsFactory = new DSFactory(nbParams, 1);
    final Field<DerivativeStructure> field = dsFactory.getDerivativeField();
    final FieldVector3D<DerivativeStructure> zero = FieldVector3D.getZero(field);
    // Range derivatives are computed with respect to spacecraft state in inertial frame
    // and station position in station's offset frame
    // -------
    // 
    // Parameters:
    // - 0..2 - Px, Py, Pz   : Position of the spacecraft in inertial frame
    // - 3..5 - Vx, Vy, Vz   : Velocity of the spacecraft in inertial frame
    // - 6..8 - QTx, QTy, QTz: Position of the station in station's offset frame
    // Coordinates of the spacecraft expressed as a derivative structure
    final TimeStampedFieldPVCoordinates<DerivativeStructure> pvaDS = getCoordinates(state, 0, dsFactory);
    // transform between station and inertial frame, expressed as a derivative structure
    // The components of station's position in offset frame are the 3 last derivative parameters
    final AbsoluteDate downlinkDate = getDate();
    final FieldAbsoluteDate<DerivativeStructure> downlinkDateDS = new FieldAbsoluteDate<>(field, downlinkDate);
    final FieldTransform<DerivativeStructure> offsetToInertialDownlink = groundStation.getOffsetToInertial(state.getFrame(), downlinkDateDS, dsFactory, indices);
    // Station position in inertial frame at end of the downlink leg
    final TimeStampedFieldPVCoordinates<DerivativeStructure> stationDownlink = offsetToInertialDownlink.transformPVCoordinates(new TimeStampedFieldPVCoordinates<>(downlinkDateDS, zero, zero, zero));
    // Compute propagation times
    // (if state has already been set up to pre-compensate propagation delay,
    // we will have offset == downlinkDelay and transitState will be
    // the same as state)
    // Downlink delay
    final DerivativeStructure tauD = signalTimeOfFlight(pvaDS, stationDownlink.getPosition(), downlinkDateDS);
    // Transit state
    final double delta = downlinkDate.durationFrom(state.getDate());
    final DerivativeStructure tauDMDelta = tauD.negate().add(delta);
    final SpacecraftState transitState = state.shiftedBy(tauDMDelta.getValue());
    // Transit state position (re)computed with derivative structures
    final TimeStampedFieldPVCoordinates<DerivativeStructure> transitStateDS = pvaDS.shiftedBy(tauDMDelta);
    // Station at transit state date (derivatives of tauD taken into account)
    final TimeStampedFieldPVCoordinates<DerivativeStructure> stationAtTransitDate = stationDownlink.shiftedBy(tauD.negate());
    // Uplink delay
    final DerivativeStructure tauU = signalTimeOfFlight(stationAtTransitDate, transitStateDS.getPosition(), transitStateDS.getDate());
    // Prepare the evaluation
    final EstimatedMeasurement<Range> estimated = new EstimatedMeasurement<Range>(this, iteration, evaluation, new SpacecraftState[] { transitState }, null);
    // Range value
    final DerivativeStructure tau = tauD.add(tauU);
    final double cOver2 = 0.5 * Constants.SPEED_OF_LIGHT;
    final DerivativeStructure range = tau.multiply(cOver2);
    estimated.setEstimatedValue(range.getValue());
    // Range partial derivatives with respect to state
    final double[] derivatives = range.getAllDerivatives();
    estimated.setStateDerivatives(0, Arrays.copyOfRange(derivatives, 1, 7));
    // (beware element at index 0 is the value, not a derivative)
    for (final ParameterDriver driver : getParametersDrivers()) {
        final Integer index = indices.get(driver.getName());
        if (index != null) {
            estimated.setParameterDerivatives(driver, derivatives[index + 1]);
        }
    }
    // ----------
    // VALIDATION
    // -----------
    // Computation of the value without DS
    // ----------------------------------
    // Time difference between t (date of the measurement) and t' (date tagged in spacecraft state)
    // Station position at signal arrival
    final Transform topoToInertDownlink = groundStation.getOffsetToInertial(state.getFrame(), downlinkDate);
    final PVCoordinates QDownlink = topoToInertDownlink.transformPVCoordinates(PVCoordinates.ZERO);
    // Downlink time of flight from spacecraft to station
    final double td = signalTimeOfFlight(state.getPVCoordinates(), QDownlink.getPosition(), downlinkDate);
    final double dt = delta - td;
    // Transit state position
    final AbsoluteDate transitT = state.getDate().shiftedBy(dt);
    final SpacecraftState transit = state.shiftedBy(dt);
    final Vector3D transitP = transitState.getPVCoordinates().getPosition();
    // Station position at signal departure
    // First guess
    // AbsoluteDate uplinkDate = downlinkDate.shiftedBy(-getObservedValue()[0] / cOver2);
    // final Transform topoToInertUplink =
    // station.getOffsetFrame().getTransformTo(state.getFrame(), uplinkDate);
    // TimeStampedPVCoordinates QUplink = topoToInertUplink.
    // transformPVCoordinates(new TimeStampedPVCoordinates(uplinkDate, PVCoordinates.ZERO));
    // Station position at transit state date
    final Transform topoToInertAtTransitDate = groundStation.getOffsetToInertial(state.getFrame(), transitT);
    TimeStampedPVCoordinates QAtTransitDate = topoToInertAtTransitDate.transformPVCoordinates(new TimeStampedPVCoordinates(transitT, PVCoordinates.ZERO));
    // Uplink time of flight
    final double tu = signalTimeOfFlight(QAtTransitDate, transitP, transitT);
    // Total time of flight
    final double t = td + tu;
    // Real date and position of station at signal departure
    AbsoluteDate uplinkDate = downlinkDate.shiftedBy(-t);
    TimeStampedPVCoordinates QUplink = topoToInertDownlink.shiftedBy(-t).transformPVCoordinates(new TimeStampedPVCoordinates(uplinkDate, PVCoordinates.ZERO));
    // Range value
    double r = t * cOver2;
    double dR = r - range.getValue();
    // td derivatives / state
    // -----------------------
    // Qt = Master station position at tmeas = t = signal arrival at master station
    final Vector3D vel = state.getPVCoordinates().getVelocity();
    final Vector3D Qt_V = QDownlink.getVelocity();
    final Vector3D Ptr = transit.getPVCoordinates().getPosition();
    final Vector3D Ptr_Qt = QDownlink.getPosition().subtract(Ptr);
    final double dDown = Constants.SPEED_OF_LIGHT * Constants.SPEED_OF_LIGHT * td - Vector3D.dotProduct(Ptr_Qt, vel);
    // Derivatives of the downlink time of flight
    final double dtddPx = -Ptr_Qt.getX() / dDown;
    final double dtddPy = -Ptr_Qt.getY() / dDown;
    final double dtddPz = -Ptr_Qt.getZ() / dDown;
    final double dtddVx = dtddPx * dt;
    final double dtddVy = dtddPy * dt;
    final double dtddVz = dtddPz * dt;
    // From the DS
    final double dtddPxDS = tauD.getPartialDerivative(1, 0, 0, 0, 0, 0, 0, 0, 0);
    final double dtddPyDS = tauD.getPartialDerivative(0, 1, 0, 0, 0, 0, 0, 0, 0);
    final double dtddPzDS = tauD.getPartialDerivative(0, 0, 1, 0, 0, 0, 0, 0, 0);
    final double dtddVxDS = tauD.getPartialDerivative(0, 0, 0, 1, 0, 0, 0, 0, 0);
    final double dtddVyDS = tauD.getPartialDerivative(0, 0, 0, 0, 1, 0, 0, 0, 0);
    final double dtddVzDS = tauD.getPartialDerivative(0, 0, 0, 0, 0, 1, 0, 0, 0);
    // Difference
    final double d_dtddPx = dtddPxDS - dtddPx;
    final double d_dtddPy = dtddPyDS - dtddPy;
    final double d_dtddPz = dtddPzDS - dtddPz;
    final double d_dtddVx = dtddVxDS - dtddVx;
    final double d_dtddVy = dtddVyDS - dtddVy;
    final double d_dtddVz = dtddVzDS - dtddVz;
    // tu derivatives / state
    // -----------------------
    final Vector3D Qt2_Ptr = Ptr.subtract(QUplink.getPosition());
    final double dUp = Constants.SPEED_OF_LIGHT * Constants.SPEED_OF_LIGHT * tu - Vector3D.dotProduct(Qt2_Ptr, Qt_V);
    // test
    // // Speed of the station at tmeas-t
    // // Note: Which one to use in the calculation of dUp ???
    // final Vector3D Qt2_V    = QUplink.getVelocity();
    // final double   dUp      = Constants.SPEED_OF_LIGHT * Constants.SPEED_OF_LIGHT * tu -
    // Vector3D.dotProduct(Qt2_Ptr, Qt2_V);
    // test
    // tu derivatives
    final double dtudPx = 1. / dUp * Qt2_Ptr.dotProduct(Vector3D.PLUS_I.add((Qt_V.subtract(vel)).scalarMultiply(dtddPx)));
    final double dtudPy = 1. / dUp * Qt2_Ptr.dotProduct(Vector3D.PLUS_J.add((Qt_V.subtract(vel)).scalarMultiply(dtddPy)));
    final double dtudPz = 1. / dUp * Qt2_Ptr.dotProduct(Vector3D.PLUS_K.add((Qt_V.subtract(vel)).scalarMultiply(dtddPz)));
    final double dtudVx = dtudPx * dt;
    final double dtudVy = dtudPy * dt;
    final double dtudVz = dtudPz * dt;
    // From the DS
    final double dtudPxDS = tauU.getPartialDerivative(1, 0, 0, 0, 0, 0, 0, 0, 0);
    final double dtudPyDS = tauU.getPartialDerivative(0, 1, 0, 0, 0, 0, 0, 0, 0);
    final double dtudPzDS = tauU.getPartialDerivative(0, 0, 1, 0, 0, 0, 0, 0, 0);
    final double dtudVxDS = tauU.getPartialDerivative(0, 0, 0, 1, 0, 0, 0, 0, 0);
    final double dtudVyDS = tauU.getPartialDerivative(0, 0, 0, 0, 1, 0, 0, 0, 0);
    final double dtudVzDS = tauU.getPartialDerivative(0, 0, 0, 0, 0, 1, 0, 0, 0);
    // Difference
    final double d_dtudPx = dtudPxDS - dtudPx;
    final double d_dtudPy = dtudPyDS - dtudPy;
    final double d_dtudPz = dtudPzDS - dtudPz;
    final double d_dtudVx = dtudVxDS - dtudVx;
    final double d_dtudVy = dtudVyDS - dtudVy;
    final double d_dtudVz = dtudVzDS - dtudVz;
    // Range derivatives / state
    // -----------------------
    // R = Range
    double dRdPx = (dtddPx + dtudPx) * cOver2;
    double dRdPy = (dtddPy + dtudPy) * cOver2;
    double dRdPz = (dtddPz + dtudPz) * cOver2;
    double dRdVx = (dtddVx + dtudVx) * cOver2;
    double dRdVy = (dtddVy + dtudVy) * cOver2;
    double dRdVz = (dtddVz + dtudVz) * cOver2;
    // With DS
    double dRdPxDS = range.getPartialDerivative(1, 0, 0, 0, 0, 0, 0, 0, 0);
    double dRdPyDS = range.getPartialDerivative(0, 1, 0, 0, 0, 0, 0, 0, 0);
    double dRdPzDS = range.getPartialDerivative(0, 0, 1, 0, 0, 0, 0, 0, 0);
    double dRdVxDS = range.getPartialDerivative(0, 0, 0, 1, 0, 0, 0, 0, 0);
    double dRdVyDS = range.getPartialDerivative(0, 0, 0, 0, 1, 0, 0, 0, 0);
    double dRdVzDS = range.getPartialDerivative(0, 0, 0, 0, 0, 1, 0, 0, 0);
    // Diff
    final double d_dRdPx = dRdPxDS - dRdPx;
    final double d_dRdPy = dRdPyDS - dRdPy;
    final double d_dRdPz = dRdPzDS - dRdPz;
    final double d_dRdVx = dRdVxDS - dRdVx;
    final double d_dRdVy = dRdVyDS - dRdVy;
    final double d_dRdVz = dRdVzDS - dRdVz;
    // td derivatives / station
    // -----------------------
    final AngularCoordinates ac = topoToInertDownlink.getAngular().revert();
    final Rotation rotTopoToInert = ac.getRotation();
    final Vector3D omega = ac.getRotationRate();
    final Vector3D dtddQI = Ptr_Qt.scalarMultiply(1. / dDown);
    final double dtddQIx = dtddQI.getX();
    final double dtddQIy = dtddQI.getY();
    final double dtddQIz = dtddQI.getZ();
    final Vector3D dtddQ = rotTopoToInert.applyTo(dtddQI);
    // With DS
    double dtddQxDS = tauD.getPartialDerivative(0, 0, 0, 0, 0, 0, 1, 0, 0);
    double dtddQyDS = tauD.getPartialDerivative(0, 0, 0, 0, 0, 0, 0, 1, 0);
    double dtddQzDS = tauD.getPartialDerivative(0, 0, 0, 0, 0, 0, 0, 0, 1);
    // Diff
    final double d_dtddQx = dtddQxDS - dtddQ.getX();
    final double d_dtddQy = dtddQyDS - dtddQ.getY();
    final double d_dtddQz = dtddQzDS - dtddQ.getZ();
    // tu derivatives / station
    // -----------------------
    // Inertial frame
    final double dtudQIx = 1 / dUp * Qt2_Ptr.dotProduct(Vector3D.MINUS_I.add((Qt_V.subtract(vel)).scalarMultiply(dtddQIx)).subtract(Vector3D.PLUS_I.crossProduct(omega).scalarMultiply(t)));
    final double dtudQIy = 1 / dUp * Qt2_Ptr.dotProduct(Vector3D.MINUS_J.add((Qt_V.subtract(vel)).scalarMultiply(dtddQIy)).subtract(Vector3D.PLUS_J.crossProduct(omega).scalarMultiply(t)));
    final double dtudQIz = 1 / dUp * Qt2_Ptr.dotProduct(Vector3D.MINUS_K.add((Qt_V.subtract(vel)).scalarMultiply(dtddQIz)).subtract(Vector3D.PLUS_K.crossProduct(omega).scalarMultiply(t)));
    // // test
    // final double dtudQIx = 1/dUp*Qt2_Ptr
    // //                        .dotProduct(Vector3D.MINUS_I);
    // //                                    .dotProduct((Qt_V.subtract(vel)).scalarMultiply(dtddQIx));
    // .dotProduct(Vector3D.MINUS_I.crossProduct(omega).scalarMultiply(t));
    // final double dtudQIy = 1/dUp*Qt2_Ptr
    // //                        .dotProduct(Vector3D.MINUS_J);
    // //                                    .dotProduct((Qt_V.subtract(vel)).scalarMultiply(dtddQIy));
    // .dotProduct(Vector3D.MINUS_J.crossProduct(omega).scalarMultiply(t));
    // final double dtudQIz = 1/dUp*Qt2_Ptr
    // //                        .dotProduct(Vector3D.MINUS_K);
    // //                                    .dotProduct((Qt_V.subtract(vel)).scalarMultiply(dtddQIz));
    // .dotProduct(Vector3D.MINUS_K.crossProduct(omega).scalarMultiply(t));
    // 
    // double dtu_dQxDS = tauU.getPartialDerivative(0, 0, 0, 0, 0, 0, 1, 0, 0);
    // double dtu_dQyDS = tauU.getPartialDerivative(0, 0, 0, 0, 0, 0, 0, 1, 0);
    // double dtu_dQzDS = tauU.getPartialDerivative(0, 0, 0, 0, 0, 0, 0, 0, 1);
    // final Vector3D dtudQDS = new Vector3D(dtu_dQxDS, dtu_dQyDS, dtu_dQzDS);
    // final Vector3D dtudQIDS = rotTopoToInert.applyInverseTo(dtudQDS);
    // double dtudQIxDS = dtudQIDS.getX();
    // double dtudQIyDS = dtudQIDS.getY();
    // double dtudQIxzS = dtudQIDS.getZ();
    // // test
    // Topocentric frame
    final Vector3D dtudQI = new Vector3D(dtudQIx, dtudQIy, dtudQIz);
    final Vector3D dtudQ = rotTopoToInert.applyTo(dtudQI);
    // With DS
    double dtudQxDS = tauU.getPartialDerivative(0, 0, 0, 0, 0, 0, 1, 0, 0);
    double dtudQyDS = tauU.getPartialDerivative(0, 0, 0, 0, 0, 0, 0, 1, 0);
    double dtudQzDS = tauU.getPartialDerivative(0, 0, 0, 0, 0, 0, 0, 0, 1);
    // Diff
    final double d_dtudQx = dtudQxDS - dtudQ.getX();
    final double d_dtudQy = dtudQyDS - dtudQ.getY();
    final double d_dtudQz = dtudQzDS - dtudQ.getZ();
    // Range derivatives / station
    // -----------------------
    double dRdQx = (dtddQ.getX() + dtudQ.getX()) * cOver2;
    double dRdQy = (dtddQ.getY() + dtudQ.getY()) * cOver2;
    double dRdQz = (dtddQ.getZ() + dtudQ.getZ()) * cOver2;
    // With DS
    double dRdQxDS = range.getPartialDerivative(0, 0, 0, 0, 0, 0, 1, 0, 0);
    double dRdQyDS = range.getPartialDerivative(0, 0, 0, 0, 0, 0, 0, 1, 0);
    double dRdQzDS = range.getPartialDerivative(0, 0, 0, 0, 0, 0, 0, 0, 1);
    // Diff
    final double d_dRdQx = dRdQxDS - dRdQx;
    final double d_dRdQy = dRdQyDS - dRdQy;
    final double d_dRdQz = dRdQzDS - dRdQz;
    // Print results to avoid warning
    final boolean printResults = false;
    if (printResults) {
        System.out.println("dR = " + dR);
        System.out.println("d_dtddPx = " + d_dtddPx);
        System.out.println("d_dtddPy = " + d_dtddPy);
        System.out.println("d_dtddPz = " + d_dtddPz);
        System.out.println("d_dtddVx = " + d_dtddVx);
        System.out.println("d_dtddVy = " + d_dtddVy);
        System.out.println("d_dtddVz = " + d_dtddVz);
        System.out.println("d_dtudPx = " + d_dtudPx);
        System.out.println("d_dtudPy = " + d_dtudPy);
        System.out.println("d_dtudPz = " + d_dtudPz);
        System.out.println("d_dtudVx = " + d_dtudVx);
        System.out.println("d_dtudVy = " + d_dtudVy);
        System.out.println("d_dtudVz = " + d_dtudVz);
        System.out.println("d_dRdPx = " + d_dRdPx);
        System.out.println("d_dRdPy = " + d_dRdPy);
        System.out.println("d_dRdPz = " + d_dRdPz);
        System.out.println("d_dRdVx = " + d_dRdVx);
        System.out.println("d_dRdVy = " + d_dRdVy);
        System.out.println("d_dRdVz = " + d_dRdVz);
        System.out.println("d_dtddQx = " + d_dtddQx);
        System.out.println("d_dtddQy = " + d_dtddQy);
        System.out.println("d_dtddQz = " + d_dtddQz);
        System.out.println("d_dtudQx = " + d_dtudQx);
        System.out.println("d_dtudQy = " + d_dtudQy);
        System.out.println("d_dtudQz = " + d_dtudQz);
        System.out.println("d_dRdQx = " + d_dRdQx);
        System.out.println("d_dRdQy = " + d_dRdQy);
        System.out.println("d_dRdQz = " + d_dRdQz);
    }
    // Dummy return
    return estimated;
}

Example 77 with TimeStampedPVCoordinates

use of org.orekit.utils.TimeStampedPVCoordinates in project Orekit by CS-SI.

the class NumericalPropagatorTest method recomputeFollowing.

/**
 * Assume we have 5 epochs, we will propagate from the input epoch to all the following epochs.
 *   If we have [0, 1, 2, 3, 4], and input is 2, then we will do 2->3, 2->4.
 * @param startIndex index of start state
 * @param states all states
 * @return position error for recomputed following points
 */
private static double[] recomputeFollowing(final int startIndex, List<SpacecraftState> allPoints) throws OrekitException {
    SpacecraftState startState = allPoints.get(startIndex);
    NumericalPropagator innerPropagator = createPropagator(startState, OrbitType.CARTESIAN, PositionAngle.TRUE);
    double[] errors = new double[allPoints.size() - startIndex - 1];
    for (int endIndex = startIndex + 1; endIndex < allPoints.size(); ++endIndex) {
        final TimeStampedPVCoordinates reference = allPoints.get(endIndex).getPVCoordinates();
        final TimeStampedPVCoordinates recomputed = innerPropagator.propagate(reference.getDate()).getPVCoordinates();
        errors[endIndex - startIndex - 1] = Vector3D.distance(recomputed.getPosition(), reference.getPosition());
    }
    return errors;
}

Example 78 with TimeStampedPVCoordinates

use of org.orekit.utils.TimeStampedPVCoordinates in project Orekit by CS-SI.

the class NumericalPropagatorTest method createHyperbolicOrbit.

private CartesianOrbit createHyperbolicOrbit() throws OrekitException {
    final AbsoluteDate date = new AbsoluteDate("2003-05-01T00:00:20.000", TimeScalesFactory.getUTC());
    final Vector3D position = new Vector3D(224267911.905821, 290251613.109399, 45534292.777492);
    final Vector3D velocity = new Vector3D(-1494.068165293, 1124.771027677, 526.915286134);
    final TimeStampedPVCoordinates pv = new TimeStampedPVCoordinates(date, position, velocity);
    final Frame frame = FramesFactory.getEME2000();
    final double mu = Constants.EIGEN5C_EARTH_MU;
    return new CartesianOrbit(pv, frame, mu);
}

Example 79 with TimeStampedPVCoordinates

use of org.orekit.utils.TimeStampedPVCoordinates in project Orekit by CS-SI.

the class NumericalPropagatorTest method testEphemerisDatesBackward.

@Test
public void testEphemerisDatesBackward() throws OrekitException {
    // setup
    TimeScale tai = TimeScalesFactory.getTAI();
    AbsoluteDate initialDate = new AbsoluteDate("2015-07-05", tai);
    AbsoluteDate startDate = new AbsoluteDate("2015-07-03", tai).shiftedBy(-0.1);
    AbsoluteDate endDate = new AbsoluteDate("2015-07-04", tai);
    Frame eci = FramesFactory.getGCRF();
    KeplerianOrbit orbit = new KeplerianOrbit(600e3 + Constants.WGS84_EARTH_EQUATORIAL_RADIUS, 0, 0, 0, 0, 0, PositionAngle.TRUE, eci, initialDate, mu);
    OrbitType type = OrbitType.CARTESIAN;
    double[][] tol = NumericalPropagator.tolerances(1e-3, orbit, type);
    NumericalPropagator prop = new NumericalPropagator(new DormandPrince853Integrator(0.1, 500, tol[0], tol[1]));
    prop.setOrbitType(type);
    prop.resetInitialState(new SpacecraftState(new CartesianOrbit(orbit)));
    // action
    prop.setEphemerisMode();
    prop.propagate(endDate, startDate);
    BoundedPropagator ephemeris = prop.getGeneratedEphemeris();
    // verify
    TimeStampedPVCoordinates actualPV = ephemeris.getPVCoordinates(startDate, eci);
    TimeStampedPVCoordinates expectedPV = orbit.getPVCoordinates(startDate, eci);
    MatcherAssert.assertThat(actualPV.getPosition(), OrekitMatchers.vectorCloseTo(expectedPV.getPosition(), 1.0));
    MatcherAssert.assertThat(actualPV.getVelocity(), OrekitMatchers.vectorCloseTo(expectedPV.getVelocity(), 1.0));
    MatcherAssert.assertThat(ephemeris.getMinDate().durationFrom(startDate), OrekitMatchers.closeTo(0, 0));
    MatcherAssert.assertThat(ephemeris.getMaxDate().durationFrom(endDate), OrekitMatchers.closeTo(0, 0));
    // test date
    AbsoluteDate date = endDate.shiftedBy(-0.11);
    Assert.assertEquals(ephemeris.propagate(date).getDate().durationFrom(date), 0, 0);
}

Example 80 with TimeStampedPVCoordinates

use of org.orekit.utils.TimeStampedPVCoordinates in project Orekit by CS-SI.

the class KeplerianPropagatorTest method testNoDerivatives.

@Test
public void testNoDerivatives() throws OrekitException {
    for (OrbitType type : OrbitType.values()) {
        // create an initial orbit with non-Keplerian acceleration
        final AbsoluteDate date = new AbsoluteDate(2003, 9, 16, TimeScalesFactory.getUTC());
        final Vector3D position = new Vector3D(-6142438.668, 3492467.56, -25767.257);
        final Vector3D velocity = new Vector3D(505.848, 942.781, 7435.922);
        final Vector3D keplerAcceleration = new Vector3D(-mu / position.getNormSq(), position.normalize());
        final Vector3D nonKeplerAcceleration = new Vector3D(0.001, 0.002, 0.003);
        final Vector3D acceleration = keplerAcceleration.add(nonKeplerAcceleration);
        final TimeStampedPVCoordinates pva = new TimeStampedPVCoordinates(date, position, velocity, acceleration);
        final Orbit initial = type.convertType(new CartesianOrbit(pva, FramesFactory.getEME2000(), mu));
        Assert.assertEquals(type, initial.getType());
        // the derivatives are available at this stage
        checkDerivatives(initial, true);
        KeplerianPropagator propagator = new KeplerianPropagator(initial);
        Assert.assertEquals(type, propagator.getInitialState().getOrbit().getType());
        // non-Keplerian derivatives are explicitly removed when building the Keplerian-only propagator
        checkDerivatives(propagator.getInitialState().getOrbit(), false);
        PVCoordinates initPV = propagator.getInitialState().getOrbit().getPVCoordinates();
        Assert.assertEquals(nonKeplerAcceleration.getNorm(), Vector3D.distance(acceleration, initPV.getAcceleration()), 2.0e-15);
        Assert.assertEquals(0.0, Vector3D.distance(keplerAcceleration, initPV.getAcceleration()), 4.0e-15);
        double dt = 0.2 * initial.getKeplerianPeriod();
        Orbit orbit = propagator.propagateOrbit(initial.getDate().shiftedBy(dt));
        Assert.assertEquals(type, orbit.getType());
        // at the end, we don't have non-Keplerian derivatives
        checkDerivatives(orbit, false);
        // using shiftedBy on the initial orbit, non-Keplerian derivatives would have been preserved
        checkDerivatives(initial.shiftedBy(dt), true);
    }
}