Example #1
0
def get_keplerian_parameters(spacecraft_state, anomaly_type="TRUE"):
    """
	Given a SpaceCraftState object this function computes the keplerian orbit parameters
    Note: parameter values may change but they'll define the same orbit
	Args:
		spacecraft_state (SpaceCraftState): SpaceCraftState orekit object that has an orbit attribute
        anomaly_type (string; "MEAN" or "TRUE"): tells to return true or mean anomaly, defaults to TRUE
	Returns:
		dict: dictionary of parameters containg eccentricity, semimajor_axis, inclination, perigee argument, right
		ascension of ascending node, anomaly, anomaly_type, and orbit_update_date
    """
    parameters = dict()
    new_orbit = KeplerianOrbit(spacecraft_state.getOrbit())

    parameters["semimajor_axis"] = new_orbit.getA()
    parameters["eccentricity"] = new_orbit.getE()
    parameters["inclination"] = new_orbit.getI()
    parameters["perigee_argument"] = new_orbit.getPerigeeArgument()
    parameters[
        "right_ascension_of_ascending_node"] = new_orbit.getRightAscensionOfAscendingNode(
        )
    parameters["orbit_update_date"] = new_orbit.getDate().toString()
    parameters["frame"] = frame_to_string(spacecraft_state.getFrame())
    if (anomaly_type == "MEAN"):
        parameters["anomaly"] = new_orbit.getMeanAnomaly()
        parameters["anomaly_type"] = "MEAN"
    else:
        parameters["anomaly"] = new_orbit.getTrueAnomaly()
        parameters["anomaly_type"] = "TRUE"
    return parameters
Example #2
0
def validate_rv2coe():
    # Orbit initial state vectors
    rx_0, ry_0, rz_0 = -6045.0e3, -3490.0e3, 2500.0e3
    vx_0, vy_0, vz_0 = -3.457e3, 6.618e3, 2.533e3

    # Build the initial Orekit orbit
    k = C.IAU_2015_NOMINAL_EARTH_GM
    r0_vec = Vector3D(rx_0, ry_0, rz_0)
    v0_vec = Vector3D(vx_0, vy_0, vz_0)
    rv_0 = PVCoordinates(r0_vec, v0_vec)
    epoch_00 = AbsoluteDate.J2000_EPOCH
    gcrf_frame = FramesFactory.getGCRF()
    ss0_orekit = KeplerianOrbit(rv_0, gcrf_frame, epoch_00, k)

    # Build poliastro orbit
    r0_vec = [rx_0, ry_0, rz_0] * u.m
    v0_vec = [vx_0, vy_0, vz_0] * u.m / u.s
    ss0_poliastro = Orbit.from_vectors(Earth, r0_vec, v0_vec)

    # Orekit bounds COE angular magnitudes between [-pi, +pi]. Let us define a
    # converter function to map values between [0, +2pi]
    def unbound_angle(angle):
        """ Bound angle between [0, +2pi] """
        if -np.pi <= angle <= 0.0:
            angle += 2 * np.pi

        return angle

    # Map angles
    orekit_raan = unbound_angle(ss0_orekit.getRightAscensionOfAscendingNode())
    orekit_argp = unbound_angle(ss0_orekit.getPerigeeArgument())
    orekit_nu = unbound_angle(ss0_orekit.getTrueAnomaly())

    # Assert classical orbital elements
    assert_quantity_allclose(ss0_poliastro.a,
                             ss0_orekit.getA() * u.m,
                             rtol=1e-6)
    assert_quantity_allclose(ss0_poliastro.ecc,
                             ss0_orekit.getE() * u.one,
                             rtol=1e-6)
    assert_quantity_allclose(ss0_poliastro.inc,
                             ss0_orekit.getI() * u.rad,
                             rtol=1e-6)
    assert_quantity_allclose(ss0_poliastro.raan,
                             orekit_raan * u.rad,
                             rtol=1e-6)
    assert_quantity_allclose(ss0_poliastro.argp,
                             orekit_argp * u.rad,
                             rtol=1e-6)
    assert_quantity_allclose(ss0_poliastro.nu, orekit_nu * u.rad, rtol=1e-6)
Example #3
0
    def osc_elems_transformation_ore(self, other, dir):

        self._orekit_lock.acquire()

        self.load_orekit()

        KepOrbElem.vm.attachCurrentThread()

        utc = TimeScalesFactory.getUTC()

        orekit_date = AbsoluteDate(2017, 1, 1, 12, 1, 1.0, utc)
        inertialFrame = FramesFactory.getEME2000()
        a = float(other.a)
        e = float(other.e)
        i = float(other.i)
        w = float(other.w)
        O = float(other.O)
        v = float(other.v)

        initialOrbit = KeplerianOrbit(a * 1000.0, e, i, w, O, v,
                                      PositionAngle.TRUE, inertialFrame,
                                      orekit_date, Constants.mu_earth * 1e9)

        initialState = SpacecraftState(initialOrbit, 1.0)

        #zonal_forces= DSSTZonal(provider,2,1,5)
        zonal_forces = DSSTZonal(KepOrbElem.provider, 6, 4, 6)
        forces = ArrayList()
        forces.add(zonal_forces)
        try:
            equinoctial = None
            if dir:

                equinoctial = DSSTPropagator.computeMeanState(
                    initialState, None, forces)
            else:

                equinoctial = DSSTPropagator.computeOsculatingState(
                    initialState, None, forces)

            newOrbit = KeplerianOrbit(equinoctial.getOrbit())

            self.a = newOrbit.getA() / 1000.0
            self.e = newOrbit.getE()
            self.i = newOrbit.getI()
            self.w = newOrbit.getPerigeeArgument()
            self.O = newOrbit.getRightAscensionOfAscendingNode()
            self.v = newOrbit.getAnomaly(PositionAngle.TRUE)

            # correct ranges

            if self.i < 0:
                self.i += 2 * np.pi

            if self.w < 0:
                self.w += 2 * np.pi

            if self.O < 0:
                self.O += 2 * np.pi

            if self.v < 0:
                self.v += 2 * np.pi

        finally:
            self._orekit_lock.release()
Example #4
0
def validate_3D_hohmann():

    # Initial orbit state vectors, final radius and time of flight
    # This orbit has an inclination of 22.30 [deg] so the maneuver will not be
    # applied on an equatorial orbit. See associated GMAT script:
    # gmat_validate_hohmann3D.script
    rx_0, ry_0, rz_0 = 7200e3, -1000.0e3, 0.0
    vx_0, vy_0, vz_0 = 0.0, 8.0e3, 3.25e3
    rf_norm = 35781.35e3
    tof = 19800.00

    # Build the initial Orekit orbit
    k = C.IAU_2015_NOMINAL_EARTH_GM
    r0_vec = Vector3D(rx_0, ry_0, rz_0)
    v0_vec = Vector3D(vx_0, vy_0, vz_0)
    rv_0 = PVCoordinates(r0_vec, v0_vec)
    epoch_00 = AbsoluteDate.J2000_EPOCH
    gcrf_frame = FramesFactory.getGCRF()
    ss_0 = KeplerianOrbit(rv_0, gcrf_frame, epoch_00, k)

    # Final desired orbit radius and auxiliary variables
    a_0, ecc_0 = ss_0.getA(), ss_0.getE()
    rp_norm = a_0 * (1 - ecc_0)
    vp_norm = np.sqrt(2 * k / rp_norm - k / a_0)
    a_trans = (rp_norm + rf_norm) / 2

    # Compute the magnitude of Hohmann's deltaV
    dv_a = np.sqrt(2 * k / rp_norm - k / a_trans) - vp_norm
    dv_b = np.sqrt(k / rf_norm) - np.sqrt(2 * k / rf_norm - k / a_trans)

    # Convert previous magnitudes into vectors within the TNW frame, which
    # is aligned with local velocity vector
    dVa_vec, dVb_vec = [
        Vector3D(float(dV), float(0), float(0)) for dV in (dv_a, dv_b)
    ]

    # Local orbit frame: X-axis aligned with velocity, Z-axis towards momentum
    attitude_provider = LofOffset(gcrf_frame, LOFType.TNW)

    # Setup impulse triggers; default apside detector stops on increasing g
    # function (aka at perigee)
    at_apoapsis = ApsideDetector(ss_0).withHandler(StopOnDecreasing())
    at_periapsis = ApsideDetector(ss_0)

    # Build the impulsive maneuvers; ISP is only related to fuel mass cost
    ISP = float(300)
    imp_A = ImpulseManeuver(at_periapsis, attitude_provider, dVa_vec, ISP)
    imp_B = ImpulseManeuver(at_apoapsis, attitude_provider, dVb_vec, ISP)

    # Generate the propagator and add the maneuvers
    propagator = KeplerianPropagator(ss_0, attitude_provider)
    propagator.addEventDetector(imp_A)
    propagator.addEventDetector(imp_B)

    # Apply the maneuver by propagating the orbit
    epoch_ff = epoch_00.shiftedBy(tof)
    rv_f = propagator.propagate(epoch_ff).getPVCoordinates(gcrf_frame)

    # Retrieve orekit final state vectors
    r_orekit, v_orekit = (
        rv_f.getPosition().toArray() * u.m,
        rv_f.getVelocity().toArray() * u.m / u.s,
    )

    # Build initial poliastro orbit and apply the maneuver
    r0_vec = [rx_0, ry_0, rz_0] * u.m
    v0_vec = [vx_0, vy_0, vz_0] * u.m / u.s
    ss0_poliastro = Orbit.from_vectors(Earth, r0_vec, v0_vec)
    man_poliastro = Maneuver.hohmann(ss0_poliastro, rf_norm * u.m)

    # Retrieve propagation time after maneuver has been applied
    tof_prop = tof - man_poliastro.get_total_time().to(u.s).value
    ssf_poliastro = ss0_poliastro.apply_maneuver(man_poliastro).propagate(
        tof_prop * u.s)

    # Retrieve poliastro final state vectors
    r_poliastro, v_poliastro = ssf_poliastro.rv()

    # Assert final state vectors
    assert_quantity_allclose(r_poliastro, r_orekit, rtol=1e-6)
    assert_quantity_allclose(v_poliastro, v_orekit, rtol=1e-6)