def test_compare_zonal_to_rv(self):
X0_meeMl0 = meeMl0_0
X0_rv = rv_0
order_H = 6
kep_dyn_meeMl0 = meeMl0.KeplerianDynamics()
zon_grav_meeMl0 = meeMl0.ZonalGravity(order=order_H)
sysmeeMl0 = utl.SystemDynamics(kep_dyn_meeMl0, zon_grav_meeMl0)
kep_dyn_rv = rv.KeplerianDynamics()
zon_grav_rv = rv.ZonalGravity(order=order_H)
sysrv = utl.SystemDynamics(kep_dyn_rv, zon_grav_rv)
segs_per_orbit = 6
segments = orbits * segs_per_orbit
domains = [k * period / segs_per_orbit for k in range(segments + 1)]
seg_number = len(domains) - 1
N = (order_mcpi, ) * seg_number
mcpi_meeMl0 = mcpyi.MCPI(sysmeeMl0, domains, N, 'warm', X0_meeMl0, tol)
mcpi_rv = mcpyi.MCPI(sysrv, domains, N, 'warm', X0_rv, tol)
X_meeMl0 = mcpi_meeMl0.solve_serial()(T)
X_rv = mcpi_rv.solve_serial()(T)
np.testing.assert_allclose(X_rv,
convert.rv_mee(
convert.mee_meeMl0(T, X_meeMl0)),
rtol=0,
atol=tol * 10)
def test_compare_a_eci_to_rv(self):
X0_mee = mee_0
X0_rv = rv_0
order_H = 6
kep_dyn_mee = mee.KeplerianDynamics()
zon_grav_mee = mee.ZonalGravity(order=order_H)
kep_dyn_rv = rv.KeplerianDynamics()
zon_grav_rv = rv.ZonalGravity(order=order_H)
segs_per_orbit = 6
segments = orbits * segs_per_orbit
domains = [k * period / segs_per_orbit for k in range(segments + 1)]
seg_number = len(domains) - 1
N = (order_mcpi, ) * seg_number
mcpi_mee = mcpyi.MCPI(kep_dyn_mee, domains, N, 'warm', X0_mee, tol)
mcpi_rv = mcpyi.MCPI(kep_dyn_rv, domains, N, 'warm', X0_rv, tol)
X_mee = mcpi_mee.solve_serial()(T)
X_rv = mcpi_rv.solve_serial()(T)
zon_grav_mee.eci_acceleration(T, convert.rv_mee(X_mee))
zon_grav_rv.eci_acceleration(T, X_rv)
np.testing.assert_allclose(zon_grav_mee.a_eci,
zon_grav_rv.a_eci,
rtol=0,
atol=tol)
def test_compare_constant_theta_thrust_to_rv(self):
X0_meeMl0 = meeMl0_0
X0_rv = rv_0
u = np.array([[0., 1e-6, 0.]])
kep_dyn_meeMl0 = meeMl0.KeplerianDynamics()
conthrust_meeMl0 = meeMl0.ConstantThrust(u)
sysmeeMl0 = utl.SystemDynamics(kep_dyn_meeMl0, conthrust_meeMl0)
kep_dyn_rv = rv.KeplerianDynamics()
conthrust_rv = rv.ConstantThrust(u)
sysrv = utl.SystemDynamics(kep_dyn_rv, conthrust_rv)
segments = orbits * segs_per_orbit
domains = [k * period / segs_per_orbit for k in range(segments + 1)]
seg_number = len(domains) - 1
N = (order_mcpi, ) * seg_number
mcpi_meeMl0 = mcpyi.MCPI(sysmeeMl0, domains, N, 'warm', X0_meeMl0, tol)
mcpi_rv = mcpyi.MCPI(sysrv, domains, N, 'warm', X0_rv, tol)
X_meeMl0 = mcpi_meeMl0.solve_serial()(T)
X_rv = mcpi_rv.solve_serial()(T)
np.testing.assert_allclose(X_rv,
convert.rv_mee(
convert.mee_meeMl0(T, X_meeMl0)),
rtol=0,
atol=tol * 10)
def test_compare_zonal_to_coe(self):
X0_mee = mee_0
X0_coe = coe_0
order_H = 6
kep_dyn_mee = mee.KeplerianDynamics()
zon_grav_mee = mee.ZonalGravity(order=order_H)
sysmee = utl.SystemDynamics(kep_dyn_mee, zon_grav_mee)
kep_dyn_coe = coe.KeplerianDynamics()
zon_grav_coe = coe.ZonalGravity(order=order_H)
syscoe = utl.SystemDynamics(kep_dyn_coe, zon_grav_coe)
segs_per_orbit = 6
orbits = 1
segments = orbits * segs_per_orbit
domains = [k * period / segs_per_orbit for k in range(segments + 1)]
seg_number = len(domains) - 1
N = (order_mcpi, ) * seg_number
mcpi_mee = mcpyi.MCPI(sysmee, domains, N, 'warm', X0_mee, tol)
mcpi_coe = mcpyi.MCPI(syscoe, domains, N, 'warm', X0_coe, tol)
X_mee = mcpi_mee.solve_serial()(T)
X_coe = mcpi_coe.solve_serial()(T)
diff = convert.mod_angles(np.abs(X_coe - convert.coe_mee(X_mee)))
indices_2pi = np.where(2 * np.pi - tol < diff)
diff[indices_2pi] -= 2 * np.pi
np.testing.assert_allclose(diff, 0., rtol=0, atol=tol)
def test_compare_a_eci_to_rv(self):
X0_coe = coe_0
X0_rv = rv_0
order_H = 6
kep_dyn_coe = coe.KeplerianDynamics()
zon_grav_coe = coe.ZonalGravity(order=order_H)
syscoe = utl.SystemDynamics(kep_dyn_coe, zon_grav_coe)
kep_dyn_rv = rv.KeplerianDynamics()
zon_grav_rv = rv.ZonalGravity(order=order_H)
sysrv = utl.SystemDynamics(kep_dyn_rv, zon_grav_rv)
segs_per_orbit = 6
segments = orbits * segs_per_orbit
domains = [k * period / segs_per_orbit for k in range(segments + 1)]
seg_number = len(domains) - 1
N = (order_mcpi, ) * seg_number
mcpi_coe = mcpyi.MCPI(syscoe, domains, N, 'warm', X0_coe, tol)
mcpi_rv = mcpyi.MCPI(sysrv, domains, N, 'warm', X0_rv, tol)
mcpi_coe.solve_serial()(T)
mcpi_rv.solve_serial()(T)
np.testing.assert_allclose(zon_grav_coe.a_eci,
zon_grav_rv.a_eci,
rtol=0,
atol=tol)
def test_zonal_round_trip(self):
X0_forward = rv_0
order_H = 6
kep_dyn_forward = rv.KeplerianDynamics()
zon_grav = rv.ZonalGravity(order=order_H)
sysfor = utl.SystemDynamics(kep_dyn_forward, zon_grav)
segments = orbits * segs_per_orbit
domains_for = [
k * period / segs_per_orbit for k in range(segments + 1)
]
seg_number = len(domains_for) - 1
N = (order_mcpi, ) * seg_number
mcpi_forward = mcpyi.MCPI(sysfor, domains_for, N, 'warm', X0_forward,
tol)
T_for = T
X_for = mcpi_forward.solve_serial()(T_for)
X0_bckward = X_for[-1:]
kep_dyn_bckward = rv.KeplerianDynamics()
sysbck = utl.SystemDynamics(kep_dyn_bckward, zon_grav)
domains_bck = [-x for x in domains_for]
mcpi_bckward = mcpyi.MCPI(sysbck, domains_bck, N, 'warm', X0_bckward,
tol)
T_bck = np.linspace(0, -10, num=m).reshape((m, 1))
X_bck = mcpi_bckward.solve_serial()(T_bck)
np.testing.assert_allclose(X0_forward,
X_bck[-1:],
rtol=0,
atol=tol * 10)
def test_compare_dynamics_to_rv(self):
X0_mee = mee_0
X0_rv = rv_0
mee_dyn = mee.KeplerianDynamics()
rv_dyn = rv.KeplerianDynamics()
segments = orbits * segs_per_orbit
domains = [k * period / segs_per_orbit for k in range(segments + 1)]
seg_number = len(domains) - 1
N = (order_mcpi, ) * seg_number
mcpi_mee = mcpyi.MCPI(mee_dyn, domains, N, 'warm', X0_mee, tol)
mcpi_rv = mcpyi.MCPI(rv_dyn, domains, N, 'warm', X0_rv, tol)
X_mee = mcpi_mee.solve_serial()(T)
X_rv = mcpi_rv.solve_serial()(T)
np.testing.assert_allclose(X_rv,
convert.rv_mee(X_mee),
rtol=0,
atol=tol * 10)
def test_hamiltonian_dynamics(self):
X0 = rv_0
kep_dyn = rv.KeplerianDynamics()
segments = orbits * segs_per_orbit
domains = [k * period / segs_per_orbit for k in range(segments + 1)]
seg_number = len(domains) - 1
N = (order_mcpi, ) * seg_number
mcpi = mcpyi.MCPI(kep_dyn, domains, N, 'warm', X0, tol)
X = mcpi.solve_serial()(T)
order_H = 1
H = rv.Hamiltonian(order=order_H)(T, X)
np.testing.assert_allclose(H[0, 0], H, rtol=tol)
def test_compare_dynamics_to_solution(self):
X0 = rv_0
Xsol = rv.KeplerianSolution(X0)(T)
kep_dyn = rv.KeplerianDynamics()
segments = orbits * segs_per_orbit
domains = [k * period / segs_per_orbit for k in range(segments + 1)]
seg_number = len(domains) - 1
N = (order_mcpi, ) * seg_number
mcpi = mcpyi.MCPI(kep_dyn, domains, N, 'warm', X0, tol)
Xdyn = mcpi.solve_serial()(T)
np.testing.assert_allclose(Xsol, Xdyn, rtol=0, atol=tol * 10)
def test_zonal_gravity(self):
X0 = coe_0
order_H = 6
kep_dyn = coe.KeplerianDynamics()
zon_grav = coe.ZonalGravity(order=order_H)
system = utl.SystemDynamics(kep_dyn, perturbations=zon_grav)
segments = orbits * segs_per_orbit
domains = [k * period / segs_per_orbit for k in range(segments + 1)]
seg_number = len(domains) - 1
N = (order_mcpi, ) * seg_number
mcpi = mcpyi.MCPI(system, domains, N, 'warm', X0, tol)
X = mcpi.solve_serial()(T)
H = coe.Hamiltonian(order=order_H)(T, X)
np.testing.assert_allclose(H[0, 0], H, rtol=tol)
def test_compare_keplerian_to_rv(self):
X0_coe = coe_0
X0_rv = rv_0
X_coe = coe.KeplerianSolution(X0_coe)(T)
kep_dyn = rv.KeplerianDynamics()
segments = orbits * segs_per_orbit
domains = [k * period / segs_per_orbit for k in range(segments + 1)]
seg_number = len(domains) - 1
N = (order_mcpi, ) * seg_number
mcpi = mcpyi.MCPI(kep_dyn, domains, N, 'warm', X0_rv, tol)
X_rv = mcpi.solve_serial()(T)
np.testing.assert_allclose(X_rv,
convert.rv_coe(X_coe),
rtol=0,
atol=tol * 10)
