Exemplo n.º 1
0
def test_anisotropic_hernquist_wrongpot():
    pot= potential.JaffePotential(amp=2.,a=1.3)   
    with pytest.raises(AssertionError)  as excinfo:
        dfh= constantbetaHernquistdf(pot=pot)
    assert str(excinfo.value) == 'pot= must be potential.HernquistPotential', 'Error message when not supplying the potential is incorrect'
    return None
Exemplo n.º 2
0
def test_dynamfric_c():
    import copy
    from galpy.orbit import Orbit
    from galpy.potential.Potential import _check_c
    from galpy.potential.mwpotentials import McMillan17
    #Basic parameters for the test
    times = numpy.linspace(0., -100., 1001)  #~3 Gyr at the Solar circle
    integrator = 'dop853_c'
    py_integrator = 'dop853'
    #Define all of the potentials (by hand, because need reasonable setup)
    MWPotential3021 = copy.deepcopy(potential.MWPotential2014)
    MWPotential3021[2] *= 1.5  # Increase mass by 50%
    pots= [potential.LogarithmicHaloPotential(normalize=1),
           potential.LogarithmicHaloPotential(normalize=1.3,
                                              q=0.9,b=0.7), #nonaxi
           potential.NFWPotential(normalize=1.,a=1.5),
           potential.MiyamotoNagaiPotential(normalize=.02,a=10.,b=10.),
           potential.MiyamotoNagaiPotential(normalize=.6,a=0.,b=3.), # special case
           potential.PowerSphericalPotential(alpha=2.3,normalize=2.),
           potential.DehnenSphericalPotential(normalize=4.,alpha=1.2),
           potential.DehnenCoreSphericalPotential(normalize=4.),
           potential.HernquistPotential(normalize=1.,a=3.5),
           potential.JaffePotential(normalize=1.,a=20.5),
           potential.DoubleExponentialDiskPotential(normalize=0.2,
                                                    hr=3.,hz=0.6),
           potential.FlattenedPowerPotential(normalize=3.),
           potential.FlattenedPowerPotential(normalize=3.,alpha=0), #special case
           potential.IsochronePotential(normalize=2.),
           potential.PowerSphericalPotentialwCutoff(normalize=0.3,rc=10.),
           potential.PlummerPotential(normalize=.6,b=3.),
           potential.PseudoIsothermalPotential(normalize=.1,a=3.),
           potential.BurkertPotential(normalize=.2,a=2.5),
           potential.TriaxialHernquistPotential(normalize=1.,a=3.5,
                                                b=0.8,c=0.9),
           potential.TriaxialNFWPotential(normalize=1.,a=1.5,b=0.8,c=0.9),
           potential.TriaxialJaffePotential(normalize=1.,a=20.5,b=0.8,c=1.4),
           potential.PerfectEllipsoidPotential(normalize=.3,a=3.,b=0.7,c=1.5),
           potential.PerfectEllipsoidPotential(normalize=.3,a=3.,b=0.7,c=1.5,
                                               pa=3.,zvec=[0.,1.,0.]), #rotated
           potential.HomogeneousSpherePotential(normalize=0.02,R=82./8), # make sure to go to dens = 0 part,
           potential.interpSphericalPotential(\
                    rforce=potential.HomogeneousSpherePotential(normalize=0.02,
                                                                R=82./8.),
                    rgrid=numpy.linspace(0.,82./8.,201)),
           potential.TriaxialGaussianPotential(normalize=.03,sigma=4.,b=0.8,c=1.5,pa=3.,zvec=[1.,0.,0.]),
           potential.SCFPotential(Acos=numpy.array([[[1.]]]), # same as Hernquist
                                  normalize=1.,a=3.5),
           potential.SCFPotential(Acos=numpy.array([[[1.,0.],[.3,0.]]]), # nonaxi
                                  Asin=numpy.array([[[0.,0.],[1e-1,0.]]]),
                                  normalize=1.,a=3.5),
           MWPotential3021,
           McMillan17 # SCF + DiskSCF
           ]
    #tolerances in log10
    tol = {}
    tol['default'] = -7.
    # Following are a little more difficult
    tol['DoubleExponentialDiskPotential'] = -4.5
    tol['TriaxialHernquistPotential'] = -6.
    tol['TriaxialNFWPotential'] = -6.
    tol['TriaxialJaffePotential'] = -6.
    tol['MWPotential3021'] = -6.
    tol['HomogeneousSpherePotential'] = -6.
    tol['interpSphericalPotential'] = -6.  # == HomogeneousSpherePotential
    tol['McMillan17'] = -6.
    for p in pots:
        if not _check_c(p, dens=True): continue  # dynamfric not in C!
        pname = type(p).__name__
        if pname == 'list':
            if isinstance(p[0],potential.PowerSphericalPotentialwCutoff) \
                    and len(p) > 1 \
                    and isinstance(p[1],potential.MiyamotoNagaiPotential) \
                    and len(p) > 2 \
                    and isinstance(p[2],potential.NFWPotential):
                pname = 'MWPotential3021'  # Must be!
            else:
                pname = 'McMillan17'
        #print(pname)
        if pname in list(tol.keys()): ttol = tol[pname]
        else: ttol = tol['default']
        # Setup orbit, ~ LMC
        o = Orbit([
            5.13200034, 1.08033051, 0.23323391, -3.48068653, 0.94950884,
            -1.54626091
        ])
        # Setup dynamical friction object
        if pname == 'McMillan17':
            cdf= potential.ChandrasekharDynamicalFrictionForce(\
                GMs=0.5553870441722593,rhm=5./8.,dens=p,maxr=500./8,nr=101)
            ttimes = numpy.linspace(0., -30.,
                                    1001)  #~1 Gyr at the Solar circle
        else:
            cdf= potential.ChandrasekharDynamicalFrictionForce(\
                GMs=0.5553870441722593,rhm=5./8.,dens=p,maxr=500./8,nr=201)
            ttimes = times
        # Integrate in C
        o.integrate(ttimes, p + cdf, method=integrator)
        # Integrate in Python
        op = o()
        op.integrate(ttimes, p + cdf, method=py_integrator)
        # Compare r (most important)
        assert numpy.amax(numpy.fabs(o.r(ttimes)-op.r(ttimes))) < 10**ttol, \
            'Dynamical friction in C does not agree with dynamical friction in Python for potential {}'.format(pname)
    return None