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test_advection.py
509 lines (423 loc) · 23.1 KB
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test_advection.py
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from parcels import (FieldSet, Field, ScipyParticle, JITParticle, ErrorCode, StateCode,
AdvectionEE, AdvectionRK4, AdvectionRK45, AdvectionRK4_3D,
AdvectionAnalytical, AdvectionDiffusionM1, AdvectionDiffusionEM)
from parcels import ParticleSetSOA, ParticleFileSOA, KernelSOA # noqa
from parcels import ParticleSetAOS, ParticleFileAOS, KernelAOS # noqa
import numpy as np
import pytest
import math
from netCDF4 import Dataset
from datetime import timedelta as delta
from parcels import logger
pset_modes = ['soa', 'aos']
ptype = {'scipy': ScipyParticle, 'jit': JITParticle}
pset_type = {'soa': {'pset': ParticleSetSOA, 'pfile': ParticleFileSOA, 'kernel': KernelSOA},
'aos': {'pset': ParticleSetAOS, 'pfile': ParticleFileAOS, 'kernel': KernelAOS}}
kernel = {'EE': AdvectionEE, 'RK4': AdvectionRK4, 'RK45': AdvectionRK45,
'AdvDiffEM': AdvectionDiffusionEM, 'AdvDiffM1': AdvectionDiffusionM1}
# Some constants
f = 1.e-4
u_0 = 0.3
u_g = 0.04
gamma = 1/(86400. * 2.89)
gamma_g = 1/(86400. * 28.9)
def lon(xdim=200):
return np.linspace(-170, 170, xdim, dtype=np.float32)
@pytest.fixture(name="lon")
def lon_fixture(xdim=200):
return lon(xdim=xdim)
def lat(ydim=100):
return np.linspace(-80, 80, ydim, dtype=np.float32)
@pytest.fixture(name="lat")
def lat_fixture(ydim=100):
return lat(ydim=ydim)
def depth(zdim=2):
return np.linspace(0, 30, zdim, dtype=np.float32)
@pytest.fixture(name="depth")
def depth_fixture(zdim=2):
return depth(zdim=zdim)
@pytest.mark.parametrize('pset_mode', pset_modes)
@pytest.mark.parametrize('mode', ['scipy', 'jit'])
def test_advection_zonal(lon, lat, depth, pset_mode, mode, npart=10):
""" Particles at high latitude move geographically faster due to
the pole correction in `GeographicPolar`.
"""
data2D = {'U': np.ones((lon.size, lat.size), dtype=np.float32),
'V': np.zeros((lon.size, lat.size), dtype=np.float32)}
data3D = {'U': np.ones((lon.size, lat.size, depth.size), dtype=np.float32),
'V': np.zeros((lon.size, lat.size, depth.size), dtype=np.float32)}
dimensions = {'lon': lon, 'lat': lat}
fieldset2D = FieldSet.from_data(data2D, dimensions, mesh='spherical', transpose=True)
assert fieldset2D.U.creation_log == 'from_data'
pset2D = pset_type[pset_mode]['pset'](fieldset2D, pclass=ptype[mode],
lon=np.zeros(npart) + 20.,
lat=np.linspace(0, 80, npart))
pset2D.execute(AdvectionRK4, runtime=delta(hours=2), dt=delta(seconds=30))
assert (np.diff(pset2D.lon) > 1.e-4).all()
dimensions['depth'] = depth
fieldset3D = FieldSet.from_data(data3D, dimensions, mesh='spherical', transpose=True)
pset3D = pset_type[pset_mode]['pset'](fieldset3D, pclass=ptype[mode],
lon=np.zeros(npart) + 20.,
lat=np.linspace(0, 80, npart),
depth=np.zeros(npart) + 10.)
pset3D.execute(AdvectionRK4, runtime=delta(hours=2), dt=delta(seconds=30))
assert (np.diff(pset3D.lon) > 1.e-4).all()
@pytest.mark.parametrize('pset_mode', pset_modes)
@pytest.mark.parametrize('mode', ['scipy', 'jit'])
def test_advection_meridional(lon, lat, pset_mode, mode, npart=10):
""" Particles at high latitude move geographically faster due to
the pole correction in `GeographicPolar`.
"""
data = {'U': np.zeros((lon.size, lat.size), dtype=np.float32),
'V': np.ones((lon.size, lat.size), dtype=np.float32)}
dimensions = {'lon': lon, 'lat': lat}
fieldset = FieldSet.from_data(data, dimensions, mesh='spherical', transpose=True)
pset = pset_type[pset_mode]['pset'](fieldset, pclass=ptype[mode],
lon=np.linspace(-60, 60, npart),
lat=np.linspace(0, 30, npart))
delta_lat = np.diff(pset.lat)
pset.execute(AdvectionRK4, runtime=delta(hours=2), dt=delta(seconds=30))
assert np.allclose(np.diff(pset.lat), delta_lat, rtol=1.e-4)
@pytest.mark.parametrize('pset_mode', pset_modes)
@pytest.mark.parametrize('mode', ['jit', 'scipy'])
def test_advection_3D(pset_mode, mode, npart=11):
""" 'Flat' 2D zonal flow that increases linearly with depth from 0 m/s to 1 m/s
"""
xdim = ydim = zdim = 2
dimensions = {'lon': np.linspace(0., 1e4, xdim, dtype=np.float32),
'lat': np.linspace(0., 1e4, ydim, dtype=np.float32),
'depth': np.linspace(0., 1., zdim, dtype=np.float32)}
data = {'U': np.ones((xdim, ydim, zdim), dtype=np.float32),
'V': np.zeros((xdim, ydim, zdim), dtype=np.float32)}
data['U'][:, :, 0] = 0.
fieldset = FieldSet.from_data(data, dimensions, mesh='flat', transpose=True)
pset = pset_type[pset_mode]['pset'](fieldset, pclass=ptype[mode],
lon=np.zeros(npart),
lat=np.zeros(npart) + 1e2,
depth=np.linspace(0, 1, npart))
time = delta(hours=2).total_seconds()
pset.execute(AdvectionRK4, runtime=time, dt=delta(seconds=30))
assert np.allclose(pset.depth*time, pset.lon, atol=1.e-1)
@pytest.mark.parametrize('pset_mode', pset_modes)
@pytest.mark.parametrize('mode', ['jit', 'scipy'])
@pytest.mark.parametrize('direction', ['up', 'down'])
@pytest.mark.parametrize('wErrorThroughSurface', [True, False])
def test_advection_3D_outofbounds(pset_mode, mode, direction, wErrorThroughSurface):
xdim = ydim = zdim = 2
dimensions = {'lon': np.linspace(0., 1, xdim, dtype=np.float32),
'lat': np.linspace(0., 1, ydim, dtype=np.float32),
'depth': np.linspace(0., 1, zdim, dtype=np.float32)}
wfac = -1. if direction == 'up' else 1.
data = {'U': 0.01*np.ones((xdim, ydim, zdim), dtype=np.float32),
'V': np.zeros((xdim, ydim, zdim), dtype=np.float32),
'W': wfac * np.ones((xdim, ydim, zdim), dtype=np.float32)}
fieldset = FieldSet.from_data(data, dimensions, mesh='flat')
def DeleteParticle(particle, fieldset, time):
particle.delete()
def SubmergeParticle(particle, fieldset, time):
particle.depth = 0
AdvectionRK4(particle, fieldset, time) # perform a 2D advection because vertical flow will always push up in this case
particle.time = time + particle.dt # to not trigger kernels again, otherwise infinite loop
particle.set_state(StateCode.Success)
recovery_dict = {ErrorCode.ErrorOutOfBounds: DeleteParticle}
if wErrorThroughSurface:
recovery_dict[ErrorCode.ErrorThroughSurface] = SubmergeParticle
pset = pset_type[pset_mode]['pset'](fieldset=fieldset, pclass=ptype[mode], lon=0.5, lat=0.5, depth=0.9)
pset.execute(AdvectionRK4_3D, runtime=10., dt=1, recovery=recovery_dict)
if direction == 'up' and wErrorThroughSurface:
assert np.allclose(pset.lon[0], 0.6)
assert np.allclose(pset.depth[0], 0)
else:
assert len(pset) == 0
def periodicfields(xdim, ydim, uvel, vvel):
dimensions = {'lon': np.linspace(0., 1., xdim+1, dtype=np.float32)[1:], # don't include both 0 and 1, for periodic b.c.
'lat': np.linspace(0., 1., ydim+1, dtype=np.float32)[1:]}
data = {'U': uvel * np.ones((xdim, ydim), dtype=np.float32),
'V': vvel * np.ones((xdim, ydim), dtype=np.float32)}
return FieldSet.from_data(data, dimensions, mesh='spherical', transpose=True)
def periodicBC(particle, fieldset, time):
particle.lon = math.fmod(particle.lon, 1)
particle.lat = math.fmod(particle.lat, 1)
@pytest.mark.parametrize('pset_mode', pset_modes)
@pytest.mark.parametrize('mode', ['scipy', 'jit'])
def test_advection_periodic_zonal(pset_mode, mode, xdim=100, ydim=100, halosize=3):
fieldset = periodicfields(xdim, ydim, uvel=1., vvel=0.)
fieldset.add_periodic_halo(zonal=True, halosize=halosize)
assert(len(fieldset.U.lon) == xdim + 2 * halosize)
pset = pset_type[pset_mode]['pset'](fieldset, pclass=ptype[mode], lon=[0.5], lat=[0.5])
pset.execute(AdvectionRK4 + pset.Kernel(periodicBC), runtime=delta(hours=20), dt=delta(seconds=30))
assert abs(pset.lon[0] - 0.15) < 0.1
@pytest.mark.parametrize('pset_mode', pset_modes)
@pytest.mark.parametrize('mode', ['scipy', 'jit'])
def test_advection_periodic_meridional(pset_mode, mode, xdim=100, ydim=100):
fieldset = periodicfields(xdim, ydim, uvel=0., vvel=1.)
fieldset.add_periodic_halo(meridional=True)
assert(len(fieldset.U.lat) == ydim + 10) # default halo size is 5 grid points
pset = pset_type[pset_mode]['pset'](fieldset, pclass=ptype[mode], lon=[0.5], lat=[0.5])
pset.execute(AdvectionRK4 + pset.Kernel(periodicBC), runtime=delta(hours=20), dt=delta(seconds=30))
assert abs(pset.lat[0] - 0.15) < 0.1
@pytest.mark.parametrize('pset_mode', pset_modes)
@pytest.mark.parametrize('mode', ['scipy', 'jit'])
def test_advection_periodic_zonal_meridional(pset_mode, mode, xdim=100, ydim=100):
fieldset = periodicfields(xdim, ydim, uvel=1., vvel=1.)
fieldset.add_periodic_halo(zonal=True, meridional=True)
assert(len(fieldset.U.lat) == ydim + 10) # default halo size is 5 grid points
assert(len(fieldset.U.lon) == xdim + 10) # default halo size is 5 grid points
assert np.allclose(np.diff(fieldset.U.lat), fieldset.U.lat[1]-fieldset.U.lat[0], rtol=0.001)
assert np.allclose(np.diff(fieldset.U.lon), fieldset.U.lon[1]-fieldset.U.lon[0], rtol=0.001)
pset = pset_type[pset_mode]['pset'](fieldset, pclass=ptype[mode], lon=[0.4], lat=[0.5])
pset.execute(AdvectionRK4 + pset.Kernel(periodicBC), runtime=delta(hours=20), dt=delta(seconds=30))
assert abs(pset.lon[0] - 0.05) < 0.1
assert abs(pset.lat[0] - 0.15) < 0.1
@pytest.mark.parametrize('pset_mode', pset_modes)
@pytest.mark.parametrize('mode', ['scipy', 'jit'])
@pytest.mark.parametrize('u', [-0.3, np.array(0.2)])
@pytest.mark.parametrize('v', [0.2, np.array(1)])
@pytest.mark.parametrize('w', [None, -0.2, np.array(0.7)])
def test_length1dimensions(pset_mode, mode, u, v, w):
logger.info("mode: {} pset_mode {}".format(mode, pset_mode))
(lon, xdim) = (np.linspace(-10, 10, 21), 21) if isinstance(u, np.ndarray) else (0, 1)
(lat, ydim) = (np.linspace(-15, 15, 31), 31) if isinstance(v, np.ndarray) else (-4, 1)
(depth, zdim) = (np.linspace(-5, 5, 11), 11) if (isinstance(w, np.ndarray) and w is not None) else (3, 1)
dimensions = {'lon': lon, 'lat': lat, 'depth': depth}
dims = []
if zdim > 1:
dims.append(zdim)
if ydim > 1:
dims.append(ydim)
if xdim > 1:
dims.append(xdim)
if len(dims) > 0:
U = u * np.ones(dims, dtype=np.float32)
V = v * np.ones(dims, dtype=np.float32)
if w is not None:
W = w * np.ones(dims, dtype=np.float32)
else:
U, V, W = u, v, w
data = {'U': U, 'V': V}
if w is not None:
data['W'] = W
fieldset = FieldSet.from_data(data, dimensions, mesh='flat')
x0, y0, z0 = 2, 8, -4
pset = pset_type[pset_mode]['pset'](fieldset, pclass=ptype[mode], lon=x0, lat=y0, depth=z0)
pfunc = AdvectionRK4 if w is None else AdvectionRK4_3D
kernel = pset.Kernel(pfunc)
pset.execute(kernel, runtime=4)
assert (len(pset.lon) == len([p.lon for p in pset]))
assert ((np.array([p.lon - x0 for p in pset]) - 4 * u) < 1e-6).all()
assert ((np.array([p.lat - y0 for p in pset]) - 4 * v) < 1e-6).all()
if w:
assert ((np.array([p.depth - y0 for p in pset]) - 4 * w) < 1e-6).all()
def truth_stationary(x_0, y_0, t):
lat = y_0 - u_0 / f * (1 - math.cos(f * t))
lon = x_0 + u_0 / f * math.sin(f * t)
return lon, lat
@pytest.fixture
def fieldset_stationary(xdim=100, ydim=100, maxtime=delta(hours=6)):
"""Generate a FieldSet encapsulating the flow field of a stationary eddy.
Reference: N. Fabbroni, 2009, "Numerical simulations of passive
tracers dispersion in the sea"
"""
time = np.arange(0., maxtime.total_seconds()+1e-5, 60., dtype=np.float64)
dimensions = {'lon': np.linspace(0, 25000, xdim, dtype=np.float32),
'lat': np.linspace(0, 25000, ydim, dtype=np.float32),
'time': time}
data = {'U': np.ones((xdim, ydim, 1), dtype=np.float32) * u_0 * np.cos(f * time),
'V': np.ones((xdim, ydim, 1), dtype=np.float32) * -u_0 * np.sin(f * time)}
return FieldSet.from_data(data, dimensions, mesh='flat', transpose=True)
@pytest.mark.parametrize('pset_mode', pset_modes)
@pytest.mark.parametrize('mode', ['scipy', 'jit'])
@pytest.mark.parametrize('method, rtol, diffField', [
('EE', 1e-2, False),
('AdvDiffEM', 1e-2, True),
('AdvDiffM1', 1e-2, True),
('RK4', 1e-5, False),
('RK45', 1e-5, False)])
def test_stationary_eddy(pset_mode, fieldset_stationary, mode, method, rtol, diffField, npart=1):
fieldset = fieldset_stationary
if diffField:
fieldset.add_field(Field('Kh_zonal', np.zeros(fieldset.U.data.shape), grid=fieldset.U.grid))
fieldset.add_field(Field('Kh_meridional', np.zeros(fieldset.V.data.shape), grid=fieldset.V.grid))
fieldset.add_constant('dres', 0.1)
lon = np.linspace(12000, 21000, npart)
lat = np.linspace(12500, 12500, npart)
pset = pset_type[pset_mode]['pset'](fieldset, pclass=ptype[mode], lon=lon, lat=lat)
endtime = delta(hours=6).total_seconds()
pset.execute(kernel[method], dt=delta(minutes=3), endtime=endtime)
exp_lon = [truth_stationary(x, y, endtime)[0] for x, y, in zip(lon, lat)]
exp_lat = [truth_stationary(x, y, endtime)[1] for x, y, in zip(lon, lat)]
assert np.allclose(pset.lon, exp_lon, rtol=rtol)
assert np.allclose(pset.lat, exp_lat, rtol=rtol)
@pytest.mark.parametrize('pset_mode', pset_modes)
@pytest.mark.parametrize('mode', ['scipy', 'jit'])
def test_stationary_eddy_vertical(pset_mode, mode, npart=1):
lon = np.linspace(12000, 21000, npart)
lat = np.linspace(10000, 20000, npart)
depth = np.linspace(12500, 12500, npart)
endtime = delta(hours=6).total_seconds()
xdim = ydim = 100
lon_data = np.linspace(0, 25000, xdim, dtype=np.float32)
lat_data = np.linspace(0, 25000, ydim, dtype=np.float32)
time_data = np.arange(0., 6*3600+1e-5, 60., dtype=np.float64)
fld1 = np.ones((xdim, ydim, 1), dtype=np.float32) * u_0 * np.cos(f * time_data)
fld2 = np.ones((xdim, ydim, 1), dtype=np.float32) * -u_0 * np.sin(f * time_data)
fldzero = np.zeros((xdim, ydim, 1), dtype=np.float32) * time_data
dimensions = {'lon': lon_data, 'lat': lat_data, 'time': time_data}
data = {'U': fld1, 'V': fldzero, 'W': fld2}
fieldset = FieldSet.from_data(data, dimensions, mesh='flat', transpose=True)
pset = pset_type[pset_mode]['pset'](fieldset, pclass=ptype[mode], lon=lon, lat=lat, depth=depth)
pset.execute(AdvectionRK4_3D, dt=delta(minutes=3), endtime=endtime)
exp_lon = [truth_stationary(x, z, endtime)[0] for x, z, in zip(lon, depth)]
exp_depth = [truth_stationary(x, z, endtime)[1] for x, z, in zip(lon, depth)]
assert np.allclose(pset.lon, exp_lon, rtol=1e-5)
assert np.allclose(pset.lat, lat, rtol=1e-5)
assert np.allclose(pset.depth, exp_depth, rtol=1e-5)
data = {'U': fldzero, 'V': fld2, 'W': fld1}
fieldset = FieldSet.from_data(data, dimensions, mesh='flat', transpose=True)
pset = pset_type[pset_mode]['pset'](fieldset, pclass=ptype[mode], lon=lon, lat=lat, depth=depth)
pset.execute(AdvectionRK4_3D, dt=delta(minutes=3), endtime=endtime)
exp_depth = [truth_stationary(z, y, endtime)[0] for z, y, in zip(depth, lat)]
exp_lat = [truth_stationary(z, y, endtime)[1] for z, y, in zip(depth, lat)]
assert np.allclose(pset.lon, lon, rtol=1e-5)
assert np.allclose(pset.lat, exp_lat, rtol=1e-5)
assert np.allclose(pset.depth, exp_depth, rtol=1e-5)
def truth_moving(x_0, y_0, t):
lat = y_0 - (u_0 - u_g) / f * (1 - math.cos(f * t))
lon = x_0 + u_g * t + (u_0 - u_g) / f * math.sin(f * t)
return lon, lat
@pytest.fixture
def fieldset_moving(xdim=100, ydim=100, maxtime=delta(hours=6)):
"""Generate a FieldSet encapsulating the flow field of a moving eddy.
Reference: N. Fabbroni, 2009, "Numerical simulations of passive
tracers dispersion in the sea"
"""
time = np.arange(0., maxtime.total_seconds()+1e-5, 60., dtype=np.float64)
dimensions = {'lon': np.linspace(0, 25000, xdim, dtype=np.float32),
'lat': np.linspace(0, 25000, ydim, dtype=np.float32),
'time': time}
data = {'U': np.ones((xdim, ydim, 1), dtype=np.float32) * u_g + (u_0 - u_g) * np.cos(f * time),
'V': np.ones((xdim, ydim, 1), dtype=np.float32) * -(u_0 - u_g) * np.sin(f * time)}
return FieldSet.from_data(data, dimensions, mesh='flat', transpose=True)
@pytest.mark.parametrize('pset_mode', pset_modes)
@pytest.mark.parametrize('mode', ['scipy', 'jit'])
@pytest.mark.parametrize('method, rtol, diffField', [
('EE', 1e-2, False),
('AdvDiffEM', 1e-2, True),
('AdvDiffM1', 1e-2, True),
('RK4', 1e-5, False),
('RK45', 1e-5, False)])
def test_moving_eddy(pset_mode, fieldset_moving, mode, method, rtol, diffField, npart=1):
fieldset = fieldset_moving
if diffField:
fieldset.add_field(Field('Kh_zonal', np.zeros(fieldset.U.data.shape), grid=fieldset.U.grid))
fieldset.add_field(Field('Kh_meridional', np.zeros(fieldset.V.data.shape), grid=fieldset.V.grid))
fieldset.add_constant('dres', 0.1)
lon = np.linspace(12000, 21000, npart)
lat = np.linspace(12500, 12500, npart)
pset = pset_type[pset_mode]['pset'](fieldset, pclass=ptype[mode], lon=lon, lat=lat)
endtime = delta(hours=6).total_seconds()
pset.execute(kernel[method], dt=delta(minutes=3), endtime=endtime)
exp_lon = [truth_moving(x, y, endtime)[0] for x, y, in zip(lon, lat)]
exp_lat = [truth_moving(x, y, endtime)[1] for x, y, in zip(lon, lat)]
assert np.allclose(pset.lon, exp_lon, rtol=rtol)
assert np.allclose(pset.lat, exp_lat, rtol=rtol)
def truth_decaying(x_0, y_0, t):
lat = y_0 - ((u_0 - u_g) * f / (f ** 2 + gamma ** 2)
* (1 - np.exp(-gamma * t) * (np.cos(f * t) + gamma / f * np.sin(f * t))))
lon = x_0 + (u_g / gamma_g * (1 - np.exp(-gamma_g * t))
+ (u_0 - u_g) * f / (f ** 2 + gamma ** 2)
* (gamma / f + np.exp(-gamma * t)
* (math.sin(f * t) - gamma / f * math.cos(f * t))))
return lon, lat
@pytest.fixture
def fieldset_decaying(xdim=100, ydim=100, maxtime=delta(hours=6)):
"""Generate a FieldSet encapsulating the flow field of a decaying eddy.
Reference: N. Fabbroni, 2009, "Numerical simulations of passive
tracers dispersion in the sea"
"""
time = np.arange(0., maxtime.total_seconds()+1e-5, 60., dtype=np.float64)
dimensions = {'lon': np.linspace(0, 25000, xdim, dtype=np.float32),
'lat': np.linspace(0, 25000, ydim, dtype=np.float32),
'time': time}
data = {'U': np.ones((xdim, ydim, 1), dtype=np.float32) * u_g * np.exp(-gamma_g * time) + (u_0 - u_g) * np.exp(-gamma * time) * np.cos(f * time),
'V': np.ones((xdim, ydim, 1), dtype=np.float32) * -(u_0 - u_g) * np.exp(-gamma * time) * np.sin(f * time)}
return FieldSet.from_data(data, dimensions, mesh='flat', transpose=True)
@pytest.mark.parametrize('pset_mode', pset_modes)
@pytest.mark.parametrize('mode', ['scipy', 'jit'])
@pytest.mark.parametrize('method, rtol, diffField', [
('EE', 1e-2, False),
('AdvDiffEM', 1e-2, True),
('AdvDiffM1', 1e-2, True),
('RK4', 1e-5, False),
('RK45', 1e-5, False)])
def test_decaying_eddy(pset_mode, fieldset_decaying, mode, method, rtol, diffField, npart=1):
fieldset = fieldset_decaying
if diffField:
fieldset.add_field(Field('Kh_zonal', np.zeros(fieldset.U.data.shape), grid=fieldset.U.grid))
fieldset.add_field(Field('Kh_meridional', np.zeros(fieldset.V.data.shape), grid=fieldset.V.grid))
fieldset.add_constant('dres', 0.1)
lon = np.linspace(12000, 21000, npart)
lat = np.linspace(12500, 12500, npart)
pset = pset_type[pset_mode]['pset'](fieldset, pclass=ptype[mode], lon=lon, lat=lat)
endtime = delta(hours=6).total_seconds()
pset.execute(kernel[method], dt=delta(minutes=3), endtime=endtime)
exp_lon = [truth_decaying(x, y, endtime)[0] for x, y, in zip(lon, lat)]
exp_lat = [truth_decaying(x, y, endtime)[1] for x, y, in zip(lon, lat)]
assert np.allclose(pset.lon, exp_lon, rtol=rtol)
assert np.allclose(pset.lat, exp_lat, rtol=rtol)
@pytest.mark.parametrize('pset_mode', pset_modes)
@pytest.mark.parametrize('mode', ['scipy', 'jit'])
def test_analyticalAgrid(pset_mode, mode):
lon = np.arange(0, 15, dtype=np.float32)
lat = np.arange(0, 15, dtype=np.float32)
U = np.ones((lat.size, lon.size), dtype=np.float32)
V = np.ones((lat.size, lon.size), dtype=np.float32)
fieldset = FieldSet.from_data({'U': U, 'V': V}, {'lon': lon, 'lat': lat}, mesh='flat')
pset = pset_type[pset_mode]['pset'](fieldset, pclass=ptype[mode], lon=1, lat=1)
failed = False
try:
pset.execute(AdvectionAnalytical, runtime=1)
except NotImplementedError:
failed = True
assert failed
@pytest.mark.parametrize('pset_mode', pset_modes)
@pytest.mark.parametrize('mode', ['scipy']) # JIT not implemented
@pytest.mark.parametrize('u', [1, -0.2, -0.3, 0])
@pytest.mark.parametrize('v', [1, -0.3, 0, -1])
@pytest.mark.parametrize('w', [None, 1, -0.3, 0, -1])
@pytest.mark.parametrize('direction', [1, -1])
def test_uniform_analytical(pset_mode, mode, u, v, w, direction, tmpdir):
lon = np.arange(0, 15, dtype=np.float32)
lat = np.arange(0, 15, dtype=np.float32)
if w is not None:
depth = np.arange(0, 40, 2, dtype=np.float32)
U = u * np.ones((depth.size, lat.size, lon.size), dtype=np.float32)
V = v * np.ones((depth.size, lat.size, lon.size), dtype=np.float32)
W = w * np.ones((depth.size, lat.size, lon.size), dtype=np.float32)
fieldset = FieldSet.from_data({'U': U, 'V': V, 'W': W}, {'lon': lon, 'lat': lat, 'depth': depth}, mesh='flat')
fieldset.W.interp_method = 'cgrid_velocity'
else:
U = u * np.ones((lat.size, lon.size), dtype=np.float32)
V = v * np.ones((lat.size, lon.size), dtype=np.float32)
fieldset = FieldSet.from_data({'U': U, 'V': V}, {'lon': lon, 'lat': lat}, mesh='flat')
fieldset.U.interp_method = 'cgrid_velocity'
fieldset.V.interp_method = 'cgrid_velocity'
x0, y0, z0 = 6.1, 6.2, 20
pset = pset_type[pset_mode]['pset'](fieldset, pclass=ptype[mode], lon=x0, lat=y0, depth=z0)
outfile_path = tmpdir.join("uniformanalytical.nc")
outfile = pset.ParticleFile(name=outfile_path, outputdt=1)
pset.execute(AdvectionAnalytical, runtime=4, dt=direction,
output_file=outfile)
outfile.close()
assert np.abs(pset.lon - x0 - 4 * u * direction) < 1e-6
assert np.abs(pset.lat - y0 - 4 * v * direction) < 1e-6
if w:
assert np.abs(pset.depth - z0 - 4 * w * direction) < 1e-4
dataset = Dataset(outfile_path, 'r', 'NETCDF4')
times = dataset.variables['time'][:]
timeref = direction * np.arange(0, 5)
logger.info("analytical - time: {}".format(times))
logger.info("analytical - reference: {}".format(timeref))
assert np.allclose(times, timeref)
lons = dataset.variables['lon'][:]
assert np.allclose(lons, x0+direction*u*np.arange(0, 5))