def test_depths_go_to_zero(self):
# Depth information is meant to be discarded when a site collection is
# created.
s1 = Site(location=Point(10, 20, 30),
vs30=1.2, vs30measured=True,
z1pt0=3.4, z2pt5=5.6)
s2 = Site(location=Point(-1.2, -3.4, -5.6),
vs30=55.4, vs30measured=False,
z1pt0=66.7, z2pt5=88.9)
cll = SiteCollection([s1, s2])
cll_sites = list(cll)
exp_s1 = Site(location=Point(10, 20, 0.0),
vs30=1.2, vs30measured=True,
z1pt0=3.4, z2pt5=5.6)
exp_s2 = Site(location=Point(-1.2, -3.4, 0.0),
vs30=55.4, vs30measured=False,
z1pt0=66.7, z2pt5=88.9)
for i, s in enumerate([exp_s1, exp_s2]):
self.assertEqual(s, cll_sites[i])
# test equality of site collections
sc = SiteCollection([exp_s1, exp_s2])
self.assertEqual(cll, sc)
# test nonequality of site collections
# (see https://github.com/gem/oq-hazardlib/pull/403)
sc._vs30 = numpy.array([numpy.nan, numpy.nan])
self.assertNotEqual(cll, sc)
def test_expand_1d(self):
col = SiteCollection(self.SITES)
col = col.filter(numpy.array([1, 0, 1, 1]))
data_condensed = numpy.array([5, 6, 7])
data_expanded = col.expand(data_condensed, placeholder=100)
data_expanded_expected = numpy.array([5, 100, 6, 7])
numpy.testing.assert_array_equal(data_expanded, data_expanded_expected)
def test_within_region(self):
region = wkt.loads('POLYGON((0 0, 9 0, 9 9, 0 9, 0 0))')
col = SiteCollection(self.SITES)
reducedcol = col.within(region)
# point (10, 20) is out, point (11, 12) is out, point (0, 2)
# is on the boundary i.e. out, (1, 1) is in
self.assertEqual(len(reducedcol), 1)
def test_expand_no_filtering(self):
col = SiteCollection(self.SITES)
data_condensed = numpy.array([3, 2, 1, 0])
data_expanded = col.expand(data_condensed, total_sites=4,
placeholder=100)
data_expanded_expected = data_condensed
numpy.testing.assert_array_equal(data_expanded, data_expanded_expected)
def test_filter(self):
col = SiteCollection(self.SITES)
filtered = col.filter(numpy.array([True, False, True, False]))
arreq = numpy.testing.assert_array_equal
arreq(filtered.vs30, [1.2, 2])
arreq(filtered.vs30measured, [True, True])
arreq(filtered.z1pt0, [3, 9])
arreq(filtered.z2pt5, [5, 17])
arreq(filtered.mesh.lons, [10, 0])
arreq(filtered.mesh.lats, [20, 2])
arreq(filtered.mesh.depths, [30, 0])
arreq(filtered.sids, [0, 2])
filtered = col.filter(numpy.array([False, True, True, True]))
arreq(filtered.vs30, [55.4, 2, 4])
arreq(filtered.vs30measured, [False, True, False])
arreq(filtered.z1pt0, [6, 9, 22])
arreq(filtered.z2pt5, [8, 17, 11])
arreq(filtered.mesh.lons, [11, 0, 1])
arreq(filtered.mesh.lats, [12, 2, 1])
arreq(filtered.mesh.depths, [13, 0, 3])
# test serialization to hdf5
fd, fpath = tempfile.mkstemp(suffix='.hdf5')
os.close(fd)
with hdf5.File(fpath, 'w') as f:
f['sitecol'] = filtered
saved = f['sitecol']
self.assertEqual(saved, filtered)
os.remove(fpath)
def test_from_sites(self):
s1 = Site(location=Point(10, 20, 30),
vs30=1.2, vs30measured=True,
z1pt0=3.4, z2pt5=5.6, backarc=True)
s2 = Site(location=Point(-1.2, -3.4, -5.6),
vs30=55.4, vs30measured=False,
z1pt0=66.7, z2pt5=88.9, backarc=False)
cll = SiteCollection([s1, s2])
self.assertTrue((cll.vs30 == [1.2, 55.4]).all())
self.assertTrue((cll.vs30measured == [True, False]).all())
self.assertTrue((cll.z1pt0 == [3.4, 66.7]).all())
self.assertTrue((cll.z2pt5 == [5.6, 88.9]).all())
self.assertTrue((cll.mesh.lons == [10, -1.2]).all())
self.assertTrue((cll.mesh.lats == [20, -3.4]).all())
self.assertTrue((cll.backarc == [True, False]).all())
self.assertIs(cll.mesh.depths, None)
for arr in (cll.vs30, cll.z1pt0, cll.z2pt5):
self.assertIsInstance(arr, numpy.ndarray)
self.assertEqual(arr.flags.writeable, False)
self.assertEqual(arr.dtype, float)
for arr in (cll.vs30measured, cll.backarc):
self.assertIsInstance(arr, numpy.ndarray)
self.assertEqual(arr.flags.writeable, False)
self.assertEqual(arr.dtype, bool)
self.assertEqual(len(cll), 2)
# test __toh5__ and __fromh5__
array, attrs = cll.__toh5__()
newcll = cll.__new__(cll.__class__)
newcll.__fromh5__(array, attrs)
self.assertEqual(newcll, cll)
def test_split(self):
col = SiteCollection(self.SITES)
close_sites, far_sites = col.split(Point(10, 19), distance=200)
self.assertEqual(len(close_sites), 1)
self.assertEqual(len(far_sites), 3)
close_sites, far_sites = col.split(Point(10, 19), distance=0)
self.assertIsNone(close_sites)
self.assertEqual(len(far_sites), 4)
close_sites, far_sites = col.split(Point(10, 19), distance=None)
self.assertEqual(len(close_sites), 4)
self.assertIsNone(far_sites)
def test_double_filter(self):
col = SiteCollection(self.SITES)
filtered = col.filter(numpy.array([True, False, True, True]))
filtered2 = filtered.filter(numpy.array([False, True, False]))
arreq = numpy.testing.assert_array_equal
arreq(filtered2.vs30, [2])
arreq(filtered2.vs30measured, [True])
arreq(filtered2.z1pt0, [9])
arreq(filtered2.z2pt5, [17])
arreq(filtered2.mesh.lons, [0])
arreq(filtered2.mesh.lats, [2])
arreq(filtered2.mesh.depths, [0])
filtered2 = filtered.filter(numpy.array([True, False, True]))
arreq(filtered2.vs30, [1.2, 4.])
def test_expand_2d(self):
col = SiteCollection(self.SITES).filter(numpy.array([False, True, False, True]))
data_condensed = numpy.array([
[1, 2, 3],
[5, 6, 7],
])
data_expanded = col.expand(data_condensed, placeholder=-1)
data_expanded_expected = numpy.array([
[-1, -1, -1],
[1, 2, 3],
[-1, -1, -1],
[5, 6, 7],
])
numpy.testing.assert_array_equal(data_expanded, data_expanded_expected)
def filter_hanging_wall(self, filter_type=None):
"""
Opt to consider only hanging wall or footwall sites
"""
if not filter_type:
# Considers both footwall and hanging wall
return self.target_sites
elif not filter_type in ['HW', 'FW']:
raise ValueError('Hanging wall filter must be either "HW" or "FW"')
else:
pass
# Gets the Rx distance
r_x = self.surface.get_rx_distance(self.target_sites.mesh)
selected_sites = []
if filter_type == "HW":
# Only hanging wall
idx = np.where(r_x >= 0.)[0]
else:
# Only footwall
idx = np.where(r_x < 0.)[0]
for val in idx:
selected_sites.append(self.target_sites.sites[val])
self.target_sites = SiteCollection(selected_sites)
return self.target_sites
def test_from_points(self):
lons = [10, -1.2]
lats = [20, -3.4]
cll = SiteCollection.from_points(lons, lats, [1, 2], SiteModelParam())
assert_eq(cll.vs30, [1.2, 1.2])
assert_eq(cll.vs30measured, [True, True])
assert_eq(cll.z1pt0, [3.4, 3.4])
assert_eq(cll.z2pt5, [5.6, 5.6])
assert_eq(cll.mesh.lons, [10, -1.2])
assert_eq(cll.mesh.lats, [20, -3.4])
assert_eq(cll.mesh.depths, None)
assert_eq(cll.backarc, [False, False])
for arr in (cll.vs30, cll.z1pt0, cll.z2pt5):
self.assertIsInstance(arr, numpy.ndarray)
self.assertEqual(arr.dtype, float)
for arr in (cll.vs30measured, cll.backarc):
self.assertIsInstance(arr, numpy.ndarray)
self.assertEqual(arr.flags.writeable, False)
self.assertEqual(arr.dtype, bool)
self.assertEqual(len(cll), 2)
# test split_in_tiles
tiles = cll.split_in_tiles(0)
self.assertEqual(len(tiles), 1)
tiles = cll.split_in_tiles(1)
self.assertEqual(len(tiles), 1)
tiles = cll.split_in_tiles(2)
self.assertEqual(len(tiles), 2)
def _append_target_sites(self, distances, azimuth, origin_location, vs30,
line_azimuth=90., origin_point=(0.5, 0.5),
as_log=False, vs30measured=True, z1pt0=None,
z2pt5=None, backarc=False):
"""
Appends the target sites along a line with respect to the rupture,
given an already set origin target site
"""
for offset in distances:
target_loc = origin_location.point_at(offset, 0., azimuth)
self.target_sites.append(Site(target_loc,
vs30,
z1pt0,
z2pt5,
vs30measured=vs30measured,
backarc=backarc))
self.target_sites_config = {
"TYPE": "Line",
"RMAX": distances[-1],
"SPACING": np.nan if len(distances) < 2 else
distances[1] - distances[0], # FIXME does it make sense?
"AZIMUTH": line_azimuth,
"ORIGIN": origin_point,
"AS_LOG": as_log,
"VS30": vs30,
"VS30MEASURED": vs30measured,
"Z1.0": z1pt0,
"Z2.5": z2pt5,
"BACKARC": backarc}
self.target_sites = SiteCollection(self.target_sites)
return self.target_sites
def test_from_points(self):
lons = [10, -1.2]
lats = [20, -3.4]
depths = [30, -5.6]
req_params = 'vs30 vs30measured z1pt0 z2pt5 backarc'.split()
cll = SiteCollection.from_points(
lons, lats, depths, SiteModelParam(), req_params)
assert_eq(cll.vs30, [1.2, 1.2])
assert_eq(cll.vs30measured, [True, True])
assert_eq(cll.z1pt0, [3.4, 3.4])
assert_eq(cll.z2pt5, [5.6, 5.6])
assert_eq(cll.mesh.lons, [10, -1.1999999999999886])
assert_eq(cll.mesh.lats, [20, -3.4])
assert_eq(cll.mesh.depths, [30, -5.6])
assert_eq(cll.backarc, [False, False])
for arr in (cll.vs30, cll.z1pt0, cll.z2pt5):
self.assertIsInstance(arr, numpy.ndarray)
self.assertEqual(arr.dtype, float)
for arr in (cll.vs30measured, cll.backarc):
self.assertIsInstance(arr, numpy.ndarray)
self.assertEqual(arr.dtype, bool)
self.assertEqual(len(cll), 2)
# test split_in_tiles
tiles = cll.split_in_tiles(0)
self.assertEqual(len(tiles), 1)
tiles = cll.split_in_tiles(1)
self.assertEqual(len(tiles), 1)
tiles = cll.split_in_tiles(2)
self.assertEqual(len(tiles), 2)
def get_target_sites_line(self, maximum_distance, spacing, vs30,
line_azimuth=90., origin_point=(0.5, 0.5), vs30measured=True,
z1pt0=None, z2pt5=None):
"""
Defines the target sites along a line with respect to the rupture
"""
azimuth, origin_point, z1pt0, z2pt5 = _setup_site_peripherals(
line_azimuth,
origin_point,
vs30,
z1pt0,
z2pt5,
self.strike,
self.surface)
targets = [origin_point]
self.target_sites = []
distance = 0.
cum_dist = distance + spacing
while distance < maximum_distance:
target_loc= origin_point.point_at(cum_dist, 0., azimuth)
# Get Rupture distance
temp_mesh = Mesh(np.array(target_loc.longitude),
np.array(target_loc.latitude),
np.array(target_loc.depth))
distance = self.surface.get_min_distance(temp_mesh)
self.target_sites.append(Site(target_loc,
vs30,
vs30measured,
z1pt0,
z2pt5))
cum_dist += spacing
self.target_sites = SiteCollection(self.target_sites)
return self.target_sites
def test_normal(self):
lons = [10, -1.2]
lats = [20, -3.4]
maximum_distance = {"Subduction IntraSlab": 200}
sitecol = SiteCollection.from_points(lons, lats, SiteModelParam())
tile = Tile(sitecol, maximum_distance)
self.assertEqual(repr(tile), "<Tile -1 <= lon <= 10, -3 <= lat <= 20>")
src = make_point_source(1, 10)
self.assertTrue(src in tile)
def test_cross_idl(self):
lons = [-179.2, 178.0]
lats = [3.0, 4.0]
maximum_distance = {"Subduction IntraSlab": 200}
sitecol = SiteCollection.from_points(lons, lats, SiteModelParam())
tile = Tile(sitecol, maximum_distance)
self.assertEqual(repr(tile), "<Tile 178 <= lon <= 180, 3 <= lat <= 4>")
src = make_point_source(-179.3, 3.5)
self.assertTrue(src in tile)
src = make_point_source(178.2, 3.5)
self.assertTrue(src in tile)
def get_target_sites_line(self, maximum_distance, spacing, vs30,
line_azimuth=90., origin_point=(0.5, 0.5), as_log=False,
vs30measured=True, z1pt0=None, z2pt5=None, backarc=False):
"""
Defines the target sites along a line with respect to the rupture
"""
#input_origin_point = deepcopy(origin_point)
azimuth, origin_location, z1pt0, z2pt5 = _setup_site_peripherals(
line_azimuth,
origin_point,
vs30,
z1pt0,
z2pt5,
self.strike,
self.surface)
self.target_sites = [Site(origin_location,
vs30,
vs30measured,
z1pt0,
z2pt5,
backarc=backarc)]
spacings = self._define_line_spacing(maximum_distance,
spacing,
as_log)
for offset in spacings:
target_loc= origin_location.point_at(offset, 0., azimuth)
# Get Rupture distance
temp_mesh = Mesh(np.array(target_loc.longitude),
np.array(target_loc.latitude),
np.array(target_loc.depth))
distance = self.surface.get_min_distance(temp_mesh)
self.target_sites.append(Site(target_loc,
vs30,
vs30measured,
z1pt0,
z2pt5,
backarc=backarc))
self.target_sites_config = {
"TYPE": "Line",
"RMAX": maximum_distance,
"SPACING": spacing,
"AZIMUTH": line_azimuth,
"ORIGIN": origin_point,
"AS_LOG": as_log,
"VS30": vs30,
"VS30MEASURED": vs30measured,
"Z1.0": z1pt0,
"Z2.5": z2pt5,
"BACKARC": backarc}
self.target_sites = SiteCollection(self.target_sites)
return self.target_sites
def test_expand_2d(self):
col = SiteCollection(self.SITES)
col.indices = numpy.array([1, 3, 5, 6])
data_condensed = numpy.array([
[1, 2, 3],
[5, 6, 7],
[10, 11, 12],
[15, 16, 17]
])
data_expanded = col.expand(data_condensed, total_sites=8,
placeholder=-1)
data_expanded_expected = numpy.array([
[-1, -1, -1],
[1, 2, 3],
[-1, -1, -1],
[5, 6, 7],
[-1, -1, -1],
[10, 11, 12],
[15, 16, 17],
[-1, -1, -1]
])
numpy.testing.assert_array_equal(data_expanded, data_expanded_expected)
def test_filter(self):
col = SiteCollection(self.SITES)
filtered = col.filter(numpy.array([True, False, True, False]))
self.assertIsInstance(filtered, FilteredSiteCollection)
arreq = numpy.testing.assert_array_equal
arreq(filtered.vs30, [1.2, 2])
arreq(filtered.vs30measured, [True, True])
arreq(filtered.z1pt0, [3, 9])
arreq(filtered.z2pt5, [5, 17])
arreq(filtered.mesh.lons, [10, 0])
arreq(filtered.mesh.lats, [20, 2])
self.assertIs(filtered.mesh.depths, None)
filtered = col.filter(numpy.array([False, True, True, True]))
self.assertIsInstance(filtered, FilteredSiteCollection)
arreq(filtered.vs30, [55.4, 2, 4])
arreq(filtered.vs30measured, [False, True, False])
arreq(filtered.z1pt0, [6, 9, 22])
arreq(filtered.z2pt5, [8, 17, 11])
arreq(filtered.mesh.lons, [11, 0, 1])
arreq(filtered.mesh.lats, [12, 2, 1])
self.assertIs(filtered.mesh.depths, None)
def get_target_sites_mesh(self, maximum_distance, spacing, vs30,
vs30measured=True, z1pt0=None, z2pt5=None,
backarc=False):
"""
Renders a two dimensional mesh of points over the rupture surface
"""
# Get bounding box of dilated rupture
lowx, highx, lowy, highy = self._get_limits_maximum_rjb(
maximum_distance)
# Create bounding box lines and then resample at spacing
ewline = Line([Point(lowx, highy, 0.), Point(highx, highy, 0.)])
nsline = Line([Point(lowx, highy, 0.), Point(lowx, lowy, 0.)])
ewline = ewline.resample(spacing)
nsline = nsline.resample(spacing)
xvals = np.array([pnt.longitude for pnt in ewline.points])
yvals = np.array([pnt.latitude for pnt in nsline.points])
gridx, gridy = np.meshgrid(xvals, yvals)
numx, numy = np.shape(gridx)
npts = numx * numy
gridx = (np.reshape(gridx, npts, 1)).flatten()
gridy = (np.reshape(gridy, npts, 1)).flatten()
site_list = []
if not z1pt0:
# z1pt0 = vs30_to_z1pt0_as08(vs30)
z1pt0 = vs30_to_z1pt0_cy14(vs30)
if not z2pt5:
# z2pt5 = z1pt0_to_z2pt5(z1pt0)
z2pt5 = vs30_to_z2pt5_cb14(vs30)
for iloc in range(0, npts):
site_list.append(Site(Point(gridx[iloc], gridy[iloc], 0.),
vs30,
z1pt0,
z2pt5,
vs30measured=vs30measured,
backarc=backarc))
self.target_sites = SiteCollection(site_list)
self.target_sites_config = {
"TYPE": "Mesh",
"RMAX": maximum_distance,
"SPACING": spacing,
"VS30": vs30,
"VS30MEASURED": vs30measured,
"Z1.0": z1pt0,
"Z2.5": z2pt5,
"BACKARC": backarc}
return self.target_sites
def test_sites_of_interest(self):
calc = hazard_getters.GroundMotionValuesCalcGetter(
self.imt, self.sites, self.sites_assets, 0, self.gsims, None)
r = ProbabilisticRupture(
mag=5.5,
rake=123.45,
tectonic_region_type=mock.Mock(),
hypocenter=Point(5, 6, 7),
surface=PlanarSurface(10, 11, 12,
Point(0, 0, 1), Point(1, 0, 1),
Point(1, 0, 2), Point(0, 0, 2)
),
occurrence_rate=1,
temporal_occurrence_model=mock.Mock(),
source_typology=mock.Mock())
r.source_typology.filter_sites_by_distance_to_rupture = mock.Mock(
return_value=None)
sites, _idxs = calc.sites_of_interest(r, 0)
self.assertEqual([], sites)
ret = SiteCollection(list(iter(self.sites)))
ret.indices = [1]
r.source_typology.filter_sites_by_distance_to_rupture = mock.Mock(
return_value=ret)
sites, idxs = calc.sites_of_interest(r, 100)
self.assertEqual(1, len(sites))
self.assertEqual(1, len(idxs))
self.assertEqual(1, idxs[0])
self.assertEqual(1, sites.get_by_id(1).id)
ret.indices = [0, 2]
r.source_typology.filter_sites_by_distance_to_rupture = mock.Mock(
return_value=ret)
sites, idxs = calc.sites_of_interest(r, 1000)
self.assertEqual(2, len(sites))
self.assertEqual([0, 2], idxs)
def test(self):
d = os.path.dirname(os.path.dirname(__file__))
source_model = os.path.join(d, 'source_model/multi-point-source.xml')
groups = nrml.parse(
source_model,
SourceConverter(investigation_time=50., rupture_mesh_spacing=2.))
site = Site(Point(0.1, 0.1), 800, True, z1pt0=100., z2pt5=1.)
sitecol = SiteCollection([site])
imtls = DictArray({'PGA': [0.01, 0.02, 0.04, 0.08, 0.16]})
gsim_by_trt = {'Stable Continental Crust': Campbell2003()}
hcurves = calc_hazard_curves(groups, sitecol, imtls, gsim_by_trt)
expected = [
0.99999778, 0.9084039, 0.148975348, 0.0036909656, 2.76326e-05
]
npt.assert_almost_equal(hcurves['PGA'][0], expected)
# splitting in point sources
[[mps1, mps2]] = groups
psources = list(mps1) + list(mps2)
hcurves = calc_hazard_curves(psources, sitecol, imtls, gsim_by_trt)
npt.assert_almost_equal(hcurves['PGA'][0], expected)
def test_some_values(self):
self.gsim_class.REQUIRES_DISTANCES = set('rjb rx'.split())
self.gsim_class.REQUIRES_RUPTURE_PARAMETERS = \
set('mag strike rake hypo_lon'.split())
self.gsim_class.REQUIRES_SITES_PARAMETERS = \
set('vs30 z1pt0 lons'.split())
sites = SiteCollection([self.site1, self.site2])
rctx, sctx, dctx = self.make_contexts(sites, self.rupture)
self.assertEqual((rctx.mag, rctx.rake, rctx.strike, rctx.hypo_lon),
(123.45, 123.56, 60.123, 2))
aac(sctx.vs30, (456, 1456))
aac(sctx.z1pt0, (12.1, 112.1))
aac(sctx.lons, [1, -2])
aac(dctx.rx, (4, 5))
self.assertEqual(
self.fake_surface.call_counts, {
'get_min_distance': 1,
'get_joyner_boore_distance': 1,
'get_rx_distance': 1,
'get_strike': 1
})
def example_calc(apply):
sitecol = SiteCollection([
Site(Point(30.0, 30.0), 760., 1.0, 1.0),
Site(Point(30.25, 30.25), 760., 1.0, 1.0),
Site(Point(30.4, 30.4), 760., 1.0, 1.0)])
mfd_1 = TruncatedGRMFD(4.5, 8.0, 0.1, 4.0, 1.0)
mfd_2 = TruncatedGRMFD(4.5, 7.5, 0.1, 3.5, 1.1)
sources = [PointSource('001', 'Point1', 'Active Shallow Crust',
mfd_1, 1.0, WC1994(), 1.0, PoissonTOM(50.0),
0.0, 30.0, Point(30.0, 30.5),
PMF([(1.0, NodalPlane(0.0, 90.0, 0.0))]),
PMF([(1.0, 10.0)])),
PointSource('002', 'Point2', 'Active Shallow Crust',
mfd_2, 1.0, WC1994(), 1.0, PoissonTOM(50.0),
0.0, 30.0, Point(30.0, 30.5),
PMF([(1.0, NodalPlane(0.0, 90.0, 0.0))]),
PMF([(1.0, 10.0)]))]
imtls = {'PGA': [0.01, 0.1, 0.2, 0.5, 0.8],
'SA(0.5)': [0.01, 0.1, 0.2, 0.5, 0.8]}
gsims = {'Active Shallow Crust': AkkarBommer2010()}
return calc_hazard_curves(sources, sitecol, imtls, gsims, apply=apply,
filter_distance='rrup')
def test(self):
d = os.path.dirname(os.path.dirname(__file__))
source_model = os.path.join(d, 'source_model/multi-point-source.xml')
groups = nrml.to_python(
source_model,
SourceConverter(investigation_time=50., rupture_mesh_spacing=2.))
site = Site(Point(0.1, 0.1), 800, z1pt0=100., z2pt5=1.)
sitecol = SiteCollection([site])
imtls = DictArray({'PGA': [0.01, 0.02, 0.04, 0.08, 0.16]})
gsim_by_trt = {'Stable Continental Crust': Campbell2003()}
hcurves = calc_hazard_curves(groups, sitecol, imtls, gsim_by_trt)
expected = [
9.999978e-01, 9.084040e-01, 1.489753e-01, 3.690966e-03,
2.763261e-05
]
npt.assert_allclose(hcurves['PGA'][0], expected, rtol=1E-6, atol=1E-6)
# splitting in point sources
[[mps1, mps2]] = groups
psources = list(mps1) + list(mps2)
hcurves = calc_hazard_curves(psources, sitecol, imtls, gsim_by_trt)
npt.assert_allclose(hcurves['PGA'][0], expected, rtol=1E-4, atol=1E-6)
def test_495_km(self):
rup = self._make_rupture(7, 10, 30)
# the JB distance area [5.84700762, 6.8290327, 14.53519629,
# 496.25926891, 497.37116174] so given that the integration
# distance is 495 only the first 3 sites are kept
filtered = filters.filter_sites_by_distance_to_rupture(
rup, integration_distance=495, sites=self.sitecol)
expected_filtered = SiteCollection(self.SITES[:3])
numpy.testing.assert_array_equal(filtered.indices, [0, 1, 2])
numpy.testing.assert_array_equal(filtered.vs30, expected_filtered.vs30)
numpy.testing.assert_array_equal(filtered.vs30measured,
expected_filtered.vs30measured)
numpy.testing.assert_array_equal(filtered.z1pt0,
expected_filtered.z1pt0)
numpy.testing.assert_array_equal(filtered.z2pt5,
expected_filtered.z2pt5)
numpy.testing.assert_array_equal(filtered.mesh.lons,
expected_filtered.mesh.lons)
numpy.testing.assert_array_equal(filtered.mesh.lats,
expected_filtered.mesh.lats)
numpy.testing.assert_array_equal(filtered.mesh.depths,
expected_filtered.mesh.depths)
def point_at_distance(self, model, distance, vs30, line_azimuth=90.,
origin_point=(0.5, 0.), vs30measured=True,
z1pt0=None, z2pt5=None, backarc=False):
"""
Generates a site given a specified rupture distance from the
rupture surface
"""
azimuth, origin_location, z1pt0, z2pt5 = _setup_site_peripherals(
line_azimuth, origin_point, vs30, z1pt0, z2pt5, model.strike,
model.surface)
selected_point = _rup_to_point(distance,
model.surface,
origin_location,
azimuth,
'rjb')
target_sites = SiteCollection([Site(selected_point,
vs30,
vs30measured,
z1pt0,
z2pt5,
backarc=backarc)])
return target_sites
def site_array_to_collection(site_array):
"""
Converts a set of sites from a 2D numpy array to an instance of :class:
openquake.hazardlib.site.SiteCollection
:param np.ndarray site_array:
Site parameters as [ID, Long, Lat, vs30, vs30measured, z1pt0, z2pt5,
backarc]
"""
site_list = []
n_sites, n_param = np.shape(site_array)
if n_param != 8:
raise ValueError('Site array incorrectly formatted!')
for iloc in range(0, n_sites):
site = Site(Point(site_array[iloc, 1], site_array[iloc, 2]), # Location
site_array[iloc, 3], # Vs30
site_array[iloc, 4].astype(bool), # vs30measured
site_array[iloc, 5], # z1pt0
site_array[iloc, 6], # z2pt5
site_array[iloc, 7].astype(bool), # Backarc
site_array[iloc, 0].astype(int)) # ID
site_list.append(site)
return SiteCollection(site_list)
def get_regular_site_collection(limits, vs30, z1pt0=100.0, z2pt5=1.0):
"""
Gets a collection of sites from a regularly spaced grid of points
:param list limits:
Limits of mesh as [lower_long, upper_long, long_spc, lower_lat,
upper_lat, lat_spc]
:param float vs30:
Vs30 values
:param float z1pt0:
Depth (m) to the 1 km/s interface
:param float z2pt5:
Depth (km) to the 2.5 km/s interface
"""
xgrd = np.arange(limits[0], limits[1] + limits[2], limits[2])
ygrd = np.arange(limits[3], limits[4] + limits[5], limits[5])
gx, gy = np.meshgrid(xgrd, ygrd)
nx, ny = np.shape(gx)
ngp = nx * ny
gx = np.reshape(gx, [ngp, 1]).flatten()
gy = np.reshape(gy, [ngp, 1]).flatten()
return SiteCollection(
[Site(Point(gx[i], gy[i]), vs30, z1pt0, z2pt5) for i in range(0, ngp)])
def test_mearn_nearfault_distance_taper(self):
rupture = self.make_rupture()
site1 = Site(location=Point(27.9, 41),
vs30=1200.,
vs30measured=True,
z1pt0=2.36,
z2pt5=2.)
site2 = Site(location=Point(28.1, 41),
vs30=1200.,
vs30measured=True,
z1pt0=2.36,
z2pt5=2.)
sites = SiteCollection([site1, site2])
fields = ground_motion_fields(rupture,
sites, [PGV()],
ChiouYoungs2014NearFaultEffect(),
truncation_level=0,
realizations=1)
gmf = fields[PGV()]
self.assertAlmostEquals(2.27328758, gmf[0], delta=1e-4)
self.assertAlmostEquals(3.38322998, gmf[1], delta=1e-4)
def test_all_values(self):
self.gsim_class.REQUIRES_DISTANCES = set(
'rjb rx rrup repi rhypo ry0 azimuth'.split())
self.gsim_class.REQUIRES_RUPTURE_PARAMETERS = set(
'mag rake strike dip ztor hypo_lon hypo_lat hypo_depth width'.
split())
self.gsim_class.REQUIRES_SITES_PARAMETERS = set(
'vs30 vs30measured z1pt0 z2pt5 lons lats'.split())
sites = SiteCollection([self.site1, self.site2])
sctx, dctx = self.make_contexts(sites, self.rupture)
rctx = self.rupture
self.assertEqual(rctx.mag, 123.45)
self.assertEqual(rctx.rake, 123.56)
self.assertEqual(rctx.strike, 60.123)
self.assertEqual(rctx.dip, 45.4545)
self.assertEqual(rctx.ztor, 30)
self.assertEqual(rctx.hypo_lon, 2)
self.assertEqual(rctx.hypo_lat, 3)
self.assertEqual(rctx.hypo_depth, 40)
self.assertEqual(rctx.width, 15)
aac(sctx.vs30, [456, 1456])
aac(sctx.vs30measured, [False, True])
aac(sctx.z1pt0, [12.1, 112.1])
aac(sctx.z2pt5, [15.1, 115.1])
aac(sctx.lons, [1, -2])
aac(sctx.lats, [2, -3])
aac(dctx.rjb, [6, 7])
aac(dctx.rx, [4, 5])
aac(dctx.ry0, [8, 9])
aac(dctx.rrup, [10, 11])
aac(dctx.azimuth, [12, 34])
aac(dctx.rhypo, [162.18749272, 802.72247682])
aac(dctx.repi, [157.17755181, 801.72524895])
self.assertEqual(self.fake_surface.call_counts,
{'get_top_edge_depth': 1, 'get_rx_distance': 1,
'get_joyner_boore_distance': 1, 'get_dip': 1,
'get_min_distance': 1, 'get_width': 1,
'get_strike': 1, 'get_ry0_distance': 1,
'get_azimuth': 1})
def get_target_sites_mesh(self, maximum_distance, spacing, vs30,
vs30measured=True, z1pt0=None, z2pt5=None):
"""
Renders a two dimensional mesh of points over the rupture surface
"""
# Get bounding box of dilated rupture
lowx, highx, lowy, highy = self._get_limits_maximum_rjb(
maximum_distance)
# Create bounding box lines and then resample at spacing
ewline = Line([Point(lowx, highy, 0.), Point(highx, highy, 0.)])
nsline = Line([Point(lowx, highy, 0.), Point(lowx, lowy, 0.)])
ewline = ewline.resample(spacing)
nsline = nsline.resample(spacing)
xvals = np.array([pnt.longitude for pnt in ewline.points])
yvals = np.array([pnt.latitude for pnt in nsline.points])
gridx, gridy = np.meshgrid(xvals, yvals)
numx, numy = np.shape(gridx)
npts = numx * numy
gridx = (np.reshape(gridx, npts, 1)).flatten()
gridy = (np.reshape(gridy, npts, 1)).flatten()
site_list = []
if not z1pt0:
z1pt0 = vs30_to_z1pt0_as08(vs30)
if not z2pt5:
z2pt5 = z1pt0_to_z2pt5(z1pt0)
for iloc in range(0, npts):
site_list.append(Site(Point(gridx[iloc], gridy[iloc], 0.),
vs30,
vs30measured,
z1pt0,
z2pt5))
self.target_sites = SiteCollection(site_list)
return self.target_sites
def test_from_sites(self):
s1 = Site(location=Point(10, 20, 30),
vs30=1.2,
vs30measured=True,
z1pt0=3.4,
z2pt5=5.6)
s2 = Site(location=Point(-1.2, -3.4, -5.6),
vs30=55.4,
vs30measured=False,
z1pt0=66.7,
z2pt5=88.9)
cll = SiteCollection([s1, s2])
assert_eq(cll.vs30, [1.2, 55.4])
assert_eq(cll.vs30measured, [True, False])
assert_eq(cll.z1pt0, [3.4, 66.7])
assert_eq(cll.z2pt5, [5.6, 88.9])
assert_eq(cll.mesh.lons, [10, -1.2])
assert_eq(cll.mesh.lats, [20, -3.4])
assert_eq(cll.mesh.depths, [30, -5.6])
for arr in (cll.vs30, cll.z1pt0, cll.z2pt5):
self.assertIsInstance(arr, numpy.ndarray)
self.assertEqual(arr.flags.writeable, False)
self.assertEqual(arr.dtype, float)
for arr in (cll.vs30measured, ):
self.assertIsInstance(arr, numpy.ndarray)
self.assertEqual(arr.flags.writeable, False)
self.assertEqual(arr.dtype, bool)
self.assertEqual(len(cll), 2)
# test serialization to hdf5
fd, fpath = tempfile.mkstemp(suffix='.hdf5')
os.close(fd)
with hdf5.File(fpath, 'w') as f:
f['folder'] = dict(sitecol=cll, b=[2, 3])
newcll = f['folder/sitecol']
self.assertEqual(newcll, cll)
self.assertEqual(list(f['folder/b']), [2, 3])
os.remove(fpath)
def test_nankai(self):
# source model for the Nankai region provided by M. Pagani
source_model = os.path.join(os.path.dirname(__file__), 'nankai.xml')
# it has a single group containing 15 mutex sources
[group] = nrml.to_python(source_model)
aae(group.srcs_weights, [
0.0125, 0.0125, 0.0125, 0.0125, 0.1625, 0.1625, 0.0125, 0.0125,
0.025, 0.025, 0.05, 0.05, 0.325, 0.025, 0.1
])
rup_serial = numpy.arange(group.tot_ruptures, dtype=numpy.uint32)
start = 0
for i, src in enumerate(group):
src.id = i
nr = src.num_ruptures
src.serial = rup_serial[start:start + nr]
start += nr
group.samples = 1
lonlat = 135.68, 35.68
site = Site(geo.Point(*lonlat), 800, True, z1pt0=100., z2pt5=1.)
s_filter = SourceFilter(SiteCollection([site]), {})
param = dict(ses_per_logic_tree_path=10,
seed=42,
filter_distance='rjb')
gsims = [SiMidorikawa1999SInter()]
dic = sample_ruptures(group, s_filter, gsims, param)
self.assertEqual(dic['num_ruptures'], 19) # total ruptures
self.assertEqual(dic['num_events'], 16)
self.assertEqual(len(dic['eb_ruptures']), 8)
self.assertEqual(len(dic['calc_times']), 15) # mutex sources
# test export
mesh = numpy.array([lonlat], [('lon', float), ('lat', float)])
ebr = dic['eb_ruptures'][0]
ebr.export(mesh)
# test no filtering
ruptures = list(stochastic_event_set(group))
self.assertEqual(len(ruptures), 19)
def test_all_values(self):
self.gsim_class.REQUIRES_DISTANCES = set(
'rjb rx rrup repi rhypo'.split())
self.gsim_class.REQUIRES_RUPTURE_PARAMETERS = set(
'mag rake dip ztor hypo_depth width'.split())
self.gsim_class.REQUIRES_SITES_PARAMETERS = set(
'vs30 vs30measured z1pt0 z2pt5'.split())
sites = SiteCollection([self.site1, self.site2])
sctx, rctx, dctx = self.gsim.make_contexts(sites, self.rupture)
self.assertIsInstance(sctx, SitesContext)
self.assertIsInstance(rctx, RuptureContext)
self.assertIsInstance(dctx, DistancesContext)
self.assertEqual(rctx.mag, 123.45)
self.assertEqual(rctx.rake, 123.56)
self.assertEqual(rctx.dip, 45.4545)
self.assertEqual(rctx.ztor, 30)
self.assertEqual(rctx.hypo_depth, 40)
self.assertEqual(rctx.width, 15)
self.assertTrue((sctx.vs30 == [456, 1456]).all())
self.assertTrue((sctx.vs30measured == [False, True]).all())
self.assertTrue((sctx.z1pt0 == [12.1, 112.1]).all())
self.assertTrue((sctx.z2pt5 == [15.1, 115.1]).all())
self.assertTrue((dctx.rjb == [6, 7]).all())
self.assertTrue((dctx.rx == [4, 5]).all())
self.assertTrue((dctx.rrup == [10, 11]).all())
numpy.testing.assert_almost_equal(dctx.rhypo,
[162.18749272, 802.72247682])
numpy.testing.assert_almost_equal(dctx.repi,
[157.17755181, 801.72524895])
self.assertEqual(
self.fake_surface.call_counts, {
'get_top_edge_depth': 1,
'get_rx_distance': 1,
'get_joyner_boore_distance': 1,
'get_dip': 1,
'get_min_distance': 1,
'get_width': 1
})
class JB2009ApplyCorrelationTestCase(unittest.TestCase):
SITECOL = SiteCollection([
Site(Point(2, -40), 1, True, 1, 1),
Site(Point(2, -40.1), 1, True, 1, 1),
Site(Point(2, -39.9), 1, True, 1, 1)
])
def test(self):
numpy.random.seed(13)
cormo = JB2009CorrelationModel(vs30_clustering=False)
intra_residuals_sampled = numpy.random.normal(size=(3, 100000))
intra_residuals_correlated = cormo.apply_correlation(
self.SITECOL, PGA(), intra_residuals_sampled)
inferred_corrcoef = numpy.corrcoef(intra_residuals_correlated)
mean = intra_residuals_correlated.mean()
std = intra_residuals_correlated.std()
self.assertAlmostEqual(mean, 0, delta=0.002)
self.assertAlmostEqual(std, 1, delta=0.002)
actual_corrcoef = cormo._get_correlation_matrix(self.SITECOL, PGA())
numpy.testing.assert_almost_equal(inferred_corrcoef,
actual_corrcoef,
decimal=2)
def _setup_sites_liquefaction_zhu():
"""
Returns a collection of sites for liquefaction hazard analysis using the
HAZUS method
"""
point_1 = Point(-64.98651, -0.15738)
point_2 = Point(-64.77466, -0.45686)
point_3 = Point(-64.92747, -0.38363)
point_4 = Point(-65.05396, -0.17088)
params = [[800., 0, 100., 0.0], [600., 1, 50., 1.0], [400., 2, 50., 2.0],
[300., 3, 20., 5.0], [200., 4, 20., 7.0], [150., 5, 20., 10.0],
[150., 5, 5., 15.0]]
sites = []
for locn in [point_1, point_2, point_3, point_4]:
for vs30, hazus_cat, dw, cti in params:
sites.append({
"lon": locn.longitude,
"lat": locn.latitude,
"vs30": vs30,
"vs30measured": False,
"z1pt0": 48.0,
"z2pt5": 0.607,
"liquefaction_susceptibility": hazus_cat,
"dw": dw,
"cti": cti
})
site_model_dt = np.dtype([(p, site_param_dt[p]) for p in sorted(sites[0])])
tuples = [
tuple(site[name] for name in site_model_dt.names) for site in sites
]
sites = np.array(tuples, site_model_dt)
req_site_params = ("vs30", "liquefaction_susceptibility", "dw", "cti")
return SiteCollection.from_points(sites["lon"],
sites["lat"],
sitemodel=sites,
req_site_params=req_site_params)
def test_case_10(self):
hypocenter_pmf = PMF([(1, test_data.SET1_CASE10_HYPOCENTER_DEPTH)])
sources = [AreaSource(
source_id='area', name='area',
tectonic_region_type=const.TRT.ACTIVE_SHALLOW_CRUST,
mfd=test_data.SET1_CASE10_MFD,
nodal_plane_distribution=PMF([(1, NodalPlane(0.0, 90.0, 0.0))]),
hypocenter_distribution=hypocenter_pmf,
upper_seismogenic_depth=0.0,
lower_seismogenic_depth=10.0,
magnitude_scaling_relationship=PointMSR(),
rupture_aspect_ratio=test_data.SET1_RUPTURE_ASPECT_RATIO,
temporal_occurrence_model=PoissonTOM(1.),
polygon=test_data.SET1_CASE10_SOURCE_POLYGON,
area_discretization=10.0,
rupture_mesh_spacing=10.0
)]
sites = SiteCollection([
test_data.SET1_CASE10_SITE1, test_data.SET1_CASE10_SITE2,
test_data.SET1_CASE10_SITE3, test_data.SET1_CASE10_SITE4
])
gsims = {const.TRT.ACTIVE_SHALLOW_CRUST: SadighEtAl1997()}
truncation_level = 0
imts = {str(test_data.IMT): test_data.SET1_CASE10_IMLS}
curves = calc_hazard_curves(
sources, sites, imts, gsims, truncation_level)
s1hc, s2hc, s3hc, s4hc = curves[str(test_data.IMT)]
assert_hazard_curve_is(self, s1hc, test_data.SET1_CASE10_SITE1_POES,
atol=1e-4, rtol=1e-1)
assert_hazard_curve_is(self, s2hc, test_data.SET1_CASE10_SITE2_POES,
atol=1e-4, rtol=1e-1)
assert_hazard_curve_is(self, s3hc, test_data.SET1_CASE10_SITE3_POES,
atol=1e-4, rtol=1e-1)
assert_hazard_curve_is(self, s4hc, test_data.SET1_CASE10_SITE4_POES,
atol=1e-4, rtol=1e-1)
def test_point_surface(self):
sid = 0
name = 'test'
trt = TRT.ACTIVE_SHALLOW_CRUST
mfd = ArbitraryMFD([7.0], [1.])
rms = 2.5
msr = WC1994()
rar = 1.0
tom = PoissonTOM(1.)
usd = 0.0
lsd = 20.0
loc = Point(0.0, 0.0)
npd = PMF([(1.0, NodalPlane(90., 90., 90.))])
hyd = PMF([(1.0, 10.)])
src = PointSource(sid, name, trt, mfd, rms, msr, rar, tom, usd, lsd,
loc, npd, hyd)
rups = [r for r in src.iter_ruptures()]
# Compute distances
param = 'closest_point'
sites = SiteCollection(
[Site(Point(0.0, 0.0, 0.0)),
Site(Point(-0.2, 0.0, 0.0))])
dsts = get_distances(rups[0], sites, param)
# Check first point
msg = 'The longitude of the first point is wrong'
self.assertTrue(abs(dsts[0, 0] - 0.0) < 1e-2, msg)
msg = 'The latitude of the first point is wrong'
self.assertTrue(abs(dsts[0, 1] - 0.0) < 1e-2, msg)
# Check second point
msg = 'The longitude of the second point is wrong'
self.assertTrue(abs(dsts[1, 0] + 0.1666) < 1e-2, msg)
msg = 'The latitude of the second point is wrong'
self.assertTrue(abs(dsts[1, 1] - 0.0) < 1e-2, msg)
def test_international_date_line(self):
maxdist = IntegrationDistance({
'default': [(3, 30), (4, 40), (5, 100), (6, 200), (7, 300),
(8, 400)]
})
sitecol = SiteCollection([
Site(location=Point(179, 80),
vs30=1.2,
vs30measured=True,
z1pt0=3.4,
z2pt5=5.6,
backarc=True),
Site(location=Point(-179, 80),
vs30=55.4,
vs30measured=False,
z1pt0=66.7,
z2pt5=88.9,
backarc=False)
])
srcfilter = SourceFilter(sitecol, maxdist)
bb1, bb2 = srcfilter.get_bounding_boxes(mag=4.5)
# bounding boxes in the form min_lon, min_lat, max_lon, max_lat
aae(bb1, (173.8210225, 79.10068, 184.1789775, 80.89932))
aae(bb2, (-184.1789775, 79.10068, -173.8210225, 80.89932))
def test_get_bounding_boxes(self):
maxdist = IntegrationDistance({
'default': [(3, 30), (4, 40), (5, 100), (6, 200), (7, 300),
(8, 400)]
})
sitecol = SiteCollection([
Site(location=Point(10, 20, 30),
vs30=1.2,
vs30measured=True,
z1pt0=3.4,
z2pt5=5.6,
backarc=True),
Site(location=Point(-1.2, -3.4, -5.6),
vs30=55.4,
vs30measured=False,
z1pt0=66.7,
z2pt5=88.9,
backarc=False)
])
srcfilter = SourceFilter(sitecol, maxdist)
bb1, bb2 = srcfilter.get_bounding_boxes(mag=4.5)
# bounding boxes in the form min_lon, min_lat, max_lon, max_lat
aae(bb1, (9.0429636, 19.10068, 10.9570364, 20.89932))
aae(bb2, (-2.1009057, -4.29932, -0.2990943, -2.50068))
def point_at_distance(self,
model,
distance,
vs30,
line_azimuth=90.,
origin_point=(0.5, 0.),
vs30measured=True,
z1pt0=None,
z2pt5=None,
backarc=False):
"""
Generates a point at a given epicentral distance
"""
azimuth, origin_point, z1pt0, z2pt5 = _setup_site_peripherals(
line_azimuth, origin_point, vs30, z1pt0, z2pt5, model.strike,
model.surface)
return SiteCollection([
Site(model.hypocentre.point_at(distance, 0., line_azimuth),
vs30,
vs30measured,
z1pt0,
z2pt5,
backarc=backarc)
])
def test(self):
sitecol = SiteCollection([Site(Point(30.0, 30.0), 760., 1.0, 1.0)])
mfd = TruncatedGRMFD(4.5, 8.0, 0.1, 4.0, 1.0)
sources = [
PointSource('001', 'Point1', 'Active Shallow Crust', mfd, 1.0,
WC1994(), 1.0, PoissonTOM(50.0), 0.0, 30.0,
Point(30.0, 30.5),
PMF([(1.0, NodalPlane(0.0, 90.0, 0.0))]),
PMF([(1.0, 10.0)]))
]
imtls = {'PGA': [0.01, 0.1, 0.2, 0.5, 0.8]}
hc1 = calc_hazard_curves(
sources, sitecol, imtls,
{'Active Shallow Crust': AkkarBommer2010()})['PGA']
hc2 = calc_hazard_curves(
sources, sitecol, imtls,
{'Active Shallow Crust': SadighEtAl1997()})['PGA']
hc = .6 * hc1 + .4 * hc2
ag = AvgGMPE(b1=dict(AkkarBommer2010={'weight': .6}),
b2=dict(SadighEtAl1997={'weight': .4}))
hcm = calc_hazard_curves(sources, sitecol, imtls,
{'Active Shallow Crust': ag})['PGA']
# the AvgGMPE is not producing real means!!
numpy.testing.assert_almost_equal(hc, hcm, decimal=3)
def setUp(self):
self.truncation_level = 3.4
self.imts = {imt.PGA(): [1, 2, 3], imt.PGD(): [2, 4]}
self.time_span = 49.2
rup11 = self.FakeRupture(0.23, const.TRT.ACTIVE_SHALLOW_CRUST)
rup12 = self.FakeRupture(0.15, const.TRT.ACTIVE_SHALLOW_CRUST)
rup21 = self.FakeRupture(0.04, const.TRT.VOLCANIC)
self.source1 = self.FakeSource(1, [rup11, rup12],
time_span=self.time_span)
self.source2 = self.FakeSource(2, [rup21], time_span=self.time_span)
self.sources = iter([self.source1, self.source2])
site1 = Site(Point(10, 20), 1, True, 2, 3)
site2 = Site(Point(20, 30), 2, False, 4, 5)
self.sites = SiteCollection([site1, site2])
gsim1 = self.FakeGSIM(self.truncation_level, self.imts, poes={
(site1.location.latitude, rup11, imt.PGA()): [0.1, 0.05, 0.03],
(site2.location.latitude, rup11, imt.PGA()): [0.11, 0.051, 0.034],
(site1.location.latitude, rup12, imt.PGA()): [0.12, 0.052, 0.035],
(site2.location.latitude, rup12, imt.PGA()): [0.13, 0.053, 0.036],
(site1.location.latitude, rup11, imt.PGD()): [0.4, 0.33],
(site2.location.latitude, rup11, imt.PGD()): [0.39, 0.331],
(site1.location.latitude, rup12, imt.PGD()): [0.38, 0.332],
(site2.location.latitude, rup12, imt.PGD()): [0.37, 0.333],
})
gsim2 = self.FakeGSIM(self.truncation_level, self.imts, poes={
(site1.location.latitude, rup21, imt.PGA()): [0.5, 0.3, 0.2],
(site2.location.latitude, rup21, imt.PGA()): [0.4, 0.2, 0.1],
(site1.location.latitude, rup21, imt.PGD()): [0.24, 0.08],
(site2.location.latitude, rup21, imt.PGD()): [0.14, 0.09],
})
self.gsims = {const.TRT.ACTIVE_SHALLOW_CRUST: gsim1,
const.TRT.VOLCANIC: gsim2}
def test_correlation_with_total_stddev(self):
mean1 = 10
mean2 = 14
inter = 1e-300
intra1 = 0.2
intra2 = 1.6
p1 = Point(0, 0)
p2 = Point(0, 0.3)
sites = [
Site(p1, mean1, False, inter, intra1),
Site(p2, mean2, False, inter, intra2)
]
self.sites = SiteCollection(sites)
numpy.random.seed(41)
cormo = JB2009CorrelationModel(vs30_clustering=False)
gsim = FakeGSIMTotalStdDev(self)
with self.assertRaises(CorrelationButNoInterIntraStdDevs):
ground_motion_fields(self.rupture,
self.sites, [self.imt1],
gsim,
truncation_level=None,
realizations=6000,
correlation_model=cormo)
def test_get_bounding_boxes(self):
maxdist = IntegrationDistance({
'default': [(3, 30), (4, 40), (5, 100), (6, 200), (7, 300),
(8, 400)]
})
sitecol = SiteCollection([
Site(location=Point(10, 20, 30),
vs30=1.2,
vs30measured=True,
z1pt0=3.4,
z2pt5=5.6,
backarc=True),
Site(location=Point(-1.2, -3.4, -5.6),
vs30=55.4,
vs30measured=False,
z1pt0=66.7,
z2pt5=88.9,
backarc=False)
])
srcfilter = SourceFilter(sitecol, maxdist)
bb1, bb2 = srcfilter.get_bounding_boxes(mag=4)
# bounding boxes in the form min_lon, min_lat, max_lon, max_lat
aae(bb1, (9.6171855, 19.640272, 10.3828145, 20.359728))
aae(bb2, (-1.5603623, -3.759728, -0.8396377, -3.040272))
def setUpClass(cls):
lons = numpy.array([-180, -178, 179, 180, 180], numpy.float32)
lats = numpy.array([-27, -28, -26, -30, -28], numpy.float32)
cls.sites = SiteCollection.from_points(lons, lats)
def test_filter_all_in(self):
col = SiteCollection(self.SITES)
filtered = col.filter(numpy.ones(len(self.SITES), bool))
self.assertIs(filtered, col)
def test_filter_all_out(self):
col = SiteCollection(self.SITES)
filtered = col.filter(numpy.zeros(len(self.SITES), bool))
self.assertIs(filtered, None)
def test_non_parametric_source(self):
# non-parametric source equivalent to case 2 simple fault source
data = test_data.SET1_CASE2_SOURCE_DATA
ruptures = []
for i in range(data['num_rups_dip']):
for j in range(data['num_rups_strike']):
lons = data['lons']
lats = data['lats'][j]
depths = data['depths'][i]
mesh = RectangularMesh(lons, lats, depths)
surf = SimpleFaultSurface(mesh)
hypo = Point(data['hypo_lons'][i, j], data['hypo_lats'][i, j],
data['hypo_depths'][i, j])
rup = BaseRupture(data['mag'], data['rake'],
data['tectonic_region_type'], hypo, surf)
ruptures.append((rup, data['pmf']))
npss = NonParametricSeismicSource('id', 'name',
data['tectonic_region_type'],
ruptures)
sites = SiteCollection([
test_data.SET1_CASE1TO9_SITE1, test_data.SET1_CASE1TO9_SITE2,
test_data.SET1_CASE1TO9_SITE3, test_data.SET1_CASE1TO9_SITE4,
test_data.SET1_CASE1TO9_SITE5, test_data.SET1_CASE1TO9_SITE6,
test_data.SET1_CASE1TO9_SITE7
])
gsims = {const.TRT.ACTIVE_SHALLOW_CRUST: SadighEtAl1997()}
truncation_level = 0
imts = {str(test_data.IMT): test_data.SET1_CASE2_IMLS}
curves = calc_hazard_curves([npss], sites, imts, gsims,
truncation_level)
s1hc, s2hc, s3hc, s4hc, s5hc, s6hc, s7hc = curves[str(test_data.IMT)]
assert_hazard_curve_is(self,
s1hc,
test_data.SET1_CASE2_SITE1_POES,
atol=3e-3,
rtol=1e-5)
assert_hazard_curve_is(self,
s2hc,
test_data.SET1_CASE2_SITE2_POES,
atol=2e-5,
rtol=1e-5)
assert_hazard_curve_is(self,
s3hc,
test_data.SET1_CASE2_SITE3_POES,
atol=2e-5,
rtol=1e-5)
assert_hazard_curve_is(self,
s4hc,
test_data.SET1_CASE2_SITE4_POES,
atol=1e-3,
rtol=1e-5)
assert_hazard_curve_is(self,
s5hc,
test_data.SET1_CASE2_SITE5_POES,
atol=1e-3,
rtol=1e-5)
assert_hazard_curve_is(self,
s6hc,
test_data.SET1_CASE2_SITE6_POES,
atol=1e-3,
rtol=1e-5)
assert_hazard_curve_is(self,
s7hc,
test_data.SET1_CASE2_SITE7_POES,
atol=2e-5,
rtol=1e-5)
def test_case_5(self):
# only mfd differs from case 2
sources = [
SimpleFaultSource(
source_id='fault1',
name='fault1',
tectonic_region_type=const.TRT.ACTIVE_SHALLOW_CRUST,
mfd=test_data.SET1_CASE5_MFD,
rupture_mesh_spacing=1.0,
magnitude_scaling_relationship=PeerMSR(),
rupture_aspect_ratio=test_data.SET1_RUPTURE_ASPECT_RATIO,
temporal_occurrence_model=PoissonTOM(1.),
upper_seismogenic_depth=test_data.
SET1_CASE1TO9_UPPER_SEISMOGENIC_DEPTH,
lower_seismogenic_depth=test_data.
SET1_CASE1TO9_LOWER_SEISMOGENIC_DEPTH,
fault_trace=test_data.SET1_CASE1TO9_FAULT_TRACE,
dip=test_data.SET1_CASE1TO9_DIP,
rake=test_data.SET1_CASE1TO9_RAKE)
]
sites = SiteCollection([
test_data.SET1_CASE1TO9_SITE1, test_data.SET1_CASE1TO9_SITE2,
test_data.SET1_CASE1TO9_SITE3, test_data.SET1_CASE1TO9_SITE4,
test_data.SET1_CASE1TO9_SITE5, test_data.SET1_CASE1TO9_SITE6,
test_data.SET1_CASE1TO9_SITE7
])
gsims = {const.TRT.ACTIVE_SHALLOW_CRUST: SadighEtAl1997()}
truncation_level = 0
imts = {str(test_data.IMT): test_data.SET1_CASE5_IMLS}
curves = calc_hazard_curves(sources, sites, imts, gsims,
truncation_level)
s1hc, s2hc, s3hc, s4hc, s5hc, s6hc, s7hc = curves[str(test_data.IMT)]
assert_hazard_curve_is(self,
s1hc,
test_data.SET1_CASE5_SITE1_POES,
atol=1e-3,
rtol=1e-5)
assert_hazard_curve_is(self,
s2hc,
test_data.SET1_CASE5_SITE2_POES,
atol=1e-3,
rtol=1e-5)
assert_hazard_curve_is(self,
s3hc,
test_data.SET1_CASE5_SITE3_POES,
atol=1e-3,
rtol=1e-5)
assert_hazard_curve_is(self,
s4hc,
test_data.SET1_CASE5_SITE4_POES,
atol=1e-3,
rtol=1e-5)
assert_hazard_curve_is(self,
s5hc,
test_data.SET1_CASE5_SITE5_POES,
atol=1e-3,
rtol=1e-5)
assert_hazard_curve_is(self,
s6hc,
test_data.SET1_CASE5_SITE6_POES,
atol=1e-3,
rtol=1e-5)
assert_hazard_curve_is(self,
s7hc,
test_data.SET1_CASE5_SITE7_POES,
atol=1e-3,
rtol=1e-5)
def setUpClass(cls):
lons = numpy.array([-180, -178, 179, 180, 180], numpy.float32)
lats = numpy.array([-27, -28, -26, -30, -28], numpy.float32)
cls.sites = SiteCollection.from_points(lons, lats)
class GSIMRupture(object):
"""
Defines a rupture plane consistent with the properties specified for
the trellis plotting. Also contains methods for configuring the site
locations
"""
def __init__(self, magnitude, dip, aspect,
tectonic_region='Active Shallow Crust', rake=0., ztor=0.,
strike=0., msr=WC1994(), initial_point=DEFAULT_POINT,
hypocentre_location=None):
"""
Instantiate the rupture - requires a minimum of a magnitude, dip
and aspect ratio
"""
self.magnitude = magnitude
self.dip = dip
self.aspect = aspect
self.rake = rake
self.strike = strike
self.location = initial_point
self.ztor = ztor
self.trt = tectonic_region
self.hypo_loc = hypocentre_location
# If the top of rupture depth in the initial
if fabs(self.location.depth - self.ztor) > 1E-9:
self.location.depth = ztor
self.msr = msr
self.area = self.msr.get_median_area(self.magnitude, self.rake)
self.surface = create_planar_surface(self.location,
self.strike,
self.dip,
self.area,
self.aspect)
self.hypocentre = get_hypocentre_on_planar_surface(self.surface,
self.hypo_loc)
self.rupture = self.get_rupture()
self.target_sites_config = None
self.target_sites = None
def get_rupture(self):
"""
Returns the rupture as an instance of the
openquake.hazardlib.source.rupture.Rupture class
"""
return Rupture(self.magnitude,
self.rake,
self.trt,
self.hypocentre,
self.surface,
PointSource)
def get_gsim_contexts(self):
"""
Returns a comprehensive set of GMPE contecxt objects
"""
assert isinstance(self.rupture, Rupture)
assert isinstance(self.target_sites, SiteCollection)
# Distances
dctx = DistancesContext()
# Rupture distance
setattr(dctx, 'rrup',
self.rupture.surface.get_min_distance(self.target_sites.mesh))
# Rx
setattr(dctx, 'rx',
self.rupture.surface.get_rx_distance(self.target_sites.mesh))
# Rjb
setattr(dctx, 'rjb', self.rupture.surface.get_joyner_boore_distance(
self.target_sites.mesh))
# Rhypo
setattr(dctx,
'rhypo',
self.rupture.hypocenter.distance_to_mesh(
self.target_sites.mesh))
# Repi
setattr(dctx, 'repi',
self.rupture.hypocenter.distance_to_mesh(
self.target_sites.mesh,
with_depths=False))
# Ry0
setattr(dctx, 'ry0',
self.rupture.surface.get_ry0_distance(self.target_sites.mesh))
# Rcdpp - ignored at present
setattr(dctx, 'rcdpp', None)
# Azimuth
setattr(dctx, 'azimuth', get_distances(self.rupture,
self.target_sites.mesh,
'azimuth'))
setattr(dctx, 'hanging_wall', None)
# Rvolc
setattr(dctx, "rvolc", np.zeros_like(self.target_sites.mesh.lons))
# Sites
sctx = SitesContext(slots=self.target_sites.array.dtype.names)
for key in sctx._slots_:
setattr(sctx, key, self.target_sites.array[key])
# Rupture
rctx = RuptureContext()
setattr(rctx, 'mag', self.magnitude)
setattr(rctx, 'strike', self.strike)
setattr(rctx, 'dip', self.dip)
setattr(rctx, 'rake', self.rake)
setattr(rctx, 'ztor', self.ztor)
setattr(rctx, 'hypo_depth', self.rupture.hypocenter.depth)
setattr(rctx, 'hypo_lat', self.rupture.hypocenter.latitude)
setattr(rctx, 'hypo_lon', self.rupture.hypocenter.longitude)
setattr(rctx, 'hypo_loc', self.hypo_loc)
setattr(rctx, 'width', self.rupture.surface.get_width())
return sctx, rctx, dctx
def get_target_sites_mesh(self, maximum_distance, spacing, vs30,
vs30measured=True, z1pt0=None, z2pt5=None,
backarc=False):
"""
Renders a two dimensional mesh of points over the rupture surface
"""
# Get bounding box of dilated rupture
lowx, highx, lowy, highy = self._get_limits_maximum_rjb(
maximum_distance)
# Create bounding box lines and then resample at spacing
ewline = Line([Point(lowx, highy, 0.), Point(highx, highy, 0.)])
nsline = Line([Point(lowx, highy, 0.), Point(lowx, lowy, 0.)])
ewline = ewline.resample(spacing)
nsline = nsline.resample(spacing)
xvals = np.array([pnt.longitude for pnt in ewline.points])
yvals = np.array([pnt.latitude for pnt in nsline.points])
gridx, gridy = np.meshgrid(xvals, yvals)
numx, numy = np.shape(gridx)
npts = numx * numy
gridx = (np.reshape(gridx, npts, 1)).flatten()
gridy = (np.reshape(gridy, npts, 1)).flatten()
site_list = []
if not z1pt0:
# z1pt0 = vs30_to_z1pt0_as08(vs30)
z1pt0 = vs30_to_z1pt0_cy14(vs30)
if not z2pt5:
# z2pt5 = z1pt0_to_z2pt5(z1pt0)
z2pt5 = vs30_to_z2pt5_cb14(vs30)
for iloc in range(0, npts):
site_list.append(Site(Point(gridx[iloc], gridy[iloc], 0.),
vs30,
z1pt0,
z2pt5,
vs30measured=vs30measured,
backarc=backarc))
self.target_sites = SiteCollection(site_list)
self.target_sites_config = {
"TYPE": "Mesh",
"RMAX": maximum_distance,
"SPACING": spacing,
"VS30": vs30,
"VS30MEASURED": vs30measured,
"Z1.0": z1pt0,
"Z2.5": z2pt5,
"BACKARC": backarc}
return self.target_sites
def get_target_sites_line(self, maximum_distance, spacing, vs30,
line_azimuth=90., origin_point=(0.5, 0.5),
as_log=False, vs30measured=True, z1pt0=None,
z2pt5=None, backarc=False):
"""
Defines the target sites along a line with respect to the rupture
:param maximum_distance:
Maximum distance to be considered [km]
:param spacing:
Sampling distance for the reference line [km]
:param vs30:
Time averaged shear wave velocity within the uppermost 30m [m/s]
:param line_azimuth:
Azimuth of the reference line [degrees]
:param origin_point:
Coordinates of the origin point of the reference line
:param bool as_log:
When True scales the distances logarithmically
:param bool vs30measured:
A boolean defining the method used to determine the vs30 value
:param z1pt0:
Depth to the 1km/s interface [km]
:param z2pt5:
Depth to the 2.5km/s interface [km]
:param bool backarc:
When True the sites are considered in the backarc region
"""
azimuth, origin_location, z1pt0, z2pt5 = \
self._define_origin_target_site(vs30, line_azimuth, origin_point,
vs30measured, z1pt0, z2pt5,
backarc)
spacings = self._define_line_spacing(maximum_distance,
spacing,
as_log)
target_sites = \
self._append_target_sites(spacings, azimuth, origin_location,
vs30, line_azimuth, origin_point,
as_log, vs30measured, z1pt0, z2pt5,
backarc)
# let's be picky and replace inferred values of
# self.target_sites_config with the values provided here:
self.target_sites_config.update({"RMAX": maximum_distance,
"SPACING": spacing})
return target_sites
def _define_line_spacing(self, maximum_distance, spacing, as_log=False):
"""
The user may wish to define the line spacing in either log or
linear space
"""
nvals = int(maximum_distance / spacing) + 1
if as_log:
spacings = np.logspace(-3., np.log10(maximum_distance), nvals)
spacings[0] = 0.0
else:
spacings = np.linspace(0.0, maximum_distance, nvals)
if spacings[-1] < (maximum_distance - 1.0E-7):
spacings = np.hstack([spacings, maximum_distance])
return spacings
def get_target_sites_line_from_given_distances(self, distances, vs30,
line_azimuth=90., origin_point=(0.5, 0.5), as_log=False,
vs30measured=True, z1pt0=None, z2pt5=None, backarc=False):
"""
Defines the target sites along a line with respect to the rupture from
a given numeric array of distances
"""
azimuth, origin_location, z1pt0, z2pt5 = \
self._define_origin_target_site(vs30, line_azimuth, origin_point,
vs30measured, z1pt0, z2pt5,
backarc)
distances = self._convert_distances(distances, as_log)
return self._append_target_sites(distances, azimuth, origin_location,
vs30, line_azimuth, origin_point,
as_log, vs30measured, z1pt0, z2pt5,
backarc)
@staticmethod
def _convert_distances(distances, as_log=False):
'''assures distances is a numpy numeric array, sorts it
and converts its value to a logaritmic scale preserving the array
bounds (min and max)'''
dist = np.asarray(distances)
dist.sort()
if as_log:
oldmin, oldmax = dist[0], dist[-1]
dist = np.log1p(dist) # avoid -inf @ zero in case
newmin, newmax = dist[0], dist[-1]
# re-map the space to be logarithmic between oldmin and oldmax:
dist = oldmin + (oldmax-oldmin)*(dist - newmin)/(newmax - newmin)
return dist
def _define_origin_target_site(self, vs30, line_azimuth=90.,
origin_point=(0.5, 0.5), vs30measured=True,
z1pt0=None, z2pt5=None, backarc=False):
"""
Defines the target site from an origin point
"""
azimuth, origin_location, z1pt0, z2pt5 = _setup_site_peripherals(
line_azimuth,
origin_point,
vs30,
z1pt0,
z2pt5,
self.strike,
self.surface)
self.target_sites = [Site(origin_location,
vs30,
z1pt0,
z2pt5,
vs30measured=vs30measured,
backarc=backarc)]
return azimuth, origin_location, z1pt0, z2pt5
def _append_target_sites(self, distances, azimuth, origin_location, vs30,
line_azimuth=90., origin_point=(0.5, 0.5),
as_log=False, vs30measured=True, z1pt0=None,
z2pt5=None, backarc=False):
"""
Appends the target sites along a line with respect to the rupture,
given an already set origin target site
"""
for offset in distances:
target_loc = origin_location.point_at(offset, 0., azimuth)
self.target_sites.append(Site(target_loc,
vs30,
z1pt0,
z2pt5,
vs30measured=vs30measured,
backarc=backarc))
self.target_sites_config = {
"TYPE": "Line",
"RMAX": distances[-1],
"SPACING": np.nan if len(distances) < 2 else
distances[1] - distances[0], # FIXME does it make sense?
"AZIMUTH": line_azimuth,
"ORIGIN": origin_point,
"AS_LOG": as_log,
"VS30": vs30,
"VS30MEASURED": vs30measured,
"Z1.0": z1pt0,
"Z2.5": z2pt5,
"BACKARC": backarc}
self.target_sites = SiteCollection(self.target_sites)
return self.target_sites
def get_target_sites_point(
self, distance, distance_type, vs30,
line_azimuth=90, origin_point=(0.5, 0.5), vs30measured=True,
z1pt0=None, z2pt5=None, backarc=False):
"""
Returns a single target site at a fixed distance from the source,
with distance defined according to a specific typology
:param float distance:
Distance (km) from the point to the source
:param str distance_type:
Type of distance {'rrup', 'rjb', 'repi', 'rhyp'}
:param float vs30:
Vs30 (m / s)
:param float line_azimuth:
Aziumth of the source-to-site line
:param tuple origin point:
Location (along strike, down dip) of the origin of the source-site
line within the rupture
:param bool vs30measured:
Is vs30 measured (True) or inferred (False)
:param float z1pt0:
Depth to 1 km/s interface
:param floar z2pt5:
Depth to 2.5 km/s interface
"""
if not distance_type in list(POINT_AT_MAPPING.keys()):
raise ValueError("Distance type must be one of: Rupture ('rrup'), "
"Joyner-Boore ('rjb'), Epicentral ('repi') or "
"Hypocentral ('rhyp')")
#input_origin_point = deepcopy(origin_point)
azimuth, origin_location, z1pt0, z2pt5 = _setup_site_peripherals(
line_azimuth,
origin_point,
vs30,
z1pt0,
z2pt5,
self.strike,
self.surface)
self.target_sites_config = {
"TYPE": "Point",
"R": distance,
"RTYPE": distance_type,
"AZIMUTH": line_azimuth,
"ORIGIN": origin_point,
"VS30": vs30,
"VS30MEASURED": vs30measured,
"Z1.0": z1pt0,
"Z2.5": z2pt5,
"BACKARC": backarc}
self.target_sites = POINT_AT_MAPPING[distance_type].point_at_distance(
self,
distance,
vs30,
line_azimuth,
origin_point,
vs30measured,
z1pt0,
z2pt5,
backarc=backarc)
def _get_limits_maximum_rjb(self, maximum_distance):
"""
Returns the bounding box of a polyon representing the locations of
maximum distance from the rupture
"""
top_left = deepcopy(self.surface.top_left)
top_left.depth = 0.
top_right = deepcopy(self.surface.top_right)
top_right.depth = 0.
bottom_left = deepcopy(self.surface.bottom_left)
bottom_left.depth = 0.
bottom_right = deepcopy(self.surface.bottom_right)
bottom_right.depth = 0.
surface_projection = Polygon([top_left,
top_right,
bottom_right,
bottom_left])
dilated_projection = surface_projection.dilate(maximum_distance)
return (np.min(dilated_projection.lons),
np.max(dilated_projection.lons),
np.min(dilated_projection.lats),
np.max(dilated_projection.lats))
def filter_hanging_wall(self, filter_type=None):
"""
Opt to consider only hanging wall or footwall sites
"""
if not filter_type:
# Considers both footwall and hanging wall
return self.target_sites
elif not filter_type in ('HW', 'FW'):
raise ValueError('Hanging wall filter must be either "HW" or "FW"')
else:
pass
# Gets the Rx distance
r_x = self.surface.get_rx_distance(self.target_sites.mesh)
selected_sites = []
if filter_type == "HW":
# Only hanging wall
idx = np.where(r_x >= 0.)[0]
else:
# Only footwall
idx = np.where(r_x < 0.)[0]
for val in idx:
selected_sites.append(self.target_sites.sites[val])
self.target_sites = SiteCollection(selected_sites)
return self.target_sites
def _site_collection_to_mesh(self):
"""
Returns a collection of sites as an instance of the :class:
`openquake.hazardlib.geo.Mesh`
"""
if isinstance(self.target_sites, SiteCollection):
locations = np.array([len(self.target_sites.sites), 3],
dtype=float)
for iloc, site in enumerate(self.target_sites.sites):
locations[iloc, 0] = site.location.longitude
locations[iloc, 1] = site.location.latitude
locations[iloc, 2] = site.location.depth
return Mesh(locations[:, 0], locations[:, 1], locations[:, 2])
else:
raise ValueError('Target sites must be an instance of '
'openquake.hazardlib.site.SiteCollection')
def plot_distance_comparisons(self, distance1, distance2, logaxis=False,
figure_size=(7, 5), filename=None, filetype="png", dpi=300):
"""
Creates a plot comparing different distance metrics for the
specific rupture and target site combination
"""
xdist = self._calculate_distance(distance1)
ydist = self._calculate_distance(distance2)
plt.figure(figsize=figure_size)
if logaxis:
plt.loglog(xdist, ydist, color='b', marker='o', linestyle='None')
else:
plt.plot(xdist, ydist, color='b', marker='o', linestyle='None')
plt.xlabel("%s (km)" % distance1, size='medium')
plt.ylabel("%s (km)" % distance2, size='medium')
plt.title('Rupture: M=%6.1f, Dip=%3.0f, Ztor=%4.1f, Aspect=%5.2f'
% (self.magnitude, self.dip, self.ztor, self.aspect))
_save_image(filename, filetype, dpi)
plt.show()
def _calculate_distance(self, distance_type):
"""
Calculates the rupture to target site distances for the present
rupture and target site configuration
"""
if distance_type == 'rrup':
return self.surface.get_min_distance(self.target_sites.mesh)
elif distance_type == 'rjb':
return self.surface.get_joyner_boore_distance(
self.target_sites.mesh)
elif distance_type == 'rx':
return self.surface.get_rx_distance(self.target_sites.mesh)
elif distance_type == 'rhypo':
return self.hypocentre.distance_to_mesh(self.target_sites.mesh)
elif distance_type == 'repi':
return self.hypocentre.distance_to_mesh(self.target_sites.mesh,
with_depths=False)
else:
raise ValueError('Unsupported Distance Measure: %s'
% distance_type)
def plot_model_configuration(self, marker_style="o", figure_size=(7, 5),
filename=None, filetype="png", dpi=300):
"""
Produces a 3D plot of the current model configuration
"""
fig = plt.figure(figsize=figure_size)
ax = fig.add_subplot(111, projection='3d')
# Wireframe rupture surface mesh
lons = []
lats = []
depths = []
for pnt in [self.surface.top_left, self.surface.top_right,
self.surface.bottom_right, self.surface.bottom_left,
self.surface.top_left]:
lons.append(pnt.longitude)
lats.append(pnt.latitude)
depths.append(-pnt.depth)
ax.plot(lons, lats, depths, "k-", lw=2)
# Scatter the target sites
ax.scatter(self.target_sites.mesh.lons,
self.target_sites.mesh.lats,
np.ones_like(self.target_sites.mesh.lons),
c='r',
marker=marker_style)
ax.set_xlabel('Longitude')
ax.set_ylabel('Latitude')
ax.set_zlabel('Depth (km)')
ax.set_zlim(np.floor(min(depths)), 0.0)
_save_image(filename, filetype, dpi)
plt.show()
def test_unknown_distance_error(self):
self.gsim_class.REQUIRES_DISTANCES.add('jump height')
err = "Unknown distance measure 'jump height'"
sites = SiteCollection([self.site1, self.site2])
self._assert_value_error(self.make_contexts, err,
site_collection=sites, rupture=self.rupture)
def test_filter_all_in(self):
col = SiteCollection(self.SITES)
filtered = col.filter(numpy.ones(len(self.SITES), bool))
self.assertIs(filtered, col)
def test_filter_all_out(self):
col = SiteCollection(self.SITES)
filtered = col.filter(numpy.zeros(len(self.SITES), bool))
self.assertIs(filtered, None)
class GSIMRupture(object):
"""
Creates a rupture plane consistent with the properties specified for
the trellis plots
"""
def __init__(self, magnitude, dip, aspect,
tectonic_region='Active Shallow Crust' , rake=0., ztor=0.,
strike=0., msr=WC1994(), initial_point=DEFAULT_POINT,
hypocentre_location=None):
"""
Instantiate the rupture
"""
self.magnitude = magnitude
self.dip = dip
self.aspect = aspect
self.rake = rake
self.strike = strike
self.location = initial_point
self.ztor = ztor
self.trt = tectonic_region
# If the top of rupture depth in the initial
if fabs(self.location.depth - self.ztor) > 1E-9:
self.location.depth = ztor
self.area = msr.get_median_area(self.magnitude, self.rake)
self.surface = create_planar_surface(self.location,
self.strike,
self.dip,
self.area,
self.aspect)
self.hypocentre = get_hypocentre_on_planar_surface(self.surface,
hypocentre_location)
self.rupture = self.get_rupture()
self.target_sites = None
def get_rupture(self):
"""
Returns the rupture as an instance of the
openquake.hazardlib.source.rupture.Rupture class
"""
return Rupture(self.magnitude,
self.rake,
self.trt,
self.hypocentre,
self.surface,
PointSource)
def get_gsim_contexts(self):
"""
Returns a comprehensive set of GMPE contecxt objects
"""
assert isinstance(self.rupture, Rupture)
assert isinstance(self.target_sites, SiteCollection)
# Distances
dctx = DistancesContext()
# Rupture distance
setattr(dctx,
'rrup',
self.rupture.surface.get_min_distance(self.target_sites.mesh))
# Rx
setattr(dctx,
'rx',
self.rupture.surface.get_rx_distance(self.target_sites.mesh))
# Rjb
setattr(dctx,
'rjb',
self.rupture.surface.get_joyner_boore_distance(
self.target_sites.mesh))
# Rhypo
setattr(dctx,
'rhypo',
self.rupture.hypocenter.distance_to_mesh(
self.target_sites.mesh))
# Repi
setattr(dctx, 'repi',
self.rupture.hypocenter.distance_to_mesh(
self.target_sites.mesh,
with_depths=False))
# Sites
sctx = SitesContext()
key_list = ['_vs30', '_vs30measured', '_z1pt0', '_z2pt5']
for key in key_list:
setattr(sctx, key[1:], getattr(self.target_sites, key))
# Rupture
rctx = RuptureContext()
setattr(rctx, 'mag', self.magnitude)
setattr(rctx, 'dip', self.dip)
setattr(rctx, 'rake', self.rake)
setattr(rctx, 'ztor', self.ztor)
setattr(rctx, 'hypo_depth', self.rupture.hypocenter.depth)
setattr(rctx, 'width', self.rupture.surface.get_width())
return sctx, rctx, dctx
def get_target_sites_mesh(self, maximum_distance, spacing, vs30,
vs30measured=True, z1pt0=None, z2pt5=None):
"""
Renders a two dimensional mesh of points over the rupture surface
"""
# Get bounding box of dilated rupture
lowx, highx, lowy, highy = self._get_limits_maximum_rjb(
maximum_distance)
# Create bounding box lines and then resample at spacing
ewline = Line([Point(lowx, highy, 0.), Point(highx, highy, 0.)])
nsline = Line([Point(lowx, highy, 0.), Point(lowx, lowy, 0.)])
ewline = ewline.resample(spacing)
nsline = nsline.resample(spacing)
xvals = np.array([pnt.longitude for pnt in ewline.points])
yvals = np.array([pnt.latitude for pnt in nsline.points])
gridx, gridy = np.meshgrid(xvals, yvals)
numx, numy = np.shape(gridx)
npts = numx * numy
gridx = (np.reshape(gridx, npts, 1)).flatten()
gridy = (np.reshape(gridy, npts, 1)).flatten()
site_list = []
if not z1pt0:
z1pt0 = vs30_to_z1pt0_as08(vs30)
if not z2pt5:
z2pt5 = z1pt0_to_z2pt5(z1pt0)
for iloc in range(0, npts):
site_list.append(Site(Point(gridx[iloc], gridy[iloc], 0.),
vs30,
vs30measured,
z1pt0,
z2pt5))
self.target_sites = SiteCollection(site_list)
return self.target_sites
def get_target_sites_line(self, maximum_distance, spacing, vs30,
line_azimuth=90., origin_point=(0.5, 0.5), vs30measured=True,
z1pt0=None, z2pt5=None):
"""
Defines the target sites along a line with respect to the rupture
"""
azimuth, origin_point, z1pt0, z2pt5 = _setup_site_peripherals(
line_azimuth,
origin_point,
vs30,
z1pt0,
z2pt5,
self.strike,
self.surface)
targets = [origin_point]
self.target_sites = []
distance = 0.
cum_dist = distance + spacing
while distance < maximum_distance:
target_loc= origin_point.point_at(cum_dist, 0., azimuth)
# Get Rupture distance
temp_mesh = Mesh(np.array(target_loc.longitude),
np.array(target_loc.latitude),
np.array(target_loc.depth))
distance = self.surface.get_min_distance(temp_mesh)
self.target_sites.append(Site(target_loc,
vs30,
vs30measured,
z1pt0,
z2pt5))
cum_dist += spacing
self.target_sites = SiteCollection(self.target_sites)
return self.target_sites
def get_target_sites_point(self, distance, distance_type, vs30,
line_azimuth=90, origin_point=(0.5, 0.5), vs30measured=True,
z1pt0=None, z2pt5=None):
"""
Returns a single target site at a fixed distance from the source,
with distance defined according to a specific typology
:param float distance:
Distance (km) from the point to the source
:param str distance_type:
Type of distance {'rrup', 'rjb', 'repi', 'rhyp'}
:param float vs30:
Vs30 (m / s)
:param float line_azimuth:
Aziumth of the source-to-site line
:param tuple origin point:
Location (along strike, down dip) of the origin of the source-site
line within the rupture
:param bool vs30measured:
Is vs30 measured (True) or inferred (False)
:param float z1pt0:
Depth to 1 km/s interface
:param floar z2pt5:
Depth to 2.5 km/s interface
"""
if not distance_type in POINT_AT_MAPPING.keys():
raise ValueError("Distance type must be one of: Rupture ('rrup'), "
"Joyner-Boore ('rjb'), Epicentral ('repi') or "
"Hypocentral ('rhyp')")
self.target_sites = POINT_AT_MAPPING[distance_type].point_at_distance(
self,
distance,
vs30,
line_azimuth,
origin_point,
vs30measured,
z1pt0,
z2pt5)
def _get_limits_maximum_rjb(self, maximum_distance):
"""
Returns the bounding box of a polyon representing the locations of
maximum distance from the rupture
"""
top_left = deepcopy(self.surface.top_left)
top_left.depth = 0.
top_right = deepcopy(self.surface.top_right)
top_right.depth = 0.
bottom_left = deepcopy(self.surface.bottom_left)
bottom_left.depth = 0.
bottom_right = deepcopy(self.surface.bottom_right)
bottom_right.depth = 0.
surface_projection = Polygon([top_left,
top_right,
bottom_right,
bottom_left])
dilated_projection = surface_projection.dilate(maximum_distance)
return (np.min(dilated_projection.lons),
np.max(dilated_projection.lons),
np.min(dilated_projection.lats),
np.max(dilated_projection.lats))
def filter_hanging_wall(self, filter_type=None):
"""
Opt to consider only hanging wall or footwall sites
"""
if not filter_type:
# Considers both footwall and hanging wall
return self.target_sites
elif not filter_type in ['HW', 'FW']:
raise ValueError('Hanging wall filter must be either "HW" or "FW"')
else:
pass
# Gets the Rx distance
r_x = self.surface.get_rx_distance(self.target_sites.mesh)
selected_sites = []
if filter_type == "HW":
# Only hanging wall
idx = np.where(r_x >= 0.)[0]
else:
# Only footwall
idx = np.where(r_x < 0.)[0]
for val in idx:
selected_sites.append(self.target_sites.sites[val])
self.target_sites = SiteCollection(selected_sites)
return self.target_sites
def _site_collection_to_mesh(self):
"""
"""
if isinstance(self.target_sites, SiteCollection):
locations = np.array([len(self.target_sites.sites), 3],
dtype=float)
for iloc, site in enumerate(self.target_sites.sites):
locations[i, 0] = site.location.longitude
locations[i, 1] = site.location.latitude
locations[i, 2] = site.location.depth
return Mesh(locations[:, 0], locations[:, 1], locations[:, 2])
else:
raise ValueError('Target sites must be an instance of '
'openquake.hazardlib.site.SiteCollection')
def plot_distance_comparisons(self, distance1, distance2, logaxis=False,
figure_size=(7, 5), filename=None, filetype="png", dpi=300):
"""
Creates a plot comparing different distance metrics for the
specific rupture and target site combination
"""
xdist = self._calculate_distance(distance1)
ydist = self._calculate_distance(distance2)
plt.figure(figsize=figure_size)
if logaxis:
plt.loglog(xdist, ydist, color='b', marker='o', linestyle='None')
else:
plt.plot(xdist, ydist, color='b', marker='o', linestyle='None')
plt.xlabel("%s (km)" % distance1, size='medium')
plt.ylabel("%s (km)" % distance2, size='medium')
plt.title('Rupture: M=%6.1f, Dip=%3.0f, Ztor=%4.1f, Aspect=%5.2f'
% (self.magnitude, self.dip, self.ztor, self.aspect))
_save_image(filename, filetype, dpi)
plt.show()
def _calculate_distance(self, distance_type):
"""
Calculates the rupture to target site distances for the present
rupture and target site configuration
"""
if distance_type == 'rrup':
return self.surface.get_min_distance(self.target_sites.mesh)
elif distance_type == 'rjb':
return self.surface.get_joyner_boore_distance(
self.target_sites.mesh)
elif distance_type == 'rx':
return self.surface.get_rx_distance(self.target_sites.mesh)
elif distance_type == 'rhypo':
return self.hypocentre.distance_to_mesh(self.target_sites.mesh)
elif distance_type == 'repi':
return self.hypocentre.distance_to_mesh(self.target_sites.mesh,
with_depths=False)
else:
raise ValueError('Unsupported Distance Measure: %s'
% distance_type)
def plot_model_configuration(self, marker_style="o", figure_size=(7, 5),
filename=None, filetype="png", dpi=300):
"""
Produces a 3D plot of the current model configuration
"""
fig = plt.figure(figsize=figure_size)
ax = fig.add_subplot(111, projection='3d')
# Wireframe rupture surface mesh
rupture_mesh = self.surface.get_mesh()
ax.plot_wireframe(rupture_mesh.lons,
rupture_mesh.lats,
-rupture_mesh.depths,
rstride=1,
cstride=1)
# Scatter the target sites
ax.scatter(self.target_sites.mesh.lons,
self.target_sites.mesh.lats,
np.ones_like(self.target_sites.mesh.lons),
c='r',
marker=marker_style)
ax.set_xlabel('Longitude')
ax.set_ylabel('Latitude')
ax.set_zlabel('Depth (km)')
_save_image(filename, filetype, dpi)
plt.show()
