def test_vtrans_correct(self): """ Test _vtrans_correct function. Compare to MATLAB reference.""" ureg = UnitRegistry() i_node = 1 tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK) tc_track.equal_timestep() tc_track.data[0]['radius_max_wind'] = ('time', tc._extra_rad_max_wind( tc_track.data[0].central_pressure.values, tc_track.data[0].radius_max_wind.values, ureg)) coast_centr = tc.coastal_centr_idx(CENT_CLB) new_centr = CENT_CLB.coord[coast_centr] r_arr = np.array([286.4938638337190, 290.5930935802884, 295.0271327746536, 299.7811253637995, 296.8484825705515, 274.9892882245964]) close_centr = np.array([400381, 400382, 400383, 400384, 401110, 1019665]) - 1 v_trans_corr = tc._vtrans_correct( tc_track.data[0].lat.values[i_node:i_node+2], tc_track.data[0].lon.values[i_node:i_node+2], tc_track.data[0].radius_max_wind.values[i_node], new_centr[close_centr, :], r_arr) to_kn = (1* ureg.meter / ureg.second).to(ureg.knot).magnitude v_trans = 10.191466256012880 / to_kn v_trans_corr *= v_trans self.assertEqual(v_trans_corr.size, 6) self.assertAlmostEqual(v_trans_corr[0] * to_kn, 2.490082696506720) self.assertAlmostEqual(v_trans_corr[1] * to_kn, 2.418324821762491) self.assertAlmostEqual(v_trans_corr[2] * to_kn, 2.344175399115656) self.assertAlmostEqual(v_trans_corr[3] * to_kn, 2.268434724527058) self.assertAlmostEqual(v_trans_corr[4] * to_kn, 2.416654031976129) self.assertAlmostEqual(v_trans_corr[5] * to_kn, -1.394485527059995)
def test_set_one_pass(self): """Test _hazard_from_track function.""" tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK_SHORT) tc_track.equal_timestep() coastal_centr = tc.coastal_centr_idx(CENT_CLB) tc_haz = TropCyclone._tc_from_track(tc_track.data[0], CENT_CLB, coastal_centr) self.assertEqual(tc_haz.tag.haz_type, 'TC') self.assertEqual(tc_haz.tag.description, '') self.assertEqual(tc_haz.tag.file_name, 'IBTrACS: 1951239N12334') self.assertEqual(tc_haz.units, 'm/s') self.assertEqual(tc_haz.centroids.size, 1656093) self.assertEqual(tc_haz.event_id.size, 1) self.assertEqual(tc_haz.date.size, 1) self.assertEqual(dt.datetime.fromordinal(tc_haz.date[0]).year, 1951) self.assertEqual(dt.datetime.fromordinal(tc_haz.date[0]).month, 8) self.assertEqual(dt.datetime.fromordinal(tc_haz.date[0]).day, 27) self.assertEqual(tc_haz.event_id[0], 1) self.assertEqual(tc_haz.event_name, ['1951239N12334']) self.assertTrue(np.array_equal(tc_haz.frequency, np.array([1]))) self.assertTrue(isinstance(tc_haz.intensity, sparse.csr.csr_matrix)) self.assertTrue(isinstance(tc_haz.fraction, sparse.csr.csr_matrix)) self.assertEqual(tc_haz.intensity.shape, (1, 1656093)) self.assertEqual(tc_haz.fraction.shape, (1, 1656093)) self.assertAlmostEqual(tc_haz.intensity[0, 1630393], 18.511077471450232, 6) self.assertEqual(tc_haz.intensity[0, 1630394], 0) self.assertEqual(tc_haz.fraction[0, 1630393], 1) self.assertEqual(tc_haz.fraction[0, 1630394], 0) self.assertEqual(tc_haz.fraction.nonzero()[0].size, 7) self.assertEqual(tc_haz.intensity.nonzero()[0].size, 7)
def test_set_one_file_pass(self): """ Test set function set_from_tracks with one input.""" pool = Pool() tc_track = TCTracks(pool) tc_track.read_processed_ibtracs_csv(TEST_TRACK) tc_track.calc_random_walk() tc_track.equal_timestep() tc_haz = TropCyclone(pool) tc_haz.set_from_tracks(tc_track, CENTR_TEST_BRB) tc_haz.check() pool.close() pool.join() self.assertEqual(tc_haz.tag.haz_type, 'TC') self.assertEqual(tc_haz.tag.description, '') self.assertEqual(tc_haz.units, 'm/s') self.assertEqual(tc_haz.centroids.size, 296) self.assertEqual(tc_haz.event_id.size, 10) self.assertTrue(isinstance(tc_haz.intensity, sparse.csr.csr_matrix)) self.assertTrue(isinstance(tc_haz.fraction, sparse.csr.csr_matrix)) self.assertEqual(tc_haz.intensity.shape, (10, 296)) self.assertEqual(tc_haz.fraction.shape, (10, 296))
def test_vang_sym(self): """ Test _vang_sym function. Compare to MATLAB reference. """ ureg = UnitRegistry() i_node = 1 tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK) tc_track.equal_timestep() tc_track.data[0]['radius_max_wind'] = ( 'time', tc._extra_rad_max_wind(tc_track.data[0].central_pressure.values, tc_track.data[0].radius_max_wind.values, ureg)) r_arr = np.array([ 286.4938638337190, 290.5930935802884, 295.0271327746536, 299.7811253637995, 296.8484825705515, 274.9892882245964 ]) v_trans = 5.2429431910897559 v_ang = tc._vang_sym( tc_track.data[0].environmental_pressure.values[i_node], tc_track.data[0].central_pressure.values[i_node - 1:i_node + 1], tc_track.data[0].lat.values[i_node], tc_track.data[0].time_step.values[i_node], tc_track.data[0].radius_max_wind.values[i_node], r_arr, v_trans, model=0) to_kn = (1 * ureg.meter / ureg.second).to(ureg.knot).magnitude self.assertEqual(v_ang.size, 6) self.assertAlmostEqual(v_ang[0] * to_kn, 10.774196807905097) self.assertAlmostEqual(v_ang[1] * to_kn, 10.591725180482094) self.assertAlmostEqual(v_ang[2] * to_kn, 10.398212766600055) self.assertAlmostEqual(v_ang[3] * to_kn, 10.195108683240084) self.assertAlmostEqual(v_ang[4] * to_kn, 10.319869893291429) self.assertAlmostEqual(v_ang[5] * to_kn, 11.305188714213809)
def test_set_one_pass(self): """Test _tc_from_track function.""" intensity_idx = [0, 1, 2, 3, 80, 100, 120, 200, 220, 250, 260, 295] intensity_values = { "geosphere": [25.60794285, 26.90906280, 28.26649026, 25.54076797, 31.21986961, 36.17171808, 21.11408573, 28.01457948, 32.65349378, 31.34027741, 0, 40.27362679], "equirect": [25.60778909, 26.90887264, 28.26624642, 25.54092386, 31.21941738, 36.16596567, 21.11399856, 28.01452136, 32.65076804, 31.33884098, 0, 40.27002104] } # the values for the two metrics should agree up to first digit at least for i, val in enumerate(intensity_values["geosphere"]): self.assertAlmostEqual(intensity_values["equirect"][i], val, 1) tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK) tc_track.equal_timestep() tc_track.data = tc_track.data[:1] for metric in ["equirect", "geosphere"]: tc_haz = TropCyclone() tc_haz.set_from_tracks(tc_track, centroids=CENTR_TEST_BRB, model='H08', store_windfields=True, metric=metric) self.assertEqual(tc_haz.tag.haz_type, 'TC') self.assertEqual(tc_haz.tag.description, '') self.assertEqual(tc_haz.tag.file_name, 'Name: 1951239N12334') self.assertEqual(tc_haz.units, 'm/s') self.assertEqual(tc_haz.centroids.size, 296) self.assertEqual(tc_haz.event_id.size, 1) self.assertEqual(tc_haz.date.size, 1) self.assertEqual(dt.datetime.fromordinal(tc_haz.date[0]).year, 1951) self.assertEqual(dt.datetime.fromordinal(tc_haz.date[0]).month, 8) self.assertEqual(dt.datetime.fromordinal(tc_haz.date[0]).day, 27) self.assertEqual(tc_haz.event_id[0], 1) self.assertEqual(tc_haz.event_name, ['1951239N12334']) self.assertTrue(np.array_equal(tc_haz.frequency, np.array([1]))) self.assertTrue(isinstance(tc_haz.fraction, sparse.csr.csr_matrix)) self.assertEqual(tc_haz.fraction.shape, (1, 296)) self.assertEqual(tc_haz.fraction[0, 100], 1) self.assertEqual(tc_haz.fraction[0, 260], 0) self.assertEqual(tc_haz.fraction.nonzero()[0].size, 280) self.assertTrue(isinstance(tc_haz.intensity, sparse.csr.csr_matrix)) self.assertEqual(tc_haz.intensity.shape, (1, 296)) self.assertEqual(np.nonzero(tc_haz.intensity)[0].size, 280) for idx, val in zip(intensity_idx, intensity_values[metric]): if val == 0: self.assertEqual(tc_haz.intensity[0, idx], 0) else: self.assertAlmostEqual(tc_haz.intensity[0, idx], val) windfields = tc_haz.windfields[0].toarray() windfields = windfields.reshape(windfields.shape[0], -1, 2) windfield_norms = np.linalg.norm(windfields, axis=-1).max(axis=0) intensity = tc_haz.intensity.toarray()[0, :] msk = (intensity > 0) np.testing.assert_array_equal(windfield_norms[msk], intensity[msk])
def test_vtrans_correct(self): """ Test _vtrans_correct function. Compare to MATLAB reference.""" ureg = UnitRegistry() i_node = 1 tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK) tc_track.equal_timestep() tc_track.data[0]['radius_max_wind'] = ( 'time', tc._extra_rad_max_wind(tc_track.data[0].central_pressure.values, tc_track.data[0].radius_max_wind.values, ureg)) r_arr = np.array([ 286.4938638337190, 290.5930935802884, 295.0271327746536, 299.7811253637995, 296.8484825705515, 274.9892882245964 ]) v_trans_corr = tc._vtrans_correct( tc_track.data[0].lat.values[i_node:i_node + 2], tc_track.data[0].lon.values[i_node:i_node + 2], tc_track.data[0].radius_max_wind.values[i_node], CENTR_TEST_BRB.coord[:6, :], r_arr) to_kn = (1 * ureg.meter / ureg.second).to(ureg.knot).magnitude v_trans = 10.191466256012880 / to_kn v_trans_corr *= v_trans self.assertEqual(v_trans_corr.size, 6) self.assertAlmostEqual(v_trans_corr[0] * to_kn, 0.06547673730228235) self.assertAlmostEqual(v_trans_corr[1] * to_kn, 0.07106877437273672) self.assertAlmostEqual(v_trans_corr[2] * to_kn, 0.07641714650288109) self.assertAlmostEqual(v_trans_corr[3] * to_kn, 0.0627289214278824) self.assertAlmostEqual(v_trans_corr[4] * to_kn, 0.0697427233582331) self.assertAlmostEqual(v_trans_corr[5] * to_kn, 0.06855335593983322)
def test_gust_from_track(self): """ Test gust_from_track function. Compare to MATLAB reference. """ tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK_SHORT) tc_track.equal_timestep() intensity = tc.gust_from_track(tc_track.data[0], CENT_CLB, model='H08') self.assertTrue(isinstance(intensity, sparse.csr.csr_matrix)) self.assertEqual(intensity.shape, (1, 1656093)) self.assertEqual(np.nonzero(intensity)[0].size, 7) self.assertEqual(intensity[0, 1630273], 0) self.assertAlmostEqual(intensity[0, 1630272], 18.505998796740347, 5) self.assertTrue(np.isclose(18.505998796740347, intensity[0, 1630272])) self.assertAlmostEqual(intensity[0, 1630393], 18.511077471450232, 6) self.assertTrue(np.isclose(18.511077471450232, intensity[0, 1630393])) self.assertAlmostEqual(intensity[0, 1630514], 18.297250626663271, 5) self.assertTrue(np.isclose(18.297250626663271, intensity[0, 1630514])) self.assertAlmostEqual(intensity[0, 1630635], 17.733240401598668, 6) self.assertTrue(np.isclose(17.733240401598668, intensity[0, 1630635])) self.assertAlmostEqual(intensity[0, 1630877], 17.525880201507256, 6) self.assertTrue(np.isclose(17.525880201507256, intensity[0, 1630877]))
def test_set_one_pass(self): """Test _set_from_track function.""" tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK) tc_track.equal_timestep() tc_haz = TCRain._set_from_track(tc_track.data[0], CENTR_TEST_BRB) self.assertEqual(tc_haz.tag.haz_type, 'TR') self.assertEqual(tc_haz.tag.description, '') self.assertEqual(tc_haz.tag.file_name, 'IBTrACS: 1951239N12334') self.assertEqual(tc_haz.units, 'mm') self.assertEqual(tc_haz.centroids.size, 296) self.assertEqual(tc_haz.event_id.size, 1) self.assertEqual(tc_haz.date.size, 1) self.assertEqual(dt.datetime.fromordinal(tc_haz.date[0]).year, 1951) self.assertEqual(dt.datetime.fromordinal(tc_haz.date[0]).month, 8) self.assertEqual(dt.datetime.fromordinal(tc_haz.date[0]).day, 27) self.assertEqual(tc_haz.event_id[0], 1) self.assertEqual(tc_haz.event_name, ['1951239N12334']) self.assertTrue(np.array_equal(tc_haz.frequency, np.array([1]))) self.assertTrue(isinstance(tc_haz.intensity, sparse.csr.csr_matrix)) self.assertTrue(isinstance(tc_haz.fraction, sparse.csr.csr_matrix)) self.assertEqual(tc_haz.intensity.shape, (1, 296)) self.assertEqual(tc_haz.fraction.shape, (1, 296)) self.assertAlmostEqual(tc_haz.intensity[0, 100], 99.7160586771286, 6) self.assertAlmostEqual(tc_haz.intensity[0, 260], 33.2087621869295) self.assertEqual(tc_haz.fraction[0, 100], 1) self.assertEqual(tc_haz.fraction[0, 260], 1) self.assertEqual(tc_haz.fraction.nonzero()[0].size, 296) self.assertEqual(tc_haz.intensity.nonzero()[0].size, 296)
def test_windfield(self): """ Test _windfield function. Compare to MATLAB reference. """ ureg = UnitRegistry() tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK) tc_track.equal_timestep() tc_track.data[0]['radius_max_wind'] = ( 'time', tc._extra_rad_max_wind(tc_track.data[0].central_pressure.values, tc_track.data[0].radius_max_wind.values, ureg)) coast_centr = tc.coastal_centr_idx(CENTR_TEST_BRB) wind = tc._windfield(tc_track.data[0], CENTR_TEST_BRB.coord, coast_centr, model=0) to_kn = (1 * ureg.meter / ureg.second).to(ureg.knot).magnitude self.assertEqual(wind.shape, (CENTR_TEST_BRB.size, )) wind = wind[coast_centr] self.assertEqual(np.nonzero(wind)[0].size, 280) self.assertAlmostEqual(wind[0] * to_kn, 51.16153933277889) self.assertAlmostEqual(wind[80] * to_kn, 64.15891933409763) self.assertAlmostEqual(wind[120] * to_kn, 41.43819201370903) self.assertAlmostEqual(wind[200] * to_kn, 57.28814245245439) self.assertAlmostEqual(wind[220] * to_kn, 69.62477194818004)
def test_interp_track_pass(self): """ Interpolate track to min_time_step. Compare to MATLAB reference.""" tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK) tc_track.equal_timestep(time_step_h=1) self.assertEqual(tc_track.data[0].time.size, 223) self.assertAlmostEqual(tc_track.data[0].lon.values[11], -27.426151640151684) self.assertAlmostEqual(tc_track.data[0].lat[23], 12.300006169591480) self.assertEqual(tc_track.data[0].time_step[7], 1) self.assertEqual(np.max(tc_track.data[0].radius_max_wind), 0) self.assertEqual(np.min(tc_track.data[0].radius_max_wind), 0) self.assertEqual(tc_track.data[0].max_sustained_wind[21], 25) self.assertAlmostEqual(tc_track.data[0].central_pressure.values[29], 1.005409300000005e+03) self.assertEqual(np.max(tc_track.data[0].environmental_pressure), 1010) self.assertEqual(np.min(tc_track.data[0].environmental_pressure), 1010) self.assertEqual(tc_track.data[0]['time.year'][13], 1951) self.assertEqual(tc_track.data[0]['time.month'][26], 8) self.assertEqual(tc_track.data[0]['time.day'][7], 27) self.assertEqual(tc_track.data[0].max_sustained_wind_unit, 'kn') self.assertEqual(tc_track.data[0].central_pressure_unit, 'mb') self.assertEqual(tc_track.data[0].orig_event_flag, 1) self.assertEqual(tc_track.data[0].name, '1951239N12334') self.assertEqual(tc_track.data[0].data_provider, 'hurdat_atl') self.assertTrue(np.isnan(tc_track.data[0].basin)) self.assertEqual(tc_track.data[0].id_no, 1951239012334) self.assertEqual(tc_track.data[0].category, 1)
def test_set_one_pass(self): """Test _tc_from_track function.""" tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK) tc_track.equal_timestep() tc_track.data = tc_track.data[:1] tc_haz = TropCyclone() tc_haz.set_from_tracks(tc_track, centroids=CENTR_TEST_BRB, model='H08', store_windfields=True) self.assertEqual(tc_haz.tag.haz_type, 'TC') self.assertEqual(tc_haz.tag.description, '') self.assertEqual(tc_haz.tag.file_name, 'Name: 1951239N12334') self.assertEqual(tc_haz.units, 'm/s') self.assertEqual(tc_haz.centroids.size, 296) self.assertEqual(tc_haz.event_id.size, 1) self.assertEqual(tc_haz.date.size, 1) self.assertEqual(dt.datetime.fromordinal(tc_haz.date[0]).year, 1951) self.assertEqual(dt.datetime.fromordinal(tc_haz.date[0]).month, 8) self.assertEqual(dt.datetime.fromordinal(tc_haz.date[0]).day, 27) self.assertEqual(tc_haz.event_id[0], 1) self.assertEqual(tc_haz.event_name, ['1951239N12334']) self.assertTrue(np.array_equal(tc_haz.frequency, np.array([1]))) self.assertTrue(isinstance(tc_haz.fraction, sparse.csr.csr_matrix)) self.assertEqual(tc_haz.fraction.shape, (1, 296)) self.assertEqual(tc_haz.fraction[0, 100], 1) self.assertEqual(tc_haz.fraction[0, 260], 0) self.assertEqual(tc_haz.fraction.nonzero()[0].size, 280) self.assertTrue(isinstance(tc_haz.intensity, sparse.csr.csr_matrix)) self.assertEqual(tc_haz.intensity.shape, (1, 296)) self.assertEqual(np.nonzero(tc_haz.intensity)[0].size, 280) self.assertEqual(tc_haz.intensity[0, 260], 0) self.assertAlmostEqual(tc_haz.intensity[0, 1], 27.08333002) self.assertAlmostEqual(tc_haz.intensity[0, 2], 28.46008202) self.assertAlmostEqual(tc_haz.intensity[0, 3], 25.70445069) self.assertAlmostEqual(tc_haz.intensity[0, 100], 36.45564037) self.assertAlmostEqual(tc_haz.intensity[0, 250], 31.60115745) self.assertAlmostEqual(tc_haz.intensity[0, 295], 40.62433745) to_kn = (1.0 * ureg.meter / ureg.second).to(ureg.knot).magnitude wind = tc_haz.intensity.toarray()[0, :] self.assertAlmostEqual(wind[0] * to_kn, 50.08492156) self.assertAlmostEqual(wind[80] * to_kn, 61.13812028) self.assertAlmostEqual(wind[120] * to_kn, 41.26159439) self.assertAlmostEqual(wind[200] * to_kn, 54.85572160) self.assertAlmostEqual(wind[220] * to_kn, 63.99749424) windfields = tc_haz.windfields[0].toarray() windfields = windfields.reshape(windfields.shape[0], -1, 2) windfield_norms = np.linalg.norm(windfields, axis=-1).max(axis=0) intensity = tc_haz.intensity.toarray()[0, :] msk = (intensity > 0) self.assertTrue(np.allclose(windfield_norms[msk], intensity[msk]))
def test_rainfield_from_track_pass(self): """Test _rainfield_from_track function. Compare to MATLAB reference.""" tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK) tc_track.equal_timestep() rainfall = rainfield_from_track(tc_track.data[0], CENTR_TEST_BRB) rainfall = np.round(rainfall, decimals=9) self.assertAlmostEqual(rainfall[0, 0], 66.801702386) self.assertAlmostEqual(rainfall[0, 130], 43.290917792) self.assertAlmostEqual(rainfall[0, 200], 76.315923838)
def test_interp_origin_inv_pass(self): """ Interpolate track to min_time_step crossing lat origin """ tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK) tc_track.data[0].lon.values = np.array([ 167.207761, 168.1, 168.936535, 169.728947, 170.5, 171.257176, 171.946822, 172.5, 172.871797, 173.113396, 173.3, 173.496375, 173.725522, 174., 174.331591, 174.728961, 175.2, 175.747632, 176.354929, 177., 177.66677, 178.362433, 179.1, 179.885288, -179.304661, -178.5, -177.726442, -176.991938, -176.3, -175.653595, -175.053513, -174.5, -173.992511, -173.527342, -173.1, -172.705991, -172.340823, -172. ]) tc_track.data[0].lon.values = -tc_track.data[0].lon.values tc_track.data[0].lat.values = np.array([ 40.196053, 40.6, 40.930215, 41.215674, 41.5, 41.816354, 42.156065, 42.5, 42.833998, 43.16377, 43.5, 43.847656, 44.188854, 44.5, 44.764269, 44.991925, 45.2, 45.402675, 45.602707, 45.8, 45.995402, 46.193543, 46.4, 46.615718, 46.82312, 47., 47.130616, 47.225088, 47.3, 47.369224, 47.435786, 47.5, 47.562858, 47.628064, 47.7, 47.783047, 47.881586, 48. ]) tc_track.equal_timestep(time_step_h=1) self.assertEqual(tc_track.data[0].time.size, 223) self.assertAlmostEqual(tc_track.data[0].lon.values[0], -167.207761) self.assertAlmostEqual(tc_track.data[0].lon.values[-1], 172) self.assertAlmostEqual(tc_track.data[0].lon.values[137], -179.75187272) self.assertAlmostEqual(tc_track.data[0].lon.values[138], -179.885288) self.assertAlmostEqual(tc_track.data[0].lon.values[139], 179.98060885) self.assertAlmostEqual(tc_track.data[0].lon.values[140], 179.84595743) self.assertAlmostEqual(tc_track.data[0].lat.values[0], 40.196053) self.assertAlmostEqual(tc_track.data[0].lat.values[-1], 48.) self.assertEqual(tc_track.data[0].time_step[7], 1) self.assertEqual(np.max(tc_track.data[0].radius_max_wind), 0) self.assertEqual(np.min(tc_track.data[0].radius_max_wind), 0) self.assertEqual(tc_track.data[0].max_sustained_wind[21], 25) self.assertAlmostEqual(tc_track.data[0].central_pressure.values[29], 1.005409300000005e+03) self.assertEqual(np.max(tc_track.data[0].environmental_pressure), 1010) self.assertEqual(np.min(tc_track.data[0].environmental_pressure), 1010) self.assertEqual(tc_track.data[0]['time.year'][13], 1951) self.assertEqual(tc_track.data[0]['time.month'][26], 8) self.assertEqual(tc_track.data[0]['time.day'][7], 27) self.assertEqual(tc_track.data[0].max_sustained_wind_unit, 'kn') self.assertEqual(tc_track.data[0].central_pressure_unit, 'mb') self.assertEqual(tc_track.data[0].orig_event_flag, 1) self.assertEqual(tc_track.data[0].name, '1951239N12334') self.assertEqual(tc_track.data[0].data_provider, 'hurdat_atl') self.assertTrue(np.isnan(tc_track.data[0].basin)) self.assertEqual(tc_track.data[0].id_no, 1951239012334) self.assertEqual(tc_track.data[0].category, 1)
def test_vtrans_pass(self): """Test _vtrans function. Compare to MATLAB reference.""" tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK) tc_track.equal_timestep() v_trans, _ = _vtrans( tc_track.data[0].lat.values, tc_track.data[0].lon.values, tc_track.data[0].time_step.values) to_kn = (1.0 * ureg.meter / ureg.second).to(ureg.knot).magnitude self.assertEqual(v_trans.size, tc_track.data[0].time.size) self.assertEqual(v_trans[0], 0) self.assertAlmostEqual(v_trans[1] * to_kn, 10.191466246)
def test_vtrans_pass(self): """ Test _vtrans function. Compare to MATLAB reference.""" ureg = UnitRegistry() i_node = 1 tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK) tc_track.equal_timestep() v_trans = tc._vtrans(tc_track.data[0].lat.values, tc_track.data[0].lon.values, tc_track.data[0].time_step.values, ureg) to_kn = (1* ureg.meter / ureg.second).to(ureg.knot).magnitude self.assertEqual(v_trans.size, tc_track.data[0].time.size-1) self.assertAlmostEqual(v_trans[i_node-1]*to_kn, 10.191466256012880)
def test_extra_rad_max_wind_pass(self): """ Test _extra_rad_max_wind function. Compare to MATLAB reference.""" ureg = UnitRegistry() tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK) tc_track.equal_timestep() rad_max_wind = tc._extra_rad_max_wind(tc_track.data[0].central_pressure.values, tc_track.data[0].radius_max_wind.values, ureg) self.assertEqual(rad_max_wind[0], 75.536713749999905) self.assertAlmostEqual(rad_max_wind[10], 75.592659583328057) self.assertAlmostEqual(rad_max_wind[128], 46.686527832605236) self.assertEqual(rad_max_wind[129], 46.089211533333405) self.assertAlmostEqual(rad_max_wind[130], 45.672274889277276) self.assertEqual(rad_max_wind[189], 45.132715266666672) self.assertAlmostEqual(rad_max_wind[190], 45.979603999211285) self.assertAlmostEqual(rad_max_wind[191], 47.287173876478825) self.assertEqual(rad_max_wind[192], 48.875090249999985) self.assertAlmostEqual(rad_max_wind[200], 59.975901084074955)
def test_gust_from_track(self): """ Test gust_from_track function. Compare to MATLAB reference. """ tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK) tc_track.equal_timestep() intensity = tc.gust_from_track(tc_track.data[0], CENTR_TEST_BRB, model='H08') self.assertTrue(isinstance(intensity, sparse.csr.csr_matrix)) self.assertEqual(intensity.shape, (1, 296)) self.assertEqual(np.nonzero(intensity)[0].size, 280) self.assertEqual(intensity[0, 260], 0) self.assertAlmostEqual(intensity[0, 1], 27.835686180065114) self.assertAlmostEqual(intensity[0, 2], 29.46862830056694) self.assertAlmostEqual(intensity[0, 3], 26.36829914594632) self.assertAlmostEqual(intensity[0, 100], 38.84863159321016) self.assertAlmostEqual(intensity[0, 250], 34.26311998266044) self.assertAlmostEqual(intensity[0, 295], 44.273964728810924)
def test_windfield(self): """ Test _windfield function. Compare to MATLAB reference. """ ureg = UnitRegistry() tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK) tc_track.equal_timestep() tc_track.data[0]['radius_max_wind'] = ( 'time', tc._extra_rad_max_wind(tc_track.data[0].central_pressure.values, tc_track.data[0].radius_max_wind.values, ureg)) int_track = tc_track.data[0].sel( time=slice('1951-08-27', '1951-08-28')) coast_centr = tc.coastal_centr_idx(CENT_CLB) wind = tc._windfield(int_track, CENT_CLB.coord, coast_centr, model=0) to_kn = (1 * ureg.meter / ureg.second).to(ureg.knot).magnitude self.assertEqual(wind.shape, (CENT_CLB.size, )) wind = wind[coast_centr] self.assertEqual(np.nonzero(wind)[0].size, 5) self.assertTrue( np.array_equal( wind.nonzero()[0], np.array([1019062, 1019183, 1019304, 1019425, 1019667]) - 1)) self.assertAlmostEqual(wind[1019061] * to_kn, 35.961499748377776, 4) self.assertTrue(np.isclose(35.961499748377776, wind[1019061] * to_kn)) self.assertAlmostEqual(wind[1019182] * to_kn, 35.985591640301138, 6) self.assertTrue(np.isclose(35.985591640301138, wind[1019182] * to_kn)) self.assertAlmostEqual(wind[1019303] * to_kn, 35.567653569424614, 5) self.assertTrue(np.isclose(35.567653569424614, wind[1019303] * to_kn)) self.assertAlmostEqual(wind[1019424] * to_kn, 34.470214174079388, 6) self.assertTrue(np.isclose(34.470214174079388, wind[1019424] * to_kn)) self.assertAlmostEqual(wind[1019666] * to_kn, 34.067538078331282, 6) self.assertTrue(np.isclose(34.067538078331282, wind[1019666] * to_kn))
def test_windfield_models(self): """Test _tc_from_track function with different wind field models.""" intensity_idx = [0, 1, 2, 3, 80, 100, 120, 200, 220, 250, 260, 295] intensity_values = { "H08": [ 25.60778909, 26.90887264, 28.26624642, 25.54092386, 31.21941738, 36.16596567, 21.11399856, 28.01452136, 32.65076804, 31.33884098, 0, 40.27002104 ], "H10": [ 27.477252, 28.626236, 29.829914, 27.393616, 32.495186, 37.113324, 23.573216, 29.552127, 33.767067, 32.530964, 19.656737, 41.014578 ], # Holland 1980 is the only model that uses recorded wind speeds, while the above use # pressure values only. That's why the results for Holland 1980 are so different: "H1980": [ 20.291397, 22.678914, 25.428598, 20.44718, 31.868592, 41.920317, 0, 25.715983, 38.351686, 35.591153, 0, 46.873912 ], } tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK) tc_track.equal_timestep() tc_track.data = tc_track.data[:1] for model in ["H08", "H10", "H1980"]: tc_haz = TropCyclone() tc_haz.set_from_tracks(tc_track, centroids=CENTR_TEST_BRB, model=model) np.testing.assert_array_almost_equal( tc_haz.intensity[0, intensity_idx].toarray()[0], intensity_values[model]) for idx, val in zip(intensity_idx, intensity_values[model]): if val == 0: self.assertEqual(tc_haz.intensity[0, idx], 0)
def test_rainfield_diff_time_steps(self): tc_track = TCTracks() tc_track.read_processed_ibtracs_csv(TEST_TRACK) train_org = TCRain() train_org.set_from_tracks(tc_track) tc_track.equal_timestep(time_step_h=1) train_1h = TCRain() train_1h.set_from_tracks(tc_track) tc_track.equal_timestep(time_step_h=0.5) train_05h = TCRain() train_05h.set_from_tracks(tc_track) np.testing.assert_allclose(train_org.intensity.sum(), train_1h.intensity.sum(), rtol=1e-1) np.testing.assert_allclose(train_org.intensity.sum(), train_05h.intensity.sum(), rtol=1e-1) np.testing.assert_allclose(train_05h.intensity.sum(), train_1h.intensity.sum(), rtol=1e-1)