def _map_join2origin(self, db): """ Return an Origin instance from an dict of CSS key/values Inputs ====== db : dict of key/values of CSS fields related to the origin (see Join) Returns ======= obspy.core.event.Origin Notes ===== Any object that supports the dict 'get' method can be passed as input, e.g. OrderedDict, custom classes, etc. Join ---- origin <- origerr (outer) """ #-- Basic location ------------------------------------------ origin = Origin() origin.latitude = db.get('lat') origin.longitude = db.get('lon') origin.depth = _km2m(db.get('depth')) origin.time = _utc(db.get('time')) origin.extra = {} #-- Quality ------------------------------------------------- quality = OriginQuality( associated_phase_count = db.get('nass'), used_phase_count = db.get('ndef'), standard_error = db.get('sdobs'), ) origin.quality = quality #-- Solution Uncertainties ---------------------------------- # in CSS the ellipse is projected onto the horizontal plane # using the covariance matrix uncertainty = OriginUncertainty() a = _km2m(db.get('smajax')) b = _km2m(db.get('sminax')) s = db.get('strike') dep_u = _km2m(db.get('sdepth')) time_u = db.get('stime') uncertainty.max_horizontal_uncertainty = a uncertainty.min_horizontal_uncertainty = b uncertainty.azimuth_max_horizontal_uncertainty = s uncertainty.horizontal_uncertainty = a uncertainty.preferred_description = "horizontal uncertainty" if db.get('conf') is not None: uncertainty.confidence_level = db.get('conf') * 100. if uncertainty.horizontal_uncertainty is not None: origin.origin_uncertainty = uncertainty #-- Parameter Uncertainties --------------------------------- if all([a, b, s]): n, e = _get_NE_on_ellipse(a, b, s) lat_u = _m2deg_lat(n) lon_u = _m2deg_lon(e, lat=origin.latitude) origin.latitude_errors = {'uncertainty': lat_u} origin.longitude_errors = {'uncertainty': lon_u} if dep_u: origin.depth_errors = {'uncertainty': dep_u} if time_u: origin.time_errors = {'uncertainty': time_u} #-- Analyst-determined Status ------------------------------- posted_author = _str(db.get('auth')) mode, status = self.get_event_status(posted_author) origin.evaluation_mode = mode origin.evaluation_status = status # Save etype per origin due to schema differences... css_etype = _str(db.get('etype')) # Compatible with future patch rename "_namespace" -> "namespace" origin.extra['etype'] = { 'value': css_etype, 'namespace': CSS_NAMESPACE } origin.creation_info = CreationInfo( creation_time = _utc(db.get('lddate')), agency_id = self.agency, version = db.get('orid'), author = posted_author, ) origin.resource_id = self._rid(origin) return origin
from obspy.core.event import Catalog, Event, Origin, Magnitude from obspy.geodetics import FlinnEngdahl # cat = Catalog() cat.description = "Just a fictitious toy example catalog built from scratch" e = Event() e.event_type = "not existing" o = Origin() o.time = UTCDateTime(2014, 2, 23, 18, 0, 0) o.latitude = 47.6 o.longitude = 12.0 o.depth = 10000 o.depth_type = "operator assigned" o.evaluation_mode = "manual" o.evaluation_status = "preliminary" o.region = FlinnEngdahl().get_region(o.longitude, o.latitude) m = Magnitude() m.mag = 7.2 m.magnitude_type = "Mw" m2 = Magnitude() m2.mag = 7.4 m2.magnitude_type = "Ms" # also included could be: custom picks, amplitude measurements, station magnitudes, # focal mechanisms, moment tensors, ... # make associations, put everything together
def _read_single_event(event_file, locate_dir, units, local_mag_ph): """ Parse an event file from QuakeMigrate into an obspy Event object. Parameters ---------- event_file : `pathlib.Path` object Path to .event file to read. locate_dir : `pathlib.Path` object Path to locate directory (contains "events", "picks" etc. directories). units : {"km", "m"} Grid projection coordinates for QM LUT (determines units of depths and uncertainties in the .event files). local_mag_ph : {"S", "P"} Amplitude measurement used to calculate local magnitudes. Returns ------- event : `obspy.Event` object Event object populated with all available information output by :class:`~quakemigrate.signal.scan.locate()`, including event locations and uncertainties, picks, and amplitudes and magnitudes if available. """ # Parse information from event file event_info = pd.read_csv(event_file).iloc[0] event_uid = str(event_info["EventID"]) # Set distance conversion factor (from units of QM LUT projection units). if units == "km": factor = 1e3 elif units == "m": factor = 1 else: raise AttributeError(f"units must be 'km' or 'm'; not {units}") # Create event object to store origin and pick information event = Event() event.extra = AttribDict() event.resource_id = str(event_info["EventID"]) event.creation_info = CreationInfo(author="QuakeMigrate", version=quakemigrate.__version__) # Add COA info to extra event.extra.coa = {"value": event_info["COA"], "namespace": ns} event.extra.coa_norm = {"value": event_info["COA_NORM"], "namespace": ns} event.extra.trig_coa = {"value": event_info["TRIG_COA"], "namespace": ns} event.extra.dec_coa = {"value": event_info["DEC_COA"], "namespace": ns} event.extra.dec_coa_norm = { "value": event_info["DEC_COA_NORM"], "namespace": ns } # Determine location of cut waveform data - add to event object as a # custom extra attribute. mseed = locate_dir / "raw_cut_waveforms" / event_uid event.extra.cut_waveforms_file = { "value": str(mseed.with_suffix(".m").resolve()), "namespace": ns } if (locate_dir / "real_cut_waveforms").exists(): mseed = locate_dir / "real_cut_waveforms" / event_uid event.extra.real_cut_waveforms_file = { "value": str(mseed.with_suffix(".m").resolve()), "namespace": ns } if (locate_dir / "wa_cut_waveforms").exists(): mseed = locate_dir / "wa_cut_waveforms" / event_uid event.extra.wa_cut_waveforms_file = { "value": str(mseed.with_suffix(".m").resolve()), "namespace": ns } # Create origin with spline location and set to preferred event origin. origin = Origin() origin.method_id = "spline" origin.longitude = event_info["X"] origin.latitude = event_info["Y"] origin.depth = event_info["Z"] * factor origin.time = UTCDateTime(event_info["DT"]) event.origins = [origin] event.preferred_origin_id = origin.resource_id # Create origin with gaussian location and associate with event origin = Origin() origin.method_id = "gaussian" origin.longitude = event_info["GAU_X"] origin.latitude = event_info["GAU_Y"] origin.depth = event_info["GAU_Z"] * factor origin.time = UTCDateTime(event_info["DT"]) event.origins.append(origin) ouc = OriginUncertainty() ce = ConfidenceEllipsoid() ce.semi_major_axis_length = event_info["COV_ErrY"] * factor ce.semi_intermediate_axis_length = event_info["COV_ErrX"] * factor ce.semi_minor_axis_length = event_info["COV_ErrZ"] * factor ce.major_axis_plunge = 0 ce.major_axis_azimuth = 0 ce.major_axis_rotation = 0 ouc.confidence_ellipsoid = ce ouc.preferred_description = "confidence ellipsoid" # Set uncertainties for both as the gaussian uncertainties for origin in event.origins: origin.longitude_errors.uncertainty = kilometer2degrees( event_info["GAU_ErrX"] * factor / 1e3) origin.latitude_errors.uncertainty = kilometer2degrees( event_info["GAU_ErrY"] * factor / 1e3) origin.depth_errors.uncertainty = event_info["GAU_ErrZ"] * factor origin.origin_uncertainty = ouc # Add OriginQuality info to each origin? for origin in event.origins: origin.origin_type = "hypocenter" origin.evaluation_mode = "automatic" # --- Handle picks file --- pick_file = locate_dir / "picks" / event_uid if pick_file.with_suffix(".picks").is_file(): picks = pd.read_csv(pick_file.with_suffix(".picks")) else: return None for _, pickline in picks.iterrows(): station = str(pickline["Station"]) phase = str(pickline["Phase"]) wid = WaveformStreamID(network_code="", station_code=station) for method in ["modelled", "autopick"]: pick = Pick() pick.extra = AttribDict() pick.waveform_id = wid pick.method_id = method pick.phase_hint = phase if method == "autopick" and str(pickline["PickTime"]) != "-1": pick.time = UTCDateTime(pickline["PickTime"]) pick.time_errors.uncertainty = float(pickline["PickError"]) pick.extra.snr = { "value": float(pickline["SNR"]), "namespace": ns } elif method == "modelled": pick.time = UTCDateTime(pickline["ModelledTime"]) else: continue event.picks.append(pick) # --- Handle amplitudes file --- amps_file = locate_dir / "amplitudes" / event_uid if amps_file.with_suffix(".amps").is_file(): amps = pd.read_csv(amps_file.with_suffix(".amps")) i = 0 for _, ampsline in amps.iterrows(): wid = WaveformStreamID(seed_string=ampsline["id"]) noise_amp = ampsline["Noise_amp"] / 1000 # mm to m for phase in ["P_amp", "S_amp"]: amp = Amplitude() if pd.isna(ampsline[phase]): continue amp.generic_amplitude = ampsline[phase] / 1000 # mm to m amp.generic_amplitude_errors.uncertainty = noise_amp amp.unit = "m" amp.type = "AML" amp.method_id = phase amp.period = 1 / ampsline[f"{phase[0]}_freq"] amp.time_window = TimeWindow( reference=UTCDateTime(ampsline[f"{phase[0]}_time"])) # amp.pick_id = ? amp.waveform_id = wid # amp.filter_id = ? amp.magnitude_hint = "ML" amp.evaluation_mode = "automatic" amp.extra = AttribDict() try: amp.extra.filter_gain = { "value": ampsline[f"{phase[0]}_filter_gain"], "namespace": ns } amp.extra.avg_amp = { "value": ampsline[f"{phase[0]}_avg_amp"] / 1000, # m "namespace": ns } except KeyError: pass if phase[0] == local_mag_ph and not pd.isna(ampsline["ML"]): i += 1 stat_mag = StationMagnitude() stat_mag.extra = AttribDict() # stat_mag.origin_id = ? local_mag_loc stat_mag.mag = ampsline["ML"] stat_mag.mag_errors.uncertainty = ampsline["ML_Err"] stat_mag.station_magnitude_type = "ML" stat_mag.amplitude_id = amp.resource_id stat_mag.extra.picked = { "value": ampsline["is_picked"], "namespace": ns } stat_mag.extra.epi_dist = { "value": ampsline["epi_dist"], "namespace": ns } stat_mag.extra.z_dist = { "value": ampsline["z_dist"], "namespace": ns } event.station_magnitudes.append(stat_mag) event.amplitudes.append(amp) mag = Magnitude() mag.extra = AttribDict() mag.mag = event_info["ML"] mag.mag_errors.uncertainty = event_info["ML_Err"] mag.magnitude_type = "ML" # mag.origin_id = ? mag.station_count = i mag.evaluation_mode = "automatic" mag.extra.r2 = {"value": event_info["ML_r2"], "namespace": ns} event.magnitudes = [mag] event.preferred_magnitude_id = mag.resource_id return event