def _map_fplane2focalmech(self, db): """ Return an obspy FocalMechanism from an dict of CSS key/values corresponding to one record. See the 'Join' section for the implied database join expected. Inputs ====== db : dict of key/values of CSS fields from the 'fplane' table Returns ======= obspy.core.event.FocalMechanism Notes ===== Any object that supports the dict 'get' method can be passed as input, e.g. OrderedDict, custom classes, etc. """ # # NOTE: Antelope schema for this is wrong, no nulls defined # fm = FocalMechanism() nps = NodalPlanes() nps.nodal_plane_1 = NodalPlane(db.get('str1'), db.get('dip1'), db.get('rake1')) nps.nodal_plane_2 = NodalPlane(db.get('str2'), db.get('dip2'), db.get('rake2')) nps.preferred_plane = 1 prin_ax = PrincipalAxes() prin_ax.t_axis = Axis(db.get('taxazm'),db.get('taxplg')) prin_ax.p_axis = Axis(db.get('paxazm'),db.get('paxplg')) fm.nodal_planes = nps fm.principal_axes = prin_ax author_string = ':'.join([db['algorithm'], db['auth']]) fm.creation_info = CreationInfo( version = db.get('mechid'), creation_time = UTCDateTime(db['lddate']), agency_id = self.agency, author = author_string, ) fm.resource_id = self._rid(fm) return fm
def __toFocalMechanism(parser, focmec_el): """ """ global CURRENT_TYPE focmec = FocalMechanism() focmec.resource_id = ResourceIdentifier( prefix="/".join([RESOURCE_ROOT, "focal_mechanism"])) if CURRENT_TYPE == "obspyck": focmec.method_id = "%s/focal_mechanism_method/focmec/1" % RESOURCE_ROOT else: focmec.method_id = "%s/focal_mechanism_method/%s/1" % ( RESOURCE_ROOT, parser.xpath2obj('program', focmec_el)) if str(focmec.method_id).lower().endswith("none"): focmec.method_id = None focmec.station_polarity_count = parser.xpath2obj("stationPolarityCount", focmec_el, int) if focmec.station_polarity_count: focmec.misfit = parser.xpath2obj("stationPolarityErrorCount", focmec_el, int) / float( focmec.station_polarity_count) focmec.nodal_planes = NodalPlanes() focmec.nodal_planes.nodal_plane_1 = NodalPlane() nodal_plane = focmec_el.find("nodalPlanes") if nodal_plane is None or not len(nodal_plane): return None n_p = focmec.nodal_planes.nodal_plane_1 # There is always only one nodal plane, called nodalPlane1 n_p.strike, strike_uncertainty = __toFloatQuantity( parser, focmec_el, "nodalPlanes/nodalPlane1/strike") n_p.dip, dip_uncertainty = __toFloatQuantity( parser, focmec_el, "nodalPlanes/nodalPlane1/dip") n_p.rake, rake_uncertainty = __toFloatQuantity( parser, focmec_el, "nodalPlanes/nodalPlane1/rake") if hasattr(strike_uncertainty, "uncertainty"): n_p.strike_errors.uncertainty = strike_uncertainty["uncertainty"] if hasattr(dip_uncertainty, "uncertainty"): n_p.dip_errors.uncertainty = dip_uncertainty["uncertainty"] if hasattr(rake_uncertainty, "uncertainty"): n_p.rake_errors.uncertainty = rake_uncertainty["uncertainty"] solution_count = parser.xpath2obj("possibleSolutionCount", focmec_el, int) if solution_count: focmec.comments.append( Comment(force_resource_id=False, resource_id=None, text="Possible Solution Count: %i" % solution_count)) return focmec
def __toFocalMechanism(parser, focmec_el): """ """ global CURRENT_TYPE focmec = FocalMechanism() focmec.resource_id = ResourceIdentifier(prefix="/".join([RESOURCE_ROOT, "focal_mechanism"])) if CURRENT_TYPE == "obspyck": focmec.method_id = "%s/focal_mechanism_method/focmec/1" % RESOURCE_ROOT else: focmec.method_id = "%s/focal_mechanism_method/%s/1" % (RESOURCE_ROOT, parser.xpath2obj('program', focmec_el)) if str(focmec.method_id).lower().endswith("none"): focmec.method_id = None focmec.station_polarity_count = parser.xpath2obj("stationPolarityCount", focmec_el, int) if focmec.station_polarity_count: focmec.misfit = parser.xpath2obj("stationPolarityErrorCount", focmec_el, int) / float(focmec.station_polarity_count) focmec.nodal_planes = NodalPlanes() focmec.nodal_planes.nodal_plane_1 = NodalPlane() nodal_plane = focmec_el.find("nodalPlanes") if nodal_plane is None or not len(nodal_plane): return None n_p = focmec.nodal_planes.nodal_plane_1 # There is always only one nodal plane, called nodalPlane1 n_p.strike, strike_uncertainty = __toFloatQuantity(parser, focmec_el, "nodalPlanes/nodalPlane1/strike") n_p.dip, dip_uncertainty = __toFloatQuantity(parser, focmec_el, "nodalPlanes/nodalPlane1/dip") n_p.rake, rake_uncertainty = __toFloatQuantity(parser, focmec_el, "nodalPlanes/nodalPlane1/rake") if hasattr(strike_uncertainty, "uncertainty"): n_p.strike_errors.uncertainty = strike_uncertainty["uncertainty"] if hasattr(dip_uncertainty, "uncertainty"): n_p.dip_errors.uncertainty = dip_uncertainty["uncertainty"] if hasattr(rake_uncertainty, "uncertainty"): n_p.rake_errors.uncertainty = rake_uncertainty["uncertainty"] solution_count = parser.xpath2obj("possibleSolutionCount", focmec_el, int) if solution_count: focmec.comments.append(Comment( force_resource_id=False, resource_id=None, text="Possible Solution Count: %i" % solution_count)) return focmec
def __read_single_fnetmt_entry(line, **kwargs): """ Reads a single F-net moment tensor solution to a :class:`~obspy.core.event.Event` object. :param line: String containing moment tensor information. :type line: str. """ a = line.split() try: ot = UTCDateTime().strptime(a[0], '%Y/%m/%d,%H:%M:%S.%f') except ValueError: ot = UTCDateTime().strptime(a[0], '%Y/%m/%d,%H:%M:%S') lat, lon, depjma, magjma = map(float, a[1:5]) depjma *= 1000 region = a[5] strike = tuple(map(int, a[6].split(';'))) dip = tuple(map(int, a[7].split(';'))) rake = tuple(map(int, a[8].split(';'))) mo = float(a[9]) depmt = float(a[10]) * 1000 magmt = float(a[11]) var_red = float(a[12]) mxx, mxy, mxz, myy, myz, mzz, unit = map(float, a[13:20]) event_name = util.gen_sc3_id(ot) e = Event(event_type="earthquake") e.resource_id = _get_resource_id(event_name, 'event') # Standard JMA solution o_jma = Origin(time=ot, latitude=lat, longitude=lon, depth=depjma, depth_type="from location", region=region) o_jma.resource_id = _get_resource_id(event_name, 'origin', 'JMA') m_jma = Magnitude(mag=magjma, magnitude_type='ML', origin_id=o_jma.resource_id) m_jma.resource_id = _get_resource_id(event_name, 'magnitude', 'JMA') # MT solution o_mt = Origin(time=ot, latitude=lat, longitude=lon, depth=depmt, region=region, depth_type="from moment tensor inversion") o_mt.resource_id = _get_resource_id(event_name, 'origin', 'MT') m_mt = Magnitude(mag=magmt, magnitude_type='Mw', origin_id=o_mt.resource_id) m_mt.resource_id = _get_resource_id(event_name, 'magnitude', 'MT') foc_mec = FocalMechanism(triggering_origin_id=o_jma.resource_id) foc_mec.resource_id = _get_resource_id(event_name, "focal_mechanism") nod1 = NodalPlane(strike=strike[0], dip=dip[0], rake=rake[0]) nod2 = NodalPlane(strike=strike[1], dip=dip[1], rake=rake[1]) nod = NodalPlanes(nodal_plane_1=nod1, nodal_plane_2=nod2) foc_mec.nodal_planes = nod tensor = Tensor(m_rr=mxx, m_tt=myy, m_pp=mzz, m_rt=mxy, m_rp=mxz, m_tp=myz) cm = Comment(text="Basis system: North,East,Down (Jost and \ Herrmann 1989") cm.resource_id = _get_resource_id(event_name, 'comment', 'mt') mt = MomentTensor(derived_origin_id=o_mt.resource_id, moment_magnitude_id=m_mt.resource_id, scalar_moment=mo, comments=[cm], tensor=tensor, variance_reduction=var_red) mt.resource_id = _get_resource_id(event_name, 'moment_tensor') foc_mec.moment_tensor = mt e.origins = [o_jma, o_mt] e.magnitudes = [m_jma, m_mt] e.focal_mechanisms = [foc_mec] e.preferred_magnitude_id = m_mt.resource_id.id e.preferred_origin_id = o_mt.resource_id.id e.preferred_focal_mechanism_id = foc_mec.resource_id.id return e
def __read_single_fnetmt_entry(line, **kwargs): """ Reads a single F-net moment tensor solution to a :class:`~obspy.core.event.Event` object. :param line: String containing moment tensor information. :type line: str. """ a = line.split() try: ot = UTCDateTime().strptime(a[0], '%Y/%m/%d,%H:%M:%S.%f') except ValueError: ot = UTCDateTime().strptime(a[0], '%Y/%m/%d,%H:%M:%S') lat, lon, depjma, magjma = map(float, a[1:5]) depjma *= 1000 region = a[5] strike = tuple(map(int, a[6].split(';'))) dip = tuple(map(int, a[7].split(';'))) rake = tuple(map(int, a[8].split(';'))) mo = float(a[9]) depmt = float(a[10]) * 1000 magmt = float(a[11]) var_red = float(a[12]) mxx, mxy, mxz, myy, myz, mzz, unit = map(float, a[13:20]) event_name = util.gen_sc3_id(ot) e = Event(event_type="earthquake") e.resource_id = _get_resource_id(event_name, 'event') # Standard JMA solution o_jma = Origin(time=ot, latitude=lat, longitude=lon, depth=depjma, depth_type="from location", region=region) o_jma.resource_id = _get_resource_id(event_name, 'origin', 'JMA') m_jma = Magnitude(mag=magjma, magnitude_type='ML', origin_id=o_jma.resource_id) m_jma.resource_id = _get_resource_id(event_name, 'magnitude', 'JMA') # MT solution o_mt = Origin(time=ot, latitude=lat, longitude=lon, depth=depmt, region=region, depth_type="from moment tensor inversion") o_mt.resource_id = _get_resource_id(event_name, 'origin', 'MT') m_mt = Magnitude(mag=magmt, magnitude_type='Mw', origin_id=o_mt.resource_id) m_mt.resource_id = _get_resource_id(event_name, 'magnitude', 'MT') foc_mec = FocalMechanism(triggering_origin_id=o_jma.resource_id) foc_mec.resource_id = _get_resource_id(event_name, "focal_mechanism") nod1 = NodalPlane(strike=strike[0], dip=dip[0], rake=rake[0]) nod2 = NodalPlane(strike=strike[1], dip=dip[1], rake=rake[1]) nod = NodalPlanes(nodal_plane_1=nod1, nodal_plane_2=nod2) foc_mec.nodal_planes = nod tensor = Tensor(m_rr=mxx, m_tt=myy, m_pp=mzz, m_rt=mxy, m_rp=mxz, m_tp=myz) cm = Comment(text="Basis system: North,East,Down (Jost and \ Herrmann 1989") cm.resource_id = _get_resource_id(event_name, 'comment', 'mt') mt = MomentTensor(derived_origin_id=o_mt.resource_id, moment_magnitude_id=m_mt.resource_id, scalar_moment=mo, comments=[cm], tensor=tensor, variance_reduction=var_red) mt.resource_id = _get_resource_id(event_name, 'moment_tensor') foc_mec.moment_tensor = mt e.origins = [o_jma, o_mt] e.magnitudes = [m_jma, m_mt] e.focal_mechanisms = [foc_mec] e.preferred_magnitude_id = m_mt.resource_id.id e.preferred_origin_id = o_mt.resource_id.id e.preferred_focal_mechanism_id = foc_mec.resource_id.id return e
def par2quakeml(Par_filename, QuakeML_filename, rotation_axis=[0.0, 1.0, 0.0], rotation_angle=-57.5, origin_time="2000-01-01 00:00:00.0", event_type="other event"): # initialise event ev = Event() # open and read Par file fid = open(Par_filename, 'r') fid.readline() fid.readline() fid.readline() fid.readline() lat_old = 90.0 - float(fid.readline().strip().split()[0]) lon_old = float(fid.readline().strip().split()[0]) depth = float(fid.readline().strip().split()[0]) fid.readline() Mtt_old = float(fid.readline().strip().split()[0]) Mpp_old = float(fid.readline().strip().split()[0]) Mrr_old = float(fid.readline().strip().split()[0]) Mtp_old = float(fid.readline().strip().split()[0]) Mtr_old = float(fid.readline().strip().split()[0]) Mpr_old = float(fid.readline().strip().split()[0]) # rotate event into physical domain lat, lon = rot.rotate_lat_lon(lat_old, lon_old, rotation_axis, rotation_angle) Mrr, Mtt, Mpp, Mtr, Mpr, Mtp = rot.rotate_moment_tensor( Mrr_old, Mtt_old, Mpp_old, Mtr_old, Mpr_old, Mtp_old, lat_old, lon_old, rotation_axis, rotation_angle) # populate event origin data ev.event_type = event_type ev_origin = Origin() ev_origin.time = UTCDateTime(origin_time) ev_origin.latitude = lat ev_origin.longitude = lon ev_origin.depth = depth ev.origins.append(ev_origin) # populte event moment tensor ev_tensor = Tensor() ev_tensor.m_rr = Mrr ev_tensor.m_tt = Mtt ev_tensor.m_pp = Mpp ev_tensor.m_rt = Mtr ev_tensor.m_rp = Mpr ev_tensor.m_tp = Mtp ev_momenttensor = MomentTensor() ev_momenttensor.tensor = ev_tensor ev_momenttensor.scalar_moment = np.sqrt(Mrr**2 + Mtt**2 + Mpp**2 + Mtr**2 + Mpr**2 + Mtp**2) ev_focalmechanism = FocalMechanism() ev_focalmechanism.moment_tensor = ev_momenttensor ev_focalmechanism.nodal_planes = NodalPlanes().setdefault(0, 0) ev.focal_mechanisms.append(ev_focalmechanism) # populate event magnitude ev_magnitude = Magnitude() ev_magnitude.mag = 0.667 * (np.log10(ev_momenttensor.scalar_moment) - 9.1) ev_magnitude.magnitude_type = 'Mw' ev.magnitudes.append(ev_magnitude) # write QuakeML file cat = Catalog() cat.append(ev) cat.write(QuakeML_filename, format="quakeml") # clean up fid.close()
def outputOBSPY(hp, event=None, only_fm_picks=False): """ Make an Event which includes the current focal mechanism information from HASH Use the 'only_fm_picks' flag to only include the picks HASH used for the FocalMechanism. This flag will replace the 'picks' and 'arrivals' lists of existing events with new ones. Inputs ------- hp : hashpy.HashPype instance event : obspy.core.event.Event only_fm_picks : bool of whether to overwrite the picks/arrivals lists Returns ------- obspy.core.event.Event Event will be new if no event was input, FocalMech added to existing event """ # Returns new (or updates existing) Event with HASH solution n = hp.npol if event is None: event = Event(focal_mechanisms=[], picks=[], origins=[]) origin = Origin(arrivals=[]) origin.time = UTCDateTime(hp.tstamp) origin.latitude = hp.qlat origin.longitude = hp.qlon origin.depth = hp.qdep origin.creation_info = CreationInfo(version=hp.icusp) origin.resource_id = ResourceIdentifier('smi:hash/Origin/{0}'.format( hp.icusp)) for _i in range(n): p = Pick() p.creation_info = CreationInfo(version=hp.arid[_i]) p.resource_id = ResourceIdentifier('smi:nsl/Pick/{0}'.format( p.creation_info.version)) p.waveform_id = WaveformStreamID(network_code=hp.snet[_i], station_code=hp.sname[_i], channel_code=hp.scomp[_i]) if hp.p_pol[_i] > 0: p.polarity = 'positive' else: p.polarity = 'negative' a = Arrival() a.creation_info = CreationInfo(version=hp.arid[_i]) a.resource_id = ResourceIdentifier('smi:nsl/Arrival/{0}'.format( p.creation_info.version)) a.azimuth = hp.p_azi_mc[_i, 0] a.takeoff_angle = 180. - hp.p_the_mc[_i, 0] a.pick_id = p.resource_id origin.arrivals.append(a) event.picks.append(p) event.origins.append(origin) event.preferred_origin_id = origin.resource_id.resource_id else: # just update the changes origin = event.preferred_origin() picks = [] arrivals = [] for _i in range(n): ind = hp.p_index[_i] a = origin.arrivals[ind] p = a.pick_id.getReferredObject() a.takeoff_angle = hp.p_the_mc[_i, 0] picks.append(p) arrivals.append(a) if only_fm_picks: origin.arrivals = arrivals event.picks = picks # Use me double couple calculator and populate planes/axes etc x = hp._best_quality_index # Put all the mechanisms into the 'focal_mechanisms' list, mark "best" as preferred for s in range(hp.nmult): dc = DoubleCouple([hp.str_avg[s], hp.dip_avg[s], hp.rak_avg[s]]) ax = dc.axis focal_mech = FocalMechanism() focal_mech.creation_info = CreationInfo(creation_time=UTCDateTime(), author=hp.author) focal_mech.triggering_origin_id = origin.resource_id focal_mech.resource_id = ResourceIdentifier( 'smi:hash/FocalMechanism/{0}/{1}'.format(hp.icusp, s + 1)) focal_mech.method_id = ResourceIdentifier('HASH') focal_mech.nodal_planes = NodalPlanes() focal_mech.nodal_planes.nodal_plane_1 = NodalPlane(*dc.plane1) focal_mech.nodal_planes.nodal_plane_2 = NodalPlane(*dc.plane2) focal_mech.principal_axes = PrincipalAxes() focal_mech.principal_axes.t_axis = Axis(azimuth=ax['T']['azimuth'], plunge=ax['T']['dip']) focal_mech.principal_axes.p_axis = Axis(azimuth=ax['P']['azimuth'], plunge=ax['P']['dip']) focal_mech.station_polarity_count = n focal_mech.azimuthal_gap = hp.magap focal_mech.misfit = hp.mfrac[s] focal_mech.station_distribution_ratio = hp.stdr[s] focal_mech.comments.append( Comment( hp.qual[s], resource_id=ResourceIdentifier( focal_mech.resource_id.resource_id + '/comment/quality'))) #---------------------------------------- event.focal_mechanisms.append(focal_mech) if s == x: event.preferred_focal_mechanism_id = focal_mech.resource_id.resource_id return event
def outputOBSPY(hp, event=None, only_fm_picks=False): """ Make an Event which includes the current focal mechanism information from HASH Use the 'only_fm_picks' flag to only include the picks HASH used for the FocalMechanism. This flag will replace the 'picks' and 'arrivals' lists of existing events with new ones. Inputs ------- hp : hashpy.HashPype instance event : obspy.core.event.Event only_fm_picks : bool of whether to overwrite the picks/arrivals lists Returns ------- obspy.core.event.Event Event will be new if no event was input, FocalMech added to existing event """ # Returns new (or updates existing) Event with HASH solution n = hp.npol if event is None: event = Event(focal_mechanisms=[], picks=[], origins=[]) origin = Origin(arrivals=[]) origin.time = UTCDateTime(hp.tstamp) origin.latitude = hp.qlat origin.longitude = hp.qlon origin.depth = hp.qdep origin.creation_info = CreationInfo(version=hp.icusp) origin.resource_id = ResourceIdentifier('smi:hash/Origin/{0}'.format(hp.icusp)) for _i in range(n): p = Pick() p.creation_info = CreationInfo(version=hp.arid[_i]) p.resource_id = ResourceIdentifier('smi:hash/Pick/{0}'.format(p.creation_info.version)) p.waveform_id = WaveformStreamID(network_code=hp.snet[_i], station_code=hp.sname[_i], channel_code=hp.scomp[_i]) if hp.p_pol[_i] > 0: p.polarity = 'positive' else: p.polarity = 'negative' a = Arrival() a.creation_info = CreationInfo(version=hp.arid[_i]) a.resource_id = ResourceIdentifier('smi:hash/Arrival/{0}'.format(p.creation_info.version)) a.azimuth = hp.p_azi_mc[_i,0] a.takeoff_angle = 180. - hp.p_the_mc[_i,0] a.pick_id = p.resource_id origin.arrivals.append(a) event.picks.append(p) event.origins.append(origin) event.preferred_origin_id = str(origin.resource_id) else: # just update the changes origin = event.preferred_origin() picks = [] arrivals = [] for _i in range(n): ind = hp.p_index[_i] a = origin.arrivals[ind] p = a.pick_id.getReferredObject() a.takeoff_angle = hp.p_the_mc[_i,0] picks.append(p) arrivals.append(a) if only_fm_picks: origin.arrivals = arrivals event.picks = picks # Use me double couple calculator and populate planes/axes etc x = hp._best_quality_index # Put all the mechanisms into the 'focal_mechanisms' list, mark "best" as preferred for s in range(hp.nmult): dc = DoubleCouple([hp.str_avg[s], hp.dip_avg[s], hp.rak_avg[s]]) ax = dc.axis focal_mech = FocalMechanism() focal_mech.creation_info = CreationInfo(creation_time=UTCDateTime(), author=hp.author) focal_mech.triggering_origin_id = origin.resource_id focal_mech.resource_id = ResourceIdentifier('smi:hash/FocalMechanism/{0}/{1}'.format(hp.icusp, s+1)) focal_mech.method_id = ResourceIdentifier('HASH') focal_mech.nodal_planes = NodalPlanes() focal_mech.nodal_planes.nodal_plane_1 = NodalPlane(*dc.plane1) focal_mech.nodal_planes.nodal_plane_2 = NodalPlane(*dc.plane2) focal_mech.principal_axes = PrincipalAxes() focal_mech.principal_axes.t_axis = Axis(azimuth=ax['T']['azimuth'], plunge=ax['T']['dip']) focal_mech.principal_axes.p_axis = Axis(azimuth=ax['P']['azimuth'], plunge=ax['P']['dip']) focal_mech.station_polarity_count = n focal_mech.azimuthal_gap = hp.magap focal_mech.misfit = hp.mfrac[s] focal_mech.station_distribution_ratio = hp.stdr[s] focal_mech.comments.append( Comment(hp.qual[s], resource_id=ResourceIdentifier(str(focal_mech.resource_id) + '/comment/quality')) ) #---------------------------------------- event.focal_mechanisms.append(focal_mech) if s == x: event.preferred_focal_mechanism_id = str(focal_mech.resource_id) return event
def par2quakeml(Par_filename, QuakeML_filename, rotation_axis=[0.0, 1.0, 0.0], rotation_angle=-57.5, origin_time="2000-01-01 00:00:00.0", event_type="other event"): # initialise event ev = Event() # open and read Par file fid = open(Par_filename, 'r') fid.readline() fid.readline() fid.readline() fid.readline() lat_old = 90.0 - float(fid.readline().strip().split()[0]) lon_old = float(fid.readline().strip().split()[0]) depth = float(fid.readline().strip().split()[0]) fid.readline() Mtt_old = float(fid.readline().strip().split()[0]) Mpp_old = float(fid.readline().strip().split()[0]) Mrr_old = float(fid.readline().strip().split()[0]) Mtp_old = float(fid.readline().strip().split()[0]) Mtr_old = float(fid.readline().strip().split()[0]) Mpr_old = float(fid.readline().strip().split()[0]) # rotate event into physical domain lat, lon = rot.rotate_lat_lon(lat_old, lon_old, rotation_axis, rotation_angle) Mrr, Mtt, Mpp, Mtr, Mpr, Mtp = rot.rotate_moment_tensor( Mrr_old, Mtt_old, Mpp_old, Mtr_old, Mpr_old, Mtp_old, lat_old, lon_old, rotation_axis, rotation_angle) # populate event origin data ev.event_type = event_type ev_origin = Origin() ev_origin.time = UTCDateTime(origin_time) ev_origin.latitude = lat ev_origin.longitude = lon ev_origin.depth = depth ev.origins.append(ev_origin) # populte event moment tensor ev_tensor = Tensor() ev_tensor.m_rr = Mrr ev_tensor.m_tt = Mtt ev_tensor.m_pp = Mpp ev_tensor.m_rt = Mtr ev_tensor.m_rp = Mpr ev_tensor.m_tp = Mtp ev_momenttensor = MomentTensor() ev_momenttensor.tensor = ev_tensor ev_momenttensor.scalar_moment = np.sqrt(Mrr ** 2 + Mtt ** 2 + Mpp ** 2 + Mtr ** 2 + Mpr ** 2 + Mtp ** 2) ev_focalmechanism = FocalMechanism() ev_focalmechanism.moment_tensor = ev_momenttensor ev_focalmechanism.nodal_planes = NodalPlanes().setdefault(0, 0) ev.focal_mechanisms.append(ev_focalmechanism) # populate event magnitude ev_magnitude = Magnitude() ev_magnitude.mag = 0.667 * (np.log10(ev_momenttensor.scalar_moment) - 9.1) ev_magnitude.magnitude_type = 'Mw' ev.magnitudes.append(ev_magnitude) # write QuakeML file cat = Catalog() cat.append(ev) cat.write(QuakeML_filename, format="quakeml") # clean up fid.close()
def build(self): """ Build an obspy moment tensor focal mech event This makes the tensor output into an Event containing: 1) a FocalMechanism with a MomentTensor, NodalPlanes, and PrincipalAxes 2) a Magnitude of the Mw from the Tensor Which is what we want for outputting QuakeML using the (slightly modified) obspy code. Input ----- filehandle => open file OR str from filehandle.read() Output ------ event => instance of Event() class as described above """ p = self.parser event = Event(event_type='earthquake') origin = Origin() focal_mech = FocalMechanism() nodal_planes = NodalPlanes() moment_tensor = MomentTensor() principal_ax = PrincipalAxes() magnitude = Magnitude() data_used = DataUsed() creation_info = CreationInfo(agency_id='NN') ev_mode = 'automatic' ev_stat = 'preliminary' evid = None orid = None # Parse the entire file line by line. for n,l in enumerate(p.line): if 'REVIEWED BY NSL STAFF' in l: ev_mode = 'manual' ev_stat = 'reviewed' if 'Event ID' in l: evid = p._id(n) if 'Origin ID' in l: orid = p._id(n) if 'Ichinose' in l: moment_tensor.category = 'regional' if re.match(r'^\d{4}\/\d{2}\/\d{2}', l): ev = p._event_info(n) if 'Depth' in l: derived_depth = p._depth(n) if 'Mw' in l: magnitude.mag = p._mw(n) magnitude.magnitude_type = 'Mw' if 'Mo' in l and 'dyne' in l: moment_tensor.scalar_moment = p._mo(n) if 'Percent Double Couple' in l: moment_tensor.double_couple = p._percent(n) if 'Percent CLVD' in l: moment_tensor.clvd = p._percent(n) if 'Epsilon' in l: moment_tensor.variance = p._epsilon(n) if 'Percent Variance Reduction' in l: moment_tensor.variance_reduction = p._percent(n) if 'Major Double Couple' in l and 'strike' in p.line[n+1]: np = p._double_couple(n) nodal_planes.nodal_plane_1 = NodalPlane(*np[0]) nodal_planes.nodal_plane_2 = NodalPlane(*np[1]) nodal_planes.preferred_plane = 1 if 'Spherical Coordinates' in l: mt = p._mt_sphere(n) moment_tensor.tensor = Tensor( m_rr = mt['Mrr'], m_tt = mt['Mtt'], m_pp = mt['Mff'], m_rt = mt['Mrt'], m_rp = mt['Mrf'], m_tp = mt['Mtf'], ) if 'Eigenvalues and eigenvectors of the Major Double Couple' in l: ax = p._vectors(n) principal_ax.t_axis = Axis(ax['T']['trend'], ax['T']['plunge'], ax['T']['ev']) principal_ax.p_axis = Axis(ax['P']['trend'], ax['P']['plunge'], ax['P']['ev']) principal_ax.n_axis = Axis(ax['N']['trend'], ax['N']['plunge'], ax['N']['ev']) if 'Number of Stations' in l: data_used.station_count = p._number_of_stations(n) if 'Maximum' in l and 'Gap' in l: focal_mech.azimuthal_gap = p._gap(n) if re.match(r'^Date', l): creation_info.creation_time = p._creation_time(n) # Creation Time creation_info.version = orid # Fill in magnitude values magnitude.evaluation_mode = ev_mode magnitude.evaluation_status = ev_stat magnitude.creation_info = creation_info.copy() magnitude.resource_id = self._rid(magnitude) # Stub origin origin.time = ev.get('time') origin.latitude = ev.get('lat') origin.longitude = ev.get('lon') origin.depth = derived_depth * 1000. origin.depth_type = "from moment tensor inversion" origin.creation_info = creation_info.copy() # Unique from true origin ID _oid = self._rid(origin) origin.resource_id = ResourceIdentifier(str(_oid) + '/mt') del _oid # Make an id for the MT that references this origin ogid = str(origin.resource_id) doid = ResourceIdentifier(ogid, referred_object=origin) # Make an id for the moment tensor mag which references this mag mrid = str(magnitude.resource_id) mmid = ResourceIdentifier(mrid, referred_object=magnitude) # MT todo: could check/use URL for RID if parsing the php file moment_tensor.evaluation_mode = ev_mode moment_tensor.evaluation_status = ev_stat moment_tensor.data_used = data_used moment_tensor.moment_magnitude_id = mmid moment_tensor.derived_origin_id = doid moment_tensor.creation_info = creation_info.copy() moment_tensor.resource_id = self._rid(moment_tensor) # Fill in focal_mech values focal_mech.nodal_planes = nodal_planes focal_mech.moment_tensor = moment_tensor focal_mech.principal_axes = principal_ax focal_mech.creation_info = creation_info.copy() focal_mech.resource_id = self._rid(focal_mech) # add mech and new magnitude to event event.focal_mechanisms = [focal_mech] event.magnitudes = [magnitude] event.origins = [origin] event.creation_info = creation_info.copy() # If an MT was done, that's the preferred mag/mech event.preferred_magnitude_id = str(magnitude.resource_id) event.preferred_focal_mechanism_id = str(focal_mech.resource_id) if evid: event.creation_info.version = evid event.resource_id = self._rid(event) self.event = event