Пример #1
0
    def __init__(self, sta, event, gacmin=5., gacmax=30., depmax=1000.):

        from obspy.geodetics.base import gps2dist_azimuth as epi
        from obspy.geodetics import kilometer2degrees as k2d

        # Extract event 4D parameters
        self.time = event.origins[0].time
        self.lon = event.origins[0].longitude
        self.lat = event.origins[0].latitude
        self.dep = event.origins[0].depth

        # Check if depth is valid type
        if self.dep is not None:
            if self.dep > 1000.:
                self.dep = self.dep / 1000.
        else:
            self.dep = 10.

        # Magnitude
        self.mag = event.magnitudes[0].mag
        if self.mag is None:
            self.mag = -9.

        # Calculate epicentral distance
        self.epi_dist, self.az, self.baz = epi(self.lat, self.lon,
                                               sta.latitude, sta.longitude)
        self.epi_dist /= 1000
        self.gac = k2d(self.epi_dist)

        if self.gac > gacmin and self.gac < gacmax and self.dep < depmax:
            self.accept = True
        else:
            self.accept = False
Пример #2
0
    def __init__(self, sta, event, gacmin=30., gacmax=90.):

        from obspy.geodetics.base import gps2dist_azimuth as epi
        from obspy.geodetics import kilometer2degrees as k2d
        from obspy.taup import TauPyModel

        # Extract event 4D parameters
        self.time = event.origins[0].time
        self.lon = event.origins[0].longitude
        self.lat = event.origins[0].latitude
        self.dep = event.origins[0].depth

        # Check if depth is valid type
        if self.dep is not None:
            if self.dep > 1000.:
                self.dep = self.dep / 1000.
        else:
            self.dep = 10.

        # Magnitude
        self.mag = event.magnitudes[0].mag
        if self.mag is None:
            self.mag = -9.

        # Calculate epicentral distance
        self.epi_dist, self.az, self.baz = epi(self.lat, self.lon,
                                               sta.latitude, sta.longitude)
        self.epi_dist /= 1000
        self.gac = k2d(self.epi_dist)

        if self.gac > 30. and self.gac < 90.:

            # Get travel time info
            tpmodel = TauPyModel()

            # Get Travel times (Careful: here dep is in meters)
            arrivals = tpmodel.get_travel_times(distance_in_degree=self.gac,
                                                source_depth_in_km=self.dep /
                                                1000.,
                                                phase_list=["P"])
            if len(arrivals) > 1:
                print("arrival has many entries:" + len(arrivals))
            arrival = arrivals[0]

            # Attributes from parameters
            self.ttime = arrival.time
            self.ph = arrival.name
            self.slow = arrival.ray_param_sec_degree / 111.
            self.inc = arrival.incident_angle
            self.accept = True
        else:
            self.ttime = None
            self.ph = None
            self.slow = None
            self.inc = None
            self.accept = False

        # Defaults for non - station-event geometry attributes
        self.vp = 6.0
        self.vs = 3.6
        self.align = 'ZRT'

        # Attributes that get updated as analysis progresses
        self.rotated = False
        self.snr = None
Пример #3
0
    def __init__(self, sta, event, gacmin=85., gacmax=120., phase='SKS',
                 maxdt=4., ddt=0.1, dphi=1.):

        from obspy.geodetics.base import gps2dist_azimuth as epi
        from obspy.geodetics import kilometer2degrees as k2d
        from obspy.taup import TauPyModel

        # Extract event 4D parameters
        self.time = event.origins[0].time
        self.lon = event.origins[0].longitude
        self.lat = event.origins[0].latitude
        self.dep = event.origins[0].depth

        # Check if depth is valid type
        if self.dep is not None:
            if self.dep > 1000.:
                self.dep = self.dep/1000.
        else:
            self.dep = 10.

        # Magnitude
        self.mag = event.magnitudes[0].mag
        if self.mag is None:
            self.mag = -9.

        # Calculate epicentral distance
        self.epi_dist, self.az, self.baz = epi(
            self.lat, self.lon, sta.latitude, sta.longitude)
        self.epi_dist /= 1000
        self.gac = k2d(self.epi_dist)

        if self.gac > gacmin and self.gac < gacmax:

            # Get travel time info
            tpmodel = TauPyModel(model='iasp91')

            # Get Travel times (Careful: here dep is in meters)
            arrivals = tpmodel.get_travel_times(
                distance_in_degree=self.gac,
                source_depth_in_km=self.dep,
                phase_list=[phase])
            if len(arrivals) > 1:
                print("arrival has many entries: ", len(arrivals))
            elif len(arrivals) == 0:
                print("no arrival found")
                self.accept = False
                return

            arrival = arrivals[0]

            # Attributes from parameters
            self.ttime = arrival.time
            self.slow = arrival.ray_param_sec_degree/111.
            self.inc = arrival.incident_angle
            self.phase = phase
            self.accept = True
        else:
            self.ttime = None
            self.slow = None
            self.inc = None
            self.phase = None
            self.accept = False

        # Attributes that get updated as analysis progresses
        self.snrq = None
        self.snrt = None
        self.maxdt = maxdt
        self.ddt = ddt
        self.dphi = dphi
        self.align = 'LQT'
        self.rotated = False
def main(args=None):

    if args is None:
        # Run Input Parser
        args = get_event_arguments()

    # Load Database
    # stdb>0.1.3
    try:
        db, stkeys = stdb.io.load_db(fname=args.indb, keys=args.stkeys)

    # stdb=0.1.3
    except:
        db = stdb.io.load_db(fname=args.indb)

        # Construct station key loop
        allkeys = db.keys()
        sorted(allkeys)

        # Extract key subset
        if len(args.stkeys) > 0:
            stkeys = []
            for skey in args.stkeys:
                stkeys.extend([s for s in allkeys if skey in s])
        else:
            stkeys = db.keys()
            sorted(stkeys)

    # Loop over station keys
    for stkey in list(stkeys):

        # Extract station information from dictionary
        sta = db[stkey]

        # Define path to see if it exists
        eventpath = Path('EVENTS') / Path(stkey)
        if not eventpath.is_dir():
            print('Path to ' + str(eventpath) + ' doesn`t exist - creating it')
            eventpath.mkdir(parents=True)

        # Establish client
        if len(args.UserAuth) == 0:
            client = Client(args.Server)
        else:
            client = Client(args.Server,
                            user=args.UserAuth[0],
                            password=args.UserAuth[1])

        # Get catalogue search start time
        if args.startT is None:
            tstart = sta.startdate
        else:
            tstart = args.startT

        # Get catalogue search end time
        if args.endT is None:
            tend = sta.enddate
        else:
            tend = args.endT
        if tstart > sta.enddate or tend < sta.startdate:
            continue

        # Temporary print locations
        tlocs = sta.location
        if len(tlocs) == 0:
            tlocs = ['']
        for il in range(0, len(tlocs)):
            if len(tlocs[il]) == 0:
                tlocs[il] = "--"
        sta.location = tlocs

        # Update Display
        print(" ")
        print(" ")
        print("|===============================================|")
        print("|===============================================|")
        print("|                   {0:>8s}                    |".format(
            sta.station))
        print("|===============================================|")
        print("|===============================================|")
        print("|  Station: {0:>2s}.{1:5s}                            |".format(
            sta.network, sta.station))
        print("|      Channel: {0:2s}; Locations: {1:15s}  |".format(
            sta.channel, ",".join(tlocs)))
        print("|      Lon: {0:7.2f}; Lat: {1:6.2f}                |".format(
            sta.longitude, sta.latitude))
        print("|      Start time: {0:19s}          |".format(
            sta.startdate.strftime("%Y-%m-%d %H:%M:%S")))
        print("|      End time:   {0:19s}          |".format(
            sta.enddate.strftime("%Y-%m-%d %H:%M:%S")))
        print("|-----------------------------------------------|")
        print("| Searching Possible events:                    |")
        print("|   Start: {0:19s}                  |".format(
            tstart.strftime("%Y-%m-%d %H:%M:%S")))
        print("|   End:   {0:19s}                  |".format(
            tend.strftime("%Y-%m-%d %H:%M:%S")))
        if args.maxmag is None:
            print("|   Mag:   >{0:3.1f}".format(args.minmag) +
                  "                                 |")
        else:
            print("|   Mag:   {0:3.1f} - {1:3.1f}".format(
                args.minmag, args.maxmag) + "                            |")
        print("| ...                                           |")

        # Get catalogue using deployment start and end
        cat = client.get_events(starttime=tstart,
                                endtime=tend,
                                minmagnitude=args.minmag,
                                maxmagnitude=args.maxmag)

        # Total number of events in Catalogue
        nevK = 0
        nevtT = len(cat)
        print("|  Found {0:5d}".format(nevtT) +
              " possible events                  |")
        ievs = range(0, nevtT)

        # Select order of processing
        if args.reverse:
            ievs = range(0, nevtT)
        else:
            ievs = range(nevtT - 1, -1, -1)

        # Read through catalogue
        for iev in ievs:

            # Extract event
            ev = cat[iev]

            window = 7200.
            new_sampling_rate = 5.

            time = ev.origins[0].time
            dep = ev.origins[0].depth
            lon = ev.origins[0].longitude
            lat = ev.origins[0].latitude
            epi_dist, az, baz = epi(lat, lon, sta.latitude, sta.longitude)
            epi_dist /= 1000.
            gac = k2d(epi_dist)
            mag = ev.magnitudes[0].mag
            if mag is None:
                mag = -9.

            # If distance between 85 and 120 deg:
            if (gac > args.mindist and gac < args.maxdist):

                # Display Event Info
                nevK = nevK + 1
                if args.reverse:
                    inum = iev + 1
                else:
                    inum = nevtT - iev + 1
                print(" ")
                print("****************************************************")
                print("* #{0:d} ({1:d}/{2:d}):  {3:13s}".format(
                    nevK, inum, nevtT, time.strftime("%Y%m%d_%H%M%S")))
                print("*   Origin Time: " + time.strftime("%Y-%m-%d %H:%M:%S"))
                print("*   Lat: {0:6.2f}; Lon: {1:7.2f}".format(lat, lon))
                print("*   Dep: {0:6.2f}; Mag: {1:3.1f}".format(
                    dep / 1000., mag))
                print("*   Dist: {0:7.2f} km; {1:7.2f} deg".format(
                    epi_dist, gac))

                t1 = time
                t2 = t1 + window

                # Time stamp
                tstamp = str(time.year).zfill(4)+'.' + \
                    str(time.julday).zfill(3)+'.'
                tstamp = tstamp + str(time.hour).zfill(2) + \
                    '.'+str(time.minute).zfill(2)

                # Define file names (to check if files already exist)
                filename = eventpath / (tstamp + '.event.pkl')
                file1 = eventpath / (tstamp + '.1.SAC')
                file2 = eventpath / (tstamp + '.2.SAC')
                fileZ = eventpath / (tstamp + '.Z.SAC')
                fileP = eventpath / (tstamp + '.P.SAC')

                print()
                print("* Channels selected: " + str(args.channels) +
                      ' and vertical')

                # If data file exists, continue
                if filename.exists():
                    if not args.ovr:
                        print("*")
                        print("*   " + str(filename))
                        print("*   -> File already exists, continuing")
                        continue

                if "P" not in args.channels:

                    # Number of channels
                    ncomp = 3

                    # Comma-separated list of channels for Client
                    channels = sta.channel.upper() + '1,' + \
                        sta.channel.upper() + '2,' + \
                        sta.channel.upper() + 'Z'

                    # Get waveforms from client
                    try:
                        print("*   " + tstamp +
                              "                                     ")
                        print("*   -> Downloading Seismic data... ")
                        sth = client.get_waveforms(network=sta.network,
                                                   station=sta.station,
                                                   location=sta.location[0],
                                                   channel=channels,
                                                   starttime=t1,
                                                   endtime=t2,
                                                   attach_response=True)
                        print("*      ...done")
                    except:
                        print(" Error: Unable to download ?H? components - " +
                              "continuing")
                        continue

                    st = sth

                elif "H" not in args.channels:

                    # Number of channels
                    ncomp = 2

                    # Comma-separated list of channels for Client
                    channels = sta.channel.upper() + 'Z'

                    # Get waveforms from client
                    try:
                        print("*   " + tstamp +
                              "                                     ")
                        print("*   -> Downloading Seismic data... ")
                        sth = client.get_waveforms(network=sta.network,
                                                   station=sta.station,
                                                   location=sta.location[0],
                                                   channel=channels,
                                                   starttime=t1,
                                                   endtime=t2,
                                                   attach_response=True)
                        print("*      ...done")
                    except:
                        print(" Error: Unable to download ?H? components - " +
                              "continuing")
                        continue
                    try:
                        print("*   -> Downloading Pressure data...")
                        stp = client.get_waveforms(network=sta.network,
                                                   station=sta.station,
                                                   location=sta.location[0],
                                                   channel='?DH',
                                                   starttime=t1,
                                                   endtime=t2,
                                                   attach_response=True)
                        print("*      ...done")
                        if len(stp) > 1:
                            print("WARNING: There are more than one ?DH trace")
                            print("*   -> Keeping the highest sampling rate")
                            if stp[0].stats.sampling_rate > \
                                    stp[1].stats.sampling_rate:
                                stp = Stream(traces=stp[0])
                            else:
                                stp = Stream(traces=stp[1])
                    except:
                        print(" Error: Unable to download ?DH component - " +
                              "continuing")
                        continue

                    st = sth + stp

                else:

                    # Comma-separated list of channels for Client
                    ncomp = 4

                    # Comma-separated list of channels for Client
                    channels = sta.channel.upper() + '1,' + \
                        sta.channel.upper() + '2,' + \
                        sta.channel.upper() + 'Z'

                    # Get waveforms from client
                    try:
                        print("*   " + tstamp +
                              "                                     ")
                        print("*   -> Downloading Seismic data... ")
                        sth = client.get_waveforms(network=sta.network,
                                                   station=sta.station,
                                                   location=sta.location[0],
                                                   channel=channels,
                                                   starttime=t1,
                                                   endtime=t2,
                                                   attach_response=True)
                        print("*      ...done")
                    except:
                        print(" Error: Unable to download ?H? components - " +
                              "continuing")
                        continue
                    try:
                        print("*   -> Downloading Pressure data...")
                        stp = client.get_waveforms(network=sta.network,
                                                   station=sta.station,
                                                   location=sta.location[0],
                                                   channel='?DH',
                                                   starttime=t1,
                                                   endtime=t2,
                                                   attach_response=True)
                        print("     ...done")
                        if len(stp) > 1:
                            print("WARNING: There are more than one ?DH trace")
                            print("*   -> Keeping the highest sampling rate")
                            if stp[0].stats.sampling_rate > \
                                    stp[1].stats.sampling_rate:
                                stp = Stream(traces=stp[0])
                            else:
                                stp = Stream(traces=stp[1])
                    except:
                        print(" Error: Unable to download ?DH component - " +
                              "continuing")
                        continue

                    st = sth + stp

                # Detrend, filter
                st.detrend('demean')
                st.detrend('linear')
                st.filter('lowpass',
                          freq=0.5 * args.new_sampling_rate,
                          corners=2,
                          zerophase=True)
                st.resample(args.new_sampling_rate)

                # Check streams
                is_ok, st = utils.QC_streams(t1, t2, st)
                if not is_ok:
                    continue

                sth = st.select(component='1') + st.select(component='2') + \
                    st.select(component='Z')

                # Remove responses
                print("*   -> Removing responses - Seismic data")
                sth.remove_response(pre_filt=args.pre_filt, output=args.units)

                # Extract traces - Z
                trZ = sth.select(component='Z')[0]
                trZ = utils.update_stats(trZ, sta.latitude, sta.longitude,
                                         sta.elevation, 'Z')
                trZ.write(str(fileZ), format='SAC')

                # Extract traces - H
                if "H" in args.channels:
                    tr1 = sth.select(component='1')[0]
                    tr2 = sth.select(component='2')[0]
                    tr1 = utils.update_stats(tr1, sta.latitude, sta.longitude,
                                             sta.elevation, '1')
                    tr2 = utils.update_stats(tr2, sta.latitude, sta.longitude,
                                             sta.elevation, '2')
                    tr1.write(str(file1), format='SAC')
                    tr2.write(str(file2), format='SAC')

                if "P" in args.channels:
                    stp = st.select(component='H')
                    print("*   -> Removing responses - Pressure data")
                    stp.remove_response(pre_filt=args.pre_filt)
                    trP = stp[0]
                    trP = utils.update_stats(trP, sta.latitude, sta.longitude,
                                             sta.elevation, 'P')
                    trP.write(str(fileP), format='SAC')

                else:
                    stp = Stream()

                # Write out SAC data

                eventstream = EventStream(sta, sth, stp, tstamp, lat, lon,
                                          time, window, args.new_sampling_rate,
                                          ncomp)

                eventstream.save(filename)
Пример #5
0
def main():

    # Run Input Parser
    (opts, indb) = options.get_event_options()

    # Load Database
    db = stdb.io.load_db(fname=indb)

    # Construct station key loop
    allkeys = db.keys()
    sorted(allkeys)

    # Extract key subset
    if len(opts.stkeys) > 0:
        stkeys = []
        for skey in opts.stkeys:
            stkeys.extend([s for s in allkeys if skey in s])
    else:
        stkeys = db.keys()
        sorted(stkeys)

    # Loop over station keys
    for stkey in list(stkeys):

        # Extract station information from dictionary
        sta = db[stkey]

        # Define path to see if it exists
        eventpath = 'EVENTS/' + stkey + '/'
        if not os.path.isdir(eventpath):
            print('Path to ' + eventpath + ' doesn`t exist - creating it')
            os.makedirs(eventpath)

        # Establish client
        if len(opts.UserAuth) == 0:
            client = Client(opts.Server)
        else:
            client = Client(opts.Server,
                            user=opts.UserAuth[0],
                            password=opts.UserAuth[1])

        # Get catalogue search start time
        if opts.startT is None:
            tstart = sta.startdate
        else:
            tstart = opts.startT

        # Get catalogue search end time
        if opts.endT is None:
            tend = sta.enddate
        else:
            tend = opts.endT
        if tstart > sta.enddate or tend < sta.startdate:
            continue

        # Temporary print locations
        tlocs = sta.location
        if len(tlocs) == 0:
            tlocs = ['']
        for il in range(0, len(tlocs)):
            if len(tlocs[il]) == 0:
                tlocs[il] = "--"
        sta.location = tlocs

        # Update Display
        print(" ")
        print(" ")
        print("|===============================================|")
        print("|===============================================|")
        print("|                   {0:>8s}                    |".format(
            sta.station))
        print("|===============================================|")
        print("|===============================================|")
        print("|  Station: {0:>2s}.{1:5s}                            |".format(
            sta.network, sta.station))
        print("|      Channel: {0:2s}; Locations: {1:15s}  |".format(
            sta.channel, ",".join(tlocs)))
        print("|      Lon: {0:7.2f}; Lat: {1:6.2f}                |".format(
            sta.longitude, sta.latitude))
        print("|      Start time: {0:19s}          |".format(
            sta.startdate.strftime("%Y-%m-%d %H:%M:%S")))
        print("|      End time:   {0:19s}          |".format(
            sta.enddate.strftime("%Y-%m-%d %H:%M:%S")))
        print("|-----------------------------------------------|")
        print("| Searching Possible events:                    |")
        print("|   Start: {0:19s}                  |".format(
            tstart.strftime("%Y-%m-%d %H:%M:%S")))
        print("|   End:   {0:19s}                  |".format(
            tend.strftime("%Y-%m-%d %H:%M:%S")))
        if opts.maxmag is None:
            print("|   Mag:   >{0:3.1f}                                 " +
                  "|".format(opts.minmag))
        else:
            print("|   Mag:   {0:3.1f} - {1:3.1f}                         " +
                  "   |".format(opts.minmag, opts.maxmag))
        print("| ...                                           |")

        # Get catalogue using deployment start and end
        cat = client.get_events(starttime=tstart,
                                endtime=tend,
                                minmagnitude=opts.minmag,
                                maxmagnitude=opts.maxmag)

        # Total number of events in Catalogue
        nevK = 0
        nevtT = len(cat)
        print("|  Found {0:5d} possible events                  " +
              "|".format(nevtT))
        ievs = range(0, nevtT)

        # Select order of processing
        if opts.reverse:
            ievs = range(0, nevtT)
        else:
            ievs = range(nevtT - 1, -1, -1)

        # Read through catalogue
        for iev in ievs:

            # Extract event
            ev = cat[iev]

            window = 7200.
            new_sampling_rate = 5.

            time = ev.origins[0].time
            dep = ev.origins[0].depth
            lon = ev.origins[0].longitude
            lat = ev.origins[0].latitude
            epi_dist, az, baz = epi(lat, lon, sta.latitude, sta.longitude)
            epi_dist /= 1000.
            gac = k2d(epi_dist)
            mag = ev.magnitudes[0].mag
            if mag is None:
                mag = -9.

            # If distance between 85 and 120 deg:
            if (gac > opts.mindist and gac < opts.maxdist):

                # Display Event Info
                nevK = nevK + 1
                if opts.reverse:
                    inum = iev + 1
                else:
                    inum = nevtT - iev + 1
                print(" ")
                print("****************************************************")
                print("* #{0:d} ({1:d}/{2:d}):  {3:13s}".format(
                    nevK, inum, nevtT, time.strftime("%Y%m%d_%H%M%S")))
                print("*   Origin Time: " + time.strftime("%Y-%m-%d %H:%M:%S"))
                print("*   Lat: {0:6.2f}; Lon: {1:7.2f}".format(lat, lon))
                print("*   Dep: {0:6.2f}; Mag: {1:3.1f}".format(
                    dep / 1000., mag))
                print("*     {0:5s} -> Ev: {1:7.2f} km; {2:7.2f} deg; " +
                      "{3:6.2f}; {4:6.2f}".format(sta.station, epi_dist, gac,
                                                  baz, az))

                t1 = time
                t2 = t1 + window

                # Time stamp
                tstamp = str(time.year).zfill(4)+'.' + \
                    str(time.julday).zfill(3)+'.'
                tstamp = tstamp + str(time.hour).zfill(2) + \
                    '.'+str(time.minute).zfill(2)

                # Define file names (to check if files already exist)
                filename = eventpath + tstamp + '.event.pkl'

                print()
                print("* Channels selected: " + str(opts.channels) +
                      ' and vertical')

                # If data file exists, continue
                if glob.glob(filename):
                    if not opts.ovr:
                        print("*")
                        print("*   " + filename)
                        print("*   -> File already exists, continuing")
                        continue

                if "P" not in opts.channels:

                    # Number of channels
                    ncomp = 3

                    # Comma-separated list of channels for Client
                    channels = sta.channel.upper() + '1,' + \
                        sta.channel.upper() + '2,' + \
                        sta.channel.upper() + 'Z'

                    # Get waveforms from client
                    try:
                        print("*   " + tstamp +
                              "                                     ")
                        print("*   -> Downloading Seismic data... ")
                        sth = client.get_waveforms(network=sta.network,
                                                   station=sta.station,
                                                   location=sta.location[0],
                                                   channel=channels,
                                                   starttime=t1,
                                                   endtime=t2,
                                                   attach_response=True)
                        print("*      ...done")
                    except:
                        print(" Error: Unable to download ?H? components - " +
                              "continuing")
                        continue

                    # Make sure length is ok
                    llZ = len(sth.select(component='Z')[0].data)
                    ll1 = len(sth.select(component='1')[0].data)
                    ll2 = len(sth.select(component='2')[0].data)

                    if (llZ != ll1) or (llZ != ll2):
                        print(" Error: lengths not all the same - continuing")
                        continue

                    ll = int(window * sth[0].stats.sampling_rate)

                    if np.abs(llZ - ll) > 1:
                        print(" Error: Time series too short - continuing")
                        print(np.abs(llZ - ll))
                        continue

                elif "H" not in opts.channels:

                    # Number of channels
                    ncomp = 2

                    # Comma-separated list of channels for Client
                    channels = sta.channel.upper() + 'Z'

                    # Get waveforms from client
                    try:
                        print("*   " + tstamp +
                              "                                     ")
                        print("*   -> Downloading Seismic data... ")
                        sth = client.get_waveforms(network=sta.network,
                                                   station=sta.station,
                                                   location=sta.location[0],
                                                   channel=channels,
                                                   starttime=t1,
                                                   endtime=t2,
                                                   attach_response=True)
                        print("*      ...done")
                    except:
                        print(" Error: Unable to download ?H? components - " +
                              "continuing")
                        continue
                    try:
                        print("*   -> Downloading Pressure data...")
                        stp = client.get_waveforms(network=sta.network,
                                                   station=sta.station,
                                                   location=sta.location[0],
                                                   channel='??H',
                                                   starttime=t1,
                                                   endtime=t2,
                                                   attach_response=True)
                        print("*      ...done")
                    except:
                        print(" Error: Unable to download ??H component - " +
                              "continuing")
                        continue

                    # Make sure length is ok
                    llZ = len(sth.select(component='Z')[0].data)
                    llP = len(stp[0].data)

                    if (llZ != llP):
                        print(" Error: lengths not all the same - continuing")
                        continue

                    ll = int(window * stp[0].stats.sampling_rate)

                    if np.abs(llZ - ll) > 1:
                        print(" Error: Time series too short - continuing")
                        print(np.abs(llZ - ll))
                        continue

                else:

                    # Comma-separated list of channels for Client
                    ncomp = 4

                    # Comma-separated list of channels for Client
                    channels = sta.channel.upper() + '1,' + \
                        sta.channel.upper() + '2,' + \
                        sta.channel.upper() + 'Z'

                    # Get waveforms from client
                    try:
                        print("*   " + tstamp +
                              "                                     ")
                        print("*   -> Downloading Seismic data... ")
                        sth = client.get_waveforms(network=sta.network,
                                                   station=sta.station,
                                                   location=sta.location[0],
                                                   channel=channels,
                                                   starttime=t1,
                                                   endtime=t2,
                                                   attach_response=True)
                        print("*      ...done")
                    except:
                        print(" Error: Unable to download ?H? components - " +
                              "continuing")
                        continue
                    try:
                        print("*   -> Downloading Pressure data...")
                        stp = client.get_waveforms(network=sta.network,
                                                   station=sta.station,
                                                   location=sta.location[0],
                                                   channel='??H',
                                                   starttime=t1,
                                                   endtime=t2,
                                                   attach_response=True)
                        print("     ...done")
                    except:
                        print(" Error: Unable to download ??H component - " +
                              "continuing")
                        continue

                    # Make sure length is ok
                    llZ = len(sth.select(component='Z')[0].data)
                    ll1 = len(sth.select(component='1')[0].data)
                    ll2 = len(sth.select(component='2')[0].data)
                    llP = len(stp[0].data)

                    if (llZ != ll1) or (llZ != ll2) or (llZ != llP):
                        print(" Error: lengths not all the same - continuing")
                        continue

                    ll = int(window * sth[0].stats.sampling_rate)

                    if np.abs(llZ - ll) > 1:
                        print(" Error: Time series too short - continuing")
                        print(np.abs(llZ - ll))
                        continue

                # Remove responses
                print("*   -> Removing responses - Seismic data")
                sth.remove_response(pre_filt=opts.pre_filt, output='DISP')
                if "P" in opts.channels:
                    print("*   -> Removing responses - Pressure data")
                    stp.remove_response(pre_filt=opts.pre_filt)

                # Detrend, filter - seismic data
                sth.detrend('demean')
                sth.detrend('linear')
                sth.filter('lowpass',
                           freq=0.5 * opts.new_sampling_rate,
                           corners=2,
                           zerophase=True)
                sth.resample(opts.new_sampling_rate)

                if "P" in opts.channels:
                    # Detrend, filter - pressure data
                    stp.detrend('demean')
                    stp.detrend('linear')
                    stp.filter('lowpass',
                               freq=0.5 * opts.new_sampling_rate,
                               corners=2,
                               zerophase=True)
                    stp.resample(opts.new_sampling_rate)
                else:
                    stp = Stream()

                eventstream = EventStream(sta, sth, stp, tstamp, lat, lon,
                                          time, window, opts.new_sampling_rate,
                                          ncomp)

                eventstream.save(filename)