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Merge branch 'develop'

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Sebastian Wehling-Benatelli 2014-12-18 13:36:05 +01:00
commit 6be85efa1f
6 changed files with 199 additions and 35 deletions
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13
QtPyLoT.py
View File

@ -143,18 +143,25 @@ class MainWindow(QMainWindow):
filt = """Supported event formats (*.mat *.qml *.xml *.kor filt = """Supported event formats (*.mat *.qml *.xml *.kor
*.evt)""" *.evt)"""
caption = 'Select event to open' caption = 'Select event to open'
fname = QFileDialog().getOpenFileName(self, caption=caption, self.fname = QFileDialog().getOpenFileName(self, caption=caption,
filter=filt) filter=filt)
else: else:
fname = unicode(action.data().toString()) self.fname = unicode(action.data().toString())
if not self.okToContinue(): if not self.okToContinue():
return return
else: else:
return return
if fname: if fname:
self.data = Data(evtdata=fname) self.fname = fname
self.data = Data(evtdata=self.fname)
def saveData(self): def saveData(self):
settings = QSettings()
exform = settings.value('data/exportFormat', 'None')
try:
self.data.exportEvent(self.fname, exform)
except FormatError:
return False
return True return True
def getComponent(self): def getComponent(self):

70
pylot/core/pick/CharFuns.py
View File

@ -117,8 +117,8 @@ class CharacteristicFunction(object):
def getTimeArray(self): def getTimeArray(self):
if self.getTime1(): if self.getTime1():
incr = self.getARdetStep() incr = self.getARdetStep()[0]
self.TimeArray = np.arange(0, len(self.getCF()) * incr[0], incr[0]) + self.getCut()[0] \ self.TimeArray = np.arange(0, len(self.getCF()) * incr, incr) + self.getCut()[0] \
+ self.getTime1() + self.getTime2() + self.getTime1() + self.getTime2()
else: else:
incr = self.getIncrement() incr = self.getIncrement()
@ -143,18 +143,31 @@ class CharacteristicFunction(object):
cutting window cutting window
''' '''
if cut is not None: if cut is not None:
if self.cut[0] == 0: if len(self.orig_data) == 1:
if self.cut[0] == 0 and self.cut[1] == 0:
start = 0 start = 0
stop = len(self.orig_data[0])
elif self.cut[0] == 0 and self.cut[1] is not 0:
start = 0
stop = self.cut[1] / self.dt
else: else:
start = self.cut[0] / self.dt start = self.cut[0] / self.dt
stop = self.cut[1] / self.dt stop = self.cut[1] / self.dt
if len(self.orig_data) == 1:
zz = self.orig_data.copy() zz = self.orig_data.copy()
z1 = zz[0].copy() z1 = zz[0].copy()
zz[0].data = z1.data[start:stop] zz[0].data = z1.data[start:stop]
data = zz data = zz
return data return data
elif len(self.orig_data) == 2: elif len(self.orig_data) == 2:
if self.cut[0] == 0 and self.cut[1] == 0:
start = 0
stop = min([len(self.orig_data[0]), len(self.orig_data[1])])
elif self.cut[0] == 0 and self.cut[1] is not 0:
start = 0
stop = self.cut[1] / self.dt
else:
start = self.cut[0] / self.dt
stop = self.cut[1] / self.dt
hh = self.orig_data.copy() hh = self.orig_data.copy()
h1 = hh[0].copy() h1 = hh[0].copy()
h2 = hh[1].copy() h2 = hh[1].copy()
@ -163,6 +176,15 @@ class CharacteristicFunction(object):
data = hh data = hh
return data return data
elif len(self.orig_data) == 3: elif len(self.orig_data) == 3:
if self.cut[0] == 0 and self.cut[1] == 0:
start = 0
stop = min([len(self.orig_data[0]), len(self.orig_data[1]), len(self.orig_data[2])])
elif self.cut[0] == 0 and self.cut[1] is not 0:
start = 0
stop = self.cut[1] / self.dt
else:
start = self.cut[0] / self.dt
stop = self.cut[1] / self.dt
hh = self.orig_data.copy() hh = self.orig_data.copy()
h1 = hh[0].copy() h1 = hh[0].copy()
h2 = hh[1].copy() h2 = hh[1].copy()
@ -195,6 +217,9 @@ class AICcf(CharacteristicFunction):
print 'Calculating AIC ...' print 'Calculating AIC ...'
x = self.getDataArray() x = self.getDataArray()
xnp = x[0].data xnp = x[0].data
nn = np.isnan(xnp)
if len(nn) > 1:
xnp[nn] = 0
datlen = len(xnp) datlen = len(xnp)
k = np.arange(1, datlen) k = np.arange(1, datlen)
cf = np.zeros(datlen) cf = np.zeros(datlen)
@ -224,6 +249,9 @@ class HOScf(CharacteristicFunction):
x = self.getDataArray(self.getCut()) x = self.getDataArray(self.getCut())
xnp =x[0].data xnp =x[0].data
nn = np.isnan(xnp)
if len(nn) > 1:
xnp[nn] = 0
if self.getOrder() == 3: # this is skewness if self.getOrder() == 3: # this is skewness
print 'Calculating skewness ...' print 'Calculating skewness ...'
y = np.power(xnp, 3) y = np.power(xnp, 3)
@ -256,6 +284,9 @@ class HOScf(CharacteristicFunction):
elif self.getOrder() == 4: elif self.getOrder() == 4:
LTA[j] = lta / np.power(lta1, 2) LTA[j] = lta / np.power(lta1, 2)
nn = np.isnan(LTA)
if len(nn) > 1:
LTA[nn] = 0
self.cf = LTA self.cf = LTA
@ -266,6 +297,9 @@ class ARZcf(CharacteristicFunction):
print 'Calculating AR-prediction error from single trace ...' print 'Calculating AR-prediction error from single trace ...'
x = self.getDataArray(self.getCut()) x = self.getDataArray(self.getCut())
xnp = x[0].data xnp = x[0].data
nn = np.isnan(xnp)
if len(nn) > 1:
xnp[nn] = 0
#some parameters needed #some parameters needed
#add noise to time series #add noise to time series
xnoise = xnp + np.random.normal(0.0, 1.0, len(xnp)) * self.getFnoise() * max(abs(xnp)) xnoise = xnp + np.random.normal(0.0, 1.0, len(xnp)) * self.getFnoise() * max(abs(xnp))
@ -288,6 +322,9 @@ class ARZcf(CharacteristicFunction):
#convert list to numpy array #convert list to numpy array
cf = np.asarray(cf) cf = np.asarray(cf)
nn = np.isnan(cf)
if len(nn) > 1:
cf[nn] = 0
self.cf = cf self.cf = cf
@ -376,6 +413,12 @@ class ARHcf(CharacteristicFunction):
print 'Calculating AR-prediction error from both horizontal traces ...' print 'Calculating AR-prediction error from both horizontal traces ...'
xnp = self.getDataArray(self.getCut()) xnp = self.getDataArray(self.getCut())
n0 = np.isnan(xnp[0].data)
if len(n0) > 1:
xnp[0].data[n0] = 0
n1 = np.isnan(xnp[1].data)
if len(n1) > 1:
xnp[1].data[n1] = 0
#some parameters needed #some parameters needed
#add noise to time series #add noise to time series
@ -390,7 +433,7 @@ class ARHcf(CharacteristicFunction):
cf = [] cf = []
loopstep = self.getARdetStep() loopstep = self.getARdetStep()
for i in range(ldet + self.getOrder() - 3, tend - lpred + 1, loopstep[1]): for i in range(ldet + self.getOrder() - 1, tend - lpred + 1, loopstep[1]):
self.arDetH(Xnoise, self.getOrder(), i-ldet, i) self.arDetH(Xnoise, self.getOrder(), i-ldet, i)
#AR prediction of waveform using calculated AR coefficients #AR prediction of waveform using calculated AR coefficients
self.arPredH(xnp, self.arpara, i + 1, lpred) self.arPredH(xnp, self.arpara, i + 1, lpred)
@ -401,6 +444,9 @@ class ARHcf(CharacteristicFunction):
#convert list to numpy array #convert list to numpy array
cf = np.asarray(cf) cf = np.asarray(cf)
nn = np.isnan(cf)
if len(nn) > 1:
cf[nn] = 0
self.cf = cf self.cf = cf
def arDetH(self, data, order, rind, ldet): def arDetH(self, data, order, rind, ldet):
@ -493,6 +539,15 @@ class AR3Ccf(CharacteristicFunction):
print 'Calculating AR-prediction error from all 3 components ...' print 'Calculating AR-prediction error from all 3 components ...'
xnp = self.getDataArray(self.getCut()) xnp = self.getDataArray(self.getCut())
n0 = np.isnan(xnp[0].data)
if len(n0) > 1:
xnp[0].data[n0] = 0
n1 = np.isnan(xnp[1].data)
if len(n1) > 1:
xnp[1].data[n1] = 0
n2 = np.isnan(xnp[2].data)
if len(n2) > 1:
xnp[2].data[n2] = 0
#some parameters needed #some parameters needed
#add noise to time series #add noise to time series
@ -508,7 +563,7 @@ class AR3Ccf(CharacteristicFunction):
cf = [] cf = []
loopstep = self.getARdetStep() loopstep = self.getARdetStep()
for i in range(ldet + self.getOrder() - 3, tend - lpred + 1, loopstep[1]): for i in range(ldet + self.getOrder() - 1, tend - lpred + 1, loopstep[1]):
self.arDet3C(Xnoise, self.getOrder(), i-ldet, i) self.arDet3C(Xnoise, self.getOrder(), i-ldet, i)
#AR prediction of waveform using calculated AR coefficients #AR prediction of waveform using calculated AR coefficients
self.arPred3C(xnp, self.arpara, i + 1, lpred) self.arPred3C(xnp, self.arpara, i + 1, lpred)
@ -520,6 +575,9 @@ class AR3Ccf(CharacteristicFunction):
#convert list to numpy array #convert list to numpy array
cf = np.asarray(cf) cf = np.asarray(cf)
nn = np.isnan(cf)
if len(nn) > 1:
cf[nn] = 0
self.cf = cf self.cf = cf
def arDet3C(self, data, order, rind, ldet): def arDet3C(self, data, order, rind, ldet):

116
pylot/core/pick/Picker.py
View File

@ -3,16 +3,16 @@
Created Dec 2014 Created Dec 2014
Implementation of the picking algorithms published and described in: Implementation of the picking algorithms published and described in:
Küperkoch, L., Meier, T., Lee, J., Friederich, W., & Egelados Working Group, 2010: Kueperkoch, L., Meier, T., Lee, J., Friederich, W., & Egelados Working Group, 2010:
Automated determination of P-phase arrival times at regional and local distances Automated determination of P-phase arrival times at regional and local distances
using higher order statistics, Geophys. J. Int., 181, 1159-1170 using higher order statistics, Geophys. J. Int., 181, 1159-1170
Küperkoch, L., Meier, T., Brüstle, A., Lee, J., Friederich, W., & Egelados Kueperkoch, L., Meier, T., Bruestle, A., Lee, J., Friederich, W., & Egelados
Working Group, 2012: Automated determination of S-phase arrival times using Working Group, 2012: Automated determination of S-phase arrival times using
autoregressive prediction: application ot local and regional distances, Geophys. J. Int., autoregressive prediction: application ot local and regional distances, Geophys. J. Int.,
188, 687-702. 188, 687-702.
:author: MAGS2 EP3 working group / Ludger Küperkoch :author: MAGS2 EP3 working group / Ludger Kueperkoch
""" """
import numpy as np import numpy as np
import matplotlib.pyplot as plt import matplotlib.pyplot as plt
@ -23,7 +23,7 @@ class AutoPicking(object):
Superclass of different, automated picking algorithms applied on a CF determined Superclass of different, automated picking algorithms applied on a CF determined
using AIC, HOS, or AR prediction. using AIC, HOS, or AR prediction.
''' '''
def __init__(self, cf, Tslope, aerr, TSNR, PickWindow, peps=None, Tsmooth=None): def __init__(self, cf, Tslope, aerr, TSNR, PickWindow, aus=None, Tsmooth=None, Pick1=None):
''' '''
:param: cf, characteristic function, on which the picking algorithm is applied :param: cf, characteristic function, on which the picking algorithm is applied
:type: `~pylot.core.pick.CharFuns.CharacteristicFunction` object :type: `~pylot.core.pick.CharFuns.CharacteristicFunction` object
@ -41,11 +41,14 @@ class AutoPicking(object):
:param: PickWindow, length of pick window [s] :param: PickWindow, length of pick window [s]
:type: float :type: float
:param: peps, find local minimum at i if aic(i-1)*(1+peps) >= aic(i) :param: aus ("artificial uplift of samples"), find local minimum at i if aic(i-1)*(1+aus) >= aic(i)
:type: float :type: float
:param: Tsmooth, length of moving smoothing window to calculate smoothed CF [s] :param: Tsmooth, length of moving smoothing window to calculate smoothed CF [s]
:type: float :type: float
:param: Pick1, initial (prelimenary) onset time, starting point for PragPicker
:type: float
''' '''
#assert isinstance(cf, CharFuns), "%s is not a CharacteristicFunction object" % str(cf) #assert isinstance(cf, CharFuns), "%s is not a CharacteristicFunction object" % str(cf)
@ -58,8 +61,9 @@ class AutoPicking(object):
self.setaerr(aerr) self.setaerr(aerr)
self.setTSNR(TSNR) self.setTSNR(TSNR)
self.setPickWindow(PickWindow) self.setPickWindow(PickWindow)
self.setpeps(peps) self.setaus(aus)
self.setTsmooth(Tsmooth) self.setTsmooth(Tsmooth)
self.setpick1(Pick1)
self.calcPick() self.calcPick()
def __str__(self): def __str__(self):
@ -68,15 +72,17 @@ class AutoPicking(object):
aerr:\t{aerr}\n aerr:\t{aerr}\n
TSNR:\t\t\t{TSNR}\n TSNR:\t\t\t{TSNR}\n
PickWindow:\t{PickWindow}\n PickWindow:\t{PickWindow}\n
peps:\t{peps}\n aus:\t{aus}\n
Tsmooth:\t{Tsmooth}\n Tsmooth:\t{Tsmooth}\n
Pick1:\t{Pick1}\n
'''.format(name=type(self).__name__, '''.format(name=type(self).__name__,
Tslope=self.getTslope(), Tslope=self.getTslope(),
aerr=self.getaerr(), aerr=self.getaerr(),
TSNR=self.getTSNR(), TSNR=self.getTSNR(),
PickWindow=self.getPickWindow(), PickWindow=self.getPickWindow(),
peps=self.getpeps(), aus=self.getaus(),
Tsmooth=self.getTsmooth()) Tsmooth=self.getTsmooth(),
Pick1=self.getpick1())
def getTslope(self): def getTslope(self):
return self.Tslope return self.Tslope
@ -102,11 +108,11 @@ class AutoPicking(object):
def setPickWindow(self, PickWindow): def setPickWindow(self, PickWindow):
self.PickWindow = PickWindow self.PickWindow = PickWindow
def getpeps(self): def getaus(self):
return self.peps return self.aus
def setpeps(self, peps): def setaus(self, aus):
self.peps = peps self.aus = aus
def setTsmooth(self, Tsmooth): def setTsmooth(self, Tsmooth):
self.Tsmooth = Tsmooth self.Tsmooth = Tsmooth
@ -117,6 +123,12 @@ class AutoPicking(object):
def getpick(self): def getpick(self):
return self.Pick return self.Pick
def getpick1(self):
return self.Pick1
def setpick1(self, Pick1):
self.Pick1 = Pick1
def calcPick(self): def calcPick(self):
self.Pick = None self.Pick = None
@ -128,7 +140,7 @@ class AICPicker(AutoPicking):
def calcPick(self): def calcPick(self):
print 'Get onset (pick) from AIC-CF ...' print 'Get onset time (pick) from AIC-CF ...'
self.Pick = -1 self.Pick = -1
#taper AIC-CF to get rid off side maxima #taper AIC-CF to get rid off side maxima
@ -155,4 +167,78 @@ class PragPicker(AutoPicking):
def calcPick(self): def calcPick(self):
print 'Get onset (pick) from HOS- or AR-CF using pragmatic picking algorithm ...' if self.getpick1() is not None:
print 'Get onset time (pick) from HOS- or AR-CF using pragmatic picking algorithm ...'
self.Pick = -1
#smooth CF
ismooth = round(self.Tsmooth / self.dt);
cfsmooth = np.zeros(len(self.cf))
if len(self.cf) < ismooth:
print 'PragPicker: Tsmooth larger than CF!'
return
else:
for i in range(1, len(self.cf)):
if i > ismooth:
ii1 = i - ismooth;
cfsmooth[i] = cfsmooth[i - 1] + (self.cf[i] - self.cf[ii1]) / ismooth
else:
cfsmooth[i] = np.mean(self.cf[1 : i])
#select picking window
#which is centered around tpick1
ipick = np.where((self.Tcf >= self.getpick1() - self.PickWindow / 2) \
& (self.Tcf <= self.getpick1() + self.PickWindow / 2))
cfipick = self.cf[ipick]
Tcfpick = self.Tcf[ipick]
cfsmoothipick = cfsmooth[ipick]
ipick1 = np.argmin(abs(self.Tcf - self.getpick1()))
cfpick1 = 2 * self.cf[ipick1]
#check trend of CF, i.e. differences of CF and adjust aus regarding this trend
#prominent trend: decrease aus
#flat: use given aus
cfdiff = np.diff(cfipick);
i0diff = np.where(cfdiff > 0)
cfdiff = cfdiff[i0diff]
minaus = min(cfdiff * (1 + self.aus));
aus1 = max([minaus, self.aus]);
#at first we look to the right until the end of the pick window is reached
flagpick_r = 0
flagpick_l = 0
flagpick = 0
lpickwindow = int(round(self.PickWindow / self.dt))
for i in range(max(np.insert(ipick, 0, 2)), min([ipick1 + lpickwindow + 1, len(self.cf) - 1])):
if self.cf[i + 1] > self.cf[i] and self.cf[i - 1] >= self.cf[i]:
if cfsmooth[i - 1] * (1 + aus1) >= cfsmooth[i]:
if cfpick1 >= self.cf[i]:
pick_r = self.Tcf[i]
self.Pick = pick_r
flagpick_l = 1
cfpick_r = self.cf[i]
break
#now we look to the left
for i in range(ipick1, max([ipick1 - lpickwindow + 1, 2]), -1):
if self.cf[i + 1] > self.cf[i] and self.cf[i - 1] >= self.cf[i]:
if cfsmooth[i - 1] * (1 + aus1) >= cfsmooth[i]:
if cfpick1 >= self.cf[i]:
pick_l = self.Tcf[i]
self.Pick = pick_l
flagpick_r = 1
cfpick_l = self.cf[i]
break
#now decide which pick: left or right?
if flagpick_l > 0 and flagpick_r > 0:
if cfpick_l <= cfpick_r:
self.Pick = pick_l
else:
self.Pick = pick_r
else:
self.Pick = -1
print 'PragPicker: No initial onset time given! Check input!'
return

22
pylot/core/pick/run_makeCF.py
View File

@ -19,7 +19,7 @@ def run_makeCF(project, database, event, iplot, station=None):
#parameters for CF calculation #parameters for CF calculation
t2 = 7 #length of moving window for HOS calculation [sec] t2 = 7 #length of moving window for HOS calculation [sec]
p = 4 #order of statistics p = 4 #order of statistics
cuttimes = [10, 40] #start and end time vor CF calculation cuttimes = [5, 40] #start and end time for CF calculation
bpz = [2, 30] #corner frequencies of bandpass filter, vertical component bpz = [2, 30] #corner frequencies of bandpass filter, vertical component
bph = [2, 15] #corner frequencies of bandpass filter, horizontal components bph = [2, 15] #corner frequencies of bandpass filter, horizontal components
tdetz= 1.2 #length of AR-determination window [sec], vertical component tdetz= 1.2 #length of AR-determination window [sec], vertical component
@ -59,9 +59,6 @@ def run_makeCF(project, database, event, iplot, station=None):
#calculate HOS-CF using subclass HOScf of class CharacteristicFunction #calculate HOS-CF using subclass HOScf of class CharacteristicFunction
hoscf = HOScf(st_copy, cuttimes, t2, p) #instance of HOScf hoscf = HOScf(st_copy, cuttimes, t2, p) #instance of HOScf
############################################################## ##############################################################
#get onset time from HOS-CF using class Picker
#hospick = PragPicker(hoscf, 2, 70, [1, 0.5, 0.2], 2, 0.001, 0.2)
##############################################################
#calculate AIC-HOS-CF using subclass AICcf of class CharacteristicFunction #calculate AIC-HOS-CF using subclass AICcf of class CharacteristicFunction
#class needs stream object => build it #class needs stream object => build it
tr_aic = tr_filt.copy() tr_aic = tr_filt.copy()
@ -69,9 +66,12 @@ def run_makeCF(project, database, event, iplot, station=None):
st_copy[0].data = tr_aic.data st_copy[0].data = tr_aic.data
aiccf = AICcf(st_copy, cuttimes, t2) #instance of AICcf aiccf = AICcf(st_copy, cuttimes, t2) #instance of AICcf
############################################################## ##############################################################
#get onset time from AIC-HOS-CF using subclass AICPicker of class AutoPicking #get prelimenary onset time from AIC-HOS-CF using subclass AICPicker of class AutoPicking
aicpick = AICPicker(aiccf, 2, 70, [1, 0.5, 0.2], 3) aicpick = AICPicker(aiccf, 2, 70, [1, 0.5, 0.2], 3)
############################################################## ##############################################################
#get refined onset time from HOS-CF using class Picker
hospick = PragPicker(hoscf, 2, 70, [1, 0.5, 0.2], 2, 0.001, 0.2, aicpick.getpick())
##############################################################
#calculate ARZ-CF using subclass ARZcf of class CharcteristicFunction #calculate ARZ-CF using subclass ARZcf of class CharcteristicFunction
#get stream object of filtered data #get stream object of filtered data
st_copy[0].data = tr_filt.data st_copy[0].data = tr_filt.data
@ -86,6 +86,9 @@ def run_makeCF(project, database, event, iplot, station=None):
############################################################## ##############################################################
#get onset time from AIC-ARZ-CF using subclass AICPicker of class AutoPicking #get onset time from AIC-ARZ-CF using subclass AICPicker of class AutoPicking
aicarzpick = AICPicker(araiccf, 2, 70, [1, 0.5, 0.2], 2) aicarzpick = AICPicker(araiccf, 2, 70, [1, 0.5, 0.2], 2)
##############################################################
#get refined onset time from ARZ-CF using class Picker
arzpick = PragPicker(arzcf, 2, 70, [1, 0.5, 0.2], 2, 0, 0.2, aicarzpick.getpick())
elif not wfzfiles: elif not wfzfiles:
print 'No vertical component data found!' print 'No vertical component data found!'
@ -156,9 +159,15 @@ def run_makeCF(project, database, event, iplot, station=None):
plt.plot([aicpick.getpick(), aicpick.getpick()], [-1, 1], 'b--') plt.plot([aicpick.getpick(), aicpick.getpick()], [-1, 1], 'b--')
plt.plot([aicpick.getpick()-0.5, aicpick.getpick()+0.5], [1, 1], 'b') plt.plot([aicpick.getpick()-0.5, aicpick.getpick()+0.5], [1, 1], 'b')
plt.plot([aicpick.getpick()-0.5, aicpick.getpick()+0.5], [-1, -1], 'b') plt.plot([aicpick.getpick()-0.5, aicpick.getpick()+0.5], [-1, -1], 'b')
plt.plot([hospick.getpick(), hospick.getpick()], [-1.3, 1.3], 'r--')
plt.plot([hospick.getpick()-0.5, hospick.getpick()+0.5], [1.3, 1.3], 'r')
plt.plot([hospick.getpick()-0.5, hospick.getpick()+0.5], [-1.3, -1.3], 'r')
plt.plot([aicarzpick.getpick(), aicarzpick.getpick()], [-1.2, 1.2], 'y--') plt.plot([aicarzpick.getpick(), aicarzpick.getpick()], [-1.2, 1.2], 'y--')
plt.plot([aicarzpick.getpick()-0.5, aicarzpick.getpick()+0.5], [1.2, 1.2], 'y') plt.plot([aicarzpick.getpick()-0.5, aicarzpick.getpick()+0.5], [1.2, 1.2], 'y')
plt.plot([aicarzpick.getpick()-0.5, aicarzpick.getpick()+0.5], [-1.2, -1.2], 'y') plt.plot([aicarzpick.getpick()-0.5, aicarzpick.getpick()+0.5], [-1.2, -1.2], 'y')
plt.plot([arzpick.getpick(), arzpick.getpick()], [-1.4, 1.4], 'g--')
plt.plot([arzpick.getpick()-0.5, arzpick.getpick()+0.5], [1.4, 1.4], 'g')
plt.plot([arzpick.getpick()-0.5, arzpick.getpick()+0.5], [-1.4, -1.4], 'g')
plt.yticks([]) plt.yticks([])
plt.xlabel('Time [s]') plt.xlabel('Time [s]')
plt.ylabel('Normalized Counts') plt.ylabel('Normalized Counts')
@ -173,7 +182,7 @@ def run_makeCF(project, database, event, iplot, station=None):
th2data = np.arange(0, trH2_filt.stats.npts / trH2_filt.stats.sampling_rate, trH2_filt.stats.delta) th2data = np.arange(0, trH2_filt.stats.npts / trH2_filt.stats.sampling_rate, trH2_filt.stats.delta)
tarhcf = np.arange(0, len(arhcf.getCF()) * tsteph, tsteph) + cuttimes[0] + tdeth +tpredh tarhcf = np.arange(0, len(arhcf.getCF()) * tsteph, tsteph) + cuttimes[0] + tdeth +tpredh
p21 = plt.plot(th1data, trH1_filt.data/max(trH1_filt.data), 'k') p21 = plt.plot(th1data, trH1_filt.data/max(trH1_filt.data), 'k')
p22 = plt.plot(tarhcf, arhcf.getCF()/max(arhcf.getCF()), 'r') p22 = plt.plot(arhcf.getTimeArray(), arhcf.getCF()/max(arhcf.getCF()), 'r')
p23 = plt.plot(arhaiccf.getTimeArray(), arhaiccf.getCF()/max(arhaiccf.getCF())) p23 = plt.plot(arhaiccf.getTimeArray(), arhaiccf.getCF()/max(arhaiccf.getCF()))
plt.plot([aicarhpick.getpick(), aicarhpick.getpick()], [-1, 1], 'b--') plt.plot([aicarhpick.getpick(), aicarhpick.getpick()], [-1, 1], 'b--')
plt.plot([aicarhpick.getpick()-0.5, aicarhpick.getpick()+0.5], [1, 1], 'b') plt.plot([aicarhpick.getpick()-0.5, aicarhpick.getpick()+0.5], [1, 1], 'b')
@ -185,7 +194,6 @@ def run_makeCF(project, database, event, iplot, station=None):
plt.legend([p21, p22, p23], ['Data', 'ARH-CF', 'ARHAIC-CF']) plt.legend([p21, p22, p23], ['Data', 'ARH-CF', 'ARHAIC-CF'])
plt.subplot(212) plt.subplot(212)
plt.plot(th2data, trH2_filt.data/max(trH2_filt.data), 'k') plt.plot(th2data, trH2_filt.data/max(trH2_filt.data), 'k')
plt.plot(tarhcf, arhcf.getCF()/max(arhcf.getCF()), 'r')
plt.plot(arhaiccf.getTimeArray(), arhaiccf.getCF()/max(arhaiccf.getCF())) plt.plot(arhaiccf.getTimeArray(), arhaiccf.getCF()/max(arhaiccf.getCF()))
plt.plot([aicarhpick.getpick(), aicarhpick.getpick()], [-1, 1], 'b--') plt.plot([aicarhpick.getpick(), aicarhpick.getpick()], [-1, 1], 'b--')
plt.plot([aicarhpick.getpick()-0.5, aicarhpick.getpick()+0.5], [1, 1], 'b') plt.plot([aicarhpick.getpick()-0.5, aicarhpick.getpick()+0.5], [1, 1], 'b')

4
pylot/core/read/data.py
View File

@ -7,6 +7,7 @@ from obspy.core import (read, Stream)
from obspy import readEvents from obspy import readEvents
from obspy.core.event import (Event, Catalog) from obspy.core.event import (Event, Catalog)
from pylot.core.util import fnConstructor from pylot.core.util import fnConstructor
from pylot.core.util.errors import FormatError
class Data(object): class Data(object):
@ -71,7 +72,8 @@ class Data(object):
from pylot.core.util.defaults import OUTPUTFORMATS from pylot.core.util.defaults import OUTPUTFORMATS
if evtformat.strip() not in OUTPUTFORMATS.values(): if evtformat.strip() not in OUTPUTFORMATS.values():
evtformat = OUTPUTFORMATS.values()[0] errmsg = 'selected format {0} not available'.format(evtformat)
raise FormatError(errmsg)
if fnout is None: if fnout is None:
ID = self.evtdata.getEventID() ID = self.evtdata.getEventID()

3
pylot/core/util/errors.py
View File

@ -8,3 +8,6 @@ Created on Thu Mar 20 09:47:04 2014
class OptionsError(Exception): class OptionsError(Exception):
pass pass
class FormatError(Exception):
pass