[remove] moved correlation code from PyLoT to the seisobs utils scope

This commit is contained in:
Sebastian Wehling-Benatelli 2016-10-03 08:54:09 +02:00
parent 45184fd888
commit ae0cc5e160
5 changed files with 7 additions and 249 deletions

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README
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PyLoT
version: 0.1
The Python picking and Localisation Tool
This python library contains a graphical user interfaces for picking
seismic phases. This software needs ObsPy (http://github.com/obspy/obspy/wiki)
and the PySide Qt4 bindings for python to be installed first.
PILOT has originally been developed in Mathworks' MatLab. In order to
distribute PILOT without facing portability problems, it has been decided
to redevelop the software package in Python. The great work of the ObsPy
group allows easy handling of a bunch of seismic data and PyLoT will
benefit a lot compared to the former MatLab version.
The development of PyLoT is part of the joint research project MAGS2.
staff:
======
original author(s): L. Kueperkoch, S. Wehling-Benatelli, M. Bischoff (PILOT)
developer(s): S. Wehling-Benatelli, L. Kueperkoch, K. Olbert, M. Bischoff,
C. Wollin, M. Rische
others: A. Bruestle, T. Meier, W. Friederich
release notes:
==============
October 2013

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original author(s): L. Kueperkoch, S. Wehling-Benatelli, M. Bischoff (PILOT) original author(s): L. Kueperkoch, S. Wehling-Benatelli, M. Bischoff (PILOT)
developer(s): S. Wehling-Benatelli, L. Kueperkoch, K. Olbert, M. Bischoff, developer(s): S. Wehling-Benatelli, L. Kueperkoch, K. Olbert, M. Bischoff,
C. Wollin, M. Rische C. Wollin, M. Rische, M. Paffrath
others: A. Bruestle, T. Meier, W. Friederich others: A. Bruestle, T. Meier, W. Friederich
release notes: release notes:
============== ==============
### Features
- consistent manual phase picking through:
1. predefined SNR dependant zoom level
2.

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#!/usr/bin/env python
# -*- coding: utf-8 -*-
from obspy.core import read
from obspy.signal.trigger import coincidenceTrigger
class CoincidenceTimes(object):
def __init__(self, st, comp='Z', coinum=4, sta=1., lta=10., on=5., off=1.):
_type = 'recstalta'
self.coinclist = self.createCoincTriggerlist(data=st, trigcomp=comp,
coinum=coinum, sta=sta,
lta=lta, trigon=on,
trigoff=off, type=_type)
def __str__(self):
n = 1
out = ''
for time in self.getCoincTimes():
out += 'event no. {0}: starttime is {1}\n'.format(n, time)
n += 1
return out
def getCoincTimes(self):
timelist = []
for info in self.getCoincList():
timelist.append(info['time'])
return timelist
def getCoincList(self):
return self.coinclist
def createCoincTriggerlist(self, data, trigcomp, coinum, sta, lta,
trigon, trigoff, type):
'''
uses a coincidence trigger to detect all events in the given
dataset
'''
triggerlist = coincidenceTrigger(type, trigon, trigoff,
data.select(component=trigcomp),
coinum, sta=sta, lta=lta)
return triggerlist
def main():
data = read('/data/SDS/2014/1A/ZV??/?H?.D/*.365')
data.filter(type='bandpass', freqmin=5., freqmax=30.)
coincs = CoincidenceTimes(data)
print(coincs)
if __name__ == '__main__':
main()

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#!/usr/bin/env python
# -*- coding: utf-8 -*-
import numpy as np
def crosscorrsingle(wf1, wf2, taumax):
'''
Calculates the crosscorrelation between two waveforms with a defined maximum timedifference.
:param wf1: first waveformdata
:type wf1: list
:param wf2: second waveformdata
:type wf2: list
:param taumax: maximum time difference between waveforms
:type taumax: positive integer
:return: returns the crosscorrelation funktion 'c' and the lagvector 'l'
:rtype: c and l are lists
'''
N = len(wf1)
c = np.zeros(2 * taumax - 1)
l = np.zeros(2 * taumax - 1)
for tau in range(taumax):
Cxyplus = 0
Cxyminus = 0
for n in range(N - tau):
Cxy1plus = wf1[n] * wf2[n + tau]
Cxy1minus = wf1[n + tau] * wf2[n]
Cxyplus = Cxyplus + Cxy1plus
Cxyminus = Cxyminus + Cxy1minus
c[(taumax - 1) - tau] = Cxyminus
c[(taumax - 1) + tau] = Cxyplus
l[(taumax - 1) - tau] = -tau
l[(taumax - 1) + tau] = tau
return c, l
def crosscorrnormcalc(weights, wfs):
'''
crosscorrnormcalc - function that calculates the normalization for the
cross correlation carried out by 'wfscrosscorr'
:param weights: weighting factors for the single components
:type weights: tuple
:param wfs: tuple of `~numpy.array` object containing waveform data
:type wfs: tuple
:return: a floating point number yielding the by 'weights' weighted energy
of the waveforms in 'wfs'
:rtype: float
'''
# check if the parameters are of the right type
if not isinstance(weights, tuple):
raise TypeError("type of 'weight' should be 'tuple', but is {0}".format(
type(weights)))
if not isinstance(wfs, tuple):
raise TypeError(
"type of parameter 'wfs' should be 'tuple', but is {0}".format(
type(wfs)))
sqrsumwfs = 0.
for n, wf in enumerate(wfs):
sqrsumwf = np.sum(weights[n] ** 2. * wf ** 2.)
sqrsumwfs += sqrsumwf
return np.sqrt(sqrsumwfs)
def wfscrosscorr(weights, wfs, taumax):
'''
wfscrosscorr - function that calculates successive cross-correlations from a set of waveforms stored in a matrix
base formula is:
C(i)=SUM[p=1:nComponent](eP(p)*(SUM[n=1:N]APp(x,n)*APp(y,n+i)))/(SQRT(SUM[p=1:nComponent]eP(p)^2*(SUM[n=1:N](APp(x,n)^2)))*SQRT(SUM[p=1:nComponent]eP(p)^2*(SUM[n=1:N]APp(y,n)^2)))
whereas
nComponent is the number of components
N is the number of samples
i is the lag-index
input:
APp rowvectors containing the waveforms of each component p for which the cross-correlation is calculated
tPp rowvectros containing times
eP vector containing the weighting factors for the components (maxsize = [1x3])
output:
C cross-correlation function
L lag-vector
author(s):
SWB 26.01.2010 as arranged with Thomas Meier and Monika Bischoff
:param weights: weighting factors for the single components
:type weights: tuple
:param wfs: tuple of `~numpy.array` object containing waveform data
:type wfs: tuple
:param taumax: maximum time difference
:type taumax: positive integer
:return: returns cross correlation function normalized by the waveform energy
'''
ccnorm = 0.
ccnorm = crosscorrnormcalc(weights, wfs[0])
ccnorm *= crosscorrnormcalc(weights, wfs[1])
c = 0.
for n in range(len(wfs)):
cc, l = crosscorrsingle(wfs[0][n], wfs[1][n], taumax)
c += cc
return c / ccnorm, l

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#!/usr/bin/env python
# -*- coding: utf-8 -*-
from obspy.signal.trigger import recursive_sta_lta, trigger_onset
def createSingleTriggerlist(st, station='ZV01', trigcomp='Z', stalta=(1, 10),
trigonoff=(6, 1)):
'''
uses a single-station trigger to create a triggerlist for this station
:param st: obspy stream
:type st:
:param station: station name to get triggers for (optional, default = ZV01)
:type station: str
:param trigcomp: (optional, default = Z)
:type trigcomp: str
:param stalta: (optional, default = (1,10))
:type stalta: tuple
:param trigonoff: (optional, default = (6,1))
:type trigonoff: tuple
:return: list of triggtimes
:rtype: list
'''
tr = st.copy().select(component=trigcomp, station=station)[0]
df = tr.stats.sampling_rate
cft = recursive_sta_lta(tr.data, int(stalta[0] * df), int(stalta[1] * df))
triggers = trigger_onset(cft, trigonoff[0], trigonoff[1])
trigg = []
for time in triggers:
trigg.append(tr.stats.starttime + time[0] / df)
return trigg
def createSubCoincTriggerlist(trig, station='ZV01'):
'''
makes a triggerlist with the events, that are triggered by the
coincidence trigger and are seen at the demanded station
:param trig: list containing triggers from coincidence trigger
:type trig: list
:param station: station name to get triggers for (optional, default = ZV01)
:type station: str
:return: list of triggertimes
:rtype: list
'''
trigg = []
for tri in trig:
if station in tri['stations']:
trigg.append(tri['time'])
return trigg