Source code for openquake.hmtk.strain.geodetic_strain
# -*- coding: utf-8 -*-
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# D. Monelli.
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# Earthquake Model).
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'''
:class:`openquake.hmtk.strain.geodectic_strain.GeodeticStain` is a
core class for storage and implementation of a geodetic strain rate
model
'''
import numpy as np
from copy import deepcopy
DATA_VARIABLES = ['longitude', 'latitude', 'exx', 'eyy', 'exy']
[docs]class GeodeticStrain(object):
'''
:class:`openquake.hmtk.strain.geodetic_strain.GeodeticStrain` describes
the geodetic strain model
:param dict data:
Strain data in the form of a dictionary where is vector of attributes
is stored under the correponding dictionary key (i.e.
- longitude - Longitude of point
- latitude - Latitiude of point
- exx - xx-component of strain tensor
- eyy - yy-component of strain tensor
- exy - xy-component of strain tensor
:param numpy.ndarray seismicity_rate:
Seismicity rate at each point associated with the strain model
:param numpy.ndarray target_magnitudes:
Magnitudes for the corresponding activity rates
:param list data_variables:
List of strain data attributes in the current class
'''
def __init__(self):
'''Instantiates'''
self.data = None
self.regions = None
self.seismicity_rate = None
self.regionalisation = None
self.target_magnitudes = None
self.data_variables = []
[docs] def get_secondary_strain_data(self, strain_data=None):
'''
Calculate the following and add to data dictionary:
1) 2nd invarient of strain
2) Dilatation rate
3) e1h and e2h
4) err
:param dict strain_data:
Strain data dictionary (as described) - will overwrite current
data if input
'''
if strain_data:
self.data = strain_data
if not isinstance(self.data, dict):
raise ValueError('Strain data not input or incorrectly formatted')
# Check to ensure essential attributes are in data dictionary
for essential_key in DATA_VARIABLES:
if essential_key not in self.data:
print(self.data)
raise ValueError('Essential strain information %s missing!'
% essential_key)
self.data_variables = deepcopy(DATA_VARIABLES)
# Second Invarient
self.data['2nd_inv'] = np.sqrt(
(self.data['exx'] ** 2.) +
(self.data['eyy'] ** 2.) +
2.0 * (self.data['exy'] ** 2.))
# Dilatation
self.data['dilatation'] = self.data['exx'] + self.data['eyy']
# err
self.data['err'] = -1. * self.data['dilatation']
center_normal_rate = (self.data['exx'] +
self.data['eyy']) / 2.
radius_rate = np.sqrt((self.data['exx'] -
center_normal_rate) ** 2. +
(self.data['exy'] ** 2.))
# e1h and e2h
self.data['e1h'] = center_normal_rate - radius_rate
self.data['e2h'] = center_normal_rate + radius_rate
self.data['area'] = np.zeros(self.get_number_observations())
self.data_variables.extend(['2nd_inv', 'dilatation', 'err', 'e1h',
'e2h'])
[docs] def get_number_observations(self):
'''
Returns the number of observations in the data file
'''
if isinstance(self.data, dict) and ('exx' in self.data.keys()):
return len(self.data['exx'])
else:
return 0