Source code for openquake.hazardlib.gsim.ghofrani_atkinson_2014

# -*- coding: utf-8 -*-
# vim: tabstop=4 shiftwidth=4 softtabstop=4
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"""
Module exports :class:`GhofraniAtkinson2014`,
               :class:`GhofraniAtkinson2014Cascadia`,
               :class:`GhofraniAtkinson2014Lower`,
               :class:`GhofraniAtkinson2014Upper`,
               :class:`GhofraniAtkinson2014CascadiaLower`,
               :class:`GhofraniAtkinson2014CascadiaUpper`
"""
import numpy as np
# standard acceleration of gravity in m/s**2
from scipy.constants import g


from openquake.hazardlib.gsim.base import GMPE, CoeffsTable
from openquake.hazardlib import const
from openquake.hazardlib.imt import PGA, PGV, SA


[docs]class GhofraniAtkinson2014(GMPE): """ Implements the Subduction Interface GMPE of Ghofrani & Atkinson (2014) for large magnitude earthquakes, based on the Tohoku records. Ghofrani, H. and Atkinson, G. M. (2014) Ground Motion Prediction Equations for Interface Earthquakes of M7 to M9 based on Empirical Data from Japan. Bulletin of Earthquake Engineering, 12, 549 - 571 """ #: The GMPE is derived for subduction interface earthquakes in Japan DEFINED_FOR_TECTONIC_REGION_TYPE = const.TRT.SUBDUCTION_INTERFACE #: Supported intensity measure types are peak ground acceleration, #: peak ground velocity and spectral acceleration DEFINED_FOR_INTENSITY_MEASURE_TYPES = set([ PGA, PGV, SA ]) #: Supported intensity measure component is assumed to be geometric mean DEFINED_FOR_INTENSITY_MEASURE_COMPONENT = const.IMC.AVERAGE_HORIZONTAL #: Supported standard deviation types is total. DEFINED_FOR_STANDARD_DEVIATION_TYPES = set([ const.StdDev.INTER_EVENT, const.StdDev.INTRA_EVENT, const.StdDev.TOTAL, ]) #: The GMPE provides a Vs30-dependent site scaling term and a forearc/ #: backarc attenuation term REQUIRES_SITES_PARAMETERS = {'vs30', 'backarc'} #: Required rupture parameters are magnitude REQUIRES_RUPTURE_PARAMETERS = {'mag'} #: Required distance measure is rupture distance REQUIRES_DISTANCES = {'rrup'}
[docs] def get_mean_and_stddevs(self, sites, rup, dists, imt, stddev_types): """ See :meth:`superclass method <.base.GroundShakingIntensityModel.get_mean_and_stddevs>` for spec of input and result values. """ C = self.COEFFS[imt] imean = (self._get_magnitude_term(C, rup.mag) + self._get_distance_term(C, dists.rrup, sites.backarc) + self._get_site_term(C, sites.vs30) + self._get_scaling_term(C, dists.rrup)) # Convert mean from cm/s and cm/s/s and from common logarithm to # natural logarithm if imt.name in "SA PGA": mean = np.log((10.0 ** (imean - 2.0)) / g) else: mean = np.log((10.0 ** (imean))) stddevs = self._get_stddevs(C, len(dists.rrup), stddev_types) return mean, stddevs
def _get_magnitude_term(self, C, mag): """ Returns the linear magnitude scaling term """ return C["a"] + C["b"] * mag def _get_distance_term(self, C, rrup, backarc): """ Returns the distance scaling term, which varies depending on whether the site is in the forearc or the backarc """ # Geometric attenuation function distance_scale = -np.log10(np.sqrt(rrup ** 2 + 3600.0)) # Anelastic attenuation in the backarc distance_scale[backarc] += (C["c2"] * rrup[backarc]) # Anelastic Attenuation in the forearc idx = np.logical_not(backarc) distance_scale[idx] += (C["c1"] * rrup[idx]) return distance_scale def _get_scaling_term(self, C, rrup): """ Returns a scaling term, which is over-ridden in subclasses """ return 0.0 def _get_site_term(self, C, vs30): """ Returns the linear site scaling term """ return C["c3"] * np.log10(vs30 / 760.0) def _get_stddevs(self, C, num_sites, stddev_types): """ Returns the total, inter-event or intra-event standard deviation """ stddevs = [] for stddev_type in stddev_types: assert stddev_type in self.DEFINED_FOR_STANDARD_DEVIATION_TYPES if stddev_type == const.StdDev.TOTAL: sig_tot = np.sqrt(C["tau"] ** 2. + C["sigma"] ** 2.) stddevs.append(np.log(10.0 ** sig_tot) + np.zeros(num_sites)) elif stddev_type == const.StdDev.INTER_EVENT: stddevs.append( np.log(10.0 ** C["tau"]) + np.zeros(num_sites)) elif stddev_type == const.StdDev.INTRA_EVENT: stddevs.append( np.log(10.0 ** C["sigma"]) + np.zeros(num_sites)) return stddevs COEFFS = CoeffsTable(sa_damping=5, table=""" IMT c0 a b c1 c2 c3 sig_init af sigma tau sig_tot pgv 3.3900 0.8540 0.2795 -0.00070 -0.00099 -0.331 0.195 0.000 0.195 0.138 0.238 pga 4.6460 2.8193 0.1908 -0.00219 -0.00298 -0.219 0.284 -0.301 0.284 0.196 0.345 0.07 4.8880 3.1807 0.1759 -0.00236 -0.00329 -0.046 0.313 -0.357 0.313 0.215 0.380 0.09 5.0220 3.3592 0.1700 -0.00244 -0.00346 0.027 0.326 -0.357 0.326 0.220 0.393 0.11 5.0820 3.4483 0.1669 -0.00245 -0.00356 0.010 0.329 -0.319 0.329 0.218 0.394 0.14 5.0720 3.5005 0.1604 -0.00240 -0.00357 -0.082 0.324 -0.272 0.324 0.212 0.387 0.18 5.0510 3.4463 0.1650 -0.00235 -0.00358 -0.180 0.312 -0.237 0.312 0.206 0.374 0.22 5.0150 3.3178 0.1763 -0.00235 -0.00355 -0.289 0.310 -0.183 0.310 0.202 0.370 0.27 4.9580 3.2008 0.1839 -0.00233 -0.00346 -0.386 0.312 -0.114 0.312 0.199 0.370 0.34 4.9070 3.0371 0.1970 -0.00231 -0.00333 -0.438 0.307 -0.046 0.307 0.191 0.361 0.42 4.8200 2.7958 0.2154 -0.00224 -0.00315 -0.520 0.295 0.002 0.295 0.171 0.341 0.53 4.7060 2.5332 0.2331 -0.00213 -0.00290 -0.606 0.276 0.007 0.276 0.155 0.316 0.65 4.5870 2.3234 0.2435 -0.00200 -0.00262 -0.672 0.257 0.011 0.257 0.147 0.296 0.81 4.4640 2.1321 0.2522 -0.00183 -0.00234 -0.705 0.249 0.014 0.249 0.131 0.281 1.01 4.3360 1.9852 0.2561 -0.00158 -0.00205 -0.690 0.249 0.021 0.249 0.115 0.274 1.25 4.2140 1.8442 0.2599 -0.00133 -0.00177 -0.646 0.261 0.089 0.261 0.110 0.283 1.56 4.1050 1.6301 0.2730 -0.00112 -0.00152 -0.578 0.274 0.139 0.274 0.113 0.296 1.92 3.9900 1.4124 0.2851 -0.00086 -0.00125 -0.518 0.285 0.174 0.285 0.121 0.310 2.44 3.8290 1.1154 0.3015 -0.00059 -0.00097 -0.513 0.275 0.129 0.275 0.132 0.305 3.03 3.6570 0.7965 0.3197 -0.00039 -0.00075 -0.554 0.264 0.079 0.264 0.137 0.298 3.70 3.5020 0.5093 0.3361 -0.00023 -0.00057 -0.574 0.252 0.044 0.252 0.138 0.287 4.55 3.3510 0.2578 0.3497 -0.00005 -0.00040 -0.561 0.237 0.013 0.237 0.147 0.279 5.88 3.2320 -0.1469 0.3835 0.00000 -0.00027 -0.491 0.218 0.000 0.218 0.151 0.265 7.14 3.1220 -0.5012 0.4119 0.00000 -0.00019 -0.462 0.201 0.000 0.201 0.148 0.250 9.09 2.9850 -1.0932 0.4641 0.00000 -0.00019 -0.413 0.175 0.000 0.175 0.155 0.233 """)
[docs]class GhofraniAtkinson2014Cascadia(GhofraniAtkinson2014): """ Implements the Subduction Interface GMPE of Ghofrani & Atkinson (2014) adapted for application to Cascadia """ def _get_scaling_term(self, C, rrup): """ Applies the log of the Cascadia multiplicative factor (as defined in Table 2) """ return C["af"]
[docs]class GhofraniAtkinson2014Upper(GhofraniAtkinson2014): """ Implements the Subduction Interface GMPE of Ghofrani & Atkinson (2014) with the "upper" epistemic uncertainty model """ def _get_scaling_term(self, C, rrup): """ Applies the positive correction factor given on Page 567 """ a_f = 0.15 + 0.0007 * rrup a_f[a_f > 0.35] = 0.35 return a_f
[docs]class GhofraniAtkinson2014Lower(GhofraniAtkinson2014): """ Implements the Subduction Interface GMPE of Ghofrani & Atkinson (2014) with the "lower" epistemic uncertainty model """ def _get_scaling_term(self, C, rrup): """ Applies the negative correction factor given on Page 567 """ a_f = 0.15 + 0.0007 * rrup a_f[a_f > 0.35] = 0.35 return -a_f
[docs]class GhofraniAtkinson2014CascadiaUpper(GhofraniAtkinson2014): """ Implements the Subduction Interface GMPE of Ghofrani & Atkinson (2014) with the "upper" epistemic uncertainty model and the Cascadia correction term. """ def _get_scaling_term(self, C, rrup): """ Applies the Cascadia correction factor from Table 2 and the positive correction factor given on Page 567 """ a_f = 0.15 + 0.0007 * rrup a_f[a_f > 0.35] = 0.35 return C["af"] + a_f
[docs]class GhofraniAtkinson2014CascadiaLower(GhofraniAtkinson2014): """ Implements the Subduction Interface GMPE of Ghofrani & Atkinson (2014) with the "lower" epistemic uncertainty model and the Cascadia correction term. """ def _get_scaling_term(self, C, rrup): """ Applies the Cascadia correction factor from Table 2 and the negative correction factor given on Page 567 """ a_f = 0.15 + 0.0007 * rrup a_f[a_f > 0.35] = 0.35 return C["af"] - a_f