# -*- coding: utf-8 -*-
# vim: tabstop=4 shiftwidth=4 softtabstop=4
#
# Copyright (C) 2014-2018 GEM Foundation
#
# OpenQuake is free software: you can redistribute it and/or modify it
# under the terms of the GNU Affero General Public License as published
# by the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# OpenQuake is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU Affero General Public License for more details.
#
# You should have received a copy of the GNU Affero General Public License
# along with OpenQuake. If not, see <http://www.gnu.org/licenses/>.
"""
Module exports :class:`CampbellBozorgnia2014`
:class:`CampbellBozorgnia2014HighQ`
:class:`CampbellBozorgnia2014LowQ`
:class:`CampbellBozorgnia2014JapanSite`
:class:`CampbellBozorgnia2014HighQJapanSite`
:class:`CampbellBozorgnia2014LowQJapanSite`
"""
import numpy as np
from math import exp, radians, cos
from openquake.hazardlib.gsim.base import GMPE, CoeffsTable
from openquake.hazardlib import const
from openquake.hazardlib.imt import PGA, PGV, SA
NON_JAPAN_CONSTS = {"c8": 0.0,
"h4": 1.0,
"c": 1.88,
"n": 1.18,
"philnAF": 0.3,
"SJ": 0}
JAPAN_CONSTS = {"c8": 0.0,
"h4": 1.0,
"c": 1.88,
"n": 1.18,
"philnAF": 0.3,
"SJ": 1}
[docs]class CampbellBozorgnia2014(GMPE):
"""
Implements NGA-West 2 GMPE developed by Kenneth W. Campbell and Yousef
Bozorgnia, published as "NGA-West2 Ground Motion Model for the Average
Horizontal Components of PGA, PGV, and 5 % Damped Linear Acceleration
Response Spectra" (2014, Earthquake Spectra, Volume 30, Number 3,
pages 1087 - 1115).
"""
#: Supported tectonic region type is active shallow crust
DEFINED_FOR_TECTONIC_REGION_TYPE = const.TRT.ACTIVE_SHALLOW_CRUST
#: Supported intensity measure types are spectral acceleration, peak
#: ground velocity and peak ground acceleration
DEFINED_FOR_INTENSITY_MEASURE_TYPES = set([
PGA,
PGV,
SA
])
#: Supported intensity measure component is orientation-independent
#: average horizontal :attr:`~openquake.hazardlib.const.IMC.GMRotI50`
DEFINED_FOR_INTENSITY_MEASURE_COMPONENT = const.IMC.RotD50
#: Supported standard deviation types are inter-event, intra-event
#: and total, see section "Aleatory Variability Model", page 1094.
DEFINED_FOR_STANDARD_DEVIATION_TYPES = set([
const.StdDev.TOTAL,
const.StdDev.INTER_EVENT,
const.StdDev.INTRA_EVENT
])
#: Required site parameters are Vs30, Vs30 type (measured or inferred),
#: and depth (km) to the 2.5 km/s shear wave velocity layer (z2pt5)
REQUIRES_SITES_PARAMETERS = set(('vs30', 'z2pt5'))
#: Required rupture parameters are magnitude, rake, dip, ztor, rupture
#: width and hypocentral depth
REQUIRES_RUPTURE_PARAMETERS = set(('mag', 'rake', 'dip', 'ztor', 'width',
'hypo_depth'))
#: Required distance measures are Rrup, Rjb and Rx
REQUIRES_DISTANCES = set(('rrup', 'rjb', 'rx'))
[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.
"""
# extract dictionaries of coefficients specific to required
# intensity measure type and for PGA
C = self.COEFFS[imt]
C_PGA = self.COEFFS[PGA()]
# Get mean and standard deviation of PGA on rock (Vs30 1100 m/s^2)
pga1100 = np.exp(self.get_mean_values(C_PGA, sites, rup, dists, None))
# Get mean and standard deviations for IMT
mean = self.get_mean_values(C, sites, rup, dists, pga1100)
if isinstance(imt, SA) and (imt.period <= 0.25):
# According to Campbell & Bozorgnia (2013) [NGA West 2 Report]
# If Sa (T) < PGA for T < 0.25 then set mean Sa(T) to mean PGA
# Get PGA on soil
pga = self.get_mean_values(C_PGA, sites, rup, dists, pga1100)
idx = mean <= pga
mean[idx] = pga[idx]
# Get standard deviations
stddevs = self._get_stddevs(C,
C_PGA,
rup,
sites,
pga1100,
stddev_types)
return mean, stddevs
[docs] def get_mean_values(self, C, sites, rup, dists, a1100):
"""
Returns the mean values for a specific IMT
"""
if isinstance(a1100, np.ndarray):
# Site model defined
temp_vs30 = sites.vs30
temp_z2pt5 = sites.z2pt5
else:
# Default site and basin model
temp_vs30 = 1100.0 * np.ones(len(sites.vs30))
temp_z2pt5 = self._select_basin_model(1100.0) *\
np.ones_like(temp_vs30)
return (self._get_magnitude_term(C, rup.mag) +
self._get_geometric_attenuation_term(C, rup.mag, dists.rrup) +
self._get_style_of_faulting_term(C, rup) +
self._get_hanging_wall_term(C, rup, dists) +
self._get_shallow_site_response_term(C, temp_vs30, a1100) +
self._get_basin_response_term(C, temp_z2pt5) +
self._get_hypocentral_depth_term(C, rup) +
self._get_fault_dip_term(C, rup) +
self._get_anelastic_attenuation_term(C, dists.rrup))
def _get_magnitude_term(self, C, mag):
"""
Returns the magnitude scaling term defined in equation 2
"""
f_mag = C["c0"] + C["c1"] * mag
if (mag > 4.5) and (mag <= 5.5):
return f_mag + (C["c2"] * (mag - 4.5))
elif (mag > 5.5) and (mag <= 6.5):
return f_mag + (C["c2"] * (mag - 4.5)) + (C["c3"] * (mag - 5.5))
elif mag > 6.5:
return f_mag + (C["c2"] * (mag - 4.5)) + (C["c3"] * (mag - 5.5)) +\
(C["c4"] * (mag - 6.5))
else:
return f_mag
def _get_geometric_attenuation_term(self, C, mag, rrup):
"""
Returns the geometric attenuation term defined in equation 3
"""
return (C["c5"] + C["c6"] * mag) * np.log(np.sqrt((rrup ** 2.) +
(C["c7"] ** 2.)))
def _get_style_of_faulting_term(self, C, rup):
"""
Returns the style-of-faulting scaling term defined in equations 4 to 6
"""
if (rup.rake > 30.0) and (rup.rake < 150.):
frv = 1.0
fnm = 0.0
elif (rup.rake > -150.0) and (rup.rake < -30.0):
fnm = 1.0
frv = 0.0
else:
fnm = 0.0
frv = 0.0
fflt_f = (self.CONSTS["c8"] * frv) + (C["c9"] * fnm)
if rup.mag <= 4.5:
fflt_m = 0.0
elif rup.mag > 5.5:
fflt_m = 1.0
else:
fflt_m = rup.mag - 4.5
return fflt_f * fflt_m
def _get_hanging_wall_term(self, C, rup, dists):
"""
Returns the hanging wall scaling term defined in equations 7 to 16
"""
return (C["c10"] *
self._get_hanging_wall_coeffs_rx(C, rup, dists.rx) *
self._get_hanging_wall_coeffs_rrup(dists) *
self._get_hanging_wall_coeffs_mag(C, rup.mag) *
self._get_hanging_wall_coeffs_ztor(rup.ztor) *
self._get_hanging_wall_coeffs_dip(rup.dip))
def _get_hanging_wall_coeffs_rx(self, C, rup, r_x):
"""
Returns the hanging wall r-x caling term defined in equation 7 to 12
"""
# Define coefficients R1 and R2
r_1 = rup.width * cos(radians(rup.dip))
r_2 = 62.0 * rup.mag - 350.0
fhngrx = np.zeros(len(r_x))
# Case when 0 <= Rx <= R1
idx = np.logical_and(r_x >= 0., r_x < r_1)
fhngrx[idx] = self._get_f1rx(C, r_x[idx], r_1)
# Case when Rx > R1
idx = r_x >= r_1
f2rx = self._get_f2rx(C, r_x[idx], r_1, r_2)
f2rx[f2rx < 0.0] = 0.0
fhngrx[idx] = f2rx
return fhngrx
def _get_f1rx(self, C, r_x, r_1):
"""
Defines the f1 scaling coefficient defined in equation 9
"""
rxr1 = r_x / r_1
return C["h1"] + (C["h2"] * rxr1) + (C["h3"] * (rxr1 ** 2.))
def _get_f2rx(self, C, r_x, r_1, r_2):
"""
Defines the f2 scaling coefficient defined in equation 10
"""
drx = (r_x - r_1) / (r_2 - r_1)
return self.CONSTS["h4"] + (C["h5"] * drx) + (C["h6"] * (drx ** 2.))
def _get_hanging_wall_coeffs_rrup(self, dists):
"""
Returns the hanging wall rrup term defined in equation 13
"""
fhngrrup = np.ones(len(dists.rrup))
idx = dists.rrup > 0.0
fhngrrup[idx] = (dists.rrup[idx] - dists.rjb[idx]) / dists.rrup[idx]
return fhngrrup
def _get_hanging_wall_coeffs_mag(self, C, mag):
"""
Returns the hanging wall magnitude term defined in equation 14
"""
if mag < 5.5:
return 0.0
elif mag > 6.5:
return 1.0 + C["a2"] * (mag - 6.5)
else:
return (mag - 5.5) * (1.0 + C["a2"] * (mag - 6.5))
def _get_hanging_wall_coeffs_ztor(self, ztor):
"""
Returns the hanging wall ztor term defined in equation 15
"""
if ztor <= 16.66:
return 1.0 - 0.06 * ztor
else:
return 0.0
def _get_hanging_wall_coeffs_dip(self, dip):
"""
Returns the hanging wall dip term defined in equation 16
"""
return (90.0 - dip) / 45.0
def _get_hypocentral_depth_term(self, C, rup):
"""
Returns the hypocentral depth scaling term defined in equations 21 - 23
"""
if rup.hypo_depth <= 7.0:
fhyp_h = 0.0
elif rup.hypo_depth > 20.0:
fhyp_h = 13.0
else:
fhyp_h = rup.hypo_depth - 7.0
if rup.mag <= 5.5:
fhyp_m = C["c17"]
elif rup.mag > 6.5:
fhyp_m = C["c18"]
else:
fhyp_m = C["c17"] + ((C["c18"] - C["c17"]) * (rup.mag - 5.5))
return fhyp_h * fhyp_m
def _get_fault_dip_term(self, C, rup):
"""
Returns the fault dip term, defined in equation 24
"""
if rup.mag < 4.5:
return C["c19"] * rup.dip
elif rup.mag > 5.5:
return 0.0
else:
return C["c19"] * (5.5 - rup.mag) * rup.dip
def _get_anelastic_attenuation_term(self, C, rrup):
"""
Returns the anelastic attenuation term defined in equation 25
"""
f_atn = np.zeros(len(rrup))
idx = rrup >= 80.0
f_atn[idx] = (C["c20"] + C["Dc20"]) * (rrup[idx] - 80.0)
return f_atn
def _select_basin_model(self, vs30):
"""
Select the preferred basin model (California or Japan) to scale
basin depth with respect to Vs30
"""
if self.CONSTS["SJ"]:
# Japan Basin Model - Equation 34 of Campbell & Bozorgnia (2014)
return np.exp(5.359 - 1.102 * np.log(vs30))
else:
# California Basin Model - Equation 33 of
# Campbell & Bozorgnia (2014)
return np.exp(7.089 - 1.144 * np.log(vs30))
def _get_basin_response_term(self, C, z2pt5):
"""
Returns the basin response term defined in equation 20
"""
f_sed = np.zeros(len(z2pt5))
idx = z2pt5 < 1.0
f_sed[idx] = (C["c14"] + C["c15"] * float(self.CONSTS["SJ"])) *\
(z2pt5[idx] - 1.0)
idx = z2pt5 > 3.0
f_sed[idx] = C["c16"] * C["k3"] * exp(-0.75) *\
(1.0 - np.exp(-0.25 * (z2pt5[idx] - 3.0)))
return f_sed
def _get_shallow_site_response_term(self, C, vs30, pga_rock):
"""
Returns the shallow site response term defined in equations 17, 18 and
19
"""
vs_mod = vs30 / C["k1"]
# Get linear global site response term
f_site_g = C["c11"] * np.log(vs_mod)
idx = vs30 > C["k1"]
f_site_g[idx] = f_site_g[idx] + (C["k2"] * self.CONSTS["n"] *
np.log(vs_mod[idx]))
# Get nonlinear site response term
idx = np.logical_not(idx)
if np.any(idx):
f_site_g[idx] = f_site_g[idx] + C["k2"] * (
np.log(pga_rock[idx] +
self.CONSTS["c"] * (vs_mod[idx] ** self.CONSTS["n"])) -
np.log(pga_rock[idx] + self.CONSTS["c"])
)
# For Japan sites (SJ = 1) further scaling is needed (equation 19)
if self.CONSTS["SJ"]:
fsite_j = np.log(vs_mod)
idx = vs30 > 200.0
if np.any(idx):
fsite_j[idx] = (C["c13"] + C["k2"] * self.CONSTS["n"]) *\
fsite_j[idx]
idx = np.logical_not(idx)
if np.any(idx):
fsite_j[idx] = (C["c12"] + C["k2"] * self.CONSTS["n"]) *\
(fsite_j[idx] - np.log(200.0 / C["k1"]))
return f_site_g + fsite_j
else:
return f_site_g
def _get_stddevs(self, C, C_PGA, rup, sites, pga1100, stddev_types):
"""
Returns the inter- and intra-event and total standard deviations
"""
# Get stddevs for PGA on basement rock
tau_lnpga_b, phi_lnpga_b = self._get_stddevs_pga(C_PGA, rup)
num_sites = len(sites.vs30)
# Get tau_lny on the basement rock
tau_lnyb = self._get_taulny(C, rup.mag)
# Get phi_lny on the basement rock
phi_lnyb = np.sqrt(self._get_philny(C, rup.mag) ** 2. -
self.CONSTS["philnAF"] ** 2.)
# Get site scaling term
alpha = self._get_alpha(C, sites.vs30, pga1100)
# Evaluate tau according to equation 29
tau = np.sqrt(
(tau_lnyb ** 2.) +
((alpha ** 2.) * (tau_lnpga_b ** 2.)) +
(2.0 * alpha * C["rholny"] * tau_lnyb * tau_lnpga_b))
# Evaluate phi according to equation 30
phi = np.sqrt(
(phi_lnyb ** 2.) +
(self.CONSTS["philnAF"] ** 2.) +
((alpha ** 2.) * (phi_lnpga_b ** 2.)) +
(2.0 * alpha * C["rholny"] * phi_lnyb * phi_lnpga_b))
stddevs = []
for stddev_type in stddev_types:
assert stddev_type in self.DEFINED_FOR_STANDARD_DEVIATION_TYPES
if stddev_type == const.StdDev.TOTAL:
stddevs.append(np.sqrt((tau ** 2.) + (phi ** 2.)) +
np.zeros(num_sites))
elif stddev_type == const.StdDev.INTRA_EVENT:
stddevs.append(phi + np.zeros(num_sites))
elif stddev_type == const.StdDev.INTER_EVENT:
stddevs.append(tau + np.zeros(num_sites))
return stddevs
def _get_stddevs_pga(self, C, rup):
"""
Returns the inter- and intra-event coefficients for PGA
"""
tau_lnpga_b = self._get_taulny(C, rup.mag)
phi_lnpga_b = np.sqrt(self._get_philny(C, rup.mag) ** 2. -
self.CONSTS["philnAF"] ** 2.)
return tau_lnpga_b, phi_lnpga_b
def _get_taulny(self, C, mag):
"""
Returns the inter-event random effects coefficient (tau)
Equation 28.
"""
if mag <= 4.5:
return C["tau1"]
elif mag >= 5.5:
return C["tau2"]
else:
return C["tau2"] + (C["tau1"] - C["tau2"]) * (5.5 - mag)
def _get_philny(self, C, mag):
"""
Returns the intra-event random effects coefficient (phi)
Equation 28.
"""
if mag <= 4.5:
return C["phi1"]
elif mag >= 5.5:
return C["phi2"]
else:
return C["phi2"] + (C["phi1"] - C["phi2"]) * (5.5 - mag)
def _get_alpha(self, C, vs30, pga_rock):
"""
Returns the alpha, the linearised functional relationship between the
site amplification and the PGA on rock. Equation 31.
"""
alpha = np.zeros(len(pga_rock))
idx = vs30 < C["k1"]
if np.any(idx):
af1 = pga_rock[idx] +\
self.CONSTS["c"] * ((vs30[idx] / C["k1"]) ** self.CONSTS["n"])
af2 = pga_rock[idx] + self.CONSTS["c"]
alpha[idx] = C["k2"] * pga_rock[idx] * ((1.0 / af1) - (1.0 / af2))
return alpha
COEFFS = CoeffsTable(sa_damping=5, table="""\
IMT c0 c1 c2 c3 c4 c5 c6 c7 c9 c10 c11 c12 c13 c14 c15 c16 c17 c18 c19 c20 Dc20 a2 h1 h2 h3 h5 h6 k1 k2 k3 phi1 phi2 tau1 tau2 phiC rholny
pgv -2.895 1.510 0.270 -1.299 -0.453 -2.466 0.204 5.837 -0.168 0.305 1.713 2.602 2.457 0.1060 0.332 0.585 0.0517 0.0327 0.00613 -0.0017 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 -1.955 1.929 0.655 0.494 0.317 0.297 0.190 0.684
pga -4.416 0.984 0.537 -1.499 -0.496 -2.773 0.248 6.768 -0.212 0.720 1.090 2.186 1.420 -0.0064 -0.202 0.393 0.0977 0.0333 0.00757 -0.0055 0.0000 0.167 0.241 1.474 -0.715 -0.337 -0.270 865 -1.186 1.839 0.734 0.492 0.409 0.322 0.166 1.000
0.01 -4.365 0.977 0.533 -1.485 -0.499 -2.773 0.248 6.753 -0.214 0.720 1.094 2.191 1.416 -0.0070 -0.207 0.390 0.0981 0.0334 0.00755 -0.0055 0.0000 0.168 0.242 1.471 -0.714 -0.336 -0.270 865 -1.186 1.839 0.734 0.492 0.404 0.325 0.166 1.000
0.02 -4.348 0.976 0.549 -1.488 -0.501 -2.772 0.247 6.502 -0.208 0.730 1.149 2.189 1.453 -0.0167 -0.199 0.387 0.1009 0.0327 0.00759 -0.0055 0.0000 0.166 0.244 1.467 -0.711 -0.339 -0.263 865 -1.219 1.840 0.738 0.496 0.417 0.326 0.166 0.998
0.03 -4.024 0.931 0.628 -1.494 -0.517 -2.782 0.246 6.291 -0.213 0.759 1.290 2.164 1.476 -0.0422 -0.202 0.378 0.1095 0.0331 0.00790 -0.0057 0.0000 0.167 0.246 1.467 -0.713 -0.338 -0.259 908 -1.273 1.841 0.747 0.503 0.446 0.344 0.165 0.986
0.05 -3.479 0.887 0.674 -1.388 -0.615 -2.791 0.240 6.317 -0.244 0.826 1.449 2.138 1.549 -0.0663 -0.339 0.295 0.1226 0.0270 0.00803 -0.0063 0.0000 0.173 0.251 1.449 -0.701 -0.338 -0.263 1054 -1.346 1.843 0.777 0.520 0.508 0.377 0.162 0.938
0.08 -3.293 0.902 0.726 -1.469 -0.596 -2.745 0.227 6.861 -0.266 0.815 1.535 2.446 1.772 -0.0794 -0.404 0.322 0.1165 0.0288 0.00811 -0.0070 0.0000 0.198 0.260 1.435 -0.695 -0.347 -0.219 1086 -1.471 1.845 0.782 0.535 0.504 0.418 0.158 0.887
0.10 -3.666 0.993 0.698 -1.572 -0.536 -2.633 0.210 7.294 -0.229 0.831 1.615 2.969 1.916 -0.0294 -0.416 0.384 0.0998 0.0325 0.00744 -0.0073 0.0000 0.174 0.259 1.449 -0.708 -0.391 -0.201 1032 -1.624 1.847 0.769 0.543 0.445 0.426 0.170 0.870
0.15 -4.866 1.267 0.510 -1.669 -0.490 -2.458 0.183 8.031 -0.211 0.749 1.877 3.544 2.161 0.0642 -0.407 0.417 0.0760 0.0388 0.00716 -0.0069 0.0000 0.198 0.254 1.461 -0.715 -0.449 -0.099 878 -1.931 1.852 0.769 0.543 0.382 0.387 0.180 0.876
0.20 -5.411 1.366 0.447 -1.750 -0.451 -2.421 0.182 8.385 -0.163 0.764 2.069 3.707 2.465 0.0968 -0.311 0.404 0.0571 0.0437 0.00688 -0.0060 0.0000 0.204 0.237 1.484 -0.721 -0.393 -0.198 748 -2.188 1.856 0.761 0.552 0.339 0.338 0.186 0.870
0.25 -5.962 1.458 0.274 -1.711 -0.404 -2.392 0.189 7.534 -0.150 0.716 2.205 3.343 2.766 0.1441 -0.172 0.466 0.0437 0.0463 0.00556 -0.0055 0.0000 0.185 0.206 1.581 -0.787 -0.339 -0.210 654 -2.381 1.861 0.744 0.545 0.340 0.316 0.191 0.850
0.30 -6.403 1.528 0.193 -1.770 -0.321 -2.376 0.195 6.990 -0.131 0.737 2.306 3.334 3.011 0.1597 -0.084 0.528 0.0323 0.0508 0.00458 -0.0049 0.0000 0.164 0.210 1.586 -0.795 -0.447 -0.121 587 -2.518 1.865 0.727 0.568 0.340 0.300 0.198 0.819
0.40 -7.566 1.739 -0.020 -1.594 -0.426 -2.303 0.185 7.012 -0.159 0.738 2.398 3.544 3.203 0.1410 0.085 0.540 0.0209 0.0432 0.00401 -0.0037 0.0000 0.160 0.226 1.544 -0.770 -0.525 -0.086 503 -2.657 1.874 0.690 0.593 0.356 0.264 0.206 0.743
0.50 -8.379 1.872 -0.121 -1.577 -0.440 -2.296 0.186 6.902 -0.153 0.718 2.355 3.016 3.333 0.1474 0.233 0.638 0.0092 0.0405 0.00388 -0.0027 0.0000 0.184 0.217 1.554 -0.770 -0.407 -0.281 457 -2.669 1.883 0.663 0.611 0.379 0.263 0.208 0.684
0.75 -9.841 2.021 -0.042 -1.757 -0.443 -2.232 0.186 5.522 -0.090 0.795 1.995 2.616 3.054 0.1764 0.411 0.776 -0.0082 0.0420 0.00420 -0.0016 0.0000 0.216 0.154 1.626 -0.780 -0.371 -0.285 410 -2.401 1.906 0.606 0.633 0.430 0.326 0.221 0.562
1.00 -11.011 2.180 -0.069 -1.707 -0.527 -2.158 0.169 5.650 -0.105 0.556 1.447 2.470 2.562 0.2593 0.479 0.771 -0.0131 0.0426 0.00409 -0.0006 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 -1.955 1.929 0.579 0.628 0.470 0.353 0.225 0.467
1.50 -12.469 2.270 0.047 -1.621 -0.630 -2.063 0.158 5.795 -0.058 0.480 0.330 2.108 1.453 0.2881 0.566 0.748 -0.0187 0.0380 0.00424 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 -1.025 1.974 0.541 0.603 0.497 0.399 0.222 0.364
2.00 -12.969 2.271 0.149 -1.512 -0.768 -2.104 0.158 6.632 -0.028 0.401 -0.514 1.327 0.657 0.3112 0.562 0.763 -0.0258 0.0252 0.00448 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 -0.299 2.019 0.529 0.588 0.499 0.400 0.226 0.298
3.00 -13.306 2.150 0.368 -1.315 -0.890 -2.051 0.148 6.759 0.000 0.206 -0.848 0.601 0.367 0.3478 0.534 0.686 -0.0311 0.0236 0.00345 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 0.000 2.110 0.527 0.578 0.500 0.417 0.229 0.234
4.00 -14.020 2.132 0.726 -1.506 -0.885 -1.986 0.135 7.978 0.000 0.105 -0.793 0.568 0.306 0.3747 0.522 0.691 -0.0413 0.0102 0.00603 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 0.000 2.200 0.521 0.559 0.543 0.393 0.237 0.202
5.00 -14.558 2.116 1.027 -1.721 -0.878 -2.021 0.135 8.538 0.000 0.000 -0.748 0.356 0.268 0.3382 0.477 0.670 -0.0281 0.0034 0.00805 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 0.000 2.291 0.502 0.551 0.534 0.421 0.237 0.184
7.50 -15.509 2.223 0.169 -0.756 -1.077 -2.179 0.165 8.468 0.000 0.000 -0.664 0.075 0.374 0.3754 0.321 0.757 -0.0205 0.0050 0.00280 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 0.000 2.517 0.457 0.546 0.523 0.438 0.271 0.176
10.0 -15.975 2.132 0.367 -0.800 -1.282 -2.244 0.180 6.564 0.000 0.000 -0.576 -0.027 0.297 0.3506 0.174 0.621 0.0009 0.0099 0.00458 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 0.000 2.744 0.441 0.543 0.466 0.438 0.290 0.154
""")
CONSTS = NON_JAPAN_CONSTS
[docs]class CampbellBozorgnia2014HighQ(CampbellBozorgnia2014):
"""
Implements the Campbell & Bozorgnia (2014) NGA-West2 GMPE for regions with
low attenuation (high quality factor, Q) (i.e. China, Turkey)
"""
COEFFS = CoeffsTable(sa_damping=5, table="""\
IMT c0 c1 c2 c3 c4 c5 c6 c7 c9 c10 c11 c12 c13 c14 c15 c16 c17 c18 c19 c20 Dc20 a2 h1 h2 h3 h5 h6 k1 k2 k3 phi1 phi2 tau1 tau2 phiC rholny
pgv -2.895 1.510 0.270 -1.299 -0.453 -2.466 0.204 5.837 -0.168 0.305 1.713 2.602 2.457 0.1060 0.332 0.585 0.0517 0.0327 0.00613 -0.0017 0.0017 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 -1.955 1.929 0.655 0.494 0.317 0.297 0.190 0.684
pga -4.416 0.984 0.537 -1.499 -0.496 -2.773 0.248 6.768 -0.212 0.720 1.090 2.186 1.420 -0.0064 -0.202 0.393 0.0977 0.0333 0.00757 -0.0055 0.0036 0.167 0.241 1.474 -0.715 -0.337 -0.270 865 -1.186 1.839 0.734 0.492 0.409 0.322 0.166 1.000
0.01 -4.365 0.977 0.533 -1.485 -0.499 -2.773 0.248 6.753 -0.214 0.720 1.094 2.191 1.416 -0.0070 -0.207 0.390 0.0981 0.0334 0.00755 -0.0055 0.0036 0.168 0.242 1.471 -0.714 -0.336 -0.270 865 -1.186 1.839 0.734 0.492 0.404 0.325 0.166 1.000
0.02 -4.348 0.976 0.549 -1.488 -0.501 -2.772 0.247 6.502 -0.208 0.730 1.149 2.189 1.453 -0.0167 -0.199 0.387 0.1009 0.0327 0.00759 -0.0055 0.0036 0.166 0.244 1.467 -0.711 -0.339 -0.263 865 -1.219 1.840 0.738 0.496 0.417 0.326 0.166 0.998
0.03 -4.024 0.931 0.628 -1.494 -0.517 -2.782 0.246 6.291 -0.213 0.759 1.290 2.164 1.476 -0.0422 -0.202 0.378 0.1095 0.0331 0.00790 -0.0057 0.0037 0.167 0.246 1.467 -0.713 -0.338 -0.259 908 -1.273 1.841 0.747 0.503 0.446 0.344 0.165 0.986
0.05 -3.479 0.887 0.674 -1.388 -0.615 -2.791 0.240 6.317 -0.244 0.826 1.449 2.138 1.549 -0.0663 -0.339 0.295 0.1226 0.0270 0.00803 -0.0063 0.0040 0.173 0.251 1.449 -0.701 -0.338 -0.263 1054 -1.346 1.843 0.777 0.520 0.508 0.377 0.162 0.938
0.08 -3.293 0.902 0.726 -1.469 -0.596 -2.745 0.227 6.861 -0.266 0.815 1.535 2.446 1.772 -0.0794 -0.404 0.322 0.1165 0.0288 0.00811 -0.0070 0.0039 0.198 0.260 1.435 -0.695 -0.347 -0.219 1086 -1.471 1.845 0.782 0.535 0.504 0.418 0.158 0.887
0.10 -3.666 0.993 0.698 -1.572 -0.536 -2.633 0.210 7.294 -0.229 0.831 1.615 2.969 1.916 -0.0294 -0.416 0.384 0.0998 0.0325 0.00744 -0.0073 0.0042 0.174 0.259 1.449 -0.708 -0.391 -0.201 1032 -1.624 1.847 0.769 0.543 0.445 0.426 0.170 0.870
0.15 -4.866 1.267 0.510 -1.669 -0.490 -2.458 0.183 8.031 -0.211 0.749 1.877 3.544 2.161 0.0642 -0.407 0.417 0.0760 0.0388 0.00716 -0.0069 0.0042 0.198 0.254 1.461 -0.715 -0.449 -0.099 878 -1.931 1.852 0.769 0.543 0.382 0.387 0.180 0.876
0.20 -5.411 1.366 0.447 -1.750 -0.451 -2.421 0.182 8.385 -0.163 0.764 2.069 3.707 2.465 0.0968 -0.311 0.404 0.0571 0.0437 0.00688 -0.0060 0.0041 0.204 0.237 1.484 -0.721 -0.393 -0.198 748 -2.188 1.856 0.761 0.552 0.339 0.338 0.186 0.870
0.25 -5.962 1.458 0.274 -1.711 -0.404 -2.392 0.189 7.534 -0.150 0.716 2.205 3.343 2.766 0.1441 -0.172 0.466 0.0437 0.0463 0.00556 -0.0055 0.0036 0.185 0.206 1.581 -0.787 -0.339 -0.210 654 -2.381 1.861 0.744 0.545 0.340 0.316 0.191 0.850
0.30 -6.403 1.528 0.193 -1.770 -0.321 -2.376 0.195 6.990 -0.131 0.737 2.306 3.334 3.011 0.1597 -0.084 0.528 0.0323 0.0508 0.00458 -0.0049 0.0031 0.164 0.210 1.586 -0.795 -0.447 -0.121 587 -2.518 1.865 0.727 0.568 0.340 0.300 0.198 0.819
0.40 -7.566 1.739 -0.020 -1.594 -0.426 -2.303 0.185 7.012 -0.159 0.738 2.398 3.544 3.203 0.1410 0.085 0.540 0.0209 0.0432 0.00401 -0.0037 0.0028 0.160 0.226 1.544 -0.770 -0.525 -0.086 503 -2.657 1.874 0.690 0.593 0.356 0.264 0.206 0.743
0.50 -8.379 1.872 -0.121 -1.577 -0.440 -2.296 0.186 6.902 -0.153 0.718 2.355 3.016 3.333 0.1474 0.233 0.638 0.0092 0.0405 0.00388 -0.0027 0.0025 0.184 0.217 1.554 -0.770 -0.407 -0.281 457 -2.669 1.883 0.663 0.611 0.379 0.263 0.208 0.684
0.75 -9.841 2.021 -0.042 -1.757 -0.443 -2.232 0.186 5.522 -0.090 0.795 1.995 2.616 3.054 0.1764 0.411 0.776 -0.0082 0.0420 0.00420 -0.0016 0.0016 0.216 0.154 1.626 -0.780 -0.371 -0.285 410 -2.401 1.906 0.606 0.633 0.430 0.326 0.221 0.562
1.00 -11.011 2.180 -0.069 -1.707 -0.527 -2.158 0.169 5.650 -0.105 0.556 1.447 2.470 2.562 0.2593 0.479 0.771 -0.0131 0.0426 0.00409 -0.0006 0.0006 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 -1.955 1.929 0.579 0.628 0.470 0.353 0.225 0.467
1.50 -12.469 2.270 0.047 -1.621 -0.630 -2.063 0.158 5.795 -0.058 0.480 0.330 2.108 1.453 0.2881 0.566 0.748 -0.0187 0.0380 0.00424 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 -1.025 1.974 0.541 0.603 0.497 0.399 0.222 0.364
2.00 -12.969 2.271 0.149 -1.512 -0.768 -2.104 0.158 6.632 -0.028 0.401 -0.514 1.327 0.657 0.3112 0.562 0.763 -0.0258 0.0252 0.00448 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 -0.299 2.019 0.529 0.588 0.499 0.400 0.226 0.298
3.00 -13.306 2.150 0.368 -1.315 -0.890 -2.051 0.148 6.759 0.000 0.206 -0.848 0.601 0.367 0.3478 0.534 0.686 -0.0311 0.0236 0.00345 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 0.000 2.110 0.527 0.578 0.500 0.417 0.229 0.234
4.00 -14.020 2.132 0.726 -1.506 -0.885 -1.986 0.135 7.978 0.000 0.105 -0.793 0.568 0.306 0.3747 0.522 0.691 -0.0413 0.0102 0.00603 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 0.000 2.200 0.521 0.559 0.543 0.393 0.237 0.202
5.00 -14.558 2.116 1.027 -1.721 -0.878 -2.021 0.135 8.538 0.000 0.000 -0.748 0.356 0.268 0.3382 0.477 0.670 -0.0281 0.0034 0.00805 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 0.000 2.291 0.502 0.551 0.534 0.421 0.237 0.184
7.50 -15.509 2.223 0.169 -0.756 -1.077 -2.179 0.165 8.468 0.000 0.000 -0.664 0.075 0.374 0.3754 0.321 0.757 -0.0205 0.0050 0.00280 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 0.000 2.517 0.457 0.546 0.523 0.438 0.271 0.176
10.0 -15.975 2.132 0.367 -0.800 -1.282 -2.244 0.180 6.564 0.000 0.000 -0.576 -0.027 0.297 0.3506 0.174 0.621 0.0009 0.0099 0.00458 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 0.000 2.744 0.441 0.543 0.466 0.438 0.290 0.154
""")
[docs]class CampbellBozorgnia2014LowQ(CampbellBozorgnia2014):
"""
Implements the Campbell & Bozorgnia (2014) NGA-West2 GMPE for regions with
high attenuation (low quality factor, Q) (i.e. Japan, Italy)
"""
COEFFS = CoeffsTable(sa_damping=5, table="""\
IMT c0 c1 c2 c3 c4 c5 c6 c7 c9 c10 c11 c12 c13 c14 c15 c16 c17 c18 c19 c20 Dc20 a2 h1 h2 h3 h5 h6 k1 k2 k3 phi1 phi2 tau1 tau2 phiC rholny
pgv -2.895 1.510 0.270 -1.299 -0.453 -2.466 0.204 5.837 -0.168 0.305 1.713 2.602 2.457 0.1060 0.332 0.585 0.0517 0.0327 0.00613 -0.0017 -0.0006 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 -1.955 1.929 0.655 0.494 0.317 0.297 0.190 0.684
pga -4.416 0.984 0.537 -1.499 -0.496 -2.773 0.248 6.768 -0.212 0.720 1.090 2.186 1.420 -0.0064 -0.202 0.393 0.0977 0.0333 0.00757 -0.0055 -0.0035 0.167 0.241 1.474 -0.715 -0.337 -0.270 865 -1.186 1.839 0.734 0.492 0.409 0.322 0.166 1.000
0.01 -4.365 0.977 0.533 -1.485 -0.499 -2.773 0.248 6.753 -0.214 0.720 1.094 2.191 1.416 -0.0070 -0.207 0.390 0.0981 0.0334 0.00755 -0.0055 -0.0035 0.168 0.242 1.471 -0.714 -0.336 -0.270 865 -1.186 1.839 0.734 0.492 0.404 0.325 0.166 1.000
0.02 -4.348 0.976 0.549 -1.488 -0.501 -2.772 0.247 6.502 -0.208 0.730 1.149 2.189 1.453 -0.0167 -0.199 0.387 0.1009 0.0327 0.00759 -0.0055 -0.0035 0.166 0.244 1.467 -0.711 -0.339 -0.263 865 -1.219 1.840 0.738 0.496 0.417 0.326 0.166 0.998
0.03 -4.024 0.931 0.628 -1.494 -0.517 -2.782 0.246 6.291 -0.213 0.759 1.290 2.164 1.476 -0.0422 -0.202 0.378 0.1095 0.0331 0.00790 -0.0057 -0.0034 0.167 0.246 1.467 -0.713 -0.338 -0.259 908 -1.273 1.841 0.747 0.503 0.446 0.344 0.165 0.986
0.05 -3.479 0.887 0.674 -1.388 -0.615 -2.791 0.240 6.317 -0.244 0.826 1.449 2.138 1.549 -0.0663 -0.339 0.295 0.1226 0.0270 0.00803 -0.0063 -0.0037 0.173 0.251 1.449 -0.701 -0.338 -0.263 1054 -1.346 1.843 0.777 0.520 0.508 0.377 0.162 0.938
0.08 -3.293 0.902 0.726 -1.469 -0.596 -2.745 0.227 6.861 -0.266 0.815 1.535 2.446 1.772 -0.0794 -0.404 0.322 0.1165 0.0288 0.00811 -0.0070 -0.0037 0.198 0.260 1.435 -0.695 -0.347 -0.219 1086 -1.471 1.845 0.782 0.535 0.504 0.418 0.158 0.887
0.10 -3.666 0.993 0.698 -1.572 -0.536 -2.633 0.210 7.294 -0.229 0.831 1.615 2.969 1.916 -0.0294 -0.416 0.384 0.0998 0.0325 0.00744 -0.0073 -0.0034 0.174 0.259 1.449 -0.708 -0.391 -0.201 1032 -1.624 1.847 0.769 0.543 0.445 0.426 0.170 0.870
0.15 -4.866 1.267 0.510 -1.669 -0.490 -2.458 0.183 8.031 -0.211 0.749 1.877 3.544 2.161 0.0642 -0.407 0.417 0.0760 0.0388 0.00716 -0.0069 -0.0030 0.198 0.254 1.461 -0.715 -0.449 -0.099 878 -1.931 1.852 0.769 0.543 0.382 0.387 0.180 0.876
0.20 -5.411 1.366 0.447 -1.750 -0.451 -2.421 0.182 8.385 -0.163 0.764 2.069 3.707 2.465 0.0968 -0.311 0.404 0.0571 0.0437 0.00688 -0.0060 -0.0031 0.204 0.237 1.484 -0.721 -0.393 -0.198 748 -2.188 1.856 0.761 0.552 0.339 0.338 0.186 0.870
0.25 -5.962 1.458 0.274 -1.711 -0.404 -2.392 0.189 7.534 -0.150 0.716 2.205 3.343 2.766 0.1441 -0.172 0.466 0.0437 0.0463 0.00556 -0.0055 -0.0033 0.185 0.206 1.581 -0.787 -0.339 -0.210 654 -2.381 1.861 0.744 0.545 0.340 0.316 0.191 0.850
0.30 -6.403 1.528 0.193 -1.770 -0.321 -2.376 0.195 6.990 -0.131 0.737 2.306 3.334 3.011 0.1597 -0.084 0.528 0.0323 0.0508 0.00458 -0.0049 -0.0035 0.164 0.210 1.586 -0.795 -0.447 -0.121 587 -2.518 1.865 0.727 0.568 0.340 0.300 0.198 0.819
0.40 -7.566 1.739 -0.020 -1.594 -0.426 -2.303 0.185 7.012 -0.159 0.738 2.398 3.544 3.203 0.1410 0.085 0.540 0.0209 0.0432 0.00401 -0.0037 -0.0034 0.160 0.226 1.544 -0.770 -0.525 -0.086 503 -2.657 1.874 0.690 0.593 0.356 0.264 0.206 0.743
0.50 -8.379 1.872 -0.121 -1.577 -0.440 -2.296 0.186 6.902 -0.153 0.718 2.355 3.016 3.333 0.1474 0.233 0.638 0.0092 0.0405 0.00388 -0.0027 -0.0034 0.184 0.217 1.554 -0.770 -0.407 -0.281 457 -2.669 1.883 0.663 0.611 0.379 0.263 0.208 0.684
0.75 -9.841 2.021 -0.042 -1.757 -0.443 -2.232 0.186 5.522 -0.090 0.795 1.995 2.616 3.054 0.1764 0.411 0.776 -0.0082 0.0420 0.00420 -0.0016 -0.0032 0.216 0.154 1.626 -0.780 -0.371 -0.285 410 -2.401 1.906 0.606 0.633 0.430 0.326 0.221 0.562
1.00 -11.011 2.180 -0.069 -1.707 -0.527 -2.158 0.169 5.650 -0.105 0.556 1.447 2.470 2.562 0.2593 0.479 0.771 -0.0131 0.0426 0.00409 -0.0006 -0.0030 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 -1.955 1.929 0.579 0.628 0.470 0.353 0.225 0.467
1.50 -12.469 2.270 0.047 -1.621 -0.630 -2.063 0.158 5.795 -0.058 0.480 0.330 2.108 1.453 0.2881 0.566 0.748 -0.0187 0.0380 0.00424 0.0000 -0.0019 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 -1.025 1.974 0.541 0.603 0.497 0.399 0.222 0.364
2.00 -12.969 2.271 0.149 -1.512 -0.768 -2.104 0.158 6.632 -0.028 0.401 -0.514 1.327 0.657 0.3112 0.562 0.763 -0.0258 0.0252 0.00448 0.0000 -0.0005 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 -0.299 2.019 0.529 0.588 0.499 0.400 0.226 0.298
3.00 -13.306 2.150 0.368 -1.315 -0.890 -2.051 0.148 6.759 0.000 0.206 -0.848 0.601 0.367 0.3478 0.534 0.686 -0.0311 0.0236 0.00345 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 0.000 2.110 0.527 0.578 0.500 0.417 0.229 0.234
4.00 -14.020 2.132 0.726 -1.506 -0.885 -1.986 0.135 7.978 0.000 0.105 -0.793 0.568 0.306 0.3747 0.522 0.691 -0.0413 0.0102 0.00603 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 0.000 2.200 0.521 0.559 0.543 0.393 0.237 0.202
5.00 -14.558 2.116 1.027 -1.721 -0.878 -2.021 0.135 8.538 0.000 0.000 -0.748 0.356 0.268 0.3382 0.477 0.670 -0.0281 0.0034 0.00805 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 0.000 2.291 0.502 0.551 0.534 0.421 0.237 0.184
7.50 -15.509 2.223 0.169 -0.756 -1.077 -2.179 0.165 8.468 0.000 0.000 -0.664 0.075 0.374 0.3754 0.321 0.757 -0.0205 0.0050 0.00280 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 0.000 2.517 0.457 0.546 0.523 0.438 0.271 0.176
10.0 -15.975 2.132 0.367 -0.800 -1.282 -2.244 0.180 6.564 0.000 0.000 -0.576 -0.027 0.297 0.3506 0.174 0.621 0.0009 0.0099 0.00458 0.0000 0.0000 0.596 0.117 1.616 -0.733 -0.128 -0.756 400 0.000 2.744 0.441 0.543 0.466 0.438 0.290 0.154
""")
[docs]class CampbellBozorgnia2014JapanSite(CampbellBozorgnia2014):
"""
Implements the Campbell & Bozorgnia (2014) NGA-West2 GMPE for the case in
which the "Japan" shallow site response term is activited
"""
CONSTS = JAPAN_CONSTS
[docs]class CampbellBozorgnia2014HighQJapanSite(CampbellBozorgnia2014HighQ):
"""
Implements the Campbell & Bozorgnia (2014) NGA-West2 GMPE, for the low
attenuation (high quality factor) coefficients, for the case in which
the "Japan" shallow site response term is activited
"""
CONSTS = JAPAN_CONSTS
[docs]class CampbellBozorgnia2014LowQJapanSite(CampbellBozorgnia2014LowQ):
"""
Implements the Campbell & Bozorgnia (2014) NGA-West2 GMPE, for the high
attenuation (low quality factor) coefficients, for the case in which
the "Japan" shallow site response term is activited
"""
CONSTS = JAPAN_CONSTS