コード例 #1
0
    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.
        """
        # extracting dictionary of coefficients specific to required
        # intensity measure type.
        C = self.COEFFS[imt]
        if isinstance(imt, PGA):
            imt_per = 0.0
        else:
            imt_per = imt.period
        # Fix site parameters for consistent dS2S application.
        sites.vs30 = np.array([250])
        sites.z1pt0 = np.array([330])
        # intensity on a reference soil is used for both mean
        # and stddev calculations.
        ln_y_ref = self._get_ln_y_ref(rup, dists, C)
        # exp1 and exp2 are parts of eq. 7
        exp1 = np.exp(C['phi3'] * (sites.vs30.clip(-np.inf, 1130) - 360))
        exp2 = np.exp(C['phi3'] * (1130 - 360))
        # v1 is the period dependent site term. The Vs30 above which, the
        # amplification is constant
        v1 = self._get_v1(imt)
        # Get log-mean from regular unadjusted model
        b13a_mean = self._get_mean(sites, C, ln_y_ref, exp1, exp2, v1)
        # Adjust mean and standard deviation
        mean = b13a_mean + self._get_dL2L(imt_per) + self._get_dS2S(imt_per)
        mean += convert_to_LHC(imt)
        stddevs = self._get_adjusted_stddevs(sites, rup, C, stddev_types,
                                             ln_y_ref, exp1, exp2, imt_per)

        return mean, stddevs
コード例 #2
0
    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.
        """
        # extracting dictionary of coefficients specific to required
        # intensity measure type.
        C = self.COEFFS[imt]
        if isinstance(imt, PGA):
            imt_per = 0.0
        else:
            imt_per = imt.period
        # Fix site parameters for consistent dS2S application.
        sites.vs30 = np.array([250])
        sites.z1pt0 = np.array([330])
        # intensity on a reference soil is used for both mean
        # and stddev calculations.
        ln_y_ref = self._get_ln_y_ref(rup, dists, C)
        # exp1 and exp2 are parts of eq. 7
        exp1 = np.exp(C['phi3'] * (sites.vs30.clip(-np.inf, 1130) - 360))
        exp2 = np.exp(C['phi3'] * (1130 - 360))
        # v1 is the period dependent site term. The Vs30 above which, the
        # amplification is constant
        v1 = self._get_v1(imt)
        # Get log-mean from regular unadjusted model
        b13a_mean = self._get_mean(sites, C, ln_y_ref, exp1, exp2, v1)
        # Adjust mean and standard deviation
        mean = b13a_mean + self._get_dL2L(imt_per) + self._get_dS2S(imt_per)
        mean += convert_to_LHC(imt)
        stddevs = self._get_adjusted_stddevs(sites, rup, C, stddev_types,
                                             ln_y_ref, exp1, exp2, imt_per)

        return mean, stddevs
コード例 #3
0
    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.
        """
        # extracting dictionary of coefficients specific to required
        # intensity measure type.
        C = self.COEFFS[imt]
        if isinstance(imt, PGA):
            imt_per = 0.0
        else:
            imt_per = imt.period
        # Check if any part of source is located within CSHM region
        in_cshm = self._check_in_cshm_polygon(rup)
        # Check if site is located in the CBD polygon
        in_cbd = self._check_in_cbd_polygon(sites.lon, sites.lat)
        # Fix CBD site terms before dS2S modification.
        sites.vs30[in_cbd == True] = 250
        sites.z1pt0[in_cbd == True] = 330
        # intensity on a reference soil is used for both mean
        # and stddev calculations.
        ln_y_ref = self._get_ln_y_ref(rup, dists, C)
        # exp1 and exp2 are parts of eq. 7
        exp1 = np.exp(C['phi3'] * (sites.vs30.clip(-np.inf, 1130) - 360))
        exp2 = np.exp(C['phi3'] * (1130 - 360))
        # v1 is the period dependent site term. The Vs30 above which, the
        # amplification is constant
        v1 = self._get_v1(imt)
        # Get log-mean from regular unadjusted model
        b13_mean = self._get_mean(sites, C, ln_y_ref, exp1, exp2, v1)
        # Adjust mean and standard deviation
        mean = self._adjust_mean_model(in_cshm, in_cbd, imt_per, b13_mean)
        mean += convert_to_LHC(imt)
        stddevs = self._get_adjusted_stddevs(sites, rup, C, stddev_types,
                                             ln_y_ref, exp1, exp2, in_cshm,
                                             in_cbd, imt_per)

        return mean, stddevs
コード例 #4
0
    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.
        """
        # extracting dictionary of coefficients specific to required
        # intensity measure type.
        C = self.COEFFS[imt]
        if isinstance(imt, PGA):
            imt_per = 0.0
        else:
            imt_per = imt.period
        # Check if any part of source is located within CSHM region
        in_cshm = self._check_in_cshm_polygon(rup)
        # Check if site is located in the CBD polygon
        in_cbd = self._check_in_cbd_polygon(sites.lon, sites.lat)
        # Fix CBD site terms before dS2S modification.
        sites.vs30[in_cbd == True] = 250
        sites.z1pt0[in_cbd == True] = 330
        # intensity on a reference soil is used for both mean
        # and stddev calculations.
        ln_y_ref = self._get_ln_y_ref(rup, dists, C)
        # exp1 and exp2 are parts of eq. 7
        exp1 = np.exp(C['phi3'] * (sites.vs30.clip(-np.inf, 1130) - 360))
        exp2 = np.exp(C['phi3'] * (1130 - 360))
        # v1 is the period dependent site term. The Vs30 above which, the
        # amplification is constant
        v1 = self._get_v1(imt)
        # Get log-mean from regular unadjusted model
        b13_mean = self._get_mean(sites, C, ln_y_ref, exp1, exp2, v1)
        # Adjust mean and standard deviation
        mean = self._adjust_mean_model(in_cshm, in_cbd, imt_per, b13_mean)
        mean += convert_to_LHC(imt)
        stddevs = self._get_adjusted_stddevs(sites, rup, C, stddev_types,
                                             ln_y_ref, exp1, exp2, in_cshm,
                                             in_cbd, imt_per)

        return mean, stddevs