Source code for obspy.taup.tau_branch

# -*- coding: utf-8 -*-
"""
Object dealing with branches in the model.
"""
import numpy as np

from .c_wrappers import clibtau
from .helper_classes import (SlownessLayer, SlownessModelError,
                             TauModelError, TimeDist)
from .slowness_layer import bullen_depth_for, bullen_radial_slowness


[docs]class TauBranch(object): """ Provides storage and methods for distance, time and tau increments for a branch. A branch is a group of layers bounded by discontinuities or reversals in slowness gradient. """
[docs] def __init__(self, top_depth=0, bot_depth=0, is_p_wave=False): self.top_depth = top_depth self.bot_depth = bot_depth self.is_p_wave = is_p_wave self.debug = False
[docs] def __str__(self): desc = "Tau Branch\n" desc += " top_depth = " + str(self.top_depth) + "\n" desc += " bot_depth = " + str(self.bot_depth) + "\n" desc += " max_ray_param=" + str(self.max_ray_param) + \ " min_turn_ray_param=" + str(self.min_turn_ray_param) desc += " min_ray_param=" + str(self.min_ray_param) + "\n" return desc
[docs] def __eq__(self, other): return self.__dict__ == other.__dict__
[docs] def create_branch(self, s_mod, min_p_so_far, ray_params): """ Calculates tau for this branch, between slowness layers top_layer_num and bot_layer_num, inclusive. """ top_layer_num = s_mod.layer_number_below(self.top_depth, self.is_p_wave) bot_layer_num = s_mod.layer_number_above(self.bot_depth, self.is_p_wave) top_s_layer = s_mod.get_slowness_layer(top_layer_num, self.is_p_wave) bot_s_layer = s_mod.get_slowness_layer(bot_layer_num, self.is_p_wave) if top_s_layer['top_depth'] != self.top_depth \ or bot_s_layer['bot_depth'] != self.bot_depth: if top_s_layer['top_depth'] != self.top_depth \ and abs(top_s_layer['top_depth'] - self.top_depth) < 0.000001: # Really close, so just move the top. print("Changing top_depth" + str(self.top_depth) + "-->" + str(top_s_layer.top_depth)) self.top_depth = top_s_layer['top_depth'] elif bot_s_layer['bot_depth'] != self.bot_depth and \ abs(bot_s_layer['bot_depth'] - self.bot_depth) < 0.000001: # Really close, so just move the bottom. print("Changing bot_depth" + str(self.bot_depth) + "-->" + str(bot_s_layer['bot_depth'])) self.bot_depth = bot_s_layer['bot_depth'] else: raise TauModelError("create_branch: TauBranch not compatible " "with slowness sampling at top_depth" + str(self.top_depth)) # Here we set min_turn_ray_param to be the ray parameter that turns # within the layer, not including total reflections off of the bottom. # max_ray_param is the largest ray parameter that can penetrate this # branch. min_ray_param is the minimum ray parameter that turns or is # totally reflected in this branch. self.max_ray_param = min_p_so_far self.min_turn_ray_param = s_mod.get_min_turn_ray_param( self.bot_depth, self.is_p_wave) self.min_ray_param = s_mod.get_min_ray_param(self.bot_depth, self.is_p_wave) time_dist = self.calc_time_dist(s_mod, top_layer_num, bot_layer_num, ray_params) self.time = time_dist['time'] self.dist = time_dist['dist'] self.tau = self.time - ray_params * self.dist
[docs] def calc_time_dist(self, s_mod, top_layer_num, bot_layer_num, ray_params, allow_turn_in_layer=False): time_dist = np.zeros(shape=ray_params.shape, dtype=TimeDist) time_dist['p'] = ray_params layer_num = np.arange(top_layer_num, bot_layer_num + 1) layer = s_mod.get_slowness_layer(layer_num, self.is_p_wave) plen = len(ray_params) llen = len(layer_num) ray_params = np.repeat(ray_params, llen).reshape((plen, llen)) layer_num = np.tile(layer_num, plen).reshape((plen, llen)) # Ignore some errors because we pass in a few invalid combinations that # are masked out later. with np.errstate(divide='ignore', invalid='ignore'): time, dist = s_mod.layer_time_dist( ray_params, layer_num, self.is_p_wave, check=False, allow_turn=True) clibtau.tau_branch_calc_time_dist_inner_loop( ray_params, time, dist, layer, time_dist, ray_params.shape[0], ray_params.shape[1], self.max_ray_param, allow_turn_in_layer) return time_dist
[docs] def insert(self, ray_param, s_mod, index): """ Inserts the distance, time, and tau increment for the slowness sample given to the branch. This is used for making the depth correction to a tau model for a non-surface source. """ top_layer_num = s_mod.layer_number_below(self.top_depth, self.is_p_wave) bot_layer_num = s_mod.layer_number_above(self.bot_depth, self.is_p_wave) top_s_layer = s_mod.get_slowness_layer(top_layer_num, self.is_p_wave) bot_s_layer = s_mod.get_slowness_layer(bot_layer_num, self.is_p_wave) if top_s_layer['top_depth'] != self.top_depth \ or bot_s_layer['bot_depth'] != self.bot_depth: raise TauModelError( "TauBranch depths not compatible with slowness sampling.") new_time = 0.0 new_dist = 0.0 if top_s_layer['bot_p'] >= ray_param and \ top_s_layer['top_p'] >= ray_param: layer_num = np.arange(top_layer_num, bot_layer_num + 1) layers = s_mod.get_slowness_layer(layer_num, self.is_p_wave) # So we don't sum below the turning depth. mask = np.cumprod(layers['bot_p'] >= ray_param).astype(np.bool_) layer_num = layer_num[mask] if len(layer_num): time, dist = s_mod.layer_time_dist(ray_param, layer_num, self.is_p_wave) new_time = np.sum(time) new_dist = np.sum(dist) new_tau = new_time - ray_param * new_dist self.time = np.insert(self.time, index, new_time) self.dist = np.insert(self.dist, index, new_dist) self.tau = np.insert(self.tau, index, new_tau)
[docs] def difference(self, top_branch, index_p, index_s, s_mod, min_p_so_far, ray_params): """ Generates a new tau branch by "subtracting" the given tau branch from this tau branch (self). The given tau branch is assumed to by the upper part of this branch. index_p specifies where a new ray corresponding to a P wave sample has been added; it is -1 if no ray parameter has been added to top_branch. index_s is similar to index_p except for a S wave sample. Note that although the ray parameters for index_p and index_s were for the P and S waves that turned at the source depth, both ray parameters need to be added to both P and S branches. """ if top_branch.top_depth != self.top_depth \ or top_branch.bot_depth > self.bot_depth: if top_branch.top_depth != self.top_depth \ and abs(top_branch.top_depth - self.top_depth) < 0.000001: # Really close, just move top. self.top_depth = top_branch.top_depth else: raise TauModelError( "TauBranch not compatible with slowness sampling.") if top_branch.is_p_wave != self.is_p_wave: raise TauModelError( "Can't subtract branches is is_p_wave doesn't agree.") # Find the top and bottom slowness layers of the bottom half. top_layer_num = s_mod.layer_number_below(top_branch.bot_depth, self.is_p_wave) bot_layer_num = s_mod.layer_number_below(self.bot_depth, self.is_p_wave) top_s_layer = s_mod.get_slowness_layer(top_layer_num, self.is_p_wave) bot_s_layer = s_mod.get_slowness_layer(bot_layer_num, self.is_p_wave) if bot_s_layer['top_depth'] == self.bot_depth \ and bot_s_layer['bot_depth'] > self.bot_depth: # Gone one too far. bot_layer_num -= 1 bot_s_layer = s_mod.get_slowness_layer(bot_layer_num, self.is_p_wave) if top_s_layer['top_depth'] != top_branch.bot_depth \ or bot_s_layer['bot_depth'] != self.bot_depth: raise TauModelError( "TauBranch not compatible with slowness sampling.") # Make sure index_p and index_s really correspond to new ray # parameters at the top of this branch. s_layer = s_mod.get_slowness_layer(s_mod.layer_number_below( top_branch.bot_depth, True), True) if index_p >= 0 and s_layer['top_p'] != ray_params[index_p]: raise TauModelError("P wave index doesn't match top layer.") s_layer = s_mod.get_slowness_layer(s_mod.layer_number_below( top_branch.bot_depth, False), False) if index_s >= 0 and s_layer['top_p'] != ray_params[index_s]: raise TauModelError("S wave index doesn't match top layer.") del s_layer # Construct the new TauBranch, going from the bottom of the top half # to the bottom of the whole branch. bot_branch = TauBranch(top_branch.bot_depth, self.bot_depth, self.is_p_wave) bot_branch.max_ray_param = top_branch.min_ray_param bot_branch.min_turn_ray_param = self.min_turn_ray_param bot_branch.min_ray_param = self.min_ray_param p_ray_param = -1 s_ray_param = -1 array_length = len(self.dist) if index_p != -1: array_length += 1 p_ray_param = ray_params[index_p:index_p + 1] time_dist_p = bot_branch.calc_time_dist( s_mod, top_layer_num, bot_layer_num, p_ray_param) if index_s != -1 and index_s != index_p: array_length += 1 s_ray_param = ray_params[index_s:index_s + 1] time_dist_s = bot_branch.calc_time_dist(s_mod, top_layer_num, bot_layer_num, s_ray_param) else: # In case index_s==P then only need one. index_s = -1 # allocate enough space bot_branch.time = np.zeros(array_length) bot_branch.dist = np.zeros(array_length) bot_branch.tau = np.zeros(array_length) if index_p == -1 and index_s == -1: # Then both indices are -1 so no new ray parameters are added. bot_branch.time = self.time - top_branch.time bot_branch.dist = self.dist - top_branch.dist bot_branch.tau = self.tau - top_branch.tau elif index_p == -1 and index_s != -1: # Only index_s != -1. bot_branch.time[:index_s] = (self.time[:index_s] - top_branch.time[:index_s]) bot_branch.dist[:index_s] = (self.dist[:index_s] - top_branch.dist[:index_s]) bot_branch.tau[:index_s] = (self.tau[:index_s] - top_branch.tau[:index_s]) bot_branch.time[index_s] = time_dist_s['time'] bot_branch.dist[index_s] = time_dist_s['dist'] bot_branch.tau[index_s] = (time_dist_s['time'] - s_ray_param * time_dist_s['dist']) bot_branch.time[index_s + 1:] = (self.time[index_s:] - top_branch.time[index_s + 1:]) bot_branch.dist[index_s + 1:] = (self.dist[index_s:] - top_branch.dist[index_s + 1:]) bot_branch.tau[index_s + 1:] = (self.tau[index_s:] - top_branch.tau[index_s + 1:]) elif index_p != -1 and index_s == -1: # Only index_p != -1. bot_branch.time[:index_p] = (self.time[:index_p] - top_branch.time[:index_p]) bot_branch.dist[:index_p] = (self.dist[:index_p] - top_branch.dist[:index_p]) bot_branch.tau[:index_p] = (self.tau[:index_p] - top_branch.tau[:index_p]) bot_branch.time[index_p] = time_dist_p['time'] bot_branch.dist[index_p] = time_dist_p['dist'] bot_branch.tau[index_p] = (time_dist_p['time'] - p_ray_param * time_dist_p['dist']) bot_branch.time[index_p + 1:] = (self.time[index_p:] - top_branch.time[index_p + 1:]) bot_branch.dist[index_p + 1:] = (self.dist[index_p:] - top_branch.dist[index_p + 1:]) bot_branch.tau[index_p + 1:] = (self.tau[index_p:] - top_branch.tau[index_p + 1:]) else: # Both index_p and S are != -1 so have two new samples bot_branch.time[:index_s] = (self.time[:index_s] - top_branch.time[:index_s]) bot_branch.dist[:index_s] = (self.dist[:index_s] - top_branch.dist[:index_s]) bot_branch.tau[:index_s] = (self.tau[:index_s] - top_branch.tau[:index_s]) bot_branch.time[index_s] = time_dist_s['time'] bot_branch.dist[index_s] = time_dist_s['dist'] bot_branch.tau[index_s] = (time_dist_s['time'] - s_ray_param * time_dist_s['dist']) bot_branch.time[index_s + 1:index_p] = ( self.time[index_s:index_p - 1] - top_branch.time[index_s + 1:index_p]) bot_branch.dist[index_s + 1:index_p] = ( self.dist[index_s:index_p - 1] - top_branch.dist[index_s + 1:index_p]) bot_branch.tau[index_s + 1:index_p] = ( self.tau[index_s:index_p - 1] - top_branch.tau[index_s + 1:index_p]) bot_branch.time[index_p] = time_dist_p['time'] bot_branch.dist[index_p] = time_dist_p['dist'] bot_branch.tau[index_p] = (time_dist_p['time'] - p_ray_param * time_dist_p['dist']) bot_branch.time[index_p + 1:] = (self.time[index_p - 1:] - top_branch.time[index_p + 1:]) bot_branch.dist[index_p + 1:] = (self.dist[index_p - 1:] - top_branch.dist[index_p + 1:]) bot_branch.tau[index_p + 1:] = (self.tau[index_p - 1:] - top_branch.tau[index_p + 1:]) return bot_branch
[docs] def path(self, ray_param, downgoing, s_mod): """ Called from TauPPath to calculate ray paths. :param ray_param: :param downgoing: :param s_mod: :return: """ if ray_param > self.max_ray_param: return np.empty(0, dtype=TimeDist) assert ray_param >= 0 try: top_layer_num = s_mod.layer_number_below(self.top_depth, self.is_p_wave) bot_layer_num = s_mod.layer_number_above(self.bot_depth, self.is_p_wave) # except NoSuchLayerError as e: except SlownessModelError: raise SlownessModelError("SlownessModel and TauModel are likely" "out of sync.") the_path = np.empty(bot_layer_num - top_layer_num + 1, dtype=TimeDist) path_index = 0 # Check to make sure layers and branches are compatible. s_layer = s_mod.get_slowness_layer(top_layer_num, self.is_p_wave) if s_layer['top_depth'] != self.top_depth: raise SlownessModelError("Branch and slowness model are not in " "agreement.") s_layer = s_mod.get_slowness_layer(bot_layer_num, self.is_p_wave) if s_layer['bot_depth'] != self.bot_depth: raise SlownessModelError("Branch and slowness model are not in " "agreement.") # Downgoing branches: if downgoing: s_layer_num = np.arange(top_layer_num, bot_layer_num + 1) s_layer = s_mod.get_slowness_layer(s_layer_num, self.is_p_wave) mask = np.cumprod(s_layer['bot_p'] >= ray_param).astype(np.bool_) mask &= s_layer['top_depth'] != s_layer['bot_depth'] s_layer_num = s_layer_num[mask] s_layer = s_layer[mask] if len(s_layer): path_index_end = path_index + len(s_layer) time, dist = s_mod.layer_time_dist( ray_param, s_layer_num, self.is_p_wave) the_path[path_index:path_index_end]['p'] = ray_param the_path[path_index:path_index_end]['time'] = time the_path[path_index:path_index_end]['dist'] = dist the_path[path_index:path_index_end]['depth'] = \ s_layer['bot_depth'] path_index = path_index_end # Apply Bullen laws on last element, if available. if len(s_layer_num): s_layer_num = s_layer_num[-1] + 1 else: s_layer_num = top_layer_num if s_layer_num <= bot_layer_num: s_layer = s_mod.get_slowness_layer(s_layer_num, self.is_p_wave) if s_layer['top_depth'] != s_layer['bot_depth']: turn_depth = bullen_depth_for(s_layer, ray_param, s_mod.radius_of_planet) turn_s_layer = np.array([ (s_layer['top_p'], s_layer['top_depth'], ray_param, turn_depth)], dtype=SlownessLayer) time, dist = bullen_radial_slowness( turn_s_layer, ray_param, s_mod.radius_of_planet) the_path[path_index]['p'] = ray_param the_path[path_index]['time'] = time the_path[path_index]['dist'] = dist the_path[path_index]['depth'] = turn_s_layer['bot_depth'] path_index += 1 # Upgoing branches: else: s_layer_num = np.arange(bot_layer_num, top_layer_num - 1, -1) s_layer = s_mod.get_slowness_layer(s_layer_num, self.is_p_wave) mask = np.logical_or(s_layer['top_p'] <= ray_param, s_layer['top_depth'] == s_layer['bot_depth']) mask = np.cumprod(mask).astype(np.bool_) mask[-1] = False # Always leave one element for Bullen. # Apply Bullen laws on first available element, if possible. first_unmasked = np.sum(mask) s_layer_2 = s_layer[first_unmasked] if s_layer_2['bot_p'] < ray_param: turn_depth = bullen_depth_for(s_layer_2, ray_param, s_mod.radius_of_planet) turn_s_layer = np.array([( s_layer_2['top_p'], s_layer_2['top_depth'], ray_param, turn_depth)], dtype=SlownessLayer) time, dist = bullen_radial_slowness( turn_s_layer, ray_param, s_mod.radius_of_planet) the_path[path_index]['p'] = ray_param the_path[path_index]['time'] = time the_path[path_index]['dist'] = dist the_path[path_index]['depth'] = turn_s_layer['top_depth'] path_index += 1 mask[first_unmasked] = True # Apply regular time/distance calculation on all unmasked and # non-zero thickness layers. mask = (~mask) & (s_layer['top_depth'] != s_layer['bot_depth']) s_layer = s_layer[mask] s_layer_num = s_layer_num[mask] if len(s_layer): path_index_end = path_index + len(s_layer) time, dist = s_mod.layer_time_dist( ray_param, s_layer_num, self.is_p_wave) the_path[path_index:path_index_end]['p'] = ray_param the_path[path_index:path_index_end]['time'] = time the_path[path_index:path_index_end]['dist'] = dist the_path[path_index:path_index_end]['depth'] = \ s_layer['top_depth'] path_index = path_index_end temp_path = the_path[:path_index] return temp_path
[docs] def _to_array(self): """ Store all attributes for serialization in a structured array. """ dtypes = [('debug', np.bool_), ('bot_depth', np.float_), ('dist', np.float_, self.dist.shape), ('is_p_wave', np.bool_), ('max_ray_param', np.float_), ('min_ray_param', np.float_), ('min_turn_ray_param', np.float_), ('tau', np.float_, self.tau.shape), ('time', np.float_, self.time.shape), ('top_depth', np.float_)] arr = np.empty(shape=(), dtype=dtypes) for dtype in dtypes: key = dtype[0] arr[key] = getattr(self, key) return arr
[docs] @staticmethod def _from_array(arr): """ Create instance object from a structured array used in serialization. """ branch = TauBranch() for key in arr.dtype.names: # restore scalar types from 0d array arr_ = arr[key] if arr_.ndim == 0: arr_ = arr_[()] setattr(branch, key, arr_) return branch