Source code for openquake.hazardlib.geo.surface.gridded

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"""
Module :mod:`openquake.hazardlib.geo.surface.gridded` defines
:class:`GriddedSurface`.
"""
import numpy as np
from numpy import linalg as la
from openquake.baselib.node import Node
from openquake.hazardlib.geo import utils
from openquake.hazardlib.geo.mesh import Mesh
from openquake.hazardlib.geo.point import Point
from openquake.hazardlib.geo import utils as geo_utils
from openquake.hazardlib.geo.surface.base import BaseSurface, _get_finite_mesh


[docs]class GriddedSurface(BaseSurface): """ Gridded surface defined by an unstructured cloud of points. This surface type is required for a proper implementation of some subduction interface surfaces included int the Japan 2012 model. Note that currently we support only one rupture-site typology i.e. since this the only one that can be unambiguosly computed. :param mesh: An unstructured mesh of points ideally representing a rupture surface. Must be an instance of :class:`~openquake.hazardlib.geo.mesh.Mesh` """ def __init__(self, mesh=None): self.mesh = mesh self.idx = None self.strike = None self.dip = None @property def surface_nodes(self): """ :param points: a list of Point objects :returns: a Node of kind 'griddedSurface' """ line = [] for point in self.mesh: line.append(point.longitude) line.append(point.latitude) line.append(point.depth) return [Node('griddedSurface', nodes=[Node('gml:posList', {}, line)])]
[docs] @classmethod def from_points_list(cls, points): """ Create a gridded surface from a list of points. :parameter points: A list of :class:`~openquake.hazardlib.geo.Point` :returns: An instance of :class:`~openquake.hazardlib.geo.surface.gridded.GriddedSurface` """ return cls(Mesh.from_points_list(points))
[docs] def get_bounding_box(self): """ Compute surface geographical bounding box. :return: A tuple of four items. These items represent western, eastern, northern and southern borders of the bounding box respectively. Values are floats in decimal degrees. """ return utils.get_spherical_bounding_box( self.mesh.lons.flatten(), self.mesh.lats.flatten())
[docs] def get_surface_boundaries(self): """ :returns: (lons, lats) for the 5 points of the bounding box """ # FIXME: implement real boundaries, not bounding box xs, ys = zip(*utils.bbox2poly(self.get_bounding_box())) return xs, ys
[docs] def get_surface_boundaries_3d(self): """ :returns: (lons, lats, depths) for the 5 points of the bounding box """ # FIXME: implement real boundaries, not bounding box xs, ys = zip(*utils.bbox2poly(self.get_bounding_box())) return xs, ys, (0, 0, 0, 0, 0)
[docs] def get_joyner_boore_distance(self, mesh): """ Compute and return Joyner-Boore (also known as ``Rjb``) distance to each point of ``mesh``. :param mesh: :class:`~openquake.hazardlib.geo.mesh.Mesh` of points to calculate Joyner-Boore distance to. :returns: Numpy array of closest distances between the projections of surface and each point of the ``mesh`` to the earth surface. """ fmesh = _get_finite_mesh(self.mesh) return fmesh.get_joyner_boore_distance(mesh, unstructured=True)
[docs] def get_rx_distance(self, mesh): """ Compute distance between each point of mesh and surface's great circle arc. Distance is measured perpendicular to the rupture strike, from the surface projection of the updip edge of the rupture, with the down dip direction being positive (this distance is usually called ``Rx``). In other words, is the horizontal distance to top edge of rupture measured perpendicular to the strike. Values on the hanging wall are positive, values on the footwall are negative. :param mesh: :class:`~openquake.hazardlib.geo.mesh.Mesh` of points to calculate Rx-distance to. :returns: Numpy array of distances in km. """ raise NotImplementedError('GriddedSurface')
[docs] def get_top_edge_depth(self): """ Compute minimum depth of surface's top edge. :returns: Float value, the vertical distance between the earth surface and the shallowest point in surface's top edge in km. """ return self.mesh.depths.min()
[docs] def get_strike(self): """ Compute surface's strike as decimal degrees in a range ``[0, 360)``. The actual definition of the strike might depend on surface geometry. :returns: The strike angle in degrees """ if self.strike is not None: return self.strike # Create a projection centered in the center of the cloud of points proj = geo_utils.OrthographicProjection( *geo_utils.get_spherical_bounding_box( self.mesh.lons.flatten(), self.mesh.lats.flatten())) # Project the coordinates lons, lats = self.mesh.lons.flatten(), self.mesh.lats.flatten() coo = np.zeros((len(lons), 3)) tmp = np.transpose(proj(lons, lats)) coo[:, 0] = tmp[:, 0] coo[:, 1] = tmp[:, 1] coo[:, 2] = self.mesh.depths.flatten() coo[:, 2] *= -1 pnt0, vers = geo_utils.plane_fit(coo) # Find the angle between the surface projection of the unit vector and # the north direction north = np.array([0, 1, 0]) tmp = np.array([vers[0], vers[1], 0]) v1_u = north / la.norm(north) v2_u = tmp / la.norm(tmp) phi = np.rad2deg(np.arccos(np.clip(np.dot(v1_u, v2_u), -1.0, 1.0))) # Find the angle between the surface projection of the unit vector and # the unit vector tmp = np.array([vers[0], vers[1], 0]) v1_u = vers v2_u = tmp / la.norm(tmp) delta = np.rad2deg(np.arccos(np.clip(np.dot(v1_u, v2_u), -1.0, 1.0))) # Set strike and dip if vers[0] < 0: self.strike = (360 - phi - 90) % 360 else: self.strike = (phi - 90) % 360 self.dip = 90 - delta return self.strike
[docs] def get_dip(self): """ Compute surface's dip as decimal degrees in a range ``(0, 90]``. The actual definition of the dip might depend on surface geometry. :returns: The dip angle in degrees """ if self.dip is None: _ = self.get_strike() return self.dip
[docs] def get_width(self): """ Compute surface's width (that is surface extension along the dip direction) in km. The actual definition depends on the type of surface geometry. :returns: Float value, the surface width """ raise NotImplementedError('GriddedSurface')
[docs] def get_area(self): """ Compute surface's area in squared km. :returns: Float value, the surface area """ raise NotImplementedError('GriddedSurface')
[docs] def get_middle_point(self): """ Compute coordinates of surface middle point. The actual definition of ``middle point`` depends on the type of surface geometry. :return: instance of :class:`openquake.hazardlib.geo.point.Point` representing surface middle point. """ lons = self.mesh.lons.squeeze() lats = self.mesh.lats.squeeze() depths = self.mesh.depths.squeeze() lon_bar = lons.mean() lat_bar = lats.mean() idx = np.argmin((lons - lon_bar)**2 + (lats - lat_bar)**2) return Point(lons[idx], lats[idx], depths[idx])
[docs] def get_ry0_distance(self, mesh): """ :param mesh: :class:`~openquake.hazardlib.geo.mesh.Mesh` of points """ raise NotImplementedError('GriddedSurface')