Source code for pyrocko.cake

# http://pyrocko.org - GPLv3
#
# The Pyrocko Developers, 21st Century
# ---|P------/S----------~Lg----------

'''
Classical seismic ray theory for layered earth models (*layer cake* models).

This module can be used to e.g. calculate arrival times, ray paths, reflection
and transmission coefficients, take-off and incidence angles and geometrical
spreading factors for arbitrary seismic phases. Computations are done for a
spherical earth, even though the module name may suggests something flat.

The main classes defined in this module are:

* :py:class:`Material` - Defines an isotropic elastic material.
* :py:class:`PhaseDef` - Defines a seismic phase arrival / wave propagation
    history.
* :py:class:`Leg` - Continuous propagation in a :py:class:`PhaseDef`.
* :py:class:`Knee` - Conversion/reflection in a :py:class:`PhaseDef`.
* :py:class:`LayeredModel` - Representation of a layer cake model.
* :py:class:`Layer` - A layer in a :py:class:`LayeredModel`.

   * :py:class:`HomogeneousLayer` - A homogeneous :py:class:`Layer`.
   * :py:class:`GradientLayer` - A gradient :py:class:`Layer`.

* :py:class:`Discontinuity` - A discontinuity in a :py:class:`LayeredModel`.

   * :py:class:`Interface` - A :py:class:`Discontinuity` between two
     :py:class:`Layer` instances.
   * :py:class:`Surface` - The surface :py:class:`Discontinuity` on top of
     a :py:class:`LayeredModel`.

* :py:class:`RayPath` - A fan of rays running through a common sequence of
  layers / interfaces.
* :py:class:`Ray` - A specific ray with a specific (ray parameter, distance,
  arrival time) choice.
* :py:class:`RayElement` - An element of a :py:class:`RayPath`.

   * :py:class:`Straight` - A ray segment representing propagation through
     one :py:class:`Layer`.
   * :py:class:`Kink` - An interaction of a ray with a
     :py:class:`Discontinuity`.
'''

from __future__ import absolute_import
from functools import reduce

import os
import logging
import copy
import math
import cmath
import operator
try:
    from StringIO import StringIO
except ImportError:
    from io import StringIO

import glob
import numpy as num
from scipy.optimize import bisect, brentq

from . import util, config

try:
    newstr = unicode
except NameError:
    newstr = str

logger = logging.getLogger('cake')

ZEPS = 0.01
P = 1
S = 2
DOWN = 4
UP = -4

DEFAULT_BURGERS = (0., 0., 1.)

earthradius = config.config().earthradius

r2d = 180./math.pi
d2r = 1./r2d
km = 1000.
d2m = d2r*earthradius
m2d = 1./d2m
sprad2spm = 1.0/(r2d*d2m)
sprad2spkm = 1.0/(r2d*d2m/km)
spm2sprad = 1.0/sprad2spm
spkm2sprad = 1.0/sprad2spkm


[docs]class CakeError(Exception): pass
[docs]class InvalidArguments(CakeError): pass
[docs]class Material(object): ''' Isotropic elastic material. :param vp: P-wave velocity [m/s] :param vs: S-wave velocity [m/s] :param rho: density [kg/m^3] :param qp: P-wave attenuation Qp :param qs: S-wave attenuation Qs :param poisson: Poisson ratio :param lame: tuple with Lame parameter `lambda` and `shear modulus` [Pa] :param qk: bulk attenuation Qk :param qmu: shear attenuation Qmu :param burgers: Burgers rheology paramerters as `tuple`. `transient viscosity` [Pa], <= 0 means infinite value, `steady-state viscosity` [Pa] and `alpha`, the ratio between the effective and unreleaxed shear modulus, mu1/(mu1 + mu2). :type burgers: tuple If no velocities and no lame parameters are given, standard crustal values of vp = 5800 m/s and vs = 3200 m/s are used. If no Q values are given, standard crustal values of qp = 1456 and qs = 600 are used. If no Burgers material parameters are given, transient and steady-state viscosities are 0 and alpha=1. Everything is in SI units (m/s, Pa, kg/m^3) unless explicitly stated. The main material properties are considered independant and are accessible as attributes (it is allowed to assign to these): .. py:attribute:: vp, vs, rho, qp, qs Other material properties are considered dependant and can be queried by instance methods. ''' def __init__( self, vp=None, vs=None, rho=2600., qp=None, qs=None, poisson=None, lame=None, qk=None, qmu=None, burgers=None): parstore_float(locals(), self, 'vp', 'vs', 'rho', 'qp', 'qs') if vp is not None and vs is not None: if poisson is not None or lame is not None: raise InvalidArguments( 'If vp and vs are given, poisson ratio and lame paramters ' 'should not be given.') elif vp is None and vs is None and lame is None: self.vp = 5800. if poisson is None: poisson = 0.25 self.vs = self.vp / math.sqrt(2.0*(1.0-poisson)/(1.0-2.0*poisson)) elif vp is None and vs is None and lame is not None: if poisson is not None: raise InvalidArguments( 'Poisson ratio should not be given, when lame parameters ' 'are given.') lam, mu = float(lame[0]), float(lame[1]) self.vp = math.sqrt((lam + 2.0*mu)/rho) self.vs = math.sqrt(mu/rho) elif vp is not None and vs is None: if poisson is None: poisson = 0.25 if lame is not None: raise InvalidArguments( 'If vp is given, Lame parameters should not be given.') poisson = float(poisson) self.vs = vp / math.sqrt(2.0*(1.0-poisson)/(1.0-2.0*poisson)) elif vp is None and vs is not None: if poisson is None: poisson = 0.25 if lame is not None: raise InvalidArguments( 'If vs is given, Lame parameters should not be given.') poisson = float(poisson) self.vp = vs * math.sqrt(2.0*(1.0-poisson)/(1.0-2.0*poisson)) else: raise InvalidArguments( 'Invalid combination of input parameters in material ' 'definition.') if qp is not None or qs is not None: if not (qk is None and qmu is None): raise InvalidArguments( 'If qp or qs are given, qk and qmu should not be given.') if qp is None: if self.vs != 0.0: s = (4.0/3.0)*(self.vs/self.vp)**2 self.qp = self.qs / s else: self.qp = 1456. if qs is None: if self.vs != 0.0: s = (4.0/3.0)*(self.vs/self.vp)**2 self.qs = self.qp * s else: self.vs = 600. elif qp is None and qs is None and qk is None and qmu is None: if self.vs == 0.: self.qs = 0. self.qp = 5782e4 else: self.qs = 600. s = (4.0/3.0)*(self.vs/self.vp)**2 self.qp = self.qs/s elif qp is None and qs is None and qk is not None and qmu is not None: s = (4.0/3.0)*(self.vs/self.vp)**2 if qmu == 0. and self.vs == 0.: self.qp = qk else: if num.isinf(qk): self.qp = qmu/s else: self.qp = 1.0 / (s/qmu + (1.0-s)/qk) self.qs = qmu else: raise InvalidArguments( 'Invalid combination of input parameters in material ' 'definition.') if burgers is None: burgers = DEFAULT_BURGERS self.burger_eta1 = burgers[0] self.burger_eta2 = burgers[1] self.burger_valpha = burgers[2]
[docs] def astuple(self): ''' Get independant material properties as a tuple. Returns a tuple with ``(vp, vs, rho, qp, qs)``. ''' return self.vp, self.vs, self.rho, self.qp, self.qs
def __eq__(self, other): return self.astuple() == other.astuple()
[docs] def lame(self): ''' Get Lame's parameter lambda and shear modulus. ''' mu = self.vs**2 * self.rho lam = self.vp**2 * self.rho - 2.0*mu return lam, mu
[docs] def lame_lambda(self): ''' Get Lame's parameter lambda. Returned units are [Pa]. ''' lam, _ = self.lame() return lam
[docs] def shear_modulus(self): ''' Get shear modulus. Returned units are [Pa]. ''' return self.vs**2 * self.rho
[docs] def poisson(self): ''' Get Poisson's ratio. ''' lam, mu = self.lame() return lam / (2.0*(lam+mu))
[docs] def bulk(self): ''' Get bulk modulus. ''' lam, mu = self.lame() return lam + 2.0*mu/3.0
[docs] def youngs(self): ''' Get Young's modulus. ''' lam, mu = self.lame() return mu * (3.0*lam + 2.0*mu) / (lam+mu)
[docs] def vp_vs_ratio(self): ''' Get vp/vs ratio. ''' return self.vp/self.vs
[docs] def qmu(self): ''' Get shear attenuation coefficient Qmu. ''' return self.qs
[docs] def qk(self): ''' Get bulk attenuation coefficient Qk. ''' if self.vs == 0. and self.qs == 0.: return self.qp else: s = (4.0/3.0)*(self.vs/self.vp)**2 denom = (1/self.qp - s/self.qs) if denom <= 0.0: return num.inf else: return (1.-s)/(1.0/self.qp - s/self.qs)
[docs] def burgers(self): ''' Get Burger parameters. ''' return self.burger_eta1, self.burger_eta2, self.burger_valpha
def _rayleigh_equation(self, cr): cr_a = (cr/self.vp)**2 cr_b = (cr/self.vs)**2 if cr_a > 1.0 or cr_b > 1.0: return None return (2.0-cr_b)**2 - 4.0 * math.sqrt(1.0-cr_a) * math.sqrt(1.0-cr_b)
[docs] def rayleigh(self): ''' Get Rayleigh velocity assuming a homogenous halfspace. Returned units are [m/s]. ''' return bisect(self._rayleigh_equation, 0.001*self.vs, self.vs)
def _has_default_burgers(self): if self.burger_eta1 == DEFAULT_BURGERS[0] and \ self.burger_eta2 == DEFAULT_BURGERS[1] and \ self.burger_valpha == DEFAULT_BURGERS[2]: return True return False
[docs] def describe(self): ''' Get a readable listing of the material properties. ''' template = ''' P wave velocity [km/s] : %12g S wave velocity [km/s] : %12g P/S wave vel. ratio : %12g Lame lambda [GPa] : %12g Lame shear modulus [GPa] : %12g Poisson ratio : %12g Bulk modulus [GPa] : %12g Young's modulus [GPa] : %12g Rayleigh wave vel. [km/s] : %12g Density [g/cm**3] : %12g Qp P-wave attenuation : %12g Qs S-wave attenuation (Qmu) : %12g Qk bulk attenuation : %12g transient viscos., eta1 [GPa] : %12g st.-state viscos., eta2 [GPa] : %12g relaxation: valpha : %12g '''.strip() return template % ( self.vp/km, self.vs/km, self.vp/self.vs, self.lame_lambda()*1e-9, self.shear_modulus()*1e-9, self.poisson(), self.bulk()*1e-9, self.youngs()*1e-9, self.rayleigh()/km, self.rho/km, self.qp, self.qs, self.qk(), self.burger_eta1*1e-9, self.burger_eta2*1e-9, self.burger_valpha)
def __str__(self): vp, vs, rho, qp, qs = self.astuple() return '%10g km/s %10g km/s %10g g/cm^3 %10g %10g' % ( vp/km, vs/km, rho/km, qp, qs) def __repr__(self): return 'Material(vp=%s, vs=%s, rho=%s, qp=%s, qs=%s)' % \ tuple(repr(x) for x in ( self.vp, self.vs, self.rho, self.qp, self.qs))
[docs]class Leg(object): ''' Represents a continuous piece of wave propagation in a phase definition. **Attributes:** To be considered as read-only. .. py:attribute:: departure One of the constants :py:const:`UP` or :py:const:`DOWN` indicating upward or downward departure. .. py:attribute:: mode One of the constants :py:const:`P` or :py:const:`S`, indicating the propagation mode. .. py:attribute:: depthmin ``None``, a number (a depth in [m]) or a string (an interface name), minimum depth. .. py:attribute:: depthmax ``None``, a number (a depth in [m]) or a string (an interface name), maximum depth. ''' def __init__(self, departure=None, mode=None): self.departure = departure self.mode = mode self.depthmin = None self.depthmax = None def set_depthmin(self, depthmin): self.depthmin = depthmin def set_depthmax(self, depthmax): self.depthmax = depthmax def __str__(self): def sd(d): if isinstance(d, float): return '%g km' % (d/km) else: return 'interface %s' % d s = '%s mode propagation, departing %s' % ( smode(self.mode).upper(), { UP: 'upward', DOWN: 'downward'}[self.departure]) sc = [] if self.depthmax is not None: sc.append('deeper than %s' % sd(self.depthmax)) if self.depthmin is not None: sc.append('shallower than %s' % sd(self.depthmin)) if sc: s = s + ' (may not propagate %s)' % ' or '.join(sc) return s
[docs]class InvalidKneeDef(CakeError): pass
[docs]class Knee(object): ''' Represents a change in wave propagation within a :py:class:`PhaseDef`. **Attributes:** To be considered as read-only. .. py:attribute:: depth Depth at which the conversion/reflection should happen. this can be a string or a number. .. py:attribute:: direction One of the constants :py:const:`UP` or :py:const:`DOWN` to indicate the incoming direction. .. py:attribute:: in_mode One of the constants :py:const:`P` or :py:const:`S` to indicate the type of mode of the incoming wave. .. py:attribute:: out_mode One of the constants :py:const:`P` or :py:const:`S` to indicate the type of mode of the outgoing wave. .. py:attribute:: conversion Boolean, whether there is a mode conversion involved. .. py:attribute:: reflection Boolean, whether there is a reflection involved. .. py:attribute:: headwave Boolean, whether there is headwave propagation involved. ''' defaults = dict( depth='surface', direction=UP, conversion=True, reflection=False, headwave=False, in_setup_state=True) defaults_surface = dict( depth='surface', direction=UP, conversion=False, reflection=True, headwave=False, in_setup_state=True) def __init__(self, *args): if args: (self.depth, self.direction, self.reflection, self.in_mode, self.out_mode) = args self.conversion = self.in_mode != self.out_mode self.in_setup_state = False def default(self, k): depth = self.__dict__.get('depth', 'surface') if depth == 'surface': return Knee.defaults_surface[k] else: return Knee.defaults[k] def __setattr__(self, k, v): if self.in_setup_state and k in self.__dict__: raise InvalidKneeDef('%s has already been set' % k) else: self.__dict__[k] = v def __getattr__(self, k): if k.startswith('__'): raise AttributeError(k) if k not in self.__dict__: return self.default(k) def set_modes(self, in_leg, out_leg): if out_leg.departure == UP and ( (self.direction == UP) == self.reflection): raise InvalidKneeDef( 'cannot enter %s from %s and emit ray upwards' % ( ['conversion', 'reflection'][self.reflection], {UP: 'below', DOWN: 'above'}[self.direction])) if out_leg.departure == DOWN and ( (self.direction == DOWN) == self.reflection): raise InvalidKneeDef( 'cannot enter %s from %s and emit ray downwards' % ( ['conversion', 'reflection'][self.reflection], {UP: 'below', DOWN: 'above'}[self.direction])) self.in_mode = in_leg.mode self.out_mode = out_leg.mode def at_surface(self): return self.depth == 'surface'
[docs] def matches(self, discontinuity, mode, direction): ''' Check whether it is relevant to a given combination of interface, propagation mode, and direction. ''' if isinstance(self.depth, float): if abs(self.depth - discontinuity.z) > ZEPS: return False else: if discontinuity.name != self.depth: return False return self.direction == direction and self.in_mode == mode
[docs] def out_direction(self): ''' Get outgoing direction. Returns one of the constants :py:const:`UP` or :py:const:`DOWN`. ''' if self.reflection: return - self.direction else: return self.direction
def __str__(self): x = [] if self.reflection: if self.at_surface(): x.append('surface') else: if not self.headwave: if self.direction == UP: x.append('underside') else: x.append('upperside') if self.headwave: x.append('headwave propagation along') elif self.reflection and self.conversion: x.append('reflection with conversion from %s to %s' % ( smode(self.in_mode).upper(), smode(self.out_mode).upper())) if not self.at_surface(): x.append('at') elif self.reflection: x.append('reflection') if not self.at_surface(): x.append('at') elif self.conversion: x.append('conversion from %s to %s at' % ( smode(self.in_mode).upper(), smode(self.out_mode).upper())) else: x.append('passing through') if isinstance(self.depth, float): x.append('interface in %g km depth' % (self.depth/1000.)) else: if not self.at_surface(): x.append('%s' % self.depth) if not self.reflection: if self.direction == UP: x.append('on upgoing path') else: x.append('on downgoing path') return ' '.join(x)
[docs]class UnknownClassicPhase(CakeError): def __init__(self, phasename): self.phasename = phasename def __str__(self): return 'Unknown classic phase name: %s' % self.phasename
[docs]class PhaseDefParseError(CakeError): ''' Exception raised when an error occures during parsing of a phase definition string. ''' def __init__(self, definition, position, exception): self.definition = definition self.position = position self.exception = exception def __str__(self): return 'Invalid phase definition: "%s" (at character %i: %s)' % ( self.definition, self.position+1, str(self.exception))
[docs]class PhaseDef(object): ''' Definition of a seismic phase arrival, based on ray propagation path. :param definition: string representation of the phase in Cake's phase syntax Seismic phases are conventionally named e.g. P, Pn, PP, PcP, etc. In Cake, a slightly different terminology is adapted, which allows to specify arbitrary conversion/reflection histories for seismic ray paths. The conventions used here are inspired by those used in the TauP toolkit, but are not completely compatible with those. The definition of a seismic ray propagation path in Cake's phase syntax is a string consisting of an alternating sequence of *legs* and *knees*. A *leg* represents seismic wave propagation without any conversions, encountering only super-critical reflections. Legs are denoted by ``P``, ``p``, ``S``, or ``s``. The capital letters are used when the take-off of the *leg* is in downward direction, while the lower case letters indicate a take-off in upward direction. A *knee* is an interaction with an interface. It can be a mode conversion, a reflection, or propagation as a headwave or diffracted wave. * conversion is simply denoted as: ``(INTERFACE)`` or ``DEPTH`` * upperside reflection: ``v(INTERFACE)`` or ``vDEPTH`` * underside reflection: ``^(INTERFACE)`` or ``^DEPTH`` * normal kind headwave or diffracted wave: ``v_(INTERFACE)`` or ``v_DEPTH`` The interface may be given by name or by depth: INTERFACE is the name of an interface defined in the model, DEPTH is the depth of an interface in [km] (the interface closest to that depth is chosen). If two legs appear consecutively without an explicit *knee*, surface interaction is assumed. The phase definition may end with a backslash ``\\``, to indicate that the ray should arrive at the receiver from above instead of from below. It is possible to restrict the maximum and minimum depth of a *leg* by appending ``<(INTERFACE)`` or ``<DEPTH`` or ``>(INTERFACE)`` or ``>DEPTH`` after the leg character, respectively. **Examples:** * ``P`` - like the classical P, but includes PKP, PKIKP, Pg * ``P<(moho)`` - like classical Pg, but must leave source downwards * ``pP`` - leaves source upward, reflects at surface, then travels as P * ``P(moho)s`` - conversion from P to S at the Moho on upgoing path * ``P(moho)S`` - conversion from P to S at the Moho on downgoing path * ``Pv12p`` - P with reflection at 12 km deep interface (or the interface closest to that) * ``Pv_(moho)p`` - classical Pn * ``Pv_(cmb)p`` - classical Pdiff * ``P^(conrad)P`` - underside reflection of P at the Conrad discontinuity **Usage:** >>> from pyrocko.cake import PhaseDef # must escape the backslash >>> my_crazy_phase = PhaseDef('pPv(moho)sP\\\\') >>> print my_crazy_phase Phase definition "pPv(moho)sP\": - P mode propagation, departing upward - surface reflection - P mode propagation, departing downward - upperside reflection with conversion from P to S at moho - S mode propagation, departing upward - surface reflection with conversion from S to P - P mode propagation, departing downward - arriving at target from above .. note:: (1) These conventions might be extended in a way to allow to fix wave propagation to SH mode, possibly by specifying SH, or a single character (e.g. H) instead of S. This would be benificial for the selection of conversion and reflection coefficients, which currently only deal with the P-SV case. ''' allowed_characters_pattern = r'[0-9a-zA-Z_()<>^v\\.]+' allowed_characters_pattern_classic = r'[a-zA-Z0-9]+' @staticmethod def classic_definitions(): defs = {} # PmP, PmS, PcP, PcS, SmP, ... for r in 'mc': for a, b in 'PP PS SS SP'.split(): defs[a+r+b] = [ '%sv(%s)%s' % (a, {'m': 'moho', 'c': 'cmb'}[r], b.lower())] # Pg, P, S, Sg for a in 'PS': defs[a+'g'] = ['%s<(moho)' % x for x in (a, a.lower())] defs[a] = ['%s<(cmb)(moho)%s' % (x, x.lower()) for x in ( a, a.lower())] defs[a.lower()] = [a.lower()] for a, b in 'PP PS SS SP'.split(): defs[a+'K'+b] = ['%s(cmb)P<(icb)(cmb)%s' % (a, b.lower())] defs[a+'KIK'+b] = ['%s(cmb)P(icb)P(icb)p(cmb)%s' % (a, b.lower())] defs[a+'KJK'+b] = ['%s(cmb)P(icb)S(icb)p(cmb)%s' % (a, b.lower())] defs[a+'KiK'+b] = ['%s(cmb)Pv(icb)p(cmb)%s' % (a, b.lower())] # PP, SS, PS, SP, PPP, ... for a in 'PS': for b in 'PS': for c in 'PS': defs[a+b+c] = [''.join(defs[x][0] for x in a+b+c)] defs[a+b] = [''.join(defs[x][0] for x in a+b)] # Pc, Pdiff, Sc, ... for x in 'PS': defs[x+'c'] = defs[x+'diff'] = [x+'v_(cmb)'+x.lower()] defs[x+'n'] = [x+'v_(moho)'+x.lower()] # depth phases for k in list(defs.keys()): if k not in 'ps': for x in 'ps': defs[x+k] = [x + defs[k][0]] return defs
[docs] @staticmethod def classic(phasename): ''' Get phase definitions based on classic phase name. :param phasename: classic name of a phase :returns: list of PhaseDef objects This returns a list of PhaseDef objects, because some classic phases (like e.g. Pg) can only be represented by two Cake style PhaseDef objects (one with downgoing and one with upgoing first leg). ''' defs = PhaseDef.classic_definitions() if phasename not in defs: raise UnknownClassicPhase(phasename) return [PhaseDef(d, classicname=phasename) for d in defs[phasename]]
def __init__(self, definition=None, classicname=None): state = 0 sdepth = '' sinterface = '' depthmax = depthmin = None depthlim = None depthlimtype = None sdepthlim = '' events = [] direction_stop = UP need_leg = True ic = 0 if definition is not None: knee = Knee() try: for ic, c in enumerate(definition): if state in (0, 1): if c in '0123456789.': need_leg = True state = 1 sdepth += c continue elif state == 1: knee.depth = float(sdepth)*1000. state = 0 if state == 2: if c == ')': knee.depth = sinterface state = 0 else: sinterface += c continue if state in (3, 4): if state == 3: if c in '0123456789.': sdepthlim += c continue elif c == '(': state = 4 continue else: depthlim = float(sdepthlim)*1000. if depthlimtype == '<': depthmax = depthlim else: depthmin = depthlim state = 0 elif state == 4: if c == ')': depthlim = sdepthlim if depthlimtype == '<': depthmax = depthlim else: depthmin = depthlim state = 0 continue else: sdepthlim += c continue if state == 0: if c == '(': need_leg = True state = 2 continue elif c in '<>': state = 3 depthlim = None sdepthlim = '' depthlimtype = c continue elif c in 'psPS': leg = Leg() if c in 'ps': leg.departure = UP else: leg.departure = DOWN leg.mode = imode(c) if events: in_leg = events[-1] if depthmin is not None: in_leg.set_depthmin(depthmin) depthmin = None if depthmax is not None: in_leg.set_depthmax(depthmax) depthmax = None if in_leg.mode != leg.mode: knee.conversion = True else: knee.conversion = False if not knee.reflection: if c in 'ps': knee.direction = UP else: knee.direction = DOWN knee.set_modes(in_leg, leg) knee.in_setup_state = False events.append(knee) knee = Knee() sdepth = '' sinterface = '' events.append(leg) need_leg = False continue elif c == '^': need_leg = True knee.direction = UP knee.reflection = True continue elif c == 'v': need_leg = True knee.direction = DOWN knee.reflection = True continue elif c == '_': need_leg = True knee.headwave = True continue elif c == '\\': direction_stop = DOWN continue else: raise PhaseDefParseError( definition, ic, 'invalid character: "%s"' % c) if state == 3: depthlim = float(sdepthlim)*1000. if depthlimtype == '<': depthmax = depthlim else: depthmin = depthlim state = 0 except (ValueError, InvalidKneeDef) as e: raise PhaseDefParseError(definition, ic, e) if state != 0 or need_leg: raise PhaseDefParseError( definition, ic, 'unfinished expression') if events and depthmin is not None: events[-1].set_depthmin(depthmin) if events and depthmax is not None: events[-1].set_depthmax(depthmax) self._definition = definition self._classicname = classicname self._events = events self._direction_stop = direction_stop def __iter__(self): for ev in self._events: yield ev def append(self, ev): self._events.append(ev)
[docs] def first_leg(self): ''' Get the first leg in phase definition. ''' return self._events[0]
[docs] def last_leg(self): ''' Get the last leg in phase definition. ''' return self._events[-1]
[docs] def legs(self): ''' Iterate over the continuous pieces of wave propagation (legs) defined within this phase definition. ''' return (leg for leg in self if isinstance(leg, Leg))
[docs] def knees(self): ''' Iterate over conversions and reflections (knees) defined within this phase definition. ''' return (knee for knee in self if isinstance(knee, Knee))
[docs] def definition(self): ''' Get original definition of the phase. ''' return self._definition
[docs] def given_name(self): ''' Get entered classic name if any, or original definition of the phase. ''' if self._classicname: return self._classicname else: return self._definition
def direction_start(self): return self.first_leg().departure def direction_stop(self): return self._direction_stop def headwave_knee(self): for el in self: if type(el) == Knee and el.headwave: return el return None
[docs] def used_repr(self): ''' Translate into textual representation (cake phase syntax). ''' def strdepth(x): if isinstance(x, float): return '%g' % (x/1000.) else: return '(%s)' % x x = [] for el in self: if type(el) == Leg: if el.departure == UP: x.append(smode(el.mode).lower()) else: x.append(smode(el.mode).upper()) if el.depthmax is not None: x.append('<'+strdepth(el.depthmax)) if el.depthmin is not None: x.append('>'+strdepth(el.depthmin)) elif type(el) == Knee: if el.reflection and not el.at_surface(): if el.direction == DOWN: x.append('v') else: x.append('^') if el.headwave: x.append('_') if not el.at_surface(): x.append(strdepth(el.depth)) elif type(el) == Head: x.append('_') x.append(strdepth(el.depth)) if self._direction_stop == DOWN: x.append('\\') return ''.join(x)
def __repr__(self): if self._definition is not None: return "PhaseDef('%s')" % self._definition else: return "PhaseDef('%s')" % self.used_repr() def __str__(self): orig = '' used = self.used_repr() if self._definition != used: orig = ' (entered as "%s")' % self._definition sarrive = '\n - arriving at target from %s' % ('below', 'above')[ self._direction_stop == DOWN] return 'Phase definition "%s"%s:\n - ' % (used, orig) + \ '\n - '.join(str(ev) for ev in self) + sarrive
[docs] def copy(self): ''' Get a deep copy of it. ''' return copy.deepcopy(self)
def to_phase_defs(phases): if isinstance(phases, (str, newstr, PhaseDef)): phases = [phases] phases_out = [] for phase in phases: if isinstance(phase, (str, newstr)): phases_out.extend(PhaseDef(x.strip()) for x in phase.split(',')) elif isinstance(phase, PhaseDef): phases_out.append(phase) else: raise PhaseDefParseError('invalid phase definition') return phases_out def csswap(x): return cmath.sqrt(1.-x**2)
[docs]def psv_surface_ind(in_mode, out_mode): ''' Get indices to select the appropriate element from scatter matrix for free surface. ''' return (int(in_mode == S), int(out_mode == S))
[docs]def psv_surface(material, p, energy=False): ''' Scatter matrix for free surface reflection/conversions. :param material: material, object of type :py:class:`Material` :param p: flat ray parameter [s/m] :param energy: bool, when ``True`` energy normalized coefficients are returned :returns: Scatter matrix The scatter matrix is ordered as follows:: [[PP, PS], [SP, SS]] The formulas given in Aki & Richards are used. ''' vp, vs, rho = material.vp, material.vs, material.rho sinphi = p * vp sinlam = p * vs cosphi = csswap(sinphi) coslam = csswap(sinlam) if vs == 0.0: scatter = num.array([[-1.0, 0.0], [0.0, 1.0]]) else: vsp_term = (1.0/vs**2 - 2.0*p**2) pcc_term = 4.0 * p**2 * cosphi/vp * coslam/vs denom = vsp_term**2 + pcc_term scatter = num.array([ [- vsp_term**2 + pcc_term, 4.0*p*coslam/vp*vsp_term], [4.0*p*cosphi/vs*vsp_term, vsp_term**2 - pcc_term]], dtype=complex) / denom if not energy: return scatter else: eps = 1e-16 normvec = num.array([vp*rho*cosphi+eps, vs*rho*coslam+eps]) escatter = scatter*num.conj(scatter) * num.real( (normvec[:, num.newaxis]) / (normvec[num.newaxis, :])) return num.real(escatter)
[docs]def psv_solid_ind(in_direction, out_direction, in_mode, out_mode): ''' Get indices to select the appropriate element from scatter matrix for solid-solid interface. ''' return ( (out_direction == DOWN)*2 + (out_mode == S), (in_direction == UP)*2 + (in_mode == S))
[docs]def psv_solid(material1, material2, p, energy=False): ''' Scatter matrix for solid-solid interface. :param material1: material above, object of type :py:class:`Material` :param material2: material below, object of type :py:class:`Material` :param p: flat ray parameter [s/m] :param energy: bool, when ``True`` energy normalized coefficients are returned :returns: Scatter matrix The scatter matrix is ordered as follows:: [[P1P1, S1P1, P2P1, S2P1], [P1S1, S1S1, P2S1, S2S1], [P1P2, S1P2, P2P2, S2P2], [P1S2, S1S2, P2S2, S2S2]] The formulas given in Aki & Richards are used. ''' vp1, vs1, rho1 = material1.vp, material1.vs, material1.rho vp2, vs2, rho2 = material2.vp, material2.vs, material2.rho sinphi1 = p * vp1 cosphi1 = csswap(sinphi1) sinlam1 = p * vs1 coslam1 = csswap(sinlam1) sinphi2 = p * vp2 cosphi2 = csswap(sinphi2) sinlam2 = p * vs2 coslam2 = csswap(sinlam2) # from aki and richards M = num.array([ [-vp1*p, -coslam1, vp2*p, coslam2], [cosphi1, -vs1*p, cosphi2, -vs2*p], [2.0*rho1*vs1**2*p*cosphi1, rho1*vs1*(1.0-2.0*vs1**2*p**2), 2.0*rho2*vs2**2*p*cosphi2, rho2*vs2*(1.0-2.0*vs2**2*p**2)], [-rho1*vp1*(1.0-2.0*vs1**2*p**2), 2.0*rho1*vs1**2*p*coslam1, rho2*vp2*(1.0-2.0*vs2**2*p**2), -2.0*rho2*vs2**2*p*coslam2]], dtype=complex) N = M.copy() N[0] *= -1.0 N[3] *= -1.0 scatter = num.dot(num.linalg.inv(M), N) if not energy: return scatter else: eps = 1e-16 if vs1 == 0.: vs1 = vp1*1e-16 if vs2 == 0.: vs2 = vp2*1e-16 normvec = num.array([ vp1*rho1*(cosphi1+eps), vs1*rho1*(coslam1+eps), vp2*rho2*(cosphi2+eps), vs2*rho2*(coslam2+eps)], dtype=complex) escatter = scatter*num.conj(scatter) * num.real( normvec[:, num.newaxis] / normvec[num.newaxis, :]) return num.real(escatter)
[docs]class BadPotIntCoefs(CakeError): pass
def potint_coefs(c1, c2, r1, r2): # r2 > r1 eps = r2*1e-9 if c1 == 0. and c2 == 0.: c1c2 = 1. else: c1c2 = c1/c2 b = math.log(c1c2)/math.log((r1+eps)/r2) if abs(b) > 10.: raise BadPotIntCoefs() a = c1/(r1+eps)**b return a, b def imode(s): if s.lower() == 'p': return P elif s.lower() == 's': return S def smode(i): if i == P: return 'p' elif i == S: return 's'
[docs]class PathFailed(CakeError): pass
[docs]class SurfaceReached(PathFailed): pass
[docs]class BottomReached(PathFailed): pass
[docs]class MaxDepthReached(PathFailed): pass
[docs]class MinDepthReached(PathFailed): pass
[docs]class Trapped(PathFailed): pass
[docs]class NotPhaseConform(PathFailed): pass
[docs]class CannotPropagate(PathFailed): def __init__(self, direction, ilayer): PathFailed.__init__(self) self._direction = direction self._ilayer = ilayer def __str__(self): return 'Cannot enter layer %i from %s' % ( self._ilayer, { UP: 'below', DOWN: 'above'}[self._direction])
[docs]class Layer(object): ''' Representation of a layer in a layered earth model. :param ztop: depth of top of layer :param zbot: depth of bottom of layer :param name: name of layer (optional) Subclasses are: :py:class:`HomogeneousLayer` and :py:class:`GradientLayer`. ''' def __init__(self, ztop, zbot, name=None): self.ztop = ztop self.zbot = zbot self.zmid = (self.ztop + self.zbot) * 0.5 self.name = name self.ilayer = None def _update_potint_coefs(self): potint_p = potint_s = False try: self._ppic = potint_coefs( self.mbot.vp, self.mtop.vp, radius(self.zbot), radius(self.ztop)) potint_p = True except BadPotIntCoefs: pass potint_s = False try: self._spic = potint_coefs( self.mbot.vs, self.mtop.vs, radius(self.zbot), radius(self.ztop)) potint_s = True except BadPotIntCoefs: pass assert P == 1 and S == 2 self._use_potential_interpolation = (None, potint_p, potint_s)
[docs] def potint_coefs(self, mode): ''' Get coefficients for potential interpolation. :param mode: mode of wave propagation, :py:const:`P` or :py:const:`S` :returns: coefficients ``(a, b)`` ''' if mode == P: return self._ppic else: return self._spic
[docs] def contains(self, z): ''' Tolerantly check if a given depth is within the layer (including boundaries). ''' return self.ztop <= z <= self.zbot or \ self.at_bottom(z) or self.at_top(z)
[docs] def inner(self, z): ''' Tolerantly check if a given depth is within the layer (not including boundaries). ''' return self.ztop <= z <= self.zbot and not \ self.at_bottom(z) and not \ self.at_top(z)
[docs] def at_bottom(self, z): ''' Tolerantly check if given depth is at the bottom of the layer. ''' return abs(self.zbot - z) < ZEPS
[docs] def at_top(self, z): ''' Tolerantly check if given depth is at the top of the layer. ''' return abs(self.ztop - z) < ZEPS
[docs] def pflat_top(self, p): ''' Convert spherical ray parameter to local flat ray parameter for top of layer. ''' return p / (earthradius-self.ztop)
[docs] def pflat_bottom(self, p): ''' Convert spherical ray parameter to local flat ray parameter for bottom of layer. ''' return p / (earthradius-self.zbot)
[docs] def pflat(self, p, z): ''' Convert spherical ray parameter to local flat ray parameter for given depth. ''' return p / (earthradius-z)
def v_potint(self, mode, z): a, b = self.potint_coefs(mode) return a*(earthradius-z)**b def u_potint(self, mode, z): a, b = self.potint_coefs(mode) return 1./(a*(earthradius-z)**b)
[docs] def xt_potint(self, p, mode, zpart=None): ''' Get travel time and distance for for traversal with given mode and ray parameter. :param p: ray parameter (spherical) :param mode: mode of propagation (:py:const:`P` or :py:const:`S`) :param zpart: if given, tuple with two depths to restrict computation to a part of the layer This implementation uses analytic formulas valid for a spherical earth in the case where the velocity c within the layer is given by potential interpolation of the form c(z) = a*z^b ''' utop, ubot = self.u_top_bottom(mode) a, b = self.potint_coefs(mode) ztop = self.ztop zbot = self.zbot if zpart is not None: utop = self.u(mode, zpart[0]) ubot = self.u(mode, zpart[1]) ztop, zbot = zpart utop = 1./(a*(earthradius-ztop)**b) ubot = 1./(a*(earthradius-zbot)**b) r1 = radius(zbot) r2 = radius(ztop) burger_eta1 = r1 * ubot burger_eta2 = r2 * utop if b != 1: def cpe(eta): return num.arccos(num.minimum(p/num.maximum(eta, p/2), 1.0)) def sep(eta): return num.sqrt(num.maximum(eta**2 - p**2, 0.0)) x = (cpe(burger_eta2)-cpe(burger_eta1))/(1.0-b) t = (sep(burger_eta2)-sep(burger_eta1))/(1.0-b) else: lr = math.log(r2/r1) sap = num.sqrt(1.0/a**2 - p**2) x = p/sap * lr t = 1./(a**2 * sap) x *= r2d return x, t
[docs] def test(self, p, mode, z): ''' Check if wave mode can exist for given ray parameter at given depth within the layer. ''' return (self.u(mode, z)*radius(z) - p) > 0.
def tests(self, p, mode): utop, ubot = self.u_top_bottom(mode) return ( (utop * radius(self.ztop) - p) > 0., (ubot * radius(self.zbot) - p) > 0.)
[docs] def zturn_potint(self, p, mode): ''' Get turning depth for given ray parameter and propagation mode. ''' a, b = self.potint_coefs(mode) r = num.exp(num.log(a*p)/(1.0-b)) return earthradius-r
[docs] def propagate(self, p, mode, direction): ''' Propagate ray through layer. :param p: ray parameter :param mode: propagation mode :param direction: in direction (:py:const:`UP` or :py:const:`DOWN` ''' if direction == DOWN: zin, zout = self.ztop, self.zbot else: zin, zout = self.zbot, self.ztop if self.v(mode, zin) == 0.0 or not self.test(p, mode, zin): raise CannotPropagate(direction, self.ilayer) if not self.test(p, mode, zout): return -direction else: return direction
[docs] def resize(self, depth_min=None, depth_max=None): ''' Change layer thinkness and interpolate material if required. ''' if depth_min: mtop = self.material(depth_min) if depth_max: mbot = self.material(depth_max) self.mtop = mtop if depth_min else self.mtop self.mbot = mbot if depth_max else self.mbot self.ztop = depth_min if depth_min else self.ztop self.zbot = depth_max if depth_max else self.zbot self.zmid = self.ztop + (self.zbot - self.ztop)/2.
[docs]class DoesNotTurn(CakeError): pass
def radius(z): return earthradius - z
[docs]class HomogeneousLayer(Layer): ''' Representation of a homogeneous layer in a layered earth model. Base class: :py:class:`Layer`. ''' def __init__(self, ztop, zbot, m, name=None): Layer.__init__(self, ztop, zbot, name=name) self.m = m self.mtop = m self.mbot = m self._update_potint_coefs() def copy(self, ztop=None, zbot=None): if ztop is None: ztop = self.ztop if zbot is None: zbot = self.zbot return HomogeneousLayer(ztop, zbot, self.m, name=self.name) def material(self, z): return self.m def u(self, mode, z=None): if self._use_potential_interpolation[mode] and z is not None: return self.u_potint(mode, z) if mode == P: return 1./self.m.vp if mode == S: return 1./self.m.vs def u_top_bottom(self, mode): u = self.u(mode) return u, u def v(self, mode, z=None): if self._use_potential_interpolation[mode] and z is not None: return self.v_potint(mode, z) if mode == P: v = self.m.vp if mode == S: v = self.m.vs if num.isscalar(z): return v else: return filled(v, len(z)) def v_top_bottom(self, mode): v = self.v(mode) return v, v def xt(self, p, mode, zpart=None): if self._use_potential_interpolation[mode]: return self.xt_potint(p, mode, zpart) u = self.u(mode) pflat = self.pflat_bottom(p) if zpart is None: dz = (self.zbot - self.ztop) else: dz = abs(zpart[1]-zpart[0]) u = self.u(mode) eps = u*0.001 denom = num.sqrt(u**2 - pflat**2) + eps x = r2d*pflat/(earthradius-self.zmid) * dz / denom t = u**2 * dz / denom return x, t def zturn(self, p, mode): if self._use_potential_interpolation[mode]: return self.zturn_potint(p, mode) raise DoesNotTurn() def split(self, z): upper = HomogeneousLayer(self.ztop, z, self.m, name=self.name) lower = HomogeneousLayer(z, self.zbot, self.m, name=self.name) upper.ilayer = self.ilayer lower.ilayer = self.ilayer return upper, lower def __str__(self): if self.name: name = self.name + ' ' else: name = '' calcmode = ''.join('HP'[self._use_potential_interpolation[mode]] for mode in (P, S)) return ' (%i) homogeneous layer %s(%g km - %g km) [%s]\n %s' % ( self.ilayer, name, self.ztop/km, self.zbot/km, calcmode, self.m)
[docs]class GradientLayer(Layer): ''' Representation of a gradient layer in a layered earth model. Base class: :py:class:`Layer`. ''' def __init__(self, ztop, zbot, mtop, mbot, name=None): Layer.__init__(self, ztop, zbot, name=name) self.mtop = mtop self.mbot = mbot self._update_potint_coefs() def copy(self, ztop=None, zbot=None): if ztop is None: ztop = self.ztop if zbot is None: zbot = self.zbot return GradientLayer(ztop, zbot, self.mtop, self.mbot, name=self.name) def interpolate(self, z, ptop, pbot): return ptop + (z - self.ztop)*(pbot - ptop)/(self.zbot-self.ztop) def material(self, z): dtop = self.mtop.astuple() dbot = self.mbot.astuple() d = [ self.interpolate(z, ptop, pbot) for (ptop, pbot) in zip(dtop, dbot)] return Material(*d) def u_top_bottom(self, mode): if mode == P: return 1./self.mtop.vp, 1./self.mbot.vp if mode == S: return 1./self.mtop.vs, 1./self.mbot.vs def u(self, mode, z): if self._use_potential_interpolation[mode]: return self.u_potint(mode, z) if mode == P: return 1./self.interpolate(z, self.mtop.vp, self.mbot.vp) if mode == S: return 1./self.interpolate(z, self.mtop.vs, self.mbot.vs) def v_top_bottom(self, mode): if mode == P: return self.mtop.vp, self.mbot.vp if mode == S: return self.mtop.vs, self.mbot.vs def v(self, mode, z): if self._use_potential_interpolation[mode]: return self.v_potint(mode, z) if mode == P: return self.interpolate(z, self.mtop.vp, self.mbot.vp) if mode == S: return self.interpolate(z, self.mtop.vs, self.mbot.vs) def xt(self, p, mode, zpart=None): if self._use_potential_interpolation[mode]: return self.xt_potint(p, mode, zpart) utop, ubot = self.u_top_bottom(mode) b = (1./ubot - 1./utop)/(self.zbot - self.ztop) pflat = self.pflat_bottom(p) if zpart is not None: utop = self.u(mode, zpart[0]) ubot = self.u(mode, zpart[1]) peps = 1e-16 pdp = pflat + peps def func(u): eta = num.sqrt(num.maximum(u**2 - pflat**2, 0.0)) xx = eta/u tt = num.where( pflat <= u, num.log(u+eta) - num.log(pdp) - eta/u, 0.0) return xx, tt xxtop, tttop = func(utop) xxbot, ttbot = func(ubot) x = (xxtop - xxbot) / (b*pdp) t = (tttop - ttbot) / b + pflat*x x *= r2d/(earthradius - self.zmid) return x, t def zturn(self, p, mode): if self._use_potential_interpolation[mode]: return self.zturn_potint(p, mode) pflat = self.pflat_bottom(p) vtop, vbot = self.v_top_bottom(mode) return (1./pflat - vtop) * (self.zbot - self.ztop) / \ (vbot-vtop) + self.ztop def split(self, z): mmid = self.material(z) upper = GradientLayer(self.ztop, z, self.mtop, mmid, name=self.name) lower = GradientLayer(z, self.zbot, mmid, self.mbot, name=self.name) upper.ilayer = self.ilayer lower.ilayer = self.ilayer return upper, lower def __str__(self): if self.name: name = self.name + ' ' else: name = '' calcmode = ''.join('HP'[self._use_potential_interpolation[mode]] for mode in (P, S)) return ''' (%i) gradient layer %s(%g km - %g km) [%s] %s %s''' % ( self.ilayer, name, self.ztop/km, self.zbot/km, calcmode, self.mtop, self.mbot)
[docs]class Discontinuity(object): ''' Base class for discontinuities in layered earth model. Subclasses are: :py:class:`Interface` and :py:class:`Surface`. ''' def __init__(self, z, name=None): self.z = z self.zbot = z self.ztop = z self.name = name def change_depth(self, z): self.z = z self.zbot = z self.ztop = z def copy(self): return copy.deepcopy(self)
[docs]class Interface(Discontinuity): ''' Representation of an interface in a layered earth model. Base class: :py:class:`Discontinuity`. ''' def __init__(self, z, mabove, mbelow, name=None): Discontinuity.__init__(self, z, name) self.mabove = mabove self.mbelow = mbelow def __str__(self): if self.name is None: return 'interface' else: return 'interface "%s"' % self.name def u_top_bottom(self, mode): if mode == P: return reci_or_none(self.mabove.vp), reci_or_none(self.mbelow.vp) if mode == S: return reci_or_none(self.mabove.vs), reci_or_none(self.mbelow.vs) def critical_ps(self, mode): uabove, ubelow = self.u_top_bottom(mode) return ( mult_or_none(uabove, radius(self.z)), mult_or_none(ubelow, radius(self.z))) def propagate(self, p, mode, direction): uabove, ubelow = self.u_top_bottom(mode) if direction == DOWN: if ubelow is not None and ubelow*radius(self.z) - p >= 0: return direction else: return -direction if direction == UP: if uabove is not None and uabove*radius(self.z) - p >= 0: return direction else: return -direction def pflat(self, p): return p / (earthradius-self.z) def efficiency(self, in_direction, out_direction, in_mode, out_mode, p): scatter = psv_solid( self.mabove, self.mbelow, self.pflat(p), energy=True) return scatter[ psv_solid_ind(in_direction, out_direction, in_mode, out_mode)]
[docs]class Surface(Discontinuity): ''' Representation of the surface discontinuity in a layered earth model. Base class: :py:class:`Discontinuity`. ''' def __init__(self, z, mbelow): Discontinuity.__init__(self, z, 'surface') self.z = z self.mbelow = mbelow def propagate(self, p, mode, direction): return direction # no implicit reflection at surface def u_top_bottom(self, mode): if mode == P: return None, reci_or_none(self.mbelow.vp) if mode == S: return None, reci_or_none(self.mbelow.vs) def critical_ps(self, mode): _, ubelow = self.u_top_bottom(mode) return None, mult_or_none(ubelow, radius(self.z)) def pflat(self, p): return p / (earthradius-self.z) def efficiency(self, in_direction, out_direction, in_mode, out_mode, p): if in_direction == DOWN or out_direction == UP: return 0.0 else: return psv_surface( self.mbelow, self.pflat(p), energy=True)[ psv_surface_ind(in_mode, out_mode)] def __str__(self): return 'surface'
class Walker(object): def __init__(self, elements): self._elements = elements self._i = 0 def current(self): return self._elements[self._i] def go(self, direction): if direction == UP: self.up() else: self.down() def down(self): if self._i < len(self._elements)-1: self._i += 1 else: raise BottomReached() def up(self): if self._i > 0: self._i -= 1 else: raise SurfaceReached() def goto_layer(self, layer): self._i = self._elements.index(layer)
[docs]class RayElement(object): ''' An element of a :py:class:`RayPath`. ''' def __eq__(self, other): return type(self) == type(other) and self.__dict__ == other.__dict__ def is_straight(self): return isinstance(self, Straight) def is_kink(self): return isinstance(self, Kink)
[docs]class Straight(RayElement): ''' A ray segment representing wave propagation through one :py:class:`Layer`. ''' def __init__(self, direction_in, direction_out, mode, layer): self.mode = mode self._direction_in = direction_in self._direction_out = direction_out self.layer = layer def angle_in(self, p, endgaps=None): z = self.z_in(endgaps) dir = self.eff_direction_in(endgaps) v = self.layer.v(self.mode, z) pf = self.layer.pflat(p, z) if dir == DOWN: return num.arcsin(v*pf)*r2d else: return 180.-num.arcsin(v*pf)*r2d def angle_out(self, p, endgaps=None): z = self.z_out(endgaps) dir = self.eff_direction_out(endgaps) v = self.layer.v(self.mode, z) pf = self.layer.pflat(p, z) if dir == DOWN: return 180.-num.arcsin(v*pf)*r2d else: return num.arcsin(v*pf)*r2d def pflat_in(self, p, endgaps=None): return p / (earthradius-self.z_in(endgaps)) def pflat_out(self, p, endgaps=None): return p / (earthradius-self.z_out(endgaps)) def test(self, p, z): return self.layer.test(p, self.mode, z) def z_in(self, endgaps=None): if endgaps is not None: return endgaps[0] else: lyr = self.layer return (lyr.ztop, lyr.zbot)[self._direction_in == UP] def z_out(self, endgaps=None): if endgaps is not None: return endgaps[1] else: lyr = self.layer return (lyr.ztop, lyr.zbot)[self._direction_out == DOWN] def turns(self): return self._direction_in != self._direction_out def eff_direction_in(self, endgaps=None): if endgaps is None: return self._direction_in else: return endgaps[2] def eff_direction_out(self, endgaps=None): if endgaps is None: return self._direction_out else: return endgaps[3] def zturn(self, p): lyr = self.layer return lyr.zturn(p, self.mode) def u_in(self, endgaps=None): return self.layer.u(self.mode, self.z_in(endgaps)) def u_out(self, endgaps=None): return self.layer.u(self.mode, self.z_out(endgaps)) def critical_p_in(self, endgaps=None): z = self.z_in(endgaps) return self.layer.u(self.mode, z)*radius(z) def critical_p_out(self, endgaps=None): z = self.z_out(endgaps) return self.layer.u(self.mode, z)*radius(z) def xt(self, p, zpart=None): x, t = self.layer.xt(p, self.mode, zpart=zpart) if self._direction_in != self._direction_out and zpart is None: x *= 2. t *= 2. return x, t def xt_gap(self, p, zstart, zstop, samedir): z1, z2 = zstart, zstop if z1 > z2: z1, z2 = z2, z1 x, t = self.layer.xt(p, self.mode, zpart=(z1, z2)) if samedir: return x, t else: xfull, tfull = self.xt(p) return xfull-x, tfull-t def __hash__(self): return hash(( self._direction_in, self._direction_out, self.mode, id(self.layer)))
[docs]class HeadwaveStraight(Straight): def __init__(self, direction_in, direction_out, mode, interface): Straight.__init__(self, direction_in, direction_out, mode, None) self.interface = interface def z_in(self, zpart=None): return self.interface.z def z_out(self, zpart=None): return self.interface.z def zturn(self, p): return filled(self.interface.z, len(p)) def xt(self, p, zpart=None): return 0., 0. def x2t_headwave(self, xstretch): xstretch_m = xstretch*d2r*radius(self.interface.z) return min_not_none(*self.interface.u_top_bottom(self.mode))*xstretch_m
[docs]class Kink(RayElement): ''' An interaction of a ray with a :py:class:`Discontinuity`. ''' def __init__( self, in_direction, out_direction, in_mode, out_mode, discontinuity): self.in_direction = in_direction self.out_direction = out_direction self.in_mode = in_mode self.out_mode = out_mode self.discontinuity = discontinuity def reflection(self): return self.in_direction != self.out_direction def conversion(self): return self.in_mode != self.out_mode def efficiency(self, p, out_direction=None, out_mode=None): if out_direction is None: out_direction = self.out_direction if out_mode is None: out_mode = self.out_mode return self.discontinuity.efficiency( self.in_direction, out_direction, self.in_mode, out_mode, p) def __str__(self): r, c = self.reflection(), self.conversion() if r and c: return '|~' if r: return '|' if c: return '~' return '_' def __hash__(self): return hash(( self.in_direction, self.out_direction, self.in_mode, self.out_mode, id(self.discontinuity)))
[docs]class PRangeNotSet(CakeError): pass
[docs]class RayPath(object): ''' Representation of a fan of rays running through a common sequence of layers / interfaces. ''' def __init__(self, phase): self.elements = [] self.phase = phase self._pmax = None self._pmin = None self._p = None self._is_headwave = False def set_is_headwave(self, is_headwave): self._is_headwave = is_headwave
[docs] def copy(self): ''' Get a copy of it. ''' c = copy.copy(self) c.elements = list(self.elements) return c
[docs] def endgaps(self, zstart, zstop): ''' Get information needed for end point adjustments. ''' return ( zstart, zstop, self.phase.direction_start(), self.phase.direction_stop())
def append(self, element): self.elements.append(element) def _check_have_prange(self): if self._pmax is None: raise PRangeNotSet() def set_prange(self, pmin, pmax, dp): self._pmin, self._pmax = pmin, pmax self._prange_dp = dp
[docs] def used_phase(self, p=None, eps=1.): ''' Calculate phase definition from ray path. ''' used = PhaseDef() fleg = self.phase.first_leg() used.append(Leg(fleg.departure, fleg.mode)) n_elements_n = [None] + self.elements + [None] for before, element, after in zip( n_elements_n[:-2], n_elements_n[1:-1], n_elements_n[2:]): if element.is_kink() and HeadwaveStraight not in ( type(before), type(after)): if element.reflection() or element.conversion(): z = element.discontinuity.z used.append(Knee( z, element.in_direction, element.out_direction != element.in_direction, element.in_mode, element.out_mode)) used.append(Leg(element.out_direction, element.out_mode)) elif type(element) is HeadwaveStraight: z = element.interface.z k = Knee( z, before.in_direction, after.out_direction != before.in_direction, before.in_mode, after.out_mode) k.headwave = True used.append(k) used.append(Leg(after.out_direction, after.out_mode)) if (p is not None and before and after and element.is_straight() and before.is_kink() and after.is_kink() and element.turns() and not before.reflection() and not before.conversion() and not after.reflection() and not after.conversion()): ai = element.angle_in(p) if 90.0-eps < ai and ai < 90+eps: used.append( Head( before.discontinuity.z, before.out_direction, element.mode)) used.append( Leg(-before.out_direction, element.mode)) used._direction_stop = self.phase.direction_stop() used._definition = self.phase.definition() return used
[docs] def pmax(self): ''' Get maximum valid ray parameter. ''' self._check_have_prange() return self._pmax
[docs] def pmin(self): ''' Get minimum valid ray parameter. ''' self._check_have_prange() return self._pmin
[docs] def xmin(self): ''' Get minimal distance. ''' self._analyse() return self._xmin
[docs] def xmax(self): ''' Get maximal distance. ''' self._analyse() return self._xmax
[docs] def kinks(self): ''' Iterate over propagation mode changes (reflections/transmissions). ''' return (k for k in self.elements if isinstance(k, Kink))
[docs] def straights(self): ''' Iterate over ray segments. ''' return (s for s in self.elements if isinstance(s, Straight))
def headwave_straight(self): for s in self.elements: if type(s) is HeadwaveStraight: return s
[docs] def first_straight(self): ''' Get first ray segment. ''' for s in self.elements: if isinstance(s, Straight): return s
[docs] def last_straight(self): ''' Get last ray segment. ''' for s in reversed(self.elements): if isinstance(s, Straight): return s
[docs] def efficiency(self, p): ''' Get product of all conversion/reflection coefficients encountered on path. ''' return reduce( operator.mul, (k.efficiency(p) for k in self.kinks()), 1.)
[docs] def spreading(self, p, endgaps): ''' Get geometrical spreading factor. ''' if self._is_headwave: return 0.0 self._check_have_prange() dp = self._prange_dp * 0.01 assert self._pmax - self._pmin > dp if p + dp > self._pmax: p = p-dp x0, t = self.xt(p, endgaps) x1, t = self.xt(p+dp, endgaps) x0 *= d2r x1 *= d2r if x1 == x0: return num.nan dp_dx = dp/(x1-x0) x = x0 if x == 0.: x = x1 p = dp first = self.first_straight() last = self.last_straight() return num.abs(dp_dx) * first.pflat_in(p, endgaps) / ( 4.0 * math.pi * num.sin(x) * (earthradius-first.z_in(endgaps)) * (earthradius-last.z_out(endgaps))**2 * first.u_in(endgaps)**2 * num.abs(num.cos(first.angle_in(p, endgaps)*d2r)) * num.abs(num.cos(last.angle_out(p, endgaps)*d2r)))
def make_p(self, dp=None, n=None, nmin=None): assert dp is None or n is None if self._pmin == self._pmax: return num.array([self._pmin]) if dp is None: dp = self._prange_dp if n is None: n = int(round((self._pmax-self._pmin)/dp)) + 1 if nmin is not None: n = max(n, nmin) ppp = num.linspace(self._pmin, self._pmax, n) return ppp
[docs] def xt_endgaps(self, p, endgaps, which='both'): ''' Get amount of distance/traveltime to be subtracted at the generic ray path's ends. ''' zstart, zstop, dirstart, dirstop = endgaps firsts = self.first_straight() lasts = self.last_straight() xs, ts = firsts.xt_gap( p, zstart, firsts.z_in(), dirstart == firsts._direction_in) xe, te = lasts.xt_gap( p, zstop, lasts.z_out(), dirstop == lasts._direction_out) if which == 'both': return xs + xe, ts + te elif which == 'left': return xs, ts elif which == 'right': return xe, te
[docs] def xt_endgaps_ptest(self, p, endgaps): ''' Check if ray parameter is valid at source and receiver. ''' zstart, zstop, dirstart, dirstop = endgaps firsts = self.first_straight() lasts = self.last_straight() return num.logical_and(firsts.test(p, zstart), lasts.test(p, zstop))
[docs] def xt(self, p, endgaps): ''' Calculate distance and traveltime for given ray parameter. ''' if isinstance(p, num.ndarray): sx = num.zeros(p.size) st = num.zeros(p.size) else: sx = 0.0 st = 0.0 for s in self.straights(): x, t = s.xt(p) sx += x st += t if endgaps: dx, dt = self.xt_endgaps(p, endgaps) sx -= dx st -= dt return sx, st
[docs] def xt_limits(self, p): ''' Calculate limits of distance and traveltime for given ray parameter. ''' if isinstance(p, num.ndarray): sx = num.zeros(p.size) st = num.zeros(p.size) sxe = num.zeros(p.size) ste = num.zeros(p.size) else: sx = 0.0 st = 0.0 sxe = 0.0 ste = 0.0 sfirst = self.first_straight() slast = self.last_straight() for s in self.straights(): if s is not sfirst and s is not slast: x, t = s.xt(p) sx += x st += t sends = [sfirst] if sfirst is not slast: sends.append(slast) for s in sends: x, t = s.xt(p) sxe += x ste += t return sx, (sx + sxe), st, (st + ste)
[docs] def iter_zxt(self, p): ''' Iterate over (depth, distance, traveltime) at each layer interface on ray path. ''' sx = num.zeros(p.size) st = num.zeros(p.size) ok = False for s in self.straights(): yield s.z_in(), sx.copy(), st.copy() x, t = s.xt(p) sx += x st += t ok = True if ok: yield s.z_out(), sx.copy(), st.copy()
[docs] def zxt_path_subdivided( self, p, endgaps, points_per_straight=20, x_for_headwave=None): ''' Get geometrical representation of ray path. ''' if self._is_headwave: assert p.size == 1 x, t = self.xt(p, endgaps) xstretch = x_for_headwave-x nout = xstretch.size else: nout = p.size dxl, dtl = self.xt_endgaps(p, endgaps, which='left') dxr, dtr = self.xt_endgaps(p, endgaps, which='right') # first create full path including the endgaps sx = num.zeros(nout) - dxl st = num.zeros(nout) - dtl zxt = [] for s in self.straights(): n = points_per_straight back = None zin, zout = s.z_in(), s.z_out() if type(s) is HeadwaveStraight: z = zin for i in range(n): xs = float(i)/(n-1) * xstretch ts = s.x2t_headwave(xs) zxt.append((filled(z, xstretch.size), sx+xs, st+ts)) else: if zin != zout: # normal traversal zs = num.linspace(zin, zout, n).tolist() for z in zs: x, t = s.xt(p, zpart=sorted([zin, z])) zxt.append((filled(z, nout), sx + x, st + t)) else: # ray turns in layer zturn = s.zturn(p) back = [] for i in range(n): z = zin + (zturn - zin) * num.sin( float(i)/(n-1)*math.pi/2.0) * 0.999 if zturn[0] >= zin: x, t = s.xt(p, zpart=[zin, z]) else: x, t = s.xt(p, zpart=[z, zin]) zxt.append((z, sx + x, st + t)) back.append((z, x, t)) if type(s) is HeadwaveStraight: x = xstretch t = s.x2t_headwave(xstretch) else: x, t = s.xt(p) sx += x st += t if back: for z, x, t in reversed(back): zxt.append((z, sx - x, st - t)) # gather results as arrays with such that x[ip, ipoint] fanz, fanx, fant = [], [], [] for z, x, t in zxt: fanz.append(z) fanx.append(x) fant.append(t) z = num.array(fanz).T x = num.array(fanx).T t = num.array(fant).T # cut off the endgaps, add exact endpoints xmax = x[:, -1] - dxr tmax = t[:, -1] - dtr zstart, zstop = endgaps[:2] zs, xs, ts = [], [], [] for i in range(nout): t_ = t[i] indices = num.where(num.logical_and(0. <= t_, t_ <= tmax[i]))[0] n = indices.size + 2 zs_, xs_, ts_ = [num.empty(n, dtype=float) for j in range(3)] zs_[1:-1] = z[i, indices] xs_[1:-1] = x[i, indices] ts_[1:-1] = t[i, indices] zs_[0], zs_[-1] = zstart, zstop xs_[0], xs_[-1] = 0., xmax[i] ts_[0], ts_[-1] = 0., tmax[i] zs.append(zs_) xs.append(xs_) ts.append(ts_) return zs, xs, ts
def _analyse(self): if self._p is not None: return p = self.make_p(nmin=20) xmin, xmax, tmin, tmax = self.xt_limits(p) self._x, self._t, self._p = xmax, tmax, p self._xmin, self._xmax = xmin.min(), xmax.max() self._tmin, self._tmax = tmin.min(), tmax.max() def draft_pxt(self, endgaps): self._analyse() if not self._is_headwave: cp, cx, ct = self._p, self._x, self._t pcrit = min( self.critical_pstart(endgaps), self.critical_pstop(endgaps)) if pcrit < self._pmin: empty = num.array([], dtype=float) return empty, empty, empty elif pcrit >= self._pmax: dx, dt = self.xt_endgaps(cp, endgaps) return cp, cx-dx, ct-dt else: n = num.searchsorted(cp, pcrit) + 1 rp, rx, rt = num.empty((3, n), dtype=float) rp[:-1] = cp[:n-1] rx[:-1] = cx[:n-1] rt[:-1] = ct[:n-1] rp[-1] = pcrit rx[-1], rt[-1] = self.xt(pcrit, endgaps) dx, dt = self.xt_endgaps(rp, endgaps) rx[:-1] -= dx[:-1] rt[:-1] -= dt[:-1] return rp, rx, rt else: dx, dt = self.xt_endgaps(self._p, endgaps) p, x, t = self._p, self._x - dx, self._t - dt p, x, t = p[0], x[0], t[0] xh = num.linspace(0., x*10-x, 10) th = self.headwave_straight().x2t_headwave(xh) return filled(p, xh.size), x+xh, t+th
[docs] def interpolate_x2pt_linear(self, x, endgaps): ''' Get approximate ray parameter and traveltime for distance. ''' self._analyse() if self._is_headwave: dx, dt = self.xt_endgaps(self._p, endgaps) xmin = self._x[0] - dx[0] tmin = self._t[0] - dt[0] el = self.headwave_straight() xok = x[x >= xmin] th = el.x2t_headwave(xstretch=(xok-xmin)) + tmin return [ (x_, self._p[0], t, None) for (x_, t) in zip(xok, th)] else: if num.all(x < self._xmin) or num.all(self._xmax < x): return [] rp, rx, rt = self.draft_pxt(endgaps) xp = interp(x, rx, rp, 0) xt = interp(x, rx, rt, 0) if (rp.size and len(xp) == 0 and rx[0] == 0.0 and any(x == 0.0) and rp[0] == 0.0): xp = [(0.0, rp[0])] xt = [(0.0, rt[0])] return [ (x_, p, t, (rp, rx, rt)) for ((x_, p), (_, t)) in zip(xp, xt)]
def __eq__(self, other): if len(self.elements) != len(other.elements): return False return all(a == b for a, b in zip(self.elements, other.elements)) def __hash__(self): return hash( tuple(hash(x) for x in self.elements) + (self.phase.definition(), )) def __str__(self, p=None, eps=1.): x = [] start_i = None end_i = None turn_i = None def append_layers(si, ei, ti): if si == ei and (ti is None or ti == si): x.append('%i' % si) else: if ti is not None: x.append('(%i-%i-%i)' % (si, ti, ei)) else: x.append('(%i-%i)' % (si, ei)) for el in self.elements: if type(el) is Straight: if start_i is None: start_i = el.layer.ilayer if el._direction_in != el._direction_out: turn_i = el.layer.ilayer end_i = el.layer.ilayer elif isinstance(el, Kink): if start_i is not None: append_layers(start_i, end_i, turn_i) start_i = None turn_i = None x.append(str(el)) if start_i is not None: append_layers(start_i, end_i, turn_i) su = '(%s)' % self.used_phase(p=p, eps=eps).used_repr() return '%-15s %-17s %s' % (self.phase.definition(), su, ''.join(x))
[docs] def critical_pstart(self, endgaps): ''' Get critical ray parameter for source depth choice. ''' return self.first_straight().critical_p_in(endgaps)
[docs] def critical_pstop(self, endgaps): ''' Get critical ray parameter for receiver depth choice. ''' return self.last_straight().critical_p_out(endgaps)
[docs] def ranges(self, endgaps): ''' Get valid ranges of ray parameter, distance, and traveltime. ''' p, x, t = self.draft_pxt(endgaps) return p.min(), p.max(), x.min(), x.max(), t.min(), t.max()
[docs] def describe(self, endgaps=None, as_degrees=False): ''' Get textual representation. ''' self._analyse() if as_degrees: xunit = 'deg' xfact = 1. else: xunit = 'km' xfact = d2m/km sg = ''' Ranges for all depths in source and receiver layers: - x [%g, %g] %s - t [%g, %g] s - p [%g, %g] s/deg ''' % ( self._xmin*xfact, self._xmax*xfact, xunit, self._tmin, self._tmax, self._pmin/r2d, self._pmax/r2d) if endgaps is not None: pmin, pmax, xmin, xmax, tmin, tmax = self.ranges(endgaps) ss = ''' Ranges for given source and receiver depths: \n - x [%g, %g] %s \n - t [%g, %g] s \n - p [%g, %g] s/deg \n''' % (xmin*xfact, xmax*xfact, xunit, tmin, tmax, pmin/r2d, pmax/r2d) else: ss = '' return '%s\n' % self + ss + sg
[docs]class RefineFailed(CakeError): pass
[docs]class Ray(object): ''' Representation of a ray with a specific (path, ray parameter, distance, arrival time) choice. **Attributes:** .. py:attribute:: path :py:class:`RayPath` object containing complete propagation history. .. py:attribute:: p Ray parameter (spherical) [s/rad] .. py:attribute:: x Radial distance [deg] .. py:attribute:: t Traveltime [s] .. py:attribute:: endgaps Needed for source/receiver depth adjustments in many :py:class:`RayPath` methods. ''' def __init__(self, path, p, x, t, endgaps, draft_pxt): self.path = path self.p = p self.x = x self.t = t self.endgaps = endgaps self.draft_pxt = draft_pxt
[docs] def given_phase(self): ''' Get phase definition which was used to create the ray. :returns: :py:class:`PhaseDef` object ''' return self.path.phase
[docs] def used_phase(self): ''' Compute phase definition from propagation path. :returns: :py:class:`PhaseDef` object ''' return self.path.used_phase(self.p)
def refine(self): if self.path._is_headwave: return if self.t == 0.0 and self.p == 0.0 and self.x == 0.0: return cp, cx, ct = self.draft_pxt ip = num.searchsorted(cp, self.p) if not (0 < ip < cp.size): raise RefineFailed() pl, ph = cp[ip-1], cp[ip] p_to_t = {} i = [0] def f(p): i[0] += 1 x, t = self.path.xt(p, self.endgaps) p_to_t[p] = t return self.x - x try: self.p = brentq(f, pl, ph) self.t = p_to_t[self.p] except ValueError: raise RefineFailed()
[docs] def takeoff_angle(self): ''' Get takeoff angle of ray. The angle is returned in [degrees]. ''' return self.path.first_straight().angle_in(self.p, self.endgaps)
[docs] def incidence_angle(self): ''' Get incidence angle of ray. The angle is returned in [degrees]. ''' return self.path.last_straight().angle_out(self.p, self.endgaps)
[docs] def efficiency(self): ''' Get conversion/reflection efficiency of the ray. A value between 0 and 1 is returned, reflecting the relative amount of energy which is transmitted along the ray and not lost by reflections or conversions. ''' return self.path.efficiency(self.p)
[docs] def spreading(self): ''' Get geometrical spreading factor. ''' return self.path.spreading(self.p, self.endgaps)
def surface_sphere(self): x1, y1 = 0., earthradius - self.endgaps[0] r2 = earthradius - self.endgaps[1] x2, y2 = r2*math.sin(self.x*d2r), r2*math.cos(self.x*d2r) return ((x2-x1)**2 + (y2-y1)**2)*4.0*math.pi
[docs] def zxt_path_subdivided(self, points_per_straight=20): ''' Get geometrical representation of ray path. Three arrays (depth, distance, time) with points on the ray's path of propagation are returned. The number of points which are used in each ray segment (passage through one layer) may be controlled by the ``points_per_straight`` parameter. ''' return self.path.zxt_path_subdivided( num.atleast_1d(self.p), self.endgaps, points_per_straight=points_per_straight, x_for_headwave=num.atleast_1d(self.x))
def __str__(self, as_degrees=False): if as_degrees: sd = '%6.3g deg' % self.x else: sd = '%7.5g km' % (self.x*(d2r*earthradius/km)) return '%7.5g s/deg %s %6.4g s %5.1f %5.1f %3.0f%% %3.0f%% %s' % ( self.p/r2d, sd, self.t, self.takeoff_angle(), self.incidence_angle(), 100*self.efficiency(), 100*self.spreading()*self.surface_sphere(), self.path.__str__(p=self.p))
def anything_to_crust2_profile(crust2_profile): from pyrocko.dataset import crust2x2 if isinstance(crust2_profile, tuple): lat, lon = [float(x) for x in crust2_profile] return crust2x2.get_profile(lat, lon) elif isinstance(crust2_profile, (str, newstr)): return crust2x2.get_profile(crust2_profile) elif isinstance(crust2_profile, crust2x2.Crust2Profile): return crust2_profile else: assert False, 'crust2_profile must be (lat, lon) a profile ' \ 'key or a crust2x2 Profile object)'
[docs]class DiscontinuityNotFound(CakeError): def __init__(self, depth_or_name): CakeError.__init__(self) self.depth_or_name = depth_or_name def __str__(self): return 'Cannot find discontinuity from given depth or name: %s' % \ self.depth_or_name
[docs]class LayeredModelError(CakeError): pass
[docs]class LayeredModel(object): ''' Representation of a layer cake model. There are several ways to initialize an instance of this class. 1. Use the module function :py:func:`load_model` to read a model from a file. 2. Create an empty model with the default constructor and append layers and discontinuities with the :py:meth:`append` method (from top to bottom). 3. Use the constructor :py:meth:`LayeredModel.from_scanlines`, to automatically create the :py:class:`Layer` and :py:class:`Discontinuity` objects from a given velocity profile. An earth model is represented by as stack of :py:class:`Layer` and :py:class:`Discontinuity` objects. The method :py:meth:`arrivals` returns :py:class:`Ray` objects which may be e.g. queried for arrival times of specific phases. Each ray is associated with a :py:class:`RayPath` object. Ray objects share common ray paths if they have the same conversion/reflection/propagation history. Creating the ray path objects is relatively expensive (this is done in :py:meth:`gather_paths`), but they are cached for reuse in successive invocations. ''' def __init__(self): self._surface_material = None self._elements = [] self.nlayers = 0 self._np = 10000 self._pdepth = 5 self._pathcache = {}
[docs] def copy_with_elevation(self, elevation): ''' Get copy of the model with surface layer stretched to given elevation. :param elevation: new surface elevation in [m] Elevation is positiv upward, contrary to the layered models downward `z` axis. ''' c = copy.deepcopy(self) c._pathcache = {} surface = c._elements[0] toplayer = c._elements[1] assert toplayer.zbot > -elevation surface.z = -elevation c._elements[1] = toplayer.copy(ztop=-elevation) c._elements[1].ilayer = 0 return c
def zeq(self, z1, z2): return abs(z1-z2) < ZEPS
[docs] def append(self, element): ''' Add a layer or discontinuity at bottom of model. :param element: object of subclass of :py:class:`Layer` or :py:class:`Discontinuity`. ''' if isinstance(element, Layer): if element.zbot >= earthradius: element.zbot = earthradius - 1. if element.ztop >= earthradius: raise CakeError('Layer deeper than earthradius') element.ilayer = self.nlayers self.nlayers += 1 self._elements.append(element)
[docs] def elements(self, direction=DOWN): ''' Iterate over all elements of the model. :param direction: direction of traversal :py:const:`DOWN` or :py:const:`UP`. Objects derived from the :py:class:`Discontinuity` and :py:class:`Layer` classes are yielded. ''' if direction == DOWN: return iter(self._elements) else: return reversed(self._elements)
[docs] def layers(self, direction=DOWN): ''' Iterate over all layers of model. :param direction: direction of traversal :py:const:`DOWN` or :py:const:`UP`. Objects derived from the :py:class:`Layer` class are yielded. ''' if direction == DOWN: return (el for el in self._elements if isinstance(el, Layer)) else: return ( el for el in reversed(self._elements) if isinstance(el, Layer))
[docs] def layer(self, z, direction=DOWN): ''' Get layer for given depth. :param z: depth [m] :param direction: direction of traversal :py:const:`DOWN` or :py:const:`UP`. Returns first layer which touches depth ``z`` (tolerant at boundaries). ''' for layer in self.layers(direction): if layer.contains(z): return layer else: raise CakeError('Failed extracting layer at depth z=%s' % z)
def walker(self): return Walker(self._elements)
[docs] def material(self, z, direction=DOWN): ''' Get material at given depth. :param z: depth [m] :param direction: direction of traversal :py:const:`DOWN` or :py:const:`UP` :returns: object of type :py:class:`Material` If given depth ``z`` happens to be at an interface, the material of the first layer with respect to the the traversal ordering is returned. ''' lyr = self.layer(z, direction) return lyr.material(z)
[docs] def discontinuities(self): ''' Iterate over all discontinuities of the model.''' return (el for el in self._elements if isinstance(el, Discontinuity))
[docs] def discontinuity(self, name_or_z): ''' Get discontinuity by name or depth. :param name_or_z: name of discontinuity or depth [m] as float value ''' if isinstance(name_or_z, float): candi = sorted( self.discontinuities(), key=lambda i: abs(i.z-name_or_z)) else: candi = [i for i in self.discontinuities() if i.name == name_or_z] if not candi: raise DiscontinuityNotFound(name_or_z) return candi[0]
[docs] def adapt_phase(self, phase): ''' Adapt a phase definition for use with this model. This returns a copy of the phase definition, where named discontinuities are replaced with the actual depth of these, as defined in the model. ''' phase = phase.copy() for knee in phase.knees(): if knee.depth != 'surface': knee.depth = self.discontinuity(knee.depth).z for leg in phase.legs(): if leg.depthmax is not None and isinstance(leg.depthmax, str): leg.depthmax = self.discontinuity(leg.depthmax).z return phase
[docs] def path(self, p, phase, layer_start, layer_stop): ''' Get ray path for given combination of ray parameter, phase definition, source and receiver layers. :param p: ray parameter (spherical) [s/rad] :param phase: phase definition (:py:class:`PhaseDef` object) :param layer_start: layer with source :param layer_stop: layer with receiver :returns: :py:class:`RayPath` object If it is not possible to find a solution, an exception of type :py:exc:`NotPhaseConform`, :py:exc:`MinDepthReached`, :py:exc:`MaxDepthReached`, :py:exc:`CannotPropagate`, :py:exc:`BottomReached` or :py:exc:`SurfaceReached` is raised. ''' phase = self.adapt_phase(phase) knees = phase.knees() legs = phase.legs() next_knee = next_or_none(knees) leg = next_or_none(legs) assert leg is not None direction = leg.departure direction_stop = phase.direction_stop() mode = leg.mode mode_stop = phase.last_leg().mode walker = self.walker() walker.goto_layer(layer_start) current = walker.current() ttop, tbot = current.tests(p, mode) if not ttop and not tbot: raise CannotPropagate(direction, current.ilayer) if (direction == DOWN and not ttop) or (direction == UP and not tbot): direction = -direction path = RayPath(phase) trapdetect = set() while True: at_layer = isinstance(current, Layer) at_discontinuity = isinstance(current, Discontinuity) # detect trapped wave k = (id(next_knee), id(current), direction, mode) if k in trapdetect: raise Trapped() trapdetect.add(k) if at_discontinuity: oldmode, olddirection = mode, direction headwave = False if next_knee is not None and next_knee.matches( current, mode, direction): headwave = next_knee.headwave direction = next_knee.out_direction() mode = next_knee.out_mode next_knee = next_or_none(knees) leg = next(legs) else: # implicit reflection/transmission direction = current.propagate(p, mode, direction) if headwave: path.set_is_headwave(True) path.append(Kink( olddirection, olddirection, oldmode, oldmode, current)) path.append(HeadwaveStraight( olddirection, direction, oldmode, current)) path.append(Kink( olddirection, direction, oldmode, mode, current)) else: path.append(Kink( olddirection, direction, oldmode, mode, current)) if at_layer: direction_in = direction direction = current.propagate(p, mode, direction_in) zturn = None if direction_in != direction: zturn = current.zturn(p, mode) zmin, zmax = leg.depthmin, leg.depthmax if zmin is not None or zmax is not None: if direction_in != direction: if zmin is not None and zturn <= zmin: raise MinDepthReached() if zmax is not None and zturn >= zmax: raise MaxDepthReached() else: if zmin is not None and current.ztop <= zmin: raise MinDepthReached() if zmax is not None and current.zbot >= zmax: raise MaxDepthReached() path.append(Straight(direction_in, direction, mode, current)) if next_knee is None and mode == mode_stop and \ current is layer_stop: if zturn is None: if direction == direction_stop: break else: break walker.go(direction) current = walker.current() return path
[docs] def gather_paths(self, phases=PhaseDef('P'), zstart=0.0, zstop=0.0): ''' Get all possible ray paths for given source and receiver depths for one or more phase definitions. :param phases: a :py:class:`PhaseDef` object or a list of such objects. Comma-separated strings and lists of such strings are also accepted and are converted to :py:class:`PhaseDef` objects for convenience. :param zstart: source depth [m] :param zstop: receiver depth [m] :returns: a list of :py:class:`RayPath` objects Results of this method are cached internally. Cached results are returned, when a given combination of source layer, receiver layer and phase definition has been used before. ''' eps = 1e-7 # num.finfo(float).eps * 1000. phases = to_phase_defs(phases) paths = [] for phase in phases: layer_start = self.layer(zstart, -phase.direction_start()) layer_stop = self.layer(zstop, phase.direction_stop()) pathcachekey = (phase.definition(), layer_start, layer_stop) if pathcachekey in self._pathcache: phase_paths = self._pathcache[pathcachekey] else: hwknee = phase.headwave_knee() if hwknee: name_or_z = hwknee.depth interface = self.discontinuity(name_or_z) mode = hwknee.in_mode in_direction = hwknee.direction pabove, pbelow = interface.critical_ps(mode) p = min_not_none(pabove, pbelow) # diffracted wave: if in_direction == DOWN and ( pbelow is None or pbelow >= pabove): p *= (1.0 - eps) path = self.path(p, phase, layer_start, layer_stop) path.set_prange(p, p, 1.) phase_paths = [path] else: try: pmax_start = max([ radius(z)/layer_start.v(phase.first_leg().mode, z) for z in (layer_start.ztop, layer_start.zbot)]) pmax_stop = max([ radius(z)/layer_stop.v(phase.last_leg().mode, z) for z in (layer_stop.ztop, layer_stop.zbot)]) pmax = min(pmax_start, pmax_stop) pedges = [0.] for layer in self.layers(): for z in (layer.ztop, layer.zbot): for mode in (P, S): for eps2 in [eps]: v = layer.v(mode, z) if v != 0.0: p = radius(z)/v if p <= pmax: pedges.append(p*(1.0-eps2)) pedges.append(p) pedges.append(p*(1.0+eps2)) pedges = num.unique(sorted(pedges)) phase_paths = {} cached = {} counter = [0] def p_to_path(p): if p in cached: return cached[p] try: counter[0] += 1 path = self.path( p, phase, layer_start, layer_stop) if path not in phase_paths: phase_paths[path] = [] phase_paths[path].append(p) except PathFailed: path = None cached[p] = path return path def recurse(pmin, pmax, i=0): if i > self._pdepth: return path1 = p_to_path(pmin) path2 = p_to_path(pmax) if path1 is None and path2 is None and i > 0: return if path1 is None or path2 is None or \ hash(path1) != hash(path2): recurse(pmin, (pmin+pmax)/2., i+1) recurse((pmin+pmax)/2., pmax, i+1) for (pl, ph) in zip(pedges[:-1], pedges[1:]): recurse(pl, ph) for path, ps in phase_paths.items(): path.set_prange( min(ps), max(ps), pmax/(self._np-1)) phase_paths = list(phase_paths.keys()) except ZeroDivisionError: phase_paths = [] self._pathcache[pathcachekey] = phase_paths paths.extend(phase_paths) paths.sort(key=lambda x: x.pmin()) return paths
[docs] def arrivals( self, distances=[], phases=PhaseDef('P'), zstart=0.0, zstop=0.0, refine=True): ''' Compute rays and traveltimes for given distances. :param distances: list or array of distances [deg] :param phases: a :py:class:`PhaseDef` object or a list of such objects. Comma-separated strings and lists of such strings are also accepted and are converted to :py:class:`PhaseDef` objects for convenience. :param zstart: source depth [m] :param zstop: receiver depth [m] :param refine: bool flag, whether to use bisectioning to improve (p, x, t) estimated from interpolation :returns: a list of :py:class:`Ray` objects, sorted by (distance, arrival time) ''' distances = num.asarray(distances, dtype=float) arrivals = [] for path in self.gather_paths(phases, zstart=zstart, zstop=zstop): endgaps = path.endgaps(zstart, zstop) for x, p, t, draft_pxt in path.interpolate_x2pt_linear( distances, endgaps): arrivals.append(Ray(path, p, x, t, endgaps, draft_pxt)) if refine: refined = [] for ray in arrivals: if ray.path._is_headwave: refined.append(ray) try: ray.refine() refined.append(ray) except RefineFailed: pass arrivals = refined arrivals.sort(key=lambda x: (x.x, x.t)) return arrivals
[docs] @classmethod def from_scanlines(cls, producer): ''' Create layer cake model from sequence of materials at depths. :param producer: iterable yielding (depth, material, name) tuples Creates a new :py:class:`LayeredModel` object and uses its :py:meth:`append` method to add layers and discontinuities as needed. ''' self = cls() for z, material, name in producer: if not self._elements: self.append(Surface(z, material)) else: element = self._elements[-1] if self.zeq(element.zbot, z): assert isinstance(element, Layer) self.append( Interface(z, element.mbot, material, name=name)) else: if isinstance(element, Discontinuity): ztop = element.z mtop = element.mbelow elif isinstance(element, Layer): ztop = element.zbot mtop = element.mbot if mtop == material: layer = HomogeneousLayer( ztop, z, material, name=name) else: layer = GradientLayer( ztop, z, mtop, material, name=name) self.append(layer) return self
def to_scanlines(self, get_burgers=False): def fmt(z, m): if not m._has_default_burgers() or get_burgers: return (z, m.vp, m.vs, m.rho, m.qp, m.qs, m.burger_eta1, m.burger_eta2, m.burger_valpha) return (z, m.vp, m.vs, m.rho, m.qp, m.qs) last = None lines = [] for element in self.elements(): if isinstance(element, Layer): if not isinstance(last, Layer): lines.append(fmt(element.ztop, element.mtop)) lines.append(fmt(element.zbot, element.mbot)) last = element if not isinstance(last, Layer): lines.append(fmt(last.z, last.mbelow)) return lines def iter_material_parameter(self, get): assert get in ('vp', 'vs', 'rho', 'qp', 'qs', 'z') if get == 'z': for layer in self.layers(): yield layer.ztop yield layer.zbot else: getter = operator.attrgetter(get) for layer in self.layers(): yield getter(layer.mtop) yield getter(layer.mbot)
[docs] def profile(self, get): ''' Get parameter profile along depth of the earthmodel. :param get: property to be queried ( ``'vp'``, ``'vs'``, ``'rho'``, ``'qp'``, or ``'qs'``, or ``'z'``) :type get: string ''' return num.array(list(self.iter_material_parameter(get)))
[docs] def min(self, get='vp'): ''' Find minimum value of a material property or depth. :param get: property to be queried ( ``'vp'``, ``'vs'``, ``'rho'``, ``'qp'``, or ``'qs'``, or ``'z'``) ''' return min(self.iter_material_parameter(get))
[docs] def max(self, get='vp'): ''' Find maximum value of a material property or depth. :param get: property to be queried ( ``'vp'``, ``'vs'``, ``'rho'``, ``'qp'``, ``'qs'``, or ``'z'``) ''' return max(self.iter_material_parameter(get))
def simplify_layers(self, layers, max_rel_error=0.001): if len(layers) <= 1: return layers ztop = layers[0].ztop zbot = layers[-1].zbot zorigs = [layer.ztop for layer in layers] zorigs.append(zbot) zs = num.linspace(ztop, zbot, 100) data = [] for z in zs: if z == ztop: direction = UP else: direction = DOWN mat = self.material(z, direction) data.append(mat.astuple()) data = num.array(data, dtype=float) data_means = num.mean(data, axis=0) nmax = len(layers) // 2 accept = False zcut_best = [] for n in range(1, nmax+1): ncutintervals = 20 zdelta = (zbot-ztop)/ncutintervals if n == 2: zcuts = [ [ztop, ztop + i*zdelta, zbot] for i in range(1, ncutintervals)] elif n == 3: zcuts = [] for j in range(1, ncutintervals): for i in range(j+1, ncutintervals): zcuts.append( [ztop, ztop + j*zdelta, ztop + i*zdelta, zbot]) else: zcuts = [] zcuts.append(num.linspace(ztop, zbot, n+1)) if zcut_best: zcuts.append(sorted(num.linspace( ztop, zbot, n).tolist() + zcut_best[1])) zcuts.append(sorted(num.linspace( ztop, zbot, n-1).tolist() + zcut_best[2])) best = None for icut, zcut in enumerate(zcuts): rel_par_errors = num.zeros(5) mpar_nodes = num.zeros((n+1, 5)) for ipar in range(5): znodes, vnodes, error_rms = util.polylinefit( zs, data[:, ipar], zcut) mpar_nodes[:, ipar] = vnodes if data_means[ipar] == 0.0: rel_par_errors[ipar] = -1 else: rel_par_errors[ipar] = error_rms/data_means[ipar] rel_error = rel_par_errors.max() if best is None or rel_error < best[0]: best = (rel_error, zcut, mpar_nodes) rel_error, zcut, mpar_nodes = best zcut_best.append(list(zcut)) zcut_best[-1].pop(0) zcut_best[-1].pop() if rel_error <= max_rel_error: accept = True break if not accept: return layers rel_error, zcut, mpar_nodes = best material_nodes = [] for i in range(n+1): material_nodes.append(Material(*mpar_nodes[i, :])) out_layers = [] for i in range(n): mtop = material_nodes[i] mbot = material_nodes[i+1] ztop = zcut[i] zbot = zcut[i+1] if mtop == mbot: lyr = HomogeneousLayer(ztop, zbot, mtop) else: lyr = GradientLayer(ztop, zbot, mtop, mbot) out_layers.append(lyr) return out_layers
[docs] def simplify(self, max_rel_error=0.001): ''' Get representation of model with lower resolution. Returns an approximation of the model. All discontinuities are kept, but layer stacks with continuous model parameters are represented, if possible, by a lower number of layers. Piecewise linear functions are fitted against the original model parameter's piecewise linear functions. Successively larger numbers of layers are tried, until the difference to the original model is below ``max_rel_error``. The difference is measured as the RMS error of the fit normalized by the mean of the input (i.e. the fitted curves should deviate, on average, less than 0.1% from the input curves if ``max_rel_error`` = 0.001). ''' mod_simple = LayeredModel() glayers = [] for element in self.elements(): if isinstance(element, Discontinuity): for layer in self.simplify_layers( glayers, max_rel_error=max_rel_error): mod_simple.append(layer) glayers = [] mod_simple.append(element) else: glayers.append(element) for layer in self.simplify_layers( glayers, max_rel_error=max_rel_error): mod_simple.append(layer) return mod_simple
[docs] def extract(self, depth_min=None, depth_max=None): ''' Extract :py:class:`LayeredModel` from :py:class:`LayeredModel`. :param depth_min: depth of upper cut or name of :py:class:`Interface` :param depth_max: depth of lower cut or name of :py:class:`Interface` Interpolates a :py:class:`GradientLayer` at ``depth_min`` and/or ``depth_max``. ''' if isinstance(depth_min, (str, newstr)): depth_min = self.discontinuity(depth_min).z if isinstance(depth_max, (str, newstr)): depth_max = self.discontinuity(depth_max).z mod_extracted = LayeredModel() for element in self.elements(): element = element.copy() do_append = False if (depth_min is None or depth_min <= element.ztop) \ and (depth_max is None or depth_max >= element.zbot): mod_extracted.append(element) continue if depth_min is not None: if element.ztop < depth_min and depth_min < element.zbot: _, element = element.split(depth_min) do_append = True if depth_max is not None: if element.zbot > depth_max and depth_max > element.ztop: element, _ = element.split(depth_max) do_append = True if do_append: mod_extracted.append(element) return mod_extracted
def replaced_crust(self, crust2_profile=None, crustmod=None): if crust2_profile is not None: profile = anything_to_crust2_profile(crust2_profile) crustmod = LayeredModel.from_scanlines( from_crust2x2_profile(profile)) newmod = LayeredModel() for element in crustmod.extract(depth_max='moho').elements(): if element.name != 'moho': newmod.append(element) else: moho1 = element mod = self.extract(depth_min='moho') first = True for element in mod.elements(): if element.name == 'moho': if element.z <= moho1.z: mbelow = mod.material(moho1.z, direction=UP) else: mbelow = element.mbelow moho = Interface(moho1.z, moho1.mabove, mbelow, name='moho') newmod.append(moho) else: if first: if isinstance(element, Layer) and element.zbot > moho.z: newmod.append(GradientLayer( moho.z, element.zbot, moho.mbelow, element.mbot, name=element.name)) first = False else: newmod.append(element) return newmod
[docs] def perturb(self, rstate=None, keep_vp_vs=False, **kwargs): ''' Create a perturbed variant of the earth model. Randomly change the thickness and material parameters of the earth model from a uniform distribution. :param kwargs: Maximum change fraction (e.g. 0.1) of the parameters. Name the parameter, prefixed by ``p``. Supported parameters are ``ph, pvp, pvs, prho, pqs, pqp``. :type kwargs: dict :param rstate: Random state to draw from, defaults to ``None`` :type rstate: :class:`numpy.random.RandomState`, optional :param keep_vp_vs: Keep the Vp/Vs ratio, defaults to False :type keep_vp_vs: bool, optional :returns: A new, perturbed earth model :rtype: :class:`~pyrocko.cake.LayeredModel` .. code-block :: python perturbed_model = model.perturb(ph=.1, pvp=.05, prho=.1) ''' _pargs = set(['ph', 'pvp', 'pvs', 'prho', 'pqs', 'pqp']) earthmod = copy.deepcopy(self) if rstate is None: rstate = num.random.RandomState() layers = earthmod.layers() discont = earthmod.discontinuities() prev_layer = None def get_change_ratios(): values = dict.fromkeys([p[1:] for p in _pargs], 0.) for param, pval in kwargs.items(): if param not in _pargs: continue values[param[1:]] = float(rstate.uniform(-pval, pval, size=1)) return values # skip Surface while True: disc = next(discont) if isinstance(disc, Surface): break while True: try: layer = next(layers) m = layer.material(None) h = layer.zbot - layer.ztop except StopIteration: break if not isinstance(layer, HomogeneousLayer): raise NotImplementedError( 'Can only perturbate homogeneous layers!') changes = get_change_ratios() # Changing thickness dh = h * changes['h'] changes['h'] = dh layer.resize(depth_max=layer.zbot + dh, depth_min=prev_layer.zbot if prev_layer else None) try: disc = next(discont) disc.change_depth(disc.z + dh) except StopIteration: pass # Setting material parameters for param, change_ratio in changes.items(): if param == 'h': continue value = m.__getattribute__(param) changes[param] = value * change_ratio if keep_vp_vs and changes['vp'] != 0.: changes['vs'] = (m.vp + changes['vp']) / m.vp_vs_ratio() - m.vs for param, change in changes.items(): if param == 'h': continue value = m.__getattribute__(param) m.__setattr__(param, value + change) logger.info( 'perturbating earthmodel: {}'.format( ' '.join(['{param}: {change:{len}.2f}'.format( param=p, change=c, len=8) for p, c in changes.items()]))) prev_layer = layer return earthmod
def require_homogeneous(self): elements = list(self.elements()) if len(elements) != 2: raise LayeredModelError( 'Homogeneous model required but found more than one layer in ' 'earthmodel.') if not isinstance(elements[1], HomogeneousLayer): raise LayeredModelError( 'Homogeneous model required but element #1 is not of type ' 'HomogeneousLayer.') return elements[1].m def __str__(self): return '\n'.join(str(element) for element in self._elements)
[docs]def read_hyposat_model(fn): ''' Reader for HYPOSAT earth model files. To be used as producer in :py:meth:`LayeredModel.from_scanlines`. Interface names are translated as follows: ``'MOHO'`` -> ``'moho'``, ``'CONR'`` -> ``'conrad'`` ''' with open(fn, 'r') as f: translate = {'MOHO': 'moho', 'CONR': 'conrad'} lname = None for iline, line in enumerate(f): if iline == 0: continue z, vp, vs, name = util.unpack_fixed('f10, f10, f10, a4', line) if not name: name = None material = Material(vp*1000., vs*1000.) tname = translate.get(lname, lname) yield z*1000., material, tname lname = name
[docs]def read_nd_model(fn): ''' Reader for TauP style '.nd' (named discontinuity) files. To be used as producer in :py:meth:`LayeredModel.from_scanlines`. Interface names are translated as follows: ``'mantle'`` -> ``'moho'``, ``'outer-core'`` -> ``'cmb'``, ``'inner-core'`` -> ``'icb'``. The format has been modified to include Burgers materials parameters in columns 7 (burger_eta1), 8 (burger_eta2) and 9. eta(3). ''' with open(fn, 'r') as f: for x in read_nd_model_fh(f): yield x
def read_nd_model_str(s): f = StringIO(s) for x in read_nd_model_fh(f): yield x f.close() def read_nd_model_fh(f): translate = {'mantle': 'moho', 'outer-core': 'cmb', 'inner-core': 'icb'} name = None for line in f: toks = line.split() if len(toks) == 9 or len(toks) == 6 or len(toks) == 4: z, vp, vs, rho = [float(x) for x in toks[:4]] qp, qs = None, None burgers = None if len(toks) == 6 or len(toks) == 9: qp, qs = [float(x) for x in toks[4:6]] if len(toks) == 9: burgers = \ [float(x) for x in toks[6:]] material = Material( vp*1000., vs*1000., rho*1000., qp, qs, burgers=burgers) yield z*1000., material, name name = None elif len(toks) == 1: name = translate.get(toks[0], toks[0]) f.close() def from_crust2x2_profile(profile, depthmantle=50000): from pyrocko.dataset import crust2x2 default_qp_qs = { 'soft sed.': (50., 50.), 'hard sed.': (200., 200.), 'upper crust': (600., 400.), } z = 0. for i in range(8): dz, vp, vs, rho = profile.get_layer(i) name = crust2x2.Crust2Profile.layer_names[i] if name in default_qp_qs: qp, qs = default_qp_qs[name] else: qp, qs = None, None material = Material(vp, vs, rho, qp, qs) iname = None if i == 7: iname = 'moho' if dz != 0.0: yield z, material, iname if i != 7: yield z+dz, material, name else: yield z+depthmantle, material, name z += dz def write_nd_model_fh(mod, fh): def fmt(z, mat): rstr = ' '.join( util.gform(x, 4) for x in ( z/1000., mat.vp/1000., mat.vs/1000., mat.rho/1000., mat.qp, mat.qs)) if not mat._has_default_burgers(): rstr += ' '.join( util.gform(x, 4) for x in ( mat.burger_eta1, mat.burger_eta2, mat.burger_valpha)) return rstr.rstrip() + '\n' translate = { 'moho': 'mantle', 'cmb': 'outer-core', 'icb': 'inner-core'} last = None for element in mod.elements(): if isinstance(element, Interface): if element.name is not None: n = translate.get(element.name, element.name) fh.write('%s\n' % n) elif isinstance(element, Layer): if not isinstance(last, Layer): fh.write(fmt(element.ztop, element.mtop)) fh.write(fmt(element.zbot, element.mbot)) last = element if not isinstance(last, Layer): fh.write(fmt(last.z, last.mbelow)) def write_nd_model_str(mod): f = StringIO() write_nd_model_fh(mod, f) return f.getvalue() def write_nd_model(mod, fn): with open(fn, 'w') as f: write_nd_model_fh(mod, f) def builtin_models(): return sorted([ os.path.splitext(os.path.basename(x))[0] for x in glob.glob(builtin_model_filename('*'))]) def builtin_model_filename(modelname): return util.data_file(os.path.join('earthmodels', modelname+'.nd'))
[docs]def load_model(fn='ak135-f-continental.m', format='nd', crust2_profile=None): ''' Load layered earth model from file. :param fn: filename :param format: format :param crust2_profile: ``(lat, lon)`` or :py:class:`pyrocko.crust2x2.Crust2Profile` object, merge model with crustal profile. If ``fn`` is forced to be ``None`` only the converted CRUST2.0 profile is returned. :returns: object of type :py:class:`LayeredModel` The following formats are currently supported: ============== =========================================================== format description ============== =========================================================== ``'nd'`` 'named discontinuity' format used by the TauP programs ``'hyposat'`` format used by the HYPOSAT location program ============== =========================================================== The naming of interfaces is translated from the file format's native naming to Cake's own convention (See :py:func:`read_nd_model` and :py:func:`read_hyposat_model` for details). Cake likes the following internal names: ``'conrad'``, ``'moho'``, ``'cmb'`` (core-mantle boundary), ``'icb'`` (inner core boundary). ''' if fn is not None: if format == 'nd': if not os.path.exists(fn) and fn in builtin_models(): fn = builtin_model_filename(fn) reader = read_nd_model(fn) elif format == 'hyposat': reader = read_hyposat_model(fn) else: assert False, 'unsupported model format' mod = LayeredModel.from_scanlines(reader) if crust2_profile is not None: return mod.replaced_crust(crust2_profile) return mod else: assert crust2_profile is not None profile = anything_to_crust2_profile(crust2_profile) return LayeredModel.from_scanlines( from_crust2x2_profile(profile))
[docs]def castagna_vs_to_vp(vs): ''' Calculate vp from vs using Castagna's relation. Castagna's relation (the mudrock line) is an empirical relation for vp/vs for siliciclastic rocks (i.e. sandstones and shales). [Castagna et al., 1985] vp = 1.16 * vs + 1360 [m/s] :param vs: S-wave velocity [m/s] :returns: P-wave velocity [m/s] ''' return vs*1.16 + 1360.0
[docs]def castagna_vp_to_vs(vp): ''' Calculate vp from vs using Castagna's relation. Castagna's relation (the mudrock line) is an empirical relation for vp/vs for siliciclastic rocks (i.e. sandstones and shales). [Castagna et al., 1985] vp = 1.16 * vs + 1360 [m/s] :param vp: P-wave velocity [m/s] :returns: S-wave velocity [m/s] ''' return (vp - 1360.0) / 1.16
def evenize(x, y, minsize=10): if x.size < minsize: return x ry = (y.max()-y.min()) if ry == 0: return x dx = (x[1:] - x[:-1])/(x.max()-x.min()) dy = (y[1:] + y[:-1])/ry s = num.zeros(x.size) s[1:] = num.cumsum(num.sqrt(dy**2 + dx**2)) s2 = num.linspace(0, s[-1], x.size) x2 = num.interp(s2, s, x) x2[0] = x[0] x2[-1] = x[-1] return x2
[docs]def filled(v, *args, **kwargs): ''' Create NumPy array filled with given value. This works like :py:func:`numpy.ones` but initializes the array with ``v`` instead of ones. ''' x = num.empty(*args, **kwargs) x.fill(v) return x
def next_or_none(i): try: return next(i) except StopIteration: return None def reci_or_none(x): try: return 1./x except ZeroDivisionError: return None def mult_or_none(a, b): if a is None or b is None: return None return a*b def min_not_none(a, b): if a is None: return b if b is None: return a return min(a, b) def xytups(xx, yy): d = [] for x, y in zip(xx, yy): if num.isfinite(y): d.append((x, y)) return d def interp(x, xp, fp, monoton): if monoton == 1: return xytups( x, num.interp(x, xp, fp, left=num.nan, right=num.nan)) elif monoton == -1: return xytups( x, num.interp(x, xp[::-1], fp[::-1], left=num.nan, right=num.nan)) else: fs = [] for xv in x: indices = num.where(num.logical_or( num.logical_and(xp[:-1] >= xv, xv > xp[1:]), num.logical_and(xp[:-1] <= xv, xv < xp[1:])))[0] for i in indices: xr = (xv - xp[i])/(xp[i+1]-xp[i]) fv = xr*fp[i] + (1.-xr)*fp[i+1] fs.append((xv, fv)) return fs def float_or_none(x): if x is not None: return float(x) def parstore_float(thelocals, obj, *args): for k, v in thelocals.items(): if k != 'self' and (not args or k in args): setattr(obj, k, float_or_none(v))