gf

Pyrocko-GF: storage and calculation of synthetic seismograms

The pyrocko.gf subpackage splits functionality into several submodules:

  • The pyrocko.gf.store module deals with the storage, retrieval and summation of Green’s functions.

  • The pyrocko.gf.meta module provides data structures for the meta information associated with the Green’s function stores and implements various the Green’s function lookup indexing schemes.

  • The pyrocko.gf.builder module defines a common base for Green’s function store builders.

  • The pyrocko.gf.seismosizer module provides high level synthetic seismogram synthesis.

All classes defined in the pyrocko.gf.* submodules are imported into the pyrocko.gf namespace, so user scripts may simply use from pyrocko import gf or from pyrocko.gf import * for convenience.

store

exception NotMultipleOfSamplingInterval[source]

Bases: Exception

class GFTrace(data=None, itmin=None, deltat=1.0, is_zero=False, begin_value=None, end_value=None, tmin=None)[source]

Bases: object

Green’s Function trace class for handling traces from the GF store.

property t

Time vector of the GF trace.

Returns:

Time vector

Return type:

numpy.ndarray

exception CannotCreate[source]

Bases: StoreError

exception CannotOpen[source]

Bases: StoreError

exception DuplicateInsert[source]

Bases: StoreError

exception NotAllowedToInterpolate[source]

Bases: StoreError

exception NoSuchExtra(s)[source]

Bases: StoreError

exception NoSuchPhase(s)[source]

Bases: StoreError

class Store(store_dir, mode='r', use_memmap=True)[source]

Bases: BaseStore

Green’s function disk storage and summation machine.

The Store can be used to efficiently store, retrieve, and sum Green’s function traces. A Store contains many 1D time traces sampled at even multiples of a global sampling rate, where each time trace has an individual start and end time. The traces are treated as having repeating end points, so the functions they represent can be non-constant only between begin and end time. It provides capabilities to retrieve decimated traces and to extract parts of the traces. The main purpose of this class is to provide a fast, easy to use, and flexible machanism to compute weighted delay-and-sum stacks with many Green’s function traces involved.

Individual Green’s functions are accessed through a single integer index at low level. On top of that, various indexing schemes can be implemented by providing a mapping from physical coordinates to the low level index i. E.g. for a problem with cylindrical symmetry, one might define a mapping from the coordinates (receiver_depth, source_depth, distance) to the low level index. Index translation is done in the pyrocko.gf.meta.Config subclass object associated with the Store. It is accessible through the store’s config attribute, and contains all meta information about the store, including physical extent, geometry, sampling rate, and information about the type of the stored Green’s functions. Information about the underlying earth model can also be found there.

A GF store can also contain tabulated phase arrivals. In basic cases, these can be created with the make_travel_time_tables() and evaluated with the t() methods.

config

The pyrocko.gf.meta.Config derived object associated with the store which contains all meta information about the store and provides the high-level to low-level index mapping.

store_dir

Path to the store’s data directory.

mode

The mode in which the store is opened: 'r': read-only, 'w': writeable.

classmethod create(store_dir, config, force=False, extra=None)[source]

Create new GF store.

Creates a new GF store at path store_dir. The layout of the GF is defined with the parameters given in config, which should be an object of a subclass of Config. This function will refuse to overwrite an existing GF store, unless force is set to True. If more information, e.g. parameters used for the modelling code, earth models or other, should be saved along with the GF store, these may be provided though a dict given to extra. The keys of this dict must be names and the values must be guts type objects.

Parameters:
  • store_dir (str) – GF store path

  • config (Config) – GF store Config

  • force (bool) – Force overwrite, defaults to False

  • extra (dict or None) – Extra information

get_extra(key)[source]

Get extra information stored under given key.

upgrade()[source]

Upgrade store config and files to latest Pyrocko version.

put(args, trace)[source]

Insert trace into GF store.

Store a single GF trace at (high-level) index args.

Parameters:

args (tuple) – Config index tuple, e.g. (source_depth, distance, component) as in ConfigTypeA.

Returns:

GF trace at args

Return type:

GFTrace

get(args, itmin=None, nsamples=None, decimate=1, interpolation='nearest_neighbor', implementation='c')[source]

Retrieve GF trace from store.

Retrieve a single GF trace from the store at (high-level) index args. By default, the full trace is retrieved. Given itmin and nsamples, only the selected portion of the trace is extracted. If decimate is an integer in the range [2,8], the trace is decimated on the fly or, if available, the trace is read from a decimated version of the GF store.

Parameters:
  • args (tuple) – Config index tuple, e.g. (source_depth, distance, component) as in ConfigTypeA.

  • itmin (int or None) – Start time index (start time is itmin * dt), defaults to None

  • nsamples (int or None) – Number of samples, defaults to None

  • decimate (int) – Decimatation factor, defaults to 1

  • interpolation (str) – Interpolation method ['nearest_neighbor', 'multilinear', 'off'], defaults to 'nearest_neighbor'

  • implementation (str) – Implementation to use ['c', 'reference'], defaults to 'c'.

Returns:

GF trace at args

Return type:

GFTrace

sum(args, delays, weights, itmin=None, nsamples=None, decimate=1, interpolation='nearest_neighbor', implementation='c', optimization='enable')[source]

Sum delayed and weighted GF traces.

Calculate sum of delayed and weighted GF traces. args is a tuple of arrays forming the (high-level) indices of the GF traces to be selected. Delays and weights for the summation are given in the arrays delays and weights. itmin and nsamples can be given to restrict to computation to a given time interval. If decimate is an integer in the range [2,8], decimated traces are used in the summation.

Parameters:
  • args (tuple(numpy.ndarray)) – Config index tuple, e.g. (source_depth, distance, component) as in ConfigTypeA.

  • delays (numpy.ndarray) – Delay times

  • weights (numpy.ndarray) – Trace weights

  • itmin (int or None) – Start time index (start time is itmin * dt), defaults to None

  • nsamples (int or None) – Number of samples, defaults to None

  • decimate (int) – Decimatation factor, defaults to 1

  • interpolation (str) – Interpolation method ['nearest_neighbor', 'multilinear', 'off'], defaults to 'nearest_neighbor'

  • implementation (str) – Implementation to use, ['c', 'alternative', 'reference'], where 'alternative' and 'reference' use a Python implementation, defaults to ‘c’

  • optimization (str) – Optimization mode ['enable', 'disable'], defaults to 'enable'

Returns:

Stacked GF trace.

Return type:

GFTrace

make_decimated(decimate, config=None, force=False, show_progress=False)[source]

Create decimated version of GF store.

Create a downsampled version of the GF store. Downsampling is done for the integer factor decimate which should be in the range [2,8]. If config is None, all traces of the GF store are decimated and held available (i.e. the index mapping of the original store is used), otherwise, a different spacial stepping can be specified by giving a modified GF store configuration in config (see create()). Decimated GF sub-stores are created under the decimated subdirectory within the GF store directory. Holding available decimated versions of the GF store can save computation time, IO bandwidth, or decrease memory footprint at the cost of increased disk space usage, when computation are done for lower frequency signals.

Parameters:
  • decimate (int) – Decimate factor

  • config (Config or None) – GF store config object, defaults to None

  • force (bool) – Force overwrite, defaults to False

  • show_progress (bool) – Show progress, defaults to False

get_stored_phase(phase_def, attribute='phase')[source]

Get stored phase from GF store.

Returns:

Phase information

Return type:

pyrocko.spit.SPTree

t(timing, *args)[source]

Compute interpolated phase arrivals.

Examples:

If test_store is a Type A store:

test_store.t('stored:p', (1000, 10000))
test_store.t('last{stored:P|stored:Pdiff}', (1000, 10000))
                                 # The latter arrival
                                 # of P or diffracted
                                 # P phase

If test_store is a Type B store:

test_store.t('S', (1000, 1000, 10000))
test_store.t('first{P|p|Pdiff|sP}', (1000, 1000, 10000))
                                 # The first arrival of
                                 # the given phases is
                                 # selected

Independent of the store type, it is also possible to specify two location objects and the GF index tuple is calculated internally:

test_store.t('p', source, target)
Parameters:
  • timing (str or Timing) – travel-time definition

  • *args ((tuple,) or (Location, Location)) – if len(args) == 1, args[0] must be a GF index tuple, e.g. (source_depth, distance, component) for a Type A store. If len(args) == 2, two location objects are expected, e.g. (source, receiver) and the appropriate GF index is computed internally.

Returns:

Phase arrival according to timing

Return type:

float or None

get_stored_attribute(phase_def, attribute, *args)[source]

Return interpolated store attribute

Parameters:
  • attribute (str) – takeoff_angle / incidence_angle [deg]

  • *args (tuple) – Config index tuple, e.g. (source_depth, distance, component) as in ConfigTypeA.

get_many_stored_attributes(phase_def, attribute, coords)[source]

Return interpolated store attribute

Parameters:
  • attribute (str) – takeoff_angle / incidence_angle [deg]

  • coords (num.array.Array) – num.array.Array, with columns being (source_depth, distance, component) as in ConfigTypeA.

make_stored_table(attribute, force=False)[source]

Compute tables for selected ray attributes.

Parameters:

attribute (str) – phase / takeoff_angle [deg]/ incidence_angle [deg]

Tables are computed using the 1D earth model defined in earthmodel_1d for each defined phase in tabulated_phases.

make_timing_params(begin, end, snap_vred=True, force=False)[source]

Compute tight parameterized time ranges to include given timings.

Calculates appropriate time ranges to cover given begin and end timings over all GF points in the store. A dict with the following keys is returned:

  • 'tmin': time [s], minimum of begin timing over all GF points

  • 'tmax': time [s], maximum of end timing over all GF points

  • 'vred', 'tmin_vred': slope [m/s] and offset [s] of reduction velocity [m/s] appropriate to catch begin timing over all GF points

  • 'tlenmax_vred': maximum time length needed to cover all end timings, when using linear slope given with (vred, tmin_vred) as start

make_travel_time_tables(force=False)[source]

Compute travel time tables.

Travel time tables are computed using the 1D earth model defined in earthmodel_1d for each defined phase in tabulated_phases. The accuracy of the tablulated times is adjusted to the sampling rate of the store.

make_takeoff_angle_tables(force=False)[source]

Compute takeoff-angle tables.

Takeoff-angle tables [deg] are computed using the 1D earth model defined in earthmodel_1d for each defined phase in tabulated_phases. The accuracy of the tablulated times is adjusted to 0.01 times the sampling rate of the store.

make_incidence_angle_tables(force=False)[source]

Compute incidence-angle tables.

Incidence-angle tables [deg] are computed using the 1D earth model defined in earthmodel_1d for each defined phase in tabulated_phases. The accuracy of the tablulated times is adjusted to 0.01 times the sampling rate of the store.

builder

seismosizer

Coordinate systems

Coordinate system names commonly used in source models.

Name

Description

'xyz'

northing, easting, depth in [m]

'xy'

northing, easting in [m]

'latlon'

latitude, longitude in [deg]

'lonlat'

longitude, latitude in [deg]

'latlondepth'

latitude, longitude in [deg], depth in [m]

exception SeismosizerError[source]

Bases: Exception

exception BadRequest[source]

Bases: SeismosizerError

exception NoSuchStore(store_id=None, dirs=None)[source]

Bases: BadRequest

exception DerivedMagnitudeError[source]

Bases: ValidationError

class STFMode(...) dummy for str[source]

Bases: StringChoice

Any str out of ['pre', 'post'].

class Source(**kwargs)[source]

Bases: Location, Cloneable

Base class for all source models.

name

str, optional, default: ''

time

time_float (pyrocko.guts.Timestamp), default: str_to_time('1970-01-01 00:00:00')

source origin time.

stf

STF, optional

source time function.

stf_mode

str (STFMode), default: 'post'

whether to apply source time function in pre or post-processing.

update(**kwargs)[source]

Change some of the source models parameters.

Example:

>>> from pyrocko import gf
>>> s = gf.DCSource()
>>> s.update(strike=66., dip=33.)
>>> print(s)
--- !pf.DCSource
depth: 0.0
time: 1970-01-01 00:00:00
magnitude: 6.0
strike: 66.0
dip: 33.0
rake: 0.0
grid(**variables)[source]

Create grid of source model variations.

Returns:

SourceGrid instance.

Example:

>>> from pyrocko import gf
>>> base = DCSource()
>>> R = gf.Range
>>> for s in base.grid(R('
base_key()[source]

Get key to decide about source discretization / GF stack sharing.

When two source models differ only in amplitude and origin time, the discretization and the GF stacking can be done only once for a unit amplitude and a zero origin time and the amplitude and origin times of the seismograms can be applied during post-processing of the synthetic seismogram.

For any derived parameterized source model, this method is called to decide if discretization and stacking of the source should be shared. When two source models return an equal vector of values discretization is shared.

get_factor()[source]

Get the scaling factor to be applied during post-processing.

Discretization of the base seismogram is usually done for a unit amplitude, because a common factor can be efficiently multiplied to final seismograms. This eliminates to do repeat the stacking when creating seismograms for a series of source models only differing in amplitude.

This method should return the scaling factor to apply in the post-processing (often this is simply the scalar moment of the source).

effective_stf_pre()[source]

Return the STF applied before stacking of the Green’s functions.

This STF is used during discretization of the parameterized source models, i.e. to produce a temporal distribution of point sources.

Handling of the STF before stacking of the GFs is less efficient but allows to use different source time functions for different parts of the source.

effective_stf_post()[source]

Return the STF applied after stacking of the Green’s fuctions.

This STF is used in the post-processing of the synthetic seismograms.

Handling of the STF after stacking of the GFs is usually more efficient but is only possible when a common STF is used for all subsources.

class SourceWithMagnitude(**kwargs)[source]

Bases: Source

Base class for sources containing a moment magnitude.

magnitude

float, default: 6.0

Moment magnitude Mw as in [Hanks and Kanamori, 1979]

class SourceWithDerivedMagnitude(**kwargs)[source]

Bases: Source

Undocumented.

check_conflicts()[source]

Check for parameter conflicts.

To be overloaded in subclasses. Raises DerivedMagnitudeError on conflicts.

class ExplosionSource(**kwargs)[source]

Bases: SourceWithDerivedMagnitude

An isotropic explosion point source.

magnitude

float, optional

moment magnitude Mw as in [Hanks and Kanamori, 1979]

volume_change

float, optional

volume change of the explosion/implosion or the contracting/extending magmatic source. [m^3]

discretized_source_class

alias of DiscretizedExplosionSource

base_key()[source]

Get key to decide about source discretization / GF stack sharing.

When two source models differ only in amplitude and origin time, the discretization and the GF stacking can be done only once for a unit amplitude and a zero origin time and the amplitude and origin times of the seismograms can be applied during post-processing of the synthetic seismogram.

For any derived parameterized source model, this method is called to decide if discretization and stacking of the source should be shared. When two source models return an equal vector of values discretization is shared.

check_conflicts()[source]

Check for parameter conflicts.

To be overloaded in subclasses. Raises DerivedMagnitudeError on conflicts.

get_factor()[source]

Get the scaling factor to be applied during post-processing.

Discretization of the base seismogram is usually done for a unit amplitude, because a common factor can be efficiently multiplied to final seismograms. This eliminates to do repeat the stacking when creating seismograms for a series of source models only differing in amplitude.

This method should return the scaling factor to apply in the post-processing (often this is simply the scalar moment of the source).

class RectangularExplosionSource(**kwargs)[source]

Bases: ExplosionSource

Rectangular or line explosion source.

strike

float, default: 0.0

strike direction in [deg], measured clockwise from north

dip

float, default: 90.0

dip angle in [deg], measured downward from horizontal

length

float, default: 0.0

length of rectangular source area [m]

width

float, default: 0.0

width of rectangular source area [m]

anchor

str (pyrocko.guts.StringChoice), optional, default: 'center'

Anchor point for positioning the plane, can be: top, center orbottom and also top_left, top_right,bottom_left,bottom_right, center_left and center right

nucleation_x

float, optional

horizontal position of rupture nucleation in normalized fault plane coordinates (-1 = left edge, +1 = right edge)

nucleation_y

float, optional

down-dip position of rupture nucleation in normalized fault plane coordinates (-1 = upper edge, +1 = lower edge)

velocity

float, default: 3500.0

speed of explosion front [m/s]

aggressive_oversampling

bool, default: False

Aggressive oversampling for basesource discretization. When using ‘multilinear’ interpolation oversampling has practically no effect.

discretized_source_class

alias of DiscretizedExplosionSource

base_key()[source]

Get key to decide about source discretization / GF stack sharing.

When two source models differ only in amplitude and origin time, the discretization and the GF stacking can be done only once for a unit amplitude and a zero origin time and the amplitude and origin times of the seismograms can be applied during post-processing of the synthetic seismogram.

For any derived parameterized source model, this method is called to decide if discretization and stacking of the source should be shared. When two source models return an equal vector of values discretization is shared.

class DCSource(**kwargs)[source]

Bases: SourceWithMagnitude

A double-couple point source.

strike

float, default: 0.0

strike direction in [deg], measured clockwise from north

dip

float, default: 90.0

dip angle in [deg], measured downward from horizontal

rake

float, default: 0.0

rake angle in [deg], measured counter-clockwise from right-horizontal in on-plane view

discretized_source_class

alias of DiscretizedMTSource

base_key()[source]

Get key to decide about source discretization / GF stack sharing.

When two source models differ only in amplitude and origin time, the discretization and the GF stacking can be done only once for a unit amplitude and a zero origin time and the amplitude and origin times of the seismograms can be applied during post-processing of the synthetic seismogram.

For any derived parameterized source model, this method is called to decide if discretization and stacking of the source should be shared. When two source models return an equal vector of values discretization is shared.

get_factor()[source]

Get the scaling factor to be applied during post-processing.

Discretization of the base seismogram is usually done for a unit amplitude, because a common factor can be efficiently multiplied to final seismograms. This eliminates to do repeat the stacking when creating seismograms for a series of source models only differing in amplitude.

This method should return the scaling factor to apply in the post-processing (often this is simply the scalar moment of the source).

class CLVDSource(**kwargs)[source]

Bases: SourceWithMagnitude

A pure CLVD point source.

azimuth

float, default: 0.0

azimuth direction of largest dipole, clockwise from north [deg]

dip

float, default: 90.0

dip direction of largest dipole, downward from horizontal [deg]

discretized_source_class

alias of DiscretizedMTSource

base_key()[source]

Get key to decide about source discretization / GF stack sharing.

When two source models differ only in amplitude and origin time, the discretization and the GF stacking can be done only once for a unit amplitude and a zero origin time and the amplitude and origin times of the seismograms can be applied during post-processing of the synthetic seismogram.

For any derived parameterized source model, this method is called to decide if discretization and stacking of the source should be shared. When two source models return an equal vector of values discretization is shared.

get_factor()[source]

Get the scaling factor to be applied during post-processing.

Discretization of the base seismogram is usually done for a unit amplitude, because a common factor can be efficiently multiplied to final seismograms. This eliminates to do repeat the stacking when creating seismograms for a series of source models only differing in amplitude.

This method should return the scaling factor to apply in the post-processing (often this is simply the scalar moment of the source).

class VLVDSource(**kwargs)[source]

Bases: SourceWithDerivedMagnitude

Volumetric linear vector dipole source.

This source is a parameterization for a restricted moment tensor point source, useful to represent dyke or sill like inflation or deflation sources. The restriction is such that the moment tensor is rotational symmetric. It can be represented by a superposition of a linear vector dipole (here we use a CLVD for convenience) and an isotropic component. The restricted moment tensor has 4 degrees of freedom: 2 independent eigenvalues and 2 rotation angles orienting the the symmetry axis.

In this parameterization, the isotropic component is controlled by volume_change. To define the moment tensor, it must be converted to the scalar moment of the the MT’s isotropic component. For the conversion, the shear modulus at the source’s position must be known. This value is extracted from the earth model defined in the GF store in use.

The CLVD part by controlled by its scalar moment M_0: clvd_moment. The sign of clvd_moment is used to switch between a positiv or negativ CLVD (the sign of the largest eigenvalue).

azimuth

float, default: 0.0

azimuth direction of symmetry axis, clockwise from north [deg].

dip

float, default: 90.0

dip direction of symmetry axis, downward from horizontal [deg].

volume_change

float, default: 0.0

volume change of the inflation/deflation [m^3].

clvd_moment

float, default: 0.0

scalar moment M_0 of the CLVD component [Nm]. The sign controls the sign of the CLVD (the sign of its largest eigenvalue).

discretized_source_class

alias of DiscretizedMTSource

base_key()[source]

Get key to decide about source discretization / GF stack sharing.

When two source models differ only in amplitude and origin time, the discretization and the GF stacking can be done only once for a unit amplitude and a zero origin time and the amplitude and origin times of the seismograms can be applied during post-processing of the synthetic seismogram.

For any derived parameterized source model, this method is called to decide if discretization and stacking of the source should be shared. When two source models return an equal vector of values discretization is shared.

class MTSource(**kwargs)[source]

Bases: Source

A moment tensor point source.

mnn

float, default: 1.0

north-north component of moment tensor in [Nm]

mee

float, default: 1.0

east-east component of moment tensor in [Nm]

mdd

float, default: 1.0

down-down component of moment tensor in [Nm]

mne

float, default: 0.0

north-east component of moment tensor in [Nm]

mnd

float, default: 0.0

north-down component of moment tensor in [Nm]

med

float, default: 0.0

east-down component of moment tensor in [Nm]

discretized_source_class

alias of DiscretizedMTSource

base_key()[source]

Get key to decide about source discretization / GF stack sharing.

When two source models differ only in amplitude and origin time, the discretization and the GF stacking can be done only once for a unit amplitude and a zero origin time and the amplitude and origin times of the seismograms can be applied during post-processing of the synthetic seismogram.

For any derived parameterized source model, this method is called to decide if discretization and stacking of the source should be shared. When two source models return an equal vector of values discretization is shared.

class RectangularSource(**kwargs)[source]

Bases: SourceWithDerivedMagnitude

Classical Haskell source model modified for bilateral rupture.

magnitude

float, optional

moment magnitude Mw as in [Hanks and Kanamori, 1979]

strike

float, default: 0.0

strike direction in [deg], measured clockwise from north

dip

float, default: 90.0

dip angle in [deg], measured downward from horizontal

rake

float, default: 0.0

rake angle in [deg], measured counter-clockwise from right-horizontal in on-plane view

length

float, default: 0.0

length of rectangular source area [m]

width

float, default: 0.0

width of rectangular source area [m]

anchor

str (pyrocko.guts.StringChoice), optional, default: 'center'

Anchor point for positioning the plane, can be: top, center bottom, top_left, top_right,bottom_left,bottom_right, center_left, center right.

nucleation_x

float, optional

horizontal position of rupture nucleation in normalized fault plane coordinates (-1. = left edge, +1. = right edge)

nucleation_y

float, optional

down-dip position of rupture nucleation in normalized fault plane coordinates (-1. = upper edge, +1. = lower edge)

velocity

float, default: 3500.0

speed of rupture front [m/s]

slip

float, optional

Slip on the rectangular source area [m]

opening_fraction

float, default: 0.0

Determines fraction of slip related to opening. (-1: pure tensile closing, 0: pure shear, 1: pure tensile opening)

decimation_factor

int, optional, default: 1

Sub-source decimation factor, a larger decimation will make the result inaccurate but shorten the necessary computation time (use for testing puposes only).

aggressive_oversampling

bool, default: False

Aggressive oversampling for basesource discretization. When using ‘multilinear’ interpolation oversampling has practically no effect.

discretized_source_class

alias of DiscretizedMTSource

base_key()[source]

Get key to decide about source discretization / GF stack sharing.

When two source models differ only in amplitude and origin time, the discretization and the GF stacking can be done only once for a unit amplitude and a zero origin time and the amplitude and origin times of the seismograms can be applied during post-processing of the synthetic seismogram.

For any derived parameterized source model, this method is called to decide if discretization and stacking of the source should be shared. When two source models return an equal vector of values discretization is shared.

check_conflicts()[source]

Check for parameter conflicts.

To be overloaded in subclasses. Raises DerivedMagnitudeError on conflicts.

get_factor()[source]

Get the scaling factor to be applied during post-processing.

Discretization of the base seismogram is usually done for a unit amplitude, because a common factor can be efficiently multiplied to final seismograms. This eliminates to do repeat the stacking when creating seismograms for a series of source models only differing in amplitude.

This method should return the scaling factor to apply in the post-processing (often this is simply the scalar moment of the source).

class PseudoDynamicRupture(**kwargs)[source]

Bases: SourceWithDerivedMagnitude

Combined Eikonal and Okada quasi-dynamic rupture model.

Details are described in Pseudo Dynamic Rupture - A stress-based self-similar finite source model. Note: attribute stf is not used so far, but kept for future applications.

strike

float, default: 0.0

Strike direction in [deg], measured clockwise from north.

dip

float, default: 0.0

Dip angle in [deg], measured downward from horizontal.

length

float, default: 10000.0

Length of rectangular source area in [m].

width

float, default: 5000.0

Width of rectangular source area in [m].

anchor

str (pyrocko.guts.StringChoice), optional, default: 'center'

Anchor point for positioning the plane, can be: top, center, bottom, top_left, top_right, bottom_left, bottom_right, center_left, center_right.

nucleation_x

numpy.ndarray (pyrocko.guts_array.Array), default: array([0.])

Horizontal position of rupture nucleation in normalized fault plane coordinates (-1. = left edge, +1. = right edge).

nucleation_y

numpy.ndarray (pyrocko.guts_array.Array), default: array([0.])

Down-dip position of rupture nucleation in normalized fault plane coordinates (-1. = upper edge, +1. = lower edge).

nucleation_time

numpy.ndarray (pyrocko.guts_array.Array), optional

Time in [s] after origin, when nucleation points defined by nucleation_x and nucleation_y rupture.

gamma

float, default: 0.8

Scaling factor between rupture velocity and S-wave velocity: v_r = \gamma * v_s.

nx

int, default: 2

Number of discrete source patches in x direction (along strike).

ny

int, default: 2

Number of discrete source patches in y direction (down dip).

slip

float, optional

Maximum slip of the rectangular source [m]. Setting the slip the tractions/stress field will be normalized to accomodate the desired maximum slip.

rake

float, optional

Rake angle in [deg], measured counter-clockwise from right-horizontal in on-plane view. Rake is translated into homogenous tractions in strike and up-dip direction. rake is mutually exclusive with tractions parameter.

patches

list of pyrocko.modelling.okada.OkadaSource objects, optional

List of all boundary elements/sub faults/fault patches.

patch_mask

numpy.ndarray (pyrocko.guts_array.Array), optional

Mask for all boundary elements/sub faults/fault patches. True leaves the patch in the calculation, False excludes the patch.

tractions

pyrocko.gf.tractions.TractionField, optional

Traction field the rupture plane is exposed to. See the:py:mod:pyrocko.gf.tractions module for more details. If tractions=None and rake is given DirectedTractions will be used.

coef_mat

numpy.ndarray (pyrocko.guts_array.Array), optional

Coefficient matrix linking traction and dislocation field.

eikonal_decimation

int, optional, default: 1

Sub-source eikonal factor, a smaller eikonal factor will increase the accuracy of rupture front calculation but increases also the computation time.

decimation_factor

int, optional, default: 1

Sub-source decimation factor, a larger decimation will make the result inaccurate but shorten the necessary computation time (use for testing puposes only).

nthreads

int, optional, default: 1

Number of threads for Okada forward modelling, matrix inversion and calculation of point subsources. Note: for small/medium matrices 1 thread is most efficient.

pure_shear

bool, optional, default: False

Calculate only shear tractions and omit tensile tractions.

smooth_rupture

bool, default: True

Smooth the tractions by weighting partially ruptured fault patches.

aggressive_oversampling

bool, default: False

Aggressive oversampling for basesource discretization. When using ‘multilinear’ interpolation oversampling has practically no effect.

discretized_source_class

alias of DiscretizedMTSource

get_tractions()[source]

Get source traction vectors.

If rake is given, unit length directed traction vectors (DirectedTractions) are returned, else the given tractions are used.

Returns:

Traction vectors per patch.

Return type:

ndarray: (n_patches, 3).

base_key()[source]

Get key to decide about source discretization / GF stack sharing.

When two source models differ only in amplitude and origin time, the discretization and the GF stacking can be done only once for a unit amplitude and a zero origin time and the amplitude and origin times of the seismograms can be applied during post-processing of the synthetic seismogram.

For any derived parameterized source model, this method is called to decide if discretization and stacking of the source should be shared. When two source models return an equal vector of values discretization is shared.

check_conflicts()[source]

Check for parameter conflicts.

To be overloaded in subclasses. Raises DerivedMagnitudeError on conflicts.

get_factor()[source]

Get the scaling factor to be applied during post-processing.

Discretization of the base seismogram is usually done for a unit amplitude, because a common factor can be efficiently multiplied to final seismograms. This eliminates to do repeat the stacking when creating seismograms for a series of source models only differing in amplitude.

This method should return the scaling factor to apply in the post-processing (often this is simply the scalar moment of the source).

outline(cs='xyz')[source]

Get source outline corner coordinates.

Parameters:

cs (optional, str) – Output coordinate system.

Returns:

Corner points in desired coordinate system.

Return type:

ndarray: (5, [2, 3]).

points_on_source(cs='xyz', **kwargs)[source]

Convert relative plane coordinates to geographical coordinates.

Given x and y coordinates (relative source coordinates between -1. and 1.) are converted to desired geographical coordinates. Coordinates need to be given as ndarray arguments points_x and points_y.

Parameters:

cs (optional, str) – Output coordinate system.

Returns:

Point coordinates in desired coordinate system.

Return type:

ndarray: (n_points, [2, 3]).

discretize_time(store, interpolation='nearest_neighbor', vr=None, times=None, *args, **kwargs)[source]

Get rupture start time for discrete points on source plane.

Parameters:
  • store (Store) – Green’s function database (needs to cover whole region of the source)

  • interpolation (optional, str) – Interpolation method to use (choose between 'nearest_neighbor' and 'multilinear').

  • vr (optional, ndarray) – Array, containing rupture user defined rupture velocity values.

  • times (optional, ndarray) – Array, containing zeros, where rupture is starting, real positive numbers at later secondary nucleation points and -1, where time will be calculated. If not given, rupture starts at nucleation_x, nucleation_y. Times are given for discrete points with equal horizontal and vertical spacing.

Returns:

Coordinates (latlondepth), coordinates (xy), rupture velocity, rupture propagation time of discrete points.

Return type:

ndarray: (n_points, 3), ndarray: (n_points, 2), ndarray: (n_points_dip, n_points_strike), ndarray: (n_points_dip, n_points_strike).

get_vr_time_interpolators(store, interpolation='nearest_neighbor', force=False, **kwargs)[source]

Get interpolators for rupture velocity and rupture time.

Additional **kwargs are passed to discretize_time().

Parameters:
  • store (Store) – Green’s function database (needs to cover whole region of the source).

  • interpolation (optional, str) – Interpolation method to use (choose between 'nearest_neighbor' and 'multilinear').

  • force (optional, bool) – Force recalculation of the interpolators (e.g. after change of nucleation point locations/times). Default is False.

discretize_patches(store, interpolation='nearest_neighbor', force=False, grid_shape=(), **kwargs)[source]

Get rupture start time and OkadaSource elements for points on rupture.

All source elements and their corresponding center points are calculated and stored in the patches attribute.

Additional **kwargs are passed to discretize_time().

Parameters:
  • store (Store) – Green’s function database (needs to cover whole region of the source).

  • interpolation (optional, str) – Interpolation method to use (choose between 'nearest_neighbor' and 'multilinear').

  • force (optional, bool) – Force recalculation of the vr and time interpolators ( e.g. after change of nucleation point locations/times). Default is False.

  • grid_shape (optional, tuple of int) – Desired sub fault patch grid size (nlength, nwidth). Either factor or grid_shape should be set.

discretize_basesource(store, target=None)[source]

Prepare source for synthetic waveform calculation.

Parameters:
  • store (Store) – Green’s function database (needs to cover whole region of the source).

  • target (optional, Target) – Target information.

Returns:

Source discretized by a set of moment tensors and times.

Return type:

DiscretizedMTSource

calc_coef_mat()[source]

Calculate coefficients connecting tractions and dislocations.

get_patch_attribute(attr)[source]

Get patch attributes.

Parameters:

attr (str) – Name of selected attribute (see :py:class`pyrocko.modelling.okada.OkadaSource`).

Returns:

Array with attribute value for each fault patch.

Return type:

ndarray

get_slip(time=None, scale_slip=True, interpolation='nearest_neighbor', **kwargs)[source]

Get slip per subfault patch for given time after rupture start.

Parameters:
  • time (optional, float > 0.) – Time after origin [s], for which slip is computed. If not given, final static slip is returned.

  • scale_slip (optional, bool) – If True and slip given, all slip values are scaled to fit the given maximum slip.

  • interpolation (optional, str) – Interpolation method to use (choose between 'nearest_neighbor' and 'multilinear').

Returns:

Inverted dislocations (u_{strike}, u_{dip}, u_{tensile}) for each source patch.

Return type:

ndarray: (n_sources, 3)

get_delta_slip(store=None, deltat=None, delta=True, interpolation='nearest_neighbor', **kwargs)[source]

Get slip change snapshots.

The time interval, within which the slip changes are computed is determined by the sampling rate of the Green’s function database or deltat. Additional **kwargs are passed to get_slip().

Parameters:
  • store (optional, Store) – Green’s function database (needs to cover whole region of of the source). Its sampling interval is used as time increment for slip difference calculation. Either deltat or store should be given.

  • deltat (optional, float) – Time interval for slip difference calculation [s]. Either deltat or store should be given.

  • delta (optional, bool) – If True, slip differences between two time steps are given. If False, cumulative slip for all time steps.

  • interpolation (optional, str) – Interpolation method to use (choose between 'nearest_neighbor' and 'multilinear').

Returns:

Displacement changes(\Delta u_{strike},
\Delta u_{dip} , \Delta u_{tensile}) for each source patch and time; corner times, for which delta slip is computed. The order of displacement changes array is:

&[[\\
&[\Delta u_{strike, patch1, t1},
    \Delta u_{dip, patch1, t1},
    \Delta u_{tensile, patch1, t1}],\\
&[\Delta u_{strike, patch1, t2},
    \Delta u_{dip, patch1, t2},
    \Delta u_{tensile, patch1, t2}]\\
&], [\\
&[\Delta u_{strike, patch2, t1}, ...],\\
&[\Delta u_{strike, patch2, t2}, ...]]]\\

Return type:

ndarray: (n_sources, n_times, 3), ndarray: (n_times, )

get_slip_rate(*args, **kwargs)[source]

Get slip rate inverted from patches.

The time interval, within which the slip rates are computed is determined by the sampling rate of the Green’s function database or deltat. Additional *args and **kwargs are passed to get_delta_slip().

Returns:

Slip rates (\Delta u_{strike}/\Delta t, \Delta u_{dip}/\Delta t, \Delta u_{tensile}/\Delta t) for each source patch and time; corner times, for which slip rate is computed. The order of sliprate array is:

&[[\\
&[\Delta u_{strike, patch1, t1}/\Delta t,
    \Delta u_{dip, patch1, t1}/\Delta t,
    \Delta u_{tensile, patch1, t1}/\Delta t],\\
&[\Delta u_{strike, patch1, t2}/\Delta t,
    \Delta u_{dip, patch1, t2}/\Delta t,
    \Delta u_{tensile, patch1, t2}/\Delta t]], [\\
&[\Delta u_{strike, patch2, t1}/\Delta t, ...],\\
&[\Delta u_{strike, patch2, t2}/\Delta t, ...]]]\\

Return type:

ndarray: (n_sources, n_times, 3), ndarray: (n_times, )

get_moment_rate_patches(*args, **kwargs)[source]

Get scalar seismic moment rate for each patch individually.

Additional *args and **kwargs are passed to get_slip_rate().

Returns:

Seismic moment rate for each source patch and time; corner times, for which patch moment rate is computed based on slip rate. The order of the moment rate array is:

&[\\
&[(\Delta M / \Delta t)_{patch1, t1},
    (\Delta M / \Delta t)_{patch1, t2}, ...],\\
&[(\Delta M / \Delta t)_{patch2, t1},
    (\Delta M / \Delta t)_{patch, t2}, ...],\\
&[...]]\\

Return type:

ndarray: (n_sources, n_times), ndarray: (n_times, )

get_moment_rate(store, target=None, deltat=None)[source]

Get seismic source moment rate for the total source (STF).

Parameters:
  • store (Store) – Green’s function database (needs to cover whole region of of the source). Its deltat [s] is used as time increment for slip difference calculation. Either deltat or store should be given.

  • target (optional, Target) – Target information, needed for interpolation method.

  • deltat (optional, float) – Time increment for slip difference calculation [s]. If not given store.deltat is used.

Returns:

Seismic moment rate [Nm/s] for each time; corner times, for which moment rate is computed. The order of the moment rate array is:

&[\\
&(\Delta M / \Delta t)_{t1},\\
&(\Delta M / \Delta t)_{t2},\\
&...]\\

Return type:

ndarray: (n_times, ), ndarray: (n_times, )

get_moment(*args, **kwargs)[source]

Get seismic cumulative moment.

Additional *args and **kwargs are passed to get_magnitude().

Returns:

Cumulative seismic moment in [Nm].

Return type:

float

rescale_slip(magnitude=None, moment=None, **kwargs)[source]

Rescale source slip based on given target magnitude or seismic moment.

Rescale the maximum source slip to fit the source moment magnitude or seismic moment to the given target values. Either magnitude or moment need to be given. Additional **kwargs are passed to get_moment().

Parameters:
  • magnitude (optional, float) – Target moment magnitude M_\mathrm{w} as in [Hanks and Kanamori, 1979]

  • moment (optional, float) – Target seismic moment M_0 [Nm].

get_centroid(store, *args, **kwargs)[source]

Centroid of the pseudo dynamic rupture model.

The centroid location and time are derived from the locations and times of the individual patches weighted with their moment contribution. Additional **kwargs are passed to pyrocko_moment_tensor().

Parameters:

store (Store) – Green’s function database (needs to cover whole region of of the source). Its deltat [s] is used as time increment for slip difference calculation. Either deltat or store should be given.

Returns:

The centroid location and associated moment tensor.

Return type:

pyrocko.model.Event

class DoubleDCSource(**kwargs)[source]

Bases: SourceWithMagnitude

Two double-couple point sources separated in space and time. Moment share between the sub-sources is controlled by the parameter mix. The position of the subsources is dependent on the moment distribution between the two sources. Depth, east and north shift are given for the centroid between the two double-couples. The subsources will positioned according to their moment shares around this centroid position. This is done according to their delta parameters, which are therefore in relation to that centroid. Note that depth of the subsources therefore can be depth+/-delta_depth. For shallow earthquakes therefore the depth has to be chosen deeper to avoid sampling above surface.

strike1

float, default: 0.0

strike direction in [deg], measured clockwise from north

dip1

float, default: 90.0

dip angle in [deg], measured downward from horizontal

azimuth

float, default: 0.0

azimuth to second double-couple [deg], measured at first, clockwise from north

rake1

float, default: 0.0

rake angle in [deg], measured counter-clockwise from right-horizontal in on-plane view

strike2

float, default: 0.0

strike direction in [deg], measured clockwise from north

dip2

float, default: 90.0

dip angle in [deg], measured downward from horizontal

rake2

float, default: 0.0

rake angle in [deg], measured counter-clockwise from right-horizontal in on-plane view

delta_time

float, default: 0.0

separation of double-couples in time (t2-t1) [s]

delta_depth

float, default: 0.0

difference in depth (z2-z1) [m]

distance

float, default: 0.0

distance between the two double-couples [m]

mix

float, default: 0.5

how to distribute the moment to the two doublecouples mix=0 -> m1=1 and m2=0; mix=1 -> m1=0, m2=1

stf1

STF, optional

Source time function of subsource 1 (if given, overrides STF from attribute Source.stf)

stf2

STF, optional

Source time function of subsource 2 (if given, overrides STF from attribute Source.stf)

discretized_source_class

alias of DiscretizedMTSource

base_key()[source]

Get key to decide about source discretization / GF stack sharing.

When two source models differ only in amplitude and origin time, the discretization and the GF stacking can be done only once for a unit amplitude and a zero origin time and the amplitude and origin times of the seismograms can be applied during post-processing of the synthetic seismogram.

For any derived parameterized source model, this method is called to decide if discretization and stacking of the source should be shared. When two source models return an equal vector of values discretization is shared.

get_factor()[source]

Get the scaling factor to be applied during post-processing.

Discretization of the base seismogram is usually done for a unit amplitude, because a common factor can be efficiently multiplied to final seismograms. This eliminates to do repeat the stacking when creating seismograms for a series of source models only differing in amplitude.

This method should return the scaling factor to apply in the post-processing (often this is simply the scalar moment of the source).

effective_stf_post()[source]

Return the STF applied after stacking of the Green’s fuctions.

This STF is used in the post-processing of the synthetic seismograms.

Handling of the STF after stacking of the GFs is usually more efficient but is only possible when a common STF is used for all subsources.

class RingfaultSource(**kwargs)[source]

Bases: SourceWithMagnitude

A ring fault with vertical doublecouples.

diameter

float, default: 1.0

diameter of the ring in [m]

sign

float, default: 1.0

inside of the ring moves up (+1) or down (-1)

strike

float, default: 0.0

strike direction of the ring plane, clockwise from north, in [deg]

dip

float, default: 0.0

dip angle of the ring plane from horizontal in [deg]

npointsources

int, default: 360

number of point sources to use

discretized_source_class

alias of DiscretizedMTSource

base_key()[source]

Get key to decide about source discretization / GF stack sharing.

When two source models differ only in amplitude and origin time, the discretization and the GF stacking can be done only once for a unit amplitude and a zero origin time and the amplitude and origin times of the seismograms can be applied during post-processing of the synthetic seismogram.

For any derived parameterized source model, this method is called to decide if discretization and stacking of the source should be shared. When two source models return an equal vector of values discretization is shared.

get_factor()[source]

Get the scaling factor to be applied during post-processing.

Discretization of the base seismogram is usually done for a unit amplitude, because a common factor can be efficiently multiplied to final seismograms. This eliminates to do repeat the stacking when creating seismograms for a series of source models only differing in amplitude.

This method should return the scaling factor to apply in the post-processing (often this is simply the scalar moment of the source).

class CombiSource(subsources=[], **kwargs)[source]

Bases: Source

Composite source model.

subsources

list of Source objects, default: []

discretized_source_class

alias of DiscretizedMTSource

get_factor()[source]

Get the scaling factor to be applied during post-processing.

Discretization of the base seismogram is usually done for a unit amplitude, because a common factor can be efficiently multiplied to final seismograms. This eliminates to do repeat the stacking when creating seismograms for a series of source models only differing in amplitude.

This method should return the scaling factor to apply in the post-processing (often this is simply the scalar moment of the source).

class SFSource(**kwargs)[source]

Bases: Source

A single force point source.

Supported GF schemes: ‘elastic5’.

fn

float, default: 0.0

northward component of single force [N]

fe

float, default: 0.0

eastward component of single force [N]

fd

float, default: 0.0

downward component of single force [N]

discretized_source_class

alias of DiscretizedSFSource

base_key()[source]

Get key to decide about source discretization / GF stack sharing.

When two source models differ only in amplitude and origin time, the discretization and the GF stacking can be done only once for a unit amplitude and a zero origin time and the amplitude and origin times of the seismograms can be applied during post-processing of the synthetic seismogram.

For any derived parameterized source model, this method is called to decide if discretization and stacking of the source should be shared. When two source models return an equal vector of values discretization is shared.

get_factor()[source]

Get the scaling factor to be applied during post-processing.

Discretization of the base seismogram is usually done for a unit amplitude, because a common factor can be efficiently multiplied to final seismograms. This eliminates to do repeat the stacking when creating seismograms for a series of source models only differing in amplitude.

This method should return the scaling factor to apply in the post-processing (often this is simply the scalar moment of the source).

class PorePressurePointSource(**kwargs)[source]

Bases: Source

Excess pore pressure point source.

For poro-elastic initial value problem where an excess pore pressure is brought into a small source volume.

pp

float, default: 1.0

initial excess pore pressure in [Pa]

discretized_source_class

alias of DiscretizedPorePressureSource

base_key()[source]

Get key to decide about source discretization / GF stack sharing.

When two source models differ only in amplitude and origin time, the discretization and the GF stacking can be done only once for a unit amplitude and a zero origin time and the amplitude and origin times of the seismograms can be applied during post-processing of the synthetic seismogram.

For any derived parameterized source model, this method is called to decide if discretization and stacking of the source should be shared. When two source models return an equal vector of values discretization is shared.

get_factor()[source]

Get the scaling factor to be applied during post-processing.

Discretization of the base seismogram is usually done for a unit amplitude, because a common factor can be efficiently multiplied to final seismograms. This eliminates to do repeat the stacking when creating seismograms for a series of source models only differing in amplitude.

This method should return the scaling factor to apply in the post-processing (often this is simply the scalar moment of the source).

class PorePressureLineSource(**kwargs)[source]

Bases: Source

Excess pore pressure line source.

The line source is centered at (north_shift, east_shift, depth).

pp

float, default: 1.0

initial excess pore pressure in [Pa]

length

float, default: 0.0

length of the line source [m]

azimuth

float, default: 0.0

azimuth direction, clockwise from north [deg]

dip

float, default: 90.0

dip direction, downward from horizontal [deg]

discretized_source_class

alias of DiscretizedPorePressureSource

base_key()[source]

Get key to decide about source discretization / GF stack sharing.

When two source models differ only in amplitude and origin time, the discretization and the GF stacking can be done only once for a unit amplitude and a zero origin time and the amplitude and origin times of the seismograms can be applied during post-processing of the synthetic seismogram.

For any derived parameterized source model, this method is called to decide if discretization and stacking of the source should be shared. When two source models return an equal vector of values discretization is shared.

get_factor()[source]

Get the scaling factor to be applied during post-processing.

Discretization of the base seismogram is usually done for a unit amplitude, because a common factor can be efficiently multiplied to final seismograms. This eliminates to do repeat the stacking when creating seismograms for a series of source models only differing in amplitude.

This method should return the scaling factor to apply in the post-processing (often this is simply the scalar moment of the source).

class STF(effective_duration=None, **kwargs)[source]

Bases: Object, Cloneable

Base class for source time functions.

class BoxcarSTF(effective_duration=None, **kwargs)[source]

Bases: STF

Boxcar type source time function.

boxcar source time function
duration

float, default: 0.0

duration of the boxcar

anchor

float, default: 0.0

anchor point with respect to source.time: (-1.0: left -> source duration [0, T] ~ hypocenter time, 0.0: center -> source duration [-T/2, T/2] ~ centroid time, +1.0: right -> source duration [-T, 0] ~ rupture end time)

class TriangularSTF(effective_duration=None, **kwargs)[source]

Bases: STF

Triangular type source time function.

triangular source time function
duration

float, default: 0.0

baseline of the triangle

peak_ratio

float, default: 0.5

fraction of time compared to duration, when the maximum amplitude is reached

anchor

float, default: 0.0

anchor point with respect to source.time: (-1.0: left -> source duration [0, T] ~ hypocenter time, 0.0: center -> source duration [-T/2, T/2] ~ centroid time, +1.0: right -> source duration [-T, 0] ~ rupture end time)

class HalfSinusoidSTF(effective_duration=None, **kwargs)[source]

Bases: STF

Half sinusoid type source time function.

half-sinusouid source time function
duration

float, default: 0.0

duration of the half-sinusoid (baseline)

anchor

float, default: 0.0

anchor point with respect to source.time: (-1.0: left -> source duration [0, T] ~ hypocenter time, 0.0: center -> source duration [-T/2, T/2] ~ centroid time, +1.0: right -> source duration [-T, 0] ~ rupture end time)

exponent

int, default: 1

set to 2 to use square of the half-period sinusoidal function.

class ResonatorSTF(effective_duration=None, **kwargs)[source]

Bases: STF

Simple resonator like source time function.

f(t) = 0 for t < 0
f(t) = e^{-t/tau} * sin(2 * pi * f * t)

smooth ramp source time function
duration

float, default: 0.0

decay time

frequency

float, default: 1.0

resonance frequency

class Request(*args, **kwargs)[source]

Bases: Object

Synthetic seismogram computation request.

Request(**kwargs)
Request(sources, targets, **kwargs)
sources

list of Source objects, default: []

list of sources for which to produce synthetics.

targets

list of pyrocko.gf.targets.Target objects, default: []

list of targets for which to produce synthetics.

class ProcessingStats(**kwargs)[source]

Bases: Object

Undocumented.

t_perc_get_store_and_receiver

float, default: 0.0

t_perc_discretize_source

float, default: 0.0

t_perc_make_base_seismogram

float, default: 0.0

t_perc_make_same_span

float, default: 0.0

t_perc_post_process

float, default: 0.0

t_perc_optimize

float, default: 0.0

t_perc_stack

float, default: 0.0

t_perc_static_get_store

float, default: 0.0

t_perc_static_discretize_basesource

float, default: 0.0

t_perc_static_sum_statics

float, default: 0.0

t_perc_static_post_process

float, default: 0.0

t_wallclock

float, default: 0.0

t_cpu

float, default: 0.0

n_read_blocks

int, default: 0

n_results

int, default: 0

n_subrequests

int, default: 0

n_stores

int, default: 0

n_records_stacked

int, default: 0

class Response(**kwargs)[source]

Bases: Object

Resonse object to a synthetic seismogram computation request.

request

Request

results_list

list of list of pyrocko.gf.meta.SeismosizerResult objects objects, default: []

stats

ProcessingStats

pyrocko_traces()[source]

Return a list of requested Trace instances.

kite_scenes()[source]

Return a list of requested scenes instances.

static_results()[source]

Return a list of requested StaticResult instances.

iter_results(get='pyrocko_traces')[source]

Generator function to iterate over results of request.

Yields associated Source, Target, Trace instances in each iteration.

snuffle(**kwargs)[source]

Open snuffler with requested traces.

class Engine(**kwargs)[source]

Bases: Object

Base class for synthetic seismogram calculators.

get_store_ids()[source]

Get list of available GF store IDs

class LocalEngine(**kwargs)[source]

Bases: Engine

Offline synthetic seismogram calculator.

Parameters:
  • use_env – if True, fill store_superdirs and store_dirs with paths set in environment variables GF_STORE_SUPERDIRS and GF_STORE_DIRS.

  • use_config

    if True, fill store_superdirs and store_dirs with paths set in the user’s config file.

    The config file can be found at ~/.pyrocko/config.pf

    gf_store_dirs: ['/home/pyrocko/gf_stores/ak135/']
    gf_store_superdirs: ['/home/pyrocko/gf_stores/']
    

store_superdirs

list of str objects, default: []

directories which are searched for Green’s function stores

store_dirs

list of str objects, default: []

additional individual Green’s function store directories

default_store_id

str, optional

default store ID to be used when a request does not provide one

get_store_dir(store_id)[source]

Lookup directory given a GF store ID.

get_store_ids()[source]

Get list of available store IDs.

get_store(store_id=None)[source]

Get a store from the engine.

Parameters:

store_id – identifier of the store (optional)

Returns:

Store object

If no store_id is provided the store associated with the default_store_id is returned. Raises NoDefaultStoreSet if default_store_id is undefined.

close_cashed_stores()[source]

Close and remove ids from cashed stores.

process(*args, **kwargs)[source]

Process a request.

process(**kwargs)
process(request, **kwargs)
process(sources, targets, **kwargs)

The request can be given a a Request object, or such an object is created using Request(**kwargs) for convenience.

Returns:

Response object

class RemoteEngine(**kwargs)[source]

Bases: Engine

Client for remote synthetic seismogram calculator.

site

str, optional, default: 'localhost'

url

str, optional, default: '%(site)s/gfws/%(service)s/%(majorversion)i/%(method)s'

class Range(*args, **kwargs)[source]

Bases: SObject

Convenient range specification.

Equivalent ways to sepecify the range [ 0., 1000., … 10000. ]:

Range('0 .. 10k : 1k')
Range(start=0., stop=10e3, step=1e3)
Range(0, 10e3, 1e3)
Range('0 .. 10k @ 11')
Range(start=0., stop=10*km, n=11)

Range(0, 10e3, n=11)
Range(values=[x*1e3 for x in range(11)])

Depending on the use context, it can be possible to omit any part of the specification. E.g. in the context of extracting a subset of an already existing range, the existing range’s specification values would be filled in where missing.

The values are distributed with equal spacing, unless the spacing argument is modified. The values can be created offset or relative to an external base value with the relative argument if the use context supports this.

The range specification can be expressed with a short string representation:

'start .. stop @ num | spacing, relative'
'start .. stop : step | spacing, relative'

most parts of the expression can be omitted if not needed. Whitespace is allowed for readability but can also be omitted.

start

float, optional

stop

float, optional

step

float, optional

n

int, optional

values

numpy.ndarray (pyrocko.guts_array.Array), optional

spacing

str (pyrocko.guts.StringChoice), optional, default: 'lin'

relative

str (pyrocko.guts.StringChoice), optional, default: ''

class SourceGroup(**kwargs)[source]

Bases: Object

Undocumented.

class SourceList(**kwargs)[source]

Bases: SourceGroup

Undocumented.

sources

list of Source objects, default: []

class SourceGrid(**kwargs)[source]

Bases: SourceGroup

Undocumented.

base

Source

variables

dict of Range objects, default: {}

order

list of str objects, default: []

targets

exception BadTarget[source]

Bases: Exception

class Filter(**kwargs)[source]

Bases: Object

Undocumented.

class OptimizationMethod(...) dummy for str[source]

Bases: StringChoice

Any str out of ['enable', 'disable'].

component_orientation(source, target, component)[source]

Get component and azimuth for standard components R, T, Z, N, and E.

Parameters:
  • sourcepyrocko.gf.Location object

  • targetpyrocko.gf.Location object

  • component – string 'R', 'T', 'Z', 'N' or 'E'

class Target(**kwargs)[source]

Bases: Receiver

A seismogram computation request for a single component, including its post-processing parmeters.

quantity

str (pyrocko.gf.meta.QuantityType), optional

Measurement quantity type. If not given, it is guessed from the channel code. For some common cases, derivatives of the stored quantities are supported by using finite difference approximations (e.g. displacement to velocity or acceleration). 4th order central FD schemes are used.

codes

tuple of 4 str objects, default: ('', 'STA', '', 'Z')

network, station, location and channel codes to be set on the response trace.

elevation

float, default: 0.0

station surface elevation in [m]

store_id

str (pyrocko.gf.meta.StringID), optional

ID of Green’s function store to use for the computation. If not given, the processor may use a system default.

sample_rate

float, optional

sample rate to produce. If not given the GF store’s default sample rate is used. GF store specific restrictions may apply.

interpolation

str (pyrocko.gf.meta.InterpolationMethod), default: 'nearest_neighbor'

Interpolation method between Green’s functions. Supported are nearest_neighbor and multilinear

optimization

str (OptimizationMethod), optional, default: 'enable'

disable/enable optimizations in weight-delay-and-sum operation

tmin

time_float (pyrocko.guts.Timestamp), optional

time of first sample to request in [s]. If not given, it is determined from the Green’s functions.

tmax

time_float (pyrocko.guts.Timestamp), optional

time of last sample to request in [s]. If not given, it is determined from the Green’s functions.

azimuth

float, optional

azimuth of sensor component in [deg], clockwise from north. If not given, it is guessed from the channel code.

dip

float, optional

dip of sensor component in [deg], measured downward from horizontal. If not given, it is guessed from the channel code.

filter

Filter, optional

frequency response filter.

class StaticTarget(*args, **kwargs)[source]

Bases: MultiLocation

A computation request for a spatial multi-location target of static/geodetic quantities.

quantity

str (pyrocko.gf.meta.QuantityType), optional, default: 'displacement'

Measurement quantity type, for now only displacement issupported.

interpolation

str (pyrocko.gf.meta.InterpolationMethod), default: 'nearest_neighbor'

Interpolation method between Green’s functions. Supported are nearest_neighbor and multilinear

tsnapshot

time_float (pyrocko.guts.Timestamp), optional

time of the desired snapshot in [s], If not given, the first sample is taken. If the desired sample exceeds the length of the Green’s function store, the last sample is taken.

store_id

str (pyrocko.gf.meta.StringID), optional

ID of Green’s function store to use for the computation. If not given, the processor may use a system default.

property ntargets

Number of targets held by instance.

get_targets()[source]

Discretizes the multilocation target into a list of Target:

Returns:

Target

Return type:

list

class SatelliteTarget(*args, **kwargs)[source]

Bases: StaticTarget

A computation request for a spatial multi-location target of static/geodetic quantities measured from a satellite instrument. The line of sight angles are provided and projecting post-processing is applied.

theta

numpy.ndarray (pyrocko.guts_array.Array)

Horizontal angle towards satellite’s line of sight in radians.

Important

0 is east and \frac{\pi}{2} is north.

phi

numpy.ndarray (pyrocko.guts_array.Array)

Theta is look vector elevation angle towards satellite from horizon in radians. Matrix of theta towards satellite’s line of sight.

Important

-\frac{\pi}{2} is down and \frac{\pi}{2} is up.

class KiteSceneTarget(scene, **kwargs)[source]

Bases: SatelliteTarget

Undocumented.

shape

tuple of 2 int objects, default: (None, None)

Shape of the displacement vectors.

class GNSSCampaignTarget(*args, **kwargs)[source]

Bases: StaticTarget

Undocumented.

tractions

class AbstractTractionField(**kwargs)[source]

Bases: Object

Base class for multiplicative traction fields (tapers).

Fields of this type a re multiplied in the TractionComposition

class TractionField(**kwargs)[source]

Bases: AbstractTractionField

Base class for additive traction fields.

Fields of this type are added in the TractionComposition

class TractionComposition(**kwargs)[source]

Bases: TractionField

Composition of traction fields.

TractionField and AbstractTractionField can be combined to realize a combination of different fields.

components

list of AbstractTractionField objects, default: []

Ordered list of tractions.

class HomogeneousTractions(**kwargs)[source]

Bases: TractionField

Homogeneous traction field.

The traction vectors in strike, dip and normal direction are acting homogeneously on the rupture plane.

strike

float, default: 1.0

Tractions in strike direction [Pa].

dip

float, default: 1.0

Traction in dip direction (up) [Pa].

normal

float, default: 1.0

Traction in normal direction [Pa].

class DirectedTractions(**kwargs)[source]

Bases: TractionField

Directed traction field.

The traction vectors are following a uniform rake.

rake

float, default: 0.0

Rake angle in [deg], measured counter-clockwise from right-horizontal in on-plane view. Rake is translated into homogenous tractions in strike and up-dip direction.

traction

float, default: 1.0

Traction in rake direction [Pa].

class FractalTractions(*args, **kwargs)[source]

Bases: TractionField

Fractal traction field.

rseed

int, optional

Seed for RandomState.If None, an random seed will be initialized.

rake

float, default: 0.0

Rake angle in [deg], measured counter-clockwise from right-horizontal in on-plane view. Rake is translated into homogenous tractions in strike and up-dip direction.

traction_max

float, default: 1.0

Maximum traction vector length [Pa].

class SelfSimilarTractions(**kwargs)[source]

Bases: TractionField

Traction model following Power & Tullis (1991).

The traction vectors are calculated as a sum of 2D-cosines with a constant amplitude / wavelength ratio. The wavenumber kx and ky are constant for each cosine function. The rank defines the maximum wavenumber used for summation. So, e.g. a rank of 3 will lead to a summation of cosines with kx = ky in (1, 2, 3). Each cosine has an associated phases, which defines both the phase shift and also the shift from the rupture plane centre. Finally the summed cosines are translated into shear tractions based on the rake and normalized with traction_max.

rank

int, default: 1

Maximum summed cosine wavenumber/spatial frequency.

rake

float, default: 0.0

Rake angle in [deg], measured counter-clockwise from right-horizontal in on-plane view. Rake is translated into homogenous tractions in strike and up-dip direction.

traction_max

float, default: 1.0

Maximum traction vector length [Pa].

phases

numpy.ndarray (pyrocko.guts_array.Array), optional

Phase shift of the cosines in [rad].

class RectangularTaper(**kwargs)[source]

Bases: AbstractTractionField

Undocumented.

width

float, default: 0.2

Width of the taper as a fraction of the plane.

type

str (pyrocko.guts.StringChoice), default: 'tukey'

Type of the taper, default: “tukey”.

class DepthTaper(**kwargs)[source]

Bases: AbstractTractionField

Undocumented.

depth_start

float

Depth where the taper begins [m].

depth_stop

float

Depth where taper ends and drops to zero [m].

type

str (pyrocko.guts.StringChoice), default: 'linear'

Type of the taper, default: “linear”.

plot_tractions(tractions, nx=15, ny=12, depth=10000.0, component='strike')[source]

Plot traction model for quick inspection.

Parameters:
  • tractions (pyrocko.gf.tractions.TractionField) – Traction field or traction composition to be displayed.

  • nx (optional, int) – Number of patches along strike.

  • ny (optional, int) – Number of patches down dip.

  • depth (optional, float) – Depth of the rupture plane center in [m].

  • component (optional, str) – Choice of traction component to be shown. Available: 'tx' (along strike), 'ty' (up dip), 'tz' (normal), 'absolute' (vector length).

meta

class Earthmodel1D(...) dummy for LayeredModel[source]

Bases: Object

Undocumented.

class StringID(...) dummy for str[source]

Bases: StringPattern

Any str matching pattern '^[A-Za-z][A-Za-z0-9._]{0,64}$'.

class ScopeType(...) dummy for str[source]

Bases: StringChoice

Any str out of ['global', 'regional', 'local'].

class WaveformType(...) dummy for str[source]

Bases: StringChoice

Any str out of ['dis', 'vel', 'acc', 'amp_spec_dis', 'amp_spec_vel', 'amp_spec_acc', 'envelope_dis', 'envelope_vel', 'envelope_acc'].

class QuantityType(...) dummy for str[source]

Bases: StringChoice

Any str out of ['displacement', 'rotation', 'velocity', 'acceleration', 'pressure', 'tilt', 'pore_pressure', 'darcy_velocity', 'vertical_tilt'].

class NearfieldTermsType(...) dummy for str[source]

Bases: StringChoice

Any str out of ['complete', 'incomplete', 'missing'].

class Reference(**kwargs)[source]

Bases: Object

Undocumented.

id

str (StringID)

type

str

title

str

journal

str, optional

volume

str, optional

number

str, optional

pages

str, optional

year

str

issn

str, optional

doi

str, optional

url

str, optional

eprint

str, optional

authors

list of str objects, default: []

publisher

str, optional

keywords

str, optional

note

str, optional

abstract

str, optional

class Region(**kwargs)[source]

Bases: Object

Undocumented.

name

str, optional

class CircularRegion(**kwargs)[source]

Bases: Region

Undocumented.

lat

float

lon

float

radius

float

class RectangularRegion(**kwargs)[source]

Bases: Region

Undocumented.

lat_min

float

lat_max

float

lon_min

float

lon_max

float

class PhaseSelect(...) dummy for str[source]

Bases: StringChoice

Any str out of ['', 'first', 'last'].

exception InvalidTimingSpecification[source]

Bases: ValidationError

class Timing(s=None, **kwargs)[source]

Bases: SObject

Definition of a time instant relative to one or more named phase arrivals.

Instances of this class can be used e.g. in cutting and tapering operations. They can hold an absolute time or an offset to a named phase arrival or group of such arrivals.

Timings can be instantiated from a simple string defintion i.e. with Timing(str) where str is something like 'SELECT{PHASE_DEFS}[+-]OFFSET[S|%]' where 'SELECT' is 'first', 'last' or empty, 'PHASE_DEFS' is a '|'-separated list of phase definitions, and 'OFFSET' is the time offset in seconds. If a '%' is appended, it is interpreted as percent. If the an 'S' is appended to 'OFFSET', it is interpreted as a surface slowness in [s/km].

Phase definitions can be specified in either of the following ways:

  • 'stored:PHASE_ID' - retrieves value from stored travel time table

  • 'cake:CAKE_PHASE_DEF' - evaluates first arrival of phase with cake (see pyrocko.cake.PhaseDef)

  • 'vel_surface:VELOCITY' - arrival according to surface distance / velocity [km/s]

  • 'vel:VELOCITY' - arrival according to 3D-distance / velocity [km/s]

Examples:

  • '100' : absolute time; 100 s

  • '{stored:P}-100' : 100 s before arrival of P phase according to stored travel time table named 'P'

  • '{stored:P}-5.1S' : 10% before arrival of P phase according to stored travel time table named 'P'

  • '{stored:P}-10%' : 10% before arrival of P phase according to stored travel time table named 'P'

  • '{stored:A|stored:B}' : time instant of phase arrival A, or B if A is undefined for a given geometry

  • 'first{stored:A|stored:B}' : as above, but the earlier arrival of A and B is chosen, if both phases are defined for a given geometry

  • 'last{stored:A|stored:B}' : as above but the later arrival is chosen

  • 'first{stored:A|stored:B|stored:C}-100' : 100 s before first out of arrivals A, B, and C

phase_defs

list of str objects, default: []

offset

float, default: 0.0

offset_is

str, optional

select

str (PhaseSelect), default: ''

Can be either '', 'first', or 'last'.

class TPDef(**kwargs)[source]

Bases: Object

Maps an arrival phase identifier to an arrival phase definition.

id

str (StringID)

name used to identify the phase

definition

str

definition of the phase in either cake syntax as defined in pyrocko.cake.PhaseDef, or, if prepended with an !, as a classic phase name, or, if it is a simple number, as a constant horizontal velocity.

exception OutOfBounds(values=None, reason=None)[source]

Bases: Exception

class Location(**kwargs)[source]

Bases: Object

Geographical location.

The location is given by a reference point at the earth’s surface (lat, lon, elevation) and a cartesian offset from this point (north_shift, east_shift, depth). The offset corrected lat/lon coordinates of the location can be accessed though the effective_latlon, effective_lat, and effective_lon properties.

lat

float, optional, default: 0.0

latitude of reference point [deg]

lon

float, optional, default: 0.0

longitude of reference point [deg]

north_shift

float, optional, default: 0.0

northward cartesian offset from reference point [m]

east_shift

float, optional, default: 0.0

eastward cartesian offset from reference point [m]

elevation

float, optional, default: 0.0

surface elevation, above sea level [m]

depth

float, default: 0.0

depth, below surface [m]

property effective_latlon

Property holding the offset-corrected lat/lon pair of the location.

property effective_lat

Property holding the offset-corrected latitude of the location.

property effective_lon

Property holding the offset-corrected longitude of the location.

same_origin(other)[source]

Check whether other location object has the same reference location.

distance_to(other)[source]

Compute surface distance [m] to other location object.

distance_3d_to(other)[source]

Compute 3D distance [m] to other location object.

All coordinates are transformed to cartesian coordinates if necessary then distance is:

\Delta = \sqrt{\Delta {\bf x}^2 + \Delta {\bf y}^2 +                       \Delta {\bf z}^2}

azibazi_to(other)[source]

Compute azimuth and backazimuth to and from other location object.

class Receiver(**kwargs)[source]

Bases: Location

Undocumented.

codes

tuple of 3 str objects, optional

network, station, and location codes

class DiscretizedExplosionSource(**kwargs)[source]

Bases: DiscretizedSource

Undocumented.

m0s

numpy.ndarray (pyrocko.guts_array.Array)

classmethod combine(sources, **kwargs)[source]

Combine several discretized source models.

Concatenenates all point sources in the given discretized sources. Care must be taken when using this function that the external amplitude factors and reference times of the parameterized (undiscretized) sources match or are accounted for.

class DiscretizedSFSource(**kwargs)[source]

Bases: DiscretizedSource

Undocumented.

forces

numpy.ndarray (pyrocko.guts_array.Array)

classmethod combine(sources, **kwargs)[source]

Combine several discretized source models.

Concatenenates all point sources in the given discretized sources. Care must be taken when using this function that the external amplitude factors and reference times of the parameterized (undiscretized) sources match or are accounted for.

class DiscretizedMTSource(**kwargs)[source]

Bases: DiscretizedSource

Undocumented.

m6s

numpy.ndarray (pyrocko.guts_array.Array)

rows with (m_nn, m_ee, m_dd, m_ne, m_nd, m_ed)

classmethod combine(sources, **kwargs)[source]

Combine several discretized source models.

Concatenenates all point sources in the given discretized sources. Care must be taken when using this function that the external amplitude factors and reference times of the parameterized (undiscretized) sources match or are accounted for.

class DiscretizedPorePressureSource(**kwargs)[source]

Bases: DiscretizedSource

Undocumented.

pp

numpy.ndarray (pyrocko.guts_array.Array)

classmethod combine(sources, **kwargs)[source]

Combine several discretized source models.

Concatenenates all point sources in the given discretized sources. Care must be taken when using this function that the external amplitude factors and reference times of the parameterized (undiscretized) sources match or are accounted for.

class ConfigTypeA(**kwargs)[source]

Bases: Config

Cylindrical symmetry, 1D earth model, single receiver depth

  • Problem is invariant to horizontal translations and rotations around vertical axis.

  • All receivers must be at the same depth (e.g. at the surface) High level index variables: (source_depth, distance, component)

  • The distance is the surface distance between source and receiver points.

receiver_depth

float, default: 0.0

Fixed receiver depth [m].

source_depth_min

float

Minimum source depth [m].

source_depth_max

float

Maximum source depth [m].

source_depth_delta

float

Grid spacing of source depths [m]

distance_min

float

Minimum source-receiver surface distance [m].

distance_max

float

Maximum source-receiver surface distance [m].

distance_delta

float

Grid spacing of source-receiver surface distance [m].

class ConfigTypeB(**kwargs)[source]

Bases: Config

Cylindrical symmetry, 1D earth model, variable receiver depth

  • Symmetries like in ConfigTypeA but has additional index for receiver depth

  • High level index variables: (receiver_depth, source_depth, receiver_distance, component)

receiver_depth_min

float

Minimum receiver depth [m].

receiver_depth_max

float

Maximum receiver depth [m].

receiver_depth_delta

float

Grid spacing of receiver depths [m]

source_depth_min

float

Minimum source depth [m].

source_depth_max

float

Maximum source depth [m].

source_depth_delta

float

Grid spacing of source depths [m]

distance_min

float

Minimum source-receiver surface distance [m].

distance_max

float

Maximum source-receiver surface distance [m].

distance_delta

float

Grid spacing of source-receiver surface distances [m].

class ConfigTypeC(**kwargs)[source]

Bases: Config

No symmetrical constraints, one fixed receiver position.

  • Cartesian 3D source volume around a reference point

  • High level index variables: (source_depth, source_east_shift, source_north_shift, component)

receiver

Receiver

Receiver location

source_origin

pyrocko.model.location.Location

Origin of the source volume grid.

source_depth_min

float

Minimum source depth [m].

source_depth_max

float

Maximum source depth [m].

source_depth_delta

float

Source depth grid spacing [m].

source_east_shift_min

float

Minimum easting of source grid [m].

source_east_shift_max

float

Maximum easting of source grid [m].

source_east_shift_delta

float

Source volume grid spacing in east direction [m].

source_north_shift_min

float

Minimum northing of source grid [m].

source_north_shift_max

float

Maximum northing of source grid [m].

source_north_shift_delta

float

Source volume grid spacing in north direction [m].

class ComponentScheme(...) dummy for str[source]

Bases: StringChoice

Different Green’s Function component schemes are available:

Name

Description

elastic10

Elastodynamic for ConfigTypeA and ConfigTypeB stores, MT sources only

elastic8

Elastodynamic for far-field only ConfigTypeA and ConfigTypeB stores, MT sources only

elastic2

Elastodynamic for ConfigTypeA and ConfigTypeB stores, purely isotropic sources only

elastic5

Elastodynamic for ConfigTypeA and ConfigTypeB stores, SF sources only

elastic18

Elastodynamic for ConfigTypeC stores, MT sources only

poroelastic10

Poroelastic for ConfigTypeA and ConfigTypeB stores

class Config(**kwargs)[source]

Bases: Object

Green’s function store meta information.

Currently implemented Store configuration types are:

  • ConfigTypeA - cylindrical or spherical symmetry, 1D earth model, single receiver depth

    • Problem is invariant to horizontal translations and rotations around vertical axis.

    • All receivers must be at the same depth (e.g. at the surface)

    • High level index variables: (source_depth, receiver_distance, component)

  • ConfigTypeB - cylindrical or spherical symmetry, 1D earth model, variable receiver depth

    • Symmetries like in Type A but has additional index for receiver depth

    • High level index variables: (source_depth, receiver_distance, receiver_depth, component)

  • ConfigTypeC - no symmetrical constraints but fixed receiver positions

    • Cartesian source volume around a reference point

    • High level index variables: (ireceiver, source_depth, source_east_shift, source_north_shift, component)

id

str (StringID)

Name of the store. May consist of upper and lower-case letters, digits, dots and underscores. The name must start with a letter.

derived_from_id

str (StringID), optional

Name of the original store, if this store has been derived from another one (e.g. extracted subset).

version

str, optional, default: '1.0'

User-defined version string. Use <major>.<minor> format.

modelling_code_id

str (StringID), optional

Identifier of the backend used to compute the store.

author

str, optional

Comma-separated list of author names.

author_email

str, optional

Author’s contact email address.

created_time

time_float (pyrocko.guts.Timestamp), optional

Time of creation of the store.

regions

list of Region objects, default: []

Geographical regions for which the store is representative.

scope_type

str (ScopeType), optional

Distance range scope of the store (choices: 'global', 'regional', 'local').

waveform_type

str (WaveType), optional

Wave type stored (choices: 'full waveform', 'bodywave', 'P wave', 'S wave', 'surface wave').

nearfield_terms

str (NearfieldTermsType), optional

Information about the inclusion of near-field terms in the modelling (choices: 'complete', 'incomplete', 'missing').

description

str, optional

Free form textual description of the GF store.

references

list of Reference objects, default: []

Reference list to cite the modelling code, earth model or related work.

earthmodel_1d

pyrocko.cake.LayeredModel (Earthmodel1D), optional

Layered earth model in ND (named discontinuity) format.

earthmodel_receiver_1d

pyrocko.cake.LayeredModel (Earthmodel1D), optional

Receiver-side layered earth model in ND format.

can_interpolate_source

bool, optional

Hint to indicate if the spatial sampling of the store is dense enough for multi-linear interpolation at the source.

can_interpolate_receiver

bool, optional

Hint to indicate if the spatial sampling of the store is dense enough for multi-linear interpolation at the receiver.

frequency_min

float, optional

Hint to indicate the lower bound of valid frequencies [Hz].

frequency_max

float, optional

Hint to indicate the upper bound of valid frequencies [Hz].

sample_rate

float, optional

Sample rate of the GF store [Hz].

factor

float, optional, default: 1.0

Gain value, factored out of the stored GF samples. (may not work properly, keep at 1.0).

component_scheme

str (ComponentScheme), default: 'elastic10'

GF component scheme (choices: 'elastic2', 'elastic8', 'elastic10', 'elastic18', 'elastic5', 'poroelastic10').

stored_quantity

str (QuantityType), optional

Physical quantity of stored values (choices: 'displacement', 'rotation', 'velocity', 'acceleration', 'pressure', 'tilt', 'pore_pressure', 'darcy_velocity', 'vertical_tilt'). If not given, a default is used based on the GF component scheme. The default for the "elastic*" family of component schemes is "displacement".

tabulated_phases

list of TPDef objects, default: []

Mapping of phase names to phase definitions, for which travel time tables are available in the GF store.

ncomponents

int, optional

Number of GF components. Use component_scheme instead.

uuid

str, optional

Heuristic hash value which can be used to uniquely identify the GF store for practical purposes.

reference

str, optional

Store reference name composed of the store’s id and the first six letters of its uuid.

get_shear_moduli(lat, lon, points, interpolation=None)[source]

Get shear moduli at given points from contained velocity model.

Parameters:
  • lat – surface origin for coordinate system of points

  • points – NumPy array of shape (N, 3), where each row is a point (north, east, depth), relative to origin at (lat, lon)

  • interpolation – interpolation method. Choose from ('nearest_neighbor', 'multilinear')

Returns:

NumPy array of length N with extracted shear moduli at each point

The default implementation retrieves and interpolates the shear moduli from the contained 1D velocity profile.

get_lambda_moduli(lat, lon, points, interpolation=None)[source]

Get lambda moduli at given points from contained velocity model.

Parameters:
  • lat – surface origin for coordinate system of points

  • points – NumPy array of shape (N, 3), where each row is a point (north, east, depth), relative to origin at (lat, lon)

  • interpolation – interpolation method. Choose from ('nearest_neighbor', 'multilinear')

Returns:

NumPy array of length N with extracted shear moduli at each point

The default implementation retrieves and interpolates the lambda moduli from the contained 1D velocity profile.

get_bulk_moduli(lat, lon, points, interpolation=None)[source]

Get bulk moduli at given points from contained velocity model.

Parameters:
  • lat – surface origin for coordinate system of points

  • points – NumPy array of shape (N, 3), where each row is a point (north, east, depth), relative to origin at (lat, lon)

  • interpolation – interpolation method. Choose from ('nearest_neighbor', 'multilinear')

Returns:

NumPy array of length N with extracted shear moduli at each point

The default implementation retrieves and interpolates the lambda moduli from the contained 1D velocity profile.

get_vs(lat, lon, points, interpolation=None)[source]

Get Vs at given points from contained velocity model.

Parameters:
  • lat – surface origin for coordinate system of points

  • points – NumPy array of shape (N, 3), where each row is a point (north, east, depth), relative to origin at (lat, lon)

  • interpolation – interpolation method. Choose from ('nearest_neighbor', 'multilinear')

Returns:

NumPy array of length N with extracted shear moduli at each point

The default implementation retrieves and interpolates Vs from the contained 1D velocity profile.

get_vp(lat, lon, points, interpolation=None)[source]

Get Vp at given points from contained velocity model.

Parameters:
  • lat – surface origin for coordinate system of points

  • points – NumPy array of shape (N, 3), where each row is a point (north, east, depth), relative to origin at (lat, lon)

  • interpolation – interpolation method. Choose from ('nearest_neighbor', 'multilinear')

Returns:

NumPy array of length N with extracted shear moduli at each point

The default implementation retrieves and interpolates Vp from the contained 1D velocity profile.

get_rho(lat, lon, points, interpolation=None)[source]

Get rho at given points from contained velocity model.

Parameters:
  • lat – surface origin for coordinate system of points

  • points – NumPy array of shape (N, 3), where each row is a point (north, east, depth), relative to origin at (lat, lon)

  • interpolation – interpolation method. Choose from ('nearest_neighbor', 'multilinear')

Returns:

NumPy array of length N with extracted shear moduli at each point

The default implementation retrieves and interpolates rho from the contained 1D velocity profile.

get_tabulated_phase(phase_id)[source]

Get tabulated phase definition.

exception GridSpecError(s)[source]

Bases: Exception

class Weighting(**kwargs)[source]

Bases: Object

Undocumented.

factor

float, default: 1.0

class Taper(**kwargs)[source]

Bases: Object

Undocumented.

tmin

Timing

tmax

Timing

tfade

float, default: 0.0

shape

str (pyrocko.guts.StringChoice), optional, default: 'cos'

class SimplePattern(pattern)[source]

Bases: SObject

Undocumented.

class ChannelSelection(**kwargs)[source]

Bases: Object

Undocumented.

pattern

SimplePattern, optional

min_sample_rate

float, optional

max_sample_rate

float, optional

class StationSelection(**kwargs)[source]

Bases: Object

Undocumented.

includes

SimplePattern

excludes

SimplePattern

distance_min

float, optional

distance_max

float, optional

azimuth_min

float, optional

azimuth_max

float, optional

class WaveformSelection(**kwargs)[source]

Bases: Object

Undocumented.

channel_selection

ChannelSelection, optional

station_selection

StationSelection, optional

taper

Taper

waveform_type

str (WaveformType), default: 'dis'

weighting

Weighting, optional

sample_rate

float, optional

gf_store_id

str (StringID), optional

exception UnavailableScheme[source]

Bases: Exception

class InterpolationMethod(...) dummy for str[source]

Bases: StringChoice

Any str out of ['nearest_neighbor', 'multilinear'].

class SeismosizerTrace(**kwargs)[source]

Bases: Object

Undocumented.

codes

tuple of 4 str objects, default: ('', 'STA', '', 'Z')

network, station, location and channel codes

data

numpy.ndarray (pyrocko.guts_array.Array)

numpy array with data samples

deltat

float, default: 1.0

sampling interval [s]

tmin

time_float (pyrocko.guts.Timestamp), default: str_to_time('1970-01-01 00:00:00')

time of first sample as a system timestamp [s]

class SeismosizerResult(**kwargs)[source]

Bases: Object

Undocumented.

n_records_stacked

int, optional, default: 1

t_stack

float, optional, default: 0.0

class Result(**kwargs)[source]

Bases: SeismosizerResult

Undocumented.

trace

SeismosizerTrace, optional

n_shared_stacking

int, optional, default: 1

t_optimize

float, optional, default: 0.0

class StaticResult(**kwargs)[source]

Bases: SeismosizerResult

Undocumented.

result

dict of numpy.ndarray (pyrocko.guts_array.Array) objects, default: {}