openquake.hazardlib package¶

Subpackages¶

contexts¶

class openquake.hazardlib.contexts.BaseContext[source]¶

Bases: object

Base class for context object.

class openquake.hazardlib.contexts.Collapser(collapse_level, kfields)[source]¶

Bases: object

Class managing the collapsing logic.

collapse(ctx, mon, rup_indep, collapse_level=None)[source]¶

Collapse a context recarray if possible.

Parameters

ctx – a recarray with “sids”
rup_indep – False if the ruptures are mutually exclusive
collapse_level – if None, use .collapse_level

Returns

the collapsed array and the inverting indices

class openquake.hazardlib.contexts.ContextMaker(trt, gsims, oq, monitor=<Monitor [runner]>, extraparams=())[source]¶

Bases: object

A class to manage the creation of contexts and to compute mean/stddevs and possibly PoEs.

Parameters

trt – tectonic region type string
gsims – list of GSIMs or a dictionary gsim -> rlz indices
oq – dictionary of parameters like the maximum_distance, the IMTLs, the investigation time, etc, or an OqParam instance
extraparams – additional site parameters to consider, used only in the tests

NB: the trt can be different from the tectonic region type for which the underlying GSIMs are defined. This is intentional.

REQUIRES = ['DISTANCES', 'SITES_PARAMETERS', 'RUPTURE_PARAMETERS']¶

dcache_size()[source]¶

Returns: the size in bytes of the distance cache

deltagetter = None¶

estimate_sites(src, sites)[source]¶

Parameters

src – a (Collapsed)PointSource
sites – a filtered SiteCollection

Returns

how many sites are impacted overall

estimate_weight(src, srcfilter, multiplier=1)[source]¶

Parameters

src – a source object
srcfilter – a SourceFilter instance

Returns

(weight, estimate_sites)

fewsites = False¶

from_srcs(srcs, sitecol)[source]¶

Parameters

srcs – a list of Source objects
sitecol – a SiteCollection instance

Returns

a list of context arrays

gen_contexts(rups_sites, src_id)[source]¶

Yields: the old-style RuptureContexts generated by the source

gen_ctxs_planar(src, sitecol)[source]¶

Parameters

src – a (Collapsed)PointSource
sitecol – a filtered SiteCollection

Yields

context arrays

gen_poes(ctx, rup_indep=True)[source]¶

Parameters

ctx – a vectorized context (recarray) of size N
rup_indep – rupture flag (false for mutex ruptures)

Yields

poes, ctxt, invs with poes of shape (N, L, G)

get_ctx_iter(src, sitecol, src_id=0, step=1)[source]¶

Parameters

src – a source object (already split) or a list of ruptures
sitecol – a (filtered) SiteCollection
src_id – integer source ID used where src is actually a list
step – > 1 only in preclassical

Returns

iterator over recarrays

get_ctx_params()[source]¶

Returns: the interesting attributes of the context

get_mean_stds(ctxs, split_by_mag=False)[source]¶

Parameters

ctxs – a list of contexts with N=sum(len(ctx) for ctx in ctxs)
disagg – True when called from the disaggregation calculator

Returns

an array of shape (4, G, M, N) with mean and stddevs

get_pmap(ctxs, rup_indep=True)[source]¶

Parameters

ctxs – a list of context arrays (only one for poissonian ctxs)
rup_indep – default True

Returns

a ProbabilityMap

get_poes(srcs, sitecol, rup_indep=True, collapse_level=- 1)[source]¶

Parameters

srcs – a list of sources with the same TRT
sitecol – a SiteCollection instance with N sites

Returns

an array of PoEs of shape (N, L, G)

get_rctx(rup, sites, distances=None)[source]¶

Returns: a RuptureContext (or None if filtered away)

horiz_comp_to_geom_mean(mean_stds)[source]¶

This function converts ground-motion obtained for a given description of horizontal component into ground-motion values for geometric_mean.

The conversion equations used are from:

Beyer and Bommer (2006): for arithmetic mean, GMRot and random
Boore and Kishida (2017): for RotD50

init_monitoring(monitor)[source]¶

make_rctx(rup)[source]¶: Add .REQUIRES_RUPTURE_PARAMETERS to the rupture

max_intensity(sitecol1, mags, dists)[source]¶

Parameters

sitecol1 – a SiteCollection instance with a single site
mags – a sequence of magnitudes
dists – a sequence of distances

Returns

an array of GMVs of shape (#mags, #dists)

new_ctx(size)[source]¶

Returns: a recarray of the given size full of zeros

read_ctxs(dstore, slc=None, magi=None)[source]¶

Parameters

dstore – a DataStore instance
slice – a slice of contexts with the same grp_id

Returns

a list of contexts

recarray(ctxs, magi=None)[source]¶

Params ctxs: a non-empty list of homogeneous contexts
Returns: a recarray, possibly collapsed

restrict(imts)[source]¶

Parameters: imts – a list of IMT strings subset of the full list
Returns: a new ContextMaker involving less IMTs

set_imts_conv()[source]¶: Set the .imts list and .conv dictionary for the horizontal component conversion (if any).

set_weight(sources, srcfilter, multiplier=1, mon=<Monitor [runner]>)[source]¶: Set the weight attribute on each prefiltered source

split_by_gsim()[source]¶: Split the ContextMaker in multiple context makers, one per GSIM

property stop¶

tom = None¶

update(pmap, ctxs, rup_indep=True)[source]¶

Parameters

pmap – probability map to update
ctxs – a list of context arrays (only one for parametric ctxs)
rup_indep – False for mutex ruptures, default True

class openquake.hazardlib.contexts.DeltaRatesGetter(dstore)[source]¶

Bases: object

Read the delta rates from an aftershock datastore

class openquake.hazardlib.contexts.DistancesContext(param_dist_pairs=())[source]¶

Bases: openquake.hazardlib.contexts.BaseContext

Distances context for ground shaking intensity models.

Instances of this class are passed into GroundShakingIntensityModel.get_mean_and_stddevs(). They are intended to represent relevant distances between sites from the collection and the rupture. Every GSIM class is required to declare what distance measures does it need. Only those required values are calculated and made available in a result context object.

roundup(minimum_distance)[source]¶: If the minimum_distance is nonzero, returns a copy of the DistancesContext with updated distances, i.e. the ones below minimum_distance are rounded up to the minimum_distance. Otherwise, returns the original DistancesContext unchanged.

class openquake.hazardlib.contexts.Effect(effect_by_mag, dists, collapse_dist=None)[source]¶

Bases: object

Compute the effect of a rupture of a given magnitude and distance.

Parameters

effect_by_mag – a dictionary magstring -> intensities
dists – array of distances, one per each intensity
cdist – collapse distance

collapse_value(collapse_dist)[source]¶

Returns: intensity at collapse distance

dist_by_mag(intensity)[source]¶

Returns: a dict magstring -> distance

exception openquake.hazardlib.contexts.FarAwayRupture[source]¶

Bases: Exception

Raised if the rupture is outside the maximum distance for all sites

class openquake.hazardlib.contexts.PmapMaker(cmaker, srcfilter, group)[source]¶

Bases: object

A class to compute the PoEs from a given source

count_bytes(ctxs)[source]¶

gen_ctxs(src)[source]¶

make(pmap)[source]¶

class openquake.hazardlib.contexts.RuptureContext(param_pairs=())[source]¶

Bases: openquake.hazardlib.contexts.BaseContext

Rupture calculation context for ground shaking intensity models.

Instances of this class are passed into GroundShakingIntensityModel.get_mean_and_stddevs(). They are intended to represent relevant features of a single rupture. Every GSIM class is required to declare what rupture parameters does it need. Only those required parameters are made available in a result context object.

roundup(minimum_distance)[source]¶: If the minimum_distance is nonzero, returns a copy of the RuptureContext with updated distances, i.e. the ones below minimum_distance are rounded up to the minimum_distance. Otherwise, returns the original.

rup_id = 0¶

size()[source]¶: If the context is a multi rupture context, i.e. it contains an array of magnitudes and it refers to a single site, returns the size of the array, otherwise returns 1.

src_id = 0¶

class openquake.hazardlib.contexts.SitesContext(slots=['vs30', 'vs30measured', 'z1pt0', 'z2pt5'], sitecol=None)[source]¶

Bases: openquake.hazardlib.contexts.BaseContext

Sites calculation context for ground shaking intensity models.

Instances of this class are passed into GroundShakingIntensityModel.get_mean_and_stddevs(). They are intended to represent relevant features of the sites collection. Every GSIM class is required to declare what sites parameters does it need. Only those required parameters are made available in a result context object.

openquake.hazardlib.contexts.basename(src)[source]¶

Returns: the base name of a split source

openquake.hazardlib.contexts.by_dists(gsim)[source]¶

openquake.hazardlib.contexts.combine_pmf(o1, o2)[source]¶

Combine probabilities of occurrence; used to collapse nonparametric ruptures.

Parameters

o1 – probability distribution of length n1
o2 – probability distribution of length n2

Returns

probability distribution of length n1 + n2 - 1

>>> combine_pmf([.99, .01], [.98, .02])
array([9.702e-01, 2.960e-02, 2.000e-04])

openquake.hazardlib.contexts.concat(ctxs)[source]¶: Concatenate context arrays. :returns: list with 0, 1 or 2 elements

openquake.hazardlib.contexts.full_context(sites, rup, dctx=None)[source]¶

Returns: a full RuptureContext with all the relevant attributes

openquake.hazardlib.contexts.get_dists(ctx)[source]¶

Extract the distance parameters from a context.

Returns: a dictionary dist_name -> distances

openquake.hazardlib.contexts.get_effect_by_mag(mags, sitecol1, gsims_by_trt, maximum_distance, imtls)[source]¶

Parameters

mags – an ordered list of magnitude strings with format %.2f
sitecol1 – a SiteCollection with a single site
gsims_by_trt – a dictionary trt -> gsims
maximum_distance – an IntegrationDistance object
imtls – a DictArray with intensity measure types and levels

Returns

a dict magnitude-string -> array(#dists, #trts)

openquake.hazardlib.contexts.get_maxsize(M, G)[source]¶

Returns: an integer N such that arrays N*M*G fit in the CPU cache

openquake.hazardlib.contexts.get_mean_stds(gsim, ctx, imts, **kw)[source]¶

Parameters

gsim – a single GSIM or a a list of GSIMs
ctx – a RuptureContext or a recarray of size N
imts – a list of M IMTs
kw – additional keyword arguments

Returns

an array of shape (4, M, N) obtained by applying the given GSIM, ctx amd imts, or an array of shape (G, 4, M, N)

openquake.hazardlib.contexts.get_num_distances(gsims)[source]¶

Returns: the number of distances required for the given GSIMs

openquake.hazardlib.contexts.is_modifiable(gsim)[source]¶

Returns: True if it is a ModifiableGMPE

openquake.hazardlib.contexts.kround1(ctx, kfields)[source]¶

openquake.hazardlib.contexts.kround2(ctx, kfields)[source]¶

openquake.hazardlib.contexts.print_finite_size(rups)[source]¶: Used to print the number of finite-size ruptures

openquake.hazardlib.contexts.read_cmaker(dstore, trt_smr)[source]¶

Parameters: dstore – a DataStore-like object
Returns: a ContextMaker instance

openquake.hazardlib.contexts.read_cmakers(dstore, full_lt=None)[source]¶

Parameters

dstore – a DataStore-like object
full_lt – a FullLogicTree instance, if given

Returns

a list of ContextMaker instance, one per source group

openquake.hazardlib.contexts.round_dist(dst)[source]¶

openquake.hazardlib.contexts.size(imtls)[source]¶

Returns: size of the dictionary of arrays imtls

openquake.hazardlib.contexts.trivial(ctx, name)[source]¶

Parameters

ctx – a recarray
name – name of a parameter

Returns

True if the parameter is missing or single valued

const¶

Module openquake.hazardlib.const defines various constants.

class openquake.hazardlib.const.IMC(value)[source]¶

Bases: enum.Enum

The intensity measure component is the component of interest of ground shaking for an intensity measure.

GEOMETRIC_MEAN = 'Average Horizontal'¶: Usually defined as the geometric average of the maximum of the two horizontal components (which may not occur at the same time).

GMRotD100 = 'Average Horizontal (GMRotD100)'¶: The geometric mean of the records rotated into the most adverse direction for the structure.

GMRotI50 = 'Average Horizontal (GMRotI50)'¶: An orientation-independent alternative to AVERAGE_HORIZONTAL. Defined at Boore et al. (2006, Bull. Seism. Soc. Am. 96, 1502-1511) and is used for all the NGA GMPEs.

GREATER_OF_TWO_HORIZONTAL = 'Greater of two horizontal'¶: The largest value obtained from two perpendicular horizontal components.

HORIZONTAL = 'Horizontal'¶: The horizontal component.

MEDIAN_HORIZONTAL = 'Median horizontal'¶: The median horizontal component.

PEAK_SRSS_HORIZONTAL = 'Peak square root of sum of squares of horizontals'¶: “the peak square root of the sum of squares of two orthogonal horizontal components in the time domain” p. 880 of Kanno et al. (2006, Bull. Seism. Soc. Am. 96, 879-897)

RANDOM_HORIZONTAL = 'Random horizontal'¶: A randomly chosen horizontal component.

RotD100 = 'Horizontal Maximum Direction (RotD100)'¶

RotD50 = 'Average Horizontal (RotD50)'¶: An orientation-independent alternative to AVERAGE_HORIZONTAL. Defined at Boore et al. (2006, Bull. Seism. Soc. Am. 96, 1502-1511) and is used for all the NGA GMPEs.

VECTORIAL = 'Square root of sum of squares of peak horizontals'¶: “Vectorial addition: a_V = sqrt(max|a_1(t)|^2 + max|a_2(t)|^2)). This means that the maximum ground amplitudes occur simultaneously on the two horizontal components; this is a conservative assumption.” p. 53 of Douglas (2003, Earth-Sci. Rev. 61, 43-104)

VERTICAL = 'Vertical'¶: The vertical component.

VERTICAL_TO_HORIZONTAL_RATIO = 'Vertical-to-Horizontal Ratio'¶: A vertical-to-horizontal spectral ratio

apply_conversion(imt)¶

Parameters

imc – IMC instance
imt – intensity measure type instance

Returns

conversion coefficients conv_median, conv_sigma, rstd

class openquake.hazardlib.const.StdDev[source]¶

Bases: object

GSIM standard deviation represents ground shaking variability at a site.

ALL = 'All'¶: Used in event based calculations, correspond to TOTAL if the gsim is defined for TOTAL, otherwise to the pair (INTER_EVENT, INTRA_EVENT)

EVENT = 'Event'¶: Total standard deviation, defined as the square root of the sum of inter- and intra-event squared standard deviations, represents the total ground shaking variability, and is the only one that is used for calculating a probability of intensity exceedance (see openquake.hazardlib.gsim.base.get_poes()).

INTER_EVENT = 'Inter event'¶: Standard deviation representing ground shaking variability within different events.

INTRA_EVENT = 'Intra event'¶: Standard deviation representing ground shaking variability within a single event.

TOTAL = 'Total'¶

idx = {'Inter event': 1, 'Intra event': 2, 'Total': 0}¶

class openquake.hazardlib.const.TRT(value)[source]¶

Bases: enum.Enum

Container for constants that define some of the common Tectonic Region Types.

ACTIVE_SHALLOW_CRUST = 'Active Shallow Crust'¶

GEOTHERMAL = 'Geothermal'¶

INDUCED = 'Induced'¶

STABLE_CONTINENTAL = 'Stable Shallow Crust'¶

SUBDUCTION_INTERFACE = 'Subduction Interface'¶

SUBDUCTION_INTRASLAB = 'Subduction IntraSlab'¶

UPPER_MANTLE = 'Upper Mantle'¶

VOLCANIC = 'Volcanic'¶

openquake.hazardlib.const.apply_conversion(imc, imt)[source]¶

Parameters

imc – IMC instance
imt – intensity measure type instance

Returns

conversion coefficients conv_median, conv_sigma, rstd

correlation¶

Module openquake.hazardlib.correlation defines correlation models for spatially-distributed ground-shaking intensities.

class openquake.hazardlib.correlation.BaseCorrelationModel[source]¶

Bases: object

Base class for correlation models for spatially-distributed ground-shaking intensities.

apply_correlation(sites, imt, residuals, stddev_intra=0)[source]¶

Apply correlation to randomly sampled residuals.

Parameters

sites – SiteCollection residuals were sampled for.
imt – Intensity measure type object, see openquake.hazardlib.imt.
residuals – 2d numpy array of sampled residuals, where first dimension represents sites (the length as sites parameter) and second one represents different realizations (samples).
stddev_intra – Intra-event standard deviation array. Note that different sites do not necessarily have the same intra-event standard deviation.

Returns

Array of the same structure and semantics as residuals but with correlations applied.

NB: the correlation matrix is cached. It is computed only once per IMT for the complete site collection and then the portion corresponding to the sites is multiplied by the residuals.

class openquake.hazardlib.correlation.HM2018CorrelationModel(uncertainty_multiplier=0)[source]¶

Bases: openquake.hazardlib.correlation.BaseCorrelationModel

“Uncertainty in intraevent spatial correlation of elastic pseudo- acceleration spectral ordinates” by Pablo Heresi and Eduardo Miranda. Submitted for possible publication in Bulletin of Earthquake Engineering, 2018.

Parameters: uncertainty_multiplier – Value to be multiplied by the uncertainty in the correlation parameter beta. If uncertainty_multiplier = 0 (default), the median value is used as a constant value.

apply_correlation(sites, imt, residuals, stddev_intra)[source]¶

Apply correlation to randomly sampled residuals.

See Parent function

class openquake.hazardlib.correlation.JB2009CorrelationModel(vs30_clustering)[source]¶

Bases: openquake.hazardlib.correlation.BaseCorrelationModel

“Correlation model for spatially distributed ground-motion intensities” by Nirmal Jayaram and Jack W. Baker. Published in Earthquake Engineering and Structural Dynamics 2009; 38, pages 1687-1708.

Parameters: vs30_clustering – Boolean value to indicate whether “Case 1” or “Case 2” from page 1700 should be applied. True value means that Vs 30 values show or are expected to show clustering (“Case 2”), False means otherwise.

get_lower_triangle_correlation_matrix(sites, imt)[source]¶

Get lower-triangle matrix as a result of Cholesky-decomposition of correlation matrix.

The resulting matrix should have zeros on values above the main diagonal.

The actual implementations of BaseCorrelationModel interface might calculate the matrix considering site collection and IMT (like JB2009CorrelationModel does) or might have it pre-constructed for a specific site collection and IMT, in which case they will need to make sure that parameters to this function match parameters that were used to pre-calculate decomposed correlation matrix.

Parameters

sites – SiteCollection to create correlation matrix for.
imt – Intensity measure type object, see openquake.hazardlib.imt.

openquake.hazardlib.correlation.hmcorrelation(sites_or_distances, imt, uncertainty_multiplier=0)[source]¶

Returns the Heresi-Miranda correlation model.

Parameters

sites_or_distances – SiteCollection instance o distance matrix
imt – Intensity Measure Type (PGA or SA)
uncertainty_multiplier – Value to be multiplied by the uncertainty in the correlation parameter beta. If uncertainty_multiplier = 0 (default), the median value is used as a constant value.

openquake.hazardlib.correlation.jbcorrelation(sites_or_distances, imt, vs30_clustering=False)[source]¶

Returns the Jayaram-Baker correlation model.

Parameters

sites_or_distances – SiteCollection instance o ristance matrix
imt – Intensity Measure Type (PGA or SA)
vs30_clustering – flag, defalt false

imt¶

Module openquake.hazardlib.imt defines different intensity measure types.

openquake.hazardlib.imt.ASH()[source]¶: Level of the ash fall in millimeters

openquake.hazardlib.imt.AvgSA()[source]¶: Dummy spectral acceleration to compute average ground motion over several spectral ordinates.

openquake.hazardlib.imt.CAV()[source]¶: Cumulative Absolute Velocity. Defins the integral of the absolute acceleration time series. Units are “g-sec”

openquake.hazardlib.imt.DRVT(frequency)[source]¶: Duration as defined in Bora et al. (2019)

openquake.hazardlib.imt.Disp()[source]¶: Displacement

openquake.hazardlib.imt.DispProb()[source]¶: Displacement probability

openquake.hazardlib.imt.EAS(frequency)[source]¶: Effective Amplitude Spectrum in terms of a frequency (in Hz).

openquake.hazardlib.imt.FAS(frequency)[source]¶: Fourier Amplitude Spectrum in terms of a frequency (in Hz).

openquake.hazardlib.imt.IA()[source]¶: Arias intensity. Determines the intensity of shaking by measuring the acceleration of transient seismic waves. Units are m/s.

class openquake.hazardlib.imt.IMT(string, period, damping)¶

Bases: tuple

damping¶: Alias for field number 2

property frequency¶

period¶: Alias for field number 1

string¶: Alias for field number 0

openquake.hazardlib.imt.JMA()[source]¶: Modified Mercalli intensity, a Roman numeral describing the severity of an earthquake in terms of its effects on the earth’s surface and on humans and their structures.

openquake.hazardlib.imt.LSD()[source]¶: Liquefaction-induced lateral spread displacements measured in units of m.

openquake.hazardlib.imt.LiqProb()[source]¶: Liquefaction probability

openquake.hazardlib.imt.MMI()[source]¶: Modified Mercalli intensity, a Roman numeral describing the severity of an earthquake in terms of its effects on the earth’s surface and on humans and their structures.

openquake.hazardlib.imt.PGA()[source]¶: Peak ground acceleration during an earthquake measured in units of g, times of gravitational acceleration.

openquake.hazardlib.imt.PGD()[source]¶: Peak ground displacement during an earthquake measured in units of cm.

openquake.hazardlib.imt.PGDGeomMean(vert_settlement, lat_spread)[source]¶: Geometric mean between vert_settlement and lat_spread

openquake.hazardlib.imt.PGDMax(vert_settlement, lat_spread)[source]¶: Maximum between vert_settlement and lat_spread

openquake.hazardlib.imt.PGV()[source]¶: Peak ground velocity during an earthquake measured in units of cm/sec.

openquake.hazardlib.imt.RSD()[source]¶: Relative significant duration, 5-95% of Arias intensity, in seconds.

openquake.hazardlib.imt.RSD2080()[source]¶: Relative significant duration, 20-80% of Arias intensity, in seconds.

openquake.hazardlib.imt.RSD575()[source]¶: Relative significant duration, 5-75% of Arias intensity, in seconds.

openquake.hazardlib.imt.RSD595()[source]¶: Alias for RSD

openquake.hazardlib.imt.SA(period, damping=5.0)[source]¶: Spectral acceleration, defined as the maximum acceleration of a damped, single-degree-of-freedom harmonic oscillator. Units are g, times of gravitational acceleration.

openquake.hazardlib.imt.from_string(imt, _damping=5.0)[source]¶

Convert an IMT string into an hazardlib object.

Parameters: imt (str) – Intensity Measure Type.

openquake.hazardlib.imt.imt2tup(string)[source]¶

>>> imt2tup('PGA')
('PGA',)
>>> imt2tup('SA(1.0)')
('SA(1.0)', 1.0)
>>> imt2tup('SA(1)')
('SA(1.0)', 1.0)

openquake.hazardlib.imt.positivefloat(val)[source]¶: Raise a ValueError if val <= 0

openquake.hazardlib.imt.repr(self)[source]¶

lt¶

class openquake.hazardlib.lt.Branch(bs_id, branch_id, weight, value)[source]¶

Bases: object

Branch object, represents a <logicTreeBranch /> element.

Parameters

bs_id – BranchSetID of the branchset to which the branch belongs
branch_id – String identifier of the branch
weight – float value of weight assigned to the branch. A text node contents of <uncertaintyWeight /> child node.
value – The actual uncertainty parameter value. A text node contents of <uncertaintyModel /> child node. Type depends on the branchset’s uncertainty type.

property id¶

is_leaf()[source]¶

Returns: True if the branch has no branchset or has a dummy branchset

class openquake.hazardlib.lt.BranchSet(uncertainty_type, ordinal=0, filters=None, collapsed=False)[source]¶

Bases: object

Branchset object, represents a <logicTreeBranchSet /> element.

Parameters

uncertainty_type –
String value. According to the spec one of:

gmpeModel
Branches contain references to different GMPEs. Values are parsed as strings and are supposed to be one of supported GMPEs. See list at GMPELogicTree.

sourceModel
Branches contain references to different PSHA source models. Values are treated as file names, relatively to base path.

maxMagGRRelative
Different values to add to Gutenberg-Richter (“GR”) maximum magnitude. Value should be interpretable as float.

bGRRelative
Values to add to GR “b” value. Parsed as float.

maxMagGRAbsolute
Values to replace GR maximum magnitude. Values expected to be lists of floats separated by space, one float for each GR MFD in a target source in order of appearance.

abGRAbsolute
Values to replace “a” and “b” values of GR MFD. Lists of pairs of floats, one pair for one GR MFD in a target source.

incrementalMFDAbsolute
Replaces an evenly discretized MFD with the values provided

simpleFaultDipRelative
Increases or decreases the angle of fault dip from that given in the original source model

simpleFaultDipAbsolute
Replaces the fault dip in the specified source(s)

simpleFaultGeometryAbsolute
Replaces the simple fault geometry (trace, upper seismogenic depth lower seismogenic depth and dip) of a given source with the values provided

complexFaultGeometryAbsolute
Replaces the complex fault geometry edges of a given source with the values provided

characteristicFaultGeometryAbsolute
Replaces the complex fault geometry surface of a given source with the values provided

truncatedGRFromSlipAbsolute
Updates a TruncatedGR using a slip rate and a rigidity
filters –
Dictionary, a set of filters to specify which sources should the uncertainty be applied to. Represented as branchset element’s attributes in xml:

applyToSources
The uncertainty should be applied only to specific sources. This filter is required for absolute uncertainties (also only one source can be used for those). Value should be the list of source ids. Can be used only in source model logic tree.

applyToTectonicRegionType
Can be used in both the source model and GMPE logic trees. Allows to specify to which tectonic region type (Active Shallow Crust, Stable Shallow Crust, etc.) the uncertainty applies to. This filter is required for all branchsets in GMPE logic tree.

applied = None¶

enumerate_paths()[source]¶

Generate all possible paths starting from this branch set.

Returns: Generator of two-item tuples. Each tuple contains weight of the path (calculated as a product of the weights of all path’s branches) and list of path’s Branch objects. Total sum of all paths’ weights is 1.0

filter_source(source)[source]¶: Apply filters to source and return True if uncertainty should be applied to it.

get_bset_values(ltpath)[source]¶

Parameters: ltpath – List of branch IDs
Returns: A list of pairs [(bset, value), …]

sample(probabilities, sampling_method)[source]¶

Parameters

num_samples – the number of samples
probabilities – (Ns, Nb) random numbers in the range 0..1
sampling_method – the sampling method used

Returns

a list of num_samples lists of branches

to_list()[source]¶

Returns: a literal list describing the branchset

class openquake.hazardlib.lt.CompositeLogicTree(branchsets)[source]¶

Bases: object

Build a logic tree from a set of branches by automatically setting the branch IDs.

get_all_paths()[source]¶

exception openquake.hazardlib.lt.LogicTreeError(node, filename, message)[source]¶

Bases: Exception

Logic tree file contains a logic error.

Parameters: node – XML node object that causes fail. Used to determine the affected line number.

All other constructor parameters are passed to superclass' constructor.

class openquake.hazardlib.lt.Realization(value, weight, ordinal, lt_path, samples=1)[source]¶

Bases: object

Generic Realization object with attributes value, weight, ordinal, lt_path, samples.

property pid¶

class openquake.hazardlib.lt.Weighted(object, weight)¶

Bases: tuple

object¶: Alias for field number 0

weight¶: Alias for field number 1

openquake.hazardlib.lt.abGR(utype, node, filename)[source]¶

openquake.hazardlib.lt.add_path(bset, bsno, brno, num_prev, tot, paths)[source]¶

openquake.hazardlib.lt.apply_uncertainties(bset_values, src_group)[source]¶

Parameters

bset_value – a list of pairs (branchset, value) List of branch IDs
src_group – SourceGroup instance

Returns

A copy of the original group with possibly modified sources

openquake.hazardlib.lt.build(*bslists)[source]¶

Parameters: bslists – a list of lists describing branchsets
Returns: a CompositeLogicTree instance

>>> lt = build(['sourceModel', '',
...              ['A', 'common1', 0.6],
...              ['B', 'common2', 0.4]],
...           ['extendModel', '',
...              ['C', 'extra1', 0.6],
...              ['D', 'extra2', 0.2],
...              ['E', 'extra2', 0.2]])
>>> lt.get_all_paths()
['AC', 'AD', 'AE', 'BC', 'BD', 'BE']

openquake.hazardlib.lt.charGeom(utype, node, filename)[source]¶

openquake.hazardlib.lt.complexGeom(utype, node, filename)[source]¶

openquake.hazardlib.lt.count_paths(branches)[source]¶

Parameters: branches – a list of branches (endpoints or nodes)
Returns: the number of paths in the branchset (slow)

openquake.hazardlib.lt.dummy_branchset()[source]¶

Returns: a dummy BranchSet with a single branch

openquake.hazardlib.lt.incMFD(utype, node, filename)[source]¶

openquake.hazardlib.lt.random(size, seed, sampling_method='early_weights')[source]¶

Parameters

size – size of the returned array (integer or pair of integers)
seed – random seed
sampling_method – ‘early_weights’, ‘early_latin’, …

Returns

an array of floats in the range 0..1

You can compare montecarlo sampling with latin square sampling with the following code:

openquake.hazardlib.lt.random_sample(branchsets, num_samples, seed, sampling_method)[source]¶

>>> bsets = [[('X', .4), ('Y', .6)], [('A', .2), ('B', .3), ('C', .5)]]
>>> paths = random_sample(bsets, 100, 42, 'early_weights')
>>> collections.Counter(paths)
Counter({'YC': 26, 'XC': 24, 'YB': 17, 'XA': 13, 'YA': 10, 'XB': 10})

>>> paths = random_sample(bsets, 100, 42, 'late_weights')
>>> collections.Counter(paths)
Counter({'XA': 20, 'YA': 18, 'XB': 17, 'XC': 15, 'YB': 15, 'YC': 15})

>>> paths = random_sample(bsets, 100, 42, 'early_latin')
>>> collections.Counter(paths)
Counter({'YC': 31, 'XC': 19, 'YB': 17, 'XB': 13, 'YA': 12, 'XA': 8})

>>> paths = random_sample(bsets, 100, 45, 'late_latin')
>>> collections.Counter(paths)
Counter({'YC': 18, 'XA': 18, 'XC': 16, 'YA': 16, 'XB': 16, 'YB': 16})

openquake.hazardlib.lt.sample(weighted_objects, probabilities, sampling_method)[source]¶

Take random samples of a sequence of weighted objects

Parameters

weighted_objects – A finite sequence of N objects with a .weight attribute. The weights must sum up to 1.
probabilities – An array of S random numbers in the range 0..1

Returns

A list of S objects extracted randomly

openquake.hazardlib.lt.setMSR_absolute(utype, node, filename)[source]¶

openquake.hazardlib.lt.simpleGeom(utype, node, filename)[source]¶

openquake.hazardlib.lt.smodel(utype, node, filename)[source]¶

openquake.hazardlib.lt.trucMFDFromSlip_absolute(utype, node, filename)[source]¶

openquake.hazardlib.lt.unknown(utype, node, filename)[source]¶

near_fault¶

Module openquake.hazardlib.nearfault provides methods for near fault PSHA calculation.

openquake.hazardlib.near_fault.average_s_rad(site, hypocenter, reference, pp, normal, dist_to_plane, e, p0, p1, delta_slip)[source]¶

Gets the average S-wave radiation pattern given an e-path as described in: Spudich et al. (2013) “Final report of the NGA-West2 directivity working group”, PEER report, page 90- 92 and computes: the site to the direct point distance, rd, and the hypocentral distance, r_hyp.

Parameters

site – Point object representing the location of the target site
hypocenter – Point object representing the location of hypocenter
reference – Point object representing the location of the reference point for coordinate projection within the calculation. The suggested reference point is Epicentre.
pp – the projection point pp on the patch plane, a numpy array
normal – normal of the plane, describe by a normal vector[a, b, c]
dist_to_plane – d is the constant term in the plane equation, e.g., ax + by + cz = d
e – a float defining the E-path length, which is the distance from Pd(direction) point to hypocentre. In km.
p0 – Point object representing the location of the starting point on fault segment
p1 – Point object representing the location of the ending point on fault segment.
delta_slip – slip direction away from the strike direction, in decimal degrees. A positive angle is generated by a counter-clockwise rotation.

Returns

fs, float value of the average S-wave radiation pattern. rd, float value of the distance from site to the direct point. r_hyp, float value of the hypocetre distance.

openquake.hazardlib.near_fault.directp(node0, node1, node2, node3, hypocenter, reference, pp)[source]¶

Get the Direct Point and the corresponding E-path as described in Spudich et al. (2013). This method also provides a logical variable stating if the DPP calculation must consider the neighbouring patch. To define the intersection point(Pd) of PpPh line segment and fault plane, we obtain the intersection points(Pd) with each side of fault plan, and check which intersection point(Pd) is the one fitting the definition in the Chiou and Spudich(2014) directivity model. Two possible locations for Pd, the first case, Pd locates on the side of the fault patch when Pp is not inside the fault patch. The second case is when Pp is inside the fault patch, then Pd=Pp.

For the first case, it follows three conditions: 1. the PpPh and PdPh line vector are the same, 2. PpPh >= PdPh, 3. Pd is not inside the fault patch.

If we can not find solution for all the four possible intersection points for the first case, we check if the intersection point fit the second case by checking if Pp is inside the fault patch.

Because of the coordinate system mapping(from geographic system to Catestian system), we allow an error when we check the location. The allow error will keep increasing after each loop when no solution in the two cases are found, until the solution get obtained.

Parameters

node0 – Point object representing the location of one vertices on the target fault segment.
node1 – Point object representing the location of one vertices on the target fault segment. Note, the order should be clockwise.
node2 – Point object representing the location of one vertices on the target fault segment. Note, the order should be clockwise.
node3 – Point object representing the location of one vertices on the target fault segment. Note, the order should be clockwise.
hypocenter – Point object representing the location of floating hypocenter on each segment calculation. In the method, we take the direction point of the previous fault patch as hypocentre for the current fault patch.
reference – Point object representing the location of reference point for projection
pp – the projection of the site onto the plane containing the fault slipped area. A numpy array.

Returns

Pd, a numpy array, representing the location of direction point E, the distance from direction point to hypocentre. go_next_patch, flag indicates if the calculation goes on the next fault patch. 1: yes, 0: no.

openquake.hazardlib.near_fault.get_plane_equation(p0, p1, p2, reference)[source]¶

Define the equation of target fault plane passing through 3 given points which includes two points on the fault trace and one point on the fault plane but away from the fault trace. Note: in order to remain the consistency of the fault normal vector direction definition, the order of the three given points is strickly defined.

Parameters

p0 – The fault trace and is the closer points from the starting point of fault trace. Point object representing the location of the one vertex of the fault patch.
p1 – The fault trace and is the further points from the starting point of fault trace. Point object representing the location of the one vertex of the fault patch.
p2 – The point on the fault plane but away from the fault trace. Point object representing the location of the one vertex of the fault patch.
reference – Point object representing the origin of the cartesian system used the represent objects in a projected reference

Returns

normal: normal vector of the plane (a,b,c) dist_to_plane: d in the plane equation, ax + by + cz = d

openquake.hazardlib.near_fault.get_xyz_from_ll(projected, reference)[source]¶

This method computes the x, y and z coordinates of a set of points provided a reference point

Parameters

projected – Point object representing the coordinates of target point to be projected
reference – Point object representing the coordinates of the reference point.

Returns

x y z

openquake.hazardlib.near_fault.isochone_ratio(e, rd, r_hyp)[source]¶

Get the isochone ratio as described in Spudich et al. (2013) PEER report, page 88.

Parameters

e – a float defining the E-path length, which is the distance from Pd(direction) point to hypocentre. In km.
rd – float, distance from the site to the direct point.
r_hyp – float, the hypocentre distance.

Returns

c_prime, a float defining the isochone ratio

openquake.hazardlib.near_fault.projection_pp(site, normal, dist_to_plane, reference)[source]¶

This method finds the projection of the site onto the plane containing the slipped area, defined as the Pp(i.e. ‘perpendicular projection of site location onto the fault plane’ Spudich et al. (2013) - page 88) given a site.

Parameters

site – Location of the site, [lon, lat, dep]
normal – Normal to the plane including the fault patch, describe by a normal vector[a, b, c]
dist_to_plane – D in the plane equation, ax + by + cz = d
reference – Point object representing the location of project reference point

Returns

pp, the projection point, [ppx, ppy, ppz], in xyz domain , a numpy array.

openquake.hazardlib.near_fault.vectors2angle(v1, v2)[source]¶

Returns the angle in radians between vectors ‘v1’ and ‘v2’.

Parameters

v1 – vector, a numpy array
v2 – vector, a numpy array

Returns

the angle in radians between the two vetors

nrml¶

It is possible to save a Node object into a NRML file by using the function write(nodes, output) where output is a file object. If you want to make sure that the generated file is valid according to the NRML schema just open it in ‘w+’ mode: immediately after writing it will be read and validated. It is also possible to convert a NRML file into a Node object with the routine read(node, input) where input is the path name of the NRML file or a file object opened for reading. The file will be validated as soon as opened.

For instance an exposure file like the following:

<?xml version='1.0' encoding='utf-8'?>
<nrml xmlns="http://openquake.org/xmlns/nrml/0.4"
      xmlns:gml="http://www.opengis.net/gml">
  <exposureModel
      id="my_exposure_model_for_population"
      category="population"
      taxonomySource="fake population datasource">

    <description>
      Sample population
    </description>

    <assets>
      <asset id="asset_01" number="7" taxonomy="IT-PV">
          <location lon="9.15000" lat="45.16667" />
      </asset>

      <asset id="asset_02" number="7" taxonomy="IT-CE">
          <location lon="9.15333" lat="45.12200" />
      </asset>
    </assets>
  </exposureModel>
</nrml>

can be converted as follows:

>> nrml = read(<path_to_the_exposure_file.xml>)

Then subnodes and attributes can be conveniently accessed:

>> nrml.exposureModel.assets[0][‘taxonomy’] ‘IT-PV’ >> nrml.exposureModel.assets[0][‘id’] ‘asset_01’ >> nrml.exposureModel.assets[0].location[‘lon’] ‘9.15000’ >> nrml.exposureModel.assets[0].location[‘lat’] ‘45.16667’

The Node class provides no facility to cast strings into Python types; this is a job for the Node class which can be subclassed and supplemented by a dictionary of validators.

exception openquake.hazardlib.nrml.DuplicatedID[source]¶

Bases: Exception

Raised when two sources with the same ID are found in a source model

class openquake.hazardlib.nrml.GeometryModel(sections)[source]¶

Bases: object

Contains a dictionary of sections

class openquake.hazardlib.nrml.SourceModel(src_groups, name='', investigation_time='', start_time='')[source]¶

Bases: collections.abc.Sequence

A container of source groups with attributes name, investigation_time and start_time. It is serialize on hdf5 as follows:

>> with openquake.baselib.hdf5.File(‘/tmp/sm.hdf5’, ‘w’) as f: .. f[‘/’] = source_model

openquake.hazardlib.nrml.check_unique(ids, msg='')[source]¶: Raise a DuplicatedID exception if there are duplicated IDs

openquake.hazardlib.nrml.get(xml, investigation_time=50.0, rupture_mesh_spacing=5.0, width_of_mfd_bin=1.0, area_source_discretization=10)[source]¶

Parameters

xml – the XML representation of a source
investigation_time – investigation time
rupture_mesh_spacing – rupture mesh spacing
width_of_mfd_bin – width of MFD bin
area_source_discretization – area source discretization

Returns

a python source object

openquake.hazardlib.nrml.get_geometry_model(node, fname, converter)[source]¶

openquake.hazardlib.nrml.get_rupture_collection(node, fname, converter)[source]¶

openquake.hazardlib.nrml.get_source_model_04(node, fname, converter=<openquake.hazardlib.sourceconverter.SourceConverter object>)[source]¶

openquake.hazardlib.nrml.get_source_model_05(node, fname, converter=<openquake.hazardlib.sourceconverter.SourceConverter object>)[source]¶

openquake.hazardlib.nrml.get_tag_version(nrml_node)[source]¶: Extract from a node of kind NRML the tag and the version. For instance from ‘{http://openquake.org/xmlns/nrml/0.4}fragilityModel’ one gets the pair (‘fragilityModel’, ‘nrml/0.4’).

openquake.hazardlib.nrml.read(source, stop=None)[source]¶

Convert a NRML file into a validated Node object. Keeps the entire tree in memory.

Parameters: source – a file name or file object open for reading

openquake.hazardlib.nrml.read_source_models(fnames, converter)[source]¶

Parameters

fnames – list of source model files
converter – a openquake.hazardlib.sourceconverter.SourceConverter instance

Yields

SourceModel instances

openquake.hazardlib.nrml.to_python(fname, *args)[source]¶: Parse a NRML file and return an associated Python object. It works by calling nrml.read() and node_to_obj() in sequence.

openquake.hazardlib.nrml.to_string(node)[source]¶: Convert a node into a string in NRML format

openquake.hazardlib.nrml.write(nodes, output=<_io.TextIOWrapper name='<stdout>' mode='w' encoding='utf-8'>, fmt='%.7E', gml=True, xmlns=None)[source]¶

Convert nodes into a NRML file. output must be a file object open in write mode. If you want to perform a consistency check, open it in read-write mode, then it will be read after creation and validated.

Params nodes

an iterable over Node objects

Params output

a file-like object in write or read-write mode

Parameters

fmt – format used for writing the floats (default ‘%.7E’)
gml – add the http://www.opengis.net/gml namespace
xmlns – NRML namespace like http://openquake.org/xmlns/nrml/0.4

pmf¶

Module openquake.hazardlib.pmf implements PMF.

class openquake.hazardlib.pmf.PMF(data, epsilon=1e-07)[source]¶

Bases: object

reduce(bin=0)[source]¶

Reduce the original PMF to a single bin distribution.

Parameters: bin – the bin to keep (default the first)

sample(number_samples)[source]¶

Produces a list of samples from the probability mass function.

Parameters: data (int) – Number of samples
Returns: Samples from PMF as a list

sample_pairs(number_samples)[source]¶

Produces a list of samples from the probability mass function.

Parameters: data (int) – Number of samples
Returns: Samples from PMF as a list of pairs

probability_map¶

class openquake.hazardlib.probability_map.ProbabilityCurve(array)[source]¶

Bases: object

This class is a small wrapper over an array of PoEs associated to a set of intensity measure types and levels. It provides a few operators, including the complement operator ~

~p = 1 - p

and the inclusive or operator |

p = p1 | p2 = ~(~p1 * ~p2)

Such operators are implemented efficiently at the numpy level, by dispatching on the underlying array.

Here is an example of use:

>>> poe = ProbabilityCurve(numpy.array([0.1, 0.2, 0.3, 0, 0]))
>>> ~(poe | poe) * .5
<ProbabilityCurve
[0.405 0.32  0.245 0.5   0.5  ]>

combine(other, rlz_groups)[source]¶: Update a ProbabilityCurve with shape (L, R) with a pcurve with shape (L, G), being G the number of realization groups, which are list of integers in the range 0..R-1.

convert(imtls, idx=0)[source]¶

Convert a probability curve into a record of dtype imtls.dt.

Parameters

imtls – DictArray instance
idx – extract the data corresponding to the given inner index

extract(inner_idx)[source]¶: Extracts the component specified by the index inner_idx.

class openquake.hazardlib.probability_map.ProbabilityMap(sids, shape_y, shape_z)[source]¶

Bases: object

Thin wrapper over a 3D-array of probabilities.

convert(imtls, nsites, idx=0)[source]¶

Convert a probability map into a composite array of length nsites and dtype imtls.dt.

Parameters

imtls – DictArray instance
nsites – the total number of sites
idx – index on the z-axis (default 0)

fill(value)[source]¶

Parameters: value – a scalar probability

Fill the ProbabilityMap underlying array with the given scalar and build the .sidx array

new(array)[source]¶

remove_zeros()[source]¶

reshape(N, M, P)[source]¶

Returns: a new Pmap associated to a reshaped array

property sidx¶

Returns: an array of length N site_id -> index

split()[source]¶

Yields: G ProbabilityMaps of shape (N, L, 1)

to_dframe()[source]¶

Returns: a DataFrame with fields sid, gid, lid, poe

update(other, i)[source]¶: Multiply by the probabilities of no exceedence

update_(poes, invs, ctxt, itime, rup_indep, idx)[source]¶: Update probabilities

openquake.hazardlib.probability_map.combine_probs(array, other, rlzs)[source]¶

openquake.hazardlib.probability_map.update_pmap_i(arr, poes, inv, rates, probs_occur, idxs, itime)[source]¶

openquake.hazardlib.probability_map.update_pmap_m(arr, poes, inv, rates, probs_occur, weights, idxs, itime)[source]¶

openquake.hazardlib.probability_map.update_pnes(arr, idxs, pnes)[source]¶

site¶

Module openquake.hazardlib.site defines Site.

class openquake.hazardlib.site.Site(location, vs30=nan, z1pt0=nan, z2pt5=nan, **extras)[source]¶

Bases: object

Site object represents a geographical location defined by its position as well as its soil characteristics.

Parameters

location – Instance of Point representing where the site is located.
vs30 – Average shear wave velocity in the top 30 m, in m/s.
z1pt0 – Vertical distance from earth surface to the layer where seismic waves start to propagate with a speed above 1.0 km/sec, in meters.
z2pt5 – Vertical distance from earth surface to the layer where seismic waves start to propagate with a speed above 2.5 km/sec, in km.

Raises

ValueError – If any of vs30, z1pt0 or z2pt5 is zero or negative.

Note

Sites are pickleable

class openquake.hazardlib.site.SiteCollection(sites)[source]¶

Bases: object

add_col(colname, dtype, values=None)[source]¶: Add a column to the underlying array

assoc(site_model, assoc_dist, ignore=())[source]¶

Associate the site_model parameters to the sites. Log a warning if the site parameters are more distant than assoc_dist.

Returns: the site model array reduced to the hazard sites

at_sea_level()[source]¶: True if all depths are zero

count_close(location, distance)[source]¶

Returns: the number of sites within the distance from the location

filter(mask)[source]¶

Create a SiteCollection with only a subset of sites.

Parameters: mask – Numpy array of boolean values of the same length as the site collection. True values should indicate that site with that index should be included into the filtered collection.
Returns: A new SiteCollection instance, unless all the values in mask are True, in which case this site collection is returned, or if all the values in mask are False, in which case method returns None. New collection has data of only those sites that were marked for inclusion in the mask.

filtered(indices)[source]¶

Parameters: indices – a subset of indices in the range [0 .. tot_sites - 1]
Returns: a filtered SiteCollection instance if indices is a proper subset of the available indices, otherwise returns the full SiteCollection

classmethod from_points(lons, lats, depths=None, sitemodel=None, req_site_params=())[source]¶

Build the site collection from

Parameters

lons – a sequence of longitudes
lats – a sequence of latitudes
depths – a sequence of depths (or None)
sitemodel – None or an object containing site parameters as attributes
req_site_params – a sequence of required site parameters, possibly empty

classmethod from_usgs_shakemap(shakemap_array)[source]¶: Build a site collection from a shakemap array

geohash(length)[source]¶

Parameters: length – length of the geohash in the range 1..8
Returns: an array of N geohashes, one per site

get_cdist(rec_or_loc)[source]¶

Parameters: rec_or_loc – a record with field ‘hypo’ or a Point instance
Returns: array of N euclidean distances from rec[‘hypo’]

make_complete()[source]¶: Turns the site collection into a complete one, if needed

property mesh¶: Return a mesh with the given lons, lats, and depths

num_geohashes(length)[source]¶

Parameters: length – length of the geohash in the range 1..8
Returns: number of distinct geohashes in the site collection

one()[source]¶

Returns: a SiteCollection with a site of the minimal vs30

reduce(nsites)[source]¶

Returns: a filtered SiteCollection with around nsites (if nsites<=N)

split(ntiles)[source]¶

Parameters: ntiles – number of tiles to generate (rounded if float)
Returns: self if there are <=1 tiles, otherwise the tiles

split_in_tiles(hint)[source]¶: Split a SiteCollection into a set of tiles with contiguous site IDs

split_max(max_sites)[source]¶: Split a SiteCollection into SiteCollection instances

within(region)[source]¶

Parameters: region – a shapely polygon
Returns: a filtered SiteCollection of sites within the region

within_bbox(bbox)[source]¶

Parameters: bbox – a quartet (min_lon, min_lat, max_lon, max_lat)
Returns: site IDs within the bounding box

property xyz¶

Returns: an array of shape (N, 3) with the cartesian coordinates

sourceconverter¶

class openquake.hazardlib.sourceconverter.NPRow(id: str, name: str, code: str, tectonicregion: str, geom: str, coords: list, wkt: str)[source]¶

Bases: object

code: str¶

coords: list¶

geom: str¶

id: str¶

name: str¶

tectonicregion: str¶

wkt: str¶

class openquake.hazardlib.sourceconverter.Row(id: str, name: str, code: str, groupname: str, tectonicregion: str, mfd: str, magscalerel: str, ruptaspectratio: float, upperseismodepth: float, lowerseismodepth: float, nodalplanedist: list, hypodepthdist: list, hypoList: list, slipList: list, rake: float, geomprops: list, geom: str, coords: list, wkt: str)[source]¶

Bases: object

code: str¶

coords: list¶

geom: str¶

geomprops: list¶

groupname: str¶

hypoList: list¶

hypodepthdist: list¶

id: str¶

lowerseismodepth: float¶

magscalerel: str¶

mfd: str¶

name: str¶

nodalplanedist: list¶

rake: float¶

ruptaspectratio: float¶

slipList: list¶

tectonicregion: str¶

upperseismodepth: float¶

wkt: str¶

class openquake.hazardlib.sourceconverter.RowConverter(investigation_time=50.0, rupture_mesh_spacing=5.0, complex_fault_mesh_spacing=None, width_of_mfd_bin=1.0, area_source_discretization=None, minimum_magnitude={'default': 0}, source_id=None, discard_trts=(), floating_x_step=0, floating_y_step=0, source_nodes=())[source]¶

Bases: openquake.hazardlib.sourceconverter.SourceConverter

Used in the command oq nrml_to_csv to convert source models into Row objects.

convert_areaSource(node)[source]¶

Convert the given node into an area source object.

Parameters: node – a node with tag areaGeometry
Returns: a openquake.hazardlib.source.AreaSource instance

convert_characteristicFaultSource(node)[source]¶

Convert the given node into a characteristic fault object.

Parameters: node – a characteristicFaultSource node
Returns: a openquake.hazardlib.source.CharacteristicFaultSource instance

convert_complexFaultSource(node)[source]¶

Convert the given node into a complex fault object.

Parameters: node – a node with tag areaGeometry
Returns: a openquake.hazardlib.source.ComplexFaultSource instance

convert_geomprops(node)[source]¶

convert_hddist(node)[source]¶

Convert the given node into a probability mass function for the hypo depth distribution.

Parameters: node – a hypoDepthDist node
Returns: a openquake.hazardlib.pmf.PMF instance

convert_hypolist(node)[source]¶

convert_mfdist(node)[source]¶

Convert the given node into a Magnitude-Frequency Distribution object.

Parameters: node – a node of kind incrementalMFD or truncGutenbergRichterMFD
Returns: a openquake.hazardlib.mfd.EvenlyDiscretizedMFD. or openquake.hazardlib.mfd.TruncatedGRMFD instance

convert_multiFaultSource(node)[source]¶

Convert the given node into a multi fault source object.

Parameters: node – a node with tag multiFaultSource
Returns: a openquake.hazardlib.source.multiFaultSource instance

convert_multiPointSource(node)[source]¶

Convert the given node into a MultiPointSource object.

Parameters: node – a node with tag multiPointGeometry
Returns: a openquake.hazardlib.source.MultiPointSource

convert_node(node)[source]¶: Convert the given source node into a Row object

convert_nonParametricSeismicSource(node)[source]¶

Convert the given node into a non parametric source object.

Parameters: node – a node with tag areaGeometry
Returns: a openquake.hazardlib.source.NonParametricSeismicSource instance

convert_npdist(node)[source]¶

Convert the given node into a Nodal Plane Distribution.

Parameters: node – a nodalPlaneDist node
Returns: a openquake.hazardlib.geo.NodalPlane instance

convert_pointSource(node)[source]¶

Convert the given node into a point source object.

Parameters: node – a node with tag pointGeometry
Returns: a openquake.hazardlib.source.PointSource instance

convert_rake(node)[source]¶

convert_simpleFaultSource(node)[source]¶

Convert the given node into a simple fault object.

Parameters: node – a node with tag areaGeometry
Returns: a openquake.hazardlib.source.SimpleFaultSource instance

convert_sliplist(node)[source]¶

class openquake.hazardlib.sourceconverter.RuptureConverter(rupture_mesh_spacing, complex_fault_mesh_spacing=None)[source]¶

Bases: object

Convert ruptures from nodes into Hazardlib ruptures.

convert_complexFaultRupture(node)[source]¶

Convert a complexFaultRupture node.

Parameters: node – the rupture node

convert_griddedRupture(node)[source]¶

Convert a griddedRupture node.

Parameters: node – the rupture node

convert_multiPlanesRupture(node)[source]¶

Convert a multiPlanesRupture node.

Parameters: node – the rupture node

convert_node(node)[source]¶

Convert the given rupture node into a hazardlib rupture, depending on the node tag.

Parameters: node – a node representing a rupture

convert_ruptureCollection(node)[source]¶

Parameters: node – a ruptureCollection node
Returns: a dictionary trt_smr -> EBRuptures

convert_simpleFaultRupture(node)[source]¶

Convert a simpleFaultRupture node.

Parameters: node – the rupture node

convert_singlePlaneRupture(node)[source]¶

Convert a singlePlaneRupture node.

Parameters: node – the rupture node

convert_surfaces(surface_nodes, sec_id='')[source]¶

Parameters: surface_nodes – surface nodes as described below

Utility to convert a list of surface nodes into a single hazardlib surface. There are four possibilities:

there is a single simpleFaultGeometry node; returns a openquake.hazardlib.geo.simpleFaultSurface instance
there is a single complexFaultGeometry node; returns a openquake.hazardlib.geo.complexFaultSurface instance
there is a single griddedSurface node; returns a openquake.hazardlib.geo.GriddedSurface instance
there is either a single planarSurface or a list of planarSurface nodes; returns a openquake.hazardlib.geo.PlanarSurface instance or a openquake.hazardlib.geo.MultiSurface instance
there is either a single kiteSurface or a list of kiteSurface nodes; returns a openquake.hazardlib.geo.KiteSurface instance or a openquake.hazardlib.geo.MultiSurface instance

fname = None¶

geo_line(edge)[source]¶

Utility function to convert a node of kind edge into a openquake.hazardlib.geo.Line instance.

Parameters: edge – a node describing an edge

geo_lines(edges)[source]¶

Utility function to convert a list of edges into a list of openquake.hazardlib.geo.Line instances.

Parameters: edge – a node describing an edge

geo_planar(surface)[source]¶

Utility to convert a PlanarSurface node with subnodes topLeft, topRight, bottomLeft, bottomRight into a openquake.hazardlib.geo.PlanarSurface instance.

Parameters: surface – PlanarSurface node

get_mag_rake_hypo(node)[source]¶

class openquake.hazardlib.sourceconverter.SourceConverter(investigation_time=50.0, rupture_mesh_spacing=5.0, complex_fault_mesh_spacing=None, width_of_mfd_bin=1.0, area_source_discretization=None, minimum_magnitude={'default': 0}, source_id=None, discard_trts=(), floating_x_step=0, floating_y_step=0, source_nodes=())[source]¶

Bases: openquake.hazardlib.sourceconverter.RuptureConverter

Convert sources from valid nodes into Hazardlib objects.

convert_areaSource(node)[source]¶

Convert the given node into an area source object.

Parameters: node – a node with tag areaGeometry
Returns: a openquake.hazardlib.source.AreaSource instance

convert_characteristicFaultSource(node)[source]¶

Convert the given node into a characteristic fault object.

Parameters: node – a characteristicFaultSource node
Returns: a openquake.hazardlib.source.CharacteristicFaultSource instance

convert_complexFaultSource(node)[source]¶

Convert the given node into a complex fault object.

Parameters: node – a node with tag areaGeometry
Returns: a openquake.hazardlib.source.ComplexFaultSource instance

convert_geometryModel(node)[source]¶

Parameters: node – a geometryModel node
Returns: a dictionary sec_id -> section

convert_hddist(node)[source]¶

Convert the given node into a probability mass function for the hypo depth distribution.

Parameters: node – a hypoDepthDist node
Returns: a openquake.hazardlib.pmf.PMF instance

convert_kiteFaultSource(node)[source]¶

Convert the given node into a kite fault object.

Parameters: node – a node with tag kiteFaultSource
Returns: a openquake.hazardlib.source.KiteFaultSource instance

convert_mfdist(node)[source]¶

Convert the given node into a Magnitude-Frequency Distribution object.

Parameters: node – a node of kind incrementalMFD or truncGutenbergRichterMFD
Returns: a openquake.hazardlib.mfd.EvenlyDiscretizedMFD. or openquake.hazardlib.mfd.TruncatedGRMFD instance

convert_multiFaultSource(node)[source]¶

Convert the given node into a multi fault source object.

Parameters: node – a node with tag multiFaultSource
Returns: a openquake.hazardlib.source.multiFaultSource instance

convert_multiPointSource(node)[source]¶

Convert the given node into a MultiPointSource object.

Parameters: node – a node with tag multiPointGeometry
Returns: a openquake.hazardlib.source.MultiPointSource

convert_node(node)[source]¶

Convert the given source node into a hazardlib source, depending on the node tag.

Parameters: node – a node representing a source or a SourceGroup

convert_nonParametricSeismicSource(node)[source]¶

Convert the given node into a non parametric source object.

Parameters: node – a node with tag areaGeometry
Returns: a openquake.hazardlib.source.NonParametricSeismicSource instance

convert_npdist(node)[source]¶

Convert the given node into a Nodal Plane Distribution.

Parameters: node – a nodalPlaneDist node
Returns: a openquake.hazardlib.geo.NodalPlane instance

convert_pointSource(node)[source]¶

Convert the given node into a point source object.

Parameters: node – a node with tag pointGeometry
Returns: a openquake.hazardlib.source.PointSource instance

convert_section(node)[source]¶

Parameters: node – a section node
Returns: a list of surfaces

convert_simpleFaultSource(node)[source]¶

Convert the given node into a simple fault object.

Parameters: node – a node with tag areaGeometry
Returns: a openquake.hazardlib.source.SimpleFaultSource instance

convert_sourceGroup(node)[source]¶

Convert the given node into a SourceGroup object.

Parameters: node – a node with tag sourceGroup
Returns: a SourceGroup instance

convert_sourceModel(node)[source]¶

get_tom(node)[source]¶

Convert the given node into a Temporal Occurrence Model object.

Parameters: node – a node of kind poissonTOM or similar
Returns: a openquake.hazardlib.tom.BaseTOM instance

class openquake.hazardlib.sourceconverter.SourceGroup(trt, sources=None, name=None, src_interdep='indep', rup_interdep='indep', grp_probability=1.0, min_mag={'default': 0}, max_mag=None, temporal_occurrence_model=None, cluster=False)[source]¶

Bases: collections.abc.Sequence

A container for the following parameters:

Parameters

trt (str) – the tectonic region type all the sources belong to
sources (list) – a list of hazardlib source objects
name – The name of the group
src_interdep – A string specifying if the sources in this cluster are independent or mutually exclusive
rup_indep – A string specifying if the ruptures within each source of the cluster are independent or mutually exclusive
weights – A dictionary whose keys are the source IDs of the cluster and the values are the weights associated with each source
min_mag – the minimum magnitude among the given sources
max_mag – the maximum magnitude among the given sources
id – an optional numeric ID (default 0) set by the engine and used when serializing SourceModels to HDF5
temporal_occurrence_model – A temporal occurrence model controlling the source group occurrence
cluster – A boolean indicating if the sources behaves as a cluster similarly to what used by the USGS for the New Madrid in the 2008 National Hazard Model.

property atomic¶

Returns: True if the group cannot be split

changes = 0¶

classmethod collect(sources)[source]¶

Parameters: sources – dictionaries with a key ‘tectonicRegion’
Returns: an ordered list of SourceGroup instances

count_ruptures()[source]¶: Set src.num_ruptures on each source in the group

get_tom_toml(time_span)[source]¶

Returns: the TOM as a json string {‘PoissonTOM’: {‘time_span’: 50}}

split(maxweight)[source]¶: Split the group in subgroups with weight <= maxweight, unless it it atomic.

property tom_name¶

Returns: name of the associated temporal occurrence model

update(src)[source]¶

Update the attributes sources, min_mag, max_mag according to the given source.

Parameters: src – an instance of :class: openquake.hazardlib.source.base.BaseSeismicSource

property weight¶

Returns: total weight of the underlying sources

openquake.hazardlib.sourceconverter.collapse(array)[source]¶: Collapse a homogeneous array into a scalar; do nothing if the array is not homogenous

openquake.hazardlib.sourceconverter.convert_nonParametricSeismicSource(fname, node, rup_spacing=5.0)[source]¶

Convert the given node into a non parametric source object.

Parameters

fname – full pathname to the XML file associated to the node
node – a Node object coming from an XML file
rup_spacing – Rupture spacing [km]

Returns

a openquake.hazardlib.source.NonParametricSeismicSource instance

openquake.hazardlib.sourceconverter.drop_trivial_weights(group)[source]¶

openquake.hazardlib.sourceconverter.extract_dupl(values)[source]¶

Parameters: values – a sequence of values
Returns: the duplicated values

openquake.hazardlib.sourceconverter.fix_dupl(dist, fname=None, lineno=None)[source]¶

Fix the distribution if it contains identical values or raise an error.

Parameters

dist – a list of pairs [(prob, value)…] for a hypocenter or nodal plane dist
fname – the file which is being read; if it is None, it means you are writing the distribution: in that case raise an error for duplicated values
lineno – the line number of the file which is being read (None in writing mode)

openquake.hazardlib.sourceconverter.mfds2multimfd(mfds)[source]¶: Convert a list of MFD nodes into a single MultiMFD node

openquake.hazardlib.sourceconverter.multikey(node)[source]¶

Returns: (usd, lsd, rar, hddist, npdist, magScaleRel) for the given node

openquake.hazardlib.sourceconverter.rounded_unique(mags, idxs)[source]¶

Parameters

mags – a list of magnitudes
idxs – a list of tuples of section indices

Returns

an array of magnitudes rounded to 2 digits

Raises

ValueError if the rounded magnitudes contain duplicates

openquake.hazardlib.sourceconverter.split_coords_2d(seq)[source]¶

Parameters: seq – a flat list with lons and lats
Returns: a validated list of pairs (lon, lat)

>>> split_coords_2d([1.1, 2.1, 2.2, 2.3])
[(1.1, 2.1), (2.2, 2.3)]

openquake.hazardlib.sourceconverter.split_coords_3d(seq)[source]¶

Parameters: seq – a flat list with lons, lats and depths
Returns: a validated list of (lon, lat, depths) triplets

>>> split_coords_3d([1.1, 2.1, 0.1, 2.3, 2.4, 0.1])
[(1.1, 2.1, 0.1), (2.3, 2.4, 0.1)]

openquake.hazardlib.sourceconverter.update_source_model(sm_node, fname)[source]¶

Parameters: sm_node – a sourceModel Node object containing sourceGroups

sourcewriter¶

Source model XML Writer

openquake.hazardlib.sourcewriter.build_arbitrary_mfd(mfd)[source]¶

Parses the arbitrary MFD as a Node

Parameters: mfd – MFD as instance of :class: openquake.hazardlib.mfd.arbitrary.ArbitraryMFD
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_area_source_geometry(area_source)[source]¶

Returns the area source geometry as a Node

Parameters: area_source – Area source model as an instance of the :class: openquake.hazardlib.source.area.AreaSource
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_area_source_node(area_source)[source]¶

Parses an area source to a Node class

Parameters: area_source – Area source as instance of :class: openquake.hazardlib.source.area.AreaSource
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_characteristic_fault_source_node(source)[source]¶

openquake.hazardlib.sourcewriter.build_complex_fault_geometry(fault_source)[source]¶

Returns the complex fault source geometry as a Node

Parameters: fault_source – Complex fault source model as an instance of the :class: openquake.hazardlib.source.complex_fault.ComplexFaultSource
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_complex_fault_source_node(fault_source)[source]¶

Parses a complex fault source to a Node class

Parameters: fault_source – Complex fault source as instance of :class: openquake.hazardlib.source.complex_fault.ComplexFaultSource
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_evenly_discretised_mfd(mfd)[source]¶

Returns the evenly discretized MFD as a Node

Parameters: mfd – MFD as instance of :class: openquake.hazardlib.mfd.evenly_discretized.EvenlyDiscretizedMFD
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_hypo_depth_dist(hdd)[source]¶

Returns the hypocentral depth distribution as a Node instance

Parameters: hdd – Hypocentral depth distribution as an instance of :class: openquake.hzardlib.pmf.PMF
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_hypo_list_node(hypo_list)[source]¶

Parameters: hypo_list – an array of shape (N, 3) with columns (alongStrike, downDip, weight)
Returns: a hypoList node containing N hypo nodes

openquake.hazardlib.sourcewriter.build_kite_fault_source_node(fault_source)[source]¶

Parses a kite fault source to a Node class

Parameters: fault_source – Kite fault source as instance of :class: openquake.hazardlib.source.kite_fault.KiteFaultSource
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_kite_surface(ksurface)[source]¶

Returns the KiteSurface instance as a Node

Parameters: ksurface – Kite fault source model as an instance of the :class: openquake.hazardlib.source.kite_fault.KiteFaultSource
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_linestring_node(line, with_depth=False)[source]¶

Parses a line to a Node class

Parameters

line – Line as instance of openquake.hazardlib.geo.line.Line
with_depth (bool) – Include the depth values (True) or not (False):

Returns

Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_multi_fault_source_node(multi_fault_source)[source]¶

Parses a MultiFaultSource to a Node class

Parameters: multi_fault_source – Multi fault source as instance of :class: openquake.hazardlib.source.multi_fault.MultiFaultSource
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_multi_mfd(mfd)[source]¶

Parses the MultiMFD as a Node

Parameters: mfd – MFD as instance of :class: openquake.hazardlib.mfd.multi_mfd.MultiMFD
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_multi_point_source_node(multi_point_source)[source]¶

Parses a point source to a Node class

Parameters: point_source – MultiPoint source as instance of :class: openquake.hazardlib.source.point.MultiPointSource
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_nodal_plane_dist(npd)[source]¶

Returns the nodal plane distribution as a Node instance

Parameters: npd – Nodal plane distribution as instance of :class: openquake.hazardlib.pmf.PMF
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_nonparametric_source_node(source)[source]¶

openquake.hazardlib.sourcewriter.build_point_source_geometry(point_source)[source]¶

Returns the poing source geometry as a Node

Parameters: point_source – Point source model as an instance of the :class: openquake.hazardlib.source.point.PointSource
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_point_source_node(point_source)[source]¶

Parses a point source to a Node class

Parameters: point_source – Point source as instance of :class: openquake.hazardlib.source.point.PointSource
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_rupture_node(rupt, probs_occur)[source]¶

Parameters

rupt – a hazardlib rupture object
probs_occur – a list of floats with sum 1

openquake.hazardlib.sourcewriter.build_simple_fault_geometry(fault_source)[source]¶

Returns the simple fault source geometry as a Node

Parameters: fault_source – Simple fault source model as an instance of the :class: openquake.hazardlib.source.simple_fault.SimpleFaultSource
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_simple_fault_source_node(fault_source)[source]¶

Parses a simple fault source to a Node class

Parameters: fault_source – Simple fault source as instance of :class: openquake.hazardlib.source.simple_fault.SimpleFaultSource
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_slip_list_node(slip_list)[source]¶

Parameters: slip_list – an array of shape (N, 2) with columns (slip, weight)
Returns: a hypoList node containing N slip nodes

openquake.hazardlib.sourcewriter.build_source_group(source_group)[source]¶

openquake.hazardlib.sourcewriter.build_source_model(csm)[source]¶

openquake.hazardlib.sourcewriter.build_source_model_node(source_model)[source]¶

openquake.hazardlib.sourcewriter.build_tapered_gr_mfd(mfd)[source]¶

Parses the truncated Gutenberg Richter MFD as a Node

Parameters: mfd – MFD as instance of :class: openquake.hazardlib.mfd.tapered_gr_mfd.TaperedGRMFD
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_truncated_gr_mfd(mfd)[source]¶

Parses the truncated Gutenberg Richter MFD as a Node

Parameters: mfd – MFD as instance of :class: openquake.hazardlib.mfd.truncated_gr.TruncatedGRMFD
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.build_youngs_coppersmith_mfd(mfd)[source]¶

Parses the Youngs & Coppersmith MFD as a node. Note that the MFD does not hold the total moment rate, but only the characteristic rate. Therefore the node is written to the characteristic rate version regardless of whether or not it was originally created from total moment rate

Parameters: mfd – MFD as instance of :class: openquake.hazardlib.mfd.youngs_coppersmith_1985. YoungsCoppersmith1985MFD
Returns: Instance of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.extract_ddict(src_groups)[source]¶

Returns: a dictionary source_id -> attr -> value

openquake.hazardlib.sourcewriter.get_distributed_seismicity_source_nodes(source)[source]¶

Returns list of nodes of attributes common to all distributed seismicity source classes

Parameters: source – Seismic source as instance of :class: openquake.hazardlib.source.area.AreaSource or :class: openquake.hazardlib.source.point.PointSource
Returns: List of instances of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.get_fault_source_nodes(source)[source]¶

Returns list of nodes of attributes common to all fault source classes

Parameters: source – Fault source as instance of :class: openquake.hazardlib.source.simple_fault.SimpleFaultSource or :class: openquake.hazardlib.source.complex_fault.ComplexFaultSource
Returns: List of instances of openquake.baselib.node.Node

openquake.hazardlib.sourcewriter.get_source_attributes(source)[source]¶

Retreives a dictionary of source attributes from the source class

Parameters: source – Seismic source as instance of :class: openquake.hazardlib.source.base.BaseSeismicSource
Returns: Dictionary of source attributes

openquake.hazardlib.sourcewriter.r4(x)[source]¶: Round lon, lat to 4 digits (11 meters)

openquake.hazardlib.sourcewriter.tomldump(obj, fileobj=None)[source]¶: Write a generic serializable object in TOML format

openquake.hazardlib.sourcewriter.write_source_model(dest, sources_or_groups, name=None, investigation_time=None)[source]¶

Writes a source model to XML.

Parameters

dest – Destination path
sources_or_groups – Source model in different formats
name – Name of the source model (if missing, extracted from the filename)

Returns

the list of generated filenames

stats¶

Utilities to compute mean and quantile curves

openquake.hazardlib.stats.apply_stat(f, arraylist, *extra, **kw)[source]¶

Parameters

f – a callable arraylist -> array (of the same shape and dtype)
arraylist – a list of arrays of the same shape and dtype
extra – additional positional arguments
kw – keyword arguments

Returns

an array of the same shape and dtype

Broadcast statistical functions to composite arrays. Here is an example:

>>> dt = numpy.dtype([('a', (float, 2)), ('b', float)])
>>> a1 = numpy.array([([1, 2], 3)], dt)
>>> a2 = numpy.array([([4, 5], 6)], dt)
>>> apply_stat(mean_curve, [a1, a2])
array([([2.5, 3.5], 4.5)], dtype=[('a', '<f8', (2,)), ('b', '<f8')])

openquake.hazardlib.stats.average_df(dframes, weights=None)[source]¶

Compute weighted average of DataFrames with the same index and columns.

>>> df1 = pandas.DataFrame(dict(value=[1, 1, 1]), [1, 2, 3])
>>> df2 = pandas.DataFrame(dict(value=[2, 2, 2]), [1, 2, 3])
>>> average_df([df1, df2], [.4, .6])
   value
1    1.6
2    1.6
3    1.6

openquake.hazardlib.stats.avg_std(array, weights=None)[source]¶

Parameters

array – an array of shape E, …
weights – an array of length E (or None for equal weights)

Returns

an array of shape (2, …) with average and standard deviation

>>> avg_std(numpy.array([[2, 4, 6], [3, 5, 7]]))
array([[2.5, 4.5, 6.5],
       [0.5, 0.5, 0.5]])

openquake.hazardlib.stats.calc_avg_std(momenta)[source]¶

Parameters

momenta – an array of shape (2, …) obtained via calc_momenta
totweight – total weight to divide for

Returns

an array of shape (2, …) with average and standard deviation

>>> arr = numpy.array([[2, 4, 6], [3, 5, 7]])
>>> weights = numpy.ones(2)
>>> calc_avg_std(calc_momenta(arr, weights))
array([[2.5, 4.5, 6.5],
       [0.5, 0.5, 0.5]])

openquake.hazardlib.stats.calc_momenta(array, weights)[source]¶

Parameters

array – an array of shape (E, …)
weights – an array of length E

Returns

an array of shape (3, …) with the first 3 statistical moments

openquake.hazardlib.stats.calc_stats(df, kfields, stats, weights)[source]¶

Parameters

df – a pandas DataFrame with a column rlz_id
kfields – fields used in the group by
stats – a dictionary stat_name->stat_func
weights – an array of weights for each realization

Returns

a DataFrame with the statistics

openquake.hazardlib.stats.combine_probs(values_by_grp, cmakers, rlz)[source]¶

Parameters

values_by_grp – C arrays of shape (D1, D2…, G)
cmakers – C ContextMakers with G gsims each
rlz – a realization index

Returns

array of shape (D1, D2, …)

openquake.hazardlib.stats.compute_pmap_stats(pmaps, stats, weights, imtls)[source]¶

Parameters

pmaps – a list of R probability maps
stats – a sequence of S statistic functions
weights – a list of ImtWeights
imtls – a DictArray of intensity measure types

Returns

a probability map with S internal values

openquake.hazardlib.stats.compute_stats(array, stats, weights)[source]¶

Parameters

array – an array of R elements (which can be arrays)
stats – a sequence of S statistic functions
weights – a list of R weights

Returns

an array of S elements (which can be arrays)

openquake.hazardlib.stats.compute_stats2(arrayNR, stats, weights)[source]¶

Parameters

arrayNR – an array of (N, R) elements
stats – a sequence of S statistic functions
weights – a list of R weights

Returns

an array of (N, S) elements

openquake.hazardlib.stats.geom_avg_std(array, weights=None)[source]¶

Returns: geometric mean and geometric stddev (see https://en.wikipedia.org/wiki/Log-normal_distribution)

openquake.hazardlib.stats.max_curve(values, weights=None)[source]¶

Compute the maximum curve by taking the upper limits of the values; the weights are ignored and present only for API compatibility. The values can be arrays and then the maximum is taken pointwise:

>>> max_curve([numpy.array([.3, .2]), numpy.array([.1, .4])])
array([0.3, 0.4])

openquake.hazardlib.stats.mean_curve(values, weights=None)[source]¶: Compute the mean by using numpy.average on the first axis.

openquake.hazardlib.stats.norm_cdf(x, a, s)[source]¶

Gaussian cumulative distribution function; if s=0, returns an Heaviside function instead. NB: for x=a, 0.5 is returned for all s.

>>> norm_cdf(1.2, 1, .1)
0.9772498680518208
>>> norm_cdf(1.2, 1, 0)
1.0
>>> norm_cdf(.8, 1, .1)
0.022750131948179216
>>> norm_cdf(.8, 1, 0)
0.0
>>> norm_cdf(1, 1, .1)
0.5
>>> norm_cdf(1, 1, 0)
0.5

openquake.hazardlib.stats.quantile_curve(quantile, curves, weights=None)[source]¶

Compute the weighted quantile aggregate of an array or list of arrays

Parameters

quantile – Quantile value to calculate. Should be in the range [0.0, 1.0].
curves – R arrays
weights – R weights with sum 1, or None

Returns

A numpy array representing the quantile of the underlying arrays

>>> arr = numpy.array([.15, .25, .3, .4, .5, .6, .75, .8, .9])
>>> quantile_curve(.8, arr)
array(0.76)

openquake.hazardlib.stats.set_rlzs_stats(dstore, name, **attrs)[source]¶

Parameters

dstore – a DataStore object
name – dataset name of kind <prefix>-rlzs

openquake.hazardlib.stats.std_curve(values, weights=None)[source]¶

openquake.hazardlib.stats.truncnorm_sf(phi_b, values)[source]¶

Fast survival function for truncated normal distribution. Assumes zero mean, standard deviation equal to one and symmetric truncation. It is faster than using scipy.stats.truncnorm.sf.

Parameters

phi_b – ndtr(truncation_level); assume phi_b > .5
values – Numpy array of values as input to a survival function for the given distribution.

Returns

Numpy array of survival function results in a range between 0 and 1. For phi_b close to .5 returns a step function 1 1 1 1 .5 0 0 0 0 0.

tom¶

Module openquake.hazardlib.tom contains implementations of probability density functions for earthquake temporal occurrence modeling.

class openquake.hazardlib.tom.BaseTOM(time_span)[source]¶

Bases: object

Base class for temporal occurrence model.

Parameters: time_span – The time interval of interest, in years.
Raises: ValueError – If time_span is not positive.

get_probability_n_occurrences()[source]¶: Calculate the probability of occurrence of a number of events in the constructor’s time_span.

get_probability_no_exceedance()[source]¶: Compute and return, for a number of ground motion levels and sites, the probability that a rupture with annual occurrence rate given by occurrence_rate and able to cause ground motion values higher than a given level at a site with probability poes, does not cause any exceedance in the time window specified by the time_span parameter given in the constructor.

get_probability_one_or_more_occurrences()[source]¶: Calculate and return the probability of event to happen one or more times within the time range defined by constructor’s time_span parameter value.

sample_number_of_occurrences(seeds=None)[source]¶

Draw a random sample from the distribution and return a number of events to occur.

The method uses the numpy random generator, which needs a seed in order to get reproducible results. If the seed is None, it should be set outside of this method.

class openquake.hazardlib.tom.ClusterPoissonTOM(time_span, occurrence_rate)[source]¶

Bases: openquake.hazardlib.tom.PoissonTOM

Poissonian temporal occurrence model with an occurrence rate

class openquake.hazardlib.tom.FatedTOM(time_span)[source]¶

Bases: openquake.hazardlib.tom.BaseTOM

get_probability_n_occurrences(occurrence_rate, num)[source]¶: Calculate the probability of occurrence of a number of events in the constructor’s time_span.

get_probability_no_exceedance(occurrence_rate, poes)[source]¶: Compute and return, for a number of ground motion levels and sites, the probability that a rupture with annual occurrence rate given by occurrence_rate and able to cause ground motion values higher than a given level at a site with probability poes, does not cause any exceedance in the time window specified by the time_span parameter given in the constructor.

get_probability_one_or_more_occurrences(occurrence_rate)[source]¶: Calculate and return the probability of event to happen one or more times within the time range defined by constructor’s time_span parameter value.

sample_number_of_occurrences(seeds=None)[source]¶

Draw a random sample from the distribution and return a number of events to occur.

The method uses the numpy random generator, which needs a seed in order to get reproducible results. If the seed is None, it should be set outside of this method.

class openquake.hazardlib.tom.NegativeBinomialTOM(time_span, mu, alpha)[source]¶

Bases: openquake.hazardlib.tom.BaseTOM

Negative Binomial temporal occurrence model.

get_pmf(mean_rate, tol=0.99999999999999, n_max=None)[source]¶

Parameters

mean_rate – The average number of events per year.
tol – Quantile value up to which calculate the pmf

Returns

1D numpy array containing the probability mass distribution, up to tolerance level.

get_probability_n_occurrences(num)[source]¶

Calculate the probability of occurrence of num events in the constructor’s time_span.

Parameters: num – Number of events
Returns: Probability of occurrence

get_probability_no_exceedance(mean_rate, poes)[source]¶

Parameters

mean_rate – The average number of events per year.
poes – 2D numpy array containing conditional probabilities that the rupture occurrence causes a ground shaking value exceeding a ground motion level at a site. First dimension represent sites, second dimension intensity measure levels. poes can be obtained calling the func.

Returns

2D numpy array containing probabilities of no exceedance. First dimension represents sites, second dimension intensity measure levels.

get_probability_one_or_more_occurrences(mean_rate=None)[source]¶

Parameters: mean_rate – The mean rate, or mean number of events per year
Returns: Float value between 0 and 1 inclusive.

sample_number_of_occurrences(mean_rate=None, seed=None)[source]¶

Draw a random sample from the distribution and return a number of events to occur.

The method uses the numpy random generator, which needs a seed in order to get reproducible results. If the seed is None, it should be set outside of this method.

Parameters

mean_rate – The mean rate, or mean number of events per year
seed – Random number generator seed

Returns

Sampled integer number of events to occur within model’s time span.

class openquake.hazardlib.tom.PoissonTOM(time_span)[source]¶

Bases: openquake.hazardlib.tom.BaseTOM

Poissonian temporal occurrence model.

get_probability_n_occurrences(occurrence_rate, num)[source]¶

Calculate the probability of occurrence of num events in the constructor’s time_span.

Parameters

occurrence_rate – Annual rate of occurrence
num – Number of events

Returns

Probability of occurrence

get_probability_no_exceedance(occurrence_rate, poes)[source]¶

Parameters

occurrence_rate – The average number of events per year.
poes – 2D numpy array containing conditional probabilities that the rupture occurrence causes a ground shaking value exceeding a ground motion level at a site. First dimension represent sites, second dimension intensity measure levels. poes can be obtained calling the func.

Returns

2D numpy array containing probabilities of no exceedance. First dimension represents sites, second dimension intensity measure levels.

The probability is computed as exp(-occurrence_rate * time_span * poes)

get_probability_one_or_more_occurrences(occurrence_rate)[source]¶

Calculates probability as 1 - e ** (-occurrence_rate*time_span).

Parameters: occurrence_rate – The average number of events per year.
Returns: Float value between 0 and 1 inclusive.

sample_number_of_occurrences(occurrence_rate, seeds=None)[source]¶

Draw a random sample from the distribution and return a number of events to occur.

The method uses the numpy random generator, which needs a seed in order to get reproducible results. If the seed is None, it should be set outside of this method.

Parameters

occurrence_rate – The average number of events per year.
seeds – Random number generator seeds, one per each occurrence_rate

Returns

Sampled integer number of events to occur within model’s time span.

openquake.hazardlib.tom.get_pnes(rate, probs, poes, time_span)[source]¶

Parameters

rate – occurrence rate in case of a poissonian rupture
probs – probabilities of occurrence in the nonpoissonian case
poes – array of PoEs of shape 2D or 4D
time_span – time span in the poissonian case (0. for FatedTOM)

Fast way to return probabilities of no exceedence given an array of PoEs and some parameter.

valid¶

Validation library for the engine, the desktop tools, and anything else

class openquake.hazardlib.valid.Choice(*choices)[source]¶

Bases: object

Check if the choice is valid (case sensitive).

class openquake.hazardlib.valid.ChoiceCI(*choices)[source]¶

Bases: object

Check if the choice is valid (case insensitive version).

class openquake.hazardlib.valid.Choices(*choices)[source]¶

Bases: openquake.hazardlib.valid.Choice

Convert the choices, passed as a comma separated string, into a tuple of validated strings. For instance

>>> Choices('xml', 'csv')('xml,csv')
('xml', 'csv')

class openquake.hazardlib.valid.FloatRange(minrange, maxrange, name='', accept=None)[source]¶: Bases: object

class openquake.hazardlib.valid.FromFile[source]¶

Bases: object

Fake GSIM to be used when the GMFs are imported from an external file and not computed with a GSIM.

DEFINED_FOR_INTENSITY_MEASURE_TYPES = {}¶

DEFINED_FOR_REFERENCE_VELOCITY = None¶

REQUIRES_DISTANCES = {}¶

REQUIRES_RUPTURE_PARAMETERS = {}¶

REQUIRES_SITES_PARAMETERS = {}¶

compute(ctx, imts, mean, sig, tau, phi)[source]¶

init()[source]¶

kwargs = {}¶

requires()[source]¶

class openquake.hazardlib.valid.MetaParamSet(name, bases, dic)[source]¶

Bases: type

Set the .name attribute of every Param instance defined inside any subclass of ParamSet.

class openquake.hazardlib.valid.NoneOr(cast)[source]¶

Bases: object

Accept the empty string (casted to None) or something else validated by the underlying cast validator.

class openquake.hazardlib.valid.Param(validator, default=<object object>, name=None)[source]¶

Bases: object

A descriptor for validated parameters with a default, to be used as attributes in ParamSet objects.

Parameters

validator – the validator
default – the default value

NODEFAULT = <object object>¶

class openquake.hazardlib.valid.ParamSet(**names_vals)[source]¶

Bases: object

A set of valid interrelated parameters. Here is an example of usage:

>>> class MyParams(ParamSet):
...     a = Param(positiveint)
...     b = Param(positivefloat)
...
...     def is_valid_not_too_big(self):
...         "The sum of a and b must be under 10: a={a} and b={b}"
...         return self.a + self.b < 10

>>> mp = MyParams(a='1', b='7.2')
>>> mp
<MyParams a=1, b=7.2>

>>> MyParams(a='1', b='9.2').validate()
Traceback (most recent call last):
...
ValueError: The sum of a and b must be under 10: a=1 and b=9.2

The constrains are applied in lexicographic order. The attribute corresponding to a Param descriptor can be set as usual:

>>> mp.a = '2'
>>> mp.a
'2'

A list with the literal strings can be extracted as follows:

>>> mp.to_params()
[('a', "'2'"), ('b', '7.2')]

It is possible to build a new object from a dictionary of parameters which are assumed to be already validated:

>>> MyParams.from_(dict(a="'2'", b='7.2'))
<MyParams a='2', b=7.2>

KNOWN_INPUTS = {}¶

classmethod check(dic)[source]¶

Check if a dictionary name->string can be converted into a dictionary name->value. If the name does not correspond to a known parameter, print a warning.

Returns: a dictionary of converted parameters

classmethod from_(dic)[source]¶: Build a new ParamSet from a dictionary of string-valued parameters which are assumed to be already valid.

json()[source]¶

Returns: the parameters as a JSON string

params = {}¶

to_params()[source]¶: Convert the instance dictionary into a sorted list of pairs (name, valrepr) where valrepr is the string representation of the underlying value.

validate()[source]¶: Apply the is_valid methods to self and possibly raise a ValueError.

class openquake.hazardlib.valid.Regex(regex)[source]¶

Bases: object

Compare the value with the given regex

class openquake.hazardlib.valid.RjbEquivalent(filename)[source]¶

Bases: object

A class to compute the equivalent Rjb distance. Usage:

>> reqv = RjbEquivalent(‘lookup.hdf5’) >> reqv.get(repi_distances, mag)

get(repi, mag)[source]¶

Parameters

repi – an array of epicentral distances in the range self.repi
mag – a magnitude in the range self.mags

Returns

an array of equivalent distances

class openquake.hazardlib.valid.SimpleId(length, regex='^[\\w_\\-:]+$')[source]¶

Bases: object

Check if the given value is a valid ID.

Parameters

length – maximum length of the ID
regex – accepted characters

openquake.hazardlib.valid.ab_values(value)[source]¶: a and b values of the GR magniture-scaling relation. a is a positive float, b is just a float.

openquake.hazardlib.valid.boolean(value)[source]¶

Parameters: value – input string such as ‘0’, ‘1’, ‘true’, ‘false’
Returns: boolean

>>> boolean('')
False
>>> boolean('True')
True
>>> boolean('false')
False
>>> boolean('t')
Traceback (most recent call last):
    ...
ValueError: Not a boolean: t

openquake.hazardlib.valid.check_levels(imls, imt, min_iml=1e-10)[source]¶

Raise a ValueError if the given levels are invalid.

Parameters

imls – a list of intensity measure and levels
imt – the intensity measure type
min_iml – minimum intensity measure level (default 1E-10)

>>> check_levels([0.1, 0.2], 'PGA')  # ok
>>> check_levels([], 'PGA')
Traceback (most recent call last):
   ...
ValueError: No imls for PGA: []
>>> check_levels([0.2, 0.1], 'PGA')
Traceback (most recent call last):
   ...
ValueError: The imls for PGA are not sorted: [0.2, 0.1]
>>> check_levels([0.2, 0.2], 'PGA')
Traceback (most recent call last):
   ...
ValueError: Found duplicated levels for PGA: [0.2, 0.2]

openquake.hazardlib.valid.check_weights(nodes_with_a_weight)[source]¶

Ensure that the sum of the values is 1

Parameters: nodes_with_a_weight – a list of Node objects with a weight attribute

openquake.hazardlib.valid.compose(*validators)[source]¶

Implement composition of validators. For instance

>>> utf8_not_empty = compose(utf8, not_empty)

openquake.hazardlib.valid.coordinates(value)[source]¶

Convert a non-empty string into a list of lon-lat coordinates.

>>> coordinates('')
Traceback (most recent call last):
...
ValueError: Empty list of coordinates: ''
>>> coordinates('1.1 1.2')
[(1.1, 1.2, 0.0)]
>>> coordinates('1.1 1.2, 2.2 2.3')
[(1.1, 1.2, 0.0), (2.2, 2.3, 0.0)]
>>> coordinates('1.1 1.2 -0.4, 2.2 2.3 -0.5')
[(1.1, 1.2, -0.4), (2.2, 2.3, -0.5)]
>>> coordinates('0 0 0, 0 0 -1')
Traceback (most recent call last):
...
ValueError: Found overlapping site #2,  0 0 -1

openquake.hazardlib.valid.decreasing_probabilities(value)[source]¶

Parameters: value – input string, comma separated or space separated
Returns: a list of decreasing probabilities

>>> decreasing_probabilities('1')
Traceback (most recent call last):
...
ValueError: Not enough probabilities, found '1'
>>> decreasing_probabilities('0.2 0.1')
[0.2, 0.1]
>>> decreasing_probabilities('0.1 0.2')
Traceback (most recent call last):
...
ValueError: The probabilities 0.1 0.2 are not in decreasing order

openquake.hazardlib.valid.depth(value)¶

Parameters: value – input string
Returns: a floating point number

openquake.hazardlib.valid.dictionary(value)[source]¶

Parameters: value – input string corresponding to a literal Python object
Returns: the Python object

>>> dictionary('')
{}
>>> dictionary('{}')
{}
>>> dictionary('{"a": 1}')
{'a': 1}
>>> dictionary('"vs30_clustering: true"')  # an error really done by a user
Traceback (most recent call last):
   ...
ValueError: '"vs30_clustering: true"' is not a valid Python dictionary
>>> dictionary('{"ls": logscale(0.01, 2, 5)}')
{'ls': [0.01, 0.03760603093086393, 0.14142135623730948, 0.5318295896944986, 1.9999999999999991]}

openquake.hazardlib.valid.disagg_outputs(value)[source]¶

Validate disaggregation outputs. For instance

>>> disagg_outputs('TRT Mag_Dist')
['TRT', 'Mag_Dist']
>>> disagg_outputs('TRT, Mag_Dist')
['TRT', 'Mag_Dist']

openquake.hazardlib.valid.float_(value)[source]¶

Parameters: value – input string
Returns: a floating point number

openquake.hazardlib.valid.floats(value)[source]¶

Parameters: value – string of whitespace separated floats
Returns: a list of floats

openquake.hazardlib.valid.gsim(value, basedir='')[source]¶

Convert a string into a GSIM instance

>>> gsim('BooreAtkinson2011')
[BooreAtkinson2011]

openquake.hazardlib.valid.host_port(value=None)[source]¶

Returns a pair (host_IP, port_number).

>>> host_port('localhost:1908')
('127.0.0.1', 1908)

If value is missing returns the parameters in openquake.cfg

openquake.hazardlib.valid.hypo_list(nodes)[source]¶

Parameters: nodes – a hypoList node with N hypocenter nodes
Returns: a numpy array of shape (N, 3) with strike, dip and weight

openquake.hazardlib.valid.integers(value)[source]¶

Parameters: value – input string
Returns: non-empty list of integers

>>> integers('1, 2')
[1, 2]
>>> integers(' ')
Traceback (most recent call last):
   ...
ValueError: Not a list of integers: ' '

openquake.hazardlib.valid.intensity_measure_type(value)[source]¶

Make sure value is a valid intensity measure type and return it in a normalized form

>>> intensity_measure_type('SA(0.10)')  # NB: strips the trailing 0
'SA(0.1)'
>>> intensity_measure_type('SA')  # this is invalid
Traceback (most recent call last):
  ...
ValueError: Invalid IMT: 'SA'

openquake.hazardlib.valid.intensity_measure_types(value)[source]¶

Parameters: value – input string
Returns: non-empty list of ordered Intensity Measure Type objects

>>> intensity_measure_types('')
[]
>>> intensity_measure_types('PGA')
['PGA']
>>> intensity_measure_types('PGA, SA(1.00)')
['PGA', 'SA(1.0)']
>>> intensity_measure_types('SA(0.1), SA(0.10)')
Traceback (most recent call last):
  ...
ValueError: Duplicated IMTs in SA(0.1), SA(0.10)
>>> intensity_measure_types('PGV, SA(1), PGA')
['PGV', 'PGA', 'SA(1.0)']

openquake.hazardlib.valid.intensity_measure_types_and_levels(value)[source]¶

Parameters: value – input string
Returns: Intensity Measure Type and Levels dictionary

>>> intensity_measure_types_and_levels('{"SA(0.10)": [0.1, 0.2]}')
{'SA(0.1)': [0.1, 0.2]}

openquake.hazardlib.valid.latitude(value)[source]¶

Parameters: value – input string
Returns: latitude float, rounded to 5 digits, i.e. 1 meter maximum

>>> latitude('-0.123456')
-0.12346

openquake.hazardlib.valid.latitudes(value)[source]¶

Parameters: value – a comma separated string of latitudes
Returns: a list of latitudes

openquake.hazardlib.valid.logic_tree_path(value)[source]¶

>>> logic_tree_path('SM2_a3b1')
['SM2', 'a3b1']

openquake.hazardlib.valid.logscale(x_min, x_max, n)[source]¶

Parameters

x_min – minumum value
x_max – maximum value
n – number of steps

Returns

an array of n values from x_min to x_max

openquake.hazardlib.valid.lon_lat(value)[source]¶

Parameters: value – a pair of coordinates
Returns: a tuple (longitude, latitude)

>>> lon_lat('12 14')
(12.0, 14.0)

openquake.hazardlib.valid.longitude(value)[source]¶

Parameters: value – input string
Returns: longitude float, rounded to 5 digits, i.e. 1 meter maximum

>>> longitude('0.123456')
0.12346

openquake.hazardlib.valid.longitudes(value)[source]¶

Parameters: value – a comma separated string of longitudes
Returns: a list of longitudes

openquake.hazardlib.valid.loss_ratios(value)[source]¶

Parameters: value – input string
Returns: dictionary loss_type -> loss ratios

>>> loss_ratios('{"structural": [0.1, 0.2]}')
{'structural': [0.1, 0.2]}

openquake.hazardlib.valid.mag_scale_rel(value)[source]¶

Parameters: value – a Magnitude-Scale relationship in hazardlib
Returns: the corresponding hazardlib object

Parametric MSR classes are supported with TOML syntax; for instance

>>> mag_scale_rel("CScalingMSR.C=4.7")
<CScalingMSR>

openquake.hazardlib.valid.namelist(value)[source]¶

Parameters: value – input string
Returns: list of identifiers separated by whitespace or commas

>>> namelist('a,b')
['a', 'b']
>>> namelist('a1  b_2       _c')
['a1', 'b_2', '_c']

>>> namelist('a1 b_2 1c')
['a1', 'b_2', '1c']

openquake.hazardlib.valid.namelists(value)[source]¶

Parameters: value – input string
Returns: list of lists of identifiers

>>> namelists('a,b')
[['a', 'b']]
>>> namelists('a1, b_2; _c')
[['a1', 'b_2'], ['_c']]

>>> namelists('a1; b_2; 1c')
[['a1'], ['b_2'], ['1c']]

openquake.hazardlib.valid.nonzero(value)[source]¶

Parameters: value – input string
Returns: the value unchanged

>>> nonzero('1')
'1'
>>> nonzero('0')
Traceback (most recent call last):
  ...
ValueError: '0' is zero

openquake.hazardlib.valid.not_empty(value)[source]¶: Check that the string is not all blanks

openquake.hazardlib.valid.occurrence_model(value)[source]¶

Converts a TOML string into a TOM instance

>>> print(occurrence_model('[PoissonTOM]\ntime_span=50.0'))
[PoissonTOM]
time_span = 50.0

openquake.hazardlib.valid.pmf(value)[source]¶

Comvert a string into a Probability Mass Function.

Parameters: value – a sequence of probabilities summing up to 1 (no commas)
Returns: a list of pairs [(probability, index), …] with index starting from 0

>>> pmf("0.157 0.843")
[(0.157, 0), (0.843, 1)]

openquake.hazardlib.valid.point(value)[source]¶

Parameters: value – a tuple of coordinates as a string (2D or 3D)
Returns: a tuple of coordinates as a string (2D or 3D)

openquake.hazardlib.valid.point3d(value, lon, lat, depth)[source]¶

This is used to convert nodes of the form <hypocenter lon=”LON” lat=”LAT” depth=”DEPTH”/>

Parameters

value – None
lon – longitude string
lat – latitude string

Returns

a validated triple (lon, lat, depth)

openquake.hazardlib.valid.posList(value)[source]¶

Parameters: value – a string with the form lon1 lat1 [depth1] … lonN latN [depthN] without commas, where the depts are optional.
Returns: a list of floats without other validations

openquake.hazardlib.valid.positivefloat(value)[source]¶

Parameters: value – input string
Returns: positive float

openquake.hazardlib.valid.positivefloats(value)[source]¶

Parameters: value – string of whitespace separated floats
Returns: a list of positive floats

openquake.hazardlib.valid.positiveint(value)[source]¶

Parameters: value – input string
Returns: positive integer

openquake.hazardlib.valid.positiveints(value)[source]¶

>>> positiveints('1, -1')
Traceback (most recent call last):
   ...
ValueError: -1 is negative in '1, -1'

openquake.hazardlib.valid.probabilities(value, rows=0, cols=0)[source]¶

Parameters

value – input string, comma separated or space separated
rows – the number of rows if the floats are in a matrix (0 otherwise)
cols – the number of columns if the floats are in a matrix (or 0

Returns

a list of probabilities

>>> probabilities('')
[]
>>> probabilities('1')
[1.0]
>>> probabilities('0.1 0.2')
[0.1, 0.2]
>>> probabilities('0.1, 0.2')  # commas are ignored
[0.1, 0.2]

openquake.hazardlib.valid.range01(value)[source]¶

Parameters: value – a string convertible to a float in the range 0..1

openquake.hazardlib.valid.risk_id(value)[source]¶: A valid risk ID cannot contain the characters #’”

openquake.hazardlib.valid.simple_slice(value)[source]¶

>>> simple_slice('2:5')
(2, 5)
>>> simple_slice('0:None')
(0, None)

openquake.hazardlib.valid.site_param(dic)[source]¶: Convert a dictionary site_model_param -> string into a dictionary of valid casted site parameters.

openquake.hazardlib.valid.slip_list(nodes)[source]¶

Parameters: nodes – a slipList node with N slip nodes
Returns: a numpy array of shape (N, 2) with slip angle and weight

openquake.hazardlib.valid.to_toml(uncertainty)[source]¶: Converts an uncertainty node into a TOML string

openquake.hazardlib.valid.uncertainty_model(value)[source]¶: Format whitespace in XML nodes of kind uncertaintyModel

openquake.hazardlib.valid.utf8(value)[source]¶

Check that the string is UTF-8. Returns an encode bytestring.

>>> utf8(b'\xe0')  
Traceback (most recent call last):
...
ValueError: Not UTF-8: ...

openquake.hazardlib.valid.utf8_not_empty(value)[source]¶: Check that the string is UTF-8 and not empty

openquake.hazardlib.valid.weights(value)[source]¶

Space-separated list of weights:

>>> weights('0.1 0.2 0.7')
[0.1, 0.2, 0.7]

>>> weights('0.1 0.2 0.8')
Traceback (most recent call last):
  ...
ValueError: The weights do not sum up to 1: [0.1, 0.2, 0.8]

openquake.hazardlib.valid.wkt_polygon(value)[source]¶: Convert a string with a comma separated list of coordinates into a WKT polygon, by closing the ring.

openquake.hazardlib package¶

Subpackages¶

contexts¶

const¶

correlation¶

imt¶

lt¶

near_fault¶

nrml¶

pmf¶

probability_map¶

site¶

sourceconverter¶

sourcewriter¶

stats¶

tom¶

valid¶

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