openquake.hmtk.seismicity.completeness package¶
Submodules¶
openquake.hmtk.seismicity.completeness.base module¶
Module :mod:’openquake.hmtk.seismicity.completeness.base’ defines an abstract base class for :class:’CataloguCompleteness <BaseCatalogueCompleteness>
openquake.hmtk.seismicity.completeness.comp_stepp_1971 module¶
Module openquake.hmtk.seismicity.completeness.comp_stepp_1972 defines
the openquake.hmtk implementation of the Stepp (1972) algorithm for analysing
the completeness of an earthquake catalogue
- class openquake.hmtk.seismicity.completeness.comp_stepp_1971.Stepp1971[source]¶
Bases:
openquake.hmtk.seismicity.completeness.base.BaseCatalogueCompletenessImplements the completeness analysis methodology of Stepp (1972) Stepp, J. C. (1972) Analysis of Completeness of the Earhquake Sample in the Puget Sound Area and Its Effect on Statistical Estimates of Earthquake Hazard, NOAA Environmental Research Laboratories.
The original methodology of J. C. Stepp (1972) implements a graphical method in which the deviation of the observed rate from the expected Poisson rate is assessed by judgement. To implement the selection in an automated fashion this implementation uses optimisation of a 2-segment piecewise linear fit to each magnitude bin, using the segment intersection point to identify the completeness period.
Adaptation implemented by Weatherill, G. A., GEM Model Facility, Pavia
- Attribute numpy.ndarray magnitude_bin
Edges of the magnitude bins
- Attribute numpy.ndarray sigma
Sigma lambda defined by Equation 4 in Stepp (1972)
- Attribute numpy.ndarray time_values
Duration values
- Attribute numpy.ndarray model_line
Expected Poisson rate for each magnitude bin
- Attribute numpy.ndarray completeness_table
Resulting completeness table
- completeness(catalogue, config)[source]¶
Gets the completeness table.
- Parameters
catalogue – Earthquake catalogue as instance of
openquake.hmtk.seismicity.catalogue.Catalogueconfig (dict) – Configuration parameters of the algorithm, containing the following information: ‘magnitude_bin’ Size of magnitude bin (non-negative float) ‘time_bin’ Size (in dec. years) of the time window (non-negative float) ‘increment_lock’ Boolean to indicate whether to ensure completeness magnitudes always decrease with more recent bins
- Returns
2-column table indicating year of completeness and corresponding magnitude numpy.ndarray
- get_completeness_points(n_years, sigma, n_mags, n_time)[source]¶
Fits a bilinear model to each sigma-n_years combination in order to get the crossover point. The gradient of the first line must always be 1 / sqrt(T), but it is free for the other lines
- Parameters
n_years (numpy.ndarray) – Duration of each completeness time window
sigma (numpy.ndarray) – Poisson variances of each time-magnitude combination
n_mags (int) – Number of magnitude bins
n_time (int) – Number of time bins
- Returns
comp_time (Completeness duration)
gradient_2 (Gradient of second slope of piecewise linear fit)
model_line (Expected Poisson rate for data (only used for plot)
- openquake.hmtk.seismicity.completeness.comp_stepp_1971.get_bilinear_residuals_stepp(input_params, xvals, yvals, slope1_fit)[source]¶
Returns the residual sum-of-squares value of a bilinear fit to a data set - with a segment - 1 gradient fixed by an input value (slope_1_fit)
- Parameters
input_params (list) –
- Input parameters for the bilinear model [slope2, crossover_point,
intercept]
xvals (numpy.ndarray) – x-values of the data to be fit
yvals (numpy.ndarray) – y-values of the data to be fit
slope1_fit (float) – Gradient of the first slope
- Returns
Residual sum-of-squares of fit