bilby.gw.prior.CalibrationPriorDict

class bilby.gw.prior.CalibrationPriorDict(dictionary=None, filename=None)[source]

Bases: PriorDict

Prior dictionary class for calibration parameters. This has methods for simplifying the creation of priors for the large numbers of parameters used with the spline model.

__init__(dictionary=None, filename=None)[source]

Initialises a Prior dictionary for calibration parameters

Parameters:

dictionary: dict, optional: See superclass
filename: str, optional: See superclass

__call__(*args, **kwargs): Call self as a function.

Methods

`__init__`([dictionary, filename])	Initialises a Prior dictionary for calibration parameters
`cdf`(sample)	Evaluate the cumulative distribution function at the provided points
`check_ln_prob`(sample, ln_prob)
`check_prob`(sample, prob)
`clear`()
`constant_uncertainty_spline`(amplitude_sigma, ...)	Make prior assuming constant in frequency calibration uncertainty.
`convert_floats_to_delta_functions`()	Convert all float parameters to delta functions
`copy`()	We have to overwrite the copy method as it fails due to the presence of defaults.
`default_conversion_function`(sample)	Placeholder parameter conversion function.
`evaluate_constraints`(sample)
`fill_priors`(likelihood[, default_priors_file])	Fill dictionary of priors based on required parameters of likelihood
`from_dictionary`(dictionary)
`from_envelope_file`(envelope_file, ...[, ...])	Load in the calibration envelope.
`from_file`(filename)	Reads in a prior from a file specification
`from_json`(filename)	Reads in a prior from a json file
`fromkeys`(iterable[, value])	Create a new dictionary with keys from iterable and values set to value.
`get`(key[, default])	Return the value for key if key is in the dictionary, else default.
`items`()
`keys`()
`ln_prob`(sample[, axis])	Parameters:
`normalize_constraint_factor`(keys[, ...])
`pop`(key[, default])	If the key is not found, return the default if given; otherwise, raise a KeyError.
`popitem`(/)	Remove and return a (key, value) pair as a 2-tuple.
`prob`(sample, **kwargs)	Parameters:
`rescale`(keys, theta)	Rescale samples from unit cube to prior
`sample`([size])	Draw samples from the prior set
`sample_subset`([keys, size])	Draw samples from the prior set for parameters which are not a DeltaFunction
`sample_subset_constrained`([keys, size])
`sample_subset_constrained_as_array`([keys, size])	Return an array of samples
`setdefault`(key[, default])	Insert key with a value of default if key is not in the dictionary.
`test_has_redundant_keys`()	Test whether there are redundant keys in self.
`test_redundancy`(key[, disable_logging])	Empty redundancy test, should be overwritten in subclasses
`to_file`(outdir, label)	Write the prior to file.
`to_json`(outdir, label)
`update`([E, ]**F)	If E is present and has a .keys() method, then does: for k in E: D[k] = E[k] If E is present and lacks a .keys() method, then does: for k, v in E: D[k] = v In either case, this is followed by: for k in F: D[k] = F[k]
`values`()

Attributes

`constraint_keys`
`fixed_keys`
`non_fixed_keys`

cdf(sample)[source]

Evaluate the cumulative distribution function at the provided points

Parameters:

sample: dict, pandas.DataFrame: Dictionary of the samples of which to calculate the CDF

Returns:

dict, pandas.DataFrame: Dictionary containing the CDF values

clear() → None. Remove all items from D.

static constant_uncertainty_spline(amplitude_sigma, phase_sigma, minimum_frequency, maximum_frequency, n_nodes, label, boundary='reflective')[source]

Make prior assuming constant in frequency calibration uncertainty.

This assumes Gaussian fluctuations about 0.

Parameters:

amplitude_sigma: float: Uncertainty in the amplitude.
phase_sigma: float: Uncertainty in the phase.
minimum_frequency: float: Minimum frequency for the spline.
maximum_frequency: float: Minimum frequency for the spline.
n_nodes: int: Number of nodes for the spline.
label: str: Label for the names of the parameters, e.g., recalib_H1_
boundary: None, ‘reflective’, ‘periodic’: The type of prior boundary to assign

Returns:

prior: PriorDict: Priors for the relevant parameters. This includes the frequencies of the nodes which are _not_ sampled.

convert_floats_to_delta_functions()[source]: Convert all float parameters to delta functions

copy()[source]: We have to overwrite the copy method as it fails due to the presence of defaults.

default_conversion_function(sample)[source]

Placeholder parameter conversion function.

Parameters:

sample: dict: Dictionary to convert

Returns:

sample: dict: Same as input

fill_priors(likelihood, default_priors_file=None)[source]

Fill dictionary of priors based on required parameters of likelihood

Any floats in prior will be converted to delta function prior. Any required, non-specified parameters will use the default.

Note: if likelihood has non_standard_sampling_parameter_keys, then this will set-up default priors for those as well.

Parameters:

likelihood: bilby.likelihood.GravitationalWaveTransient instance: Used to infer the set of parameters to fill the prior with
default_priors_file: str, optional: If given, a file containing the default priors.

Returns:

prior: dict: The filled prior dictionary

static from_envelope_file(envelope_file, minimum_frequency, maximum_frequency, n_nodes, label, boundary='reflective')[source]

Load in the calibration envelope.

This is a text file with columns

frequency median-amplitude median-phase -1-sigma-amplitude
-1-sigma-phase +1-sigma-amplitude +1-sigma-phase

Parameters:

envelope_file: str: Name of file to read in.
minimum_frequency: float: Minimum frequency for the spline.
maximum_frequency: float: Minimum frequency for the spline.
n_nodes: int: Number of nodes for the spline.
label: str: Label for the names of the parameters, e.g., recalib_H1_
boundary: None, ‘reflective’, ‘periodic’: The type of prior boundary to assign

Returns:

prior: PriorDict: Priors for the relevant parameters. This includes the frequencies of the nodes which are _not_ sampled.

from_file(filename)[source]

Reads in a prior from a file specification

Parameters:

filename: str: Name of the file to be read in

Notes

Lines beginning with ‘#’ or empty lines will be ignored. Priors can be loaded from:

bilby.core.prior as, e.g., foo = Uniform(minimum=0, maximum=1)
floats, e.g., foo = 1
bilby.gw.prior as, e.g., foo = bilby.gw.prior.AlignedSpin()
other external modules, e.g., foo = my.module.CustomPrior(...)

classmethod from_json(filename)[source]

Reads in a prior from a json file

Parameters:

filename: str: Name of the file to be read in

fromkeys(iterable, value=None, /): Create a new dictionary with keys from iterable and values set to value.

get(key, default=None, /): Return the value for key if key is in the dictionary, else default.

items() → a set-like object providing a view on D's items

keys() → a set-like object providing a view on D's keys

ln_prob(sample, axis=None)[source]

Parameters:

sample: dict: Dictionary of the samples of which to calculate the log probability
axis: None or int: Axis along which the summation is performed

Returns:

float or ndarray:: Joint log probability of all the individual sample probabilities

pop(key, default=<unrepresentable>, /): If the key is not found, return the default if given; otherwise, raise a KeyError.

popitem(/)

Remove and return a (key, value) pair as a 2-tuple.

Pairs are returned in LIFO (last-in, first-out) order. Raises KeyError if the dict is empty.

prob(sample, **kwargs)[source]

Parameters:

sample: dict: Dictionary of the samples of which we want to have the probability of
kwargs:: The keyword arguments are passed directly to np.prod

Returns:

float: Joint probability of all individual sample probabilities

rescale(keys, theta)[source]

Rescale samples from unit cube to prior

Parameters:

keys: list: List of prior keys to be rescaled
theta: list: List of randomly drawn values on a unit cube associated with the prior keys

Returns:

list: List of floats containing the rescaled sample

sample(size=None)[source]

Draw samples from the prior set

Parameters:

size: int or tuple of ints, optional: See numpy.random.uniform docs

Returns:

dict: Dictionary of the samples

sample_subset(keys=<list_iterator object>, size=None)[source]

Draw samples from the prior set for parameters which are not a DeltaFunction

Parameters:

keys: list: List of prior keys to draw samples from
size: int or tuple of ints, optional: See numpy.random.uniform docs

Returns:

dict: Dictionary of the drawn samples

sample_subset_constrained_as_array(keys=<list_iterator object>, size=None)[source]

Return an array of samples

Parameters:

keys: list: A list of keys to sample in
size: int: The number of samples to draw

Returns:

array: array_like: An array of shape (len(key), size) of the samples (ordered by keys)

setdefault(key, default=None, /)

Insert key with a value of default if key is not in the dictionary.

Return the value for key if key is in the dictionary, else default.

test_has_redundant_keys()[source]

Test whether there are redundant keys in self.

Returns:

bool: Whether there are redundancies or not

test_redundancy(key, disable_logging=False)[source]: Empty redundancy test, should be overwritten in subclasses

to_file(outdir, label)[source]

Write the prior to file. This includes information about the source if possible.

Parameters:

outdir: str: Output directory.
label: str: Label for prior.

update([E, ]**F) → None. Update D from dict/iterable E and F.: If E is present and has a .keys() method, then does: for k in E: D[k] = E[k] If E is present and lacks a .keys() method, then does: for k, v in E: D[k] = v In either case, this is followed by: for k in F: D[k] = F[k]

values() → an object providing a view on D's values