bilby.core.likelihood.PoissonLikelihood

class bilby.core.likelihood.PoissonLikelihood(x, y, func, **kwargs)[source]

__init__(x, y, func, **kwargs)[source]

A general Poisson likelihood for a rate - the model parameters are inferred from the arguments of function, which provides a rate.

Parameters:

x: array_like: A dependent variable at which the Poisson rates will be calculated
y: array_like: The data to analyse - this must be a set of non-negative integers, each being the number of events within some interval.
func:: The python function providing the rate of events per interval to fit to the data. The function must be defined with the first argument being a dependent parameter (although this does not have to be used by the function if not required). The subsequent arguments will require priors and will be sampled over (unless a fixed value is given).

Methods

`__init__`(x, y, func, **kwargs)	A general Poisson likelihood for a rate - the model parameters are inferred from the arguments of function, which provides a rate.
`log_likelihood`()	Returns:
`log_likelihood_ratio`()	Difference between log likelihood and noise log likelihood
`noise_log_likelihood`()	Returns:

Attributes

`func`	Make func read-only
`function_keys`	Makes function_keys read_only
`marginalized_parameters`
`meta_data`
`model_parameters`	This sets up the function only parameters (i.e. not sigma for the GaussianLikelihood) .
`n`	The number of data points
`residual`	Residual of the function against the data.
`x`	The independent variable.
`y`	Property assures that y-value is a positive integer.

log_likelihood()[source]

Returns:

log_likelihood_ratio()[source]

Difference between log likelihood and noise log likelihood

Returns:

property model_parameters: This sets up the function only parameters (i.e. not sigma for the GaussianLikelihood)

noise_log_likelihood()[source]

Returns:

property x: The independent variable. Setter assures that single numbers will be converted to arrays internally