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Installation Guide | readthedocs | Introduction on Binder | HowToFit

PyAutoFit is a Python based probabilistic programming language for the fully Bayesian analysis of extremely large datasets which:

  • Makes it simple to compose and fit multi-level models using a range of Bayesian inference libraries, such as emcee and dynesty.

  • Handles the ‘heavy lifting’ that comes with model-fitting, including model composition & customization, outputting results, model-specific visualization and posterior analysis.

  • Is built for big-data analysis, whereby results are output as a sqlite database which can be queried after model-fitting is complete.

PyAutoFit supports advanced statistical methods such as graphical and hierarchical models, model-fit chaining, sensitivity mapping and massively parallel model-fits .

Getting Started

The following links are useful for new starters:

Why PyAutoFit?

PyAutoFit began as an Astronomy project for fitting large imaging datasets of galaxies after the developers found that existing PPLs (e.g., PyMC3, Pyro, STAN) were not suited to the model fitting problems many Astronomers faced. This includes:

  • Efficiently analysing large and homogenous datasets with an identical model fitting procedure, with tools for processing the large libraries of results output.

  • Problems where likelihood evaluations are expensive (e.g. run times of days per model-fit), necessitating highly customizable model-fitting pipelines with support for massively parallel computing.

  • Fitting many different models to the same dataset with tools that streamline model comparison.

If these challenges sound familiar, then PyAutoFit may be the right software for your model-fitting needs!

API Overview

To illustrate the PyAutoFit API, we’ll use an illustrative toy model of fitting a one-dimensional Gaussian to noisy 1D data. Here’s the data (black) and the model (red) we’ll fit:

https://raw.githubusercontent.com/rhayes777/PyAutoFit/master/files/toy_model_fit.png

We define our model, a 1D Gaussian by writing a Python class using the format below:

class Gaussian:

    def __init__(
        self,
        centre=0.0,        # <- PyAutoFit recognises these
        normalization=0.1, # <- constructor arguments are
        sigma=0.01,        # <- the Gaussian's parameters.
    ):
        self.centre = centre
        self.normalization = normalization
        self.sigma = sigma

    """
    An instance of the Gaussian class will be available during model fitting.

    This method will be used to fit the model to data and compute a likelihood.
    """

    def model_data_1d_via_xvalues_from(self, xvalues):

        transformed_xvalues = xvalues - self.centre

        return (self.normalization / (self.sigma * (2.0 * np.pi) ** 0.5)) * \
                np.exp(-0.5 * (transformed_xvalues / self.sigma) ** 2.0)

PyAutoFit recognises that this Gaussian may be treated as a model component whose parameters can be fitted for via a non-linear search like emcee.

To fit this Gaussian to the data we create an Analysis object, which gives PyAutoFit the data and a log_likelihood_function describing how to fit the data with the model:

class Analysis(af.Analysis):

    def __init__(self, data, noise_map):

        self.data = data
        self.noise_map = noise_map

    def log_likelihood_function(self, instance):

        """
        The 'instance' that comes into this method is an instance of the Gaussian class
        above, with the parameters set to values chosen by the non-linear search.
        """

        print("Gaussian Instance:")
        print("Centre = ", instance.centre)
        print("normalization = ", instance.normalization)
        print("Sigma = ", instance.sigma)

        """
        We fit the ``data`` with the Gaussian instance, using its
        "model_data_1d_via_xvalues_from" function to create the model data.
        """

        xvalues = np.arange(self.data.shape[0])

        model_data = instance.model_data_1d_via_xvalues_from(xvalues=xvalues)
        residual_map = self.data - model_data
        chi_squared_map = (residual_map / self.noise_map) ** 2.0
        log_likelihood = -0.5 * sum(chi_squared_map)

        return log_likelihood

We can now fit our model to the data using a non-linear search:

model = af.Model(Gaussian)

analysis = Analysis(data=data, noise_map=noise_map)

emcee = af.Emcee(nwalkers=50, nsteps=2000)

result = emcee.fit(model=model, analysis=analysis)

The result contains information on the model-fit, for example the parameter samples, maximum log likelihood model and marginalized probability density functions.

Support

Support for installation issues, help with Fit modeling and using PyAutoFit is available by raising an issue on the GitHub issues page.

We also offer support on the PyAutoFit Slack channel, where we also provide the latest updates on PyAutoFit. Slack is invitation-only, so if you’d like to join send an email requesting an invite.

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