bayesflow.benchmarks package

Submodules

bayesflow.benchmarks.bernoulli_glm module

bayesflow.benchmarks.bernoulli_glm.configurator(forward_dict, mode='posterior')[source]

Configures simulator outputs for use in BayesFlow training.

bayesflow.benchmarks.bernoulli_glm.prior(rng=None)[source]

Generates a random draw from the custom prior over the 10 Bernoulli GLM parameters (1 intercept and 9 weights). Uses a global covariance matrix Cov for the multivariate Gaussian prior over the model weights, which is pre-computed for efficiency.

Parameters

rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

theta – A single draw from the prior.

Return type

np.ndarray of shape (10,)

bayesflow.benchmarks.bernoulli_glm.simulator(theta, T=100, scale_by_T=True, rng=None)[source]

Simulates data from the custom Bernoulli GLM likelihood, see https://arxiv.org/pdf/2101.04653.pdf, Task T.5

Important: scale_sum should be set to False if the simulator is used with variable T during training, otherwise the information of T will be lost.

Parameters

  • theta (np.ndarray of shape (10,)) – The vector of model parameters (theta[0] is intercept, theta[i], i > 0 are weights).

  • T (int, optional, default: 100) – The simulated duration of the task (eq. the number of Bernoulli draws).

  • scale_by_T (bool, optional, default: True) – A flag indicating whether to scale the summayr statistics by T.

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

x – The vector of sufficient summary statistics of the data.

Return type

np.ndarray of shape (10,)

bayesflow.benchmarks.bernoulli_glm_raw module

bayesflow.benchmarks.bernoulli_glm_raw.configurator(forward_dict, mode='posterior', as_summary_condition=False)[source]

Configures simulator outputs for use in BayesFlow training.

bayesflow.benchmarks.bernoulli_glm_raw.prior(rng=None)[source]

Generates a random draw from the custom prior over the 10 Bernoulli GLM parameters (1 intercept and 9 weights). Uses a global covariance matrix Cov for the multivariate Gaussian prior over the model weights, which is pre-computed for efficiency.

Parameters

rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

theta – A single draw from the prior.

Return type

np.ndarray of shape (10,)

bayesflow.benchmarks.bernoulli_glm_raw.simulator(theta, T=100, rng=None)[source]

Simulates data from the custom Bernoulli GLM likelihood, see: https://arxiv.org/pdf/2101.04653.pdf, Task T.6

Returns the raw Bernoulli data.

Parameters

  • theta (np.ndarray of shape (10,)) – The vector of model parameters (theta[0] is intercept, theta[i], i > 0 are weights)

  • T (int, optional, default: 100) – The simulated duration of the task (eq. the number of Bernoulli draws).

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

x – The full simulated set of Bernoulli draws. Should be configured with an additional trailing dimension if the data is (properly) to be treated as a set.

Return type

np.ndarray of shape (T,)

bayesflow.benchmarks.gaussian_linear module

bayesflow.benchmarks.gaussian_linear.configurator(forward_dict, mode='posterior')[source]

Configures simulator outputs for use in BayesFlow training.

bayesflow.benchmarks.gaussian_linear.prior(D=10, scale=0.1, rng=None)[source]

Generates a random draw from a D-dimensional Gaussian prior distribution with a spherical convariance matrix given by sigma * I_D. Represents the location vector of a (conjugate) Gaussian likelihood.

Parameters

  • D (int, optional, default : 10) – The dimensionality of the Gaussian prior distribution.

  • scale (float, optional, default : 0.1) – The scale of the Gaussian prior.

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

theta – A single draw from the D-dimensional Gaussian prior.

Return type

np.ndarray of shape (D, )

bayesflow.benchmarks.gaussian_linear.simulator(theta, n_obs=None, scale=0.1, rng=None)[source]

Generates batched draws from a D-dimenional Gaussian distributions given a batch of location (mean) parameters of D dimensions. Assumes a spherical convariance matrix given by scale * I_D.

Parameters

  • theta (np.ndarray of shape (theta, D)) – The location parameters of the Gaussian likelihood.

  • n_obs (int or None, optional, default: None) – The number of observations to draw from the likelihood given the location parameter theta. If n obs is None, a single draw is produced.

  • scale (float, optional, default : 0.1) – The scale of the Gaussian likelihood.

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

x – else np.ndarray of shape (theta.shape[0], n_obs, theta.shape[1]) A single draw or a sample from a batch of Gaussians.

Return type

np.ndarray of shape (theta.shape[0], theta.shape[1]) if n_obs is None,

bayesflow.benchmarks.gaussian_linear_uniform module

bayesflow.benchmarks.gaussian_linear_uniform.configurator(forward_dict, mode='posterior')[source]

Configures simulator outputs for use in BayesFlow training.

bayesflow.benchmarks.gaussian_linear_uniform.prior(D=10, lower_bound=- 1.0, upper_bound=1.0, rng=None)[source]

Generates a random draw from a D-dimensional uniform prior bounded between lower_bound and upper_bound which represents the location vector of a (conjugate) Gaussian likelihood.

Parameters

  • D (int, optional, default : 10) – The dimensionality of the Gaussian prior.

  • lower_bound (float, optional, default : -1.) – The lower bound of the uniform prior.

  • upper_bound (float, optional, default : 1.) – The upper bound of the uniform prior.

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

theta – A single draw from the D-dimensional uniform prior.

Return type

np.ndarray of shape (D, )

bayesflow.benchmarks.gaussian_linear_uniform.simulator(theta, n_obs=None, scale=0.1, rng=None)[source]

Generates batched draws from a D-dimenional Gaussian distributions given a batch of location (mean) parameters of D dimensions. Assumes a spherical convariance matrix given by scale * I_D.

Parameters

  • theta (np.ndarray of shape (theta, D)) – The location parameters of the Gaussian likelihood.

  • n_obs (int or None, optional, default: None) – The number of observations to draw from the likelihood given the location parameter theta. If None, a single draw is produced.

  • scale (float, optional, default : 0.1) – The scale of the Gaussian likelihood.

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

x – else np.ndarray of shape (theta.shape[0], n_obs, theta.shape[1]) A single draw or a sample from a batch of Gaussians.

Return type

np.ndarray of shape (theta.shape[0], theta.shape[1]) if n_obs is None,

bayesflow.benchmarks.gaussian_mixture module

bayesflow.benchmarks.gaussian_mixture.configurator(forward_dict, mode='posterior', scale_data=12)[source]

Configures simulator outputs for use in BayesFlow training.

bayesflow.benchmarks.gaussian_mixture.prior(lower_bound=- 10.0, upper_bound=10.0, D=2, rng=None)[source]

Generates a random draw from a 2-dimensional uniform prior bounded between lower_bound and upper_bound representing the common mean of a 2D Gaussian mixture model (GMM).

Parameters

  • lower_bound (float, optional, default : -10) – The lower bound of the uniform prior.

  • upper_bound (float, optional, default : 10) – The upper bound of the uniform prior.

  • D (int, optional, default: 2) – The dimensionality of the mixtrue model

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

theta – A single draw from the D-dimensional uniform prior.

Return type

np.ndarray of shape (D, )

bayesflow.benchmarks.gaussian_mixture.simulator(theta, prob=0.5, scale_c1=1.0, scale_c2=0.01, rng=None)[source]

Simulates data from the Gaussian mixture model (GMM) with shared location vector. For more details, see

https://arxiv.org/pdf/2101.04653.pdf, Benchmark Task T.7

Parameters

  • theta (np.ndarray of shape (D,)) – The D-dimensional vector of parameter locations.

  • prob (float, optional, default: 0.5) – The mixture probability (coefficient).

  • scale_c1 (float, optional, default: 1.) – The scale of the first component.

  • scale_c2 (float, optional, default: 0.01) – The scale of the second component.

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

x – The 2D vector generated from the GMM simulator.

Return type

np.ndarray of shape (2,)

bayesflow.benchmarks.lotka_volterra module

bayesflow.benchmarks.lotka_volterra.configurator(forward_dict, mode='posterior', scale_data=1000, as_summary_condition=False)[source]

Configures simulator outputs for use in BayesFlow training.

bayesflow.benchmarks.lotka_volterra.prior(rng=None)[source]

Generates a random draw from a 4-dimensional (independent) lognormal prior which represents the four contact parameters of the Lotka-Volterra model.

Parameters

rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

theta – A single draw from the 4-dimensional prior.

Return type

np.ndarray of shape (4,)

bayesflow.benchmarks.lotka_volterra.simulator(theta, X0=30, Y0=1, T=20, subsample=10, flatten=True, rng=None)[source]

Runs a Lotka-Volterra simulation for T time steps and returns subsample evenly spaced points from the simulated trajectory, given contact parameters theta.

See https://arxiv.org/pdf/2101.04653.pdf, Benchmark Task T.10.

Parameters

  • theta (np.ndarray of shape (2,)) – The 2-dimensional vector of disease parameters.

  • X0 (float, optional, default: 30) – Initial number of prey species.

  • Y0 (float, optional, default: 1) – Initial number of predator species.

  • T (T, optional, default: 20) – The duration (time horizon) of the simulation.

  • subsample (int or None, optional, default: 10) – The number of evenly spaced time points to return. If None, no subsampling will be performed and all T timepoints will be returned.

  • flatten (bool, optional, default: True) – A flag to indicate whather a 1D (flatten=True) or a 2D (flatten=False) representation of the simulated data is returned.

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

x – otherwise shape (T, 2) or (T*2,) if subsample is None. The time series of simulated predator and pray populations

Return type

np.ndarray of shape (subsample, 2) or (subsample*2,) if subsample is not None,

bayesflow.benchmarks.sir module

bayesflow.benchmarks.sir.configurator(forward_dict, mode='posterior', as_summary_condition=False)[source]

Configures simulator outputs for use in BayesFlow training.

bayesflow.benchmarks.sir.prior(rng=None)[source]

Generates a random draw from a 2-dimensional (independent) lognormal prior which represents the contact and recovery rate parameters of a basic SIR model.

Parameters

rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

theta – A single draw from the 2-dimensional prior.

Return type

np.ndarray of shape (2,)

bayesflow.benchmarks.sir.simulator(theta, N=1000000.0, T=160, I0=1.0, R0=0.0, subsample=10, total_count=1000, rng=None)[source]

Runs a basic SIR model simulation for T time steps and returns subsample evenly spaced points from the simulated trajectory, given disease parameters (contact and recovery rate) theta.

See https://arxiv.org/pdf/2101.04653.pdf, Benchmark Task T.9.

Note, that the simulator will scale the outputs between 0 and 1.

Parameters

  • theta (np.ndarray of shape (2,)) – The 2-dimensional vector of disease parameters.

  • N (float, optional, default: 1e6 = 1 000 000) – The size of the simulated population.

  • T (T, optional, default: 160) – The duration (time horizon) of the simulation.

  • I0 (float, optional, default: 1.) – The number of initially infected individuals.

  • R0 (float, optional, default: 0.) – The number of initially recovered individuals.

  • subsample (int or None, optional, default: 10) – The number of evenly spaced time points to return. If None, no subsampling will be performed and all T timepoints will be returned.

  • total_count (int, optional, default: 1000) – The N parameter of the binomial noise distribution. Used just for scaling the data and magnifying the effect of noise, such that max infected = total_count.

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

x – The time series of simulated infected individuals. A trailing dimension of 1 should be added by a BayesFlow configurator if the data is (properly) to be treated as time series.

Return type

np.ndarray of shape (subsample,) or (T,) if subsample=None

bayesflow.benchmarks.slcp module

bayesflow.benchmarks.slcp.configurator(forward_dict, mode='posterior', scale_data=30.0, as_summary_condition=False)[source]

Configures simulator outputs for use in BayesFlow training.

bayesflow.benchmarks.slcp.prior(lower_bound=- 3.0, upper_bound=3.0, rng=None)[source]

Generates a random draw from a 5-dimensional uniform prior bounded between lower_bound and upper_bound which represents the 5 parameters of the SLCP simulator.

Parameters

  • lower_bound (float, optional, default : -3) – The lower bound of the uniform prior.

  • upper_bound (float, optional, default : 3) – The upper bound of the uniform prior.

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

theta – A single draw from the 5-dimensional uniform prior.

Return type

np.ndarray of shape (5, )

bayesflow.benchmarks.slcp.simulator(theta, n_obs=4, flatten=True, rng=None)[source]

Generates data from the SLCP model designed as a benchmark for a simple likelihood and a complex posterior due to a non-linear pushforward theta -> x.

See https://arxiv.org/pdf/2101.04653.pdf, Benchmark Task T.3

Parameters

  • theta (np.ndarray of shape (theta, D)) – The location parameters of the Gaussian likelihood.

  • n_obs (int, optional, default: 4) – The number of observations to generate from the slcp likelihood.

  • flatten (bool, optional, default: True) – A flag to indicate whather a 1D (flatten=True) or a 2D (flatten=False) representation of the simulated data is returned.

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

x – boolean flag. The sample of simulated data from the SLCP model.

Return type

np.ndarray of shape (n_obs*2, ) or (n_obs, 2), as indictated by the flatten

bayesflow.benchmarks.slcp_distractors module

bayesflow.benchmarks.slcp_distractors.configurator(forward_dict, mode='posterior', scale_data=50.0, as_summary_condition=False)[source]

Configures simulator outputs for use in BayesFlow training.

bayesflow.benchmarks.slcp_distractors.draw_mixture_student_t(num_students, n_draws=46, dim=2, mu_scale=15.0, rng=None)[source]

Helper function to generate n_draws random draws from a mixture of num_students multivariate Student-t distributions.

Uses the function get_random_student_t to create each of the studen-t callable objects.

Parameters

  • num_students (int) – The number of multivariate student-t mixture components

  • n_draws (int, optional, default: 46) – The number of draws to obtain from the mixture distribution.

  • dim (int, optional, default: 2) – The dimensionality of each student-t distribution in the mixture.

  • mu_scale (float, optional, default: 15) – The scale of the zero-centered Gaussian prior from which the mean vector of each student-t distribution in the mixture is drawn.

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

sample – The random draws from the mixture of students.

Return type

np.ndarray of shape (n_draws, dim)

bayesflow.benchmarks.slcp_distractors.get_random_student_t(dim=2, mu_scale=15, shape_scale=0.01, rng=None)[source]

A helper function to create a “frozen” multivariate student-t distribution of dimensions dim.

Parameters

  • dim (int, optional, default: 2) – The dimensionality of the student-t distribution.

  • mu_scale (float, optional, default: 15) – The scale of the zero-centered Gaussian prior from which the mean vector of the student-t distribution is drawn.

  • shape_scale (float, optional, default: 0.01) – The scale of the assumed np.eye(dim) shape matrix. The default is chosen to keep the scale of the distractors and observations relatively similar.

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

student – The student-t generator.

Return type

callable (scipy.stats._multivariate.multivariate_t_frozen)

bayesflow.benchmarks.slcp_distractors.prior(lower_bound=- 3.0, upper_bound=3.0, rng=None)[source]

Generates a random draw from a 5-dimensional uniform prior bounded between lower_bound and upper_bound.

Parameters

  • lower_bound (float, optional, default : -3) – The lower bound of the uniform prior.

  • upper_bound (float, optional, default : 3) – The upper bound of the uniform prior.

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

theta – A single draw from the 5-dimensional uniform prior.

Return type

np.ndarray of shape (5, )

bayesflow.benchmarks.slcp_distractors.simulator(theta, n_obs=4, n_dist=46, dim=2, mu_scale=15.0, flatten=True, rng=None)[source]

Generates data from the SLCP model designed as a benchmark for a simple likelihood and a complex posterior due to a non-linear pushforward theta -> x. In addition, it outputs uninformative distractor data.

See https://arxiv.org/pdf/2101.04653.pdf, Benchmark Task T.4

Parameters

  • theta (np.ndarray of shape (theta, D)) – The location parameters of the Gaussian likelihood.

  • n_obs (int, optional, default: 4) – The number of observations to generate from the slcp likelihood.

  • n_dist (int, optional, default: 46) – The number of distractor to draw from the distractor likelihood.

  • dim (int, optional, default: 2) – The dimensionality of each student-t distribution in the mixture.

  • mu_scale (float, optional, default: 15) – The scale of the zero-centered Gaussian prior from which the mean vector of each student-t distribution in the mixture is drawn.

  • flatten (bool, optional, default: True) – A flag to indicate whather a 1D (flatten=True) or a 2D (flatten=False) representation of the simulated data is returned.

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

x – np.ndarray of shape (n_obs + n_dist, 2) if flatten=False

Return type

np.ndarray of shape (n_obs*2 + n_dist*2,) if flatten=True, otherwise

bayesflow.benchmarks.two_moons module

bayesflow.benchmarks.two_moons.configurator(forward_dict, mode='posterior')[source]

Configures simulator outputs for use in BayesFlow training.

bayesflow.benchmarks.two_moons.prior(lower_bound=- 1.0, upper_bound=1.0, rng=None)[source]

Generates a random draw from a 2-dimensional uniform prior bounded between lower_bound and upper_bound which represents the two parameters of the two moons simulator.

Parameters

  • lower_bound (float, optional, default : -1) – The lower bound of the uniform prior.

  • upper_bound (float, optional, default : 1) – The upper bound of the uniform prior.

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

theta – A single draw from the 2-dimensional uniform prior.

Return type

np.ndarray of shape (2,)

bayesflow.benchmarks.two_moons.simulator(theta, rng=None)[source]

Implements data generation from the two-moons model with a bimodal posterior. See https://arxiv.org/pdf/2101.04653.pdf, Benchmark Task T.8

Parameters

  • theta (np.ndarray of shape (2,)) – The vector of two model parameters.

  • rng (np.random.Generator or None, default: None) – An optional random number generator to use.

Returns

x – The 2D vector generated from the two moons simulator.

Return type

np.ndarray of shape (2,)

Module contents

class bayesflow.benchmarks.Benchmark(name, mode='joint', seed=None, **kwargs)[source]

Bases: object

Interface class for a benchmark.

bayesflow.benchmarks.get_benchmark_module(benchmark_name)[source]

Loads the corresponding benchmark file under bayesflow.benchmarks.<benchmark_name> as a module and returns it.