tfp.sts.SemiLocalLinearTrendStateSpaceModel

State space model for a semi-local linear trend.

Inherits From: LinearGaussianStateSpaceModel, AutoCompositeTensorDistribution, Distribution, AutoCompositeTensor

tfp.sts.SemiLocalLinearTrendStateSpaceModel(
    num_timesteps,
    level_scale,
    slope_mean,
    slope_scale,
    autoregressive_coef,
    initial_state_prior,
    observation_noise_scale=0.0,
    name=None,
    **linear_gaussian_ssm_kwargs
)

A state space model (SSM) posits a set of latent (unobserved) variables that evolve over time with dynamics specified by a probabilistic transition model p(z[t+1] | z[t]). At each timestep, we observe a value sampled from an observation model conditioned on the current state, p(x[t] | z[t]). The special case where both the transition and observation models are Gaussians with mean specified as a linear function of the inputs, is known as a linear Gaussian state space model and supports tractable exact probabilistic calculations; see tfp.distributions.LinearGaussianStateSpaceModel for details.

The semi-local linear trend model is a special case of a linear Gaussian SSM, in which the latent state posits a level and slope. The level evolves via a Gaussian random walk centered at the current slope, while the slope follows a first-order autoregressive (AR1) process with mean slope_mean:

level[t] = level[t-1] + slope[t-1] + Normal(0., level_scale)
slope[t] = (slope_mean +
            autoregressive_coef * (slope[t-1] - slope_mean) +
            Normal(0., slope_scale))

The latent state is the two-dimensional tuple [level, slope]. The level is observed at each timestep.

The parameters level_scale, slope_mean, slope_scale, autoregressive_coef, and observation_noise_scale are each (a batch of) scalars. The batch shape of this Distribution is the broadcast batch shape of these parameters and of the initial_state_prior.

Mathematical Details

The semi-local linear trend model implements a tfp.distributions.LinearGaussianStateSpaceModel with latent_size = 2 and observation_size = 1, following the transition model:

transition_matrix = [[1., 1.]
                     [0., autoregressive_coef]]
transition_noise ~ N(loc=slope_mean - autoregressive_coef * slope_mean,
                     scale=diag([level_scale, slope_scale]))

which implements the evolution of [level, slope] described above, and the observation model:

observation_matrix = [[1., 0.]]
observation_noise ~ N(loc=0, scale=observation_noise_scale)

which picks out the first latent component, i.e., the level, as the observation at each timestep.

Examples

A simple model definition:

semilocal_trend_model = SemiLocalLinearTrendStateSpaceModel(
    num_timesteps=50,
    level_scale=0.5,
    slope_mean=0.2,
    slope_scale=0.5,
    autoregressive_coef=0.9,
    initial_state_prior=tfd.MultivariateNormalDiag(scale_diag=[1., 1.]))

y = semilocal_trend_model.sample() # y has shape [50, 1]
lp = semilocal_trend_model.log_prob(y) # log_prob is scalar

Passing additional parameter dimensions constructs a batch of models. The overall batch shape is the broadcast batch shape of the parameters:

semilocal_trend_model = SemiLocalLinearTrendStateSpaceModel(
    num_timesteps=50,
    level_scale=tf.ones([10]),
    slope_mean=0.2,
    slope_scale=0.5,
    autoregressive_coef=0.9,
    initial_state_prior=tfd.MultivariateNormalDiag(
      scale_diag=tf.ones([10, 10, 2])))

y = semilocal_trend_model.sample(5)    # y has shape [5, 10, 10, 50, 1]
lp = semilocal_trend_model.log_prob(y) # lp has shape [5, 10, 10]

num_timesteps Scalar int Tensor number of timesteps to model with this distribution.
level_scale Scalar (any additional dimensions are treated as batch dimensions) float Tensor indicating the standard deviation of the level transitions.
slope_mean Scalar (any additional dimensions are treated as batch dimensions) float Tensor indicating the expected long-term mean of the latent slope.
slope_scale Scalar (any additional dimensions are treated as batch dimensions) float Tensor indicating the standard deviation of the slope transitions.
autoregressive_coef Scalar (any additional dimensions are treated as batch dimensions) float Tensor defining the AR1 process on the latent slope.
initial_state_prior instance of tfd.MultivariateNormal representing the prior distribution on latent states; must have event shape [2].
observation_noise_scale Scalar (any additional dimensions are treated as batch dimensions) float Tensor indicating the standard deviation of the observation noise.
name Python str name prefixed to ops created by this class. Default value: "SemiLocalLinearTrendStateSpaceModel".
**linear_gaussian_ssm_kwargs Optional additional keyword arguments to to the base tfd.LinearGaussianStateSpaceModel constructor.

allow_nan_stats Python bool describing behavior when a stat is undefined.

Stats return +/- infinity when it makes sense. E.g., the variance of a Cauchy distribution is infinity. However, sometimes the statistic is undefined, e.g., if a distribution's pdf does not achieve a maximum within the support of the distribution, the mode is undefined. If the mean is undefined, then by definition the variance is undefined. E.g. the mean for Student's T for df = 1 is undefined (no clear way to say it is either + or - infinity), so the variance = E[(X - mean)**2] is also undefined.

autoregressive_coef

batch_shape Shape of a single sample from a single event index as a TensorShape.

May be partially defined or unknown.

The batch dimensions are indexes into independent, non-identical parameterizations of this distribution.

dtype The DType of Tensors handled by this Distribution.
event_shape Shape of a single sample from a single batch as a TensorShape.

May be partially defined or unknown.

experimental_parallelize

experimental_shard_axis_names The list or structure of lists of active shard axis names.
initial_state_prior

initial_step

level_scale

mask

name Name prepended to all ops created by this Distribution.
name_scope Returns a tf.name_scope instance for this class.
non_trainable_variables Sequence of non-trainable variables owned by this module and its submodules.
num_timesteps

observation_matrix

observation_noise

observation_noise_scale

parameters Dictionary of parameters used to instantiate this Distribution.
reparameterization_type Describes how samples from the distribution are reparameterized.

Currently this is one of the static instances tfd.FULLY_REPARAMETERIZED or tfd.NOT_REPARAMETERIZED.

slope_mean

slope_scale

submodules Sequence of all sub-modules.

Submodules are modules which are properties of this module, or found as properties of modules which are properties of this module (and so on).

a = tf.Module()
b = tf.Module()
c = tf.Module()
a.b = b
b.c = c
list(a.submodules) == [b, c]
True
list(b.submodules) == [c]
True
list(c.submodules) == []
True

trainable_variables Sequence of trainable variables owned by this module and its submodules.
transition_matrix

transition_noise

validate_args Python bool indicating possibly expensive checks are enabled.
variables Sequence of variables owned by this module and its submodules.

Methods

backward_smoothing_pass

View source

backward_smoothing_pass(
    filtered_means, filtered_covs, predicted_means, predicted_covs
)

Run the backward pass in Kalman smoother.

The backward smoothing is using Rauch, Tung and Striebel smoother as as discussed in section 18.3.2 of Kevin P. Murphy, 2012, Machine Learning: A Probabilistic Perspective, The MIT Press. The inputs are returned by forward_filter function.

Args
filtered_means Means of the per-timestep filtered marginal distributions p(z[t] | x[:t]), as a Tensor of shape sample_shape(x) + batch_shape + [num_timesteps, latent_size].
filtered_covs Covariances of the per-timestep filtered marginal distributions p(z[t] | x[:t]), as a Tensor of shape sample_shape(x) + batch_shape + [num_timesteps, latent_size, latent_size].
predicted_means Means of the per-timestep predictive distributions over latent states, p(z[t+1] | x[:t]), as a Tensor of shape sample_shape(x) + batch_shape + [num_timesteps, latent_size].
predicted_covs Covariances of the per-timestep predictive distributions over latent states, p(z[t+1] | x[:t]), as a Tensor of shape sample_shape(x) + batch_shape + [num_timesteps, latent_size, latent_size].

Returns
posterior_means Means of the smoothed marginal distributions p(z[t] | x[1:T]), as a Tensor of shape sample_shape(x) + batch_shape + [num_timesteps, latent_size], which is of the same shape as filtered_means.
posterior_covs Covariances of the smoothed marginal distributions p(z[t] | x[1:T]), as a Tensor of shape sample_shape(x) + batch_shape + [num_timesteps, latent_size, latent_size]. which is of the same shape as filtered_covs.

batch_shape_tensor

View source

batch_shape_tensor(
    name='batch_shape_tensor'
)

Shape of a single sample from a single event index as a 1-D Tensor.

The batch dimensions are indexes into independent, non-identical parameterizations of this distribution.

Args
name name to give to the op

Returns
batch_shape Tensor.

cdf

View source

cdf(
    value, name='cdf', **kwargs
)

Cumulative distribution function.

Given random variable X, the cumulative distribution function cdf is:

cdf(x) := P[X <= x]

Args
value float or double Tensor.
name Python str prepended to names of ops created by this function.
**kwargs Named arguments forwarded to subclass implementation.

Returns
cdf a Tensor of shape sample_shape(x) + self.batch_shape with values of type self.dtype.

copy

View source

copy(
    **override_parameters_kwargs
)

Creates a deep copy of the distribution.

Args
**override_parameters_kwargs String/value dictionary of initialization arguments to override with new values.

Returns
distribution A new instance of type(self) initialized from the union of self.parameters and override_parameters_kwargs, i.e., dict(self.parameters, **override_parameters_kwargs).

covariance

View source

covariance(
    name='covariance', **kwargs
)

Covariance.

Covariance is (possibly) defined only for non-scalar-event distributions.

For example, for a length-k, vector-valued distribution, it is calculated as,

Cov[i, j] = Covariance(X_i, X_j) = E[(X_i - E[X_i]) (X_j - E[X_j])]

where Cov is a (batch of) k x k matrix, 0 <= (i, j) < k, and E denotes expectation.

Alternatively, for non-vector, multivariate distributions (e.g., matrix-valued, Wishart), Covariance shall return a (batch of) matrices under some vectorization of the events, i.e.,

Cov[i, j] = Covariance(Vec(X)_i, Vec(X)_j) = [as above]

where Cov is a (batch of) k' x k' matrices, 0 <= (i, j) < k' = reduce_prod(event_shape), and Vec is some function mapping indices of this distribution's event dimensions to indices of a length-k' vector.

Args
name Python str prepended to names of ops created by this function.
**kwargs Named arguments forwarded to subclass implementation.

Returns
covariance Floating-point Tensor with shape [B1, ..., Bn, k', k'] where the first n dimensions are batch coordinates and k' = reduce_prod(self.event_shape).

cross_entropy

View source

cross_entropy(
    other, name='cross_entropy'
)

Computes the (Shannon) cross entropy.

Denote this distribution (self) by P and the other distribution by Q. Assuming P, Q are absolutely continuous with respect to one another and permit densities p(x) dr(x) and q(x) dr(x), (Shannon) cross entropy is defined as:

H[P, Q] = E_p[-log q(X)] = -int_F p(x) log q(x) dr(x)

where F denotes the support of the random variable X ~ P.

Args
other tfp.distributions.Distribution instance.
name Python str prepended to names of ops created by this function.

Returns
cross_entropy self.dtype Tensor with shape [B1, ..., Bn] representing n different calculations of (Shannon) cross entropy.

entropy

View source

entropy(
    name='entropy', **kwargs
)

Shannon entropy in nats.

event_shape_tensor

View source

event_shape_tensor(
    name='event_shape_tensor'
)

Shape of a single sample from a single batch as a 1-D int32 Tensor.

Args
name name to give to the op

Returns
event_shape Tensor.

experimental_default_event_space_bijector

View source

experimental_default_event_space_bijector(
    *args, **kwargs
)

Bijector mapping the reals (R**n) to the event space of the distribution.

Distributions with continuous support may implement _default_event_space_bijector which returns a subclass of tfp.bijectors.Bijector that maps R**n to the distribution's event space. For example, the default bijector for the Beta distribution is tfp.bijectors.Sigmoid(), which maps the real line to [0, 1], the support of the Beta distribution. The default bijector for the CholeskyLKJ distribution is tfp.bijectors.CorrelationCholesky, which maps R^(k * (k-1) // 2) to the submanifold of k x k lower triangular matrices with ones along the diagonal.

The purpose of experimental_default_event_space_bijector is to enable gradient descent in an unconstrained space for Variational Inference and Hamiltonian Monte Carlo methods. Some effort has been made to choose bijectors such that the tails of the distribution in the unconstrained space are between Gaussian and Exponential.

For distributions with discrete event space, or for which TFP currently lacks a suitable bijector, this function returns None.

Args
*args Passed to implementation _default_event_space_bijector.
**kwargs Passed to implementation _default_event_space_bijector.

Returns
event_space_bijector Bijector instance or None.

experimental_fit

View source

@classmethod
experimental_fit(
    value, sample_ndims=1, validate_args=False, **init_kwargs
)

Instantiates a distribution that maximizes the likelihood of x.

Args
value a Tensor valid sample from this distribution family.
sample_ndims Positive int Tensor number of leftmost dimensions of value that index i.i.d. samples. Default value: 1.
validate_args Python bool, default False. When True, distribution parameters are checked for validity despite possibly degrading runtime performance. When False, invalid inputs may silently render incorrect outputs. Default value: False.
**init_kwargs Additional keyword arguments passed through to cls.__init__. These take precedence in case of collision with the fitted parameters; for example, tfd.Normal.experimental_fit([1., 1.], scale=20.) returns a Normal distribution with scale=20. rather than the maximum likelihood parameter scale=0..

Returns
maximum_likelihood_instance instance of cls with parameters that maximize the likelihood of value.

experimental_local_measure

View source

experimental_local_measure(
    value, backward_compat=False, **kwargs
)

Returns a log probability density together with a TangentSpace.

A TangentSpace allows us to calculate the correct push-forward density when we apply a transformation to a Distribution on a strict submanifold of R^n (typically via a Bijector in the TransformedDistribution subclass). The density correction uses the basis of the tangent space.

Args
value float or double Tensor.
backward_compat bool specifying whether to fall back to returning FullSpace as the tangent space, and representing R^n with the standard basis.
**kwargs Named arguments forwarded to subclass implementation.

Returns
log_prob a Tensor representing the log probability density, of shape sample_shape(x) + self.batch_shape with values of type self.dtype.
tangent_space a TangentSpace object (by default FullSpace) representing the tangent space to the manifold at value.

Raises
UnspecifiedTangentSpaceError if backward_compat is False and the _experimental_tangent_space attribute has not been defined.

experimental_sample_and_log_prob

View source

experimental_sample_and_log_prob(
    sample_shape=(), seed=None, name='sample_and_log_prob', **kwargs
)

Samples from this distribution and returns the log density of the sample.

The default implementation simply calls sample and log_prob:

def _sample_and_log_prob(self, sample_shape, seed, **kwargs):
  x = self.sample(sample_shape=sample_shape, seed=seed, **kwargs)
  return x, self.log_prob(x, **kwargs)

However, some subclasses may provide more efficient and/or numerically stable implementations.

Args
sample_shape integer Tensor desired shape of samples to draw. Default value: ().
seed PRNG seed; see tfp.random.sanitize_seed for details. Default value: None.
name name to give to the op. Default value: 'sample_and_log_prob'.
**kwargs Named arguments forwarded to subclass implementation.

Returns
samples a Tensor, or structure of Tensors, with prepended dimensions sample_shape.
log_prob a Tensor of shape sample_shape(x) + self.batch_shape with values of type self.dtype.

forward_filter

View source

forward_filter(
    x, mask=None, final_step_only=False
)

Run a Kalman filter over a provided sequence of outputs.

Note that the returned values filtered_means, predicted_means, and observation_means depend on the observed time series x, while the corresponding covariances are independent of the observed series; i.e., they depend only on the model itself. This means that the mean values have shape concat([sample_shape(x), batch_shape, [num_timesteps, {latent/observation}_size]]), while the covariances have shape concat[(batch_shape, [num_timesteps, {latent/observation}_size, {latent/observation}_size]]), which does not depend on the sample shape.

Args
x a float-type Tensor with rightmost dimensions [num_timesteps, observation_size] matching self.event_shape. Additional dimensions must match or be broadcastable to self.batch_shape; any further dimensions are interpreted as a sample shape.
mask optional bool-type Tensor with rightmost dimension [num_timesteps]; True values specify that the value of x at that timestep is masked, i.e., not conditioned on. Additional dimensions must match or be broadcastable to self.batch_shape; any further dimensions must match or be broadcastable to the sample shape of x. Default value: None (falls back to self.mask).
final_step_only optional Python bool. If True, the num_timesteps dimension is omitted from all return values and only the value from the final timestep is returned (in this case, log_likelihoods will be the cumulative log marginal likelihood). This may be significantly more efficient than returning all values (although note that no efficiency gain is expected when self.experimental_parallelize=True). Default value: False.

Returns
log_likelihoods Per-timestep log marginal likelihoods log p(x[t] | x[:t-1]) evaluated at the input x, as a Tensor of shape sample_shape(x) + batch_shape + [num_timesteps]. If final_step_only is True, this will instead be the cumulative log marginal likelihood at the final step.
filtered_means Means of the per-timestep filtered marginal distributions p(z[t] | x[:t]), as a Tensor of shape sample_shape(x) + batch_shape + [num_timesteps, latent_size].
filtered_covs Covariances of the per-timestep filtered marginal distributions p(z[t] | x[:t]), as a Tensor of shape sample_shape(x) + batch_shape + [num_timesteps, latent_size, latent_size]. Since posterior covariances do not depend on observed data, some implementations may return a Tensor whose shape omits the initial sample_shape(x).
predicted_means Means of the per-timestep predictive distributions over latent states, p(z[t+1] | x[:t]), as a Tensor of shape sample_shape(x) + batch_shape + [num_timesteps, latent_size].
predicted_covs Covariances of the per-timestep predictive distributions over latent states, p(z[t+1] | x[:t]), as a Tensor of shape sample_shape(x) + batch_shape + [num_timesteps, latent_size, latent_size]. Since posterior covariances do not depend on observed data, some implementations may return a Tensor whose shape omits the initial sample_shape(x).
observation_means Means of the per-timestep predictive distributions over observations, p(x[t] | x[:t-1]), as a Tensor of shape sample_shape(x) + batch_shape + [num_timesteps, observation_size].
observation_covs Covariances of the per-timestep predictive distributions over observations, p(x[t] | x[:t-1]), as a Tensor of shape sample_shape(x) + batch_shape + [num_timesteps, observation_size, observation_size]. Since posterior covariances do not depend on observed data, some implementations may return a Tensor whose shape omits the initial sample_shape(x).

is_scalar_batch

View source

is_scalar_batch(
    name='is_scalar_batch'
)

Indicates that batch_shape == [].

Args
name Python str prepended to names of ops created by this function.

Returns
is_scalar_batch bool scalar Tensor.

is_scalar_event

View source

is_scalar_event(
    name='is_scalar_event'
)

Indicates that event_shape == [].

Args
name Python str prepended to names of ops created by this function.

Returns
is_scalar_event bool scalar Tensor.

kl_divergence

View source

kl_divergence(
    other, name='kl_divergence'
)

Computes the Kullback--Leibler divergence.

Denote this distribution (self) by p and the other distribution by q. Assuming p, q are absolutely continuous with respect to reference measure r, the KL divergence is defined as:

KL[p, q] = E_p[log(p(X)/q(X))]
         = -int_F p(x) log q(x) dr(x) + int_F p(x) log p(x) dr(x)
         = H[p, q] - H[p]

where F denotes the support of the random variable X ~ p, H[., .] denotes (Shannon) cross entropy, and H[.] denotes (Shannon) entropy.

Args
other tfp.distributions.Distribution instance.
name Python str prepended to names of ops created by this function.

Returns
kl_divergence self.dtype Tensor with shape [B1, ..., Bn] representing n different calculations of the Kullback-Leibler divergence.

latent_size_tensor

View source

latent_size_tensor()

latents_to_observations

View source

latents_to_observations(
    latent_means, latent_covs
)

Push latent means and covariances forward through the observation model.

Args
latent_means float Tensor of shape [..., num_timesteps, latent_size]
latent_covs float Tensor of shape [..., num_timesteps, latent_size, latent_size].

Returns
observation_means float Tensor of shape [..., num_timesteps, observation_size]
observation_covs float Tensor of shape [..., num_timesteps, observation_size, observation_size]

log_cdf

View source

log_cdf(
    value, name='log_cdf', **kwargs
)

Log cumulative distribution function.

Given random variable X, the cumulative distribution function cdf is:

log_cdf(x) := Log[ P[X <= x] ]

Often, a numerical approximation can be used for log_cdf(x) that yields a more accurate answer than simply taking the logarithm of the cdf when x << -1.

Args
value float or double Tensor.
name Python str prepended to names of ops created by this function.
**kwargs Named arguments forwarded to subclass implementation.

Returns
logcdf a Tensor of shape sample_shape(x) + self.batch_shape with values of type self.dtype.

log_prob

View source

log_prob(
    value, name='log_prob', **kwargs
)

Log probability density/mass function.

Additional documentation from LinearGaussianStateSpaceModel:

kwargs:
  • mask: optional bool-type Tensor with rightmost dimension [num_timesteps]; True values specify that the value of x at that timestep is masked, i.e., not conditioned on. Additional dimensions must match or be broadcastable to self.batch_shape; any further dimensions must match or be broadcastable to the sample shape of x. Default value: None (falls back to self.mask).

Args
value float or double Tensor.
name Python str prepended to names of ops created by this function.
**kwargs Named arguments forwarded to subclass implementation.

Returns
log_prob a Tensor of shape sample_shape(x) + self.batch_shape with values of type self.dtype.

log_survival_function

View source

log_survival_function(
    value, name='log_survival_function', **kwargs
)

Log survival function.

Given random variable X, the survival function is defined:

log_survival_function(x) = Log[ P[X > x] ]
                         = Log[ 1 - P[X <= x] ]
                         = Log[ 1 - cdf(x) ]

Typically, different numerical approximations can be used for the log survival function, which are more accurate than 1 - cdf(x) when x >> 1.

Args
value float or double Tensor.
name Python str prepended to names of ops created by this function.
**kwargs Named arguments forwarded to subclass implementation.

Returns
Tensor of shape sample_shape(x) + self.batch_shape with values of type self.dtype.

mean

View source

mean(
    name='mean', **kwargs
)

Mean.

mode

View source

mode(
    name='mode', **kwargs
)

Mode.

observation_size_tensor

View source

observation_size_tensor()

param_shapes

View source

@classmethod
param_shapes(
    sample_shape, name='DistributionParamShapes'
)

Shapes of parameters given the desired shape of a call to sample(). (deprecated)

This is a class method that describes what key/value arguments are required to instantiate the given Distribution so that a particular shape is returned for that instance's call to sample().

Subclasses should override class method _param_shapes.

Args
sample_shape Tensor or python list/tuple. Desired shape of a call to sample().
name name to prepend ops with.

Returns
dict of parameter name to Tensor shapes.

param_static_shapes

View source

@classmethod
param_static_shapes(
    sample_shape
)

param_shapes with static (i.e. TensorShape) shapes. (deprecated)

This is a class method that describes what key/value arguments are required to instantiate the given Distribution so that a particular shape is returned for that instance's call to sample(). Assumes that the sample's shape is known statically.

Subclasses should override class method _param_shapes to return constant-valued tensors when constant values are fed.

Args
sample_shape TensorShape or python list/tuple. Desired shape of a call to sample().

Returns
dict of parameter name to TensorShape.

Raises
ValueError if sample_shape is a TensorShape and is not fully defined.

parameter_properties

View source

@classmethod
parameter_properties(
    dtype=tf.float32, num_classes=None
)

Returns a dict mapping constructor arg names to property annotations.

This dict should include an entry for each of the distribution's Tensor-valued constructor arguments.

Distribution subclasses are not required to implement _parameter_properties, so this method may raise NotImplementedError. Providing a _parameter_properties implementation enables several advanced features, including:

  • Distribution batch slicing (sliced_distribution = distribution[i:j]).
  • Automatic inference of _batch_shape and _batch_shape_tensor, which must otherwise be computed explicitly.
  • Automatic instantiation of the distribution within TFP's internal property tests.
  • Automatic construction of 'trainable' instances of the distribution using appropriate bijectors to avoid violating parameter constraints. This enables the distribution family to be used easily as a surrogate posterior in variational inference.

In the future, parameter property annotations may enable additional functionality; for example, returning Distribution instances from tf.vectorized_map.

Args
dtype Optional float dtype to assume for continuous-valued parameters. Some constraining bijectors require advance knowledge of the dtype because certain constants (e.g., tfb.Softplus.low) must be instantiated with the same dtype as the values to be transformed.
num_classes Optional int Tensor number of classes to assume when inferring the shape of parameters for categorical-like distributions. Otherwise ignored.

Returns
parameter_properties A str ->tfp.python.internal.parameter_properties.ParameterPropertiesdict mapping constructor argument names toParameterProperties` instances.

Raises
NotImplementedError if the distribution class does not implement _parameter_properties.

posterior_marginals

View source

posterior_marginals(
    x, mask=None
)

Run a Kalman smoother to return posterior mean and cov.

Note that the returned values smoothed_means depend on the observed time series x, while the smoothed_covs are independent of the observed series; i.e., they depend only on the model itself. This means that the mean values have shape concat([sample_shape(x), batch_shape, [num_timesteps, {latent/observation}_size]]), while the covariances have shape concat[(batch_shape, [num_timesteps, {latent/observation}_size, {latent/observation}_size]]), which does not depend on the sample shape.

This function only performs smoothing. If the user wants the intermediate values, which are returned by filtering pass forward_filter, one could get it by:

(log_likelihoods,
 filtered_means, filtered_covs,
 predicted_means, predicted_covs,
 observation_means, observation_covs) = model.forward_filter(x)
smoothed_means, smoothed_covs = model.backward_smoothing_pass(
    filtered_means, filtered_covs,
    predicted_means, predicted_covs)

where x is an observation sequence.

Args
x a float-type Tensor with rightmost dimensions [num_timesteps, observation_size] matching self.event_shape. Additional dimensions must match or be broadcastable to self.batch_shape; any further dimensions are interpreted as a sample shape.
mask optional bool-type Tensor with rightmost dimension [num_timesteps]; True values specify that the value of x at that timestep is masked, i.e., not conditioned on. Additional dimensions must match or be broadcastable to self.batch_shape; any further dimensions must match or be broadcastable to the sample shape of x. Default value: None (falls back to self.mask).

Returns
smoothed_means Means of the per-timestep smoothed distributions over latent states, p(z[t] | x[:T]), as a Tensor of shape sample_shape(x) + batch_shape + [num_timesteps, observation_size].
smoothed_covs Covariances of the per-timestep smoothed distributions over latent states, p(z[t] | x[:T]), as a Tensor of shape sample_shape(mask) + batch_shape + [num_timesteps, observation_size, observation_size]. Note that the covariances depend only on the model and the mask, not on the data, so this may have fewer dimensions than filtered_means.

posterior_sample

View source

posterior_sample(
    x, sample_shape=(), mask=None, seed=None, name=None
)

Draws samples from the posterior over latent trajectories.

This method uses Durbin-Koopman sampling [1], an efficient algorithm to sample from the posterior latents of a linear Gaussian state space model. The cost of drawing a sample is equal to the cost of drawing a prior sample (.sample(sample_shape)), plus the cost of Kalman smoothing ( .posterior_marginals(...) on both the observed time series and the prior sample. This method is significantly more efficient in graph mode, because it uses only the posterior means and can elide the unneeded calculation of marginal covariances.

[1] Durbin, J. and Koopman, S.J. A simple and efficient simulation smoother for state space time series analysis. Biometrika 89(3):603-615, 2002. https://www.jstor.org/stable/4140605

Args
x a float-type Tensor with rightmost dimensions [num_timesteps, observation_size] matching self.event_shape. Additional dimensions must match or be broadcastable with self.batch_shape.
sample_shape int Tensor shape of samples to draw. Default value: ().
mask optional bool-type Tensor with rightmost dimension [num_timesteps]; True values specify that the value of x at that timestep is masked, i.e., not conditioned on. Additional dimensions must match or be broadcastable with self.batch_shape and x.shape[:-2]. Default value: None (falls back to self.mask).
seed PRNG seed; see tfp.random.sanitize_seed for details.
name Python str name for ops generated by this method.

Returns
latent_posterior_sample Float Tensor of shape concat([sample_shape, batch_shape, [num_timesteps, latent_size]]), where batch_shape is the broadcast shape of self.batch_shape, x.shape[:-2], and mask.shape[:-1], representing n samples from the posterior over latent states given the observed value x.

prob

View source

prob(
    value, name='prob', **kwargs
)

Probability density/mass function.

Additional documentation from LinearGaussianStateSpaceModel:

kwargs:
  • mask: optional bool-type Tensor with rightmost dimension [num_timesteps]; True values specify that the value of x at that timestep is masked, i.e., not conditioned on. Additional dimensions must match or be broadcastable to self.batch_shape; any further dimensions must match or be broadcastable to the sample shape of x. Default value: None (falls back to self.mask).

Args
value float or double Tensor.
name Python str prepended to names of ops created by this function.
**kwargs Named arguments forwarded to subclass implementation.

Returns
prob a Tensor of shape sample_shape(x) + self.batch_shape with values of type self.dtype.

quantile

View source

quantile(
    value, name='quantile', **kwargs
)

Quantile function. Aka 'inverse cdf' or 'percent point function'.

Given random variable X and p in [0, 1], the quantile is:

quantile(p) := x such that P[X <= x] == p

Args
value float or double Tensor.
name Python str prepended to names of ops created by this function.
**kwargs Named arguments forwarded to subclass implementation.

Returns
quantile a Tensor of shape sample_shape(x) + self.batch_shape with values of type self.dtype.

sample

View source

sample(
    sample_shape=(), seed=None, name='sample', **kwargs
)

Generate samples of the specified shape.

Note that a call to sample() without arguments will generate a single sample.

Args
sample_shape 0D or 1D int32 Tensor. Shape of the generated samples.
seed PRNG seed; see tfp.random.sanitize_seed for details.
name name to give to the op.
**kwargs Named arguments forwarded to subclass implementation.

Returns
samples a Tensor with prepended dimensions sample_shape.

stddev

View source

stddev(
    name='stddev', **kwargs
)

Standard deviation.

Standard deviation is defined as,

stddev = E[(X - E[X])**2]**0.5

where X is the random variable associated with this distribution, E denotes expectation, and stddev.shape = batch_shape + event_shape.

Args
name Python str prepended to names of ops created by this function.
**kwargs Named arguments forwarded to subclass implementation.

Returns
stddev Floating-point Tensor with shape identical to batch_shape + event_shape, i.e., the same shape as self.mean().

survival_function

View source

survival_function(
    value, name='survival_function', **kwargs
)

Survival function.

Given random variable X, the survival function is defined:

survival_function(x) = P[X > x]
                     = 1 - P[X <= x]
                     = 1 - cdf(x).

Args
value float or double Tensor.
name Python str prepended to names of ops created by this function.
**kwargs Named arguments forwarded to subclass implementation.

Returns
Tensor of shape sample_shape(x) + self.batch_shape with values of type self.dtype.

unnormalized_log_prob

View source

unnormalized_log_prob(
    value, name='unnormalized_log_prob', **kwargs
)

Potentially unnormalized log probability density/mass function.

This function is similar to log_prob, but does not require that the return value be normalized. (Normalization here refers to the total integral of probability being one, as it should be by definition for any probability distribution.) This is useful, for example, for distributions where the normalization constant is difficult or expensive to compute. By default, this simply calls log_prob.

Args
value float or double Tensor.
name Python str prepended to names of ops created by this function.
**kwargs Named arguments forwarded to subclass implementation.

Returns
unnormalized_log_prob a Tensor of shape sample_shape(x) + self.batch_shape with values of type self.dtype.

variance

View source

variance(
    name='variance', **kwargs
)

Variance.

Variance is defined as,

Var = E[(X - E[X])**2]

where X is the random variable associated with this distribution, E denotes expectation, and Var.shape = batch_shape + event_shape.

Args
name Python str prepended to names of ops created by this function.
**kwargs Named arguments forwarded to subclass implementation.

Returns
variance Floating-point Tensor with shape identical to batch_shape + event_shape, i.e., the same shape as self.mean().

with_name_scope

@classmethod
with_name_scope(
    method
)

Decorator to automatically enter the module name scope.

class MyModule(tf.Module):
  @tf.Module.with_name_scope
  def __call__(self, x):
    if not hasattr(self, 'w'):
      self.w = tf.Variable(tf.random.normal([x.shape[1], 3]))
    return tf.matmul(x, self.w)

Using the above module would produce tf.Variables and tf.Tensors whose names included the module name:

mod = MyModule()
mod(tf.ones([1, 2]))
<tf.Tensor: shape=(1, 3), dtype=float32, numpy=..., dtype=float32)>
mod.w
<tf.Variable 'my_module/Variable:0' shape=(2, 3) dtype=float32,
numpy=..., dtype=float32)>

Args
method The method to wrap.

Returns
The original method wrapped such that it enters the module's name scope.

__getitem__

View source

__getitem__(
    slices
)

Slices the batch axes of this distribution, returning a new instance.

b = tfd.Bernoulli(logits=tf.zeros([3, 5, 7, 9]))
b.batch_shape  # => [3, 5, 7, 9]
b2 = b[:, tf.newaxis, ..., -2:, 1::2]
b2.batch_shape  # => [3, 1, 5, 2, 4]

x = tf.random.normal([5, 3, 2, 2])
cov = tf.matmul(x, x, transpose_b=True)
chol = tf.linalg.cholesky(cov)
loc = tf.random.normal([4, 1, 3, 1])
mvn = tfd.MultivariateNormalTriL(loc, chol)
mvn.batch_shape  # => [4, 5, 3]
mvn.event_shape  # => [2]
mvn2 = mvn[:, 3:, ..., ::-1, tf.newaxis]
mvn2.batch_shape  # => [4, 2, 3, 1]
mvn2.event_shape  # => [2]

Args
slices slices from the [] operator

Returns
dist A new tfd.Distribution instance with sliced parameters.

__iter__

View source

__iter__()