tfp.substrates.numpy.glm.Poisson

View source on GitHub

Poisson(rate=mean) where mean = exp(X @ weights).

Inherits From: ExponentialFamily

View aliases

Main aliases

tfp.experimental.substrates.numpy.glm.Poisson

tfp.substrates.numpy.glm.Poisson(
    name=None
)

Args
name	Python str used as TF namescope for ops created by member functions. Default value: None (i.e., the subclass name).

Attributes
name
trainable_variables
variables

Methods

as_distribution

View source

as_distribution(
    predicted_linear_response, name=None
)

Builds a mean parameterized TFP Distribution from linear response.

Example:

model = tfp.glm.Bernoulli()
r = tfp.glm.compute_predicted_linear_response(x, w)
yhat = model.as_distribution(r)

Args
predicted_linear_response	response-shaped Tensor representing linear predictions based on new model_coefficients, i.e., tfp.glm.compute_predicted_linear_response( model_matrix, model_coefficients, offset).
name	Python str used as TF namescope for ops created by member functions. Default value: None (i.e., 'log_prob').

Returns
model	tfp.distributions.Distribution-like object with mean parameterized by predicted_linear_response.

log_prob

View source

log_prob(
    response, predicted_linear_response, name=None
)

Computes D(param=mean(r)).log_prob(response) for linear response, r.

Args
response	float-like Tensor representing observed ("actual") responses.
predicted_linear_response	float-like Tensor corresponding to tf.linalg.matmul(model_matrix, weights).
name	Python str used as TF namescope for ops created by member functions. Default value: None (i.e., 'log_prob').

Returns
log_prob	Tensor with shape and dtype of predicted_linear_response representing the distribution prescribed log-probability of the observed responses.

__call__

View source

__call__(
    predicted_linear_response, name=None
)

Computes mean(r), var(mean), d/dr mean(r) for linear response, r.

Here mean and var are the mean and variance of the sufficient statistic, which may not be the same as the mean and variance of the random variable itself. If the distribution's density has the form

p_Y(y) = h(y) Exp[dot(theta, T(y)) - A]

where theta and A are constants and h and T are known functions, then mean and var are the mean and variance of T(Y). In practice, often T(Y) := Y and in that case the distinction doesn't matter.

Args
predicted_linear_response	float-like Tensor corresponding to tf.linalg.matmul(model_matrix, weights).
name	Python str used as TF namescope for ops created by member functions. Default value: None (i.e., 'call').

Returns
mean	Tensor with shape and dtype of predicted_linear_response representing the distribution prescribed mean, given the prescribed linear-response to mean mapping.
variance	Tensor with shape and dtype of predicted_linear_response representing the distribution prescribed variance, given the prescribed linear-response to mean mapping.
grad_mean	Tensor with shape and dtype of predicted_linear_response representing the gradient of the mean with respect to the linear-response and given the prescribed linear-response to mean mapping.