`ReparameterizationKLKLqp`

Inherits From: `VariationalInference`

- Class
`ed.ReparameterizationKLKLqp`

- Class
`ed.inferences.ReparameterizationKLKLqp`

Defined in `edward/inferences/klqp.py`

.

Variational inference with the KL divergence

\(\text{KL}( q(z; \lambda) \| p(z \mid x) ).\)

This class minimizes the objective using the reparameterization gradient and an analytic KL term.

The objective function also adds to itself a summation over all tensors in the `REGULARIZATION_LOSSES`

collection.

**init**

```
__init__(
latent_vars=None,
data=None
)
```

Create an inference algorithm.

: list of RandomVariable or dict of RandomVariable to RandomVariable. Collection of random variables to perform inference on. If list, each random variable will be implictly optimized using a`latent_vars`

`Normal`

random variable that is defined internally with a free parameter per location and scale and is initialized using standard normal draws. The random variables to approximate must be continuous.

`build_loss_and_gradients`

`build_loss_and_gradients(var_list)`

`finalize`

`finalize()`

Function to call after convergence.

`initialize`

```
initialize(
n_samples=1,
kl_scaling=None,
*args,
**kwargs
)
```

Initialize inference algorithm. It initializes hyperparameters and builds ops for the algorithm’s computation graph.

: int. Number of samples from variational model for calculating stochastic gradients.`n_samples`

: dict of RandomVariable to tf.Tensor. Provides option to scale terms when using ELBO with KL divergence. If the KL divergence terms are`kl_scaling`

\(\alpha_p \mathbb{E}_{q(z\mid x, \lambda)} [ \log q(z\mid x, \lambda) - \log p(z)],\)

then pass {\(p(z)\): \(\alpha_p\)} as

`kl_scaling`

, where \(\alpha_p\) is a tensor. Its shape must be broadcastable; it is multiplied element-wise to the batchwise KL terms.

`print_progress`

`print_progress(info_dict)`

Print progress to output.

`run`

```
run(
variables=None,
use_coordinator=True,
*args,
**kwargs
)
```

A simple wrapper to run inference.

- Initialize algorithm via
`initialize`

. - (Optional) Build a TensorFlow summary writer for TensorBoard.
- (Optional) Initialize TensorFlow variables.
- (Optional) Start queue runners.
- Run
`update`

for`self.n_iter`

iterations. - While running,
`print_progress`

. - Finalize algorithm via
`finalize`

. - (Optional) Stop queue runners.

To customize the way inference is run, run these steps individually.

: list. A list of TensorFlow variables to initialize during inference. Default is to initialize all variables (this includes reinitializing variables that were already initialized). To avoid initializing any variables, pass in an empty list.`variables`

: bool. Whether to start and stop queue runners during inference using a TensorFlow coordinator. For example, queue runners are necessary for batch training with file readers. *args, **kwargs: Passed into`use_coordinator`

`initialize`

.

`update`

`update(feed_dict=None)`

Run one iteration of optimization.

: dict. Feed dictionary for a TensorFlow session run. It is used to feed placeholders that are not fed during initialization.`feed_dict`

dict. Dictionary of algorithm-specific information. In this case, the loss function value after one iteration.