# Reinforcement Learning, how can I sample action from Gaussian distribution with action dimension space larger than one?

In the code of Actor-Critic with Gaussian,

``````class PolicyEstimator():
"""
Policy Function approximator.
"""

def __init__(self, learning_rate=0.01, scope="policy_estimator"):
with tf.variable_scope(scope):
self.state = tf.placeholder(tf.float32, [400], "state")
self.target = tf.placeholder(dtype=tf.float32, name="target")

# This is just linear classifier
self.mu = tf.contrib.layers.fully_connected(
inputs=tf.expand_dims(self.state, 0),
num_outputs=1,
activation_fn=None,
weights_initializer=tf.zeros_initializer)
self.mu = tf.squeeze(self.mu)

self.sigma = tf.contrib.layers.fully_connected(
inputs=tf.expand_dims(self.state, 0),
num_outputs=1,
activation_fn=None,
weights_initializer=tf.zeros_initializer)

self.sigma = tf.squeeze(self.sigma)
self.sigma = tf.nn.softplus(self.sigma) + 1e-5
self.normal_dist = tf.contrib.distributions.Normal(self.mu, self.sigma)
self.action = self.normal_dist._sample_n(1)
``````

Initializing an instance of Normal distribution

``````self.normal_dist = tf.contrib.distributions.Normal(self.mu, self.sigma)
``````

Sampling

``````self.action = self.normal_dist._sample_n(1)
``````

the code samples only one action since the dimension of the env is 1. However, if the action space is 40 or more, how can I sample the action?

``````self.action = self.normal_dist._sample_n(40)
``````

I think it means sampling 40 actions of which dimension space is 1 not sampling an action with 40 dimension value.

How can I sample one action of which dimension value is 40 or more?

To create an action vector with shape `(40)`, you need the last layer of your network to output a vector with a shape of 40. So change:

``````self.mu = tf.contrib.layers.fully_connected(
inputs=tf.expand_dims(self.state, 0),
num_outputs=1,
activation_fn=None,
weights_initializer=tf.zeros_initializer)
``````

To:

``````self.mu = tf.contrib.layers.fully_connected(
inputs=tf.expand_dims(self.state, 0),
num_outputs=40,
activation_fn=None,
weights_initializer=tf.zeros_initializer)
``````

This means that `self.mu` (which is fed to `tf.distributions.Normal`) will be a vector with shape `(40)`.

You can do the same for `sigma`, but in my experience, it is better to treat this as a trainable parameter rather than an output from a network, for example:

``````import numpy as np
import tensorflow as tf

state_dim = 3  # 3 dimentional state
action_dim = 40  # 40 dimentional action
action_bound = 2  # Actions are scaled between -2 & +2

# Define ops for actor/policy
state = tf.placeholder(tf.float32, [None, state_dim])

# Dense layer which takes an imput of shape 3, and output shape 40
mu = tf.layers.dense(state, action_dim, tf.nn.tanh, name='pi_mu')

# Use log sigma to prevent NaNs (initialised to 0)
log_sigma = tf.get_variable(name="log_sigma", shape=action_dim, initializer=tf.zeros_initializer())

# Create a 40D Gaussian distribution (sigma = exp(0) = 1)
dist = tf.distributions.Normal(loc=mu * action_bound, scale=tf.exp(log_sigma))

# This sample_op returns a single vector of shape 40 sampled from dist
sample_op = tf.squeeze(dist.sample(1), axis=0)

# Start session
sess = tf.Session()
sess.run(tf.global_variables_initializer())

# Sample a 40D action using an input state
sess.run(sample_op, feed_dict={state: np.array([[1, 0, -1]])})
``````

Output:

``````array([[-0.12732446, -1.0969237 ,  0.19172549, -0.53541076, -1.7409694 ,
-1.9716561 , -0.4621313 ,  1.1770394 , -0.89807725, -0.428378  ,
0.43714064,  0.5723815 , -2.4273002 , -1.1083983 , -0.67126757,
1.4471897 , -1.9418054 , -0.3857537 ,  0.3149717 , -0.5094094 ,
-0.9856905 ,  1.1567912 ,  0.37608355, -1.1339413 ,  0.13634366,
-0.22886413,  1.2220807 , -0.9807693 ,  1.5443543 , -0.01700211,
-0.30074215,  0.77911556,  1.0790621 ,  1.4446486 ,  0.11510286,
0.13127172,  0.9332013 , -0.22423705,  0.27746603,  0.03245509]],
dtype=float32)
``````
• Sorry to reply to your answer so late. Could you please offer a working code so that I can try it and get an intuitive understanding of the process. – GoingMyWay Sep 26 '18 at 7:55
• I've added some working code – Anjum Sayed Sep 26 '18 at 10:34
• Thank you, some people say that if the action dimension is large than one, multivariate normal is preferred than unimodal normal. – GoingMyWay Sep 26 '18 at 13:09