# Understanding TensorBoard (weight) histograms

It is really straightforward to see and understand the scalar values in TensorBoard. However, it's not clear how to understand histogram graphs.

For example, they are the histograms of my network weights. (After fixing a bug thanks to sunside) What is the best way to interpret these? Layer 1 weights look mostly flat, what does this mean?

I added the network construction code here.

``````X = tf.placeholder(tf.float32, [None, input_size], name="input_x")
x_image = tf.reshape(X, [-1, 6, 10, 1])
tf.summary.image('input', x_image, 4)

# First layer of weights
with tf.name_scope("layer1"):
W1 = tf.get_variable("W1", shape=[input_size, hidden_layer_neurons],
initializer=tf.contrib.layers.xavier_initializer())
layer1 = tf.matmul(X, W1)
layer1_act = tf.nn.tanh(layer1)
tf.summary.histogram("weights", W1)
tf.summary.histogram("layer", layer1)
tf.summary.histogram("activations", layer1_act)

# Second layer of weights
with tf.name_scope("layer2"):
W2 = tf.get_variable("W2", shape=[hidden_layer_neurons, hidden_layer_neurons],
initializer=tf.contrib.layers.xavier_initializer())
layer2 = tf.matmul(layer1_act, W2)
layer2_act = tf.nn.tanh(layer2)
tf.summary.histogram("weights", W2)
tf.summary.histogram("layer", layer2)
tf.summary.histogram("activations", layer2_act)

# Third layer of weights
with tf.name_scope("layer3"):
W3 = tf.get_variable("W3", shape=[hidden_layer_neurons, hidden_layer_neurons],
initializer=tf.contrib.layers.xavier_initializer())
layer3 = tf.matmul(layer2_act, W3)
layer3_act = tf.nn.tanh(layer3)

tf.summary.histogram("weights", W3)
tf.summary.histogram("layer", layer3)
tf.summary.histogram("activations", layer3_act)

# Fourth layer of weights
with tf.name_scope("layer4"):
W4 = tf.get_variable("W4", shape=[hidden_layer_neurons, output_size],
initializer=tf.contrib.layers.xavier_initializer())
Qpred = tf.nn.softmax(tf.matmul(layer3_act, W4)) # Bug fixed: Qpred = tf.nn.softmax(tf.matmul(layer3, W4))
tf.summary.histogram("weights", W4)
tf.summary.histogram("Qpred", Qpred)

# We need to define the parts of the network needed for learning a policy
Y = tf.placeholder(tf.float32, [None, output_size], name="input_y")

# Loss function
# Sum (Ai*logp(yi|xi))
log_lik = -Y * tf.log(Qpred)
loss = tf.reduce_mean(tf.reduce_sum(log_lik * advantages, axis=1))
tf.summary.scalar("Q", tf.reduce_mean(Qpred))
tf.summary.scalar("Y", tf.reduce_mean(Y))
tf.summary.scalar("log_likelihood", tf.reduce_mean(log_lik))
tf.summary.scalar("loss", loss)

# Learning
``````
• I just noticed that you're not using the activations at all on the last layer. You probably meant `tf.nn.softmax(tf.matmul(layer3_act, W4))`. – sunside Feb 18 '17 at 23:48
• @sunside Thanks. It turns out histogram is very useful for debugging as well. I updated pics. – Sung Kim Feb 19 '17 at 2:22
• @SungKim I'm using your implementation as a reference, but how do you add the bias? Like this? `B1 = tf.get_variable("B1", shape=[hidden_layer_neurons],initializer=tf.random_normal_initializer())` and `layer1_bias = tf.add(layer1, B1)` and `tf.summary.histogram("bias", layer1_bias)` – Gert Kommer Jul 12 '17 at 10:48
• @SungKim if you still have the log directory, could you upload it to Aughie Boards? It would be great to see the histograms in an interactive dashboard – Agost Biro Dec 4 '18 at 18:40
• @SungKim would you fix your code by defining `input_size` so that we can run it and see the result in `tensorboard` – Mario Jul 6 '19 at 20:28

It appears that the network hasn't learned anything in the layers one to three. The last layer does change, so that means that there either may be something wrong with the gradients (if you're tampering with them manually), you're constraining learning to the last layer by optimizing only its weights or the last layer really 'eats up' all error. It could also be that only biases are learned. The network appears to learn something though, but it might not be using its full potential. More context would be needed here, but playing around with the learning rate (e.g. using a smaller one) might be worth a shot.

In general, histograms display the number of occurrences of a value relative to each other values. Simply speaking, if the possible values are in a range of `0..9` and you see a spike of amount `10` on the value `0`, this means that 10 inputs assume the value `0`; in contrast, if the histogram shows a plateau of `1` for all values of `0..9`, it means that for 10 inputs, each possible value `0..9` occurs exactly once. You can also use histograms to visualize probability distributions when you normalize all histogram values by their total sum; if you do that, you'll intuitively obtain the likelihood with which a certain value (on the x axis) will appear (compared to other inputs).

Now for `layer1/weights`, the plateau means that:

• most of the weights are in the range of -0.15 to 0.15
• it is (mostly) equally likely for a weight to have any of these values, i.e. they are (almost) uniformly distributed

Said differently, almost the same number of weights have the values `-0.15`, `0.0`, `0.15` and everything in between. There are some weights having slightly smaller or higher values. So in short, this simply looks like the weights have been initialized using a uniform distribution with zero mean and value range `-0.15..0.15` ... give or take. If you do indeed use uniform initialization, then this is typical when the network has not been trained yet.

In comparison, `layer1/activations` forms a bell curve (gaussian)-like shape: The values are centered around a specific value, in this case `0`, but they may also be greater or smaller than that (equally likely so, since it's symmetric). Most values appear close around the mean of `0`, but values do range from `-0.8` to `0.8`. I assume that the `layer1/activations` is taken as the distribution over all layer outputs in a batch. You can see that the values do change over time.

The layer 4 histogram doesn't tell me anything specific. From the shape, it's just showing that some weight values around `-0.1`, `0.05` and `0.25` tend to be occur with a higher probability; a reason could be, that different parts of each neuron there actually pick up the same information and are basically redundant. This can mean that you could actually use a smaller network or that your network has the potential to learn more distinguishing features in order to prevent overfitting. These are just assumptions though.

Also, as already stated in the comments below, do add bias units. By leaving them out, you are forcefully constraining your network to a possibly invalid solution.

• Not having a bias at all can be a very bad idea - it's really like trying to draw a line through a (ver high-dimensional) cloud of points, but being forced to go through the value 0; it might work, and will give you some solution, but chances are it is a bad or simply wrong one. – sunside Feb 18 '17 at 22:09
• I can't tell you much from the histogram sadly. (Updated my answer though.) – sunside Feb 18 '17 at 22:31
• It should probably train a bit longer now. Especially given your first results, `layer4/Qpred` looks like it could get much better. As for the weights staying the same ... I find that fishy, but I cannot make sense of it right now. Could be that it really is the correct distribution, but given that there is no change at all, I find that hard to believe. – sunside Feb 18 '17 at 23:43
• @sunside is there any method to prioritize updating network weights over the biases? As the biases as well as the last layer do seem to suck all the error. I am having a similar issue where only the biases are updated, and the weight histogram remains relatively unchanged. – mamafoku Aug 8 '17 at 19:11
• Not having a bias is ok if using batch norm before activation – Tosha Jul 2 '18 at 13:51