# Deep-Learning Nan loss reasons

Perhaps too general a question, but can anyone explain what would cause a Convolutional Neural Network to diverge?

Specifics:

I am using Tensorflow's iris_training model with some of my own data and keep getting

ERROR:tensorflow:Model diverged with loss = NaN.

Traceback...

tensorflow.contrib.learn.python.learn.monitors.NanLossDuringTrainingError: NaN loss during training.

Traceback originated with line:

`````` tf.contrib.learn.DNNClassifier(feature_columns=feature_columns,
hidden_units=[300, 300, 300],
n_classes=11,
model_dir="/tmp/iris_model")
``````

I've tried adjusting the optimizer, using a zero for learning rate, and using no optimizer. Any insights into network layers, data size, etc is appreciated.

• It's a natural property of stochastic gradient descent, if the learning rate is too large, SGD can diverge into infinity – Yaroslav Bulatov Oct 14 '16 at 20:02
• @YaroslavBulatov I've tried with that AdagradOptiizer with a learning rate of about 1E-15. Perhaps my data isn't suited to SGD, can you suggest another algorithm? Still new to Tensorflow and Deep Learning. – Free Url Oct 14 '16 at 20:13
• In my case normalization helped – Dmitry Jan 9 at 19:04
• The solution for me was using `tf.losses.sparse_softmax_cross_entropy(y, logits)` instead of my own implementation of Safe Softmax using `tf.nn.Softmax` – Eduardo Reis Mar 22 at 0:45

There are lots of things I have seen make a model diverge.

1. Too high of a learning rate. You can often tell if this is the case if the loss begins to increase and then diverges to infinity.

2. I am not to familiar with the DNNClassifier but I am guessing it uses the categorical cross entropy cost function. This involves taking the log of the prediction which diverges as the prediction approaches zero. That is why people usually add a small epsilon value to the prediction to prevent this divergence. I am guessing the DNNClassifier probably does this or uses the tensorflow opp for it. Probably not the issue.

3. Other numerical stability issues can exist such as division by zero where adding the epsilon can help. Another less obvious one if the square root who's derivative can diverge if not properly simplified when dealing with finite precision numbers. Yet again I doubt this is the issue in the case of the DNNClassifier.

4. You may have an issue with the input data. Try calling `assert not np.any(np.isnan(x))` on the input data to make sure you are not introducing the nan. Also make sure all of the target values are valid. Finally, make sure the data is properly normalized. You probably want to have the pixels in the range [-1, 1] and not [0, 255].

5. The labels must be in the domain of the loss function, so if using a logarithmic-based loss function all labels must be non-negative (as noted by evan pu and the comments below).

• thanks for the breakdown. My problem was that my labels were symmetric around zero (i.e. [-5,...,5]). Shifting solved the problem. – Free Url Nov 8 '16 at 0:45
• The labels should be binary. 1 or 0. Otherwise the categorical cross-entropy cost function would not make sense. – chasep255 Nov 8 '16 at 1:26
• `tf.keras.utils.normalize(data)` was useful to normalize the data. – transistor1 Nov 22 '17 at 3:21
• by 'binary' one means that they should be one-hot encoded, i.e. a vector (1,0,0,....,0) for examples of the first class, (0,1,0,....0) for examples of the second class and (0,....,0,1) for examples of the last class. The number of output nodes should be the same as the number of classes you have. – Andre Holzner Jan 12 '18 at 7:33
• You are my hero! When I try the linear regression example (toptal.com/machine-learning/…) with another dataset, say Celsius to Fahrenheit , I got W, b, loss all 'nan'. But after follow your answer, I changed learning_rate = 0.01 to learning_rate = 0.001, then everything worked perfect! – holibut Mar 16 '18 at 8:22

If you're training for cross entropy, you want to add a small number like 1e-8 to your output probability.

Because log(0) is negative infinity, when your model trained enough the output distribution will be very skewed, for instance say I'm doing a 4 class output, in the beginning my probability looks like

``````0.25 0.25 0.25 0.25
``````

but toward the end the probability will probably look like

``````1.0 0 0 0
``````

And you take a cross entropy of this distribution everything will explode. The fix is to artifitially add a small number to all the terms to prevent this.

• I use the `categorical_crossentropy` loss function from keras, does it already implement this? – StayFoolish Sep 10 '18 at 3:25
• @StayFoolish I am not sure, the cop-out answer would be to look at their source code, but I'm willing to bet they have taken-care of this in their code already. I'd try and see, most likely you're fine. – Evan Pu Nov 28 '18 at 16:20

If using integers as targets, makes sure they aren't symmetrical at 0.

I.e., don't use classes -1, 0, 1. Use instead 0, 1, 2.

• Would you care to comment a little bit on the reasons why or cite a reference for completion? – gsimard Apr 16 '18 at 3:36
• @gsimard Honestly I don't remember as I worked with this a while back. – yper Apr 16 '18 at 7:31
• @gsimard, this is because of reason 5 in the accepted answer. Logistic-based regression functions often use logarithms, which are only defined on non-negative numbers – Free Url Apr 29 '18 at 18:31
• @Zroach No, in my case negative numbers were supported but the reason of it not working was specifically symmetry at 0. – yper Nov 15 '18 at 5:58

In my case I got NAN when setting distant integer LABELs. ie:

• Labels [0..100] the training was ok,
• Labels [0..100] plus one additional label 8000, then I got NANs.

So, not use a very distant Label.

EDIT You can see the effect in the following simple code:

``````from keras.models import Sequential
from keras.layers import Dense, Activation
import numpy as np

X=np.random.random(size=(20,5))
y=np.random.randint(0,high=5, size=(20,1))

model = Sequential([
Dense(10, input_dim=X.shape),
Activation('relu'),
Dense(5),
Activation('softmax')
])
model.compile(optimizer = "Adam", loss = "sparse_categorical_crossentropy", metrics = ["accuracy"] )

print('fit model with labels in range 0..5')
history = model.fit(X, y, epochs= 5 )

X = np.vstack( (X, np.random.random(size=(1,5))))
y = np.vstack( ( y, []))
print('fit model with labels in range 0..5 plus 8000')
history = model.fit(X, y, epochs= 5 )
``````

The result shows the NANs after adding the label 8000:

``````fit model with labels in range 0..5
Epoch 1/5
20/20 [==============================] - 0s 25ms/step - loss: 1.8345 - acc: 0.1500
Epoch 2/5
20/20 [==============================] - 0s 150us/step - loss: 1.8312 - acc: 0.1500
Epoch 3/5
20/20 [==============================] - 0s 151us/step - loss: 1.8273 - acc: 0.1500
Epoch 4/5
20/20 [==============================] - 0s 198us/step - loss: 1.8233 - acc: 0.1500
Epoch 5/5
20/20 [==============================] - 0s 151us/step - loss: 1.8192 - acc: 0.1500
fit model with labels in range 0..5 plus 8000
Epoch 1/5
21/21 [==============================] - 0s 142us/step - loss: nan - acc: 0.1429
Epoch 2/5
21/21 [==============================] - 0s 238us/step - loss: nan - acc: 0.2381
Epoch 3/5
21/21 [==============================] - 0s 191us/step - loss: nan - acc: 0.2381
Epoch 4/5
21/21 [==============================] - 0s 191us/step - loss: nan - acc: 0.2381
Epoch 5/5
21/21 [==============================] - 0s 188us/step - loss: nan - acc: 0.2381
``````
• Interesting. I would think this is dependent on your loss function. Can you please specify how you were measuring loss? – Free Url Feb 4 at 2:14
• I used, as is, the 'sparse_categorical_crossentropy' – Guido Feb 4 at 8:26

If you'd like to gather more information on the error and if the error occurs in the first few iterations, I suggest you run the experiment in CPU-only mode (no GPUs). The error message will be much more specific.