I'm trying to implement a neural network that classifies images into one of the two discrete categories. The problem is, however, that it currently always predicts 0 for any input and I'm not really sure why.

Here's my feature extraction method:

def extract(file):
    # Resize and subtract mean pixel
    img = cv2.resize(cv2.imread(file), (224, 224)).astype(np.float32)
    img[:, :, 0] -= 103.939
    img[:, :, 1] -= 116.779
    img[:, :, 2] -= 123.68
    # Normalize features
    img = (img.flatten() - np.mean(img)) / np.std(img)

    return np.array([img])

Here's my gradient descent routine:

def fit(x, y, t1, t2):
    """Training routine"""
    ils = x.shape[1] if len(x.shape) > 1 else 1
    labels = len(set(y))

    if t1 is None or t2 is None:
        t1 = randweights(ils, 10)
        t2 = randweights(10, labels)

    params = np.concatenate([t1.reshape(-1), t2.reshape(-1)])
    res = grad(params, ils, 10, labels, x, y)
    params -= 0.1 * res

    return unpack(params, ils, 10, labels)

Here are my forward and back(gradient) propagations:

def forward(x, theta1, theta2):
    """Forward propagation"""

    m = x.shape[0]

    # Forward prop
    a1 = np.vstack((np.ones([1, m]), x.T))
    z2 = np.dot(theta1, a1)

    a2 = np.vstack((np.ones([1, m]), sigmoid(z2)))
    a3 = sigmoid(np.dot(theta2, a2))

    return (a1, a2, a3, z2, m)

def grad(params, ils, hls, labels, x, Y, lmbda=0.01):
    """Compute gradient for hypothesis Theta"""

    theta1, theta2 = unpack(params, ils, hls, labels)

    a1, a2, a3, z2, m = forward(x, theta1, theta2)
    d3 = a3 - Y.T
    print('Current error: {}'.format(np.mean(np.abs(d3))))

    d2 = np.dot(theta2.T, d3) * (np.vstack([np.ones([1, m]), sigmoid_prime(z2)]))
    d3 = d3.T
    d2 = d2[1:, :].T

    t1_grad = np.dot(d2.T, a1.T)
    t2_grad = np.dot(d3.T, a2.T)

    theta1[0] = np.zeros([1, theta1.shape[1]])
    theta2[0] = np.zeros([1, theta2.shape[1]])

    t1_grad = t1_grad + (lmbda / m) * theta1
    t2_grad = t2_grad + (lmbda / m) * theta2

    return np.concatenate([t1_grad.reshape(-1), t2_grad.reshape(-1)])

And here's my prediction function:

def predict(theta1, theta2, x):
    """Predict output using learned weights"""
    m = x.shape[0]

    h1 = sigmoid(np.hstack((np.ones([m, 1]), x)).dot(theta1.T))
    h2 = sigmoid(np.hstack((np.ones([m, 1]), h1)).dot(theta2.T))

    return h2.argmax(axis=1)

I can see that the error rate is gradually decreasing with each iteration, generally converging somewhere around 1.26e-05.

What I've tried so far:

  1. PCA
  2. Different datasets (Iris from sklearn and handwritten numbers from Coursera ML course, achieving about 95% accuracy on both). However, both of those were processed in a batch, so I can assume that my general implementation is correct, but there is something wrong with either how I extract features, or how I train the classifier.
  3. Tried sklearn's SGDClassifier and it didn't perform much better, giving me a ~50% accuracy. So something wrong with the features, then?

Edit: An average output of h2 looks like the following:

[0.5004899   0.45264441]
[0.50048522  0.47439413]
[0.50049019  0.46557124]
[0.50049261  0.45297816]

So, very similar sigmoid outputs for all validation examples.

  • 2
    One thought, are you randomizing your training set? If there are a bunch of the 0 class in the first batches it is possible it becomes focused on them very early. – cdeterman Jan 5 '17 at 15:34
  • The data is ordered, i.e.: 10000 of 0s, then 10000 of 1s. – Yurii Dolhikh Jan 5 '17 at 15:43
  • Just realized you said 'batch'. I think I was confusing with 'mini-batch' where this is a common problem. I will need to think about this some more. – cdeterman Jan 5 '17 at 15:47
  • Just FYI: I tried randomizing the input data and the result is still the same. – Yurii Dolhikh Jan 5 '17 at 16:41
  • Try returning the raw h2 values from your final predict call. Are they all the same as well? – cdeterman Jan 5 '17 at 17:44

My network does always predict the same class. What is the problem?

I had this a couple of times. Although I'm currently too lazy to go through your code, I think I can give some general hints which might also help others who have the same symptom but probably different underlying problems.

Debugging Neural Networks

Fitting one item datasets

For every class i the network should be able to predict, try the following:

  1. Create a dataset of only one data point of class i.
  2. Fit the network to this dataset.
  3. Does the network learn to predict "class i"?

If this doesn't work, there are four possible error sources:

  1. Buggy training algorithm: Try a smaller model, print a lot of values which are calculated in between and see if those match your expectation.
    1. Dividing by 0: Add a small number to the denominator
    2. Logarithm of 0 / negativ number: Like dividing by 0
  2. Data: It is possible that your data has the wrong type. For example, it might be necessary that your data is of type float32 but actually is an integer.
  3. Model: It is also possible that you just created a model which cannot possibly predict what you want. This should be revealed when you try simpler models.
  4. Initialization / Optimization: Depending on the model, your initialization and your optimization algorithm might play a crucial role. For beginners who use standard stochastic gradient descent, I would say it is mainly important to initialize the weights randomly (each weight a different value). - see also: this question / answer

Learning Curve

See sklearn for details.

enter image description here

The idea is to start with a tiny training dataset (probably only one item). Then the model should be able to fit the data perfectly. If this works, you make a slightly larger dataset. Your training error should slightly go up at some point. This reveals your models capacity to model the data.

Data analysis

Check how often the other class(es) appear. If one class dominates the others (e.g. one class is 99.9% of the data), this is a problem. Look for "outlier detection" techniques.


  • Learning rate: If your network doesn't improve and get only slightly better than random chance, try reducing the learning rate. For computer vision, a learning rate of 0.001 is often used / working. This is also relevant if you use Adam as an optimizer.
  • Preprocessing: Make sure you use the same preprocessing for training and testing. You might see differences in the confusion matrix (see this question)

Common Mistakes

This is inspired by reddit:

  • You forgot to apply preprocessing
  • Dying ReLU
  • Too small / too big learning rate
  • Wrong activation function in final layer:
    • Your targets are not in sum one? -> Don't use softmax
    • Single elements of your targets are negative -> Don't use Softmax, ReLU, Sigmoid. tanh might be an option
  • Too deep network: You fail to train. Try a simpler neural network first.
  • Vastly unbalanced data: You might want to look into imbalanced-learn
  • Single elements of your targets are negative -> Don't use Softmax, ReLU, Sigmoid. tanh might be an option. Can you please suggest then the correct activation function in this case? – omilus Jan 17 at 15:10
  • Did you see that I suggest tanh? What else do you expect? (You can always design your own ones; sometimes linear is also a good option) – Martin Thoma Jan 17 at 15:15
  • i misread. I thought tanh is in the list of functions not to use. Maybe it should be Tanh, as it is first word in the sentence – omilus Jan 17 at 15:54

After a week and a half of research I think I understand what the issue is. There is nothing wrong with the code itself. The only two issues that prevent my implementation from classifying successfully are time spent learning and proper selection of learning rate / regularization parameters.

I've had the learning routine running for some tome now, and it's pushing 75% accuracy already, though there is still plenty of space for improvement.


Just incase some one else encounters this problem. Mine was with a deeplearning4j Lenet(CNN) architecture, It kept on giving the final output of the last training folder for every test. I was able to solve it by increasing my batchsize and shuffling the training data so each batch contained at least a sample from more than one folder. My data class had a batchsize of 1 which was really dangerous.

Edit: Although another thing I observed recently is having limited sets of training samples per class despite having a large dataset. e.g. training a neural-network to recognise human faces but having only a maximum of say 2 different faces for 1 person mean while the dataset consists of say 10,000 persons thus a dataset of 20,000 faces in total. A better dataset would be 1000 different faces for 10,000 persons thus a dataset of 10,000,000 faces in total. This is relatively necessary if you want avoid overfitting the data to one class so your network can easily generalise and produce better predictiond.

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