3

I am building a neural network to learn to recognize handwritten digits from MNIST. I have confirmed that backpropagation calculates the gradients perfectly (gradient checking gives error < 10 ^ -10).

It appears that no matter how I train the weights, the cost function always tends towards around 3.24-3.25 (never below that, just approaching from above) and the training/test set accuracy is very low (around 11% for the test set). It appears that the h values in the end are all very close to 0.1 and to each other.

I cannot find why my program cannot produce better results. I was wondering if anyone could maybe take a look at my code and please tell me any reasons for this occurring. Thank you so much for all your help, I really appreciate it!

Here is my Python code:

import numpy as np
import math
from tensorflow.examples.tutorials.mnist import input_data

# Neural network has four layers
# The input layer has 784 nodes
# The two hidden layers each have 5 nodes
# The output layer has 10 nodes
num_layer = 4
num_node = [784,5,5,10]
num_output_node = 10

# 30000 training sets are used
# 10000 test sets are used
# Can be adjusted
Ntrain = 30000
Ntest = 10000

# Sigmoid Function
def g(X):
    return 1/(1 + np.exp(-X))

# Forwardpropagation
def h(W,X):
    a = X
    for l in range(num_layer - 1):
        a = np.insert(a,0,1)
        z = np.dot(a,W[l])
        a = g(z)
    return a      

# Cost Function
def J(y, W, X, Lambda):
    cost = 0
    for i in range(Ntrain):
        H = h(W,X[i])
        for k in range(num_output_node):            
            cost = cost + y[i][k] * math.log(H[k]) + (1-y[i][k]) * math.log(1-H[k])
    regularization = 0
    for l in range(num_layer - 1):
        for i in range(num_node[l]):
            for j in range(num_node[l+1]):
                regularization = regularization + W[l][i+1][j] ** 2
    return (-1/Ntrain * cost + Lambda / (2*Ntrain) * regularization)

# Backpropagation - confirmed to be correct
# Algorithm based on https://www.coursera.org/learn/machine-learning/lecture/1z9WW/backpropagation-algorithm
# Returns D, the value of the gradient
def BackPropagation(y, W, X, Lambda):
    delta = np.empty(num_layer-1, dtype = object)
    for l in range(num_layer - 1):
        delta[l] = np.zeros((num_node[l]+1,num_node[l+1]))
    for i in range(Ntrain):
        A = np.empty(num_layer-1, dtype = object)
        a = X[i]
        for l in range(num_layer - 1):
            A[l] = a
            a = np.insert(a,0,1)
            z = np.dot(a,W[l])
            a = g(z)
        diff = a - y[i]
        delta[num_layer-2] = delta[num_layer-2] + np.outer(np.insert(A[num_layer-2],0,1),diff)
        for l in range(num_layer-2):
            index = num_layer-2-l
            diff = np.multiply(np.dot(np.array([W[index][k+1] for k in range(num_node[index])]), diff), np.multiply(A[index], 1-A[index])) 
            delta[index-1] = delta[index-1] + np.outer(np.insert(A[index-1],0,1),diff)
    D = np.empty(num_layer-1, dtype = object)
    for l in range(num_layer - 1):
        D[l] = np.zeros((num_node[l]+1,num_node[l+1]))
    for l in range(num_layer-1):
        for i in range(num_node[l]+1):
            if i == 0:
                for j in range(num_node[l+1]):
                    D[l][i][j] = 1/Ntrain * delta[l][i][j]
            else:
                for j in range(num_node[l+1]):
                    D[l][i][j] = 1/Ntrain * (delta[l][i][j] + Lambda * W[l][i][j])
    return D

# Neural network - this is where the learning/adjusting of weights occur
# W is the weights
# learn is the learning rate
# iterations is the number of iterations we pass over the training set
# Lambda is the regularization parameter
def NeuralNetwork(y, X, learn, iterations, Lambda):

    W = np.empty(num_layer-1, dtype = object)
    for l in range(num_layer - 1):
        W[l] = np.random.rand(num_node[l]+1,num_node[l+1])/100
    for k in range(iterations):
        print(J(y, W, X, Lambda))
        D = BackPropagation(y, W, X, Lambda)
        for l in range(num_layer-1):
            W[l] = W[l] - learn * D[l]
    print(J(y, W, X, Lambda))
    return W

mnist = input_data.read_data_sets("MNIST_data/", one_hot=True)

# Training data, read from MNIST
inputpix = []
output = []

for i in range(Ntrain):
    inputpix.append(2 * np.array(mnist.train.images[i]) - 1)
    output.append(np.array(mnist.train.labels[i]))

np.savetxt('input.txt', inputpix, delimiter=' ')
np.savetxt('output.txt', output, delimiter=' ')

# Train the weights
finalweights = NeuralNetwork(output, inputpix, 2, 5, 1)

# Test data
inputtestpix = []
outputtest = []

for i in range(Ntest):
    inputtestpix.append(2 * np.array(mnist.test.images[i]) - 1)
    outputtest.append(np.array(mnist.test.labels[i]))

np.savetxt('inputtest.txt', inputtestpix, delimiter=' ')
np.savetxt('outputtest.txt', outputtest, delimiter=' ')

# Determine the accuracy of the training data
count = 0
for i in range(Ntrain):
    H = h(finalweights,inputpix[i])
    print(H)
    for j in range(num_output_node):
        if H[j] == np.amax(H) and output[i][j] == 1:
            count = count + 1
print(count/Ntrain)

# Determine the accuracy of the test data
count = 0
for i in range(Ntest):
    H = h(finalweights,inputtestpix[i])
    print(H)
    for j in range(num_output_node):
        if H[j] == np.amax(H) and outputtest[i][j] == 1:
            count = count + 1
print(count/Ntest)
  • Could you change one tag to python? Thus the code will be highlighted appropriately. – ahmedus Aug 4 '17 at 23:09
3

Your network is tiny, 5 neurons make it basically a linear model. Increase it to 256 per layer.

Notice, that trivial linear model has 768 * 10 + 10 (biases) parameters, adding up to 7690 floats. Your neural network on the other hand has 768 * 5 + 5 + 5 * 5 + 5 + 5 * 10 + 10 = 3845 + 30 + 60 = 3935. In other words despite being nonlinear neural network, it is actualy a simpler model than a trivial logistic regression applied to this problem. And logistic regression obtains around 11% error on its own, thus you cannot really expect to beat it. Of course this is not a strict argument, but should give you some intuition for why it should not work.

Second issue is related to other hyperparameters, you seem to be using:

  • huge learning rate (is it 2?) it should be more of order 0.0001
  • very little training iterations (are you just executing 5 epochs?)
  • your regularization parameter is huge (it is set to 1), so your network is heavily penalised for learning anything, again - change it to something order of magnitude smaller
  • It seems that the main problem was that I used the wrong activation function. However, adding more neurons per layer helped a lot with the accuracy. I was just wondering, how does one choose all of the hyperparameters and number of neurons per layer? Thank you so much for all your help! – user8384788 Aug 2 '17 at 2:39
  • sigmoid activation is fine, not the best one, but for MNIST it should be fine. Setting hyperparameters is a bit of wild guess - there are some rules of the thumb (like being able to tell that you are clearly not using enough), but usually it is mostly experience with models and/or a lot of search/checking different things. For example if the training error gets stuck than your model probably lacks capacity (thus too few neurons) etc. but there are no "hard" rules here – lejlot Aug 2 '17 at 23:40
  • Interesting, yes I will keep those in mind when setting my hyperparameters. Thank you very much for everything, I truly appreciate it! – user8384788 Aug 3 '17 at 13:36
0

The NN architecture is most likely under-fitting. Maybe, the learning rate is high/low. Or there are most issues with the regularization parameter.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.