# Neural Network not learning - MNIST data - Handwriting recognition

I have written a Neural Network Program. It works for Logic Gates, but when I try to use it for recognizing handwritten digits - it simply does not learn.

// This is a single neuron; this might be necessary in order to understand remaining code

``````typedef struct SingleNeuron
{
double                  outputValue;
std::vector<double>     weight;
std::vector<double>     deltaWeight;
double                  sum;
}SingleNeuron;
``````

Then I initialize the net. I set weights to be random value between -0.5 to +0.5, sum to 0, deltaWeight to 0

Then comes the FeedForward:

``````for (unsigned i = 0; i < inputValues.size(); ++i)
{
neuralNet[0][i].outputValue = inputValues[i];
neuralNet[0][i].sum = 0.0;
//  std::cout << "o/p Val = " << neuralNet[0][i].outputValue << std::endl;
}

for (unsigned i = 1; i < neuralNet.size(); ++i)
{
std::vector<SingleNeuron> prevLayerNeurons = neuralNet[i - 1];
unsigned j = 0;
double thisNeuronOPVal = 0;
//  std::cout << std::endl;
for (j = 0; j < neuralNet[i].size() - 1; ++j)
{
double sum = 0;
for (unsigned k = 0; k < prevLayerNeurons.size(); ++k)
{
sum += prevLayerNeurons[k].outputValue * prevLayerNeurons[k].weight[j];
}
neuralNet[i][j].sum = sum;
neuralNet[i][j].outputValue = TransferFunction(sum);
//      std::cout << neuralNet[i][j].outputValue << "\t";
}
//      std::cout << std::endl;
}
``````

My transfer function and its derivative is mentioned at the end.

After this I try to back-propagate using:

``````// calculate output layer gradients
for (unsigned i = 0; i < outputLayer.size() - 1; ++i)
{
double delta = actualOutput[i] - outputLayer[i].outputValue;
}
//  std::cout << "Found Output gradients "<< std::endl;
for (unsigned i = neuralNet.size() - 2; i > 0; --i)
{
std::vector<SingleNeuron>& hiddenLayer = neuralNet[i];
std::vector<SingleNeuron>& nextLayer = neuralNet[i + 1];

for (unsigned j = 0; j < hiddenLayer.size(); ++j)
{
double dow = 0.0;
for (unsigned k = 0; k < nextLayer.size() - 1; ++k)
{
}
}
}
//  std::cout << "Found hidden layer gradients "<< std::endl;

// from output to 1st hidden layer, update all weights
for (unsigned i = neuralNet.size() - 1; i > 0; --i)
{
std::vector <SingleNeuron>& currentLayer = neuralNet[i];
std::vector <SingleNeuron>& prevLayer = neuralNet[i - 1];

for (unsigned j = 0; j < currentLayer.size() - 1; ++j)
{
for (unsigned k = 0; k < prevLayer.size(); ++k)
{
SingleNeuron& thisNeueon = prevLayer[k];
double oldDeltaWeight = thisNeueon.deltaWeight[j];
double newDeltaWeight = ETA * thisNeueon.outputValue * currentLayer[j].gradient + (ALPHA * oldDeltaWeight);
thisNeueon.deltaWeight[j] = newDeltaWeight;
thisNeueon.weight[j] += newDeltaWeight;
}
}
}
``````

These are the TransferFuntion and its derivative;

``````double TransferFunction(double x)
{
double val;
//val = tanh(x);
val = 1 / (1 + exp(x * -1));
return val;
}

double TransferFunctionDerivative(double x)
{
//return 1 - x * x;
double val = exp(x * -1) / pow((exp(x * -1) + 1), 2);
return val;
}
``````

One thing I observed If i use standard sigmoid function to be my transfer function AND if I pass output of neuron to transfer function - Result is INFINITY. But tanh(x) works fine with this value

So if I am using 1/1+e^(-x) as transfer function I have to pass `Sum of Net Inputs` and with `tanh` being my transfer function I have to pass `output` of current neuron.

I do not completely understand why this is the way it is, may be this calls for a different question.

But this question is really about something else: NETWORK IS WORKING FOR LOGIC GATES BUT NOT FOR CHARACTER RECOGNITION

I have tried many variations/combinations of `Learning Rate` and `Acceleration` and `# hidden layers` and `their sizes`. Please find the results below:

``````AvgErr: 0.299399          #Pass799
AvgErr : 0.305071         #Pass809
AvgErr : 0.303046         #Pass819
AvgErr : 0.299569         #Pass829
AvgErr : 0.30413          #Pass839
AvgErr : 0.304165         #Pass849
AvgErr : 0.300529         #Pass859
AvgErr : 0.302973         #Pass869
AvgErr : 0.299238         #Pass879
AvgErr : 0.304708         #Pass889
AvgErr : 0.30068          #Pass899
AvgErr : 0.302582         #Pass909
AvgErr : 0.301767         #Pass919
AvgErr : 0.303167         #Pass929
AvgErr : 0.299551         #Pass939
AvgErr : 0.301295         #Pass949
AvgErr : 0.300651         #Pass959
AvgErr : 0.297867         #Pass969
AvgErr : 0.304221         #Pass979
AvgErr : 0.303702         #Pass989
``````

After looking at the results you might feel this guy is simply stuck into local minima, but please wait and read through:

``````Input = [0, 0, 0, 0, 0, 0, 1, 0, 0, 0]
Output = 0.0910903, 0.105674, 0.064575, 0.0864824, 0.128682, 0.0878434, 0.0946296, 0.154405, 0.0678767, 0.0666924

Input = [1, 0, 0, 0, 0, 0, 0, 0, 0, 0]
Output = 0.0916106, 0.105958, 0.0655508, 0.086579, 0.126461, 0.0884082, 0.110953, 0.163343, 0.0689315, 0.0675822

Input = [0, 0, 0, 1, 0, 0, 0, 0, 0, 0]
Output = 0.105344, 0.105021, 0.0659517, 0.0858077, 0.123104, 0.0884107, 0.116917, 0.161911, 0.0693426, 0.0675156

Input = [0, 0, 0, 0, 0, 0, 1, 0, 0, 0]
Output = , 0.107113, 0.101838, 0.0641632, 0.0967766, 0.117149, 0.085271, 0.11469, 0.153649, 0.0672772, 0.0652416
``````

Above is the output of epoch #996, #997,#998 and #999

So simply network is not learning. For this e.g. I have used ALPHA = 0.4, ETA = 0.7, 10 hidden layers each of 100 neurons and average is over 10 epochs. If you are worried about Learning Rate being 0.4 or so many hidden layers I have already tried their variations. For e.g. for learning rate being 0.1 and 4 hidden layers - each of 16

``````Input = [0, 0, 0, 0, 0, 0, 1, 0, 0, 0]
Output = 0.0883238, 0.0983253, 0.0613749, 0.0809751, 0.124972, 0.0897194, 0.0911235, 0.179984, 0.0681346, 0.0660039

Input = [1, 0, 0, 0, 0, 0, 0, 0, 0, 0]
Output = 0.0868767, 0.0966924, 0.0612488, 0.0798343, 0.120353, 0.0882381, 0.111925, 0.169309, 0.0676711, 0.0656819

Input = [0, 0, 0, 1, 0, 0, 0, 0, 0, 0]
Output = 0.105252, 0.0943837, 0.0604416, 0.0781779, 0.116231, 0.0858496, 0.108437, 0.1588, 0.0663156, 0.0645477

Input = [0, 0, 0, 0, 0, 0, 1, 0, 0, 0]
Output = 0.102023, 0.0914957, 0.059178, 0.09339, 0.111851, 0.0842454, 0.104834, 0.149892, 0.0651799, 0.063558
``````

I am so damn sure that I have missed something. I am not able to figure it out. I have read Tom Mitchel's algorithm so many times, but I don't know what is wrong. Whatever example I solve by hand - works! (Please don't ask me to solve MNIST data images by hand ;) ) I do not know where to change the code, what to do.. please help out..

1 Hidden Layer of 32 -- still no learning.

Expected Output -- Input is images between 0-9, so a simple vector describing which is current image, that bit is 1 all others are 0. So i would want output to be as close to 1 for that particular bit and others being close to 0 For e.g. if input is `Input = [0, 0, 0, 0, 0, 0, 1, 0, 0, 0]` I would want output to be something like `Output = 0.002023, 0.0914957, 0.059178, 0.09339, 0.011851, 0.0842454, 0.924834, 0.049892, 0.0651799, 0.063558` (THis is vague, hand-generated)

Here are the links of other researcher's work.

SourceForge -- This is rather a library

Not only these 2, there are so many sites showing the demos.

Things are working quite fine for them. If I set my network parameters(Alpha, ETA) like them I am not getting results like them, so this is reassurance that something is wrong with my code.

## EDIT 2

Accelaration - 0.7, Learning Rate 0.1

Accelaration - 0.7, Learning Rate 0.6

In both of the above cases Hidden layers were 3, each of 32 neurons.

• I haven't dissected your code but your `TransferFunctionDerivative` can overflow for very large negative inputs. It would be better to define the derivative in terms of the sigmoid. If `s(x)` is the sigmoid value, then `ds/dx = s(x)[1 - s(x)]`. Feb 26, 2015 at 16:16
• First thing to do is to remove 9 of 10 hidden layers. Deep nets can be remarkably uncooperative even when coded right. So please leave 1 hidden layer, and let us know what happens (1 hidden layer NN can solve MNIST to a reasonable 93% accuracy at least). Feb 26, 2015 at 16:50
• I solved the puzzle. I had made the worst possible mistake. I was giving wrong input. I have used opencv to scan the images, instead of using `reshape` i was using `resize` and so input was linear interpolation of images. So my input was wrong. There was nothing wrong with the code. My network is `784 - 65 - 10`giving 96.43% accuracy. I apologize from the bottom of my heart for wasting your time. From next time onwards I will try to take care of such issues. Special Thanks to Denis! Mar 3, 2015 at 7:50
I solved the puzzle. I had made the worst possible mistake. I was giving wrong input. I have used opencv to scan the images, instead of using `reshape` I was using `resize` and so input was linear interpolation of images. So my input was wrong. There was nothing wrong with the code. My network is `784 - 65 - 10` giving 96.43% accuracy.