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I am trying to make a digit recognition program. I shall feed a white/black image of a digit and my output layer will fire the corresponding digit (one neuron shall fire, out of the 0 -> 9 neurons in the Output Layer). I finished implementing a Two-dimensional BackPropagation Neuron Network. My topology sizes are [5][3] -> [3][3] -> 1[10]. So it's One 2-D Input Layer, One 2-D Hidden Layer and One 1-D Output Layer. However I am getting weird and wrong results (Average Error and Output Values).

Debugging at this stage is kind of time consuming. Therefore, I would love to hear if this is the correct design so I continue debugging. Here are the flow steps of my implementation:

  • Build the Network: One Bias on each Layer except on the Output Layer (No Bias). A Bias's output value is always = 1.0, however its Connections Weights get updated on each pass like all other neurons in the network. All Weights range 0.000 -> 1.000 (no negatives)

  • Get Input data (0 | OR | 1) and set nth value as the nth Neuron Output Value in the input layer.

  • Feed Forward: On each Neuron 'n' in every Layer (except the Input Layer):

    • Get result of SUM (Output Value * Connection Weight) of connected Neurons from previous layer towards this nth Neuron.
    • Get TanHyperbolic - Transfer Function - of this SUM as Results
    • Set Results as the Output Value of this nth Neuron
  • Get Results: Take Output Values of Neurons in the Output Layer

  • BackPropagation:

    • Calculate Network Error: on the Output Layer, get SUM Neurons' (Target Values - Output Values)^2. Divide this SUM by the size of the Output Layer. Get its SquareRoot as Result. Compute Average Error = (OldAverageError * SmoothingFactor * Result) / (SmoothingFactor + 1.00)
    • Calculate Output Layer Gradients: for each Output Neuron 'n', nth Gradient = (nth Target Value - nth Output Value) * nth Output Value TanHyperbolic Derivative
    • Calculate Hidden Layer Gradients: for each Neuron 'n', get SUM (TanHyperbolic Derivative of a weight going from this nth Neuron * Gradient of the destination Neuron) as Results. Assign (Results * this nth Output Value) as the Gradient.
    • Update all Weights: Starting from the hidden Layer and back to the Input Layer, for nth Neuron: Compute NewDeltaWeight = (NetLearningRate * nth Output Value * nth Gradient + Momentum * OldDeltaWeight). Then assign New Weight as (OldWeight + NewDeltaWeight)
  • Repeat process.

Here is my attempt for digit number seven. The outputs are Neuron # zero and Neuron # 6. Neuron six should be carrying 1 and Neuron # zero should be carrying 0. In my results, all Neuron other than six are carrying the same value (# zero is a sample).

Sample Results

Sorry for the long post. If you know this then you probably know how cool it is and how large it is to be in a single post. Thank you in advance

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  • Typically Softmax with log-loss is typically used for multiclass output layer activation function. It is not clear to me if you were doing binary or multiclass output. Dec 20 '15 at 0:13
  • I am a beginner. I don't know the meaning of binary vs multiclass output layer. I provided my goal of this project in the first paragraph. Please read it and provide any feedback. Appreciate it and thanks
    – user5348609
    Dec 20 '15 at 0:22
  • Sure. You have multiclass/multinomial: with the 10 possible digits comprising the 10 classes. So you can try changing your output layer activation function to softmax en.wikipedia.org/wiki/Softmax_function. Let us know what effect that has. Dec 20 '15 at 0:26
  • I made this an answer in order to put the relevant section in relief. Dec 20 '15 at 0:34
  • Do we need to delete the comments then?
    – user5348609
    Dec 20 '15 at 1:20
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Softmax with log-loss is typically used for multiclass output layer activation function. You have multiclass/multinomial: with the 10 possible digits comprising the 10 classes.

So you can try changing your output layer activation function to softmax

http://en.wikipedia.org/wiki/Softmax_function

Artificial neural networks

In neural network simulations, the softmax function is often implemented at the final layer of a network used for classification. Such networks are then trained under a log loss (or cross-entropy) regime, giving a non-linear variant of multinomial logistic regression.

Let us know what effect that has. –

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  • Thanks for your comment. Q: if I have 10 Neurons (each shall carry 0 or 1) is't still considered 10 classes? Indeed 10 digits but each Neuron has one of two possible values. I took a look on Softmax, another Q: Should I create another class of Neurons (to carry this different transfer method) then create an Output Layer containing such objects? Or same class but add a second transfer function should be fine? Thanks again.
    – user5348609
    Dec 20 '15 at 1:31
  • Just replace tanh activation function with softmax only on the output layer. The tanh is reasonable for the input to hidden and hidden to hidden layers. Re: 10 neurons - yes that is what I said that you do have ten classes. Dec 20 '15 at 3:59
  • Working on it. I also decided to build the XOR instead of my goal, for testing/learning/simplifying the Neuron Network. Thank you
    – user5348609
    Dec 21 '15 at 20:13

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