# BackPropagation Neuron Network Approach - Design

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).

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

• 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

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

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. –

• 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