I have coded up a backpropagation algorithm in Matlab based on these notes: http://dl.dropbox.com/u/7412214/BackPropagation.pdf
My network takes input/feature vectors of length 43, has 20 nodes in the hidden layer (arbitrary parameter choice I can change), and has a single output node. I want to train my network to take the 43 features and output a single value between 0 and 100. The input data was normalized to zero mean and unit standard deviation (via z = x - mean / std) and then I appended a "1" term to input vectors to represent a bias. My targetValues are just single numbers between 0 and 100.
Here is the relevant parts of my code:
(By my convention, layer I (i) refers to the input layer, J (j) refers to the hidden layer, and K (k) refers to the output layer, which is a single node in this case.)
for train=1:numItrs for iterator=1:numTrainingSets %%%%%%%% FORWARD PROPAGATION %%%%%%%% % Grab the inputs, which are rows of the inputFeatures matrix InputLayer = inputFeatures(iterator, :)'; %don't forget to turn into column % Calculate the hidden layer outputs: HiddenLayer = sigmoidVector(WeightMatrixIJ' * InputLayer); % Now the output layer outputs: OutputLayer = sigmoidVector(WeightMatrixJK' * HiddenLayer); %%%%%%% Debug stuff %%%%%%%% (for single valued output) if (mod(train+iterator, 100) == 0) str = strcat('Output value: ', num2str(OutputLayer), ' | Test value: ', num2str(targetValues(iterator, :)')); disp(str); end %%%%%%%% BACKWARDS PROPAGATION %%%%%%%% % Propagate backwards for the hidden-output weights currentTargets = targetValues(iterator, :)'; %strip off the row, make it a column for easy subtraction OutputDelta = (OutputLayer - currentTargets) .* OutputLayer .* (1 - OutputLayer); EnergyWeightDwJK = HiddenLayer * OutputDelta'; %outer product % Update this layer's weight matrix: WeightMatrixJK = WeightMatrixJK - epsilon*EnergyWeightDwJK; %does it element by element % Propagate backwards for the input-hidden weights HiddenDelta = HiddenLayer .* (1 - HiddenLayer) .* WeightMatrixJK*OutputDelta; EnergyWeightDwIJ = InputLayer * HiddenDelta'; WeightMatrixIJ = WeightMatrixIJ - epsilon*EnergyWeightDwIJ; end end
And the weight matrices are initialized as follows:
WeightMatrixIJ = rand(numInputNeurons, numHiddenNeurons) - 0.5; WeightMatrixJK = rand(numHiddenNeurons, numOutputNeurons) - 0.5; %randoms b/w (-0.5, 0.5)
The "sigmoidVector" function takes every element in a vector and applies
y = 1 / (1 + exp(-x)).
Here's what the debug messages look like, from the start of the code:
Output value:0.99939 | Test value:20 Output value:0.99976 | Test value:20 Output value:0.99985 | Test value:20 Output value:0.99989 | Test value:55 Output value:0.99991 | Test value:65 Output value:0.99993 | Test value:62 Output value:0.99994 | Test value:20 Output value:0.99995 | Test value:20 Output value:0.99995 | Test value:20 Output value:0.99996 | Test value:20 Output value:0.99996 | Test value:20 Output value:0.99997 | Test value:92 Output value:0.99997 | Test value:20 Output value:0.99997 | Test value:20 Output value:0.99997 | Test value:20 Output value:0.99997 | Test value:20 Output value:0.99998 | Test value:20 Output value:0.99998 | Test value:20 Output value:0.99999 | Test value:20 Output value:0.99999 | Test value:20 Output value:1 | Test value:20 Output value:1 | Test value:62 Output value:1 | Test value:70 Output value:1 | Test value:77 Output value:1 | Test value:20 ** stays saturated at 1 **
Obviously I'd like the network to train output values to be between 0 and 100 to try and match those target values!
Thank you for any help, if you need more information I'll provide all I can.