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I have an ANN which I am using on the iris data set found here:- Iris data

My network is initiated as follows:-

package neuralnet;
import neuralnet.networks.*;
import neuralnet.framework.transfer.*;
import neuralnet.utility.*;

public class Main{
    public static void main(String[] args){
        String fname = "../data/iris/iris.data";
        String fname2 = "../data/iris/iris2.data";
        Dataset ds = new Dataset(fname);
        Dataset ds2 = new Dataset(fname2);
        TransferFunction tf = new Sigmoid();
        MLP mlp = new MLP(ds, ds2, 3, 3, 0.7, 0.0, tf);

And the network itself is as follows:-

   Backpropagation Network.


package neuralnet.networks;

import java.util.Arrays;
import neuralnet.framework.transfer.*;
import neuralnet.framework.*;
import neuralnet.utility.*;

public class MLP{
    private Dataset ds, ds2;
    private double rate, momentum;
    private NeuronLayer[] layers;
    private TransferFunction tf;

       Constructs a new MLP network.
    public MLP(Dataset ds, Dataset ds2, int noLayers, int neurons, double rate, double momentum, TransferFunction tf){
        this.ds = ds;
        this.ds2 = ds2;
        this.rate = rate;
        this.momentum = momentum;
        this.tf = tf;
        layers = new NeuronLayer[noLayers];
        //Input layer.
        layers[0] = new NeuronLayer(neurons, ds.getNumAttributes(), tf);
        //Hidden layers.
        for(int i=1; i<layers.length-1; i++){
           layers[i] = new NeuronLayer(neurons, layers[i-1].getSize(),tf);
        //Output layer.
        layers[layers.length-1] = new NeuronLayer(ds.getNumClasses(), layers[layers.length-2].getSize(), tf);

       Tests the network against data it hasn't seen before.
    public void test(){
        System.out.println("--------TESTING UNSEEN DATA--------");
        for(int i=0; i<ds2.numEntries(); i++){
            double[] inputs = ds2.getAttributeSet(i);
            double desired = ds2.getClass(i);
            double[] outputs = layers[layers.length-1].getOutputs();
            System.out.println("DESIRED: "+desired+" ACTUAL: "+Arrays.toString(outputs)+"");

       Runs all of the training data through the network without updating weights.
    public void visualise(String outFname, String templateFname){
        double[] outs = new double[ds.numEntries()];
        double[] desired = new double[ds.numEntries()];

        for(int i=0; i<ds.numEntries(); i++){
            outs[i] = ds.getClass(i);
            desired[i] = getMax(layers[layers.length-1].getOutputs());
        Grapher.writeScript(desired, outs, outFname, templateFname);

       Performs the On-Line/Sequential variant of the training algorithm.
    public void sequential(){
        double error;
        Neuron[] neurons, earlierNeurons;
        double[] weights, outputs;
        int epoch = 0;
            error = 0f;
            //For each example in the training set.
            for(int i=0; i<ds.numEntries(); i++){
                //Feedforward, calculate error and backwards propagate error across neurons.
                outputs = layers[layers.length-1].getOutputs();
                error += backPropagate(outputs, toOutputVector(ds.getClass(i), layers[layers.length-1].getSize()));

                //For each layer, update weights.
                for(int j=layers.length-1; j>0; j--){
                    neurons = layers[j].getNeurons(); 
                    earlierNeurons = layers[j-1].getNeurons();
                    for(int k=0; k<neurons.length; k++){
                        weights = neurons[k].getWeights();
                        for(int l=0; l<earlierNeurons.length; l++){
                            weights[l] += rate*(neurons[k].getDelta()*earlierNeurons[l].getOutput());
                System.out.println("EPOCH: "+epoch+" EXAMPLE: "+i+" OUTPUT: "+Arrays.toString(outputs)+" DESIRED: "+ds.getClass(i)+" ERROR: "+error+"");
            error /= ds.numEntries();
        }while(error > 0.01);//TO DO: Change target error

       Method to classify a set of features.
    public double classify(){
        return 0f;

       Takes a scalar class value, and returns the binary representation, used as a target output vector.
    private double[] toOutputVector(double val, int length){
        double[] out = new double[length];
        out[(int)val-1] = 1f;
        return out;

       Gives the Sum Squared Error.
    private double getSSE(double output, double desired){
        //return 0.5*Math.pow((desired - output), 2);
        return (desired-output);

       Finds the maximum value in a double array.
    private double getMax(double[] outputs){
        double out = 0f;
        for(int i=0; i<outputs.length; i++){
            if(outputs[i] > out){
                out = outputs[i];
        return out;

       Feeds the inputs forward through the network.
    private void feedForward(double[] input){
        //Update input layer.
        layers[0].setInput(addBias(input, 0));

        //Update hidden layers and output layer.
        for(int i=1; i<layers.length; i++){

       Adds bias value to inputs.
        Bias value is taken from a layers bias node.
    private double[] addBias(double[] input, int index){
        double[] tmp = new double[input.length+1];
        for(int i=0; i<input.length; i++){
            tmp[i] = input[i];
        tmp[tmp.length-1] = layers[index].getBias();
        return tmp;

       Backwards propagate errors.
    private double backPropagate(double[] outputs, double[] desired){
        Neuron[] neurons, laterNeurons;
        double delta, sum;
        double error = 0f;

        //Calculate delta's of output neurons.
        neurons = layers[layers.length-1].getNeurons();
        for(int i=0; i<neurons.length; i++){
            error = getSSE(outputs[i], desired[i]);
            delta = tf.getDerivativeValue(neurons[i].weightedInput())*error;

        //For hidden and input layers, update delta's.
        for(int i=layers.length-2; i>=0; i--){
            neurons = layers[i].getNeurons();
            laterNeurons = layers[i+1].getNeurons();
            for(int j=0; j<neurons.length; j++){
                sum = 0f;
                for(int k=0; k<laterNeurons.length; k++){
                    sum += neurons[j].getWeights()[k]*laterNeurons[k].getDelta();
                delta = tf.getDerivativeValue(neurons[j].weightedInput())*sum;
        return error;

I have been following the algorithm description in "Artificial Intelligence" by Norvig et al

I have been working on this for weeks now. The network gives perfect output on the second epoch of the training session, however, when presented with new data, it is very inaccurate, with the exception of classifying one of the classes. The third class is calssifies accurately.

If anybody could see an issue with my implementation that would be wonderful; I believe I may have missed something, or misunderstood something.


share|improve this question
@larsmans Ahh thank you, I shall try a higher error margin. –  VisionIncision Mar 25 '13 at 16:05
[Repost of earlier comment:] If the net gives perfect output on the training set but inaccurate predictions on new data, then you're overfitting the training set. The key to preventing this is to use a less complicated network, e.g. fewer hidden nodes, or to implement regularization. Iris is a very simple dataset, where you don't really need hidden units at all to get good accuracy. –  larsmans Mar 25 '13 at 16:06
@larsmans regularization? Sorry, I am new to this. –  VisionIncision Mar 25 '13 at 16:07
That's a standard trick in machine learning: instead of optimizing for log-loss (or whatever your error represents), you optimize for loss + a term that depends on the magnitudes of your weights. That prevents the weights from growing too large and the network learning too complicated a function. –  larsmans Mar 25 '13 at 16:10
@larsmans Like a momentum term? –  VisionIncision Mar 25 '13 at 16:10
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