**Overview**

So I'm trying to get a grasp on the mechanics of neural networks. I still don't totally grasp the math behind it, but I think I understand how to implement it. I currently have a neural net that can learn AND, OR, and NOR training patterns. However, I can't seem to get it to implement the XOR pattern. My **feed forward** neural network consists of **2 inputs, 3 hidden, and 1 output.** The weights and biases are randomly set between **-0.5 and 0.5**, and outputs are generated with the **sigmoidal activation function**

**Algorithm**

So far, I'm guessing I made a mistake in my training algorithm which is described below:

- For each neuron in the output layer, provide an
`error`

value that is the`desiredOutput - actualOutput`

--*go to step 3* - For each neuron in a hidden or input layer (working backwards) provide an
`error`

value that is the sum of all`forward connection weights * the errorGradient of the neuron at the other end of the connection`

--*go to step 3* - For each neuron, using the
`error`

value provided, generate an`error gradient`

that equals`output * (1-output) * error`

. --*go to step 4* - For each neuron, adjust the bias to equal
`current bias + LEARNING_RATE * errorGradient`

. Then adjust each backward connection's weight to equal`current weight + LEARNING_RATE * output of neuron at other end of connection * this neuron's errorGradient`

I'm training my neural net online, so this runs after each training sample.

**Code**

This is the main code that runs the neural network:

```
private void simulate(double maximumError) {
int errorRepeatCount = 0;
double prevError = 0;
double error; // summed squares of errors
int trialCount = 0;
do {
error = 0;
// loop through each training set
for(int index = 0; index < Parameters.INPUT_TRAINING_SET.length; index++) {
double[] currentInput = Parameters.INPUT_TRAINING_SET[index];
double[] expectedOutput = Parameters.OUTPUT_TRAINING_SET[index];
double[] output = getOutput(currentInput);
train(expectedOutput);
// Subtracts the expected and actual outputs, gets the average of those outputs, and then squares it.
error += Math.pow(getAverage(subtractArray(output, expectedOutput)), 2);
}
} while(error > maximumError);
```

Now the `train()`

function:

```
public void train(double[] expected) {
layers.outputLayer().calculateErrors(expected);
for(int i = Parameters.NUM_HIDDEN_LAYERS; i >= 0; i--) {
layers.allLayers[i].calculateErrors();
}
}
```

Output layer `calculateErrors()`

function:

```
public void calculateErrors(double[] expectedOutput) {
for(int i = 0; i < numNeurons; i++) {
Neuron neuron = neurons[i];
double error = expectedOutput[i] - neuron.getOutput();
neuron.train(error);
}
}
```

Normal (Hidden & Input) layer `calculateErrors()`

function:

```
public void calculateErrors() {
for(int i = 0; i < neurons.length; i++) {
Neuron neuron = neurons[i];
double error = 0;
for(Connection connection : neuron.forwardConnections) {
error += connection.output.errorGradient * connection.weight;
}
neuron.train(error);
}
}
```

Full Neuron class:

```
package neuralNet.layers.neurons;
import java.util.ArrayList;
import java.util.List;
import java.util.Random;
import neuralNet.Parameters;
import neuralNet.layers.NeuronLayer;
public class Neuron {
private double output, bias;
public List<Connection> forwardConnections = new ArrayList<Connection>(); // Forward = layer closer to input -> layer closer to output
public List<Connection> backwardConnections = new ArrayList<Connection>(); // Backward = layer closer to output -> layer closer to input
public double errorGradient;
public Neuron() {
Random random = new Random();
bias = random.nextDouble() - 0.5;
}
public void addConnections(NeuronLayer prevLayer) {
// This is true for input layers. They create their connections differently. (See InputLayer class)
if(prevLayer == null) return;
for(Neuron neuron : prevLayer.neurons) {
Connection.createConnection(neuron, this);
}
}
public void calcOutput() {
output = bias;
for(Connection connection : backwardConnections) {
connection.input.calcOutput();
output += connection.input.getOutput() * connection.weight;
}
output = sigmoid(output);
}
private double sigmoid(double output) {
return 1 / (1 + Math.exp(-1*output));
}
public double getOutput() {
return output;
}
public void train(double error) {
this.errorGradient = output * (1-output) * error;
bias += Parameters.LEARNING_RATE * errorGradient;
for(Connection connection : backwardConnections) {
// for clarification: connection.input refers to a neuron that outputs to this neuron
connection.weight += Parameters.LEARNING_RATE * connection.input.getOutput() * errorGradient;
}
}
}
```

**Results**

When I'm training for AND, OR, or NOR the network can usually converge within about 1000 epochs, however when I train with XOR, the outputs become fixed and it never converges. So, what am I doing wrong? Any ideas?

**Edit**

Following the advice of others, I started over and implemented my neural network without classes...and it works. I'm still not sure where my problem lies in the above code, but it's in there somewhere.

longtime since I dealt with neural nets. My 1st thought when you say it gets stuck and never converges is that you are maybe hitting a local minimum. I don't recall what kind of NN architectures and conditions can produce that, or what you do to solve it. – Kevin Welker Feb 20 '12 at 22:44