# Single layer neural network [closed]

For the implementation of single layer neural network, I have two data files.

``````In:
0.832 64.643
0.818 78.843

Out:
0 0 1
0 0 1
``````

The above is the format of 2 data files.

The target output is "1" for a particular class that the corresponding input belongs to and "0" for the remaining 2 outputs.

The problem is as follows:

Your single layer neural network will find A (3 by 2 matrix) and b (3 by 1 vector) in Y = A*X + b where Y is [C1, C2, C3]' and X is [x1, x2]'.

To solve the problem above with a neural network, we can re-write the equation as follow: Y = A' * X' where A' = [A b] (3 by 3 matrix) and X' is [x1, x2, 1]'

Now you can use a neural network with three input nodes (one for x1, x2, and 1 respectively) and three outputs (C1, C2, C3).

The resulting 9 (since we have 9 connections between 3 inputs and 3 outputs) weights will be equivalent to elements of A' matrix.

Basicaly, I am trying to do something like this, but it is not working:

``````function neuralNetwork
x = X_Q2(:,1);
y = X_Q2(:,2);

learningrate = 0.2;
max_iteration = 50;

% initialize parameters
count = length(x);
weights = rand(1,3); % creates a 1-by-3 array with random weights
globalerror = 0;
iter = 0;
while globalerror ~= 0 && iter <= max_iteration
iter = iter + 1;
globalerror = 0;
for p = 1:count
output = calculateOutput(weights,x(p),y(p));
localerror = T_Q2(p) - output
weights(1)= weights(1) + learningrate *localerror*x(p);
weights(2)= weights(1) + learningrate *localerror*y(p);
weights(3)= weights(1) + learningrate *localerror;
globalerror = globalerror + (localerror*localerror);
end
end
``````

I write this function in some other file and calling it in my previous code.

``````function result = calculateOutput (weights, x, y)
s = x * weights(1) + y * weights(2) + weights(3);
if s >= 0
result = 1;
else
result = -1;
end
``````

I can spot a few problems with the code. The main issue is that the target is multi-class (not binary), so you need to either use 3 output nodes one for each class (called 1-of-N encoding), or use a single output node with a different activation function (something capable of more than just binary output -1/1 or 0/1)

In the solution below, the perceptron has the following structure: ``````%# load your data
input = [
0.832 64.643
0.818 78.843
1.776 45.049
0.597 88.302
1.412 63.458
];
target = [
0 0 1
0 0 1
0 1 0
0 0 1
0 0 1
];

%# parameters of the learning algorithm
LEARNING_RATE = 0.1;
MAX_ITERATIONS = 100;
MIN_ERROR = 1e-4;

[numInst numDims] = size(input);
numClasses = size(target,2);

%# three output nodes connected to two-dimensional input nodes + biases
weights = randn(numClasses, numDims+1);

isDone = false;               %# termination flag
iter = 0;                     %# iterations counter
while ~isDone
iter = iter + 1;

%# for each instance
err = zeros(numInst,numClasses);
for i=1:numInst
%# compute output: Y = W*X + b, then apply threshold activation
output = ( weights * [input(i,:)';1] >= 0 );                       %#'

%# error: err = T - Y
err(i,:) = target(i,:)' - output;                                  %#'

%# update weights (delta rule): delta(W) = alpha*(T-Y)*X
weights = weights + LEARNING_RATE * err(i,:)' * [input(i,:) 1];    %#'
end

%# Root mean squared error
rmse = sqrt(sum(err.^2,1)/numInst);
fprintf(['Iteration %d: ' repmat('%f ',1,numClasses) '\n'], iter, rmse);

%# termination criteria
if ( iter >= MAX_ITERATIONS || all(rmse < MIN_ERROR) )
isDone = true;
end
end

%# plot points and one-against-all decision boundaries
[~,group] = max(target,[],2);                     %# actual class of instances
gscatter(input(:,1), input(:,2), group), hold on
xLimits = get(gca,'xlim'); yLimits = get(gca,'ylim');
for i=1:numClasses
ezplot(sprintf('%f*x + %f*y + %f', weights(i,:)), xLimits, yLimits)
end
title('Perceptron decision boundaries')
hold off
``````

The results of training over the five sample you provided:

``````Iteration 1: 0.447214 0.632456 0.632456
Iteration 2: 0.000000 0.447214 0.447214
...
Iteration 49: 0.000000 0.447214 0.447214
Iteration 50: 0.000000 0.632456 0.000000
Iteration 51: 0.000000 0.447214 0.000000
Iteration 52: 0.000000 0.000000 0.000000
`````` Note that the data used in the example above only contains 5 samples. You would get more meaningful results if you had more training instances in each class.