# Simple/Single layer perceptron algorithm doesn't work

I am trying to grasp the ideas behind neural networks (fully) so I'm starting out by creating my own simple perceptron algorithm.

Here is my code (in JavaScript):

``````var lr = 0.1;//learning rate

//Initiate the weights randomly
function initWeights(weights, trainingSets){
for(var i=0; i<trainingSets[0].in.length; i++){
weights[i] = Math.random()*2 - 1;
}
weights.push(Math.random()*2 - 1); //b
}

//Return the raw activation value for a giving trainingSet
function getSum(weights, trainingSet){
var sum = 0;
for(var i=0; i < trainingSet.in.length; i++){
sum += weights[i]*trainingSet.in[i];
}
sum += 1 * weights[weights.length-1];
return sum;
}

//Activation function
function activate(value){
return (value >= 0)? 1 : 0;
}

function train(weights, trainingSets){
var error = 0;
for(var i=0; i<trainingSets.length; i++){
var currentSet = trainingSets[i];
var activationValue = getSum(weights, currentSet);
var error = currentSet.out - activate(activationValue);
error += error;
for(var j=0; j<weights.length-1; j++){
var deltaW = error * lr * currentSet.in[j];
weights[j] += deltaW;
}
weights[weights.length-1] += error * lr * 1;
}
return error/(weights.length);
}

var inp = [
{in:[1,1], out:1},
{in:[0,0], out:0},
{in:[0,1], out:0},
];
var w = [];
initWeights(w, inp);
//for(var j = 0; j < inp.length; j++){
var error = 1;
while(error >= 0.01){
error = train(w, inp);
}
//}
console.log("===")
var tester = {in:[1,0], out: NaN};
console.log(getSum(w, tester)) //should be negative
console.log("y=("+w[1]+"*x+"+w[2]+")/"+w[1])
``````

The results aren't consistent, (I'm using an AND algorithm to learn by).
The plot should look like:

But usually looks like this:

I'm sure that I'm missing something small here,

-

There are at least three problems with your code:

• You are redeclaring the error variable, it was first meant to be a summarized error, then you declare it again as a per-output-neuron error, which leads to the lose of information reagarding the whole process
• Your stopping criterion is bad - it should be a mean absolute value of errors, not just sum of errors - consider simple network, which classyfies one training example of label `0` as `1`, it will result in negative error in your code, so training stops, even though it is far from being over
• It is not true, that after training with

``````var inp = [
{in:[1,1], out:1},
{in:[0,0], out:0},
{in:[0,1], out:0},
];
``````

you will get `f( [1,0] ) == 0`, this is not how perceptron works. It will simply find such a line in the 2 dimensioal plane, that `[1,1]` is on its one side, and `[0,0]` and `[0,1]` on the other. There is no guarantee, that `[1,0]` lies on the same side as `[0,0]` and `[0,1]`, and this is expected behaviour. With provided data, there is no reason for perceptron to not use the vertical line with `x=0.5`, which perfectly separates your data, but `f( [1,0] ) == 1`. Your training data does not "define" and operation, just a simple set of rules, which are obeyed by infinite number of classifiers.

``````function train(weights, trainingSets){
var error = 0;
for(var i=0; i<trainingSets.length; i++){
var currentSet = trainingSets[i];
var activationValue = getSum(weights, currentSet);
var error_current = currentSet.out - activate(activationValue);
error += Math.abs( error_current );
for(var j=0; j<weights.length-1; j++){
var deltaW = error_current * lr * currentSet.in[j];
weights[j] += deltaW;
}
weights[weights.length-1] += error_current * lr * 1;
}
return error/(weights.length);
}
``````

as stated in the comment, if you train your network with values for points (1,0), (0,1) and (1,1) it will infer value for (0,0) by itself

``````var inp = [
{in:[1,1], out:1},
{in:[0,1], out:0},
{in:[1,0], out:0},
];

var w = [];
initWeights(w, inp);
//for(var j = 0; j < inp.length; j++){
var error = 1;
while(error >= 0.01){
error = train(w, inp);
}
//}
console.log("===")

var test = [
{in:[1,1], out:1},
{in:[0,0], out:0},
{in:[0,1], out:0},
{in:[1,0], out:0},
];

for(var i=0; i<test.length; ++i){
console.log(test[i].in + " out: " +test[i].out + " nn: " + activate(getSum(w, test[i]) ) );
}
``````

produces

``````1,1 out: 1 nn: 1
0,0 out: 0 nn: 0
0,1 out: 0 nn: 0
1,0 out: 0 nn: 0
``````
-
Heh, I was just about to write my answer with the same results. – tsiki Aug 19 '13 at 7:01
Yes, error was re-declared, my bad (I didn't mean to do that). Also, the last point makes me confused, isn't the whole idea to give a basic set of rules (not all of them) and (hope) the network will behave accordingly? – funerr Aug 19 '13 at 7:30
But it does behave accordingly. Simply your set of rules is to small to expect such big generalization. There are too many possible models, which perfectly fit your set of rules to expect, that it will magicaly select the only one you are interested in. – lejlot Aug 19 '13 at 7:59
@lejlot, then how can I train it for an AND rule? (without teaching it all 4 possibilities) – funerr Aug 25 '13 at 17:58
This is not what neural networks are for. In case of and you could train it with (0,1)->0, (1,0)->0, (1,1)->1, and it will infer (0,0)->0 by itself (only because there is no line in the R^2 space which would be consistent with those 3 values and inconsistent with the forth one), but once again this is not what nn are for. – lejlot Aug 25 '13 at 18:30