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I'm taking the course in Matlab, and I have done a gradient descent implementation but it gives incorrect results.

The code:

for iter = 1:num_iters

sumTheta1 = 0;
sumTheta2 = 0;
for s = 1:m
    sumTheta1 = theta(1) + theta(2) .* X(s,2) - y(s);
    sumTheta2 = theta(1) + theta(2) .* X(s,2) - y(s) .* X(s,2);
end

theta(1) = theta(1) - alpha .* (1/m) .* sumTheta1;
theta(2) = theta(2) - alpha .* (1/m) .* sumTheta2;

J_history(iter) = computeCost(X, y, theta);

end

This is the important part. I think the implementation of the formula is correct, even though it's not optimized. The formula is:

theta1 = theta1 - (alpha)(1/m)(summation_i^m(theta1 + theta2*x(i)-y(i)))
theta2 = theta2 - (alpha)(1/m)(summation_i^m(theta1 + theta2*x(i)-y(i)))(x(i))

So where could the problem be?

EDIT: CODE updated

function [theta, J_history] = gradientDescent(X, y, theta, alpha, num_iters)

m = length(y); % number of training examples
J_history = zeros(num_iters, 1);


for iter = 1:num_iters

for s = 1:m

sumTheta1 = ((theta(1) .* X(s,1)) + (theta(2) .* X(s,2))) - (y(s));
sumTheta2 = ((theta(1) .* X(s,1)) + (theta(2) .* X(s,2))) - (y(s)) .* X(s,2);
end

temp1 = theta(1) - alpha .* (1/m) .* sumTheta1;
temp2 = theta(2) - alpha .* (1/m) .* sumTheta2;

theta(1) = temp1;
theta(2) = temp2;

J_history(iter) = computeCost(X, y, theta);

end

end

EDIT(2): Fixed it, working code.

Got it, it was the +Dan hint that did it I will accept his answer and still put the code here to anyone stuck :), cheers.

function [theta, J_history] = gradientDescent(X, y, theta, alpha, num_iters)

 m = length(y); % number of training examples
 J_history = zeros(num_iters, 1);


for iter = 1:num_iters

sumTheta1 = 0;
sumTheta2 = 0;

for s = 1:m

sumTheta1 = sumTheta1 + ((theta(1) .* X(s,1)) + (theta(2) .* X(s,2))) - (y(s));
sumTheta2 = sumTheta2 + (((theta(1) .* X(s,1)) + (theta(2) .* X(s,2))) - (y(s))) .* X(s,2);
end

temp1 = theta(1) - alpha .* (1/m) .* sumTheta1;
temp2 = theta(2) - alpha .* (1/m) .* sumTheta2;

theta(1) = temp1;
theta(2) = temp2;

% Save the cost J in every iteration    
J_history(iter) = computeCost(X, y, theta);

end

end 
share|improve this question
    
You know that Matlab will not understand the syntax (alpha)(1/m) right? You need to explicitly put in a multiplication sign, eg (alpha)*(1/m)*(summation_i^m * (theta1 + theta2 * x(i) - y(i))) * x(i). Does this make sense? –  Colin T Bowers Oct 16 '13 at 3:02
1  
Yes that is the formula that says in the notes, not the matlab implementation, the matlab code is above that. Because I don't know how to write formulas here. –  Pedro.Alonso Oct 16 '13 at 3:08
    
Not sure if there is a generally agreed upon method for writing equations on SO. Personally, I prefer not to use code-highlighting on equations, but some users do. If you wanted to go all-out, you can use the Google API's - see here –  Colin T Bowers Oct 17 '13 at 3:18
    
Cool will check it, thanks. :) –  Pedro.Alonso Oct 17 '13 at 23:39

3 Answers 3

up vote 1 down vote accepted

At first glance I notice that your sumTheta1 is not actually summing but rather replacing itself each iteration. I think you meant:

sumTheta1 = sumTheta1 + theta(1) + theta(2) .* X(s,2) - y(s);

And the same for sumTheta2

But for future reference you could replace this (corrected) loop:

for s = 1:m
    sumTheta1 = theta(1) + theta(2) .* X(s,2) - y(s);
    sumTheta2 = theta(1) + theta(2) .* X(s,2) - y(s) .* X(s,2);
end

with this vectorized formula

sumTheta1 = sum(theta(1) + theta(2)*X(:,2) - y);
sumTheta2 = sum(theta(1) + theta(2)*X(:,2) - y.*X(:,2))
share|improve this answer
    
Well I did the change and it got worse,the thetas I got with the first code where -3.120881 1.112813 very close to the minimum, with the addition of sumTheta(x) to the loop it blows up -73.069510 16.165062 –  Pedro.Alonso Oct 16 '13 at 13:58

If I see this formula

theta1 = theta1 - (alpha)(1/m)(summation_i^m(theta1 + theta2*x(i)-y(i)))

I guess the matlab equivalent would be:

theta1 = theta1 - alpha/m*(theta1 + theta2)*sum(x-y)

Probably you can determine m as follows:

m =length(x);

However, your two formulas make me wonder whether you want to calculate them sequentially or simultaneously.

In the second case create a temporary variable and use this in the calculation.

myFactor = alpha/m*(theta1_previous + theta2_previous)

theta1 = theta1_previous - myFactor*sum(x-y)
theta2 = theta2_previous - myFactor*sum((x-y).*x)
share|improve this answer
    
Gradient descent should be simultaneous –  Dan Oct 16 '13 at 13:56
    
Is simultaneous, I think in this line: theta(1) = theta(1) - alpha .* (1/m) .* sumTheta1; theta(2) = theta(2) - alpha .* (1/m) .* sumTheta2; –  Pedro.Alonso Oct 16 '13 at 14:00
    
@Pedro.Alonso Of course there are multiple ways to do it. I have updated my answer with one that should do the trick. –  Dennis Jaheruddin Oct 16 '13 at 14:15
    
Thanks, but with my code how that will go? Updated code. –  Pedro.Alonso Oct 16 '13 at 14:31

Vectorized version:

for iter = 1:num_iters
    theta = theta - (alpha .* X'*(X * theta - y) ./m);
    J_history(iter) = computeCost(X, y, theta);
end
share|improve this answer
    
I have another problem chat –  Pedro.Alonso Nov 12 '13 at 21:26

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