I'm working on machine learning problem and want to use linear regression as learning algorithm. I have implemented 2 different methods to find parameters `theta`

of linear regression model: Gradient (steepest) descent and Normal equation. On the same data they should both give approximately equal `theta`

vector. However they do not.

Both `theta`

vectors are very similar on all elements but the first one. That is the one used to multiply vector of all 1 added to the data.

Here is how the `theta`

s look like (fist column is output of Gradient descent, second output of Normal equation):

```
Grad desc Norm eq
-237.7752 -4.6736
-5.8471 -5.8467
9.9174 9.9178
2.1135 2.1134
-1.5001 -1.5003
-37.8558 -37.8505
-1.1024 -1.1116
-19.2969 -19.2956
66.6423 66.6447
297.3666 296.7604
-741.9281 -744.1541
296.4649 296.3494
146.0304 144.4158
-2.9978 -2.9976
-0.8190 -0.8189
```

What can cause the difference in `theta(1, 1)`

returned by gradient descent compared to `theta(1, 1)`

returned by normal equation? Do I have bug in my code?

Here is my implementation of normal equation in Matlab:

```
function theta = normalEque(X, y)
[m, n] = size(X);
X = [ones(m, 1), X];
theta = pinv(X'*X)*X'*y;
end
```

Here is code for gradient descent:

```
function theta = gradientDesc(X, y)
options = optimset('GradObj', 'on', 'MaxIter', 9999);
[theta, ~, ~] = fminunc(@(t)(cost(t, X, y)),...
zeros(size(X, 2), 1), options);
end
function [J, grad] = cost(theta, X, y)
m = size(X, 1);
X = [ones(m, 1), X];
J = sum((X * theta - y) .^ 2) ./ (2*m);
for i = 1:size(theta, 1)
grad(i, 1) = sum((X * theta - y) .* X(:, i)) ./ m;
end
end
```

I pass exactly the same data `X`

and `y`

to both functions (I do not normalize `X`

).

## Edit 1:

Based on answers and comments I checked few my code and run some tests.

First I want to check if the problem can be cause by X beeing near singular as suggested by @user1489497's answer. So I replaced pinv by inv - and when run it I really got warning `Matrix is close to singular or badly scaled.`

. To be sure that that is not the problem I obtained much larger dataset and run tests with this new dataset. This time `inv(X)`

did not display the warning and using `pinv`

and `inv`

gave same results. So I hope that ** X is not close to singular any more**.

Then **I changed normalEque code as suggested** by woodchips so now it looks like:

```
function theta = normalEque(X, y)
X = [ones(size(X, 1), 1), X];
theta = pinv(X)*y;
end
```

**However the problem is still there**. New `normalEque`

function on new data that are not close to singular gives different `theta`

as `gradientDesc`

.

To find out which algorithm is buggy I have run linear regression algorithm of data mining software Weka on the same data. Weka computed theta very similar to output of `normalEque`

but different to the output of `gradientDesc`

. So I guess that `normalEque`

is correct and **there is a bug in gradientDesc**.

Here is comparison of `theta`

s computed by Weka, `normalEque`

and `GradientDesc`

:

```
Weka(correct) normalEque gradientDesc
779.8229 779.8163 302.7994
1.6571 1.6571 1.7064
1.8430 1.8431 2.3809
-1.5945 -1.5945 -1.5964
3.8190 3.8195 5.7486
-4.8265 -4.8284 -11.1071
-6.9000 -6.9006 -11.8924
-15.6956 -15.6958 -13.5411
43.5561 43.5571 31.5036
-44.5380 -44.5386 -26.5137
0.9935 0.9926 1.2153
-3.1556 -3.1576 -1.8517
-0.1927 -0.1919 -0.6583
2.9207 2.9227 1.5632
1.1713 1.1710 1.1622
0.1091 0.1093 0.0084
1.5768 1.5762 1.6318
-1.3968 -1.3958 -2.1131
0.6966 0.6963 0.5630
0.1990 0.1990 -0.2521
0.4624 0.4624 0.2921
-12.6013 -12.6014 -12.2014
-0.1328 -0.1328 -0.1359
```

I also computed errors as suggested by Justin Peel's answer. Output of `normalEque`

gives slightly lesser squared error but the difference is marginal. What is more **when I compute gradient of cost of theta using function cost (the same as the one used by gradientDesc) I got gradient near zero**. Same done on output of

`gradientDesc`

does not give gradient near zero. Here is what I mean:```
>> [J_gd, grad_gd] = cost(theta_gd, X, y, size(X, 1));
>> [J_ne, grad_ne] = cost(theta_ne, X, y, size(X, 1));
>> disp([J_gd, J_ne])
120.9932 119.1469
>> disp([grad_gd, grad_ne])
-0.005172856743846 -0.000000000908598
-0.026126463200876 -0.000000135414602
-0.008365136595272 -0.000000140327001
-0.094516503056041 -0.000000169627717
-0.028805977931093 -0.000000045136985
-0.004761477661464 -0.000000005065103
-0.007389474786628 -0.000000005010731
0.065544198835505 -0.000000046847073
0.044205371015018 -0.000000046169012
0.089237705611538 -0.000000046081288
-0.042549228192766 -0.000000051458654
0.016339232547159 -0.000000037654965
-0.043200042729041 -0.000000051748545
0.013669010209370 -0.000000037399261
-0.036586854750176 -0.000000027931617
-0.004761447097231 -0.000000027168798
0.017311225027280 -0.000000039099380
0.005650124339593 -0.000000037005759
0.016225097484138 -0.000000039060168
-0.009176443862037 -0.000000012831350
0.055653840638386 -0.000000020855391
-0.002834810081935 -0.000000006540702
0.002794661393905 -0.000000032878097
```

This would suggest that gradient descent simply did not converge to global minimum... But that is hardly the case as I run it for thousands of iterations. **So where is the bug?**

`theta = pinv(Xones'*Xones + lambda.*eyen)*Xones'*y;`

. I forgot to changed when I removed regularisation. – drasto Jun 30 '12 at 12:47