Dismiss
Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

# Find a “best fit” equation

It's been a while since I was in college and knew how to calculate a best fit line, but I find myself needing to. Suppose I have a set of points, and I want to find the line that is the best of those points.

What is the equation to determine a best fit line? How would I do that with PHP?

-

Method of Least Squares http://en.wikipedia.org/wiki/Least_squares. This book Numerical Recipes 3rd Edition: The Art of Scientific Computing (Hardcover) has all you need for algorithms to implement Least Squares and other techniques.

-

Here's an article comparing two ways to fit a line to data. One thing to watch out for is that there is a direct solution that is correct in theory but can have numerical problems. The article shows why that method can fail and gives another method that is better.

-
+1 This by far the best answer, the other method is vastly inferior, albeit more popular. – Muhd Jun 8 '11 at 18:02

Although you can use an iterative approach, you can directly calculate the slope and intercept of a line given a set of observations using a least-squares approach. See the "Univariate Linear Case" section of the Wikipedia article on linear regression for how to calculate the coefficients `a` and `b` in `y = a + bx` given sets of `(x,y)` points.

-

Implemented from wiki page, untested.

``````\$sx = 0;
\$sy = 0;
\$sxy = 0;
\$sx2 = 0;
\$n = count(\$data);
foreach (\$data as \$x => \$y)
{
\$sx += \$x;
\$sy += \$y;
\$sxy += \$x * \$y;
\$sx2 += \$x * \$x;
}
\$beta = (\$n*\$sxy - \$sx*\$sy) / (\$n*\$sx2 - \$sx*\$sx);
\$alpha = \$sy/\$n - \$sx*\$beta/\$n;

echo "y = \$alpha + \$beta x";
``````
-

Of additional interest is probably how good of a fit the line is. For that, use the Pearson correlation, here in a PHP function:

``````/**
* returns the pearson correlation coefficient (least squares best fit line)
*
* @param array \$x array of all x vals
* @param array \$y array of all y vals
*/

function pearson(array \$x, array \$y)
{
// number of values
\$n = count(\$x);
\$keys = array_keys(array_intersect_key(\$x, \$y));

// get all needed values as we step through the common keys
\$x_sum = 0;
\$y_sum = 0;
\$x_sum_sq = 0;
\$y_sum_sq = 0;
\$prod_sum = 0;
foreach(\$keys as \$k)
{
\$x_sum += \$x[\$k];
\$y_sum += \$y[\$k];
\$x_sum_sq += pow(\$x[\$k], 2);
\$y_sum_sq += pow(\$y[\$k], 2);
\$prod_sum += \$x[\$k] * \$y[\$k];
}

\$numerator = \$prod_sum - (\$x_sum * \$y_sum / \$n);
\$denominator = sqrt( (\$x_sum_sq - pow(\$x_sum, 2) / \$n) * (\$y_sum_sq - pow(\$y_sum, 2) / \$n) );

return \$denominator == 0 ? 0 : \$numerator / \$denominator;
}
``````
-
btw, the Pearson coefficient ranges from 0 (no correlation) to 1.0 (points lie on a straight line) – ruquay Dec 13 '08 at 0:46

You may want to check out linear regression, or more generally, curve fitting.

-

An often used approach is to iteratively minimize the sum of squared y-differences between your points and the fit function.

-