# How can I calculate a trend line in PHP?

So I've read the two related questions for calculating a trend line for a graph, but I'm still lost.

I have an array of xy coordinates, and I want to come up with another array of xy coordinates (can be fewer coordinates) that represent a logarithmic trend line using PHP.

I'm passing these arrays to javascript to plot graphs on the client side.

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## Logarithmic Least Squares

Since we can convert a logarithmic function into a line by taking the `log` of the `x` values, we can perform a linear least squares curve fitting. In fact, the work has been done for us and a solution is presented at Math World.

In brief, we're given `\$X` and `\$Y` values that are from a distribution like `y = a + b * log(x)`. The least squares method will give some values `aFit` and `bFit` that minimize the distance from the parametric curve to the data points given.

Here is an example implementation in PHP:

First I'll generate some random data with known underlying distribution given by `\$a` and `\$b`

``````  // True parameter valaues
\$a = 10;
\$b = 5;

// Range of x values to generate
\$x_min = 1;
\$x_max = 10;
\$nPoints = 50;

// Generate some random points on y = a * log(x) + b
\$X = array();
\$Y = array();
for(\$p = 0; \$p < \$nPoints; \$p++){
\$x = \$p / \$nPoints * (\$x_max - \$x_min) + \$x_min;
\$y = \$a + \$b * log(\$x);

\$X[] = \$x + rand(0, 200) / (\$nPoints * \$x_max);
\$Y[] = \$y + rand(0, 200) / (\$nPoints * \$x_max);

}
``````

Now, here's how to use the equations given to estimate `\$a` and `\$b`.

``````  // Now convert to log-scale for X
\$logX = array_map('log', \$X);

// Now estimate \$a and \$b using equations from Math World
\$n = count(\$X);
\$square = create_function('\$x', 'return pow(\$x,2);');
\$x_squared = array_sum(array_map(\$square, \$logX));
\$xy = array_sum(array_map(create_function('\$x,\$y', 'return \$x*\$y;'), \$logX, \$Y));

\$bFit = (\$n * \$xy - array_sum(\$Y) * array_sum(\$logX)) /
(\$n * \$x_squared - pow(array_sum(\$logX), 2));

\$aFit = (array_sum(\$Y) - \$bFit * array_sum(\$logX)) / \$n;
``````

You may then generate points for your Javascript as densely as you like:

``````  \$Yfit = array();
foreach(\$X as \$x) {
\$Yfit[] = \$aFit + \$bFit * log(\$x);
}
``````

In this case, the code estimates `bFit = 5.17` and `aFit = 9.7`, which is quite close for only `50` data points.

For the example data given in the comment below, a logarithmic function does not fit well.

The least squares solution is `y = -514.734835478 + 2180.51562281 * log(x)` which is essentially a line in this domain.

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Alright, I'm off to the google races. I'll get back to you with what I find. –  Stephen May 4 '10 at 21:31
In theory, your updated comment makes sense. In practice? I'm a dunce at math. I looked at the two equations you mentioned and almost fainted. –  Stephen May 4 '10 at 21:54
Okay. Well, I did some more research into the problem and have written and tested some code that does this for you, and re-written my answer. Let me know if you have any questions. –  Geoff May 5 '10 at 15:06
That's awesome. This is exactly what I was looking for. I'm going to break down your code and try to learn what exactly is going on. I appreciate it. –  Stephen May 5 '10 at 17:03
I tried to implement your solution, but my y values are coming out way wrong the range of y values in my array of points is anywhere from 0 to 100. The trendline I'm coming up with has y values in the negative thousands. Here's the code: –  Stephen May 5 '10 at 18:05