If you are certain the `xy`

data describe a straight line, you'd do the following.

Finding the best fitting straight line equals solving the over-determined linear system `Ax = b`

in a least-squares sense, where

```
xy = [
308 522
307 523
307 523
307 523
307 523
307 523
306 523];
x_vals = xy(:,1);
y_vals = xy(:,2);
A = [x_vals ones(size(x_vals))];
b = y_vals;
```

This can be done in Matlab like so:

```
sol = A\b;
m = sol(1);
c = sol(2);
```

What we've done now is find the values for `m`

and `c`

so that the line described by the equation `y = mx+c`

best-fits the data you've given. This best-fit line is not perfect, so it has errors w.r.t. the y-data:

```
errs = (m*x_vals + c) - y_vals;
```

The standard deviation of these errors can be computed like so:

```
>> std(errs)
ans =
0.2440
```

If you want to use the perpendicular distance to the line (Euclidian distance), you'll have to include a geometric factor:

```
errs = (m*x_vals + c) - y;
errs_perpendicular = errs * cos(atan(m));
```

Using trig identities this can be reworked to

```
errs_perpendicular = errs * 1/sqrt(1+m*m);
```

and of course,

```
>> std(errs_perpendicular)
ans =
0.2182
```

If you are not certain that a straight line fits through the data and/or your `xy`

data essentially describe a point cloud around some common centre, you'd do the following.

Find the center of mass (`COM`

):

```
COM = mean(xy);
```

the distances of all points to the `COM`

:

```
dists = sqrt(sum(bsxfun(@minus, COM, xy).^2,2));
```

and the standard deviation thereof:

```
>> std(dists)
ans =
0.5059
```