The following code should do the trick. I used the following formula for the residuals:

```
residual[i] = (computed_x[i] - actual_x[i])^2
+ (computed_y[i] - actual_y[i])^2
```

And then derived the least-squares formulae based on the general procedure described at Wolfram's MathWorld.

I tested out this algorithm in Excel and it performs as expected. I Used a collection of ten random points which were then rotated, translated and scaled by a randomly generated transformation matrix.

With no random noise applied to the output data, this program produces four parameters (`P`

, `Q`

, `R`

, and `S`

) which are identical to the input parameters, and an `rSquared`

value of zero.

As more and more random noise is applied to the output points, the constants start to drift away from the correct values, and the `rSquared`

value increases accordingly.

Here is the code:

```
// test data
const int N = 1000;
float oldPoints_x[N] = { ... };
float oldPoints_y[N] = { ... };
float newPoints_x[N] = { ... };
float newPoints_y[N] = { ... };
// compute various sums and sums of products
// across the entire set of test data
float Ex = Sum(oldPoints_x, N);
float Ey = Sum(oldPoints_y, N);
float Exn = Sum(newPoints_x, N);
float Eyn = Sum(newPoints_y, N);
float Ex2 = SumProduct(oldPoints_x, oldPoints_x, N);
float Ey2 = SumProduct(oldPoints_y, oldPoints_y, N);
float Exxn = SumProduct(oldPoints_x, newPoints_x, N);
float Exyn = SumProduct(oldPoints_x, newPoints_y, N);
float Eyxn = SumProduct(oldPoints_y, newPoints_x, N);
float Eyyn = SumProduct(oldPoints_y, newPoints_y, N);
// compute the transformation constants
// using least-squares regression
float divisor = Ex*Ex + Ey*Ey - N*(Ex2 + Ey2);
float P = (Exn*Ex + Eyn*Ey - N*(Exxn + Eyyn))/divisor;
float Q = (Exn*Ey + Eyn*Ex + N*(Exyn - Eyxn))/divisor;
float R = (Exn - P*Ex - Q*Ey)/N;
float S = (Eyn - P*Ey + Q*Ex)/N;
// compute the rSquared error value
// low values represent a good fit
float rSquared = 0;
float x;
float y;
for (int i = 0; i < N; i++)
{
x = R + P*oldPoints_x[i] + Q*oldPoints_y[i];
y = S - Q*oldPoints_x[i] + P*oldPoints_y[i];
rSquared += (x - newPoints_x[i])^2;
rSquared += (y - newPoints_y[i])^2;
}
```

onlydo an exact solution, and there is no way to extract an error estimate... – dmckee Aug 7 '09 at 17:25