# Approximation of 2D-function with weight coefficients

I need to approximate a table-defined 2D-function like that

``````x0 y0
x1 y1
...
xn yn
``````

for every point I have a "weight" (root-mean-square error for this measure). I need to write a function like this:

``````typedef std::vector< double > DVector;
void approximate2D(
const DVector & x
, const DVector & y
, const DVector & weights
, double newMeasuredX
, double newMeasuredY
, double newMeasuredWeight
, double & outApproximatedX
, double & outApproximatedY
);
``````

to get one value ( outApproximatedX; outApproximatedY ) depend on previous values and new measured value.

Root-mean-square (RMS) error should be used as follows: if a RMS error is minimal, then desired function should go close to this point, if a RMS error is maximal, then this point should be use with a minimal contribution.

Approximation should be linear (I think), since I know, that desired function is a straight line.

Thank you.

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Do you know `std::vector` is actually a class template and so you need to provide atleast one type argument when you `typedef` it? –  Nawaz Mar 19 '11 at 12:49
Nawaz of course I know it. Just forgot. And... what's happening ? there is < double > in my post, but I have a copy of my post in clipboard - there is no type for vector... hmmm –  borisbn Mar 19 '11 at 13:37
I don't understand what it is you want the function to do. In a simple (or weighted) linear fit; what you want to calculate is the slope and offset of a line (`y = k x + m`), that passes as closely as possible to the given points. It doesn't make sense to return another point. –  Markus Jarderot Mar 19 '11 at 18:20
Check alglib alglib.net/interpolation/leastsquares.php –  belisarius Mar 19 '11 at 18:23

To minimize the total squared closest distances to the line a x + b y = r, you can't use matrix equations, since the problem is no longer linear.

The distance to the line can be defined as follows. Then the function you want to minimize is f(a,b,r). This task is simplified somewhat when a2 + b2 = 1.

If you expand that, it gets quite complex. I managed to break it down and simplify it somewhat.

To calculate this over many points (O(n2)) can get slow. There is however an easy optimization. Instead of calculating the sums over and over again, you can store partial results:

Here the σ variables are accumulators for common terms. Each time you want to add another point to the calculations, you update the 9 variables, and use those to calculate a, b and r as before.

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What you want is a space-filling-curve either a Hilbert-Curve or a Peano-Curve. A sfc is a good approximation of a 2D or XD grid.

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