# algorithm for the inverse of a 2d bijective function

I want to write a function f_1(a,b) = (x,y) that approximates the inverse of f, where f(x,y) = (a,b) is a bijective function (over a specific range)

Any suggestions on how to get an efficient numerical approximation?

The programming language used is not important.

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If your function is well behaved, you can approximate the inverse iteratively using a root finding method. Here's some inspiration in the 1-d case math.uiuc.edu/~jared/Math341/iteration.pdf. Secant method can work (slower) if you don't have access to derivatives. –  A. Webb Nov 14 '12 at 3:14

There is no 'automatic' solution that wil work for any general function. Even in the simpler case of y = f(x) it can be hard to find a suitable starting point. As an example:

``````y = x^2
``````

has a nice algebraic inverse

``````x = sqrt(y)
``````

but trying to approximate the sqrt function in the range [0..1] with a polynomial (for instance) sucks badly.

If your range is small enough, and your function well behaved enough, then you might get a fit using 2D splines. If this is going to work, then you should try using independant functions for x and y, i.e. use

``````y = Y_1(a,b)  and x = X_1(a,b)
``````

rather than the more complicated

``````(x,y) = F_1(a,b)
``````
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Solving `f(x,y)=(a,b)` for x,y is equivalent to finding the root or minimum of `f(x,y)-(a,b)` ( = 0) so you can use any of the standard root finding or optimization algorithms. If you are implementing this yourself, I recommend Coordinate descent because it is probably the most simple algorithm. You could also try Adaptive coordinate descent although that may be a bit harder to analyze.