# I have a function f(w,x,y,z) and a target value A, how can I discover values for w,x,y,z that produce A?

So I have a function that takes four numerical arguments and produces a numerical argument.

``````f(w,x,y,z) --> A
``````

If I have the function `f` and a target result `A`, is there an iterative method for discovering parameters `w,x,y,z` that produce a given number `A`?

If it helps, my function `f` is a quintic bezier where most of the parameters are determined. I have isolated just these four that are required to fit the value `A`.

``````Q(t)=R(1−t)^5+5S(1−t)^4*t+10T(1−t)^3*t^2+10U(1−t)^2*t^3+5V(1−t)t^4+Wt^5
``````

`R,S,T,U,V,W` are vectors where `R` and `W` are known, I have isolated only a single element in each of `S,T,U,V` that vary as parameters.

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It largely depends on the function itself - in the most general case, you'll have to iterate over every possible tuple of `(w,x,y,z)` –  Drew McGowen Aug 1 '13 at 18:56
There's not enough information here. This will depend on what your function F does. You will likely also need to set an upper bound limit. You will probably want to approach this algorithmically, rather than brute-forcing iteratively too. –  multiphrenic Aug 1 '13 at 18:57
Well, the function is a quintic bezier where I have isolated these four elements of the six vectors that are allowed to vary. I added more information. –  prismofeverything Aug 1 '13 at 18:57
@multiphrenic Right, I am looking for an algorithm. –  prismofeverything Aug 1 '13 at 19:03
I'm not knowledgeable enough to tell you anything specific to a quintic bezier, but you might want to look at the standard optimizations functions available in a package like `SciPy`, or just at black-box search algorithms (BBSAs) in general. They solve a superset of your problem, but they should work. –  Ryan Marcus Aug 1 '13 at 19:13

The set of solutions of the equation `f(w,x,y,z)=A` (where all of `w`, `x`, `y`, `z` and `A` are scalars) is, in general, a 3 dimensional manifold (surface) in the 4-dimensional space `R^4` of `(w,x,y,z)`. I.e., the solution is massively non-unique.

Now, if `f` is simple enough for you to compute its derivative, you can use the Newton's method to find a root: the gradient is the direction of the fastest change of the function, so you go there.

Specifically, let `X_0=(w_0,x_0,y_0,z_0)` be your initial approximation of a solution and let `G=f'(X_0)` be the gradient at `X_0`. Then `f(X_0+h)=f(X_0)+(G,h)+O(|h|^2)` (where `(a,b)` is the dot product). Let `h=a*G`, and solve `A=f(X_0)+a*|G|^2` to get `a=(A-f(X_0))/|G|^2` (if `G=0`, change `X_0`) and `X_1=X_0+a*G`. If `f(X_1)` is close enough to `A`, you are done, otherwise proceed to compute `f'(X_1)` &c.

If you cannot compute `f'`, you can play with many other methods.

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Can you elaborate how to use Newton's method to solve a multi-variate system of equations where there are more variables than equations? –  user2566092 Aug 1 '13 at 19:59
@user2566092: edited. –  sds Aug 1 '13 at 20:17

If you can impose 3 (or more) additional equations that you know (or suspect) must be true for your 4-variable solution that gives target value `A`, then you can try applying Newton's method for solving a system of k equations with k unknowns. Otherwise, without a deeper understanding of the structure of the function you are trying to make equal to `A`, the only general type of technique I'm aware of that's easy to implement is to simply define the error function as `g(w,x,y,z) = |f(w,x,y,z) - A|` and search for a minimum of `g`. Typically the "minimum" found will be a local minimum, so it may require many restarts of the minimization problem with different starting values for your parameters to actually find a solution that gives a local minimum you want of `g = 0`. This is very easy to implement and try in a few lines e.g. in MATLAB using `fminsearch`

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