# How to numerically calculate value of complex function given derivative of this function in Haskell?

Given:

2. Complex-valued function `df/dz` defined on complex plane `U` (let's say `z` is a `Complex Double`).
3. Point `z1` from the `U` on which `df/dz` is defined.

Question:

How to get value of function `f(z)` for which `df/dz` is a derivative, in point `z1`? I. e. how to restore value of original function given only it's derivative, assuming complex plane?

This question is somewhat related to my previous question about calculating integrals of complex functions, but they are about different things. Here I am interested not in calculating some scalar value, but in finding the origin function given it's derivative. It's essentially calculating the indefinite integral of this derivative.

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You can't do that. The derivative of a function doesn't uniquely determine the function. The is the same as doing integration, so there'll be at least a constant you don't know. –  augustss Jun 12 '13 at 7:01
Do you want a numerical or symbolic approach? I.e. is `df/dz` always some expression involving plus, times, exponents, sine, ... etc., or do you have e.g. some numerical data? Unfortunately, both cases are rather hard... –  luqui Jun 12 '13 at 7:42
OMG, @augustss thank you so much, I totally don't know how I would forget this basic math problem... (facepalm) However, I still need to solve this problem at least partially. I can infer missing C using some additional constraints to original problem (so initial data will be not just `df/dz` but also some set of constraints). –  hijarian Jun 12 '13 at 8:45
@luqui I need just a numerical solution, even if analytical representation of origin function would be absolutely great, just a value of `f(x)` is enough. –  hijarian Jun 12 '13 at 8:46

You can use some numeric solver like Runge-Kutta

``````-- define 4th order Runge-Kutta map (RK4)
rk4 :: Floating a => (a -> a) -> a -> a -> a
rk4 f h x = x + (1/6) * (k1 + 2*k2 + 2*k3 + k4)
where k1 = h * f (x)
k2 = h * f (x + 0.5*k1)
k3 = h * f (x + 0.5*k2)
k4 = h * f (x + k3)
``````

in that case function signature is `Floating` but you can use `RealFloat` instead (you can use runge-kutta in complex).

Complete example:

``````Prelude> import Data.Complex
Prelude Data.Complex> let rk4 f h x = x + (1/6) * (k1 + 2*k2 + 2*k3 + k4) where {k1 = h * f(x);k2 = h * f (x + 0.5*k1);k3 = h * f (x + 0.5*k2);k4 = h * f (x + k3)}
Prelude Data.Complex> let f z = 2 * z
Prelude Data.Complex> rk4 f (0.1 :+ 0.2) (0.3 :+ 1.2)
(-0.2334199999999999) :+ 1.4925599999999999
Prelude Data.Complex>
``````

On the other hand, @leftaroundabout suggest extend that behavior to `VectorSpace` (great! of course! :D )

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In fact, it could be quite a lot more general than `Floating` yet, `VectorSpace` is what I'd go for. –  leftaroundabout Jun 12 '13 at 8:24
I think I'll need a lot more math&haskell background to understand the necessity in `VectorSpace`, but nevertheless the Runge-Kutta solution using `RealFloat` seems to be what I want. :) –  hijarian Jun 12 '13 at 9:01
@hijarian: there's no necessity to use `VectorSpace`, it just allows using the algorithm for much more complicated problems. (And the standard `RealFloat` types are instances of `VectorSpace` already, namely ℝ). –  leftaroundabout Jun 12 '13 at 9:58
Why RK? Why not explicit Euler for example? For that matter RK4 may not be appropriate depending on your application. –  idontgetoutmuch Jun 29 '13 at 12:56
@DominicSteinitz, yes you can use another one method :) –  josejuan Jun 29 '13 at 17:10