# Optimization to find complex number as input

I am wondering if there is a C/C++ library or Matlab code technique to determine real and complex numbers using a minimization solver. Here is a code snippet showing what I would like to do. For example, suppose that I know `Utilde`, but not `x` and `U` variables. I want to use optimization (`fminsearch`) to determine `x` and `U`, given `Utilde`. Note that `Utilde` is a complex number.

``````x = 1.5;
U = 50 + 1i*25;
x0 = [1 20];  % starting values
Utilde = U * (1 / exp(2 * x)) * exp( 1i * 2 * x);
xout = fminsearch(@(v)optim(v, Utilde), x0);

function diff = optim(v, Utilde)
x = v(1);
U = v(2);
diff =  abs( -(Utilde/U) + (1 / exp(2 * x)) * exp( 1i * 2 * x  ) );
``````

The code above does not converge to the proper values, and `xout = 1.7318 88.8760`. However, if `U = 50`, which is not a complex number, then `xout = 1.5000 50.0000`, which are the proper values.

Is there a way in Matlab or C/C++ to ensure proper convergence, given `Utilde` as a complex number? Maybe I have to change the code above?

• If there isn't a way to do this natively in Matlab, then perhaps one gist of the question is this: Is there a multivariate (i.e. Nelder-Mead or similar algorithm) optimization library that is able to work with real and complex inputs and outputs?

• Yet another question is whether the function is convergent or not. I don't know if it is the algorithm or the function. Might I need to change something in the `Utilde = U * (1 / exp(2 * x)) * exp( 1i * 2 * x)` expression to make it convergent?

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From my experience: using these built-in minimization procedures often gives you more headaches than it helps. If you definitely need to do it this way, I would stick to Python - with MATLAB it will probably not be better. – Michael Schlottke-Lakemper Jul 13 '12 at 17:16
Sure - what is the best way in Python to set up this optimization problem? Is there a tool for Python that can optimize using complex numbers? – Nicholas Kinar Jul 13 '12 at 23:06
@NicholasKinar I am a little bit uncertain about the arithmetic rules for complex numbers right now, but if you only want to retrieve the topmost `x` and `U` values in the optimization, would it not be more appropriate to specify `diff` as `diff = abs( Utilde - U * (1 / exp(2 * x)) * exp( 1i * 2 * x ) )`? Or better still from a differentiation point of view the difference squared instead of the absolute difference? – Anders Gustafsson Jul 24 '12 at 21:07
@AndersGustafsson: Thanks for your comment. Hmm...I tried this, and I still can't reach convergence for all `x` and `U`. For example, `x = 7` and `U = 10`. Maybe I am doing something wrong. – Nicholas Kinar Jul 25 '12 at 0:32
@NicholasKinar I have looked a little further at this problem and provided an answer. Please have a look to see if you agree. – Anders Gustafsson Jul 31 '12 at 7:33

The main problem here is that there is no unique solution to this optimization or parameter fitting problem. For example, looking at the expected and actual results above, `Utilde` is equivalent (ignoring round-off differences) for the two (`x`, `U`) pairs, i.e.

``````Utilde(x = 1.5, U = 50 + 25i) = Utilde(x = 1.7318, U = 88.8760)
``````

Although I have not examined it in depth, I even suspect that for any value of `x`, you can find an `U` that computes to `Utilde(x, U) = Utilde(x = 1.5, U = 50 + 25i)`.

The solution here would thus be to further constrain the parameter fitting problem so that the solver yields any solution that can be considered acceptable. Alternatively, reformulate `Utilde` to have a unique value for any (`x`, `U`) pair.

UPDATE, AUG 1

Given reasonable starting values, it actually seems like it is sufficient to restrict `x` to be real-valued. Performing unconstrained non-linear optimization using the `diff` function formulated above, I get the following result:

``````x = 1.50462926953244
U = 50.6977768845879 + 24.7676554234729i
diff = 3.18731710515855E-06
``````

However, changing the starting guess to values more distant from the desired values does yield different solutions, so restricting `x` to be real-values does not alone provide a unique solution to the problem.

I have implemented this in C#, using the BOBYQA optimizer, but the numerics should be the same as above. If you want to try outside of Matlab, it should also be relatively simple to turn the C# code below into C++ code using the std::complex class and an (unconstrained) nonlinear C++ optimizer of your own choice. You could find some C++ compatible codes that do not require gradient computation here, and there is also various implementations available in Numerical Recipes. For example, you could access the C version of NR online here.

For reference, here are the relevant parts of my C# code:

``````class Program
{
private static readonly Complex Coeff = new Complex(-2.0, 2.0);
private static readonly Complex UTilde0 = GetUTilde(1.5, new Complex(50.0, 25.0));

static void Main(string[] args)
{
double[] vars = new[] {1.0, 25.0, 0.0}; // xstart = 1.0, Ustart = 25.0
BobyqaExitStatus status = Bobyqa.FindMinimum(GetObjfnValue, vars.Length, vars);
}

public static Complex GetUTilde(double x, Complex U)
{
return U * Complex.Exp(Coeff * x);
}

public static double GetObjfnValue(int n, double[] vars)
{
double x = vars[0];
Complex U = new Complex(vars[1], vars[2]);
return Complex.Abs(-UTilde0 / U + Complex.Exp(Coeff * x));
}
}
``````
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Thanks for your insightful answer. How might I reformulate `Utilde` to have a unique value for any `(x, U)` pair? – Nicholas Kinar Jul 31 '12 at 13:57
@NicholasKinar What is `Utilde` meant to represent? Can you link to some context where this is illustrated? – Anders Gustafsson Jul 31 '12 at 14:07
Utilde (as a complex number) is the output of a product of two numbers in the frequency domain. The `(1 / exp(2 * x)) * exp( 1i * 2 * x)` is the filter kernel, and the `U` is a Gabor transformed signal. This is a seismic Q filtering application, and there is a similar equation on pg. 128 of the book Seismic Inverse Q filtering: scribd.com/doc/45448335/SEISMIC-INVERSE-q-FILTERING. Could you suggest a good reference book on this type of optimization problem? Maybe if `U` is unknown, this is a blind deconvolution problem? – Nicholas Kinar Jul 31 '12 at 14:46
@NicholasKinar Please see my encouraging :-) update to this answer. – Anders Gustafsson Aug 1 '12 at 14:47
Thanks, Anders; this is very much appreciated. Thank you for giving me an excellent framework and code for this problem. I will experiment with the exponential function argument a little bit more and then get back to you. – Nicholas Kinar Aug 1 '12 at 16:19

The documentation for `fminsearch` says how to deal with complex numbers in the limitations section:

`fminsearch` only minimizes over the real numbers, that is, `x` must only consist of real numbers and `f(x)` must only return real numbers. When `x` has complex variables, they must be split into real and imaginary parts.

You can use the functions `real` and `imag` to extract the real and imaginary parts, respectively.

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Actually, this probably doesn't help here since your function returns a complex output for a real input. If your function were real-valued, though, then I think that this method would work. – zroth Jul 13 '12 at 17:40
Isn't the `diff` variable always real since this is the absolute value of a complex number? If this is the case, then how do I split into real and imaginary parts? – Nicholas Kinar Jul 13 '12 at 23:04
@NicholasKinar You're right. Your function seems to take real inputs and be real-valued. Why do you say that `fminsearch` isn't converging properly with complex `Utilde`? Did you find the minimum analytically? – zroth Jul 20 '12 at 18:32
Hmm, I don't know if this is a problem with the function, or if there is another issue here. I will investigate. – Nicholas Kinar Jul 21 '12 at 18:54

It appears that there is no easy way to do this, even if both `x` and `U` are real numbers. The equation for `Utilde` is not well-posed for an optimization problem, and so it must be modified.

I've tried to code up my own version of the Nelder-Mead optimization algorithm, as well as tried Powell's method. Neither seem to work well for this problem, even when I attempted to modify these methods.

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