# Complex matrix exponential in C++

Is it actually possible to calculate the Matrix Exponential of a Complex Matrix in c / c++?

I've managed to take the product of two complex matrices using blas functions from the GNU Science Library. for matC = matA * matB:

``````gsl_blas_zgemm (CblasNoTrans, CblasNoTrans, GSL_COMPLEX_ONE, matA, matB, GSL_COMPLEX_ZERO, matC);
``````

And I've managed to get the matrix exponential of a matrix by using the undocumented

``````gsl_linalg_exponential_ss(&m.matrix, &em.matrix, .01);
``````

But this doesn't seems to accept complex arguments.

Is there anyway to do this? I used to think c++ was capable of anything. Now I think its outdated and cryptic...

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See example at: guwi17.de/ublas/examples (the bottom of the page). –  Jerry Coffin Apr 6 '12 at 21:01
This problem has nothing to do with the C++ language itself, but with a GSL library, so don't dislike C++ for that :) Also, there are no tools capable of anything. –  Rafał Rawicki Apr 6 '12 at 21:02
Thanks Jerry, I'm now using the function given at the bottom of that page. It works, it's unfortunately a little slower than I would have like but it looks like I may just be able to take fewer sample points and run some interpolation (which is much quicker). Many thanks for pointing that out! –  Quantum_Oli Apr 10 '12 at 14:12

Several options:

1. modify the `gsl_linalg_exponential_ss` code to accept complex matrices

2. write your complex NxN matrix as real 2N x 2N matrix

3. Diagonalize the matrix, take the exponential of the eigenvalues, and rotate the matrix back to the original basis

4. Using the complex matrix product that is available, implement the matrix exponential according to it's definition: `exp(A) = sum_(n=0)^(n=infinity) A^n/(n!)`

You have to check which methods are appropriate for your problem.

C++ is a general purpose language. As mentioned above, if you need specific functionality you have to find a library that can do it or implement it yourself. Alternatively you could use software like MatLab and Mathematica. If that's too expensive there are open source alternatives, e.g. Sage and Octave.

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(2) wastes some memory, but is probably your best option, since (3) will only work if you know that your matrix is normal (AA^* = A^*A), (4) is not the best way to implement exponential (use exp(A / 2^n)^(2^n) = exp (A), find n such that the norm of A / 2^n is small and taylor expand exp (A/2^n) = B. Now compute B^(2^n) with n multiplications) –  Alexandre C. Feb 4 '13 at 20:32

"I used to think c++ was capable of anything" - if a general-purpose language has built-in complex math in its core, then something is wrong with that language.

Fur such very specific tasks there is a well-accepted solution: libraries. Either write your own, or much better, use an already existing one.

I myself rarely need complex matrices in C++, I always used Matlab and similar tools for that. However, this http://www.mathtools.net/C_C__/Mathematics/index.html might be of interest to you if you know Matlab.

There are a couple other libraries which might be of help:

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I was also thinking to do the same, writing your complex NxN matrix as real 2N x 2N matrix is the best way to solve the problem, then use `gsl_linalg_exponential_ss()`.

Suppose `A=Ar+i*Ai`, where `A` is the complex matrix and `Ar` and `Ai` are the real matrices. Then write the new matrix `B=[Ar Ai ;-Ai Ar]` (Here the matrix is written in matlab notation). Now calculate the exponential of `B`, that is `eB=[eB1 eB2 ;eB3 eB4]`, then exponential of `A` is given by, `eA=eB1+1i.*eB2`
(summing the matrices `eB1` and `1i.*eB2`).

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I have written a code to calculate the matrix exponential of the complex matrices with the gsl function, gsl_linalg_exponential_ss(&m.matrix, &em.matrix, .01); Here you have the complete code, and the compilation results. I have checked the result with the Matlab and result agrees.

``````#include <stdio.h>
#include <gsl/gsl_matrix.h>
#include <gsl/gsl_linalg.h>
#include <gsl/gsl_complex.h>
#include <gsl/gsl_complex_math.h>
void my_gsl_complex_matrix_exponential(gsl_matrix_complex *eA, gsl_matrix_complex *A, int dimx)
{
int j,k=0;
gsl_complex temp;
gsl_matrix *matreal =gsl_matrix_alloc(2*dimx,2*dimx);
gsl_matrix *expmatreal =gsl_matrix_alloc(2*dimx,2*dimx);
//Converting the complex matrix into real one using A=[Areal, Aimag;-Aimag,Areal]
for (j = 0; j < dimx;j++)
for (k = 0; k < dimx;k++)
{
temp=gsl_matrix_complex_get(A,j,k);
gsl_matrix_set(matreal,j,k,GSL_REAL(temp));
gsl_matrix_set(matreal,dimx+j,dimx+k,GSL_REAL(temp));
gsl_matrix_set(matreal,j,dimx+k,GSL_IMAG(temp));
gsl_matrix_set(matreal,dimx+j,k,-GSL_IMAG(temp));
}

gsl_linalg_exponential_ss(matreal,expmatreal,.01);

double realp;
double imagp;
for (j = 0; j < dimx;j++)
for (k = 0; k < dimx;k++)
{
realp=gsl_matrix_get(expmatreal,j,k);
imagp=gsl_matrix_get(expmatreal,j,dimx+k);
gsl_matrix_complex_set(eA,j,k,gsl_complex_rect(realp,imagp));
}
gsl_matrix_free(matreal);
gsl_matrix_free(expmatreal);
}

int main()
{
int dimx=4;
int i, j ;
gsl_matrix_complex *A = gsl_matrix_complex_alloc (dimx, dimx);
gsl_matrix_complex *eA = gsl_matrix_complex_alloc (dimx, dimx);

for (i = 0; i < dimx;i++)
{
for (j = 0; j < dimx;j++)
{
gsl_matrix_complex_set(A,i,j,gsl_complex_rect(i+j,i-j));
if ((i-j)>=0)
printf("%d+%di ",i+j,i-j);
else
printf("%d%di  ",i+j,i-j);

}
printf(";\n");
}
my_gsl_complex_matrix_exponential(eA,A,dimx);
printf("\n Printing the complex matrix exponential\n");
gsl_complex compnum;
for (i = 0; i < dimx;i++)
{
for (j = 0; j < dimx;j++)
{
compnum=gsl_matrix_complex_get(eA,i,j);
if (GSL_IMAG(compnum)>=0)
printf("%f+%fi\t ",GSL_REAL(compnum),GSL_IMAG(compnum));
else
printf("%f%fi\t ",GSL_REAL(compnum),GSL_IMAG(compnum));
}
printf("\n");
}
return(0);
}
``````
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