# Fast matrix exponential of a complex symmetric tridiagonal matrix

Basically I need the above. I have trawled the Googles and cannot find a way of implementing this.

I've found this function here http://www.guwi17.de/ublas/examples/ but it is too slow. I even wrote my own Pade Approximation following MATLAB's routine but it was only fractionally faster than the one in the link.

What stuns me is how quick Mathematica is able to compute matrix exponentials (whether it cares if the matrix is tridiag I don't know).

Is anyone able to help?

EDIT: Here's what I've come up with, any comments? Will hopefully be useful for future readers

I've been out of c++ for a while so the below code may be a bit scrappy / slow, so please enlighten me if you see improvements.

``````//Program will compute the matrix exponential expm( i gA ). where i = sqrt(-1) and gA is a matrix

#include <iostream>
#include <gsl/gsl_complex.h>
#include <gsl/gsl_complex_math.h>
#include <gsl/gsl_matrix.h>
#include <gsl/gsl_linalg.h>
#include <gsl/gsl_blas.h>

int main() {

int n = 100;

unsigned i = 0;
unsigned j = 0;

gsl_complex img = gsl_complex_rect (0.,1.);

gsl_matrix * gA = gsl_matrix_alloc (n, n);

//Set gA:
for ( i = 0; i<n; i++) {
for ( j = 0; j<=i; j++) {
if( i == j ) {
if( i == 0 || i == n-1 ) {
gsl_matrix_set (gA, i, j, 1.);
} else {
gsl_matrix_set (gA, i, j, 2.);
}
} else if( j == i-1 ) {
gsl_matrix_set (gA, i, j, 1.);
gsl_matrix_set (gA, j, i, 1.);
} else {
gsl_matrix_set (gA, i, j, 0.);
gsl_matrix_set (gA, j, i, 0.);
}
}
}

//get SVD of gA
gsl_matrix * gA_t = gsl_matrix_alloc (n, n);
gsl_matrix_transpose_memcpy (gA_t, gA);

gsl_matrix * U = gsl_matrix_alloc (n, n);
gsl_matrix * V= gsl_matrix_alloc (n, n);
gsl_vector * S = gsl_vector_alloc (n);

gsl_vector * work = gsl_vector_alloc (n);
gsl_linalg_SV_decomp (gA_t, V, S, work);
gsl_vector_free(work);

gsl_matrix_memcpy (U, gA_t);

//Take exponential of S and form matrix
gsl_matrix_complex * Sp = gsl_matrix_complex_alloc (n, n);
gsl_matrix_complex_set_zero (Sp);
for (i = 0; i < n; i++) {
gsl_matrix_complex_set (Sp, i, i, gsl_complex_exp ( gsl_complex_mul_real ( img, gsl_vector_get(S, i) ) ) ); // Vector 'S' to matrix 'Sp'
}

gsl_matrix_complex * Uc = gsl_matrix_complex_alloc (n, n);

//convert U to a complex matrix for next step
for (i = 0; i < n; i++) {
for ( j = 0; j<n; j++) {
gsl_matrix_complex_set (Uc, i, j, gsl_complex_rect ( gsl_matrix_get(U, i, j), 0. ) );
}
}

//recombine U S Utranspose
gsl_matrix_complex * tA = gsl_matrix_complex_alloc (n, n);
gsl_matrix_complex * eA = gsl_matrix_complex_alloc (n, n);
gsl_blas_zgemm (CblasNoTrans, CblasNoTrans, GSL_COMPLEX_ONE, Uc, Sp, GSL_COMPLEX_ZERO, tA);
gsl_blas_zgemm (CblasNoTrans, CblasTrans, GSL_COMPLEX_ONE, tA, Uc, GSL_COMPLEX_ZERO, eA);

//Print result
std::cout << "eA:" << std::endl;
for (i = 0; i < n; i++)
for (j = 0; j < n; j++)
printf ("%g + %g i\n", GSL_REAL(gsl_matrix_complex_get (eA, i, j)), GSL_IMAG(gsl_matrix_complex_get (eA, i, j)));
std::cout << "\n" << std::endl;

//Free up
gsl_matrix_free(gA_t);
gsl_matrix_free(U);
gsl_matrix_free(gA);
gsl_matrix_free(V);
gsl_vector_free(S);
gsl_matrix_complex_free(Uc);
gsl_matrix_complex_free(tA);
gsl_matrix_complex_free(eA);

return 0;
}
``````
-
Do you need just one exponential, or many with different multipliers? In the latter case it's advisable to diagonalise the matrix, possibly Mathematica does this automatically. –  leftaroundabout Apr 12 '12 at 13:49
Many with different multiplies. I have a real tridiagonal matrix U and need to compute expm( i z U) where i = sqrt(-1) for many values of z. If you recommend diagonalizing the matrix can you recommend a fast c++ library for doing so? –  Quantum_Oli Apr 12 '12 at 15:01
That's what I thought. I personally use CULA for this, which is specialized for Nvidia GPUs. GSL also has decent algorithms, should work quite well. Both are rather low-level, however – no nice C++ interface. –  leftaroundabout Apr 12 '12 at 15:20
I've diagonalized! See above. Its around 100x faster than the function using the Pade method given in my link. This should be fast enough for my means. Also I only have to do the decomposition once. Thanks for your help. –  Quantum_Oli Apr 12 '12 at 19:25