Is there any faster method of matrix exponentiation to calculate M^n ( where M is a matrix and n is an integer ) than the simple divide and conquer algorithm.

You could factor the matrix into eigenvalues and eigenvectors. Then you get
Where V is the eigenvector matrix and D is a diagonal matrix. To raise this to the Nth power, you get something like:
Because all the V and V^1 terms cancel. Since D is diagonal, you just have to raise a bunch of (real) numbers to the nth power, rather than full matrices. You can do that in logarithmic time in n. Calculating eigenvalues and eigenvectors is r^3 (where r is the number of rows/columns of M). Depending on the relative sizes of r and n, this might be faster or not. 


Exponentiation by squaring is frequently used to get high powers of matrices. 


I would recommend approach used to calculate Fibbonacci sequence in matrix form. AFAIK, its efficiency is O(log(n)). 


It's quite simple to use Euler fast power algorith. Use next algorith.
Below please find equivalent for numbers:


