What is the best way to calculate sum of matrices such as A^i + A^(i+1) + A^i+2........A^n for very large n?

I have thought of two possible ways:

1) Use logarithmic matrix exponentiation(LME) for A^i, then calculate the subsequent matrices by multiplying by A.

Problem: Doesn't really take advantage of the LME algorithm as i am using it only for the lowest power!!

2)Use LME for finding A^n and memoize the intermediate calculations.

Problem: Too much space required for large n.

Is there a third way?


Notice that:

A + A^2 = A(I + A)
A + A^2 + A^3 = A(I + A) + A^3
A + A^2 + A^3 + A^4 = (A + A^2)(I + A^2)
                    = A(I + A)(I + A^2)


B(n) = A + ... + A^n

We have:

B(1) = A
B(n) = B(n / 2) * (I + A^(n / 2)) if n is even
B(n) = B(n / 2) * (I + A^(n / 2)) + A^n if n is odd

So you will be doing a logarithmic number of steps and there is no need to compute inverses.

While a direct implementation will lead to a (log n)^2 factor, you can keep it at log n by computing the powers of A as you compute B.

  • Calculating the inverse is about O(m^2.4) where m is the size of the matrix. Multiplication cost is O(m^2.4) too, and you are doing way more multiplication then I do. The only advantage of this approach is it works even if you can't invert I-A, but I'm quite sure that it's worth checking first if you can invert it, and if so use my solution. – Save Sep 19 '13 at 9:50
  • @Save - finding the inverse is also significantly more difficult to implement correctly. Even checking if it exists requires computing the determinant, which is not a trivial problem. – IVlad Sep 19 '13 at 9:52
  • There are tons of libraries to do taht for you. And a trivial implementation of both multiplication and inversion costs O(n^3) and it's quite easy to do (Gaussian Elimination), so, again, I'd suggest about checking first and then decide the method. – Save Sep 19 '13 at 9:54
  • It might work, but inverses will require floating point numbers. Consider that you might not get exact results. – IVlad Sep 19 '13 at 9:57
  • 1
    @fresidue - The complexity is O(m^3 * log n) if using the naive matrix multiplication and O(m^2.4 * log n) using the optimal multiplication algorithm. As long as the matrices are small enough, this is going to be very efficient, regardless of how large n is. – IVlad Sep 19 '13 at 11:02

You can use the fact that the sum to n of a geometric series of matrices equals:

S_n = (I-A)^(-1) (I-A^n)

and, since you don't start from 0, you can simply calculate:

result = S_n - S_i

where i is your starting index.

  • 1
    just be carefull, because I-A doesn't always have an inverse – Save Sep 19 '13 at 9:38
  • This is not ideal because it requires computing the inverse, which is difficult for large matrices and it might not even exist. – IVlad Sep 19 '13 at 9:39
  • don't worry my matrix is small – ishan3243 Sep 19 '13 at 9:40
  • @IVlad see my comment to your reply, about the cost of multiplication and inversion – Save Sep 19 '13 at 9:52

Why not just diagonalize the matrix to make the multiplication cheap.


As long as the matrix is nonsingular you should be able to find a diagonal representation D of matrix A such that A = PDP^-1 where P is made up of the eigenvectors of A, and D has the eigenvalues of A along the diagonal. Getting D^m = D*D^(m-1) is cheap since it's you're only multiplying along the diagonal (i.e. the same number of multiplications as the dimension of the matrix)

Getting S(m)=S(m-1)+D^m is also cheap since you're only adding diagonal elements.

Then you have

A^i + A^(i+1) + A^i+2........A^n = P(D^i + D^(i+1) + D^i+2........D^n)P^-1 = P( S(n) - S(i) )P^-1

The only difficult thing is finding P and P^-1

  • 1
    Not every matrix is diagonalizable. Try matrix ((a,1),(0,a)) for any a. – Michael Sep 19 '13 at 16:03

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