The O(n log n) algorithm for the product of a Toeplitz matrix and a vector of the correct length is well-known: put it in a circulant matrix, multiply it by the vector (and subsequent zeroes), and return the top n elements of the product.

I'm finding trouble finding the best (time-wise) algorithm for multiplying two Toeplitz matrices of the same size.

Can anyone give me an algorithm for this?

  • The product of Toeplitz matrices is not necessarily Toeplitz. How is the output to be represented? – David Eisenstat Apr 8 '13 at 23:27
  • As an nxn matrix, seeing as there's no other representation that would display all the relevant data in this case. I'm not asking for an algorithm that runs faster than O(n^2), I am merely wondering if there is a faster algorithm than the standard matrix multiplication routine in this case. – Govind Parmar Apr 9 '13 at 2:13
  • Note that the product of two circulant matrices is circulant. I wonder if there's a algorithm faster than O(n^2) to calculate the product of two circulant matrices, both expressed as vectors. – nneonneo Apr 9 '13 at 2:55
  • @nneonneo There's an O(n log n)-time algorithm -- multiply the first matrix by one row of the second and take n different rotations. – David Eisenstat Apr 9 '13 at 12:25

Here's an O(n^2)-time algorithm.

To compute one of the diagonals of the product matrix, we need to compute dot products over length-n windows of length-(2n-1) lists that are sliding in lockstep. The difference between two successive entries can be computed in time O(1).

For example, consider the product of

e f g h i    o p q r s
d e f g h    m o p q r
c d e f g    l m o p q
b c d e f    k l m o p
a b c d e    j k l m o

The 1,1 entry is eo + fm + gl + hk + ij. The 2,2 entry is dp + eo + fm + gl + hk, or the 1,1 entry minus ij plus dp. The 3,3 entry is cq + dp + eo + fm + gl, or the 2,2 entry minus hk plus cq. The 4,4 entry is br + cq + dp + eo + fm, etc.

If you implement this in floating point, be mindful of catastrophic cancellation.

  • Can you please expand on this? I don't understand what you mean by sliding in lock step, but I do see the pattern you're trying to show. – Jonathan Oct 13 '18 at 9:31
  • 1
    @Jonathan I guess another way to say it is that we can multiply the lists pointwise and then the elements of the diagonal are sums of n consecutive elements of the products list. – David Eisenstat Oct 13 '18 at 13:25
  • Is there a way to mathematically represent that? – Jonathan Oct 16 '18 at 3:08
  • @Jonathan Convolution with an all-ones vector? – David Eisenstat Oct 18 '18 at 12:35

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