# Smartest way to apply matrix multiplication on a rolling window

This is a use-case that I encounter quite often, for example when I want to compute a spectrogram matrix. Given a fixed matrix M (FFT matrix) and a vector v (audio signal), compute the matrix N such that each column i of N is the product M * v.segment(i * window_hop, i * window_hop + window_size).

This can be easily implemented, since the size of N is known, by preallocating then iterating through the columns.

I feel like there is something smarter that can be done, namely constructing a matrix V where each column i of V is v.segment(i * window_hop, i * window_hop + window_size). Then N = M * V, no need for a for loop and everything can be parallelized smoothly (you can cut v into chunks if needed).

The bottom line of this method is the construction of V. Is there a way to construct V that is both fast and memory-efficient? (since V has a lot of repetitions if window_hop < window_size)

Is there an even better way to perform this calculation?

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sounds like a question for math.stackexchange.com, but from a programming perspective, it sounds like you could hack something to make the horizontal-step of a matrix equal to its own vertical-step. It could well play havoc with the existing optimisation code though. – Dave Jun 4 '14 at 21:19
It looks as if certain partial products can be re-used between windows, because many of the values are the same and they shift by some predictable delta. That is to say, when you are doing overlapping FFT's. – Kaz Jun 4 '14 at 22:26
Well, if we agree on the solution (compressing several matrix / vector multiplications into one matrix / matrix multiplication), what is the most efficient way to create a stacking of segments of v? Using a for loop? – Flavian Hautbois Jun 5 '14 at 14:59