If a sliding window would work, you're probably doing a cross-correlation, in which case you can use FFTs to solve your problem faster by a factor of O(n/log(n)).

So if you have a vector V, and a corpus of C other vectors, and all vectors are size N, then the sliding window solution would take O(N^2 * C) time. By using FFTs you can reduce a single sliding window from O(N^2) to O(N log N), so the total time would be O(CN log N).

If you aren't familiar with FFTs then you will probably need to read up on them before using them, but the general idea is this:

```
# If you forget to take the complex conjugate of V you'll be doing a
# convolution instead of a correlation
V' := Fft(Conjugate(V))
for each vector W in C:
W' := Fft(W)
P := W' * V' # Multiplication here is the dot product
R := inverse_Fft(P)
# Check through the vector R for any spikes, a large value at
# R[i] indicates that if you shift W' by i then it will
# correlate strongly with W
```

Caveats:

1) If you're doing correlations at all you'll need to normalize your vectors, or at least do something to make sure you don't get false positives from vectors whose values are just larger and more positive than other vectors. If yours is a typical use case of looking for a signal in noise, though, then you're fine.

2) FFTs correlate under the assumption that all of these signals are circular. If you don't want to treat them like they're circular then you need to add a buffer of 0's to the end of each vector to double its length.