The nice thing about R is that you can often dig into the functions and see for yourself what is going on. If you type
cosine (without any parentheses, arguments, etc.) then R prints out the body of the function. Poking through it (which takes some practice), you can see that there is a bunch of machinery for computing the pairwise similarities of the columns of the matrix (i.e., the bit wrapped in the
if (is.matrix(x) && is.null(y)) condition, but the key line of the function is
crossprod(x, y)/sqrt(crossprod(x) * crossprod(y))
Let's pull this out and apply it to your example:
So, you're using vectors that are already normalized, so you just have
crossprod to look at. In your case this is equivalent to
(for real matrix operations,
crossprod is much more efficient than constructing the equivalent operation by hand).
As @Jack Maney's answer says, the dot product of two vectors (which is length(a)*length(b)*cos(a,b)) can be negative ...
For what it's worth, I suspect that the
cosine function in
lsa might be more easily/efficiently implemented for matrix arguments as
edit: in comments on a now-deleted answer below, I suggested that the square of the cosine-distance measure might be appropriate if one wants a similarity measure on [0,1] -- this would be analogous to using the coefficient of determination (r^2) rather than the correlation coefficient (r) -- but that it might also be worth going back and thinking more carefully about the purpose/meaning of the similarity measures to be used ...