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:

```
> crossprod(a,b)/sqrt(crossprod(a)*crossprod(b))
[,1]
[1,] -0.05397935
> crossprod(a)
[,1]
[1,] 1
> crossprod(b)
[,1]
[1,] 1
```

So, you're using vectors that are already normalized, so you just have `crossprod`

to look at. In your case this is equivalent to

```
> sum(a*b)
[1] -0.05397935
```

(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 `as.dist(crossprod(x))`

...

**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 ...