Hi Ali,
The acos and (m dot n) approach is not a good way to go about this at all. It's inaccurate when n is almost equal to -m as you have. It seems like a good idea to normalize m and n, so assume that has been done. Then
m.n = cos(alpha) alpha = acos(m.n)
and alpha is very close to -pi. Let
where theta is small, and is the amount by which alpha falls short of -pi.
Define q = -n so that m and q are amost identical. Then a much better method, which treats small differences in linear fashion, shows that
In your case
Details:
First of all, consider
m.n = cos(alpha) alpha = acos(m.n),
Since m.n is almost exactly -1, alpha is almost exactly - pi. But if you take a look at acos, acos(arg) is a rapidly varying function of its argument when that argument is close to -1 or 1. And at -1 or 1, acosh has infinite slope. So a small change in arg leads to a resulting angle that can easily be off.
Now it's easy to show that
m.(-n) = cos(-pi + alpha)
Let
where theta is small. Also so define a new vector q = -n, so q and m are almost identical. Then
m.q = cos(theta) theta = acos(m.q)
This does not help yet, because here the argument of acos is almost 1, and acos has the same problem as before. But now you have the small quantity
available as the third side of a triangle whose other two sides have length 1 and angle theta between them. So
|d| = 2*sin(theta/2) theta = 2*asin(|d|/2)
asin for small argument is basically linear and has no issues like acos does. For very small |d|,
