# Simplest way to find any vector with a different direction

What is the simplest way to take an input vector, given as (x,y,z), and find some new vector with a different direction than it? Any direction will do, it just has to be a different direction than the input (other than exact opposite direction, which is trivial).

It seems like there should be a simple solution that does not involve branching, but I can't seem to find one, and after some though, I'm interested to know if there actually is one.

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any vector that is not in the form of a*(x,y,z) will do –  chaohuang Sep 3 '12 at 4:40
well, to be more specific, I want a way to find one of those vectors which is not in that form, by using some function of the input vector. –  Stravant Rae Sep 3 '12 at 4:44

I'm not sure how simple this is, but assuming that (x,y,z) has length L (which is not 0) the vector below has length 1 and is at right angles to (x,y,z)

``````-y * (x + sign(x)*L) / (L*(L+|x|))
1 - y * y / (L*(L+|x|))
-y * z / (L*(L+|x|))
``````

(here |x| is the absolute value of x and sign(x) is -1 if x<0, and 1 if x >= 0)

I derived this formula by computing the householder reflection ( eg http://en.wikipedia.org/wiki/Householder_transformation) that maps (x,y,z) to a multiple of (1,0,0) and then computing the image of (0,1,0) under this matrix; since the matrix is both orthogonal and symmetric this vector will be orthogonal to (x,y,z).

There is no continuous function (x,y,z) -> (x',y',z') (for (x,y,z) != (0,0,0)) such that (x',y',z') is never a multiple of (x,y,z); if there were you could remove from (x',y',z') its component in the (x,y,z) direction and so get a continuous map (x,y,z)->(x'',y'',z'') where (x'',y'',z'') is at right angles to (x,y,z), but by the hairy ball theorem you can't.

In the formula above the occurrence of the discontinuous sign function makes the formula discontinuous. Note that sign needn't involve a branch; in some languages there is a build in function to do it; in C you could use 2*(x>=0)-1.

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Using sign is sort of still branching, but that is the sort of answer I was looking for, thanks. I did manage to find another even simpler answer: <x,y,z> => <z,-z,x+y>. The proof that they are different for all non-zero inputs using that transform is quite easy. –  Stravant Rae Sep 3 '12 at 16:45
For (1,-1,0) you get (0,0,0). –  dmuir Sep 3 '12 at 16:54