I am looking for a fast and effective way to determine if Vector B is Between the small angle of Vector A and Vector C. Normally I would use the perpendicular dot product to determine which sides of each line B lies on but in this case is not so simple because of the following.

- none of the vectors can be assumed to be normalized and normalizing them is an extra step I would prefer to avoid.
- I have no clear notion as to which side is the smallest angle so it is hard to say which side of the line is good or not.
- It is possible for A and B to be co-linear or exactly 180 degrees apart in which case I want to return false.
- while i am working in a 3d enviroment it is easy for me to simplify this to 2d if that makes things easier and more importantly faster. This test will be used in a algorithm that needs to run as fast as possible.

If there is some easy and efficient method to determining which direction my perpendicular vectors should both point I could use the two dot products for my test.

Another approach In have been considering without much success so far is using a matrix. In theory from what i understand of matrix transforms i should be able to use A and C as basis vectors. Then multiplying B by the matrix i should be able to test what quadrant B then lies in by whether X and Y are both positive. If i could get this approach to work it would likely be the best since one matrix multiplication should be faster than two dot products and I should not have to worry about which side has the smallest angle on it.

The problem is from my tests I cannot simply use A and C as bases and multiply it normally and get correct behavior. I am really not sure what i am doing wrong here. I have run across the term Vector spaces a few times which as near as i can figure seems to be a very similar concept to Matrix transforms without any requirements for orthogonal bases or orthonormal bases. Is it the same thing as matrix if not might that be a better approach and how would i use that.

Just to give a more visual explanation of what i am talking about. This is just an example.

@Aki Suihkonen I would like to say that is working for me but I can't seem to get it working. Coded up a mock case i could run through and see if i can't figure somthing out

For this case using Ax 2.9579773 Ay 3.315979 Cx 2.5879822 Cy 5.1630249 For B I rotated around the four quadrants the vectors divide the space up into.

The Signs I got for Q1 -- For Q2 +- for Q3 +- and for Q4 --

Assuming i rotated around in the enviroment the same direction as the image I am fairly sure I did.