I have a collection of 3D vectors. How do I verify if these Vectors are in the same plane
closed as offtopic by Flexo♦ Jan 3 '14 at 8:45



First, you should select one of your N points and subtract its coordinates from all the other N1 point coordinates. You thus get a collection of N1 vectors. The question of whether the N points are in the same plane is equivalent to knowing whether the N1 vectors are in a plane that goes through the origin. The determinant of any matrix 3x3 made of three vectors is zero if and only if the three vectors are in the same plane. You could set two columns to two fixed, noncolinear vectors (this defines a plane that contains the origin), and then check all the other vectors successively by setting the third column of the matrix to their coordinates and calculating its determinant. As noted by woodchips, calculating a determinant with a good precision is not completely trivial, so it is best to use a welltested function, for this (like a function in a matrix package). Another, computationally faster and more precise approach is to take two of your vectors, make sure that they define a plane (i.e. that they are not colinear), and then calculate their cross product: this gives you a vector normal to the plane. Then, you can make sure that each other vector is in the same plane by performing a dot product with the normal vector: this dot product is zero only if the new vector is in the same plane as your first two vectors. You can test whether two vectors are colinear or not by calculating the norm of their cross product: if the norm is not zero (to a given precision), then the vectors are not colinear. 


Not an answer so much as three observations, the first of which is too long to be a comment. Observation #1: This problem as stated is ambiguous.
To illustrate this ambiguity, consider the three canonical unit vectors xhat, yhat, and zhat. By meaning #1, these three vectors are not coplanar. By meaning #2, they are. It takes three points to define a plane, so three points cannot be noncoplanar. Another example:
By meaning #1, these vectors are not coplanar but they are by meaning #2. If the second meaning is the correct interpretation, then doing the subtractions as described in the solutions to date is essential. For example, consider the SVD/PCA solution described by woodchips. Bypassing step 1, "Subtract off the mean value of all the vectors," would result in the SVD finding that xhat is the first principal component. If the first meaning is the correct interpretation, then doing those subtractions is absolutely the wrong thing to do. Here the SVD should find xhat as the first principal component and should find that there are indeed three significant components. Observation #2: On SVD versus iterative solutions Observation #3: On detection 


That third singular value should be on the order of 10^15 as large as the largest singular value. If it is not so, then the vectors do not all lie in a single plane. (This presumes that your work was in double precision. As well, if that ratio is only 1e13, I'd not complain.) 


Wikipedia has all the answers you need. As you know, 3 points determine a plane. Therefore, if you have 0,1,2, or 3 distinct vectors in your collection, they are on a same plane for certain. Follow the above link and you will find a way to determine the plane from the first three (distinct) vectors of your collection. And another section tells you how to compute the distance to this plane for the remaining points. If the distance is 0 for all of them, they are in the same plane. 


A simple algorithm:
In detail:
This algorithm assumes that you are interested in the plane containing both the origin and the ends of all the vectors. If instead you are thinking about a collection of points rather than a collection of vectors, simply subtract the mean of all the points from each point first. This is basically a variant of the GramSchmidt process for making an orthonormal basis. 

