Now that we have a representation for lines, we can proceed to more
complex relations. It should not surprise the reader
that the coordinates of the plane passing through the three
points
,
*i*=1,2,3, is obtained from the
determinants of the four
submatrices of

Paying careful attention to the order of the submatrices then yields the plane's coordinates:

Note that, as a result of duality, the same formula can be used to find the point defining the intersection of three planes.

A point
lies on a line
if and only if the vectors
,
,
and
are collinear, that is, the
determinants of the four
submatrices of the following matrix

are zero. In terms of the Plücker coordinates, this concurrence can be expressed as follows:

where

An intuitive way to think about

Two lines
and
intersect if and only if their Plücker
coordinates satisfy the equation

(*l*_{41}*l*'_{23}+*l*'_{41}*l*_{23}) +
(*l*_{42}*l*'_{31}+*l*'_{42}*l*_{31}) +
(*l*_{43}*l*'_{12}+*l*'_{43}*l*_{12}) = 0,

which arises from the fact that the determinant is zero, where and lie on and and lie on .

In this section we have shown how to find the line containing two points and the plane containing three points. Symmetrically, we have shown how to find the point at the intersection of three planes but have not shown how to find the line at the intersection of two planes. This latter problem can be solved by computing the determinants of the submatrices, but it appears according to my calculations that a different choice of submatrices will have to be made. We have shown how to determine whether a point lies on a line or in a plane, and we have shown whether two lines intersect, though we have not calculated their intersection point. Other remaining problems include finding the intersection of a line and a plane, calculating the plane defined by two lines, and computing the plane defined by a point and a line.