Plücker matrix
The Plücker matrix is a special skew-symmetric 4 × 4 matrix, which characterizes a straight line in projective space.
The matrix is defined by 6 Plücker coordinates with 4 degrees of freedom.
It is named after the German mathematician Julius Plücker.
A straight line in space is defined by two distinct points
in homogeneous coordinates of the projective space.
Its Plücker matrix is: Where the skew-symmetric
-matrix is defined by the 6 Plücker coordinates with Plücker coordinates fulfill the Grassmann–Plücker relations and are defined up to scale.
A Plücker matrix has only rank 2 and four degrees of freedom (just like lines in
They are independent of a particular choice of the points
and can be seen as a generalization of the line equation i.e. of the cross product for both the intersection (meet) of two lines, as well as the joining line of two points in the projective plane.
The Plücker matrix allows us to express the following geometric operations as matrix-vector product: Two arbitrary distinct points on the line can be written as a linear combination of
: Their Plücker matrix is thus: up to scale identical to
denote the plane with the equation which does not contain the line
Then, the matrix-vector product with the Plücker matrix describes a point which lies on the line
because it is a linear combination of
is also contained in the plane
and must therefore be their point of intersection.
In addition, the product of the Plücker matrix with a plane is the zero-vector, exactly if the line
is contained entirely in the plane: In projective three-space, both points and planes have the same representation as 4-vectors and the algebraic description of their geometric relationship (point lies on plane) is symmetric.
By interchanging the terms plane and point in a theorem, one obtains a dual theorem which is also true.
In case of the Plücker matrix, there exists a dual representation of the line in space as the intersection of two planes: and in homogeneous coordinates of projective space.
Their Plücker matrix is: and describes the plane
which contains both the point
and the line
, with an arbitrary plane
, is either the zero-vector or a point on the line, it follows: Thus: The following product fulfills these properties: due to the Grassmann–Plücker relation.
With the uniqueness of Plücker matrices up to scalar multiples, for the primal Plücker coordinates we obtain the following dual Plücker coordinates: The 'join' of two points in the projective plane is the operation of connecting two points with a straight line.
Its line equation can be computed using the cross product: Dually, one can express the 'meet', or intersection of two straight lines by the cross-product: The relationship to Plücker matrices becomes evident, if one writes the cross product as a matrix-vector product with a skew-symmetric matrix: and analogously
is the displacement and
is the moment of the line, compare the geometric intuition of Plücker coordinates.
