Projective transformation

A one-to-one mapping of a projective space onto itself preserving the order relation in the partially ordered (by inclusion) set of all subspaces of , that is, a mapping of onto itself such that:

1) if , then ;

2) for every there is an such that ;

3) if and only if .

Under a projective transformation the sum and intersection of subspaces are preserved, points are mapped to points, and independence of points is preserved. The projective transformations constitute a group, called the projective group. Examples of projective transformations are: a collineation, a perspective and a homology.

Let the space be interpreted as the collection of subspaces of the left vector space over a skew-field . A semi-linear transformation of into itself is a pair consisting of an automorphism of the additive group and an automorphism of the skew-field such that for any and the equality holds. In particular, a semi-linear transformation is linear if . A semi-linear transformation induces a projective transformation . The converse assertion is the first fundamental theorem of projective geometry: If , then every projective transformation is induced by some semi-linear transformation of the space .

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A projective transformation can also be defined as a bijection of the points of preserving collinearity in both directions.

Other names used for a projective transformation are: projectivity, collineation. See also Collineation for terminology.