📑 Table of Contents

In mathematics, projectivization is a procedure which associates with a non-zero vector space V a projective space P(V), whose elements are one-dimensional subspaces of V. More generally, any subset S of V closed under scalar multiplication defines a subset of P(V) formed by the lines contained in S and is called the projectivization of S.[1]

Properties

edit
  • Projectivization is a special case of the factorization by a group action: the projective space P(V) is the quotient of the open set V \ {0} of nonzero vectors by the action of the multiplicative group of the base field by scalar transformations. The dimension of P(V) in the sense of algebraic geometry is one less than the dimension of the vector space V.
  • Projectivization is functorial with respect to injective linear maps: if
is a linear map with trivial kernel then f defines an algebraic map of the corresponding projective spaces,
In particular, the general linear group GL(V) acts on the projective space P(V) by automorphisms.

Projective completion

edit

A related procedure embeds a vector space V over a field K into the projective space P(VK) of the same dimension. To every vector v of V, it associates the line spanned by the vector (v, 1) of VK.

Generalization

edit
Main article: Projective bundle

In algebraic geometry, there is a procedure that associates a projective variety Proj S with a graded commutative algebra S (under some technical restrictions on S). If S is the algebra of polynomials on a vector space V then Proj S is P(V). This Proj construction gives rise to a contravariant functor from the category of graded commutative rings and surjective graded maps to the category of projective schemes.

References

edit
  1. ^ Weisstein, Eric W. "Projectivization". mathworld.wolfram.com. Retrieved 2024-08-27.

📚 Artikel Terkait di Wikipedia

Algebraic geometry of projective spaces

over k defined by Proj(k[V]) is called projectivization of V. The projective n-space on k is the projectivization of the vector space A k n + 1 {\displaystyle

Projective Hilbert space

number λ {\displaystyle \lambda } . This is the usual construction of projectivization, applied to a complex Hilbert space. In quantum mechanics, the equivalence

Projective linear group

exception of the non-Desarguesian planes, all projective spaces are the projectivization of a linear space over a division ring though, as noted above, there

Collineation

For a projective space defined in terms of linear algebra (as the projectivization of a vector space), a collineation is a map between the projective

Plücker embedding

map embeds G r ( k , V ) {\displaystyle \mathrm {Gr} (k,V)} into the projectivization P ( ⋀ k V ) {\displaystyle \mathbb {P} ({\textstyle \bigwedge }^{k}V)}

Grassmannian

Grassmannian G r ( k , V ) {\displaystyle \mathbf {Gr} (k,V)} into the projectivization of the k {\displaystyle k} th exterior power Λ k V {\displaystyle \Lambda

Blowing up

{m}}=(x,y)} is the maximal ideal of the origin. Algebraically, the projectivization of this vector space is Proj of its symmetric algebra, that is, X =

Outer space (mathematics)

actions coincide, so the closure can be understood in either sense. The projectivization of c v ¯ n {\displaystyle {\overline {cv}}_{n}} with respect to multiplication