Plücker embedding

In mathematics, the Plücker map embeds the Grassmannian ${\displaystyle 𝐆𝐫(k,V)}$, whose elements are k-dimensional subspaces of an n-dimensional vector space V, either real or complex, in a projective space, thereby realizing it as a projective algebraic variety. More precisely, the Plücker map embeds ${\displaystyle 𝐆𝐫(k,V)}$ into the projectivization ${\displaystyle 𝐏({\bigwedge }^{k}V)}$ of the ${\displaystyle k}$-th exterior power of ${\displaystyle V}$. The image is algebraic, consisting of the intersection of a number of quadrics defined by the Template:Slink (see below).

The Plücker embedding was first defined by Julius Plücker in the case ${\displaystyle k=2,n=4}$ as a way of describing the lines in three-dimensional space (which, as projective lines in real projective space, correspond to two-dimensional subspaces of a four-dimensional vector space). The image of that embedding is the Klein quadric in RP⁵.

Hermann Grassmann generalized Plücker's embedding to arbitrary k and n. The homogeneous coordinates of the image of the Grassmannian ${\displaystyle 𝐆𝐫(k,V)}$ under the Plücker embedding, relative to the basis in the exterior space ${\displaystyle {\bigwedge }^{k}V}$ corresponding to the natural basis in ${\displaystyle V=K^n}$ (where ${\displaystyle K}$ is the base field) are called Plücker coordinates.

Denoting by ${\displaystyle V=K^n}$ the ${\displaystyle n}$-dimensional vector space over the field ${\displaystyle K}$, and by ${\displaystyle 𝐆𝐫(k,V)}$ the Grassmannian of ${\displaystyle k}$-dimensional subspaces of ${\displaystyle V}$, the Plücker embedding is the map ι defined by

${\displaystyle \begin{array}{cc}\iota :𝐆𝐫(k,V)& \to 𝐏({\bigwedge }^{k}V),\\ \iota :𝒲:=\mathrm{span}(w_1,\dots ,w_k)& \mapsto [w_1\wedge \cdots \wedge w_k],\end{array}}$

where ${\displaystyle (w_1,\dots ,w_k)}$ is a basis for the element ${\displaystyle 𝒲\in 𝐆𝐫(k,V)}$ and ${\displaystyle [w_1\wedge \cdots \wedge w_k]}$ is the projective equivalence class of the element ${\displaystyle w_1\wedge \cdots \wedge w_k\in {\bigwedge }^{k}V}$ of the ${\displaystyle k}$th exterior power of ${\displaystyle V}$.

This is an embedding of the Grassmannian into the projectivization ${\displaystyle 𝐏({\bigwedge }^{k}V)}$. The image can be completely characterized as the intersection of a number of quadrics, the Plücker quadrics (see below), which are expressed by homogeneous quadratic relations on the Plücker coordinates (see below) that derive from linear algebra.

The bracket ring appears as the ring of polynomial functions on ${\displaystyle {\bigwedge }^{k}V}$.^[1]

The image under the Plücker embedding satisfies a simple set of homogeneous quadratic relations, usually called the Plücker relations, or Grassmann–Plücker relations, defining the intersection of a number of quadrics in ${\displaystyle 𝐏({\bigwedge }^{k}V)}$. This shows that the Grassmannian embeds as an algebraic subvariety of ${\displaystyle 𝐏({\bigwedge }^{k}V)}$ and gives another method of constructing the Grassmannian. To state the Grassmann–Plücker relations, let ${\displaystyle 𝒲\in 𝐆𝐫(k,V)}$ be the ${\displaystyle k}$-dimensional subspace spanned by the basis represented by column vectors ${\displaystyle W_1,\dots ,W_k}$. Let ${\displaystyle W}$ be the ${\displaystyle n\times k}$ matrix of homogeneous coordinates, whose columns are ${\displaystyle W_1,\dots ,W_k}$. Then the equivalence class ${\displaystyle [W]}$ of all such homogeneous coordinates matrices ${\displaystyle Wg\sim W}$ related to each other by right multiplication by an invertible ${\displaystyle k\times k}$ matrix ${\displaystyle g\in 𝐆𝐋(k,K)}$ may be identified with the element ${\displaystyle 𝒲}$. For any ordered sequence ${\displaystyle 1\le i_1<\cdots <i_k\le n}$ of ${\displaystyle k}$ integers, let ${\displaystyle W_{i_1,\dots ,i_k}}$ be the determinant of the ${\displaystyle k\times k}$ matrix whose rows are the rows ${\displaystyle (i_1,\dots i_k)}$ of ${\displaystyle W}$. Then, up to projectivization, ${\displaystyle \{W_{i_1,\dots ,i_k}\}}$ are the Plücker coordinates of the element ${\displaystyle 𝒲\sim [W]\in 𝐆𝐫(k,V)}$ whose homogeneous coordinates are ${\displaystyle W}$. They are the linear coordinates of the image ${\displaystyle \iota (𝒲)}$ of ${\displaystyle 𝒲\in 𝐆𝐫(k,V)}$ under the Plücker map, relative to the standard basis in the exterior space ${\displaystyle {\bigwedge }^{k}V}$. Changing the basis defining the homogeneous coordinate matrix ${\displaystyle W}$ just changes the Plücker coordinates by a nonzero scaling factor equal to the determinant of the change of basis matrix ${\displaystyle g}$, and hence just the representative of the projective equivalence class in ${\displaystyle {\bigwedge }^{k}V}$.

For any two ordered sequences:

${\displaystyle i_1<i_2<\cdots <i_{k-1},j_1<j_2<\cdots <j_{k+1}}$

of positive integers ${\displaystyle 1\le i_l,j_m\le n}$, the following homogeneous equations are valid, and determine the image of ${\displaystyle 𝒲}$ under the Plücker map:^[2] Template:NumBlk where ${\displaystyle j_1,\dots ,{\hat{j}}_l\dots j_{k+1}}$ denotes the sequence ${\displaystyle j_1,\dots ,\dots j_{k+1}}$ with the term ${\displaystyle j_l}$ omitted. These are generally referred to as the Plücker relations.

When Template:Math and Template:Math, we get ${\displaystyle 𝐆𝐫(2,V)}$, the simplest Grassmannian which is not a projective space, and the above reduces to a single equation. Denoting the coordinates of ${\displaystyle {\bigwedge }^{2}V}$ by

${\displaystyle W_{ij}=-W_{ji},1\le i,j\le 4,}$

the image of ${\displaystyle 𝐆𝐫(2,V)}$ under the Plücker map is defined by the single equation

${\displaystyle W_{12}{W}_{34}-W_{13}{W}_{24}+W_{14}{W}_{23}=0.}$

In general, many more equations are needed to define the image of the Plücker embedding, as in (Template:EquationNote), but these are not, in general, algebraically independent. The maximal number of algebraically independent relations (on Zariski open sets) is given by the difference of dimension between ${\displaystyle 𝐏({\bigwedge }^{k}V)}$ and ${\displaystyle 𝐆𝐫(k,V)}$, which is ${\displaystyle (\genfrac{}{}{0ex}{}{n}{k})-k(n-k)-1.}$

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