<!-- varieties.xml FinInG package documentation John Bamberg Anton Betten Philippe Cara Jan De Beule Michel Lavrauw Max Neunhoeffer
Copyright (C) 2018, Colorado State University Sabancı Üniversitesi Università degli Studi di Padova Universiteit Gent University of St. Andrews University of Western Australia Vrije Universiteit Brussel This is the chapter of the documentation describing the algebraic varieties.
-->
<Chapter Label="varieties">
<Heading>Algebraic Varieties</Heading>
In <Package>FinInG</Package> we provide some basic functionality for algebraic varieties defined over finite fields. The algebraic varieties in <Package>FinInG</Package> are defined by a list of multivariate polynomials over a finite field, and an ambient geometry. This ambient geometry is either a projective space, and then the algebraic variety is called a <E>projective variety</E>, or an affine geometry, and then the algebraic variety is called an <E>affine variety</E>. In this chapter we give a brief overview of the features of <Package>FinInG</Package> concerning these two types of algebraic varieties.
The package <Package>FinInG</Package> also contains the Veronese varieties <Ref Oper="VeroneseVariety"/>, the Segre varieties <Ref Oper="SegreVariety"/> and the Grassmann varieties <Ref Oper="GrassmannVariety"/>; three classical projective varieties. These varieties have an associated <E>geometry map</E> (the <Ref Oper="VeroneseMap"/>, <Ref Oper="SegreMap"/> and <Ref Oper="GrassmannMap"/>) and <Package>FinInG</Package> also provides some general functionality for these.
<!--SECTION ALGEBRAIC VARIETIES -->
<Section Label="algebraicvarieties">
<Heading>Algebraic Varieties</Heading>
An <E>algebraic variety</E> in <Package>FinInG</Package> is an algebraic variety in a projective space or affine space, defined by a list of polynomials over a finite field.
<ManSection>
<Oper Name="AlgebraicVariety" Arg="space, pring, pollist"/>
<Oper Name="AlgebraicVariety" Arg="space, pollist"/>
<Returns>an algebraic variety</Returns>
<Description>
The argument <A>space</A> is an affine or projective space over a finite field <A>F</A>, the argument <A>pring</A> is a multivariate polynomial ring defined over
(a subfield of) <A>F</A>, and <A>pollist</A> is a list of polynomials in <A>pring</A>. If the <A>space</A> is a projective space, then <A>pollist</A> needs to be a list of homogeneous polynomials. In <Package>FinInG</Package> there are two types of projective varieties: projective varieties and affine varieties. The following operations apply to both types.
<Example>
<#Include SYSTEM "../examples/include/varieties_general.include">
</Example>
</Description>
</ManSection>
<ManSection>
<Attr Name="DefiningListOfPolynomials" Arg="var"/>
<Returns>a list of polynomials</Returns>
<Description>
The argument <A>var</A> is an algebraic variety. This attribute returns the list of polynomials that was used to define the variety <A>var</A>.
</Description>
</ManSection>
<ManSection>
<Attr Name="AmbientSpace" Arg="var"/>
<Returns>an affine or projective space</Returns>
<Description>
The argument <A>var</A> is an algebraic variety. This attribute returns the affine or projective space in which the variety <A>var</A> was defined.
</Description>
</ManSection>
<ManSection>
<Oper Name="PointsOfAlgebraicVariety" Arg="var"/>
<Oper Name="Points" Arg="var" />
<Returns>a list of points</Returns>
<Description>
The argument <A>var</A> is an algebraic variety. This operation returns the list of points of the <Ref Attr="AmbientSpace" /> of the algebraic variety <A>var</A> whose coordinates satisfy the <Ref Attr="DefiningListOfPolynomials"/> of the algebraic variety <A>var</A>.
<Example>
<#Include SYSTEM "../examples/include/varieties_points.include">
</Example>
</Description>
</ManSection>
<ManSection>
<Oper Name="Iterator" Arg="pts"/>
<Returns>an iterator</Returns>
<Description>
The argument <A>pts</A> is the set of <Ref Oper="PointsOfAlgebraicVariety" /> of an algebraic variety <A>var</A>. This operation returns an iterator for the points of an algebraic variety.
</Description>
</ManSection>
<ManSection>
<Oper Name="\in" Arg="x,var"/>
<Oper Name="\in" Arg="x,pts"/>
<Returns>true or false</Returns>
<Description>
The argument <A>x</A> is a point of the <Ref Attr="AmbientSpace" /> of an algebraic variety <Ref Oper="AlgebraicVariety" />. This operation also works for a point <A>x</A> and the collection <A>pts</A> returned by <Ref Oper="PointsOfAlgebraicVariety"/>.
</Description>
</ManSection>
</Section>
<!--SECTION PROJECTIVE VARIETIES -->
<Section Label="projectivevarieties">
<Heading>Projective Varieties</Heading>
A <E>projective variety</E> in <Package>FinInG</Package> is an algebraic variety in a projective space defined by a list of homogeneous polynomials over a finite field.
<ManSection>
<Oper Name="ProjectiveVariety" Arg="pg, pring, pollist"/>
<Oper Name="ProjectiveVariety" Arg="pg, pollist"/>
<Oper Name="AlgebraicVariety" Arg="pg, pring, pollist"/>
<Oper Name="AlgebraicVariety" Arg="pg, pollist"/>
<Returns>a projective algebraic variety</Returns>
<Description>
<Example>
<#Include SYSTEM "../examples/include/varieties_general.include">
</Example>
</Description>
</ManSection>
</Section>
<!--SECTION QUADRICS AND HERMITIAN VARIETIES -->
<Section Label="quadricshermitian">
<Heading>Quadrics and Hermitian varieties</Heading>
Quadrics (<Ref Oper="QuadraticVariety"/>) and Hermitian varieties (<Ref Oper="HermitianVariety"/>) are projective varieties that have the
associated quadratic or hermitian form as an extra
attribute installed.
Furthermore, we provide a method for <F>PolarSpace</F> taking as an argument a projective algebraic variety.
<ManSection>
<Oper Name="HermitianVariety" Arg="pg, pring, pol"/>
<Oper Name="HermitianVariety" Arg="pg, pol"/>
<Oper Name="HermitianVariety" Arg="n,F"/>
<Oper Name="HermitianVariety" Arg="n,q"/>
<Returns>a hermitian variety in a projective space</Returns>
<Description>
For the first two methods, the argument <A>pg</A> is a projective space, <A>pring</A> is a polynomial ring,
and <A>pol</A> is polynomial.
For the third and fourth variations, the argument <A>n</A> is an integer,
the argument <A>F</A> is a finite field, and the argument <A>q</A> is a prime power.
These variations of the operation return the hermitian variety associated to the standard hermitian form in the projective space of dimension <M>n</M> over the field <M>F</M> of order <M>q</M>.
<Example>
<#Include SYSTEM "../examples/include/varieties_hermitian.include">
</Example>
</Description>
</ManSection>
<!-- <ManSection> <Oper Name="HermitianVariety" Arg="n,F"/> <Oper Name="HermitianVariety" Arg="n,q"/> <Returns>a hermitian variety in a projective space</Returns> <Description> The argument <A>n</A> is an integer, the argument <A>F</A> is a finite field, and the argument <A>q</A> is a prime power. This function returns the hermitian variety associated to the standard hermitian form in the projective space of dimension <M>n</M> over the field <M>F</M> of order <M>q</M>. </Description> </ManSection>
-->
<ManSection>
<Oper Name="QuadraticVariety" Arg="pg, pring, pol"/>
<Oper Name="QuadraticVariety" Arg="pg, pol"/>
<Oper Name="QuadraticVariety" Arg="n, F, type"/>
<Oper Name="QuadraticVariety" Arg="n, q, type"/>
<Oper Name="QuadraticVariety" Arg="n, F"/>
<Oper Name="QuadraticVariety" Arg="n, q"/>
<Returns>a quadratic variety in a projective space</Returns>
<Description>
In the first two methods, the argument <A>pg</A> is a projective space, <A>pring</A> is a polynomial ring,
and <A>pol</A> is a polynomial. The latter four return a standard non-degenerate quadric. The
argument <A>n</A> is a projective dimension, <A>F</A> is a field, and <A>q</A> is a prime power
that gives just the order of the defining field. If the <A>type</A> is given, then it will
return a quadric of a particular type as follows:
<Row><Item>elliptic quadric</Item>
<Item><Alt Only="LaTeX">\makecell[cl]{<M>X_0^2 + tX_1^2 + X_2X_3 + \ldots + X_{n-1}X_n</M>,\\ <M>t</M> a primitive element of <M>\mathrm{GF}(p)</M>}</Alt>
<Alt Only="HTML MathJax"><M>X_0^2 + tX_1^2 + X_2X_3 + \ldots + X_{n-1}X_n</M>, <M>t</M> a primitive element of <M>\mathrm{GF}(p)</M></Alt>
<Alt Only="Text"><M>X_0^2 + tX_1^2 + X_2X_3 + \ldots + X_{n-1}X_n</M>, <M>t</M> a primitive element of <M>GF(p)</M></Alt>
<Alt Only="HTML noMathJax">X<sub>0</sub><sup>2</sup> + tX<sub>1</sub><sup>2</sup> + X<sub>2</sub> X<sub>3</sub> + ... + X<sub>n-1</sub>X<sub>n</sub>, <M>t</M> a primitive element of GF(p)</Alt>
</Item>
<Item><Alt Only="HTML noMathJax">p ≡ 1 mod 4</Alt>
<Alt Only="HTML MathJax"><M>p \equiv 1 \pmod{4}</M></Alt>
<Alt Not="HTML"><M>p \equiv 1 \pmod{4}</M></Alt>
</Item><Item>odd</Item><Item>"elliptic", "-", or "-1"</Item></Row>
<Row><Item>elliptic quadric</Item>
<Item><Alt Only="Text"><M>X_0^2 + X_0X_1 + dX_1^2 + X_2X_3 + \ldots + X_{n-1}X_n
</M>, <M>Tr(d)=1</M></Alt>
<Alt Only="LaTeX">\makecell[cl]{<M>X_0^2 + X_0X_1 + dX_1^2 + X_2X_3 + \ldots + X_{n-1}X_n</M>,\\ <M>\mathrm{Tr}(d)=1</M>}</Alt>
<Alt Only="HTML MathJax"><M>X_0^2 + X_0X_1 + dX_1^2 + X_2X_3 + \ldots + X_{n-1}X_n</M>, <M>\mathrm{Tr}(d)=1</M></Alt>
<Alt Only="HTML noMathJax">X<sub>0</sub><sup>2</sup> + X<sub>0</sub>X<sub>1</sub> +
d X<sub>1</sub><sup>2</sup> + X<sub>2</sub>
X<sub>3</sub> + ... + X<sub>n-1</sub>X<sub>n</sub>
, Tr(d) = 1</Alt>
</Item><Item>even</Item><Item>odd</Item><Item>"elliptic", "-", or "-1"</Item></Row>
<HorLine/>
</Table>
If no type is given, and only the dimension and field/field order are given, then it is assumed
that the dimension is even and the user wants a standard parabolic quadric.
<Example>
<#Include SYSTEM "../examples/include/varieties_quadratic.include">
</Example>
</Description>
</ManSection>
<ManSection>
<Attr Name="QuadraticForm" Arg="var"/>
<Returns> a quadratic form</Returns>
<Description>
When the argument <A>var</A> is a <Ref Oper="QuadraticVariety"/>, this returns the associated quadratic form.
</Description>
</ManSection>
<ManSection>
<Attr Name="SesquilinearForm" Arg="var"/>
<Returns> a hermitian form</Returns>
<Description>
If the argument <A>var</A> is a <Ref Oper="HermitianVariety"/>, this returns the associated hermitian form.
</Description>
</ManSection>
<ManSection>
<Oper Name="PolarSpace" Arg="var"/>
<Description>
the argument <A>var</A> is a projective algebraic variety. When its list of defining polynomial contains exactly one polynomial,
depending on its degree, the operation <F>QuadraticFormByPolynomial</F> or <F>HermitianFormByPolynomial</F> is used to compute
a quadratic form or a hermitian form. These operations check whether this is possible, and produce an error message if not. If the
conversion is possible, then the appropriate polar space is returned.
<Example>
<#Include SYSTEM "../examples/include/varieties_polarspace.include">
</Example>
</Description>
</ManSection>
</Section>
<!--SECTION AFFINE VARIETIES -->
<Section Label="affinevarieties">
<Heading>Affine Varieties</Heading>
An <E>affine variety</E> in <Package>FinInG</Package> is an algebraic variety in an affine space defined by a list of polynomials over a finite field.
<ManSection>
<Oper Name="AffineVariety" Arg="ag, pring, pollist"/>
<Oper Name="AffineVariety" Arg="ag, pollist"/>
<Oper Name="AlgebraicVariety" Arg="ag, pring, pollist"/>
<Oper Name="AlgebraicVariety" Arg="ag, pollist"/>
<Returns>an affine algebraic variety</Returns>
<Description>
The argument <A>ag</A> is an affine space over a finite field <A>F</A>, the
argument <A>pring</A> is a multivariate polynomial ring defined over
(a subfield of) <A>F</A>, and <A>pollist</A> is a list of
polynomials in <A>pring</A>.
</Description>
</ManSection>
</Section>
<!--SECTION GEOMETRY MAPS -->
<Section Label="geometrymaps">
<Heading>Geometry maps</Heading>
A <A>geometry map</A> is a map from a set of elements of a geometry to a set of elements of another geometry, which is not necessarily a geometry morphism. Examples are the <Ref Oper="SegreMap"/>, the <Ref Oper="VeroneseMap"/>, and the <Ref Oper="GrassmannMap"/>.
<ManSection>
<Oper Name="Source" Arg="gm"/>
<Returns>the source of a geometry map</Returns>
<Description>
The argument <A>gm</A> is a geometry map.
</Description>
</ManSection>
<ManSection>
<Oper Name="Range" Arg="gm"/>
<Returns>the range of a geometry map</Returns>
<Description>
The argument <A>gm</A> is a geometry map.
</Description>
</ManSection>
<ManSection>
<Oper Name="ImageElm" Arg="gm,x"/>
<Returns>the image of an element under a geometry map</Returns>
<Description>
The argument <A>gm</A> is a geometry map, the element <A>x</A> is an element of the <Ref Oper="Source"/> of the geometry map <A>gm</A>.
</Description>
</ManSection>
<ManSection>
<Oper Name="ImagesSet" Arg="gm,elms"/>
<Returns>the image of a subset of the source under a geometry map</Returns>
<Description>
The argument <A>gm</A> is a geometry map, the elements <A>elms</A> is a subset of the <Ref Oper="Source"/> of the geometry map <A>gm</A>.
</Description>
</ManSection>
<ManSection>
<Oper Name="\^" Arg="x,gm"/>
<Returns>the image of an element of the source under a geometry map</Returns>
<Description>
The argument <A>gm</A> is a geometry map, the element <A>x</A> is an element of the <Ref Oper="Source"/> of the geometry map <A>gm</A>.
</Description>
</ManSection>
</Section>
<!--SECTION SEGRE VARIETIES -->
<Section Label="segrevarieties">
<Heading>Segre Varieties</Heading>
A <E>Segre variety</E> in <Package>FinInG</Package> is a projective algebraic variety in a projective space over a finite field. The set of points that lie on this variety is the image of the <E>Segre map</E>.
<ManSection>
<Oper Name="SegreVariety" Arg="listofpgs"/>
<Oper Name="SegreVariety" Arg="listofdims,field"/>
<Oper Name="SegreVariety" Arg="pg1,pg2"/>
<Oper Name="SegreVariety" Arg="d1,d2,field"/>
<Oper Name="SegreVariety" Arg="d1,d2,q"/>
<Returns>a Segre variety</Returns>
<Description>
The argument <A>listofpgs</A> is a list of projective spaces defined over the same finite field, say <Alt Not="HTML"><M>[PG(n_1-1,q)</M></Alt> <Alt Only="HTML">[PG(n<sub>1 </sub>-1,q)</Alt>, <Alt Not="HTML"><M>PG(n_2-1,q)</M></Alt> <Alt Only="HTML">PG(n<sub>2 </sub>-1,q)</Alt>, ..., <Alt Not="HTML"><M>PG(n_k-1,q)]</M></Alt> <Alt Only="HTML">PG(n<sub>k </sub>-1,q)]</Alt>. The operation also takes as input the list of dimensions (<A>listofdims</A>) and a finite field <A>field</A> (e.g.
<Alt Not="HTML"><M>[n_1,n_2,\ldots,n_k,GF(q)]</M></Alt>
<Alt Only="HTML">[n<sub>1</sub>, n<sub>2</sub>, ..., n<sub>k</sub>,GF(q)]</Alt>). A Segre variety with only two factors (<M>k=2</M>), can also be constructed using the operation with two projective spaces <A>pg1</A> and <A>pg2</A> as arguments, or with two dimensions <A>d1</A>, <A>d2</A>, and a finite field <A>field</A>(or a prime power <A>q</A>).
The operation returns a projective algebraic variety in the projective space of dimension <Alt Not="HTML"><M>n_1n_2\ldots n_k-1</M></Alt>
<Alt Only="HTML">n<sub>1</sub> n<sub>2</sub> ... n<sub>k</sub>-1</Alt>.
</Description>
</ManSection>
<ManSection>
<Oper Name="PointsOfSegreVariety" Arg="sv"/>
<Oper Name="Points" Arg="sv"/>
<Returns>the points of a Segre variety</Returns>
<Description>
The argument <A>sv</A> is a Segre variety. This operation returns a set of points of the <Ref Attr="AmbientSpace" /> of the Segre variety. This set of points corresponds to the image of the <Ref Oper="SegreMap"/>.
</Description>
</ManSection>
<ManSection>
<Oper Name="SegreMap" Arg="listofpgs"/>
<Oper Name="SegreMap" Arg="listofdims,field"/>
<Oper Name="SegreMap" Arg="pg1,pg2"/>
<Oper Name="SegreMap" Arg="d1,d2,field"/>
<Oper Name="SegreMap" Arg="d1,d2,q"/>
<Oper Name="SegreMap" Arg="sv"/>
<Returns>a geometry map</Returns>
<Description>
The argument <A>listofpgs</A> is a list of projective spaces defined over the same finite field, say <Alt Not="HTML"><M>[PG(n_1-1,q)</M></Alt> <Alt Only="HTML">[PG(n<sub>1 </sub>-1,q)</Alt>, <Alt Not="HTML"><M>PG(n_2-1,q)</M></Alt> <Alt Only="HTML">PG(n<sub>2 </sub>-1,q)</Alt>, ..., <Alt Not="HTML"><M>PG(n_k-1,q)]</M></Alt> <Alt Only="HTML">PG(n<sub>k </sub>-1,q)]</Alt>. The operation also takes as input the list of dimensions (<A>listofdims</A>) and a finite field <A>field</A> (e.g.
<Alt Not="HTML"><M>[n_1,n_2,\ldots,n_k,GF(q)]</M></Alt>
<Alt Only="HTML">[n<sub>1</sub>, n<sub>2</sub>, ..., n<sub>k</sub>,GF(q)]</Alt>). A Segre map with only two factors (<M>k=2</M>), can also be constructed using the operation with two projective spaces <A>pg1</A> and <A>pg2</A> as arguments, or with two dimensions <A>d1</A>, <A>d2</A>, and a finite field <A>field</A>(or a prime power <A>q</A>).
The operation returns a function with domain the product of the point sets of projective spaces in the list <Alt Not="HTML"><M>[PG(n_1-1,q)</M></Alt> <Alt Only="HTML">[PG(n<sub>1 </sub>-1,q)</Alt>, <Alt Not="HTML"><M>PG(n_2-1,q)</M></Alt> <Alt Only="HTML">PG(n<sub>2 </sub>-1,q)</Alt>, ..., <Alt Not="HTML"><M>PG(n_k-1,q)]</M></Alt> <Alt Only="HTML">PG(n<sub>k </sub>-1,q)]</Alt> and image the set of points of the Segre variety (<Ref Oper="PointsOfSegreVariety"/>) in the projective space of dimension <Alt Not="HTML"><M>n_1n_2\ldots n_k-1</M></Alt>
<Alt Only="HTML">n<sub>1</sub> n<sub>2</sub> ... n<sub>k</sub>-1</Alt>.
When a Segre variety <A>sv</A> is given as input, the operation returns the associated Segre map.
<Example>
<#Include SYSTEM "../examples/include/varieties_segre.include">
</Example>
</Description>
</ManSection>
<ManSection>
<Oper Name="Source" Arg="sm"/>
<Returns>the source of a Segre map</Returns>
<Description>
The argument <A>sm</A> is a <Ref Oper="SegreMap"/>. This operation returns the cartesian product of the list consisting of the pointsets of the projective spaces that were used to construct the <Ref Oper="SegreMap"/>.
</Description>
</ManSection>
</Section>
<!--SECTION VERONESE VARIETIES -->
<Section Label="veronesevarieties">
<Heading>Veronese Varieties</Heading>
A <E>Veronese variety</E> in <Package>FinInG</Package> is a projective algebraic variety in a projective space over a finite field. The set of points that lie on this variety is the image of the <E>Veronese map</E>.
<ManSection>
<Oper Name="VeroneseVariety" Arg="pg"/>
<Oper Name="VeroneseVariety" Arg="n-1,field"/>
<Oper Name="VeroneseVariety" Arg="n-1,q"/>
<Returns>a Veronese variety</Returns>
<Description>
The argument <A>pg</A> is a projective space defined over a finite field, say <M>PG(n-1,q)</M>. The operation also takes as input the dimension and a finite field <A>field</A> (e.g. <M>[n-1,q]</M>).
The operation returns a projective algebraic variety in the projective space of dimension <M>(n^2+n)/2-1</M>, known as the
(quadratic) Veronese variety. It is the image of the map
<Alt Not="HTML"><M>(x_0,x_1,\ldots,x_n)\mapsto (x_0^2,x_0x_1,\ldots,x_0x_n,x_1^2,x_1x_2,\ldots,x_1x_n,\ldots,x_n^2)</M></Alt><Alt Only="HTML">(x<sub>0</sub>,x<sub>1</sub>,...,x<sub>n</sub>)→
(x<sub>0</sub><sup>2</sup>,x<sub>0</sub>x<sub>1</sub>,...,x<sub>0</sub>x<sub>n</sub>,x<sub>1</sub><sup>2</sup>,x<sub>1</sub>x<sub>2</sub>,...,x<sub>1</sub>x<sub>n</sub>,...,x<sub>n</sub><sup>2</sup>)
</Alt>
</Description>
</ManSection>
<ManSection>
<Oper Name="PointsOfVeroneseVariety" Arg="vv"/>
<Oper Name="Points" Arg="vv"/>
<Returns>the points of a Veronese variety</Returns>
<Description>
The argument <A>vv</A> is a Veronese variety. This operation returns a set of points of the <Ref Attr="AmbientSpace" /> of the Veronese variety. This set of points corresponds to the image of the <Ref Oper="VeroneseMap"/>.
</Description>
</ManSection>
<ManSection>
<Oper Name="VeroneseMap" Arg="pg"/>
<Oper Name="VeroneseMap" Arg="n-1,field"/>
<Oper Name="VeroneseMap" Arg="n-1,q"/>
<Oper Name="VeroneseMap" Arg="vv"/>
<Returns>a geometry map</Returns>
<Description>
The argument <A>pg</A> is a projective space defined over a finite field, say <M>PG(n-1,q)</M>. The operation also takes as input the dimension and a finite field <A>field</A> (e.g. <M>[n-1,q]</M>).
The operation returns a function with domain the product of the point set of the projective space <M>PG(n-1,q)</M> and image the set of points of the Veronese variety (<Ref Oper="PointsOfVeroneseVariety"/>) in the projective space of dimension <M>(n^2+n)/2-1</M>.
When a Veronese variety <A>vv</A> is given as input, the operation returns the associated Veronese map.
<Example>
<#Include SYSTEM "../examples/include/varieties_veronese.include">
</Example>
</Description>
</ManSection>
<ManSection>
<Oper Name="Source" Arg="vm"/>
<Returns>the source of a Veronese map</Returns>
<Description>
The argument <A>vm</A> is a <Ref Oper="VeroneseMap"/>. This operation returns the pointset of the projective space that was used to construct the <Ref Oper="VeroneseMap"/>.
</Description>
</ManSection>
</Section>
<!--SECTION GRASSMANN VARIETIES -->
<Section Label="grassmannvarieties">
<Heading>Grassmann Varieties</Heading>
A <E>Grassmann variety</E> in <Package>FinInG</Package> is a projective algebraic variety in a projective space over a finite field. The set of points that lie on this variety is the image of the <E>Grassmann map</E>.
<ManSection>
<Oper Name="GrassmannVariety" Arg="k,pg"/>
<Oper Name="GrassmannVariety" Arg="subspaces"/>
<Oper Name="GrassmannVariety" Arg="k,n,q"/>
<Returns>a Grassmann variety</Returns>
<Description>
The argument <A>pg</A> is a projective space defined over a finite field, say <M>PG(n,q)</M>, and argument <A>k</A> is an integer (<M>k</M> at least <M>1</M> and at most <M>n-2</M>) and denotes the projective dimension determining the Grassmann Variety. The operation also takes as input the set <A>subspaces</A> of subspaces of a projective space, or the dimension <A>k</A>, the dimension <A>n</A> and the size <A>q</A> of the finite field (<M>k</M> at least <M>1</M> and at most <M>n-2</M>).
The operation returns a projective algebraic variety known as the Grassmann variety.
</Description>
</ManSection>
<ManSection>
<Oper Name="PointsOfGrassmannVariety" Arg="gv"/>
<Oper Name="Points" Arg="gv"/>
<Returns>the points of a Grassmann variety</Returns>
<Description>
The argument <A>gv</A> is a Grassmann variety. This operation returns a set of points of the <Ref Attr="AmbientSpace" /> of the Grassmann variety. This set of points corresponds to the image of the <Ref Oper="GrassmannMap"/>.
</Description>
</ManSection>
<ManSection>
<Oper Name="GrassmannMap" Arg="k,pg"/>
<Oper Name="GrassmannMap" Arg="subspaces"/>
<Oper Name="GrassmannMap" Arg="k,n,q"/>
<Oper Name="GrassmannMap" Arg="gv"/>
<Returns>a geometry map</Returns>
<Description>
The argument <A>pg</A> is a projective space defined over a finite field, say <M>PG(n,q)</M>, and argument <A>k</A> is an integer (<M>k</M> at least <M>1</M> and at most <M>n-2</M>), and denotes the projective dimension determining the Grassmann Variety. The operation also takes as input the set <A>subspaces</A> of subspaces of a projective space, or the dimension <A>k</A>, the dimension <A>n</A> and the size <A>q</A> of the finite field (<M>k</M> at least <M>1</M> and at most <M>n-2</M>).
The operation returns a function with domain the set of subspaces of dimension <M>k</M> in the <M>n</M>-dimensional projective space over <M>GF(q)</M>, and image the set of points of the Grassmann variety (<Ref Oper="PointsOfGrassmannVariety"/>).
When a Grassmann variety <A>gv</A> is given as input, the operation returns the associated Grassmann map.
</Description>
</ManSection>
<ManSection>
<Oper Name="Source" Arg="gm"/>
<Returns>the source of a Grassmann map</Returns>
<Description>
The argument <A>gm</A> is a <Ref Oper="GrassmannMap"/>. This operation returns the set of subspaces of the projective space that was used to construct the <Ref Oper="GrassmannMap"/>.
</Description>
</ManSection>
</Section>
</Chapter>
<!-- <ManSection> <Oper Name="GrassmannMap" Arg="k, n, q"/> <Oper Name="GrassmannMap" Arg="k, ps"/> <Oper Name="GrassmannMap" Arg="vars"/> <Returns>a geometry morphism</Returns> <Description> If one argument <A>vars</A> is given, then <A>vars</A> is the set of k-subspaces of a projective space. If two arguments are given, then <A>k</A> is a dimension and <A>ps</A> is a projective space. Finally, if three arguments <A>k</A>, <A>n</A>, and <A>q</A> are given, then they represent k-subspaces of the projective space <M>PG(n,q)</M>. Here, k must be at least 1 but at most n-2. This operation returns a projective algebraic variety; the Grassmann variety <M>Gr(k,n,q)</M>. <Example> gap> g := GrassmannMap(lines); <geometry morphism from <lines of PG(3, 3)> to <points of Gr(1, 3, 3)>> gap> l := Random(lines); <a line in PG(3, 3)> gap> l^g; <a point in Gr(1, 3, 3)> </Example> </Description> </ManSection> <ManSection> <Oper Name="SegreMap" Arg="list"/> <Returns>a geometry morphism</Returns> <Description> <Example> </Example> </Description> </ManSection> <ManSection> <Oper Name="VeroneseMap" Arg="n, q"/> <Oper Name="VeroneseMap" Arg="n, F"/> <Oper Name="VeroneseMap" Arg="ps"/> <Returns>a geometry morphism</Returns> <Description> <Example> gap> pg:=ProjectiveSpace(3,3); PG(3, 3) gap> vmap:=VeroneseMap(pg); <geometry morphism from <points of PG(3, 3)> to <points of Ver(9, 3)>> gap> p:=Random(Points(pg)); <a point in PG(3, 3)> gap> p^vmap; <a point in Ver(9, 3)> </Example> </Description> </ManSection>
-->
¤ Dauer der Verarbeitung: 0.36 Sekunden
(vorverarbeitet)
¤
Die Informationen auf dieser Webseite wurden
nach bestem Wissen sorgfältig zusammengestellt. Es wird jedoch weder Vollständigkeit, noch Richtigkeit,
noch Qualität der bereit gestellten Informationen zugesichert.
Bemerkung:
Die farbliche Syntaxdarstellung ist noch experimentell.
