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Cremona : Index

A B C D E F G H I J K L M N O P Q R S T U V W X Y Z

? Ideal -- describe a rational map
abstractRationalMap -- make an abstract rational map
abstractRationalMap(PolynomialRing,PolynomialRing,FunctionClosure) -- make an abstract rational map
abstractRationalMap(PolynomialRing,PolynomialRing,FunctionClosure,ZZ) -- make an abstract rational map
abstractRationalMap(RationalMap) -- make an abstract rational map
approximateInverseMap -- random map related to the inverse of a birational map
approximateInverseMap(...,Certify=>...) -- whether to ensure correctness of output
approximateInverseMap(...,CodimBsInv=>...)
approximateInverseMap(...,Verbose=>...)
approximateInverseMap(RationalMap) -- random map related to the inverse of a birational map
approximateInverseMap(RationalMap,ZZ) -- random map related to the inverse of a birational map
approximateInverseMap(RingMap) -- random map related to the inverse of a birational map
approximateInverseMap(RingMap,ZZ) -- random map related to the inverse of a birational map
BlowUpStrategy
Certify -- whether to ensure correctness of output
ChernSchwartzMacPherson -- Chern-Schwartz-MacPherson class of a projective scheme
ChernSchwartzMacPherson(...,BlowUpStrategy=>...)
ChernSchwartzMacPherson(...,Certify=>...) -- whether to ensure correctness of output
ChernSchwartzMacPherson(...,Verbose=>...)
ChernSchwartzMacPherson(Ideal) -- Chern-Schwartz-MacPherson class of a projective scheme
CodimBsInv
coefficientRing(RationalMap) -- coefficient ring of a rational map
coefficients(RationalMap) -- coefficient matrix of a rational map
compose(RationalMap,RationalMap) -- composition of rational maps
compose(RingMap,RingMap) -- composition of rational maps
Cremona -- package for some computations on rational maps between projective varieties
degree(RationalMap) -- degree of a rational map
degreeMap -- degree of a rational map between projective varieties
degreeMap(...,BlowUpStrategy=>...)
degreeMap(...,Certify=>...) -- whether to ensure correctness of output
degreeMap(...,Verbose=>...)
degreeMap(RationalMap) -- degree of a rational map
degreeMap(RingMap) -- degree of a rational map between projective varieties
degrees(RationalMap) -- projective degrees of a rational map
describe(RationalMap) -- describe a rational map
Dominant
entries(RationalMap) -- the entries of the matrix associated to a rational map
EulerCharacteristic -- topological Euler characteristic of a (smooth) projective variety
EulerCharacteristic(...,BlowUpStrategy=>...)
EulerCharacteristic(...,Certify=>...) -- whether to ensure correctness of output
EulerCharacteristic(...,Verbose=>...)
EulerCharacteristic(Ideal) -- topological Euler characteristic of a (smooth) projective variety
exceptionalLocus -- exceptional locus of a birational map
exceptionalLocus(...,Certify=>...) -- whether to ensure correctness of output
exceptionalLocus(RationalMap) -- exceptional locus of a birational map
flatten(RationalMap) -- write source and target as nondegenerate varieties
forceImage -- declare which is the image of a rational map
forceImage(RationalMap,Ideal) -- declare which is the image of a rational map
forceInverseMap -- declare that two rational maps are one the inverse of the other
forceInverseMap(RationalMap,RationalMap) -- declare that two rational maps are one the inverse of the other
graph -- closure of the graph of a rational map
graph(...,BlowUpStrategy=>...)
graph(RationalMap) -- closure of the graph of a rational map
graph(RingMap) -- closure of the graph of a rational map
ideal(RationalMap) -- base locus of a rational map
image(RationalMap) -- closure of the image of a rational map
image(RationalMap,String) -- closure of the image of a rational map using the F4 algorithm (experimental)
image(RationalMap,ZZ) -- closure of the image of a rational map
inverse(RationalMap) -- inverse of a birational map
inverse(RationalMap,Option) -- inverse of a birational map
inverseMap -- inverse of a birational map
inverseMap(...,BlowUpStrategy=>...)
inverseMap(...,Certify=>...) -- whether to ensure correctness of output
inverseMap(...,Verbose=>...)
inverseMap(RationalMap) -- inverse of a birational map
inverseMap(RingMap) -- inverse of a birational map
isBirational -- whether a rational map is birational
isBirational(...,BlowUpStrategy=>...)
isBirational(...,Certify=>...) -- whether to ensure correctness of output
isBirational(...,Verbose=>...)
isBirational(RationalMap) -- whether a rational map is birational
isBirational(RingMap) -- whether a rational map is birational
isDominant -- whether a rational map is dominant
isDominant(...,Certify=>...) -- whether to ensure correctness of output
isDominant(...,Verbose=>...)
isDominant(RationalMap) -- whether a rational map is dominant
isDominant(RingMap) -- whether a rational map is dominant
isInverseMap -- checks whether a rational map is the inverse of another
isInverseMap(RationalMap,RationalMap) -- checks whether two rational maps are one the inverse of the other
isInverseMap(RingMap,RingMap) -- checks whether a rational map is the inverse of another
isIsomorphism(RationalMap) -- whether a birational map is an isomorphism
isMorphism -- whether a rational map is a morphism
isMorphism(RationalMap) -- whether a rational map is a morphism
kernel(RingMap,ZZ) -- homogeneous components of the kernel of a homogeneous ring map
map(RationalMap) -- get the ring map defining a rational map
map(ZZ,RationalMap) -- get the ring map defining a rational map
matrix(RationalMap) -- the matrix associated to a rational map
matrix(ZZ,RationalMap) -- the matrix associated to a rational map
multidegree(RationalMap) -- projective degrees of a rational map
NumDegrees
parametrize -- parametrization of a rational projective variety
parametrize(Ideal) -- parametrization of linear varieties and hyperquadrics
parametrize(PolynomialRing) -- parametrization of linear varieties and hyperquadrics
parametrize(QuotientRing) -- parametrization of linear varieties and hyperquadrics
point -- pick a random rational point on a projective variety
point(PolynomialRing) -- pick a random rational point on a projective variety
point(QuotientRing) -- pick a random rational point on a projective variety
projectiveDegrees -- projective degrees of a rational map between projective varieties
projectiveDegrees(...,BlowUpStrategy=>...)
projectiveDegrees(...,Certify=>...) -- whether to ensure correctness of output
projectiveDegrees(...,NumDegrees=>...)
projectiveDegrees(...,Verbose=>...)
projectiveDegrees(RationalMap) -- projective degrees of a rational map
projectiveDegrees(RingMap) -- projective degrees of a rational map between projective varieties
quadroQuadricCremonaTransformation -- quadro-quadric Cremona transformations
quadroQuadricCremonaTransformation(Ring,ZZ,ZZ) -- quadro-quadric Cremona transformations
quadroQuadricCremonaTransformation(ZZ,ZZ) -- quadro-quadric Cremona transformations
quadroQuadricCremonaTransformation(ZZ,ZZ,Ring) -- quadro-quadric Cremona transformations
RationalMap -- the class of all rational maps between absolutely irreducible projective varieties over a field
rationalMap -- makes a rational map
RationalMap ! -- calculates every possible thing
RationalMap * RationalMap -- composition of rational maps
RationalMap ** Ring -- change the coefficient ring of a rational map
RationalMap == RationalMap -- equality of rational maps
RationalMap == ZZ -- equality of rational maps
RationalMap ^ ZZ -- power
RationalMap ^* -- inverse image via a rational map
RationalMap ^** Ideal -- inverse image via a rational map
RationalMap _* -- direct image via a rational map
RationalMap | Ideal -- restriction of a rational map
RationalMap | Ring -- restriction of a rational map
RationalMap | RingElement -- restriction of a rational map
RationalMap || Ideal -- restriction of a rational map
RationalMap || Ring -- restriction of a rational map
RationalMap || RingElement -- restriction of a rational map
RationalMap Ideal -- direct image via a rational map
rationalMap(...,Dominant=>...)
rationalMap(Ideal) -- makes a rational map from an ideal
rationalMap(Ideal,List) -- makes a rational map from an ideal
rationalMap(Ideal,ZZ) -- makes a rational map from an ideal
rationalMap(Ideal,ZZ,ZZ) -- makes a rational map from an ideal
rationalMap(List) -- makes a rational map
rationalMap(Matrix) -- makes a rational map
rationalMap(PolynomialRing,List) -- rational map defined by the linear system of hypersurfaces passing through random points with multiplicity
rationalMap(RationalMap) -- get the rational map whose target is a projective space
rationalMap(Ring) -- makes a rational map
rationalMap(Ring,Ring) -- makes a rational map
rationalMap(Ring,Ring,List) -- makes a rational map
rationalMap(Ring,Ring,Matrix) -- makes a rational map
rationalMap(Ring,Tally) -- rational map defined by an effective divisor
rationalMap(RingMap) -- makes a rational map
rationalMap(Tally) -- rational map defined by an effective divisor
segre -- Segre embedding
segre(PolynomialRing) -- Segre embedding
segre(QuotientRing) -- Segre embedding
segre(RationalMap) -- Segre embedding
SegreClass -- Segre class of a closed subscheme of a projective variety
SegreClass(...,BlowUpStrategy=>...)
SegreClass(...,Certify=>...) -- whether to ensure correctness of output
SegreClass(...,Verbose=>...)
SegreClass(Ideal) -- Segre class of a closed subscheme of a projective variety
SegreClass(RationalMap) -- Segre class of a closed subscheme of a projective variety
SegreClass(RingMap) -- Segre class of a closed subscheme of a projective variety
source(RationalMap) -- coordinate ring of the source for a rational map
specialCremonaTransformation -- special Cremona transformations whose base locus has dimension at most three
specialCremonaTransformation(Ring,ZZ) -- special Cremona transformations whose base locus has dimension at most three
specialCremonaTransformation(ZZ) -- special Cremona transformations whose base locus has dimension at most three
specialCremonaTransformation(ZZ,Ring) -- special Cremona transformations whose base locus has dimension at most three
specialCubicTransformation -- special cubic transformations whose base locus has dimension at most three
specialCubicTransformation(Ring,ZZ) -- special cubic transformations whose base locus has dimension at most three
specialCubicTransformation(ZZ) -- special cubic transformations whose base locus has dimension at most three
specialCubicTransformation(ZZ,Ring) -- special cubic transformations whose base locus has dimension at most three
specialQuadraticTransformation -- special quadratic transformations whose base locus has dimension three
specialQuadraticTransformation(Ring,ZZ) -- special quadratic transformations whose base locus has dimension three
specialQuadraticTransformation(ZZ) -- special quadratic transformations whose base locus has dimension three
specialQuadraticTransformation(ZZ,Ring) -- special quadratic transformations whose base locus has dimension three
substitute(RationalMap,PolynomialRing,PolynomialRing) -- substitute the ambient projective spaces of source and target
super(RationalMap) -- get the rational map whose target is a projective space
target(RationalMap) -- coordinate ring of the target for a rational map
toExternalString(RationalMap) -- convert to a readable string
toMap -- rational map defined by a linear system
toMap(...,Dominant=>...)
toMap(Ideal) -- rational map defined by a linear system
toMap(Ideal,List) -- rational map defined by a linear system
toMap(Ideal,ZZ) -- rational map defined by a linear system
toMap(Ideal,ZZ,ZZ) -- rational map defined by a linear system
toMap(List) -- rational map defined by a linear system
toMap(Matrix) -- rational map defined by a linear system
toMap(RingMap) -- rational map defined by a linear system
ZZ == RationalMap -- equality of rational maps