JetBundleXExpression JB¶

JB: JetBundleCategory

JetBundleXExpression implements arbitrary functions in a jet bundle which depend only on the independent variables x. Otherwise it is identical with JetBundleExpression. Such a domain is needed for JetLinearFunction.

0: %: from AbelianMonoid

1: %: from MagmaWithUnit

*: (%, %) -> %: from Magma
*: (%, Fraction Integer) -> %: from RightModule Fraction Integer
*: (%, Integer) -> %: from RightModule Integer
*: (Fraction Integer, %) -> %: from LeftModule Fraction Integer
*: (Integer, %) -> %: from AbelianGroup
*: (NonNegativeInteger, %) -> %: from AbelianMonoid
*: (PositiveInteger, %) -> %: from AbelianSemiGroup

+: (%, %) -> %: from AbelianSemiGroup

-: % -> %: from AbelianGroup
-: (%, %) -> %: from AbelianGroup

/: (%, %) -> %: from Group
/: (SparseMultivariatePolynomial(Integer, Kernel %), SparseMultivariatePolynomial(Integer, Kernel %)) -> %: from FunctionSpace Integer

=: (%, %) -> Boolean: from BasicType

^: (%, %) -> %: from ElementaryFunctionCategory
^: (%, Fraction Integer) -> %: from RadicalCategory
^: (%, Integer) -> %: from Group
^: (%, NonNegativeInteger) -> %: from MagmaWithUnit
^: (%, PositiveInteger) -> %: from Magma

~=: (%, %) -> Boolean: from BasicType

abs: % -> %: from SpecialFunctionCategory

acos: % -> %: from ArcTrigonometricFunctionCategory

acosh: % -> %: from ArcHyperbolicFunctionCategory

acot: % -> %: from ArcTrigonometricFunctionCategory

acoth: % -> %: from ArcHyperbolicFunctionCategory

acsc: % -> %: from ArcTrigonometricFunctionCategory

acsch: % -> %: from ArcHyperbolicFunctionCategory

airyAi: % -> %: from SpecialFunctionCategory

airyAiPrime: % -> %: from SpecialFunctionCategory

airyBi: % -> %: from SpecialFunctionCategory

airyBiPrime: % -> %: from SpecialFunctionCategory

algtower: % -> List Kernel %: from FunctionSpace Integer
algtower: List % -> List Kernel %: from FunctionSpace Integer

angerJ: (%, %) -> %: from SpecialFunctionCategory

annihilate?: (%, %) -> Boolean: from Rng

antiCommutator: (%, %) -> %: from NonAssociativeSemiRng

applyQuote: (Symbol, %) -> %: from FunctionSpace Integer
applyQuote: (Symbol, %, %) -> %: from FunctionSpace Integer
applyQuote: (Symbol, %, %, %) -> %: from FunctionSpace Integer
applyQuote: (Symbol, %, %, %, %) -> %: from FunctionSpace Integer
applyQuote: (Symbol, List %) -> %: from FunctionSpace Integer

asec: % -> %: from ArcTrigonometricFunctionCategory

asech: % -> %: from ArcHyperbolicFunctionCategory

asin: % -> %: from ArcTrigonometricFunctionCategory

asinh: % -> %: from ArcHyperbolicFunctionCategory

associates?: (%, %) -> Boolean: from EntireRing

associator: (%, %, %) -> %: from NonAssociativeRng

atan: % -> %: from ArcTrigonometricFunctionCategory

atanh: % -> %: from ArcHyperbolicFunctionCategory

autoReduce: List % -> List %: from JetBundleFunctionCategory JB

belong?: BasicOperator -> Boolean: from ExpressionSpace

besselI: (%, %) -> %: from SpecialFunctionCategory

besselJ: (%, %) -> %: from SpecialFunctionCategory

besselK: (%, %) -> %: from SpecialFunctionCategory

besselY: (%, %) -> %: from SpecialFunctionCategory

Beta: (%, %) -> %: from SpecialFunctionCategory
Beta: (%, %, %) -> %: from SpecialFunctionCategory

binomial: (%, %) -> %: from CombinatorialFunctionCategory

box: % -> %: from ExpressionSpace

ceiling: % -> %: from SpecialFunctionCategory

characteristic: () -> NonNegativeInteger: from NonAssociativeRing

charlierC: (%, %, %) -> %: from SpecialFunctionCategory

charthRoot: % -> Union(%, failed) if Integer has CharacteristicNonZero: from CharacteristicNonZero

Chi: % -> %: from LiouvillianFunctionCategory

Ci: % -> %: from LiouvillianFunctionCategory

class: % -> NonNegativeInteger: from JetBundleFunctionCategory JB

coerce: % -> %: from Algebra %

coerce: % -> Expression Integer

coerce: % -> OutputForm: from CoercibleTo OutputForm
coerce: AlgebraicNumber -> %: from CoercibleFrom AlgebraicNumber

coerce: Expression Integer -> %

coerce: Fraction Integer -> %: from FunctionSpace Integer
coerce: Fraction Polynomial Fraction Integer -> %: from FunctionSpace Integer
coerce: Fraction Polynomial Integer -> %: from CoercibleFrom Fraction Polynomial Integer
coerce: Integer -> %: from NonAssociativeRing
coerce: JB -> %: from JetBundleFunctionCategory JB
coerce: Kernel % -> %: from CoercibleFrom Kernel %
coerce: Polynomial Fraction Integer -> %: from FunctionSpace Integer
coerce: Polynomial Integer -> %: from CoercibleFrom Polynomial Integer
coerce: SparseMultivariatePolynomial(Integer, Kernel %) -> %: from FunctionSpace Integer
coerce: Symbol -> %: from CoercibleFrom Symbol

commutator: (%, %) -> %: from NonAssociativeRng

conjugate: % -> %: from SpecialFunctionCategory
conjugate: (%, %) -> % if Integer has Group: from Group

const?: % -> Boolean: from JetBundleFunctionCategory JB

convert: % -> InputForm: from ConvertibleTo InputForm
convert: % -> Pattern Float if Integer has ConvertibleTo Pattern Float: from ConvertibleTo Pattern Float
convert: % -> Pattern Integer: from ConvertibleTo Pattern Integer
convert: Factored % -> %: from FunctionSpace Integer

cos: % -> %: from TrigonometricFunctionCategory

cosh: % -> %: from HyperbolicFunctionCategory

cot: % -> %: from TrigonometricFunctionCategory

coth: % -> %: from HyperbolicFunctionCategory

csc: % -> %: from TrigonometricFunctionCategory

csch: % -> %: from HyperbolicFunctionCategory

D: (%, List Symbol) -> %: from PartialDifferentialRing Symbol
D: (%, List Symbol, List NonNegativeInteger) -> %: from PartialDifferentialRing Symbol
D: (%, Symbol) -> %: from PartialDifferentialRing Symbol
D: (%, Symbol, NonNegativeInteger) -> %: from PartialDifferentialRing Symbol

definingPolynomial: % -> %: from ExpressionSpace

denom: % -> SparseMultivariatePolynomial(Integer, Kernel %): from FunctionSpace Integer

denominator: % -> %: from FunctionSpace Integer

differentiate: (%, JB) -> %: from JetBundleFunctionCategory JB
differentiate: (%, List Symbol) -> %: from PartialDifferentialRing Symbol
differentiate: (%, List Symbol, List NonNegativeInteger) -> %: from PartialDifferentialRing Symbol
differentiate: (%, Symbol) -> %: from PartialDifferentialRing Symbol
differentiate: (%, Symbol, NonNegativeInteger) -> %: from PartialDifferentialRing Symbol

digamma: % -> %: from SpecialFunctionCategory

dilog: % -> %: from LiouvillianFunctionCategory

dimension: (List %, SparseEchelonMatrix(JB, %), NonNegativeInteger) -> NonNegativeInteger: from JetBundleFunctionCategory JB

diracDelta: % -> %: from SpecialFunctionCategory

distribute: % -> %: from ExpressionSpace
distribute: (%, %) -> %: from ExpressionSpace

divide: (%, %) -> Record(quotient: %, remainder: %): from EuclideanDomain

dSubst: (%, JB, %) -> %: from JetBundleFunctionCategory JB

Ei: % -> %: from LiouvillianFunctionCategory

ellipticE: % -> %: from SpecialFunctionCategory
ellipticE: (%, %) -> %: from SpecialFunctionCategory

ellipticF: (%, %) -> %: from SpecialFunctionCategory

ellipticK: % -> %: from SpecialFunctionCategory

ellipticPi: (%, %, %) -> %: from SpecialFunctionCategory

elt: (BasicOperator, %) -> %: from ExpressionSpace
elt: (BasicOperator, %, %) -> %: from ExpressionSpace
elt: (BasicOperator, %, %, %) -> %: from ExpressionSpace
elt: (BasicOperator, %, %, %, %) -> %: from ExpressionSpace
elt: (BasicOperator, %, %, %, %, %) -> %: from ExpressionSpace
elt: (BasicOperator, %, %, %, %, %, %) -> %: from ExpressionSpace
elt: (BasicOperator, %, %, %, %, %, %, %) -> %: from ExpressionSpace
elt: (BasicOperator, %, %, %, %, %, %, %, %) -> %: from ExpressionSpace
elt: (BasicOperator, %, %, %, %, %, %, %, %, %) -> %: from ExpressionSpace
elt: (BasicOperator, List %) -> %: from ExpressionSpace

erf: % -> %: from LiouvillianFunctionCategory

erfi: % -> %: from LiouvillianFunctionCategory

euclideanSize: % -> NonNegativeInteger: from EuclideanDomain

eval: (%, %, %) -> %: from InnerEvalable(%, %)
eval: (%, BasicOperator, % -> %) -> %: from ExpressionSpace
eval: (%, BasicOperator, %, Symbol) -> %: from FunctionSpace Integer
eval: (%, BasicOperator, List % -> %) -> %: from ExpressionSpace
eval: (%, Equation %) -> %: from Evalable %
eval: (%, Kernel %, %) -> %: from InnerEvalable(Kernel %, %)
eval: (%, List %, List %) -> %: from InnerEvalable(%, %)
eval: (%, List BasicOperator, List %, Symbol) -> %: from FunctionSpace Integer
eval: (%, List BasicOperator, List(% -> %)) -> %: from ExpressionSpace
eval: (%, List BasicOperator, List(List % -> %)) -> %: from ExpressionSpace
eval: (%, List Equation %) -> %: from Evalable %
eval: (%, List Kernel %, List %) -> %: from InnerEvalable(Kernel %, %)
eval: (%, List Symbol, List NonNegativeInteger, List(% -> %)) -> %: from FunctionSpace Integer
eval: (%, List Symbol, List NonNegativeInteger, List(List % -> %)) -> %: from FunctionSpace Integer
eval: (%, List Symbol, List(% -> %)) -> %: from ExpressionSpace
eval: (%, List Symbol, List(List % -> %)) -> %: from ExpressionSpace
eval: (%, Symbol, % -> %) -> %: from ExpressionSpace
eval: (%, Symbol, List % -> %) -> %: from ExpressionSpace
eval: (%, Symbol, NonNegativeInteger, % -> %) -> %: from FunctionSpace Integer
eval: (%, Symbol, NonNegativeInteger, List % -> %) -> %: from FunctionSpace Integer

even?: % -> Boolean: from ExpressionSpace

exp: % -> %: from ElementaryFunctionCategory

expressIdealMember: (List %, %) -> Union(List %, failed): from PrincipalIdealDomain

exquo: (%, %) -> Union(%, failed): from EntireRing

extendedEuclidean: (%, %) -> Record(coef1: %, coef2: %, generator: %): from EuclideanDomain
extendedEuclidean: (%, %, %) -> Union(Record(coef1: %, coef2: %), failed): from EuclideanDomain

extractSymbol: SparseEchelonMatrix(JB, %) -> SparseEchelonMatrix(JB, %): from JetBundleFunctionCategory JB

factor: % -> Factored %: from UniqueFactorizationDomain

factorial: % -> %: from CombinatorialFunctionCategory

factorials: % -> %: from CombinatorialOpsCategory
factorials: (%, Symbol) -> %: from CombinatorialOpsCategory

floor: % -> %: from SpecialFunctionCategory

formalDiff2: (%, PositiveInteger, SparseEchelonMatrix(JB, %)) -> Record(DPhi: %, JVars: List JB): from JetBundleFunctionCategory JB
formalDiff2: (List %, PositiveInteger, SparseEchelonMatrix(JB, %)) -> Record(DSys: List %, JVars: List List JB): from JetBundleFunctionCategory JB

formalDiff: (%, List NonNegativeInteger) -> %: from JetBundleFunctionCategory JB
formalDiff: (%, PositiveInteger) -> %: from JetBundleFunctionCategory JB
formalDiff: (List %, PositiveInteger) -> List %: from JetBundleFunctionCategory JB

fractionPart: % -> %: from SpecialFunctionCategory

freeOf?: (%, %) -> Boolean: from ExpressionSpace
freeOf?: (%, JB) -> Boolean: from JetBundleFunctionCategory JB
freeOf?: (%, Symbol) -> Boolean: from ExpressionSpace

fresnelC: % -> %: from LiouvillianFunctionCategory

fresnelS: % -> %: from LiouvillianFunctionCategory

function: (Symbol, List %) -> %: function(f, arg) generates a function with name f and arguments arg.

Gamma: % -> %: from SpecialFunctionCategory
Gamma: (%, %) -> %: from SpecialFunctionCategory

gcd: (%, %) -> %: from GcdDomain
gcd: List % -> %: from GcdDomain

gcdPolynomial: (SparseUnivariatePolynomial %, SparseUnivariatePolynomial %) -> SparseUnivariatePolynomial %: from GcdDomain

getNotation: () -> Symbol: from JetBundleFunctionCategory JB

ground?: % -> Boolean: from FunctionSpace Integer

ground: % -> Integer: from FunctionSpace Integer

hankelH1: (%, %) -> %: from SpecialFunctionCategory

hankelH2: (%, %) -> %: from SpecialFunctionCategory

height: % -> NonNegativeInteger: from ExpressionSpace

hermiteH: (%, %) -> %: from SpecialFunctionCategory

hypergeometricF: (List %, List %, %) -> %: from SpecialFunctionCategory

integral: (%, SegmentBinding %) -> %: from PrimitiveFunctionCategory
integral: (%, Symbol) -> %: from PrimitiveFunctionCategory

inv: % -> %: from Group

is?: (%, BasicOperator) -> Boolean: from ExpressionSpace
is?: (%, Symbol) -> Boolean: from ExpressionSpace

isExpt: % -> Union(Record(var: Kernel %, exponent: Integer), failed): from FunctionSpace Integer
isExpt: (%, BasicOperator) -> Union(Record(var: Kernel %, exponent: Integer), failed): from FunctionSpace Integer
isExpt: (%, Symbol) -> Union(Record(var: Kernel %, exponent: Integer), failed): from FunctionSpace Integer

isMult: % -> Union(Record(coef: Integer, var: Kernel %), failed): from FunctionSpace Integer

isPlus: % -> Union(List %, failed): from FunctionSpace Integer

isPower: % -> Union(Record(val: %, exponent: Integer), failed): from FunctionSpace Integer

isTimes: % -> Union(List %, failed): from FunctionSpace Integer

jacobiCn: (%, %) -> %: from SpecialFunctionCategory

jacobiDn: (%, %) -> %: from SpecialFunctionCategory

jacobiMatrix: (List %, List List JB) -> SparseEchelonMatrix(JB, %): from JetBundleFunctionCategory JB
jacobiMatrix: List % -> SparseEchelonMatrix(JB, %): from JetBundleFunctionCategory JB

jacobiP: (%, %, %, %) -> %: from SpecialFunctionCategory

jacobiSn: (%, %) -> %: from SpecialFunctionCategory

jacobiTheta: (%, %) -> %: from SpecialFunctionCategory

jacobiZeta: (%, %) -> %: from SpecialFunctionCategory

jetVariables: % -> List JB: from JetBundleFunctionCategory JB

kelvinBei: (%, %) -> %: from SpecialFunctionCategory

kelvinBer: (%, %) -> %: from SpecialFunctionCategory

kelvinKei: (%, %) -> %: from SpecialFunctionCategory

kelvinKer: (%, %) -> %: from SpecialFunctionCategory

kernel: (BasicOperator, %) -> %: from ExpressionSpace
kernel: (BasicOperator, List %) -> %: from ExpressionSpace

kernels: % -> List Kernel %: from ExpressionSpace
kernels: List % -> List Kernel %: from ExpressionSpace

kummerM: (%, %, %) -> %: from SpecialFunctionCategory

kummerU: (%, %, %) -> %: from SpecialFunctionCategory

laguerreL: (%, %, %) -> %: from SpecialFunctionCategory

lambertW: % -> %: from SpecialFunctionCategory

latex: % -> String: from SetCategory

lcm: (%, %) -> %: from GcdDomain
lcm: List % -> %: from GcdDomain

lcmCoef: (%, %) -> Record(llcm_res: %, coeff1: %, coeff2: %): from LeftOreRing

leadingDer: % -> JB: from JetBundleFunctionCategory JB

leftPower: (%, NonNegativeInteger) -> %: from MagmaWithUnit
leftPower: (%, PositiveInteger) -> %: from Magma

leftRecip: % -> Union(%, failed): from MagmaWithUnit

legendreP: (%, %, %) -> %: from SpecialFunctionCategory

legendreQ: (%, %, %) -> %: from SpecialFunctionCategory

lerchPhi: (%, %, %) -> %: from SpecialFunctionCategory

li: % -> %: from LiouvillianFunctionCategory

log: % -> %: from ElementaryFunctionCategory

lommelS1: (%, %, %) -> %: from SpecialFunctionCategory

lommelS2: (%, %, %) -> %: from SpecialFunctionCategory

mainKernel: % -> Union(Kernel %, failed): from ExpressionSpace

map: (% -> %, Kernel %) -> %: from ExpressionSpace

meijerG: (List %, List %, List %, List %, %) -> %: from SpecialFunctionCategory

meixnerM: (%, %, %, %) -> %: from SpecialFunctionCategory

minPoly: Kernel % -> SparseUnivariatePolynomial %: from ExpressionSpace

multiEuclidean: (List %, %) -> Union(List %, failed): from EuclideanDomain

nthRoot: (%, Integer) -> %: from RadicalCategory

numDepVar: () -> PositiveInteger: from JetBundleFunctionCategory JB

numer: % -> SparseMultivariatePolynomial(Integer, Kernel %): from FunctionSpace Integer

numerator: % -> %: from FunctionSpace Integer

numIndVar: () -> PositiveInteger: from JetBundleFunctionCategory JB

odd?: % -> Boolean: from ExpressionSpace

one?: % -> Boolean: from MagmaWithUnit

operator: BasicOperator -> BasicOperator: from ExpressionSpace

operators: % -> List BasicOperator: from ExpressionSpace

opposite?: (%, %) -> Boolean: from AbelianMonoid

order: % -> NonNegativeInteger: from JetBundleFunctionCategory JB

orderDim: (List %, SparseEchelonMatrix(JB, %), NonNegativeInteger) -> NonNegativeInteger: from JetBundleFunctionCategory JB

P: (PositiveInteger, List NonNegativeInteger) -> %: from JetBundleFunctionCategory JB
P: (PositiveInteger, NonNegativeInteger) -> %: from JetBundleFunctionCategory JB
P: List NonNegativeInteger -> %: from JetBundleFunctionCategory JB
P: NonNegativeInteger -> %: from JetBundleFunctionCategory JB

paren: % -> %: from ExpressionSpace

patternMatch: (%, Pattern Float, PatternMatchResult(Float, %)) -> PatternMatchResult(Float, %) if Integer has PatternMatchable Float: from PatternMatchable Float
patternMatch: (%, Pattern Integer, PatternMatchResult(Integer, %)) -> PatternMatchResult(Integer, %): from PatternMatchable Integer

permutation: (%, %) -> %: from CombinatorialFunctionCategory

pi: () -> %: from TranscendentalFunctionCategory

plenaryPower: (%, PositiveInteger) -> %: from NonAssociativeAlgebra Integer

polygamma: (%, %) -> %: from SpecialFunctionCategory

polylog: (%, %) -> %: from SpecialFunctionCategory

prime?: % -> Boolean: from UniqueFactorizationDomain

principalIdeal: List % -> Record(coef: List %, generator: %): from PrincipalIdealDomain

product: (%, SegmentBinding %) -> %: from CombinatorialOpsCategory
product: (%, Symbol) -> %: from CombinatorialOpsCategory

quo: (%, %) -> %: from EuclideanDomain

recip: % -> Union(%, failed): from MagmaWithUnit

reduce: % -> %: reduce(x) reduces the algebraics in x.

reducedSystem: (Matrix %, Vector %) -> Record(mat: Matrix Integer, vec: Vector Integer): from LinearlyExplicitOver Integer
reducedSystem: Matrix % -> Matrix Integer: from LinearlyExplicitOver Integer

reduceMod: (List %, List %) -> List %: from JetBundleFunctionCategory JB

rem: (%, %) -> %: from EuclideanDomain

retract: % -> AlgebraicNumber: from RetractableTo AlgebraicNumber
retract: % -> Fraction Integer: from RetractableTo Fraction Integer
retract: % -> Fraction Polynomial Integer: from RetractableTo Fraction Polynomial Integer
retract: % -> Integer: from RetractableTo Integer
retract: % -> JB: from RetractableTo JB
retract: % -> Kernel %: from RetractableTo Kernel %
retract: % -> Polynomial Integer: from RetractableTo Polynomial Integer
retract: % -> Symbol: from RetractableTo Symbol

retract: JetBundleExpression JB -> %: retract(p) is like retractIfCan(p) put yields a hard error, if p contains further jet variables.

retractIfCan: % -> Union(AlgebraicNumber, failed): from RetractableTo AlgebraicNumber
retractIfCan: % -> Union(Fraction Integer, failed): from RetractableTo Fraction Integer
retractIfCan: % -> Union(Fraction Polynomial Integer, failed): from RetractableTo Fraction Polynomial Integer
retractIfCan: % -> Union(Integer, failed): from RetractableTo Integer
retractIfCan: % -> Union(JB, failed): from RetractableTo JB
retractIfCan: % -> Union(Kernel %, failed): from RetractableTo Kernel %
retractIfCan: % -> Union(Polynomial Integer, failed): from RetractableTo Polynomial Integer
retractIfCan: % -> Union(Symbol, failed): from RetractableTo Symbol

retractIfCan: JetBundleExpression JB -> Union(%, failed): retractIfCan(p) checks whether p depends only on the independent variables. If yes, it is coerced.