Safe Haskell	Safe-Infered

Numeric.Covector

Contents

Synopsis

Documentation

Linear functionals from elements of an (infinite) free module to a scalar

Constructors

Covector ((a -> r) -> r)

Instances

RightModule r s => RightModule r (Covector s m)
LeftModule r s => LeftModule r (Covector s m)
Monad (Covector r)
Functor (Covector r)
Monoidal r => MonadPlus (Covector r)
Applicative (Covector r)
Monoidal r => Alternative (Covector r)
Monoidal r => Plus (Covector r)
Additive r => Alt (Covector r)
Apply (Covector r)
Bind (Covector r)
Idempotent r => Idempotent (Covector r a)
Abelian s => Abelian (Covector s a)
Additive r => Additive (Covector r a)
Monoidal s => Monoidal (Covector s a)
Coalgebra r m => Semiring (Covector r m)
Coalgebra r m => Multiplicative (Covector r m)
Group s => Group (Covector s a)
CounitalCoalgebra r m => Unital (Covector r m)
(Idempotent r, IdempotentCoalgebra r a) => Band (Covector r a)
(Rig r, CounitalCoalgebra r m) => Rig (Covector r m)
(Ring r, CounitalCoalgebra r m) => Ring (Covector r m)
(Commutative m, Coalgebra r m) => Commutative (Covector r m)
Distinguished a => Distinguished (Covector r a)
Complicated a => Complicated (Covector r a)
Hamiltonian a => Hamiltonian (Covector r a)
Infinitesimal a => Infinitesimal (Covector r a)
Hyperbolic a => Hyperbolic (Covector r a)
Trigonometric a => Trigonometric (Covector r a)
Coalgebra r m => RightModule (Covector r m) (Covector r m)
Coalgebra r m => LeftModule (Covector r m) (Covector r m)

Covectors as linear functionals

convolveM antipodeM return = convolveM return antipodeM = comultM >=> uncurry joinM

convolveM :: (Algebra r c, Coalgebra r a) => (c -> Covector r a) -> (c -> Covector r a) -> c -> Covector r aSource