The FrΓ©chet-Riesz representation theorem #
We consider an inner product space E
over π
, which is either β
or β
. We define
toDualMap
, a conjugate-linear isometric embedding of E
into its dual, which maps an element
x
of the space to fun y => βͺx, yβ«
.
Under the hypothesis of completeness (i.e., for Hilbert spaces), we upgrade this to toDual
, a
conjugate-linear isometric equivalence of E
onto its dual; that is, we establish the
surjectivity of toDualMap
. This is the FrΓ©chet-Riesz representation theorem: every element of
the dual of a Hilbert space E
has the form fun u => βͺx, uβ«
for some x : E
.
For a bounded sesquilinear form B : E βLβ[π] E βL[π] π
,
we define a map InnerProductSpace.continuousLinearMapOfBilin B : E βL[π] E
,
given by substituting E βL[π] π
with E
using toDual
.
References #
- [M. Einsiedler and T. Ward, Functional Analysis, Spectral Theory, and Applications] [EinsiedlerWard2017]
Tags #
dual, FrΓ©chet-Riesz
An element x
of an inner product space E
induces an element of the dual space Dual π E
,
the map fun y => βͺx, yβ«
; moreover this operation is a conjugate-linear isometric embedding of E
into Dual π E
.
If E
is complete, this operation is surjective, hence a conjugate-linear isometric equivalence;
see toDual
.
Equations
- InnerProductSpace.toDualMap π E = let __src := innerSL π; { toLinearMap := β__src, norm_map' := β― }
Instances For
FrΓ©chet-Riesz representation: any β
in the dual of a Hilbert space E
is of the form
fun u => βͺy, uβ«
for some y : E
, i.e. toDualMap
is surjective.
Equations
- InnerProductSpace.toDual π E = LinearIsometryEquiv.ofSurjective (InnerProductSpace.toDualMap π E) β―
Instances For
Maps a bounded sesquilinear form to its continuous linear map,
given by interpreting the form as a map B : E βLβ[π] NormedSpace.Dual π E
and dualizing the result using toDual
.
Equations
- InnerProductSpace.continuousLinearMapOfBilin B = (β(InnerProductSpace.toDual π E).symm.toContinuousLinearEquiv).comp B