Operator norm for maps on normed spaces #
This file contains statements about operator norm for which it really matters that the underlying space has a norm (rather than just a seminorm).
LinearMap.bound_of_ball_bound'
is a version of this lemma over a field satisfying RCLike
that produces a concrete bound.
An operator is zero iff its norm vanishes.
Alias of ContinuousLinearMap.opNorm_zero_iff
.
An operator is zero iff its norm vanishes.
If a normed space is non-trivial, then the norm of the identity equals 1
.
Equations
- โฏ = โฏ
Continuous linear maps themselves form a normed space with respect to the operator norm.
Equations
- ContinuousLinearMap.toNormedAddCommGroup = NormedAddCommGroup.ofSeparation โฏ
Continuous linear maps form a normed ring with respect to the operator norm.
Equations
- ContinuousLinearMap.toNormedRing = let __src := ContinuousLinearMap.toNormedAddCommGroup; let __src_1 := ContinuousLinearMap.toSemiNormedRing; NormedRing.mk โฏ โฏ
If a continuous linear map is a topology embedding, then it is expands the distances by a positive factor.
Postcomposition of a continuous linear map with a linear isometry preserves the operator norm.
Precomposition with a linear isometry preserves the operator norm.
Alias of ContinuousLinearMap.opNorm_comp_linearIsometryEquiv
.
Precomposition with a linear isometry preserves the operator norm.
The norm of the tensor product of a scalar linear map and of an element of a normed space is the product of the norms.
The non-negative norm of the tensor product of a scalar linear map and of an element of a normed space is the product of the non-negative norms.
ContinuousLinearMap.smulRight
as a continuous trilinear map:
smulRightL (c : E โL[๐] ๐) (f : F) (x : E) = c x โข f
.
Equations
- ContinuousLinearMap.smulRightL ๐ E Fโ = LinearMap.mkContinuousโ { toAddHom := { toFun := ContinuousLinearMap.smulRightโ, map_add' := โฏ }, map_smul' := โฏ } 1 โฏ
Instances For
An auxiliary instance to be able to just state the fact that the norm of smulRightL
makes
sense. This shouldn't be needed. See lean4#3927.
Equations
- ContinuousLinearMap.seminormedAddCommGroup_aux_for_smulRightL ๐ E Fโ = ContinuousLinearMap.toSeminormedAddCommGroup
Instances For
A bounded bilinear form B
in a real normed space is coercive
if there is some positive constant C such that C * โuโ * โuโ โค B u u
.
Instances For
Equivalent characterizations for equicontinuity of a family of continuous linear maps
between normed spaces. See also WithSeminorms.equicontinuous_TFAE
for similar characterizations
between spaces satisfying WithSeminorms
.