mathlib documentation

analysis.normed_space.dual

The topological dual of a normed space #

In this file we define the topological dual of a normed space, and the bounded linear map from a normed space into its double dual.

We also prove that, for base field 𝕜 with [is_R_or_C 𝕜], this map is an isometry.

We then consider inner product spaces, with base field over ℝ (the corresponding results for ℂ will require the definition of conjugate-linear maps). We define to_dual_map, a continuous linear map from E to its dual, which maps an element x of the space to λ y, ⟪x, y⟫. We check (to_dual_map_isometry) that this map is an isometry onto its image, and particular is injective. We also define to_dual' as the function taking taking a vector to its dual for a base field 𝕜 with [is_R_or_C 𝕜]; this is a function and not a linear map.

Finally, under the hypothesis of completeness (i.e., for Hilbert spaces), we prove the Fréchet-Riesz representation (to_dual_map_eq_top), which states the surjectivity: every element of the dual of a Hilbert space E has the form λ u, ⟪x, u⟫ for some x : E. This permits the map to_dual_map to be upgraded to an (isometric) continuous linear equivalence, to_dual, between a Hilbert space and its dual.

Since a lot of elementary properties don't require eq_of_dist_eq_zero we start setting up the theory for semi_normed_space and we specialize to normed_space when needed.

References #

M. Einsiedler and T. Ward, Functional Analysis, Spectral Theory, and Applications

Tags #

dual, Fréchet-Riesz

@[instance]

def normed_space.dual.semi_normed_space (𝕜 : Type u_1) [nondiscrete_normed_field 𝕜] (E : Type u_2) [semi_normed_group E] [semi_normed_space 𝕜 E] :

semi_normed_space 𝕜 (normed_space.dual 𝕜 E)

def normed_space.dual (𝕜 : Type u_1) [nondiscrete_normed_field 𝕜] (E : Type u_2) [semi_normed_group E] [semi_normed_space 𝕜 E] :

Type (max u_2 u_1)

The topological dual of a seminormed space E.

Equations

normed_space.dual 𝕜 E = (E →L[𝕜] 𝕜)

@[instance]

def normed_space.dual.semi_normed_group (𝕜 : Type u_1) [nondiscrete_normed_field 𝕜] (E : Type u_2) [semi_normed_group E] [semi_normed_space 𝕜 E] :

semi_normed_group (normed_space.dual 𝕜 E)

@[instance]

def normed_space.dual.has_coe_to_fun (𝕜 : Type u_1) [nondiscrete_normed_field 𝕜] (E : Type u_2) [semi_normed_group E] [semi_normed_space 𝕜 E] :

has_coe_to_fun (normed_space.dual 𝕜 E)

@[instance]

def normed_space.dual.inhabited (𝕜 : Type u_1) [nondiscrete_normed_field 𝕜] (E : Type u_2) [semi_normed_group E] [semi_normed_space 𝕜 E] :

inhabited (normed_space.dual 𝕜 E)

Equations

normed_space.dual.inhabited 𝕜 E = {default := 0}

@[instance]

def normed_space.dual.normed_group (𝕜 : Type u_1) [nondiscrete_normed_field 𝕜] (F : Type u_3) [normed_group F] [normed_space 𝕜 F] :

normed_group (normed_space.dual 𝕜 F)

Equations

normed_space.dual.normed_group 𝕜 F = continuous_linear_map.to_normed_group

@[instance]

def normed_space.dual.normed_space (𝕜 : Type u_1) [nondiscrete_normed_field 𝕜] (F : Type u_3) [normed_group F] [normed_space 𝕜 F] :

normed_space 𝕜 (normed_space.dual 𝕜 F)

Equations

normed_space.dual.normed_space 𝕜 F = continuous_linear_map.to_normed_space

def normed_space.inclusion_in_double_dual' (𝕜 : Type u_1) [nondiscrete_normed_field 𝕜] (E : Type u_2) [semi_normed_group E] [semi_normed_space 𝕜 E] (x : E) :

normed_space.dual 𝕜 (normed_space.dual 𝕜 E)

The inclusion of a normed space in its double (topological) dual.

Equations

normed_space.inclusion_in_double_dual' 𝕜 E x = {to_fun := λ (f : normed_space.dual 𝕜 E), ⇑f x, map_add' := _, map_smul' := _}.mk_continuous ∥x∥ _

@[simp]

theorem normed_space.dual_def (𝕜 : Type u_1) [nondiscrete_normed_field 𝕜] (E : Type u_2) [semi_normed_group E] [semi_normed_space 𝕜 E] (x : E) (f : normed_space.dual 𝕜 E) :

⇑(normed_space.inclusion_in_double_dual' 𝕜 E x) f = ⇑f x

theorem normed_space.double_dual_bound (𝕜 : Type u_1) [nondiscrete_normed_field 𝕜] (E : Type u_2) [semi_normed_group E] [semi_normed_space 𝕜 E] (x : E) :

∥normed_space.inclusion_in_double_dual' 𝕜 E x∥ ≤ ∥x∥

def normed_space.inclusion_in_double_dual (𝕜 : Type u_1) [nondiscrete_normed_field 𝕜] (E : Type u_2) [semi_normed_group E] [semi_normed_space 𝕜 E] :

E →L[𝕜] normed_space.dual 𝕜 (normed_space.dual 𝕜 E)

The inclusion of a normed space in its double (topological) dual, considered as a bounded linear map.

Equations

normed_space.inclusion_in_double_dual 𝕜 E = {to_fun := λ (x : E), normed_space.inclusion_in_double_dual' 𝕜 E x, map_add' := _, map_smul' := _}.mk_continuous 1 _

theorem normed_space.norm_le_dual_bound (𝕜 : Type v) [is_R_or_C 𝕜] {E : Type u} [normed_group E] [normed_space 𝕜 E] (x : E) {M : ℝ} (hMp : 0 ≤ M) (hM : ∀ (f : normed_space.dual 𝕜 E), ∥⇑f x∥ ≤ M * ∥f∥) :

If one controls the norm of every f x, then one controls the norm of x. Compare continuous_linear_map.op_norm_le_bound.

theorem normed_space.eq_zero_of_forall_dual_eq_zero (𝕜 : Type v) [is_R_or_C 𝕜] {E : Type u} [normed_group E] [normed_space 𝕜 E] {x : E} (h : ∀ (f : normed_space.dual 𝕜 E), ⇑f x = 0) :

x = 0

theorem normed_space.eq_zero_iff_forall_dual_eq_zero (𝕜 : Type v) [is_R_or_C 𝕜] {E : Type u} [normed_group E] [normed_space 𝕜 E] (x : E) :

x = 0 ↔ ∀ (g : normed_space.dual 𝕜 E), ⇑g x = 0

theorem normed_space.eq_iff_forall_dual_eq (𝕜 : Type v) [is_R_or_C 𝕜] {E : Type u} [normed_group E] [normed_space 𝕜 E] {x y : E} :

x = y ↔ ∀ (g : normed_space.dual 𝕜 E), ⇑g x = ⇑g y

theorem normed_space.inclusion_in_double_dual_isometry (𝕜 : Type v) [is_R_or_C 𝕜] {E : Type u} [normed_group E] [normed_space 𝕜 E] (x : E) :

∥⇑(normed_space.inclusion_in_double_dual 𝕜 E) x∥ = ∥x∥

The inclusion of a normed space in its double dual is an isometry onto its image.

def inner_product_space.to_dual' (𝕜 : Type u_1) {E : Type u_2} [is_R_or_C 𝕜] [inner_product_space 𝕜 E] :

E →+ normed_space.dual 𝕜 E

Given some x in an inner product space, we can define its dual as the continuous linear map λ y, ⟪x, y⟫. Consider using to_dual or to_dual_map instead in the real case.

Equations

inner_product_space.to_dual' 𝕜 = {to_fun := λ (x : E), {to_fun := λ (y : E), inner x y, map_add' := _, map_smul' := _}.mk_continuous ∥x∥ _, map_zero' := _, map_add' := _}

@[simp]

theorem inner_product_space.to_dual'_apply (𝕜 : Type u_1) {E : Type u_2} [is_R_or_C 𝕜] [inner_product_space 𝕜 E] {x y : E} :

⇑(⇑(inner_product_space.to_dual' 𝕜) x) y = inner x y

@[simp]

theorem inner_product_space.norm_to_dual'_apply (𝕜 : Type u_1) {E : Type u_2} [is_R_or_C 𝕜] [inner_product_space 𝕜 E] (x : E) :

∥⇑(inner_product_space.to_dual' 𝕜) x∥ = ∥x∥

In an inner product space, the norm of the dual of a vector x is ∥x∥

theorem inner_product_space.to_dual'_isometry (𝕜 : Type u_1) (E : Type u_2) [is_R_or_C 𝕜] [inner_product_space 𝕜 E] :

isometry ⇑(inner_product_space.to_dual' 𝕜)

theorem inner_product_space.to_dual'_surjective (𝕜 : Type u_1) (E : Type u_2) [is_R_or_C 𝕜] [inner_product_space 𝕜 E] [complete_space E] :

function.surjective ⇑(inner_product_space.to_dual' 𝕜)

Fréchet-Riesz representation: any ℓ in the dual of a Hilbert space E is of the form λ u, ⟪y, u⟫ for some y : E, i.e. to_dual' is surjective.

def inner_product_space.to_dual_map {F : Type u_1} [inner_product_space ℝ F] :

F →L[ℝ ] normed_space.dual ℝ F

In a real inner product space F, the function that takes a vector x in F to its dual λ y, ⟪x, y⟫ is a continuous linear map. If the space is complete (i.e. is a Hilbert space), consider using to_dual instead.

Equations

inner_product_space.to_dual_map = {to_fun := ⇑(inner_product_space.to_dual' ℝ), map_add' := _, map_smul' := _}.mk_continuous 1 inner_product_space.to_dual_map._proof_3

@[simp]

theorem inner_product_space.to_dual_map_apply {F : Type u_1} [inner_product_space ℝ F] {x y : F} :

⇑(⇑inner_product_space.to_dual_map x) y = inner x y

@[simp]

theorem inner_product_space.norm_to_dual_map_apply {F : Type u_1} [inner_product_space ℝ F] (x : F) :

∥⇑inner_product_space.to_dual_map x∥ = ∥x∥

In an inner product space, the norm of the dual of a vector x is ∥x∥

theorem inner_product_space.to_dual_map_isometry {F : Type u_1} [inner_product_space ℝ F] :

isometry ⇑inner_product_space.to_dual_map

theorem inner_product_space.to_dual_map_injective {F : Type u_1} [inner_product_space ℝ F] :

function.injective ⇑inner_product_space.to_dual_map

@[simp]

theorem inner_product_space.ker_to_dual_map {F : Type u_1} [inner_product_space ℝ F] :

inner_product_space.to_dual_map.ker = ⊥

@[simp]

theorem inner_product_space.to_dual_map_eq_iff_eq {F : Type u_1} [inner_product_space ℝ F] {x y : F} :

⇑inner_product_space.to_dual_map x = ⇑inner_product_space.to_dual_map y ↔ x = y

theorem inner_product_space.range_to_dual_map {F : Type u_1} [inner_product_space ℝ F] [complete_space F] :

inner_product_space.to_dual_map.range = ⊤

Fréchet-Riesz representation: any ℓ in the dual of a real Hilbert space F is of the form λ u, ⟪y, u⟫ for some y in F. See inner_product_space.to_dual for the continuous linear equivalence thus induced.

def inner_product_space.to_dual {F : Type u_1} [inner_product_space ℝ F] [complete_space F] :

F ≃L[ℝ ] normed_space.dual ℝ F

Fréchet-Riesz representation: If F is a Hilbert space, the function that takes a vector in F to its dual is a continuous linear equivalence.

Equations

inner_product_space.to_dual = continuous_linear_equiv.of_isometry inner_product_space.to_dual_map.to_linear_map inner_product_space.to_dual_map_isometry inner_product_space.range_to_dual_map

def inner_product_space.isometric.to_dual {F : Type u_1} [inner_product_space ℝ F] [complete_space F] :

F ≃ᵢ normed_space.dual ℝ F

Fréchet-Riesz representation: If F is a Hilbert space, the function that takes a vector in F to its dual is an isometry.

Equations

inner_product_space.isometric.to_dual = {to_equiv := inner_product_space.to_dual.to_linear_equiv.to_equiv, isometry_to_fun := _}

@[simp]

theorem inner_product_space.to_dual_apply {F : Type u_1} [inner_product_space ℝ F] [complete_space F] {x y : F} :

⇑(⇑inner_product_space.to_dual x) y = inner x y

@[simp]

theorem inner_product_space.to_dual_eq_iff_eq {F : Type u_1} [inner_product_space ℝ F] [complete_space F] {x y : F} :

⇑inner_product_space.to_dual x = ⇑inner_product_space.to_dual y ↔ x = y

theorem inner_product_space.to_dual_eq_iff_eq' {F : Type u_1} [inner_product_space ℝ F] [complete_space F] {x x' : F} :

(∀ (y : F), inner x y = inner x' y) ↔ x = x'

@[simp]

theorem inner_product_space.norm_to_dual_apply {F : Type u_1} [inner_product_space ℝ F] [complete_space F] (x : F) :

∥⇑inner_product_space.to_dual x∥ = ∥x∥

theorem inner_product_space.norm_to_dual_symm_apply {F : Type u_1} [inner_product_space ℝ F] [complete_space F] (ℓ : normed_space.dual ℝ F) :

∥⇑(inner_product_space.to_dual.symm) ℓ∥ = ∥ℓ∥

In a Hilbert space, the norm of a vector in the dual space is the norm of its corresponding primal vector.