mathlib documentation

analysis.normed_space.dual

The topological dual of a normed space #

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

For base field π•œ = ℝ or π•œ = β„‚, this map is actually an isometric embedding; we provide a version normed_space.inclusion_in_double_dual_li of the map which is of type a bundled linear isometric embedding, E β†’β‚—α΅’[π•œ] (dual π•œ (dual π•œ E)).

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

Main definitions #

Tags #

dual

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@[protected, instance]
def normed_space.dual.inhabited (π•œ : Type u_1) [nontrivially_normed_field π•œ] (E : Type u_2) [seminormed_add_comm_group E] [normed_space π•œ E] :
inhabited (normed_space.dual π•œ E)
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def normed_space.dual (π•œ : Type u_1) [nontrivially_normed_field π•œ] (E : Type u_2) [seminormed_add_comm_group E] [normed_space π•œ E] :
Type (max u_2 u_1)

The topological dual of a seminormed space E.

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Instances for normed_space.dual
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@[protected, instance]
noncomputable def normed_space.dual.seminormed_add_comm_group (π•œ : Type u_1) [nontrivially_normed_field π•œ] (E : Type u_2) [seminormed_add_comm_group E] [normed_space π•œ E] :
seminormed_add_comm_group (normed_space.dual π•œ E)
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@[protected, instance]
def normed_space.dual.normed_space (π•œ : Type u_1) [nontrivially_normed_field π•œ] (E : Type u_2) [seminormed_add_comm_group E] [normed_space π•œ E] :
normed_space π•œ (normed_space.dual π•œ E)
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@[protected, instance]
def normed_space.continuous_linear_map_class (π•œ : Type u_1) [nontrivially_normed_field π•œ] (E : Type u_2) [seminormed_add_comm_group E] [normed_space π•œ E] :
continuous_linear_map_class (normed_space.dual π•œ E) π•œ E π•œ
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@[protected, instance]
def normed_space.dual.has_coe_to_fun (π•œ : Type u_1) [nontrivially_normed_field π•œ] (E : Type u_2) [seminormed_add_comm_group E] [normed_space π•œ E] :
has_coe_to_fun (normed_space.dual π•œ E) (Ξ» (_x : normed_space.dual π•œ E), E β†’ π•œ)
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@[protected, instance]
noncomputable def normed_space.dual.normed_add_comm_group (π•œ : Type u_1) [nontrivially_normed_field π•œ] (F : Type u_3) [normed_add_comm_group F] [normed_space π•œ F] :
normed_add_comm_group (normed_space.dual π•œ F)
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@[protected, instance]
def normed_space.dual.finite_dimensional (π•œ : Type u_1) [nontrivially_normed_field π•œ] (E : Type u_2) [seminormed_add_comm_group E] [normed_space π•œ E] [finite_dimensional π•œ E] :
finite_dimensional π•œ (normed_space.dual π•œ E)
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noncomputable def normed_space.inclusion_in_double_dual (π•œ : Type u_1) [nontrivially_normed_field π•œ] (E : Type u_2) [seminormed_add_comm_group E] [normed_space π•œ E] :
E β†’L[π•œ] normed_space.dual π•œ (normed_space.dual π•œ E)

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

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@[simp]
theorem normed_space.dual_def (π•œ : Type u_1) [nontrivially_normed_field π•œ] (E : Type u_2) [seminormed_add_comm_group E] [normed_space π•œ E] (x : E) (f : normed_space.dual π•œ E) :
⇑(⇑(normed_space.inclusion_in_double_dual π•œ E) x) f = ⇑f x
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theorem normed_space.inclusion_in_double_dual_norm_eq (π•œ : Type u_1) [nontrivially_normed_field π•œ] (E : Type u_2) [seminormed_add_comm_group E] [normed_space π•œ E] :
β€–normed_space.inclusion_in_double_dual π•œ Eβ€– = β€–continuous_linear_map.id π•œ (normed_space.dual π•œ E)β€–
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theorem normed_space.inclusion_in_double_dual_norm_le (π•œ : Type u_1) [nontrivially_normed_field π•œ] (E : Type u_2) [seminormed_add_comm_group E] [normed_space π•œ E] :
β€–normed_space.inclusion_in_double_dual π•œ Eβ€– ≀ 1
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theorem normed_space.double_dual_bound (π•œ : Type u_1) [nontrivially_normed_field π•œ] (E : Type u_2) [seminormed_add_comm_group E] [normed_space π•œ E] (x : E) :
‖⇑(normed_space.inclusion_in_double_dual π•œ E) xβ€– ≀ β€–xβ€–
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def normed_space.dual_pairing (π•œ : Type u_1) [nontrivially_normed_field π•œ] (E : Type u_2) [seminormed_add_comm_group E] [normed_space π•œ E] :
normed_space.dual π•œ E β†’β‚—[π•œ] E β†’β‚—[π•œ] π•œ

The dual pairing as a bilinear form.

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@[simp]
theorem normed_space.dual_pairing_apply (π•œ : Type u_1) [nontrivially_normed_field π•œ] (E : Type u_2) [seminormed_add_comm_group E] [normed_space π•œ E] {v : normed_space.dual π•œ E} {x : E} :
⇑(⇑(normed_space.dual_pairing π•œ E) v) x = ⇑v x
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theorem normed_space.dual_pairing_separating_left (π•œ : Type u_1) [nontrivially_normed_field π•œ] (E : Type u_2) [seminormed_add_comm_group E] [normed_space π•œ E] :
(normed_space.dual_pairing π•œ E).separating_left
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theorem normed_space.norm_le_dual_bound (π•œ : Type v) [is_R_or_C π•œ] {E : Type u} [normed_add_comm_group E] [normed_space π•œ E] (x : E) {M : ℝ} (hMp : 0 ≀ M) (hM : βˆ€ (f : normed_space.dual π•œ E), ‖⇑f xβ€– ≀ M * β€–fβ€–) :
β€–xβ€– ≀ M

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

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theorem normed_space.eq_zero_of_forall_dual_eq_zero (π•œ : Type v) [is_R_or_C π•œ] {E : Type u} [normed_add_comm_group E] [normed_space π•œ E] {x : E} (h : βˆ€ (f : normed_space.dual π•œ E), ⇑f x = 0) :
x = 0
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theorem normed_space.eq_zero_iff_forall_dual_eq_zero (π•œ : Type v) [is_R_or_C π•œ] {E : Type u} [normed_add_comm_group E] [normed_space π•œ E] (x : E) :
x = 0 ↔ βˆ€ (g : normed_space.dual π•œ E), ⇑g x = 0
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theorem normed_space.eq_iff_forall_dual_eq (π•œ : Type v) [is_R_or_C π•œ] {E : Type u} [normed_add_comm_group E] [normed_space π•œ E] {x y : E} :
x = y ↔ βˆ€ (g : normed_space.dual π•œ E), ⇑g x = ⇑g y

See also geometric_hahn_banach_point_point.

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noncomputable def normed_space.inclusion_in_double_dual_li (π•œ : Type v) [is_R_or_C π•œ] {E : Type u} [normed_add_comm_group E] [normed_space π•œ E] :
E β†’β‚—α΅’[π•œ] normed_space.dual π•œ (normed_space.dual π•œ E)

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

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def normed_space.polar (π•œ : Type u_1) [nontrivially_normed_field π•œ] {E : Type u_2} [seminormed_add_comm_group E] [normed_space π•œ E] :
set E β†’ set (normed_space.dual π•œ E)

Given a subset s in a normed space E (over a field π•œ), the polar polar π•œ s is the subset of dual π•œ E consisting of those functionals which evaluate to something of norm at most one at all points z ∈ s.

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theorem normed_space.mem_polar_iff (π•œ : Type u_1) [nontrivially_normed_field π•œ] {E : Type u_2} [seminormed_add_comm_group E] [normed_space π•œ E] {x' : normed_space.dual π•œ E} (s : set E) :
x' ∈ normed_space.polar π•œ s ↔ βˆ€ (z : E), z ∈ s β†’ ‖⇑x' zβ€– ≀ 1
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@[simp]
theorem normed_space.polar_univ (π•œ : Type u_1) [nontrivially_normed_field π•œ] {E : Type u_2} [seminormed_add_comm_group E] [normed_space π•œ E] :
normed_space.polar π•œ set.univ = {0}
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theorem normed_space.is_closed_polar (π•œ : Type u_1) [nontrivially_normed_field π•œ] {E : Type u_2} [seminormed_add_comm_group E] [normed_space π•œ E] (s : set E) :
is_closed (normed_space.polar π•œ s)
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@[simp]
theorem normed_space.polar_closure (π•œ : Type u_1) [nontrivially_normed_field π•œ] {E : Type u_2} [seminormed_add_comm_group E] [normed_space π•œ E] (s : set E) :
normed_space.polar π•œ (closure s) = normed_space.polar π•œ s
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theorem normed_space.smul_mem_polar {π•œ : Type u_1} [nontrivially_normed_field π•œ] {E : Type u_2} [seminormed_add_comm_group E] [normed_space π•œ E] {s : set E} {x' : normed_space.dual π•œ E} {c : π•œ} (hc : βˆ€ (z : E), z ∈ s β†’ ‖⇑x' zβ€– ≀ β€–cβ€–) :
c⁻¹ β€’ x' ∈ normed_space.polar π•œ s

If x' is a dual element such that the norms β€–x' zβ€– are bounded for z ∈ s, then a small scalar multiple of x' is in polar π•œ s.

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theorem normed_space.polar_ball_subset_closed_ball_div {π•œ : Type u_1} [nontrivially_normed_field π•œ] {E : Type u_2} [seminormed_add_comm_group E] [normed_space π•œ E] {c : π•œ} (hc : 1 < β€–cβ€–) {r : ℝ} (hr : 0 < r) :
normed_space.polar π•œ (metric.ball 0 r) βŠ† metric.closed_ball 0 (β€–cβ€– / r)
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theorem normed_space.closed_ball_inv_subset_polar_closed_ball (π•œ : Type u_1) [nontrivially_normed_field π•œ] {E : Type u_2} [seminormed_add_comm_group E] [normed_space π•œ E] {r : ℝ} :
metric.closed_ball 0 r⁻¹ βŠ† normed_space.polar π•œ (metric.closed_ball 0 r)
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theorem normed_space.polar_closed_ball {π•œ : Type u_1} {E : Type u_2} [is_R_or_C π•œ] [normed_add_comm_group E] [normed_space π•œ E] {r : ℝ} (hr : 0 < r) :
normed_space.polar π•œ (metric.closed_ball 0 r) = metric.closed_ball 0 r⁻¹

The polar of closed ball in a normed space E is the closed ball of the dual with inverse radius.

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theorem normed_space.bounded_polar_of_mem_nhds_zero (π•œ : Type u_1) [nontrivially_normed_field π•œ] {E : Type u_2} [seminormed_add_comm_group E] [normed_space π•œ E] {s : set E} (s_nhd : s ∈ nhds 0) :
metric.bounded (normed_space.polar π•œ s)

Given a neighborhood s of the origin in a normed space E, the dual norms of all elements of the polar polar π•œ s are bounded by a constant.