topology.algebra.group - mathlib docs

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@[protected]

def homeomorph.add_left {G : Type w} [topological_space G] [add_group G] [has_continuous_add G] (a : G) :

G ≃ₜ G

Addition from the left in a topological additive group as a homeomorphism.

Equations

homeomorph.add_left a = {to_equiv := {to_fun := (equiv.add_left a).to_fun, inv_fun := (equiv.add_left a).inv_fun, left_inv := _, right_inv := _}, continuous_to_fun := _, continuous_inv_fun := _}

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@[protected]

def homeomorph.mul_left {G : Type w} [topological_space G] [group G] [has_continuous_mul G] (a : G) :

G ≃ₜ G

Multiplication from the left in a topological group as a homeomorphism.

Equations

homeomorph.mul_left a = {to_equiv := {to_fun := (equiv.mul_left a).to_fun, inv_fun := (equiv.mul_left a).inv_fun, left_inv := _, right_inv := _}, continuous_to_fun := _, continuous_inv_fun := _}

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@[simp]

theorem homeomorph.coe_add_left {G : Type w} [topological_space G] [add_group G] [has_continuous_add G] (a : G) :

⇑(homeomorph.add_left a) = has_add.add a

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@[simp]

theorem homeomorph.coe_mul_left {G : Type w} [topological_space G] [group G] [has_continuous_mul G] (a : G) :

⇑(homeomorph.mul_left a) = has_mul.mul a

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theorem homeomorph.add_left_symm {G : Type w} [topological_space G] [add_group G] [has_continuous_add G] (a : G) :

(homeomorph.add_left a).symm = homeomorph.add_left (-a)

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theorem homeomorph.mul_left_symm {G : Type w} [topological_space G] [group G] [has_continuous_mul G] (a : G) :

(homeomorph.mul_left a).symm = homeomorph.mul_left a⁻¹

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theorem is_open_map_add_left {G : Type w} [topological_space G] [add_group G] [has_continuous_add G] (a : G) :

is_open_map (λ (x : G), a + x)

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theorem is_open_map_mul_left {G : Type w} [topological_space G] [group G] [has_continuous_mul G] (a : G) :

is_open_map (λ (x : G), a * x)

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theorem is_open.left_add_coset {G : Type w} [topological_space G] [add_group G] [has_continuous_add G] {U : set G} (h : is_open U) (x : G) :

is_open (left_add_coset x U)

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theorem is_open.left_coset {G : Type w} [topological_space G] [group G] [has_continuous_mul G] {U : set G} (h : is_open U) (x : G) :

is_open (left_coset x U)

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theorem is_closed_map_mul_left {G : Type w} [topological_space G] [group G] [has_continuous_mul G] (a : G) :

is_closed_map (λ (x : G), a * x)

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theorem is_closed_map_add_left {G : Type w} [topological_space G] [add_group G] [has_continuous_add G] (a : G) :

is_closed_map (λ (x : G), a + x)

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theorem is_closed.left_add_coset {G : Type w} [topological_space G] [add_group G] [has_continuous_add G] {U : set G} (h : is_closed U) (x : G) :

is_closed (left_add_coset x U)

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theorem is_closed.left_coset {G : Type w} [topological_space G] [group G] [has_continuous_mul G] {U : set G} (h : is_closed U) (x : G) :

is_closed (left_coset x U)

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@[protected]

def homeomorph.add_right {G : Type w} [topological_space G] [add_group G] [has_continuous_add G] (a : G) :

G ≃ₜ G

Addition from the right in a topological additive group as a homeomorphism.

Equations

homeomorph.add_right a = {to_equiv := {to_fun := (equiv.add_right a).to_fun, inv_fun := (equiv.add_right a).inv_fun, left_inv := _, right_inv := _}, continuous_to_fun := _, continuous_inv_fun := _}

source

@[protected]

def homeomorph.mul_right {G : Type w} [topological_space G] [group G] [has_continuous_mul G] (a : G) :

G ≃ₜ G

Multiplication from the right in a topological group as a homeomorphism.

Equations

homeomorph.mul_right a = {to_equiv := {to_fun := (equiv.mul_right a).to_fun, inv_fun := (equiv.mul_right a).inv_fun, left_inv := _, right_inv := _}, continuous_to_fun := _, continuous_inv_fun := _}

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@[simp]

theorem homeomorph.coe_mul_right {G : Type w} [topological_space G] [group G] [has_continuous_mul G] (a : G) :

⇑(homeomorph.mul_right a) = λ (g : G), g * a

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@[simp]

theorem homeomorph.coe_add_right {G : Type w} [topological_space G] [add_group G] [has_continuous_add G] (a : G) :

⇑(homeomorph.add_right a) = λ (g : G), g + a

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theorem homeomorph.mul_right_symm {G : Type w} [topological_space G] [group G] [has_continuous_mul G] (a : G) :

(homeomorph.mul_right a).symm = homeomorph.mul_right a⁻¹

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theorem homeomorph.add_right_symm {G : Type w} [topological_space G] [add_group G] [has_continuous_add G] (a : G) :

(homeomorph.add_right a).symm = homeomorph.add_right (-a)

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theorem is_open_map_mul_right {G : Type w} [topological_space G] [group G] [has_continuous_mul G] (a : G) :

is_open_map (λ (x : G), x * a)

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theorem is_open_map_add_right {G : Type w} [topological_space G] [add_group G] [has_continuous_add G] (a : G) :

is_open_map (λ (x : G), x + a)

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theorem is_open.right_coset {G : Type w} [topological_space G] [group G] [has_continuous_mul G] {U : set G} (h : is_open U) (x : G) :

is_open (right_coset U x)

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theorem is_open.right_add_coset {G : Type w} [topological_space G] [add_group G] [has_continuous_add G] {U : set G} (h : is_open U) (x : G) :

is_open (right_add_coset U x)

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theorem is_closed_map_mul_right {G : Type w} [topological_space G] [group G] [has_continuous_mul G] (a : G) :

is_closed_map (λ (x : G), x * a)

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theorem is_closed_map_add_right {G : Type w} [topological_space G] [add_group G] [has_continuous_add G] (a : G) :

is_closed_map (λ (x : G), x + a)

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theorem is_closed.right_coset {G : Type w} [topological_space G] [group G] [has_continuous_mul G] {U : set G} (h : is_closed U) (x : G) :

is_closed (right_coset U x)

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theorem is_closed.right_add_coset {G : Type w} [topological_space G] [add_group G] [has_continuous_add G] {U : set G} (h : is_closed U) (x : G) :

is_closed (right_add_coset U x)

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theorem discrete_topology_of_open_singleton_zero {G : Type w} [topological_space G] [add_group G] [has_continuous_add G] (h : is_open {0}) :

discrete_topology G

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theorem discrete_topology_of_open_singleton_one {G : Type w} [topological_space G] [group G] [has_continuous_mul G] (h : is_open {1}) :

discrete_topology G

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theorem discrete_topology_iff_open_singleton_zero {G : Type w} [topological_space G] [add_group G] [has_continuous_add G] :

discrete_topology G ↔ is_open {0}

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theorem discrete_topology_iff_open_singleton_one {G : Type w} [topological_space G] [group G] [has_continuous_mul G] :

discrete_topology G ↔ is_open {1}

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@[class]

structure has_continuous_neg (G : Type u) [topological_space G] [has_neg G] :

Prop

continuous_neg : continuous (λ (a : G), -a)

Basic hypothesis to talk about a topological additive group. A topological additive group over M, for example, is obtained by requiring the instances add_group M and has_continuous_add M and has_continuous_neg M.

Instances of this typeclass

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@[class]

structure has_continuous_inv (G : Type u) [topological_space G] [has_inv G] :

Prop

continuous_inv : continuous (λ (a : G), a⁻¹)

Basic hypothesis to talk about a topological group. A topological group over M, for example, is obtained by requiring the instances group M and has_continuous_mul M and has_continuous_inv M.

Instances of this typeclass

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theorem continuous_on_inv {G : Type w} [topological_space G] [has_inv G] [has_continuous_inv G] {s : set G} :

continuous_on has_inv.inv s

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theorem continuous_on_neg {G : Type w} [topological_space G] [has_neg G] [has_continuous_neg G] {s : set G} :

continuous_on has_neg.neg s

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theorem continuous_within_at_inv {G : Type w} [topological_space G] [has_inv G] [has_continuous_inv G] {s : set G} {x : G} :

continuous_within_at has_inv.inv s x

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theorem continuous_within_at_neg {G : Type w} [topological_space G] [has_neg G] [has_continuous_neg G] {s : set G} {x : G} :

continuous_within_at has_neg.neg s x

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theorem continuous_at_neg {G : Type w} [topological_space G] [has_neg G] [has_continuous_neg G] {x : G} :

continuous_at has_neg.neg x

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theorem continuous_at_inv {G : Type w} [topological_space G] [has_inv G] [has_continuous_inv G] {x : G} :

continuous_at has_inv.inv x

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theorem tendsto_inv {G : Type w} [topological_space G] [has_inv G] [has_continuous_inv G] (a : G) :

filter.tendsto has_inv.inv (nhds a) (nhds a⁻¹)

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theorem tendsto_neg {G : Type w} [topological_space G] [has_neg G] [has_continuous_neg G] (a : G) :

filter.tendsto has_neg.neg (nhds a) (nhds (-a))

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theorem filter.tendsto.inv {α : Type u} {G : Type w} [topological_space G] [has_inv G] [has_continuous_inv G] {f : α → G} {l : filter α} {y : G} (h : filter.tendsto f l (nhds y)) :

filter.tendsto (λ (x : α), (f x)⁻¹) l (nhds y⁻¹)

If a function converges to a value in a multiplicative topological group, then its inverse converges to the inverse of this value. For the version in normed fields assuming additionally that the limit is nonzero, use tendsto.inv'.

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theorem filter.tendsto.neg {α : Type u} {G : Type w} [topological_space G] [has_neg G] [has_continuous_neg G] {f : α → G} {l : filter α} {y : G} (h : filter.tendsto f l (nhds y)) :

filter.tendsto (λ (x : α), -f x) l (nhds (-y))

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@[continuity]

theorem continuous.inv {α : Type u} {G : Type w} [topological_space G] [has_inv G] [has_continuous_inv G] [topological_space α] {f : α → G} (hf : continuous f) :

continuous (λ (x : α), (f x)⁻¹)

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@[continuity]

theorem continuous.neg {α : Type u} {G : Type w} [topological_space G] [has_neg G] [has_continuous_neg G] [topological_space α] {f : α → G} (hf : continuous f) :

continuous (λ (x : α), -f x)

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theorem continuous_at.neg {α : Type u} {G : Type w} [topological_space G] [has_neg G] [has_continuous_neg G] [topological_space α] {f : α → G} {x : α} (hf : continuous_at f x) :

continuous_at (λ (x : α), -f x) x

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theorem continuous_at.inv {α : Type u} {G : Type w} [topological_space G] [has_inv G] [has_continuous_inv G] [topological_space α] {f : α → G} {x : α} (hf : continuous_at f x) :

continuous_at (λ (x : α), (f x)⁻¹) x

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theorem continuous_on.inv {α : Type u} {G : Type w} [topological_space G] [has_inv G] [has_continuous_inv G] [topological_space α] {f : α → G} {s : set α} (hf : continuous_on f s) :

continuous_on (λ (x : α), (f x)⁻¹) s

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theorem continuous_on.neg {α : Type u} {G : Type w} [topological_space G] [has_neg G] [has_continuous_neg G] [topological_space α] {f : α → G} {s : set α} (hf : continuous_on f s) :

continuous_on (λ (x : α), -f x) s

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theorem continuous_within_at.inv {α : Type u} {G : Type w} [topological_space G] [has_inv G] [has_continuous_inv G] [topological_space α] {f : α → G} {s : set α} {x : α} (hf : continuous_within_at f s x) :

continuous_within_at (λ (x : α), (f x)⁻¹) s x

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theorem continuous_within_at.neg {α : Type u} {G : Type w} [topological_space G] [has_neg G] [has_continuous_neg G] [topological_space α] {f : α → G} {s : set α} {x : α} (hf : continuous_within_at f s x) :

continuous_within_at (λ (x : α), -f x) s x

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@[protected, instance]

def prod.has_continuous_neg {G : Type w} {H : Type x} [topological_space G] [has_neg G] [has_continuous_neg G] [topological_space H] [has_neg H] [has_continuous_neg H] :

has_continuous_neg (G × H)

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@[protected, instance]

def prod.has_continuous_inv {G : Type w} {H : Type x} [topological_space G] [has_inv G] [has_continuous_inv G] [topological_space H] [has_inv H] [has_continuous_inv H] :

has_continuous_inv (G × H)

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@[protected, instance]

def pi.has_continuous_inv {ι : Type u_1} {C : ι → Type u_2} [Π (i : ι), topological_space (C i)] [Π (i : ι), has_inv (C i)] [∀ (i : ι), has_continuous_inv (C i)] :

has_continuous_inv (Π (i : ι), C i)

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@[protected, instance]

def pi.has_continuous_neg {ι : Type u_1} {C : ι → Type u_2} [Π (i : ι), topological_space (C i)] [Π (i : ι), has_neg (C i)] [∀ (i : ι), has_continuous_neg (C i)] :

has_continuous_neg (Π (i : ι), C i)

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@[protected, instance]

def pi.has_continuous_neg' {G : Type w} [topological_space G] [has_neg G] [has_continuous_neg G] {ι : Type u_1} :

has_continuous_neg (ι → G)

A version of pi.has_continuous_neg for non-dependent functions. It is needed because sometimes Lean fails to use pi.has_continuous_neg for non-dependent functions.

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@[protected, instance]

def pi.has_continuous_inv' {G : Type w} [topological_space G] [has_inv G] [has_continuous_inv G] {ι : Type u_1} :

has_continuous_inv (ι → G)

A version of pi.has_continuous_inv for non-dependent functions. It is needed because sometimes Lean fails to use pi.has_continuous_inv for non-dependent functions.

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@[protected, instance]

def has_continuous_neg_of_discrete_topology {H : Type x} [topological_space H] [has_neg H] [discrete_topology H] :

has_continuous_neg H

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@[protected, instance]

def has_continuous_inv_of_discrete_topology {H : Type x} [topological_space H] [has_inv H] [discrete_topology H] :

has_continuous_inv H

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theorem is_closed_set_of_map_neg (G₁ : Type u_2) (G₂ : Type u_3) [topological_space G₂] [t2_space G₂] [has_neg G₁] [has_neg G₂] [has_continuous_neg G₂] :

is_closed {f : G₁ → G₂ | ∀ (x : G₁), f (-x) = -f x}

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theorem is_closed_set_of_map_inv (G₁ : Type u_2) (G₂ : Type u_3) [topological_space G₂] [t2_space G₂] [has_inv G₁] [has_inv G₂] [has_continuous_inv G₂] :

is_closed {f : G₁ → G₂ | ∀ (x : G₁), f x⁻¹ = (f x)⁻¹}

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@[protected, instance]

def additive.has_continuous_neg {H : Type x} [h : topological_space H] [has_inv H] [has_continuous_inv H] :

has_continuous_neg (additive H)

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@[protected, instance]

def multiplicative.has_continuous_inv {H : Type x} [h : topological_space H] [has_neg H] [has_continuous_neg H] :

has_continuous_inv (multiplicative H)

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theorem is_compact.neg {G : Type w} [topological_space G] [has_involutive_neg G] [has_continuous_neg G] {s : set G} (hs : is_compact s) :

is_compact (-s)

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theorem is_compact.inv {G : Type w} [topological_space G] [has_involutive_inv G] [has_continuous_inv G] {s : set G} (hs : is_compact s) :

is_compact s⁻¹

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@[protected]

def homeomorph.neg (G : Type u_1) [topological_space G] [has_involutive_neg G] [has_continuous_neg G] :

G ≃ₜ G

Negation in a topological group as a homeomorphism.

Equations

homeomorph.neg G = {to_equiv := {to_fun := (equiv.neg G).to_fun, inv_fun := (equiv.neg G).inv_fun, left_inv := _, right_inv := _}, continuous_to_fun := _, continuous_inv_fun := _}

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@[protected]

def homeomorph.inv (G : Type u_1) [topological_space G] [has_involutive_inv G] [has_continuous_inv G] :

G ≃ₜ G

Inversion in a topological group as a homeomorphism.

Equations

homeomorph.inv G = {to_equiv := {to_fun := (equiv.inv G).to_fun, inv_fun := (equiv.inv G).inv_fun, left_inv := _, right_inv := _}, continuous_to_fun := _, continuous_inv_fun := _}

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theorem is_open_map_neg (G : Type w) [topological_space G] [has_involutive_neg G] [has_continuous_neg G] :

is_open_map has_neg.neg

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theorem is_open_map_inv (G : Type w) [topological_space G] [has_involutive_inv G] [has_continuous_inv G] :

is_open_map has_inv.inv

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theorem is_closed_map_inv (G : Type w) [topological_space G] [has_involutive_inv G] [has_continuous_inv G] :

is_closed_map has_inv.inv

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theorem is_closed_map_neg (G : Type w) [topological_space G] [has_involutive_neg G] [has_continuous_neg G] :

is_closed_map has_neg.neg

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theorem is_open.inv {G : Type w} [topological_space G] [has_involutive_inv G] [has_continuous_inv G] {s : set G} (hs : is_open s) :

is_open s⁻¹

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theorem is_open.neg {G : Type w} [topological_space G] [has_involutive_neg G] [has_continuous_neg G] {s : set G} (hs : is_open s) :

is_open (-s)

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theorem is_closed.neg {G : Type w} [topological_space G] [has_involutive_neg G] [has_continuous_neg G] {s : set G} (hs : is_closed s) :

is_closed (-s)

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theorem is_closed.inv {G : Type w} [topological_space G] [has_involutive_inv G] [has_continuous_inv G] {s : set G} (hs : is_closed s) :

is_closed s⁻¹

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theorem neg_closure {G : Type w} [topological_space G] [has_involutive_neg G] [has_continuous_neg G] (s : set G) :

-closure s = closure (-s)

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theorem inv_closure {G : Type w} [topological_space G] [has_involutive_inv G] [has_continuous_inv G] (s : set G) :

(closure s)⁻¹ = closure s⁻¹

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theorem has_continuous_neg_Inf {G : Type w} [has_neg G] {ts : set (topological_space G)} (h : ∀ (t : topological_space G), t ∈ ts → has_continuous_neg G) :

has_continuous_neg G

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theorem has_continuous_inv_Inf {G : Type w} [has_inv G] {ts : set (topological_space G)} (h : ∀ (t : topological_space G), t ∈ ts → has_continuous_inv G) :

has_continuous_inv G

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theorem has_continuous_inv_infi {G : Type w} {ι' : Sort u_1} [has_inv G] {ts' : ι' → topological_space G} (h' : ∀ (i : ι'), has_continuous_inv G) :

has_continuous_inv G

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theorem has_continuous_neg_infi {G : Type w} {ι' : Sort u_1} [has_neg G] {ts' : ι' → topological_space G} (h' : ∀ (i : ι'), has_continuous_neg G) :

has_continuous_neg G

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theorem has_continuous_inv_inf {G : Type w} [has_inv G] {t₁ t₂ : topological_space G} (h₁ : has_continuous_inv G) (h₂ : has_continuous_inv G) :

has_continuous_inv G

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theorem has_continuous_neg_inf {G : Type w} [has_neg G] {t₁ t₂ : topological_space G} (h₁ : has_continuous_neg G) (h₂ : has_continuous_neg G) :

has_continuous_neg G

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@[class]

structure topological_add_group (G : Type u) [topological_space G] [add_group G] :

Prop

to_has_continuous_add : has_continuous_add G
to_has_continuous_neg : has_continuous_neg G

A topological (additive) group is a group in which the addition and negation operations are continuous.

Instances of this typeclass

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@[class]

structure topological_group (G : Type u_1) [topological_space G] [group G] :

Prop

to_has_continuous_mul : has_continuous_mul G
to_has_continuous_inv : has_continuous_inv G

A topological group is a group in which the multiplication and inversion operations are continuous.

When you declare an instance that does not already have a uniform_space instance, you should also provide an instance of uniform_space and uniform_group using topological_group.to_uniform_space and topological_group_is_uniform.

Instances of this typeclass

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@[protected, instance]

def conj_act.units_has_continuous_const_smul {M : Type u_1} [monoid M] [topological_space M] [has_continuous_mul M] :

has_continuous_const_smul (conj_act Mˣ) M

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theorem topological_group.continuous_conj_prod {G : Type w} [topological_space G] [has_inv G] [has_mul G] [has_continuous_mul G] [has_continuous_inv G] :

continuous (λ (g : G × G), g.fst * g.snd * (g.fst)⁻¹)

Conjugation is jointly continuous on G × G when both mul and inv are continuous.

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theorem topological_add_group.continuous_conj_sum {G : Type w} [topological_space G] [has_neg G] [has_add G] [has_continuous_add G] [has_continuous_neg G] :

continuous (λ (g : G × G), g.fst + g.snd + -g.fst)

Conjugation is jointly continuous on G × G when both mul and inv are continuous.

source

theorem topological_add_group.continuous_conj {G : Type w} [topological_space G] [has_neg G] [has_add G] [has_continuous_add G] (g : G) :

continuous (λ (h : G), g + h + -g)

Conjugation by a fixed element is continuous when add is continuous.

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theorem topological_group.continuous_conj {G : Type w} [topological_space G] [has_inv G] [has_mul G] [has_continuous_mul G] (g : G) :

continuous (λ (h : G), g * h * g⁻¹)

Conjugation by a fixed element is continuous when mul is continuous.

source

theorem topological_add_group.continuous_conj' {G : Type w} [topological_space G] [has_neg G] [has_add G] [has_continuous_add G] [has_continuous_neg G] (h : G) :

continuous (λ (g : G), g + h + -g)

Conjugation acting on fixed element of the additive group is continuous when both add and neg are continuous.

source

theorem topological_group.continuous_conj' {G : Type w} [topological_space G] [has_inv G] [has_mul G] [has_continuous_mul G] [has_continuous_inv G] (h : G) :

continuous (λ (g : G), g * h * g⁻¹)

Conjugation acting on fixed element of the group is continuous when both mul and inv are continuous.

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@[continuity]

theorem continuous_zpow {G : Type w} [topological_space G] [group G] [topological_group G] (z : ℤ) :

continuous (λ (a : G), a ^ z)

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@[continuity]

theorem continuous_zsmul {G : Type w} [topological_space G] [add_group G] [topological_add_group G] (z : ℤ) :

continuous (λ (a : G), z • a)

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@[protected, instance]

def add_group.has_continuous_const_smul_int {A : Type u_1} [add_group A] [topological_space A] [topological_add_group A] :

has_continuous_const_smul ℤ A

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@[protected, instance]

def add_group.has_continuous_smul_int {A : Type u_1} [add_group A] [topological_space A] [topological_add_group A] :

has_continuous_smul ℤ A

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@[continuity]

theorem continuous.zsmul {α : Type u} {G : Type w} [topological_space G] [add_group G] [topological_add_group G] [topological_space α] {f : α → G} (h : continuous f) (z : ℤ) :

continuous (λ (b : α), z • f b)

source

@[continuity]

theorem continuous.zpow {α : Type u} {G : Type w} [topological_space G] [group G] [topological_group G] [topological_space α] {f : α → G} (h : continuous f) (z : ℤ) :

continuous (λ (b : α), f b ^ z)

source

theorem continuous_on_zpow {G : Type w} [topological_space G] [group G] [topological_group G] {s : set G} (z : ℤ) :

continuous_on (λ (x : G), x ^ z) s

source

theorem continuous_on_zsmul {G : Type w} [topological_space G] [add_group G] [topological_add_group G] {s : set G} (z : ℤ) :

continuous_on (λ (x : G), z • x) s

source

theorem continuous_at_zsmul {G : Type w} [topological_space G] [add_group G] [topological_add_group G] (x : G) (z : ℤ) :

continuous_at (λ (x : G), z • x) x

source

theorem continuous_at_zpow {G : Type w} [topological_space G] [group G] [topological_group G] (x : G) (z : ℤ) :

continuous_at (λ (x : G), x ^ z) x

source

theorem filter.tendsto.zpow {G : Type w} [topological_space G] [group G] [topological_group G] {α : Type u_1} {l : filter α} {f : α → G} {x : G} (hf : filter.tendsto f l (nhds x)) (z : ℤ) :

filter.tendsto (λ (x : α), f x ^ z) l (nhds (x ^ z))

source

theorem filter.tendsto.zsmul {G : Type w} [topological_space G] [add_group G] [topological_add_group G] {α : Type u_1} {l : filter α} {f : α → G} {x : G} (hf : filter.tendsto f l (nhds x)) (z : ℤ) :

filter.tendsto (λ (x : α), z • f x) l (nhds (z • x))

source

theorem continuous_within_at.zpow {α : Type u} {G : Type w} [topological_space G] [group G] [topological_group G] [topological_space α] {f : α → G} {x : α} {s : set α} (hf : continuous_within_at f s x) (z : ℤ) :

continuous_within_at (λ (x : α), f x ^ z) s x

source

theorem continuous_within_at.zsmul {α : Type u} {G : Type w} [topological_space G] [add_group G] [topological_add_group G] [topological_space α] {f : α → G} {x : α} {s : set α} (hf : continuous_within_at f s x) (z : ℤ) :

continuous_within_at (λ (x : α), z • f x) s x

source

theorem continuous_at.zsmul {α : Type u} {G : Type w} [topological_space G] [add_group G] [topological_add_group G] [topological_space α] {f : α → G} {x : α} (hf : continuous_at f x) (z : ℤ) :

continuous_at (λ (x : α), z • f x) x

source

theorem continuous_at.zpow {α : Type u} {G : Type w} [topological_space G] [group G] [topological_group G] [topological_space α] {f : α → G} {x : α} (hf : continuous_at f x) (z : ℤ) :

continuous_at (λ (x : α), f x ^ z) x

source

theorem continuous_on.zsmul {α : Type u} {G : Type w} [topological_space G] [add_group G] [topological_add_group G] [topological_space α] {f : α → G} {s : set α} (hf : continuous_on f s) (z : ℤ) :

continuous_on (λ (x : α), z • f x) s

source

theorem continuous_on.zpow {α : Type u} {G : Type w} [topological_space G] [group G] [topological_group G] [topological_space α] {f : α → G} {s : set α} (hf : continuous_on f s) (z : ℤ) :

continuous_on (λ (x : α), f x ^ z) s

source

theorem tendsto_inv_nhds_within_Ioi {H : Type x} [topological_space H] [ordered_comm_group H] [topological_group H] {a : H} :

filter.tendsto has_inv.inv (nhds_within a (set.Ioi a)) (nhds_within a⁻¹ (set.Iio a⁻¹))

source

theorem tendsto_neg_nhds_within_Ioi {H : Type x} [topological_space H] [ordered_add_comm_group H] [topological_add_group H] {a : H} :

filter.tendsto has_neg.neg (nhds_within a (set.Ioi a)) (nhds_within (-a) (set.Iio (-a)))

source

theorem tendsto_inv_nhds_within_Iio {H : Type x} [topological_space H] [ordered_comm_group H] [topological_group H] {a : H} :

filter.tendsto has_inv.inv (nhds_within a (set.Iio a)) (nhds_within a⁻¹ (set.Ioi a⁻¹))

source

theorem tendsto_neg_nhds_within_Iio {H : Type x} [topological_space H] [ordered_add_comm_group H] [topological_add_group H] {a : H} :

filter.tendsto has_neg.neg (nhds_within a (set.Iio a)) (nhds_within (-a) (set.Ioi (-a)))

source

theorem tendsto_inv_nhds_within_Ioi_inv {H : Type x} [topological_space H] [ordered_comm_group H] [topological_group H] {a : H} :

filter.tendsto has_inv.inv (nhds_within a⁻¹ (set.Ioi a⁻¹)) (nhds_within a (set.Iio a))

source

theorem tendsto_neg_nhds_within_Ioi_neg {H : Type x} [topological_space H] [ordered_add_comm_group H] [topological_add_group H] {a : H} :

filter.tendsto has_neg.neg (nhds_within (-a) (set.Ioi (-a))) (nhds_within a (set.Iio a))

source

theorem tendsto_inv_nhds_within_Iio_inv {H : Type x} [topological_space H] [ordered_comm_group H] [topological_group H] {a : H} :

filter.tendsto has_inv.inv (nhds_within a⁻¹ (set.Iio a⁻¹)) (nhds_within a (set.Ioi a))

source

theorem tendsto_neg_nhds_within_Iio_neg {H : Type x} [topological_space H] [ordered_add_comm_group H] [topological_add_group H] {a : H} :

filter.tendsto has_neg.neg (nhds_within (-a) (set.Iio (-a))) (nhds_within a (set.Ioi a))

source

theorem tendsto_inv_nhds_within_Ici {H : Type x} [topological_space H] [ordered_comm_group H] [topological_group H] {a : H} :

filter.tendsto has_inv.inv (nhds_within a (set.Ici a)) (nhds_within a⁻¹ (set.Iic a⁻¹))

source

theorem tendsto_neg_nhds_within_Ici {H : Type x} [topological_space H] [ordered_add_comm_group H] [topological_add_group H] {a : H} :

filter.tendsto has_neg.neg (nhds_within a (set.Ici a)) (nhds_within (-a) (set.Iic (-a)))

source

theorem tendsto_inv_nhds_within_Iic {H : Type x} [topological_space H] [ordered_comm_group H] [topological_group H] {a : H} :

filter.tendsto has_inv.inv (nhds_within a (set.Iic a)) (nhds_within a⁻¹ (set.Ici a⁻¹))

source

theorem tendsto_neg_nhds_within_Iic {H : Type x} [topological_space H] [ordered_add_comm_group H] [topological_add_group H] {a : H} :

filter.tendsto has_neg.neg (nhds_within a (set.Iic a)) (nhds_within (-a) (set.Ici (-a)))

source

theorem tendsto_neg_nhds_within_Ici_neg {H : Type x} [topological_space H] [ordered_add_comm_group H] [topological_add_group H] {a : H} :

filter.tendsto has_neg.neg (nhds_within (-a) (set.Ici (-a))) (nhds_within a (set.Iic a))

source

theorem tendsto_inv_nhds_within_Ici_inv {H : Type x} [topological_space H] [ordered_comm_group H] [topological_group H] {a : H} :

filter.tendsto has_inv.inv (nhds_within a⁻¹ (set.Ici a⁻¹)) (nhds_within a (set.Iic a))

source

theorem tendsto_neg_nhds_within_Iic_neg {H : Type x} [topological_space H] [ordered_add_comm_group H] [topological_add_group H] {a : H} :

filter.tendsto has_neg.neg (nhds_within (-a) (set.Iic (-a))) (nhds_within a (set.Ici a))

source

theorem tendsto_inv_nhds_within_Iic_inv {H : Type x} [topological_space H] [ordered_comm_group H] [topological_group H] {a : H} :

filter.tendsto has_inv.inv (nhds_within a⁻¹ (set.Iic a⁻¹)) (nhds_within a (set.Ici a))

source

@[protected, instance]

def prod.topological_add_group {G : Type w} {H : Type x} [topological_space G] [add_group G] [topological_add_group G] [topological_space H] [add_group H] [topological_add_group H] :

topological_add_group (G × H)

source

@[protected, instance]

def prod.topological_group {G : Type w} {H : Type x} [topological_space G] [group G] [topological_group G] [topological_space H] [group H] [topological_group H] :

topological_group (G × H)

source

@[protected, instance]

def pi.topological_add_group {β : Type v} {C : β → Type u_1} [Π (b : β), topological_space (C b)] [Π (b : β), add_group (C b)] [∀ (b : β), topological_add_group (C b)] :

topological_add_group (Π (b : β), C b)

source

@[protected, instance]

def pi.topological_group {β : Type v} {C : β → Type u_1} [Π (b : β), topological_space (C b)] [Π (b : β), group (C b)] [∀ (b : β), topological_group (C b)] :

topological_group (Π (b : β), C b)

source

@[protected, instance]

def add_opposite.has_continuous_neg {α : Type u} [topological_space α] [add_group α] [has_continuous_neg α] :

has_continuous_neg αᵃᵒᵖ

source

@[protected, instance]

def mul_opposite.has_continuous_inv {α : Type u} [topological_space α] [group α] [has_continuous_inv α] :

has_continuous_inv αᵐᵒᵖ

source

@[protected, instance]

def add_opposite.topological_add_group {α : Type u} [topological_space α] [add_group α] [topological_add_group α] :

topological_add_group αᵃᵒᵖ

If addition is continuous in α, then it also is in αᵃᵒᵖ.

source

@[protected, instance]

def mul_opposite.topological_group {α : Type u} [topological_space α] [group α] [topological_group α] :

topological_group αᵐᵒᵖ

If multiplication is continuous in α, then it also is in αᵐᵒᵖ.

source

theorem nhds_one_symm (G : Type w) [topological_space G] [group G] [topological_group G] :

filter.comap has_inv.inv (nhds 1) = nhds 1

source

theorem nhds_zero_symm (G : Type w) [topological_space G] [add_group G] [topological_add_group G] :

filter.comap has_neg.neg (nhds 0) = nhds 0

source

@[protected]

def homeomorph.shear_mul_right (G : Type w) [topological_space G] [group G] [topological_group G] :

G × G ≃ₜ G × G

The map (x, y) ↦ (x, xy) as a homeomorphism. This is a shear mapping.

Equations

homeomorph.shear_mul_right G = {to_equiv := {to_fun := ((equiv.refl G).prod_shear equiv.mul_left).to_fun, inv_fun := ((equiv.refl G).prod_shear equiv.mul_left).inv_fun, left_inv := _, right_inv := _}, continuous_to_fun := _, continuous_inv_fun := _}

source

@[protected]

def homeomorph.shear_add_right (G : Type w) [topological_space G] [add_group G] [topological_add_group G] :

G × G ≃ₜ G × G

The map (x, y) ↦ (x, x + y) as a homeomorphism. This is a shear mapping.

Equations

homeomorph.shear_add_right G = {to_equiv := {to_fun := ((equiv.refl G).prod_shear equiv.add_left).to_fun, inv_fun := ((equiv.refl G).prod_shear equiv.add_left).inv_fun, left_inv := _, right_inv := _}, continuous_to_fun := _, continuous_inv_fun := _}

source

@[simp]

theorem homeomorph.shear_mul_right_coe (G : Type w) [topological_space G] [group G] [topological_group G] :

⇑(homeomorph.shear_mul_right G) = λ (z : G × G), (z.fst, z.fst * z.snd)

source

@[simp]

theorem homeomorph.shear_add_right_coe (G : Type w) [topological_space G] [add_group G] [topological_add_group G] :

⇑(homeomorph.shear_add_right G) = λ (z : G × G), (z.fst, z.fst + z.snd)

source

@[simp]

theorem homeomorph.shear_add_right_symm_coe (G : Type w) [topological_space G] [add_group G] [topological_add_group G] :

⇑((homeomorph.shear_add_right G).symm) = λ (z : G × G), (z.fst, -z.fst + z.snd)

source

@[simp]

theorem homeomorph.shear_mul_right_symm_coe (G : Type w) [topological_space G] [group G] [topological_group G] :

⇑((homeomorph.shear_mul_right G).symm) = λ (z : G × G), (z.fst, (z.fst)⁻¹ * z.snd)

source

@[protected, instance]

def add_subgroup.topological_add_group {G : Type w} [topological_space G] [add_group G] [topological_add_group G] (S : add_subgroup G) :

topological_add_group ↥S

source

@[protected, instance]

def subgroup.topological_group {G : Type w} [topological_space G] [group G] [topological_group G] (S : subgroup G) :

topological_group ↥S

source

def subgroup.topological_closure {G : Type w} [topological_space G] [group G] [topological_group G] (s : subgroup G) :

subgroup G

The (topological-space) closure of a subgroup of a space M with has_continuous_mul is itself a subgroup.

Equations

s.topological_closure = {carrier := closure ↑s, mul_mem' := _, one_mem' := _, inv_mem' := _}

Instances for ↥subgroup.topological_closure

subgroup.topological_closure_topological_group

source

def add_subgroup.topological_closure {G : Type w} [topological_space G] [add_group G] [topological_add_group G] (s : add_subgroup G) :

add_subgroup G

The (topological-space) closure of an additive subgroup of a space M with has_continuous_add is itself an additive subgroup.

Equations

s.topological_closure = {carrier := closure ↑s, add_mem' := _, zero_mem' := _, neg_mem' := _}

Instances for ↥add_subgroup.topological_closure

add_subgroup.topological_closure_topological_add_group

source

@[simp]

theorem subgroup.topological_closure_coe {G : Type w} [topological_space G] [group G] [topological_group G] {s : subgroup G} :

↑(s.topological_closure) = closure ↑s

source

@[simp]

theorem add_subgroup.topological_closure_coe {G : Type w} [topological_space G] [add_group G] [topological_add_group G] {s : add_subgroup G} :

↑(s.topological_closure) = closure ↑s

source

@[protected, instance]

def add_subgroup.topological_closure_topological_add_group {G : Type w} [topological_space G] [add_group G] [topological_add_group G] (s : add_subgroup G) :

topological_add_group ↥(s.topological_closure)

source

@[protected, instance]

def subgroup.topological_closure_topological_group {G : Type w} [topological_space G] [group G] [topological_group G] (s : subgroup G) :

topological_group ↥(s.topological_closure)

source

theorem add_subgroup.add_subgroup_topological_closure {G : Type w} [topological_space G] [add_group G] [topological_add_group G] (s : add_subgroup G) :

s ≤ s.topological_closure

source

theorem subgroup.subgroup_topological_closure {G : Type w} [topological_space G] [group G] [topological_group G] (s : subgroup G) :

s ≤ s.topological_closure

source

theorem subgroup.is_closed_topological_closure {G : Type w} [topological_space G] [group G] [topological_group G] (s : subgroup G) :

is_closed ↑(s.topological_closure)

source

theorem add_subgroup.is_closed_topological_closure {G : Type w} [topological_space G] [add_group G] [topological_add_group G] (s : add_subgroup G) :

is_closed ↑(s.topological_closure)

source

theorem add_subgroup.topological_closure_minimal {G : Type w} [topological_space G] [add_group G] [topological_add_group G] (s : add_subgroup G) {t : add_subgroup G} (h : s ≤ t) (ht : is_closed ↑t) :

s.topological_closure ≤ t

source

theorem subgroup.topological_closure_minimal {G : Type w} [topological_space G] [group G] [topological_group G] (s : subgroup G) {t : subgroup G} (h : s ≤ t) (ht : is_closed ↑t) :

s.topological_closure ≤ t

source

theorem dense_range.topological_closure_map_add_subgroup {G : Type w} {H : Type x} [topological_space G] [add_group G] [topological_add_group G] [add_group H] [topological_space H] [topological_add_group H] {f : G →+ H} (hf : continuous ⇑f) (hf' : dense_range ⇑f) {s : add_subgroup G} (hs : s.topological_closure = ⊤) :

(add_subgroup.map f s).topological_closure = ⊤

source

theorem dense_range.topological_closure_map_subgroup {G : Type w} {H : Type x} [topological_space G] [group G] [topological_group G] [group H] [topological_space H] [topological_group H] {f : G →* H} (hf : continuous ⇑f) (hf' : dense_range ⇑f) {s : subgroup G} (hs : s.topological_closure = ⊤) :

(subgroup.map f s).topological_closure = ⊤

source

theorem add_subgroup.is_normal_topological_closure {G : Type u_1} [topological_space G] [add_group G] [topological_add_group G] (N : add_subgroup G) [N.normal] :

N.topological_closure.normal

The topological closure of a normal additive subgroup is normal.

source

theorem subgroup.is_normal_topological_closure {G : Type u_1} [topological_space G] [group G] [topological_group G] (N : subgroup G) [N.normal] :

N.topological_closure.normal

The topological closure of a normal subgroup is normal.

source

theorem mul_mem_connected_component_one {G : Type u_1} [topological_space G] [mul_one_class G] [has_continuous_mul G] {g h : G} (hg : g ∈ connected_component 1) (hh : h ∈ connected_component 1) :

g * h ∈ connected_component 1

source

theorem add_mem_connected_component_zero {G : Type u_1} [topological_space G] [add_zero_class G] [has_continuous_add G] {g h : G} (hg : g ∈ connected_component 0) (hh : h ∈ connected_component 0) :

g + h ∈ connected_component 0

source

theorem inv_mem_connected_component_one {G : Type u_1} [topological_space G] [group G] [topological_group G] {g : G} (hg : g ∈ connected_component 1) :

g⁻¹ ∈ connected_component 1

source

theorem neg_mem_connected_component_zero {G : Type u_1} [topological_space G] [add_group G] [topological_add_group G] {g : G} (hg : g ∈ connected_component 0) :

-g ∈ connected_component 0

source

def subgroup.connected_component_of_one (G : Type u_1) [topological_space G] [group G] [topological_group G] :

subgroup G

The connected component of 1 is a subgroup of G.

Equations

subgroup.connected_component_of_one G = {carrier := connected_component 1, mul_mem' := _, one_mem' := _, inv_mem' := _}

source

def add_subgroup.connected_component_of_zero (G : Type u_1) [topological_space G] [add_group G] [topological_add_group G] :

add_subgroup G

The connected component of 0 is a subgroup of G.

Equations

add_subgroup.connected_component_of_zero G = {carrier := connected_component 0, add_mem' := _, zero_mem' := _, neg_mem' := _}

source

def subgroup.comm_group_topological_closure {G : Type w} [topological_space G] [group G] [topological_group G] [t2_space G] (s : subgroup G) (hs : ∀ (x y : ↥s), x * y = y * x) :

comm_group ↥(s.topological_closure)

If a subgroup of a topological group is commutative, then so is its topological closure.

Equations

s.comm_group_topological_closure hs = {mul := group.mul s.topological_closure.to_group, mul_assoc := _, one := group.one s.topological_closure.to_group, one_mul := _, mul_one := _, npow := group.npow s.topological_closure.to_group, npow_zero' := _, npow_succ' := _, inv := group.inv s.topological_closure.to_group, div := group.div s.topological_closure.to_group, div_eq_mul_inv := _, zpow := group.zpow s.topological_closure.to_group, zpow_zero' := _, zpow_succ' := _, zpow_neg' := _, mul_left_inv := _, mul_comm := _}

source

def add_subgroup.add_comm_group_topological_closure {G : Type w} [topological_space G] [add_group G] [topological_add_group G] [t2_space G] (s : add_subgroup G) (hs : ∀ (x y : ↥s), x + y = y + x) :

add_comm_group ↥(s.topological_closure)

If a subgroup of an additive topological group is commutative, then so is its topological closure.

Equations

s.add_comm_group_topological_closure hs = {add := add_group.add s.topological_closure.to_add_group, add_assoc := _, zero := add_group.zero s.topological_closure.to_add_group, zero_add := _, add_zero := _, nsmul := add_group.nsmul s.topological_closure.to_add_group, nsmul_zero' := _, nsmul_succ' := _, neg := add_group.neg s.topological_closure.to_add_group, sub := add_group.sub s.topological_closure.to_add_group, sub_eq_add_neg := _, zsmul := add_group.zsmul s.topological_closure.to_add_group, zsmul_zero' := _, zsmul_succ' := _, zsmul_neg' := _, add_left_neg := _, add_comm := _}

source

theorem exists_nhds_half_neg {G : Type w} [topological_space G] [add_group G] [topological_add_group G] {s : set G} (hs : s ∈ nhds 0) :

∃ (V : set G) (H : V ∈ nhds 0), ∀ (v : G), v ∈ V → ∀ (w : G), w ∈ V → v - w ∈ s

source

theorem exists_nhds_split_inv {G : Type w} [topological_space G] [group G] [topological_group G] {s : set G} (hs : s ∈ nhds 1) :

∃ (V : set G) (H : V ∈ nhds 1), ∀ (v : G), v ∈ V → ∀ (w : G), w ∈ V → v / w ∈ s

source

theorem nhds_translation_add_neg {G : Type w} [topological_space G] [add_group G] [topological_add_group G] (x : G) :

filter.comap (λ (y : G), y + -x) (nhds 0) = nhds x

source

theorem nhds_translation_mul_inv {G : Type w} [topological_space G] [group G] [topological_group G] (x : G) :

filter.comap (λ (y : G), y * x⁻¹) (nhds 1) = nhds x

source

@[simp]

theorem map_add_left_nhds {G : Type w} [topological_space G] [add_group G] [topological_add_group G] (x y : G) :

filter.map (has_add.add x) (nhds y) = nhds (x + y)

source

@[simp]

theorem map_mul_left_nhds {G : Type w} [topological_space G] [group G] [topological_group G] (x y : G) :

filter.map (has_mul.mul x) (nhds y) = nhds (x * y)

source

theorem map_add_left_nhds_zero {G : Type w} [topological_space G] [add_group G] [topological_add_group G] (x : G) :

filter.map (has_add.add x) (nhds 0) = nhds x

source

theorem map_mul_left_nhds_one {G : Type w} [topological_space G] [group G] [topological_group G] (x : G) :

filter.map (has_mul.mul x) (nhds 1) = nhds x

source

theorem continuous_of_continuous_at_one {G : Type w} [topological_space G] [group G] [topological_group G] {M : Type u_1} {hom : Type u_2} [mul_one_class M] [topological_space M] [has_continuous_mul M] [monoid_hom_class hom G M] (f : hom) (hf : continuous_at ⇑f 1) :

continuous ⇑f

A monoid homomorphism (a bundled morphism of a type that implements monoid_hom_class) from a topological group to a topological monoid is continuous provided that it is continuous at one. See also uniform_continuous_of_continuous_at_one.

source

theorem continuous_of_continuous_at_zero {G : Type w} [topological_space G] [add_group G] [topological_add_group G] {M : Type u_1} {hom : Type u_2} [add_zero_class M] [topological_space M] [has_continuous_add M] [add_monoid_hom_class hom G M] (f : hom) (hf : continuous_at ⇑f 0) :

continuous ⇑f

An additive monoid homomorphism (a bundled morphism of a type that implements add_monoid_hom_class) from an additive topological group to an additive topological monoid is continuous provided that it is continuous at zero. See also uniform_continuous_of_continuous_at_zero.

source

theorem topological_group.ext {G : Type u_1} [group G] {t t' : topological_space G} (tg : topological_group G) (tg' : topological_group G) (h : nhds 1 = nhds 1) :

t = t'

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theorem topological_add_group.ext {G : Type u_1} [add_group G] {t t' : topological_space G} (tg : topological_add_group G) (tg' : topological_add_group G) (h : nhds 0 = nhds 0) :

t = t'

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theorem topological_group.of_nhds_aux {G : Type u_1} [group G] [topological_space G] (hinv : filter.tendsto (λ (x : G), x⁻¹) (nhds 1) (nhds 1)) (hleft : ∀ (x₀ : G), nhds x₀ = filter.map (λ (x : G), x₀ * x) (nhds 1)) (hconj : ∀ (x₀ : G), filter.map (λ (x : G), x₀ * x * x₀⁻¹) (nhds 1) ≤ nhds 1) :

continuous (λ (x : G), x⁻¹)

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theorem topological_add_group.of_nhds_aux {G : Type u_1} [add_group G] [topological_space G] (hinv : filter.tendsto (λ (x : G), -x) (nhds 0) (nhds 0)) (hleft : ∀ (x₀ : G), nhds x₀ = filter.map (λ (x : G), x₀ + x) (nhds 0)) (hconj : ∀ (x₀ : G), filter.map (λ (x : G), x₀ + x + -x₀) (nhds 0) ≤ nhds 0) :

continuous (λ (x : G), -x)

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theorem topological_group.of_nhds_one' {G : Type u} [group G] [topological_space G] (hmul : filter.tendsto (function.uncurry has_mul.mul) ((nhds 1).prod (nhds 1)) (nhds 1)) (hinv : filter.tendsto (λ (x : G), x⁻¹) (nhds 1) (nhds 1)) (hleft : ∀ (x₀ : G), nhds x₀ = filter.map (λ (x : G), x₀ * x) (nhds 1)) (hright : ∀ (x₀ : G), nhds x₀ = filter.map (λ (x : G), x * x₀) (nhds 1)) :

topological_group G

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theorem topological_add_group.of_nhds_zero' {G : Type u} [add_group G] [topological_space G] (hmul : filter.tendsto (function.uncurry has_add.add) ((nhds 0).prod (nhds 0)) (nhds 0)) (hinv : filter.tendsto (λ (x : G), -x) (nhds 0) (nhds 0)) (hleft : ∀ (x₀ : G), nhds x₀ = filter.map (λ (x : G), x₀ + x) (nhds 0)) (hright : ∀ (x₀ : G), nhds x₀ = filter.map (λ (x : G), x + x₀) (nhds 0)) :

topological_add_group G

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theorem topological_add_group.of_nhds_zero {G : Type u} [add_group G] [topological_space G] (hmul : filter.tendsto (function.uncurry has_add.add) ((nhds 0).prod (nhds 0)) (nhds 0)) (hinv : filter.tendsto (λ (x : G), -x) (nhds 0) (nhds 0)) (hleft : ∀ (x₀ : G), nhds x₀ = filter.map (λ (x : G), x₀ + x) (nhds 0)) (hconj : ∀ (x₀ : G), filter.tendsto (λ (x : G), x₀ + x + -x₀) (nhds 0) (nhds 0)) :

topological_add_group G

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theorem topological_group.of_nhds_one {G : Type u} [group G] [topological_space G] (hmul : filter.tendsto (function.uncurry has_mul.mul) ((nhds 1).prod (nhds 1)) (nhds 1)) (hinv : filter.tendsto (λ (x : G), x⁻¹) (nhds 1) (nhds 1)) (hleft : ∀ (x₀ : G), nhds x₀ = filter.map (λ (x : G), x₀ * x) (nhds 1)) (hconj : ∀ (x₀ : G), filter.tendsto (λ (x : G), x₀ * x * x₀⁻¹) (nhds 1) (nhds 1)) :

topological_group G

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theorem topological_add_group.of_comm_of_nhds_zero {G : Type u} [add_comm_group G] [topological_space G] (hmul : filter.tendsto (function.uncurry has_add.add) ((nhds 0).prod (nhds 0)) (nhds 0)) (hinv : filter.tendsto (λ (x : G), -x) (nhds 0) (nhds 0)) (hleft : ∀ (x₀ : G), nhds x₀ = filter.map (λ (x : G), x₀ + x) (nhds 0)) :

topological_add_group G

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theorem topological_group.of_comm_of_nhds_one {G : Type u} [comm_group G] [topological_space G] (hmul : filter.tendsto (function.uncurry has_mul.mul) ((nhds 1).prod (nhds 1)) (nhds 1)) (hinv : filter.tendsto (λ (x : G), x⁻¹) (nhds 1) (nhds 1)) (hleft : ∀ (x₀ : G), nhds x₀ = filter.map (λ (x : G), x₀ * x) (nhds 1)) :

topological_group G

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@[protected, instance]

def quotient_group.quotient.topological_space {G : Type u_1} [group G] [topological_space G] (N : subgroup G) :

topological_space (G ⧸ N)

Equations

quotient_group.quotient.topological_space N = quotient.topological_space

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@[protected, instance]

def quotient_add_group.quotient.topological_space {G : Type u_1} [add_group G] [topological_space G] (N : add_subgroup G) :

topological_space (G ⧸ N)

Equations

quotient_add_group.quotient.topological_space N = quotient.topological_space

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theorem quotient_group.is_open_map_coe {G : Type w} [topological_space G] [group G] [topological_group G] (N : subgroup G) :

is_open_map coe

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theorem quotient_add_group.is_open_map_coe {G : Type w} [topological_space G] [add_group G] [topological_add_group G] (N : add_subgroup G) :

is_open_map coe

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@[protected, instance]

def topological_add_group_quotient {G : Type w} [topological_space G] [add_group G] [topological_add_group G] (N : add_subgroup G) [N.normal] :

topological_add_group (G ⧸ N)

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@[protected, instance]

def topological_group_quotient {G : Type w} [topological_space G] [group G] [topological_group G] (N : subgroup G) [N.normal] :

topological_group (G ⧸ N)

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@[class]

structure has_continuous_sub (G : Type u_1) [topological_space G] [has_sub G] :

Prop

continuous_sub : continuous (λ (p : G × G), p.fst - p.snd)

A typeclass saying that λ p : G × G, p.1 - p.2 is a continuous function. This property automatically holds for topological additive groups but it also holds, e.g., for ℝ≥0.

Instances of this typeclass

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@[class]

structure has_continuous_div (G : Type u_1) [topological_space G] [has_div G] :

Prop

continuous_div' : continuous (λ (p : G × G), p.fst / p.snd)

A typeclass saying that λ p : G × G, p.1 / p.2 is a continuous function. This property automatically holds for topological groups. Lemmas using this class have primes. The unprimed version is for group_with_zero.

Instances of this typeclass

topological_group.to_has_continuous_div

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@[protected, instance]

def topological_add_group.to_has_continuous_sub {G : Type w} [topological_space G] [add_group G] [topological_add_group G] :

has_continuous_sub G

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@[protected, instance]

def topological_group.to_has_continuous_div {G : Type w} [topological_space G] [group G] [topological_group G] :

has_continuous_div G

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theorem filter.tendsto.div' {α : Type u} {G : Type w} [topological_space G] [has_div G] [has_continuous_div G] {f g : α → G} {l : filter α} {a b : G} (hf : filter.tendsto f l (nhds a)) (hg : filter.tendsto g l (nhds b)) :

filter.tendsto (λ (x : α), f x / g x) l (nhds (a / b))

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theorem filter.tendsto.sub {α : Type u} {G : Type w} [topological_space G] [has_sub G] [has_continuous_sub G] {f g : α → G} {l : filter α} {a b : G} (hf : filter.tendsto f l (nhds a)) (hg : filter.tendsto g l (nhds b)) :

filter.tendsto (λ (x : α), f x - g x) l (nhds (a - b))

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theorem filter.tendsto.const_sub {α : Type u} {G : Type w} [topological_space G] [has_sub G] [has_continuous_sub G] (b : G) {c : G} {f : α → G} {l : filter α} (h : filter.tendsto f l (nhds c)) :

filter.tendsto (λ (k : α), b - f k) l (nhds (b - c))

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theorem filter.tendsto.const_div' {α : Type u} {G : Type w} [topological_space G] [has_div G] [has_continuous_div G] (b : G) {c : G} {f : α → G} {l : filter α} (h : filter.tendsto f l (nhds c)) :

filter.tendsto (λ (k : α), b / f k) l (nhds (b / c))

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theorem filter.tendsto.div_const' {α : Type u} {G : Type w} [topological_space G] [has_div G] [has_continuous_div G] (b : G) {c : G} {f : α → G} {l : filter α} (h : filter.tendsto f l (nhds c)) :

filter.tendsto (λ (k : α), f k / b) l (nhds (c / b))

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theorem filter.tendsto.sub_const {α : Type u} {G : Type w} [topological_space G] [has_sub G] [has_continuous_sub G] (b : G) {c : G} {f : α → G} {l : filter α} (h : filter.tendsto f l (nhds c)) :

filter.tendsto (λ (k : α), f k - b) l (nhds (c - b))

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@[continuity]

theorem continuous.div' {α : Type u} {G : Type w} [topological_space G] [has_div G] [has_continuous_div G] [topological_space α] {f g : α → G} (hf : continuous f) (hg : continuous g) :

continuous (λ (x : α), f x / g x)

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@[continuity]

theorem continuous.sub {α : Type u} {G : Type w} [topological_space G] [has_sub G] [has_continuous_sub G] [topological_space α] {f g : α → G} (hf : continuous f) (hg : continuous g) :

continuous (λ (x : α), f x - g x)

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theorem continuous_sub_left {G : Type w} [topological_space G] [has_sub G] [has_continuous_sub G] (a : G) :

continuous (λ (b : G), a - b)

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theorem continuous_div_left' {G : Type w} [topological_space G] [has_div G] [has_continuous_div G] (a : G) :

continuous (λ (b : G), a / b)

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theorem continuous_sub_right {G : Type w} [topological_space G] [has_sub G] [has_continuous_sub G] (a : G) :

continuous (λ (b : G), b - a)

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theorem continuous_div_right' {G : Type w} [topological_space G] [has_div G] [has_continuous_div G] (a : G) :

continuous (λ (b : G), b / a)

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theorem continuous_at.div' {α : Type u} {G : Type w} [topological_space G] [has_div G] [has_continuous_div G] [topological_space α] {f g : α → G} {x : α} (hf : continuous_at f x) (hg : continuous_at g x) :

continuous_at (λ (x : α), f x / g x) x

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theorem continuous_at.sub {α : Type u} {G : Type w} [topological_space G] [has_sub G] [has_continuous_sub G] [topological_space α] {f g : α → G} {x : α} (hf : continuous_at f x) (hg : continuous_at g x) :

continuous_at (λ (x : α), f x - g x) x

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theorem continuous_within_at.sub {α : Type u} {G : Type w} [topological_space G] [has_sub G] [has_continuous_sub G] [topological_space α] {f g : α → G} {s : set α} {x : α} (hf : continuous_within_at f s x) (hg : continuous_within_at g s x) :

continuous_within_at (λ (x : α), f x - g x) s x

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theorem continuous_within_at.div' {α : Type u} {G : Type w} [topological_space G] [has_div G] [has_continuous_div G] [topological_space α] {f g : α → G} {s : set α} {x : α} (hf : continuous_within_at f s x) (hg : continuous_within_at g s x) :

continuous_within_at (λ (x : α), f x / g x) s x

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theorem continuous_on.sub {α : Type u} {G : Type w} [topological_space G] [has_sub G] [has_continuous_sub G] [topological_space α] {f g : α → G} {s : set α} (hf : continuous_on f s) (hg : continuous_on g s) :

continuous_on (λ (x : α), f x - g x) s

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theorem continuous_on.div' {α : Type u} {G : Type w} [topological_space G] [has_div G] [has_continuous_div G] [topological_space α] {f g : α → G} {s : set α} (hf : continuous_on f s) (hg : continuous_on g s) :

continuous_on (λ (x : α), f x / g x) s

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@[simp]

theorem homeomorph.sub_left_symm_apply {G : Type w} [add_group G] [topological_space G] [topological_add_group G] (x ᾰ : G) :

⇑((homeomorph.sub_left x).symm) ᾰ = -ᾰ + x

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def homeomorph.div_left {G : Type w} [group G] [topological_space G] [topological_group G] (x : G) :

G ≃ₜ G

A version of homeomorph.mul_left a b⁻¹ that is defeq to a / b.

Equations

homeomorph.div_left x = {to_equiv := {to_fun := (equiv.div_left x).to_fun, inv_fun := (equiv.div_left x).inv_fun, left_inv := _, right_inv := _}, continuous_to_fun := _, continuous_inv_fun := _}

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def homeomorph.sub_left {G : Type w} [add_group G] [topological_space G] [topological_add_group G] (x : G) :

G ≃ₜ G

A version of homeomorph.add_left a (-b) that is defeq to a - b.

Equations

homeomorph.sub_left x = {to_equiv := {to_fun := (equiv.sub_left x).to_fun, inv_fun := (equiv.sub_left x).inv_fun, left_inv := _, right_inv := _}, continuous_to_fun := _, continuous_inv_fun := _}

source

@[simp]

theorem homeomorph.div_left_symm_apply {G : Type w} [group G] [topological_space G] [topological_group G] (x ᾰ : G) :

⇑((homeomorph.div_left x).symm) ᾰ = ᾰ⁻¹ * x

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@[simp]

theorem homeomorph.sub_left_apply {G : Type w} [add_group G] [topological_space G] [topological_add_group G] (x ᾰ : G) :

⇑(homeomorph.sub_left x) ᾰ = x - ᾰ

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@[simp]

theorem homeomorph.div_left_apply {G : Type w} [group G] [topological_space G] [topological_group G] (x ᾰ : G) :

⇑(homeomorph.div_left x) ᾰ = x / ᾰ

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theorem is_open_map_div_left {G : Type w} [group G] [topological_space G] [topological_group G] (a : G) :

is_open_map (has_div.div a)

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theorem is_open_map_sub_left {G : Type w} [add_group G] [topological_space G] [topological_add_group G] (a : G) :

is_open_map (has_sub.sub a)

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theorem is_closed_map_div_left {G : Type w} [group G] [topological_space G] [topological_group G] (a : G) :

is_closed_map (has_div.div a)

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theorem is_closed_map_sub_left {G : Type w} [add_group G] [topological_space G] [topological_add_group G] (a : G) :

is_closed_map (has_sub.sub a)

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@[simp]

theorem homeomorph.sub_right_symm_apply {G : Type w} [add_group G] [topological_space G] [topological_add_group G] (x ᾰ : G) :

⇑((homeomorph.sub_right x).symm) ᾰ = ᾰ + x

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@[simp]

theorem homeomorph.div_right_symm_apply {G : Type w} [group G] [topological_space G] [topological_group G] (x ᾰ : G) :

⇑((homeomorph.div_right x).symm) ᾰ = ᾰ * x

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@[simp]

theorem homeomorph.sub_right_apply {G : Type w} [add_group G] [topological_space G] [topological_add_group G] (x ᾰ : G) :

⇑(homeomorph.sub_right x) ᾰ = ᾰ - x

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@[simp]

theorem homeomorph.div_right_apply {G : Type w} [group G] [topological_space G] [topological_group G] (x ᾰ : G) :

⇑(homeomorph.div_right x) ᾰ = ᾰ / x

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def homeomorph.div_right {G : Type w} [group G] [topological_space G] [topological_group G] (x : G) :

G ≃ₜ G

A version of homeomorph.mul_right a⁻¹ b that is defeq to b / a.

Equations

homeomorph.div_right x = {to_equiv := {to_fun := (equiv.div_right x).to_fun, inv_fun := (equiv.div_right x).inv_fun, left_inv := _, right_inv := _}, continuous_to_fun := _, continuous_inv_fun := _}

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def homeomorph.sub_right {G : Type w} [add_group G] [topological_space G] [topological_add_group G] (x : G) :

G ≃ₜ G

A version of homeomorph.add_right (-a) b that is defeq to b - a.

Equations

homeomorph.sub_right x = {to_equiv := {to_fun := (equiv.sub_right x).to_fun, inv_fun := (equiv.sub_right x).inv_fun, left_inv := _, right_inv := _}, continuous_to_fun := _, continuous_inv_fun := _}

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theorem is_open_map_sub_right {G : Type w} [add_group G] [topological_space G] [topological_add_group G] (a : G) :

is_open_map (λ (x : G), x - a)

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theorem is_open_map_div_right {G : Type w} [group G] [topological_space G] [topological_group G] (a : G) :

is_open_map (λ (x : G), x / a)

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theorem is_closed_map_sub_right {G : Type w} [add_group G] [topological_space G] [topological_add_group G] (a : G) :

is_closed_map (λ (x : G), x - a)

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theorem is_closed_map_div_right {G : Type w} [group G] [topological_space G] [topological_group G] (a : G) :

is_closed_map (λ (x : G), x / a)

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theorem tendsto_div_nhds_one_iff {G : Type w} [group G] [topological_space G] [topological_group G] {α : Type u_1} {l : filter α} {x : G} {u : α → G} :

filter.tendsto (λ (n : α), u n / x) l (nhds 1) ↔ filter.tendsto u l (nhds x)

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theorem tendsto_sub_nhds_zero_iff {G : Type w} [add_group G] [topological_space G] [topological_add_group G] {α : Type u_1} {l : filter α} {x : G} {u : α → G} :

filter.tendsto (λ (n : α), u n - x) l (nhds 0) ↔ filter.tendsto u l (nhds x)

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theorem nhds_translation_div {G : Type w} [group G] [topological_space G] [topological_group G] (x : G) :

filter.comap (λ (_x : G), _x / x) (nhds 1) = nhds x

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theorem nhds_translation_sub {G : Type w} [add_group G] [topological_space G] [topological_add_group G] (x : G) :

filter.comap (λ (_x : G), _x - x) (nhds 0) = nhds x

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theorem is_open.mul_left {α : Type u} [topological_space α] [group α] [has_continuous_mul α] {s t : set α} (ht : is_open t) :

is_open (s * t)

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theorem is_open.add_left {α : Type u} [topological_space α] [add_group α] [has_continuous_add α] {s t : set α} (ht : is_open t) :

is_open (s + t)

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theorem is_open.mul_right {α : Type u} [topological_space α] [group α] [has_continuous_mul α] {s t : set α} (hs : is_open s) :

is_open (s * t)

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theorem is_open.add_right {α : Type u} [topological_space α] [add_group α] [has_continuous_add α] {s t : set α} (hs : is_open s) :

is_open (s + t)

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theorem subset_interior_mul_left {α : Type u} [topological_space α] [group α] [has_continuous_mul α] {s t : set α} :

interior s * t ⊆ interior (s * t)

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theorem subset_interior_add_left {α : Type u} [topological_space α] [add_group α] [has_continuous_add α] {s t : set α} :

interior s + t ⊆ interior (s + t)

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theorem subset_interior_add_right {α : Type u} [topological_space α] [add_group α] [has_continuous_add α] {s t : set α} :

s + interior t ⊆ interior (s + t)

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theorem subset_interior_mul_right {α : Type u} [topological_space α] [group α] [has_continuous_mul α] {s t : set α} :

s * interior t ⊆ interior (s * t)

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theorem subset_interior_add {α : Type u} [topological_space α] [add_group α] [has_continuous_add α] {s t : set α} :

interior s + interior t ⊆ interior (s + t)

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theorem subset_interior_mul {α : Type u} [topological_space α] [group α] [has_continuous_mul α] {s t : set α} :

interior s * interior t ⊆ interior (s * t)

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theorem is_open.div_left {α : Type u} [topological_space α] [group α] [topological_group α] {s t : set α} (ht : is_open t) :

is_open (s / t)

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theorem is_open.sub_left {α : Type u} [topological_space α] [add_group α] [topological_add_group α] {s t : set α} (ht : is_open t) :

is_open (s - t)

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theorem is_open.div_right {α : Type u} [topological_space α] [group α] [topological_group α] {s t : set α} (hs : is_open s) :

is_open (s / t)

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theorem is_open.sub_right {α : Type u} [topological_space α] [add_group α] [topological_add_group α] {s t : set α} (hs : is_open s) :

is_open (s - t)

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theorem subset_interior_div_left {α : Type u} [topological_space α] [group α] [topological_group α] {s t : set α} :

interior s / t ⊆ interior (s / t)

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theorem subset_interior_sub_left {α : Type u} [topological_space α] [add_group α] [topological_add_group α] {s t : set α} :

interior s - t ⊆ interior (s - t)

source

theorem subset_interior_sub_right {α : Type u} [topological_space α] [add_group α] [topological_add_group α] {s t : set α} :

s - interior t ⊆ interior (s - t)

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theorem subset_interior_div_right {α : Type u} [topological_space α] [group α] [topological_group α] {s t : set α} :

s / interior t ⊆ interior (s / t)

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theorem subset_interior_sub {α : Type u} [topological_space α] [add_group α] [topological_add_group α] {s t : set α} :

interior s - interior t ⊆ interior (s - t)

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theorem subset_interior_div {α : Type u} [topological_space α] [group α] [topological_group α] {s t : set α} :

interior s / interior t ⊆ interior (s / t)

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theorem is_open.mul_closure {α : Type u} [topological_space α] [group α] [topological_group α] {s : set α} (hs : is_open s) (t : set α) :

s * closure t = s * t

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theorem is_open.add_closure {α : Type u} [topological_space α] [add_group α] [topological_add_group α] {s : set α} (hs : is_open s) (t : set α) :

s + closure t = s + t

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theorem is_open.closure_add {α : Type u} [topological_space α] [add_group α] [topological_add_group α] {t : set α} (ht : is_open t) (s : set α) :

closure s + t = s + t

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theorem is_open.closure_mul {α : Type u} [topological_space α] [group α] [topological_group α] {t : set α} (ht : is_open t) (s : set α) :

closure s * t = s * t

source

theorem is_open.sub_closure {α : Type u} [topological_space α] [add_group α] [topological_add_group α] {s : set α} (hs : is_open s) (t : set α) :

s - closure t = s - t

source

theorem is_open.div_closure {α : Type u} [topological_space α] [group α] [topological_group α] {s : set α} (hs : is_open s) (t : set α) :

s / closure t = s / t

source

theorem is_open.closure_div {α : Type u} [topological_space α] [group α] [topological_group α] {t : set α} (ht : is_open t) (s : set α) :

closure s / t = s / t

source

theorem is_open.closure_sub {α : Type u} [topological_space α] [add_group α] [topological_add_group α] {t : set α} (ht : is_open t) (s : set α) :

closure s - t = s - t

source

@[class]

structure add_group_with_zero_nhd (G : Type u) :

Type u

to_add_comm_group : add_comm_group G
Z : filter G
zero_Z : has_pure.pure 0 ≤ add_group_with_zero_nhd.Z G
sub_Z : filter.tendsto (λ (p : G × G), p.fst - p.snd) ((add_group_with_zero_nhd.Z G).prod (add_group_with_zero_nhd.Z G)) (add_group_with_zero_nhd.Z G)

additive group with a neighbourhood around 0. Only used to construct a topology and uniform space.

This is currently only available for commutative groups, but it can be extended to non-commutative groups too.

Instances for add_group_with_zero_nhd

add_group_with_zero_nhd.has_sizeof_inst

source

theorem topological_add_group.t1_space (G : Type w) [topological_space G] [add_group G] [topological_add_group G] (h : is_closed {0}) :

t1_space G

source

theorem topological_group.t1_space (G : Type w) [topological_space G] [group G] [topological_group G] (h : is_closed {1}) :

t1_space G

source

theorem topological_add_group.regular_space (G : Type w) [topological_space G] [add_group G] [topological_add_group G] [t1_space G] :

regular_space G

source

theorem topological_group.regular_space (G : Type w) [topological_space G] [group G] [topological_group G] [t1_space G] :

regular_space G

source

theorem topological_add_group.t2_space (G : Type w) [topological_space G] [add_group G] [topological_add_group G] [t1_space G] :

t2_space G

source

theorem topological_group.t2_space (G : Type w) [topological_space G] [group G] [topological_group G] [t1_space G] :

t2_space G

source

@[protected, instance]

def subgroup.regular_quotient_of_is_closed {G : Type w} [topological_space G] [group G] [topological_group G] (S : subgroup G) [S.normal] [is_closed ↑S] :

regular_space (G ⧸ S)

source

@[protected, instance]

def add_subgroup.regular_quotient_of_is_closed {G : Type w} [topological_space G] [add_group G] [topological_add_group G] (S : add_subgroup G) [S.normal] [is_closed ↑S] :

regular_space (G ⧸ S)

source

theorem compact_open_separated_add_right {G : Type w} [topological_space G] [add_group G] [topological_add_group G] {K U : set G} (hK : is_compact K) (hU : is_open U) (hKU : K ⊆ U) :

∃ (V : set G) (H : V ∈ nhds 0), K + V ⊆ U

Given a compact set K inside an open set U, there is a open neighborhood V of 0 such that K + V ⊆ U.

source

theorem compact_open_separated_mul_right {G : Type w} [topological_space G] [group G] [topological_group G] {K U : set G} (hK : is_compact K) (hU : is_open U) (hKU : K ⊆ U) :

∃ (V : set G) (H : V ∈ nhds 1), K * V ⊆ U

Given a compact set K inside an open set U, there is a open neighborhood V of 1 such that K * V ⊆ U.

source

theorem compact_open_separated_add_left {G : Type w} [topological_space G] [add_group G] [topological_add_group G] {K U : set G} (hK : is_compact K) (hU : is_open U) (hKU : K ⊆ U) :

∃ (V : set G) (H : V ∈ nhds 0), V + K ⊆ U

Given a compact set K inside an open set U, there is a open neighborhood V of 0 such that V + K ⊆ U.

source

theorem compact_open_separated_mul_left {G : Type w} [topological_space G] [group G] [topological_group G] {K U : set G} (hK : is_compact K) (hU : is_open U) (hKU : K ⊆ U) :

∃ (V : set G) (H : V ∈ nhds 1), V * K ⊆ U

Given a compact set K inside an open set U, there is a open neighborhood V of 1 such that V * K ⊆ U.

source

theorem compact_covered_by_add_left_translates {G : Type w} [topological_space G] [add_group G] [topological_add_group G] {K V : set G} (hK : is_compact K) (hV : (interior V).nonempty) :

∃ (t : finset G), K ⊆ ⋃ (g : G) (H : g ∈ t), (λ (h : G), g + h) ⁻¹' V

A compact set is covered by finitely many left additive translates of a set with non-empty interior.

source

theorem compact_covered_by_mul_left_translates {G : Type w} [topological_space G] [group G] [topological_group G] {K V : set G} (hK : is_compact K) (hV : (interior V).nonempty) :

∃ (t : finset G), K ⊆ ⋃ (g : G) (H : g ∈ t), (λ (h : G), g * h) ⁻¹' V

A compact set is covered by finitely many left multiplicative translates of a set with non-empty interior.

source

@[protected, instance]

def separable_locally_compact_add_group.sigma_compact_space {G : Type w} [topological_space G] [add_group G] [topological_add_group G] [topological_space.separable_space G] [locally_compact_space G] :

sigma_compact_space G

source

@[protected, instance]

def separable_locally_compact_group.sigma_compact_space {G : Type w} [topological_space G] [group G] [topological_group G] [topological_space.separable_space G] [locally_compact_space G] :

sigma_compact_space G

Every locally compact separable topological group is σ-compact. Note: this is not true if we drop the topological group hypothesis.

source

theorem topological_space.positive_compacts.locally_compact_space_of_add_group {G : Type w} [topological_space G] [add_group G] [topological_add_group G] [t2_space G] (K : topological_space.positive_compacts G) :

locally_compact_space G

source

theorem topological_space.positive_compacts.locally_compact_space_of_group {G : Type w} [topological_space G] [group G] [topological_group G] [t2_space G] (K : topological_space.positive_compacts G) :

locally_compact_space G

Every separated topological group in which there exists a compact set with nonempty interior is locally compact.

source

theorem nhds_mul {G : Type w} [topological_space G] [comm_group G] [topological_group G] (x y : G) :

nhds (x * y) = nhds x * nhds y

source

theorem nhds_add {G : Type w} [topological_space G] [add_comm_group G] [topological_add_group G] (x y : G) :

nhds (x + y) = nhds x + nhds y

source

@[simp]

theorem nhds_mul_hom_apply {G : Type w} [topological_space G] [comm_group G] [topological_group G] (a : G) :

⇑nhds_mul_hom a = nhds a

source

def nhds_add_hom {G : Type w} [topological_space G] [add_comm_group G] [topological_add_group G] :

add_hom G (filter G)

On an additive topological group, 𝓝 : G → filter G can be promoted to an add_hom.

Equations

nhds_add_hom = {to_fun := nhds _inst_1, map_add' := _}

source

@[simp]

theorem nhds_add_hom_apply {G : Type w} [topological_space G] [add_comm_group G] [topological_add_group G] (a : G) :

⇑nhds_add_hom a = nhds a

source

def nhds_mul_hom {G : Type w} [topological_space G] [comm_group G] [topological_group G] :

G →ₙ* filter G

On a topological group, 𝓝 : G → filter G can be promoted to a mul_hom.

Equations

nhds_mul_hom = {to_fun := nhds _inst_1, map_mul' := _}

source

@[protected, instance]

def additive.topological_add_group {G : Type u_1} [h : topological_space G] [group G] [topological_group G] :

topological_add_group (additive G)

source

@[protected, instance]

def multiplicative.topological_group {G : Type u_1} [h : topological_space G] [add_group G] [topological_add_group G] :

topological_group (multiplicative G)

source

@[protected, instance]

def quotient_group.has_continuous_const_smul {G : Type w} [group G] [topological_space G] [topological_group G] {Γ : subgroup G} :

has_continuous_const_smul G (G ⧸ Γ)

source

@[protected, instance]

def quotient_add_group.has_continuous_const_vadd {G : Type w} [add_group G] [topological_space G] [topological_add_group G] {Γ : add_subgroup G} :

has_continuous_const_vadd G (G ⧸ Γ)

source

theorem quotient_add_group.continuous_smul₁ {G : Type w} [add_group G] [topological_space G] [topological_add_group G] {Γ : add_subgroup G} (x : G ⧸ Γ) :

continuous (λ (g : G), g +ᵥ x)

source

theorem quotient_group.continuous_smul₁ {G : Type w} [group G] [topological_space G] [topological_group G] {Γ : subgroup G} (x : G ⧸ Γ) :

continuous (λ (g : G), g • x)

source

@[protected, instance]

def quotient_add_group.has_continuous_vadd {G : Type w} [add_group G] [topological_space G] [topological_add_group G] {Γ : add_subgroup G} [locally_compact_space G] :

has_continuous_vadd G (G ⧸ Γ)

source

@[protected, instance]

def quotient_group.has_continuous_smul {G : Type w} [group G] [topological_space G] [topological_group G] {Γ : subgroup G} [locally_compact_space G] :

has_continuous_smul G (G ⧸ Γ)

source

@[protected, instance]

def add_units.topological_add_group {α : Type u} [add_monoid α] [topological_space α] [has_continuous_add α] :

topological_add_group (add_units α)

source

@[protected, instance]

def units.topological_group {α : Type u} [monoid α] [topological_space α] [has_continuous_mul α] :

topological_group αˣ

source

def units.homeomorph.prod_units {α : Type u} {β : Type v} [monoid α] [topological_space α] [has_continuous_mul α] [monoid β] [topological_space β] [has_continuous_mul β] :

(α × β)ˣ ≃ₜ αˣ × βˣ

The topological group isomorphism between the units of a product of two monoids, and the product of the units of each monoid.

Equations

units.homeomorph.prod_units = {to_equiv := {to_fun := mul_equiv.prod_units.to_fun, inv_fun := mul_equiv.prod_units.inv_fun, left_inv := _, right_inv := _}, continuous_to_fun := _, continuous_inv_fun := _}

source

theorem topological_group_Inf {G : Type w} [group G] {ts : set (topological_space G)} (h : ∀ (t : topological_space G), t ∈ ts → topological_group G) :

topological_group G

source

theorem topological_add_group_Inf {G : Type w} [add_group G] {ts : set (topological_space G)} (h : ∀ (t : topological_space G), t ∈ ts → topological_add_group G) :

topological_add_group G

source

theorem topological_add_group_infi {G : Type w} {ι : Sort u_1} [add_group G] {ts' : ι → topological_space G} (h' : ∀ (i : ι), topological_add_group G) :

topological_add_group G

source

theorem topological_group_infi {G : Type w} {ι : Sort u_1} [group G] {ts' : ι → topological_space G} (h' : ∀ (i : ι), topological_group G) :

topological_group G

source

theorem topological_group_inf {G : Type w} [group G] {t₁ t₂ : topological_space G} (h₁ : topological_group G) (h₂ : topological_group G) :

topological_group G

source

theorem topological_add_group_inf {G : Type w} [add_group G] {t₁ t₂ : topological_space G} (h₁ : topological_add_group G) (h₂ : topological_add_group G) :

topological_add_group G

source

theorem topological_group_induced {G : Type w} {H : Type x} [group G] [group H] {t : topological_space H} [topological_group H] {F : Type u_2} [monoid_hom_class F G H] (f : F) :

topological_group G

source

theorem topological_add_group_induced {G : Type w} {H : Type x} [add_group G] [add_group H] {t : topological_space H} [topological_add_group H] {F : Type u_2} [add_monoid_hom_class F G H] (f : F) :

topological_add_group G

source

structure group_topology (α : Type u) [group α] :

Type u

to_topological_space : topological_space α
to_topological_group : topological_group α

A group topology on a group α is a topology for which multiplication and inversion are continuous.

Instances for group_topology

source

structure add_group_topology (α : Type u) [add_group α] :

Type u

to_topological_space : topological_space α
to_topological_add_group : topological_add_group α

An additive group topology on an additive group α is a topology for which addition and negation are continuous.

Instances for add_group_topology

source

theorem add_group_topology.continuous_add' {α : Type u} [add_group α] (g : add_group_topology α) :

continuous (λ (p : α × α), p.fst + p.snd)

source

theorem group_topology.continuous_mul' {α : Type u} [group α] (g : group_topology α) :

continuous (λ (p : α × α), p.fst * p.snd)

A version of the global continuous_mul suitable for dot notation.

source

theorem add_group_topology.continuous_neg' {α : Type u} [add_group α] (g : add_group_topology α) :

continuous has_neg.neg

source

theorem group_topology.continuous_inv' {α : Type u} [group α] (g : group_topology α) :

continuous has_inv.inv

A version of the global continuous_inv suitable for dot notation.

source

theorem add_group_topology.to_topological_space_injective {α : Type u} [add_group α] :

function.injective add_group_topology.to_topological_space

source

theorem group_topology.to_topological_space_injective {α : Type u} [group α] :

function.injective group_topology.to_topological_space

source

@[ext]

theorem group_topology.ext' {α : Type u} [group α] {f g : group_topology α} (h : f.to_topological_space.is_open = g.to_topological_space.is_open) :

f = g

source

theorem add_group_topology.ext' {α : Type u} [add_group α] {f g : add_group_topology α} (h : f.to_topological_space.is_open = g.to_topological_space.is_open) :

f = g

source

@[protected, instance]

def group_topology.partial_order {α : Type u} [group α] :

partial_order (group_topology α)

The ordering on group topologies on the group γ. t ≤ s if every set open in s is also open in t (t is finer than s).

Equations

group_topology.partial_order = partial_order.lift group_topology.to_topological_space group_topology.to_topological_space_injective

source

@[protected, instance]

def add_group_topology.partial_order {α : Type u} [add_group α] :

partial_order (add_group_topology α)

Equations

add_group_topology.partial_order = partial_order.lift add_group_topology.to_topological_space add_group_topology.to_topological_space_injective

source

@[simp]

theorem group_topology.to_topological_space_le {α : Type u} [group α] {x y : group_topology α} :

x.to_topological_space ≤ y.to_topological_space ↔ x ≤ y

source

@[simp]

theorem add_group_topology.to_topological_space_le {α : Type u} [add_group α] {x y : add_group_topology α} :

x.to_topological_space ≤ y.to_topological_space ↔ x ≤ y

source

@[protected, instance]

def group_topology.has_top {α : Type u} [group α] :

has_top (group_topology α)

Equations

group_topology.has_top = {top := {to_topological_space := ⊤, to_topological_group := _}}

source

@[protected, instance]

def add_group_topology.has_top {α : Type u} [add_group α] :

has_top (add_group_topology α)

Equations

add_group_topology.has_top = {top := {to_topological_space := ⊤, to_topological_add_group := _}}

source

@[simp]

theorem add_group_topology.to_topological_space_top {α : Type u} [add_group α] :

⊤.to_topological_space = ⊤

source

@[simp]

theorem group_topology.to_topological_space_top {α : Type u} [group α] :

⊤.to_topological_space = ⊤

source

@[protected, instance]

def group_topology.has_bot {α : Type u} [group α] :

has_bot (group_topology α)

Equations

group_topology.has_bot = {bot := {to_topological_space := ⊥, to_topological_group := _}}

source

@[protected, instance]

def add_group_topology.has_bot {α : Type u} [add_group α] :

has_bot (add_group_topology α)

Equations

add_group_topology.has_bot = {bot := {to_topological_space := ⊥, to_topological_add_group := _}}

source

@[simp]

theorem add_group_topology.to_topological_space_bot {α : Type u} [add_group α] :

⊥.to_topological_space = ⊥

source

@[simp]

theorem group_topology.to_topological_space_bot {α : Type u} [group α] :

⊥.to_topological_space = ⊥

source

@[protected, instance]

def group_topology.bounded_order {α : Type u} [group α] :

bounded_order (group_topology α)

Equations

group_topology.bounded_order = {top := ⊤, le_top := _, bot := ⊥, bot_le := _}

source

@[protected, instance]

def add_group_topology.bounded_order {α : Type u} [add_group α] :

bounded_order (add_group_topology α)

Equations

add_group_topology.bounded_order = {top := ⊤, le_top := _, bot := ⊥, bot_le := _}

source

@[protected, instance]

def group_topology.has_inf {α : Type u} [group α] :

has_inf (group_topology α)

Equations

group_topology.has_inf = {inf := λ (x y : group_topology α), {to_topological_space := x.to_topological_space ⊓ y.to_topological_space, to_topological_group := _}}

source

@[protected, instance]

def add_group_topology.has_inf {α : Type u} [add_group α] :

has_inf (add_group_topology α)

Equations

add_group_topology.has_inf = {inf := λ (x y : add_group_topology α), {to_topological_space := x.to_topological_space ⊓ y.to_topological_space, to_topological_add_group := _}}

source

@[simp]

theorem add_group_topology.to_topological_space_inf {α : Type u} [add_group α] (x y : add_group_topology α) :

(x ⊓ y).to_topological_space = x.to_topological_space ⊓ y.to_topological_space

source

@[simp]

theorem group_topology.to_topological_space_inf {α : Type u} [group α] (x y : group_topology α) :

(x ⊓ y).to_topological_space = x.to_topological_space ⊓ y.to_topological_space

source

@[protected, instance]

def group_topology.semilattice_inf {α : Type u} [group α] :

semilattice_inf (group_topology α)

Equations

group_topology.semilattice_inf = function.injective.semilattice_inf group_topology.to_topological_space group_topology.to_topological_space_injective group_topology.to_topological_space_inf

source

@[protected, instance]

def add_group_topology.semilattice_inf {α : Type u} [add_group α] :

semilattice_inf (add_group_topology α)

Equations

add_group_topology.semilattice_inf = function.injective.semilattice_inf add_group_topology.to_topological_space add_group_topology.to_topological_space_injective add_group_topology.to_topological_space_inf

source

@[protected, instance]

def add_group_topology.inhabited {α : Type u} [add_group α] :

inhabited (add_group_topology α)

Equations

add_group_topology.inhabited = {default := ⊤}

source

@[protected, instance]

def group_topology.inhabited {α : Type u} [group α] :

inhabited (group_topology α)

Equations

group_topology.inhabited = {default := ⊤}

source

@[protected, instance]

def group_topology.has_Inf {α : Type u} [group α] :

has_Inf (group_topology α)

Equations

group_topology.has_Inf = {Inf := λ (S : set (group_topology α)), {to_topological_space := has_Inf.Inf (group_topology.to_topological_space '' S), to_topological_group := _}}

source

@[protected, instance]

def add_group_topology.has_Inf {α : Type u} [add_group α] :

has_Inf (add_group_topology α)

Infimum of a collection of additive group topologies

Equations

add_group_topology.has_Inf = {Inf := λ (S : set (add_group_topology α)), {to_topological_space := has_Inf.Inf (add_group_topology.to_topological_space '' S), to_topological_add_group := _}}

source

@[simp]

theorem group_topology.to_topological_space_Inf {α : Type u} [group α] (s : set (group_topology α)) :

(has_Inf.Inf s).to_topological_space = has_Inf.Inf (group_topology.to_topological_space '' s)

source

@[simp]

theorem add_group_topology.to_topological_space_Inf {α : Type u} [add_group α] (s : set (add_group_topology α)) :

(has_Inf.Inf s).to_topological_space = has_Inf.Inf (add_group_topology.to_topological_space '' s)

source

@[simp]

theorem group_topology.to_topological_space_infi {α : Type u} [group α] {ι : Sort u_1} (s : ι → group_topology α) :

(⨅ (i : ι), s i).to_topological_space = ⨅ (i : ι), (s i).to_topological_space

source

@[simp]

theorem add_group_topology.to_topological_space_infi {α : Type u} [add_group α] {ι : Sort u_1} (s : ι → add_group_topology α) :

(⨅ (i : ι), s i).to_topological_space = ⨅ (i : ι), (s i).to_topological_space

source

@[protected, instance]

def group_topology.complete_semilattice_Inf {α : Type u} [group α] :

complete_semilattice_Inf (group_topology α)

Group topologies on γ form a complete lattice, with ⊥ the discrete topology and ⊤ the indiscrete topology.

The infimum of a collection of group topologies is the topology generated by all their open sets (which is a group topology).

The supremum of two group topologies s and t is the infimum of the family of all group topologies contained in the intersection of s and t.

Equations

group_topology.complete_semilattice_Inf = {le := partial_order.le group_topology.partial_order, lt := partial_order.lt group_topology.partial_order, le_refl := _, le_trans := _, lt_iff_le_not_le := _, le_antisymm := _, Inf := has_Inf.Inf group_topology.has_Inf, Inf_le := _, le_Inf := _}

source

@[protected, instance]

def add_group_topology.complete_semilattice_Inf {α : Type u} [add_group α] :

complete_semilattice_Inf (add_group_topology α)

Equations

add_group_topology.complete_semilattice_Inf = {le := partial_order.le add_group_topology.partial_order, lt := partial_order.lt add_group_topology.partial_order, le_refl := _, le_trans := _, lt_iff_le_not_le := _, le_antisymm := _, Inf := has_Inf.Inf add_group_topology.has_Inf, Inf_le := _, le_Inf := _}

source

@[protected, instance]

def add_group_topology.complete_lattice {α : Type u} [add_group α] :

complete_lattice (add_group_topology α)

Equations

add_group_topology.complete_lattice = {sup := complete_lattice.sup (complete_lattice_of_complete_semilattice_Inf (add_group_topology α)), le := semilattice_inf.le add_group_topology.semilattice_inf, lt := semilattice_inf.lt add_group_topology.semilattice_inf, le_refl := _, le_trans := _, lt_iff_le_not_le := _, le_antisymm := _, le_sup_left := _, le_sup_right := _, sup_le := _, inf := has_inf.inf add_group_topology.has_inf, inf_le_left := _, inf_le_right := _, le_inf := _, Sup := complete_lattice.Sup (complete_lattice_of_complete_semilattice_Inf (add_group_topology α)), le_Sup := _, Sup_le := _, Inf := complete_lattice.Inf (complete_lattice_of_complete_semilattice_Inf (add_group_topology α)), Inf_le := _, le_Inf := _, top := ⊤, bot := ⊥, le_top := _, bot_le := _}

source

@[protected, instance]

def group_topology.complete_lattice {α : Type u} [group α] :

complete_lattice (group_topology α)

Equations

group_topology.complete_lattice = {sup := complete_lattice.sup (complete_lattice_of_complete_semilattice_Inf (group_topology α)), le := semilattice_inf.le group_topology.semilattice_inf, lt := semilattice_inf.lt group_topology.semilattice_inf, le_refl := _, le_trans := _, lt_iff_le_not_le := _, le_antisymm := _, le_sup_left := _, le_sup_right := _, sup_le := _, inf := has_inf.inf group_topology.has_inf, inf_le_left := _, inf_le_right := _, le_inf := _, Sup := complete_lattice.Sup (complete_lattice_of_complete_semilattice_Inf (group_topology α)), le_Sup := _, Sup_le := _, Inf := complete_lattice.Inf (complete_lattice_of_complete_semilattice_Inf (group_topology α)), Inf_le := _, le_Inf := _, top := ⊤, bot := ⊥, le_top := _, bot_le := _}

source

def add_group_topology.coinduced {α : Type u_1} {β : Type u_2} [t : topological_space α] [add_group β] (f : α → β) :

add_group_topology β

Given f : α → β and a topology on α, the coinduced additive group topology on β is the finest topology such that f is continuous and β is a topological additive group.

Equations

add_group_topology.coinduced f = has_Inf.Inf {b : add_group_topology β | topological_space.coinduced f t ≤ b.to_topological_space}

source

def group_topology.coinduced {α : Type u_1} {β : Type u_2} [t : topological_space α] [group β] (f : α → β) :

group_topology β

Given f : α → β and a topology on α, the coinduced group topology on β is the finest topology such that f is continuous and β is a topological group.

Equations