Urysohn's lemma for bounded continuous functions #
In this file we reformulate Urysohn's lemma exists_continuous_zero_one_of_isClosed
in terms of
bounded continuous functions X →ᵇ ℝ
. These lemmas live in a separate file because
Topology.ContinuousFunction.Bounded
imports too many other files.
Tags #
Urysohn's lemma, normal topological space
theorem
exists_bounded_zero_one_of_closed
{X : Type u_1}
[TopologicalSpace X]
[NormalSpace X]
{s : Set X}
{t : Set X}
(hs : IsClosed s)
(ht : IsClosed t)
(hd : Disjoint s t)
:
Urysohn's lemma: if s
and t
are two disjoint closed sets in a normal topological
space X
, then there exists a continuous function f : X → ℝ
such that
f
equals zero ons
;f
equals one ont
;0 ≤ f x ≤ 1
for allx
.
theorem
exists_bounded_mem_Icc_of_closed_of_le
{X : Type u_1}
[TopologicalSpace X]
[NormalSpace X]
{s : Set X}
{t : Set X}
(hs : IsClosed s)
(ht : IsClosed t)
(hd : Disjoint s t)
{a : ℝ}
{b : ℝ}
(hle : a ≤ b)
:
∃ (f : BoundedContinuousFunction X ℝ),
Set.EqOn (⇑f) (Function.const X a) s ∧ Set.EqOn (⇑f) (Function.const X b) t ∧ ∀ (x : X), f x ∈ Set.Icc a b
Urysohn's lemma: if s
and t
are two disjoint closed sets in a normal topological space X
,
and a ≤ b
are two real numbers, then there exists a continuous function f : X → ℝ
such that
f
equalsa
ons
;f
equalsb
ont
;a ≤ f x ≤ b
for allx
.