Uniform convergence #
A sequence of functions Fₙ
(with values in a metric space) converges uniformly on a set s
to a
function f
if, for all ε > 0
, for all large enough n
, one has for all y ∈ s
the inequality
dist (f y, Fₙ y) < ε
. Under uniform convergence, many properties of the Fₙ
pass to the limit,
most notably continuity. We prove this in the file, defining the notion of uniform convergence
in the more general setting of uniform spaces, and with respect to an arbitrary indexing set
endowed with a filter (instead of just ℕ
with atTop
).
Main results #
Let α
be a topological space, β
a uniform space, Fₙ
and f
be functions from α
to β
(where the index n
belongs to an indexing type ι
endowed with a filter p
).
TendstoUniformlyOn F f p s
: the fact thatFₙ
converges uniformly tof
ons
. This means that, for any entourageu
of the diagonal, for large enoughn
(with respect top
), one has(f y, Fₙ y) ∈ u
for ally ∈ s
.TendstoUniformly F f p
: same notion withs = univ
.TendstoUniformlyOn.continuousOn
: a uniform limit on a set of functions which are continuous on this set is itself continuous on this set.TendstoUniformly.continuous
: a uniform limit of continuous functions is continuous.TendstoUniformlyOn.tendsto_comp
: IfFₙ
tends uniformly tof
on a sets
, andgₙ
tends tox
withins
, thenFₙ gₙ
tends tof x
iff
is continuous atx
withins
.TendstoUniformly.tendsto_comp
: IfFₙ
tends uniformly tof
, andgₙ
tends tox
, thenFₙ gₙ
tends tof x
.
We also define notions where the convergence is locally uniform, called
TendstoLocallyUniformlyOn F f p s
and TendstoLocallyUniformly F f p
. The previous theorems
all have corresponding versions under locally uniform convergence.
Finally, we introduce the notion of a uniform Cauchy sequence, which is to uniform convergence what a Cauchy sequence is to the usual notion of convergence.
Implementation notes #
We derive most of our initial results from an auxiliary definition TendstoUniformlyOnFilter
.
This definition in and of itself can sometimes be useful, e.g., when studying the local behavior
of the Fₙ
near a point, which would typically look like TendstoUniformlyOnFilter F f p (𝓝 x)
.
Still, while this may be the "correct" definition (see
tendstoUniformlyOn_iff_tendstoUniformlyOnFilter
), it is somewhat unwieldy to work with in
practice. Thus, we provide the more traditional definition in TendstoUniformlyOn
.
Most results hold under weaker assumptions of locally uniform approximation. In a first section, we prove the results under these weaker assumptions. Then, we derive the results on uniform convergence from them.
Tags #
Uniform limit, uniform convergence, tends uniformly to
Different notions of uniform convergence #
We define uniform convergence and locally uniform convergence, on a set or in the whole space.
A sequence of functions Fₙ
converges uniformly on a filter p'
to a limiting function f
with respect to the filter p
if, for any entourage of the diagonal u
, one has
p ×ˢ p'
-eventually (f x, Fₙ x) ∈ u
.
Equations
- TendstoUniformlyOnFilter F f p p' = ∀ u ∈ uniformity β, ∀ᶠ (n : ι × α) in p ×ˢ p', (f n.2, F n.1 n.2) ∈ u
Instances For
A sequence of functions Fₙ
converges uniformly on a filter p'
to a limiting function f
w.r.t.
filter p
iff the function (n, x) ↦ (f x, Fₙ x)
converges along p ×ˢ p'
to the uniformity.
In other words: one knows nothing about the behavior of x
in this limit besides it being in p'
.
A sequence of functions Fₙ
converges uniformly on a set s
to a limiting function f
with
respect to the filter p
if, for any entourage of the diagonal u
, one has p
-eventually
(f x, Fₙ x) ∈ u
for all x ∈ s
.
Equations
- TendstoUniformlyOn F f p s = ∀ u ∈ uniformity β, ∀ᶠ (n : ι) in p, ∀ x ∈ s, (f x, F n x) ∈ u
Instances For
Alias of the forward direction of tendstoUniformlyOn_iff_tendstoUniformlyOnFilter
.
Alias of the reverse direction of tendstoUniformlyOn_iff_tendstoUniformlyOnFilter
.
A sequence of functions Fₙ
converges uniformly on a set s
to a limiting function f
w.r.t.
filter p
iff the function (n, x) ↦ (f x, Fₙ x)
converges along p ×ˢ 𝓟 s
to the uniformity.
In other words: one knows nothing about the behavior of x
in this limit besides it being in s
.
A sequence of functions Fₙ
converges uniformly to a limiting function f
with respect to a
filter p
if, for any entourage of the diagonal u
, one has p
-eventually
(f x, Fₙ x) ∈ u
for all x
.
Equations
- TendstoUniformly F f p = ∀ u ∈ uniformity β, ∀ᶠ (n : ι) in p, ∀ (x : α), (f x, F n x) ∈ u
Instances For
A sequence of functions Fₙ
converges uniformly to a limiting function f
w.r.t.
filter p
iff the function (n, x) ↦ (f x, Fₙ x)
converges along p ×ˢ ⊤
to the uniformity.
In other words: one knows nothing about the behavior of x
in this limit.
Uniform converence implies pointwise convergence.
Uniform converence implies pointwise convergence.
Uniform converence implies pointwise convergence.
Composing on the right by a function preserves uniform convergence on a filter
Composing on the right by a function preserves uniform convergence on a set
Composing on the right by a function preserves uniform convergence
Composing on the left by a uniformly continuous function preserves uniform convergence on a filter
Composing on the left by a uniformly continuous function preserves uniform convergence on a set
Composing on the left by a uniformly continuous function preserves uniform convergence
Uniform convergence on a filter p'
to a constant function is equivalent to convergence in
p ×ˢ p'
.
Uniform convergence on a set s
to a constant function is equivalent to convergence in
p ×ˢ 𝓟 s
.
Uniform convergence to a constant function is equivalent to convergence in p ×ˢ ⊤
.
Uniform convergence on the empty set is vacuously true
Uniform convergence on a singleton is equivalent to regular convergence
If a sequence g
converges to some b
, then the sequence of constant functions
fun n ↦ fun a ↦ g n
converges to the constant function fun a ↦ b
on any set s
If a sequence g
converges to some b
, then the sequence of constant functions
fun n ↦ fun a ↦ g n
converges to the constant function fun a ↦ b
on any set s
A sequence is uniformly Cauchy if eventually all of its pairwise differences are uniformly bounded
Equations
- UniformCauchySeqOnFilter F p p' = ∀ u ∈ uniformity β, ∀ᶠ (m : (ι × ι) × α) in (p ×ˢ p) ×ˢ p', (F m.1.1 m.2, F m.1.2 m.2) ∈ u
Instances For
A sequence is uniformly Cauchy if eventually all of its pairwise differences are uniformly bounded
Equations
- UniformCauchySeqOn F p s = ∀ u ∈ uniformity β, ∀ᶠ (m : ι × ι) in p ×ˢ p, ∀ x ∈ s, (F m.1 x, F m.2 x) ∈ u
Instances For
A sequence that converges uniformly is also uniformly Cauchy
A sequence that converges uniformly is also uniformly Cauchy
A uniformly Cauchy sequence converges uniformly to its limit
A uniformly Cauchy sequence converges uniformly to its limit
Composing on the right by a function preserves uniform Cauchy sequences
Composing on the right by a function preserves uniform Cauchy sequences
Composing on the left by a uniformly continuous function preserves uniform Cauchy sequences
If a sequence of functions is uniformly Cauchy on a set, then the values at each point form a Cauchy sequence.
A sequence of functions Fₙ
converges locally uniformly on a set s
to a limiting function
f
with respect to a filter p
if, for any entourage of the diagonal u
, for any x ∈ s
, one
has p
-eventually (f y, Fₙ y) ∈ u
for all y
in a neighborhood of x
in s
.
Equations
- TendstoLocallyUniformlyOn F f p s = ∀ u ∈ uniformity β, ∀ x ∈ s, ∃ t ∈ nhdsWithin x s, ∀ᶠ (n : ι) in p, ∀ y ∈ t, (f y, F n y) ∈ u
Instances For
A sequence of functions Fₙ
converges locally uniformly to a limiting function f
with respect
to a filter p
if, for any entourage of the diagonal u
, for any x
, one has p
-eventually
(f y, Fₙ y) ∈ u
for all y
in a neighborhood of x
.
Equations
- TendstoLocallyUniformly F f p = ∀ u ∈ uniformity β, ∀ (x : α), ∃ t ∈ nhds x, ∀ᶠ (n : ι) in p, ∀ y ∈ t, (f y, F n y) ∈ u
Instances For
On a compact space, locally uniform convergence is just uniform convergence.
For a compact set s
, locally uniform convergence on s
is just uniform convergence on s
.
Uniform approximation #
In this section, we give lemmas ensuring that a function is continuous if it can be approximated
uniformly by continuous functions. We give various versions, within a set or the whole space, at
a single point or at all points, with locally uniform approximation or uniform approximation. All
the statements are derived from a statement about locally uniform approximation within a set at
a point, called continuousWithinAt_of_locally_uniform_approx_of_continuousWithinAt
.
A function which can be locally uniformly approximated by functions which are continuous within a set at a point is continuous within this set at this point.
A function which can be locally uniformly approximated by functions which are continuous at a point is continuous at this point.
A function which can be locally uniformly approximated by functions which are continuous on a set is continuous on this set.
A function which can be uniformly approximated by functions which are continuous on a set is continuous on this set.
A function which can be locally uniformly approximated by continuous functions is continuous.
A function which can be uniformly approximated by continuous functions is continuous.
Uniform limits #
From the previous statements on uniform approximation, we deduce continuity results for uniform limits.
A locally uniform limit on a set of functions which are continuous on this set is itself continuous on this set.
A uniform limit on a set of functions which are continuous on this set is itself continuous on this set.
A locally uniform limit of continuous functions is continuous.
A uniform limit of continuous functions is continuous.
Composing limits under uniform convergence #
In general, if Fₙ
converges pointwise to a function f
, and gₙ
tends to x
, it is not true
that Fₙ gₙ
tends to f x
. It is true however if the convergence of Fₙ
to f
is uniform. In
this paragraph, we prove variations around this statement.
If Fₙ
converges locally uniformly on a neighborhood of x
within a set s
to a function f
which is continuous at x
within s
, and gₙ
tends to x
within s
, then Fₙ (gₙ)
tends
to f x
.
If Fₙ
converges locally uniformly on a neighborhood of x
to a function f
which is
continuous at x
, and gₙ
tends to x
, then Fₙ (gₙ)
tends to f x
.
If Fₙ
tends locally uniformly to f
on a set s
, and gₙ
tends to x
within s
, then
Fₙ gₙ
tends to f x
if f
is continuous at x
within s
and x ∈ s
.
If Fₙ
tends uniformly to f
on a set s
, and gₙ
tends to x
within s
, then Fₙ gₙ
tends to f x
if f
is continuous at x
within s
.
If Fₙ
tends locally uniformly to f
, and gₙ
tends to x
, then Fₙ gₙ
tends to f x
.
If Fₙ
tends uniformly to f
, and gₙ
tends to x
, then Fₙ gₙ
tends to f x
.