Convergence of intervals #
Motivation #
If a function tends to infinity somewhere, then its derivative is not integrable around this place. One should be careful about this statement: "somewhere" could mean a point, but also convergence from the left or from the right, or it could also be infinity, and "around this place" will refer to these directed neighborhoods. Therefore, the above theorem has many variants. Instead of stating all these variants, one can look for the common abstraction and have a single version. One has to be careful: if one considers convergence along a sequence, then the function may tend to infinity but have a derivative which is small along the sequence (with big jumps inbetween), so in the end the derivative may be integrable on a neighborhood of the sequence. What really matters for such calculus issues in terms of derivatives is that whole intervals are included in the sets we consider.
The right common abstraction is provided in this file, as the TendstoIxxClass
typeclass.
It takes as parameters a class of bounded intervals and two real filters l₁
and l₂
.
An instance TendstoIxxClass Icc l₁ l₂
registers that, if aₙ
and bₙ
are converging towards
the filter l₁
, then the intervals Icc aₙ bₙ
are eventually contained in any given set
belonging to l₂
. For instance, for l₁ = 𝓝[>] x
and l₂ = 𝓝[≥] x
, the strict and large right
neighborhoods of x
respectively, then given any large right neighborhood s ∈ 𝓝[≥] x
and any two
sequences xₙ
and yₙ
converging strictly to the right of x
,
then the interval [xₙ, yₙ]
is eventually contained in s
. Therefore, the instance
TendstoIxxClass Icc (𝓝[>] x) (𝓝[≥] x)
holds. Note that one could have taken as
well l₂ = 𝓝[>] x
, but that l₁ = 𝓝[≥] x
and l₂ = 𝓝[>] x
wouldn't work.
With this formalism, the above theorem would read: if TendstoIxxClass Icc l l
and f
tends
to infinity along l
, then its derivative is not integrable on any element of l
.
Beyond this simple example, this typeclass plays a prominent role in generic formulations of
the fundamental theorem of calculus.
Main definition #
If both a
and b
tend to some filter l₁
, sometimes this implies that Ixx a b
tends to
l₂.smallSets
, i.e., for any s ∈ l₂
eventually Ixx a b
becomes a subset of s
. Here and below
Ixx
is one of Set.Icc
, Set.Ico
, Set.Ioc
, and Set.Ioo
.
We define Filter.TendstoIxxClass Ixx l₁ l₂
to be a typeclass representing this property.
The instances provide the best l₂
for a given l₁
. In many cases l₁ = l₂
but sometimes we can
drop an endpoint from an interval: e.g., we prove
Filter.TendstoIxxClass Set.Ico (𝓟 (Set.Iic a)) (𝓟 (Set.Iio a))
, i.e., if u₁ n
and u₂ n
belong
eventually to Set.Iic a
, then the interval Set.Ico (u₁ n) (u₂ n)
is eventually included in
Set.Iio a
.
The next table shows “output” filters l₂
for different values of Ixx
and l₁
. The instances
that need topology are defined in Mathlib/Topology/Algebra/Ordered
.
| Input filter | Ixx = Set.Icc
| Ixx = Set.Ico
| Ixx = Set.Ioc
| Ixx = Set.Ioo
|
|-----------------:|:----------------:|:----------------:|:----------------:|:----------------:|
| Filter.atTop
| Filter.atTop
| Filter.atTop
| Filter.atTop
| Filter.atTop
|
| Filter.atBot
| Filter.atBot
| Filter.atBot
| Filter.atBot
| Filter.atBot
|
| pure a
| pure a
| ⊥
| ⊥
| ⊥
|
| 𝓟 (Set.Iic a)
| 𝓟 (Set.Iic a)
| 𝓟 (Set.Iio a)
| 𝓟 (Set.Iic a)
| 𝓟 (Set.Iio a)
|
| 𝓟 (Set.Ici a)
| 𝓟 (Set.Ici a)
| 𝓟 (Set.Ici a)
| 𝓟 (Set.Ioi a)
| 𝓟 (Set.Ioi a)
|
| 𝓟 (Set.Ioi a)
| 𝓟 (Set.Ioi a)
| 𝓟 (Set.Ioi a)
| 𝓟 (Set.Ioi a)
| 𝓟 (Set.Ioi a)
|
| 𝓟 (Set.Iio a)
| 𝓟 (Set.Iio a)
| 𝓟 (Set.Iio a)
| 𝓟 (Set.Iio a)
| 𝓟 (Set.Iio a)
|
| 𝓝 a
| 𝓝 a
| 𝓝 a
| 𝓝 a
| 𝓝 a
|
| 𝓝[Set.Iic a] b
| 𝓝[Set.Iic a] b
| 𝓝[Set.Iio a] b
| 𝓝[Set.Iic a] b
| 𝓝[Set.Iio a] b
|
| 𝓝[Set.Ici a] b
| 𝓝[Set.Ici a] b
| 𝓝[Set.Ici a] b
| 𝓝[Set.Ioi a] b
| 𝓝[Set.Ioi a] b
|
| 𝓝[Set.Ioi a] b
| 𝓝[Set.Ioi a] b
| 𝓝[Set.Ioi a] b
| 𝓝[Set.Ioi a] b
| 𝓝[Set.Ioi a] b
|
| 𝓝[Set.Iio a] b
| 𝓝[Set.Iio a] b
| 𝓝[Set.Iio a] b
| 𝓝[Set.Iio a] b
| 𝓝[Set.Iio a] b
|
A pair of filters l₁
, l₂
has TendstoIxxClass Ixx
property if Ixx a b
tends to
l₂.small_sets
as a
and b
tend to l₁
. In all instances Ixx
is one of Set.Icc
, Set.Ico
,
Set.Ioc
, or Set.Ioo
. The instances provide the best l₂
for a given l₁
. In many cases
l₁ = l₂
but sometimes we can drop an endpoint from an interval: e.g., we prove
TendstoIxxClass Set.Ico (𝓟 (Set.Iic a)) (𝓟 (Set.Iio a))
, i.e., if u₁ n
and u₂ n
belong
eventually to Set.Iic a
, then the interval Set.Ico (u₁ n) (u₂ n)
is eventually included in
Set.Iio a
.
We mark l₂
as an outParam
so that Lean can automatically find an appropriate l₂
based on
Ixx
and l₁
. This way, e.g., tendsto.Ico h₁ h₂
works without specifying explicitly l₂
.
- tendsto_Ixx : Filter.Tendsto (fun (p : α × α) => Ixx p.1 p.2) (l₁ ×ˢ l₁) (Filter.smallSets l₂)
Function.uncurry Ixx
tends tol₂.smallSets
alongl₁ ×ˢ l₁
. In other words, for anys ∈ l₂
there existst ∈ l₁
such thatIxx x y ⊆ s
wheneverx ∈ t
andy ∈ t
.Use lemmas like
Filter.Tendsto.Icc
instead.
Instances
Equations
- ⋯ = ⋯
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Equations
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Equations
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Equations
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Equations
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Equations
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Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯
Equations
- ⋯ = ⋯