Measure-theoretic results about the additive circle #
The file is a place to collect measure-theoretic results about the additive circle.
Main definitions: #
AddCircle.closedBall_ae_eq_ball
: open and closed balls in the additive circle are almost equalAddCircle.isAddFundamentalDomain_of_ae_ball
: a ball is a fundamental domain for rational angle rotation in the additive circle
theorem
AddCircle.closedBall_ae_eq_ball
{T : ℝ}
[hT : Fact (0 < T)]
{x : AddCircle T}
{ε : ℝ}
:
Metric.closedBall x ε =ᶠ[MeasureTheory.Measure.ae MeasureTheory.volume] Metric.ball x ε
theorem
AddCircle.isAddFundamentalDomain_of_ae_ball
{T : ℝ}
[hT : Fact (0 < T)]
(I : Set (AddCircle T))
(u : AddCircle T)
(x : AddCircle T)
(hu : IsOfFinAddOrder u)
(hI : I =ᶠ[MeasureTheory.Measure.ae MeasureTheory.volume] Metric.ball x (T / (2 * ↑(addOrderOf u))))
:
Let G
be the subgroup of AddCircle T
generated by a point u
of finite order n : ℕ
. Then
any set I
that is almost equal to a ball of radius T / 2n
is a fundamental domain for the action
of G
on AddCircle T
by left addition.
theorem
AddCircle.volume_of_add_preimage_eq
{T : ℝ}
[hT : Fact (0 < T)]
(s : Set (AddCircle T))
(I : Set (AddCircle T))
(u : AddCircle T)
(x : AddCircle T)
(hu : IsOfFinAddOrder u)
(hs : u +ᵥ s =ᶠ[MeasureTheory.Measure.ae MeasureTheory.volume] s)
(hI : I =ᶠ[MeasureTheory.Measure.ae MeasureTheory.volume] Metric.ball x (T / (2 * ↑(addOrderOf u))))
:
↑↑MeasureTheory.volume s = addOrderOf u • ↑↑MeasureTheory.volume (s ∩ I)