Documentation

Mathlib.Analysis.Normed.Ring.Units

The group of units of a complete normed ring #

This file contains the basic theory for the group of units (invertible elements) of a complete normed ring (Banach algebras being a notable special case).

Main results #

The constructions Units.add and Units.ofNearby (based on Units.oneSub defined elsewhere) state, in varying forms, that perturbations of a unit are units. They are not stated in their optimal form; more precise versions would use the spectral radius.

The first main result is Units.isOpen: the group of units of a normed ring with summable geometric series is an open subset of the ring.

The function Ring.inverse (defined elsewhere), for a ring R, sends a : R to a⁻¹ if a is a unit and 0 if not. The other major results of this file (notably NormedRing.inverse_add, NormedRing.inverse_add_norm and NormedRing.inverse_add_norm_diff_nth_order) cover the asymptotic properties of Ring.inverse (x + t) as t → 0.

@[simp]
theorem Units.val_add {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] (x : Rˣ) (t : R) (h : t < x⁻¹⁻¹) :
(x.add t h) = x + t
def Units.add {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] (x : Rˣ) (t : R) (h : t < x⁻¹⁻¹) :

In a normed ring with summable geometric series, a perturbation of a unit x by an element t of distance less than ‖x⁻¹‖⁻¹ from x is a unit. Here we construct its Units structure.

Equations
Instances For
    @[simp]
    theorem Units.val_ofNearby {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] (x : Rˣ) (y : R) (h : y - x < x⁻¹⁻¹) :
    (x.ofNearby y h) = y
    def Units.ofNearby {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] (x : Rˣ) (y : R) (h : y - x < x⁻¹⁻¹) :

    In a normed ring with summable geometric series, an element y of distance less than ‖x⁻¹‖⁻¹ from x is a unit. Here we construct its Units structure.

    Equations
    • x.ofNearby y h = (x.add (y - x) h).copy y (x.add (y - x) h)⁻¹
    Instances For
      theorem Units.isOpen {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] :
      IsOpen {x : R | IsUnit x}

      The group of units of a normed ring with summable geometric series is an open subset of the ring.

      theorem Units.nhds {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] (x : Rˣ) :
      {x : R | IsUnit x} nhds x

      The nonunits in a normed ring with summable geometric series are contained in the complement of the ball of radius 1 centered at 1 : R.

      theorem NormedRing.inverse_add {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] (x : Rˣ) :
      ∀ᶠ (t : R) in nhds 0, Ring.inverse (x + t) = Ring.inverse (1 + x⁻¹ * t) * x⁻¹

      The formula Ring.inverse (x + t) = Ring.inverse (1 + x⁻¹ * t) * x⁻¹ holds for t sufficiently small.

      theorem NormedRing.inverse_one_sub_nth_order' {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] (n : ) {t : R} (ht : t < 1) :
      Ring.inverse (1 - t) = iFinset.range n, t ^ i + t ^ n * Ring.inverse (1 - t)
      theorem NormedRing.inverse_one_sub_nth_order {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] (n : ) :
      ∀ᶠ (t : R) in nhds 0, Ring.inverse (1 - t) = iFinset.range n, t ^ i + t ^ n * Ring.inverse (1 - t)
      theorem NormedRing.inverse_add_nth_order {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] (x : Rˣ) (n : ) :
      ∀ᶠ (t : R) in nhds 0, Ring.inverse (x + t) = (∑ iFinset.range n, (-x⁻¹ * t) ^ i) * x⁻¹ + (-x⁻¹ * t) ^ n * Ring.inverse (x + t)

      The formula Ring.inverse (x + t) = (∑ i ∈ Finset.range n, (- x⁻¹ * t) ^ i) * x⁻¹ + (- x⁻¹ * t) ^ n * Ring.inverse (x + t) holds for t sufficiently small.

      theorem NormedRing.inverse_one_sub_norm {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] :
      (fun (t : R) => Ring.inverse (1 - t)) =O[nhds 0] fun (_t : R) => 1
      theorem NormedRing.inverse_add_norm {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] (x : Rˣ) :
      (fun (t : R) => Ring.inverse (x + t)) =O[nhds 0] fun (_t : R) => 1

      The function fun t ↦ inverse (x + t) is O(1) as t → 0.

      theorem NormedRing.inverse_add_norm_diff_nth_order {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] (x : Rˣ) (n : ) :
      (fun (t : R) => Ring.inverse (x + t) - (∑ iFinset.range n, (-x⁻¹ * t) ^ i) * x⁻¹) =O[nhds 0] fun (t : R) => t ^ n

      The function fun t ↦ Ring.inverse (x + t) - (∑ i ∈ Finset.range n, (- x⁻¹ * t) ^ i) * x⁻¹ is O(t ^ n) as t → 0.

      theorem NormedRing.inverse_add_norm_diff_first_order {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] (x : Rˣ) :
      (fun (t : R) => Ring.inverse (x + t) - x⁻¹) =O[nhds 0] fun (t : R) => t

      The function fun t ↦ Ring.inverse (x + t) - x⁻¹ is O(t) as t → 0.

      theorem NormedRing.inverse_add_norm_diff_second_order {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] (x : Rˣ) :
      (fun (t : R) => Ring.inverse (x + t) - x⁻¹ + x⁻¹ * t * x⁻¹) =O[nhds 0] fun (t : R) => t ^ 2

      The function fun t ↦ Ring.inverse (x + t) - x⁻¹ + x⁻¹ * t * x⁻¹ is O(t ^ 2) as t → 0.

      theorem NormedRing.inverse_continuousAt {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] (x : Rˣ) :
      ContinuousAt Ring.inverse x

      The function Ring.inverse is continuous at each unit of R.

      In a normed ring with summable geometric series, the coercion from (equipped with the induced topology from the embedding in R × R) to R is an open embedding.

      @[deprecated Units.isOpenEmbedding_val]

      Alias of Units.isOpenEmbedding_val.


      In a normed ring with summable geometric series, the coercion from (equipped with the induced topology from the embedding in R × R) to R is an open embedding.

      In a normed ring with summable geometric series, the coercion from (equipped with the induced topology from the embedding in R × R) to R is an open map.

      theorem Ideal.eq_top_of_norm_lt_one {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] (I : Ideal R) {x : R} (hxI : x I) (hx : 1 - x < 1) :
      I =

      An ideal which contains an element within 1 of 1 : R is the unit ideal.

      theorem Ideal.closure_ne_top {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] (I : Ideal R) (hI : I ) :
      I.closure

      The Ideal.closure of a proper ideal in a normed ring with summable geometric series is proper.

      theorem Ideal.IsMaximal.closure_eq {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] {I : Ideal R} (hI : I.IsMaximal) :
      I.closure = I

      The Ideal.closure of a maximal ideal in a normed ring with summable geometric series is the ideal itself.

      instance Ideal.IsMaximal.isClosed {R : Type u_1} [NormedRing R] [HasSummableGeomSeries R] {I : Ideal R} [hI : I.IsMaximal] :

      Maximal ideals in normed rings with summable geometric series are closed.

      Equations
      • =