Schwarz lemma #
In this file we prove several versions of the Schwarz lemma.
-
Complex.norm_deriv_le_div_of_mapsTo_ball
,Complex.abs_deriv_le_div_of_mapsTo_ball
: iff : ℂ → E
sends an open disk with centerc
and a positive radiusR₁
to an open ball with centerf c
and radiusR₂
, then the absolute value of the derivative off
atc
is at most the ratioR₂ / R₁
; -
Complex.dist_le_div_mul_dist_of_mapsTo_ball
: iff : ℂ → E
sends an open disk with centerc
and radiusR₁
to an open disk with centerf c
and radiusR₂
, then for anyz
in the former disk we havedist (f z) (f c) ≤ (R₂ / R₁) * dist z c
; -
Complex.abs_deriv_le_one_of_mapsTo_ball
: iff : ℂ → ℂ
sends an open disk of positive radius to itself and the center of this disk to itself, then the absolute value of the derivative off
at the center of this disk is at most1
; -
Complex.dist_le_dist_of_mapsTo_ball_self
: iff : ℂ → ℂ
sends an open disk to itself and the centerc
of this disk to itself, then for any pointz
of this disk we havedist (f z) c ≤ dist z c
; -
Complex.abs_le_abs_of_mapsTo_ball_self
: iff : ℂ → ℂ
sends an open disk with center0
to itself, then for any pointz
of this disk we haveabs (f z) ≤ abs z
.
Implementation notes #
We prove some versions of the Schwarz lemma for a map f : ℂ → E
taking values in any normed space
over complex numbers.
TODO #
-
Prove that these inequalities are strict unless
f
is an affine map. -
Prove that any diffeomorphism of the unit disk to itself is a Möbius map.
Tags #
Schwarz lemma
An auxiliary lemma for Complex.norm_dslope_le_div_of_mapsTo_ball
.
Two cases of the Schwarz Lemma (derivative and distance), merged together.
Equality case in the Schwarz Lemma: in the setup of norm_dslope_le_div_of_mapsTo_ball
, if
‖dslope f c z₀‖ = R₂ / R₁
holds at a point in the ball then the map f
is affine.
The Schwarz Lemma: if f : ℂ → E
sends an open disk with center c
and a positive radius
R₁
to an open ball with center f c
and radius R₂
, then the absolute value of the derivative of
f
at c
is at most the ratio R₂ / R₁
.
The Schwarz Lemma: if f : ℂ → E
sends an open disk with center c
and radius R₁
to an
open ball with center f c
and radius R₂
, then for any z
in the former disk we have
dist (f z) (f c) ≤ (R₂ / R₁) * dist z c
.
The Schwarz Lemma: if f : ℂ → ℂ
sends an open disk with center c
and a positive radius
R₁
to an open disk with center f c
and radius R₂
, then the absolute value of the derivative of
f
at c
is at most the ratio R₂ / R₁
.
The Schwarz Lemma: if f : ℂ → ℂ
sends an open disk of positive radius to itself and the
center of this disk to itself, then the absolute value of the derivative of f
at the center of
this disk is at most 1
.
The Schwarz Lemma: if f : ℂ → ℂ
sends an open disk to itself and the center c
of this
disk to itself, then for any point z
of this disk we have dist (f z) c ≤ dist z c
.
The Schwarz Lemma: if f : ℂ → ℂ
sends an open disk with center 0
to itself, then for any
point z
of this disk we have abs (f z) ≤ abs z
.