Convergence of Taylor series of holomorphic functions #
We show that the Taylor series around some point c : ℂ
of a function f
that is complex
differentiable on the open ball of radius r
around c
converges to f
on that open ball;
see Complex.hasSum_taylorSeries_on_ball
and Complex.taylorSeries_eq_on_ball
for versions
(in terms of HasSum
and tsum
, repsectively) for functions to a complete normed
space over ℂ
, and Complex.taylorSeries_eq_on_ball'
for a variant when f : ℂ → ℂ
.
There are corresponding statements for EMEtric.ball
s; see
Complex.hasSum_taylorSeries_on_emetric_ball
, Complex.taylorSeries_eq_on_emetric_ball
and Complex.taylorSeries_eq_on_ball'
.
We also show that the Taylor series around some point c : ℂ
of a function f
that is complex
differentiable on all of ℂ
converges to f
on ℂ
;
see Complex.hasSum_taylorSeries_of_entire
, Complex.taylorSeries_eq_of_entire
and
Complex.taylorSeries_eq_of_entire'
.
A function that is complex differentiable on the open ball of radius r
around c
is given by evaluating its Taylor series at c
on this open ball.
A function that is complex differentiable on the open ball of radius r
around c
is given by evaluating its Taylor series at c
on this open ball.
A function that is complex differentiable on the open ball of radius r
around c
is given by evaluating its Taylor series at c
on this open ball.
A function that is complex differentiable on the open ball of radius r ≤ ∞
around c
is given by evaluating its Taylor series at c
on this open ball.
A function that is complex differentiable on the open ball of radius r ≤ ∞
around c
is given by evaluating its Taylor series at c
on this open ball.
A function that is complex differentiable on the open ball of radius r ≤ ∞
around c
is given by evaluating its Taylor series at c
on this open ball.
A function that is complex differentiable on the complex plane is given by evaluating
its Taylor series at any point c
.
A function that is complex differentiable on the complex plane is given by evaluating
its Taylor series at any point c
.