Extending differentiability to the boundary #
We investigate how differentiable functions inside a set extend to differentiable functions
on the boundary. For this, it suffices that the function and its derivative admit limits there.
A general version of this statement is given in has_fderiv_at_boundary_of_tendsto_fderiv
.
One-dimensional versions, in which one wants to obtain differentiability at the left endpoint or
the right endpoint of an interval, are given in
has_deriv_at_interval_left_endpoint_of_tendsto_deriv
and
has_deriv_at_interval_right_endpoint_of_tendsto_deriv
. These versions are formulated in terms
of the one-dimensional derivative deriv ℝ f
.
If a function f
is differentiable in a convex open set and continuous on its closure, and its
derivative converges to a limit f'
at a point on the boundary, then f
is differentiable there
with derivative f'
.
If a function is differentiable on the right of a point a : ℝ
, continuous at a
, and
its derivative also converges at a
, then f
is differentiable on the right at a
.
If a function is differentiable on the left of a point a : ℝ
, continuous at a
, and
its derivative also converges at a
, then f
is differentiable on the left at a
.
If a real function f
has a derivative g
everywhere but at a point, and f
and g
are
continuous at this point, then g
is also the derivative of f
at this point.
If a real function f
has a derivative g
everywhere but at a point, and f
and g
are
continuous at this point, then g
is the derivative of f
everywhere.