Locally integrable functions #
A function is called locally integrable (MeasureTheory.LocallyIntegrable
) if it is integrable
on a neighborhood of every point. More generally, it is locally integrable on s
if it is
locally integrable on a neighbourhood within s
of any point of s
.
This file contains properties of locally integrable functions, and integrability results on compact sets.
Main statements #
Continuous.locallyIntegrable
: A continuous function is locally integrable.ContinuousOn.locallyIntegrableOn
: A function which is continuous ons
is locally integrable ons
.
A function f : X → E
is locally integrable on s, for s ⊆ X
, if for every x ∈ s
there is
a neighbourhood of x
within s
on which f
is integrable. (Note this is, in general, strictly
weaker than local integrability with respect to μ.restrict s
.)
Equations
- MeasureTheory.LocallyIntegrableOn f s μ = ∀ x ∈ s, MeasureTheory.IntegrableAtFilter f (nhdsWithin x s) μ
Instances For
If a function is locally integrable on a compact set, then it is integrable on that set.
If a function f
is locally integrable on a set s
in a second countable topological space,
then there exist countably many open sets u
covering s
such that f
is integrable on each
set u ∩ s
.
If a function f
is locally integrable on a set s
in a second countable topological space,
then there exists a sequence of open sets u n
covering s
such that f
is integrable on each
set u n ∩ s
.
If s
is either open, or closed, then f
is locally integrable on s
iff it is integrable on
every compact subset contained in s
.
A function f : X → E
is locally integrable if it is integrable on a neighborhood of every
point. In particular, it is integrable on all compact sets,
see LocallyIntegrable.integrableOn_isCompact
.
Equations
- MeasureTheory.LocallyIntegrable f μ = ∀ (x : X), MeasureTheory.IntegrableAtFilter f (nhds x) μ
Instances For
If f
is locally integrable with respect to μ.restrict s
, it is locally integrable on s
.
(See locallyIntegrableOn_iff_locallyIntegrable_restrict
for an iff statement when s
is
closed.)
If s
is closed, being locally integrable on s
wrt μ
is equivalent to being locally
integrable with respect to μ.restrict s
. For the one-way implication without assuming s
closed,
see locallyIntegrableOn_of_locallyIntegrable_restrict
.
If a function is locally integrable, then it is integrable on any compact set.
If a function is locally integrable, then it is integrable on an open neighborhood of any compact set.
If a function is locally integrable in a second countable topological space, then there exists a sequence of open sets covering the space on which it is integrable.
If f
is locally integrable and g
is continuous with compact support,
then g • f
is integrable.
If f
is locally integrable and g
is continuous with compact support,
then f • g
is integrable.
A continuous function f
is locally integrable with respect to any locally finite measure.
A function f
continuous on a set K
is locally integrable on this set with respect
to any locally finite measure.
A function f
continuous on a compact set K
is integrable on this set with respect to any
locally finite measure.
A continuous function with compact support is integrable on the whole space.