Completeness in terms of Cauchy
filters vs isCauSeq
sequences #
In this file we apply Metric.complete_of_cauchySeq_tendsto
to prove that a NormedRing
is complete in terms of Cauchy
filter if and only if it is complete in terms
of CauSeq
Cauchy sequences.
theorem
CauSeq.tendsto_limit
{β : Type v}
[NormedRing β]
[hn : IsAbsoluteValue norm]
(f : CauSeq β norm)
[CauSeq.IsComplete β norm]
:
Filter.Tendsto (↑f) Filter.atTop (nhds (CauSeq.lim f))
theorem
CauchySeq.isCauSeq
{β : Type v}
[NormedField β]
{f : ℕ → β}
(hf : CauchySeq f)
:
IsCauSeq norm f
In a normed field, CauSeq
coincides with the usual notion of Cauchy sequences.
instance
completeSpace_of_cauSeq_isComplete
{β : Type v}
[NormedField β]
[CauSeq.IsComplete β norm]
:
A complete normed field is complete as a metric space, as Cauchy sequences converge by assumption and this suffices to characterize completeness.
Equations
- (_ : CompleteSpace β) = (_ : CompleteSpace β)