In calculus, the Abel–Dini–Pringsheim theorem is a convergence test which constructs from a divergent series a series that diverges more slowly, and from convergent series one that converges more slowly.[1]: §IX.39 Consequently, for every convergence test based on a particular series there is a series about which the test is inconclusive.[1]: 299 For example, the Raabe test is essentially a comparison test based on the family of series whose th term is (with ) and is therefore inconclusive about the series of terms which diverges more slowly than the harmonic series.
The Abel–Dini–Pringsheim theorem can be given for divergent series or convergent series. Helpfully, these definitions are equivalent, and it suffices to prove only one case. This is because applying the Abel–Dini–Pringsheim theorem for divergent series to the series with partial sum
yields the Abel–Dini–Pringsheim theorem for convergent series.[2]
For divergent series
[edit]
Suppose that is a sequence of positive real numbers such that the series
diverges to infinity. Let denote the th partial sum. The Abel–Dini–Pringsheim theorem for divergent series states that the following conditions hold.
- For all we have
- If also , then
Consequently, the series
converges if and diverges if . When , this series diverges less rapidy than .[1]
Proof
Proof of the first part. By the assumption is nondecreasing and diverges to infinity. So, for all there is such that
Therefore
and hence is not a Cauchy sequence. This implies that the series
is divergent.
Proof of the second part. If , we have for sufficiently large and thus . So, it suffices to consider the case . For all we have the inequality
This is because, letting
we have
(Alternatively, is convex and its tangent at is )
Therefore,
Proof of the third part. The sequence is nondecreasing and diverges to infinity. By the Stolz-Cesaro theorem,
For convergent series
[edit]
Suppose that is a sequence of positive real numbers such that the series
converges to a finite number. Let denote the th remainder of the series. According to the Abel–Dini–Pringsheim theorem for convergent series, the following conditions hold.
- For all we have
- If also then
In particular, the series
is convergent when , and divergent when . When , this series converges more slowly than .[1]
The series
is divergent with the th partial sum being . By the Abel–Dini–Pringsheim theorem, the series
converges when and diverges when . Since converges to 0, we have the asymptotic approximation
Now, consider the divergent series
thus found. Apply the Abel–Dini–Pringsheim theorem but with partial sum replaced by asymptotically equivalent sequence . (It is not hard to verify that this can always be done.) Then we may conclude that the series
converges when and diverges when . Since converges to 0, we have
The theorem was proved in three parts. Niels Henrik Abel proved a weak form of the first part of the theorem (for divergent series).[3] Ulisse Dini proved the complete form and a weak form of the second part.[4] Alfred Pringsheim proved the second part of the theorem.[5] The third part is due to Ernesto Cesàro.[6]