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Agnew's theorem

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Agnew's theorem, proposed by American mathematician Ralph Palmer Agnew, characterizes reorderings of terms of infinite series that preserve convergence for all series.[1]

Statement

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Let's call a permutation an Agnew permutation[a] if there exists such that any interval that starts with 1 is mapped by p to a union of at most K intervals, i.e., , where counts the number of intervals.

Agnew's theorem.   is an Agnew permutation for all converging series of real or complex terms , the series converges to the same sum.[2]

Corollary 1.   (the inverse of ) is an Agnew permutation for all diverging series of real or complex terms , the series diverges.[b]

Corollary 2.   and are Agnew permutations for all series of real or complex terms , the convergence type of the series is the same.[c][b]

Usage

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Agnew's theorem is useful when the convergence of has already been established: any Agnew permutation can be used to rearrange its terms while preserving convergence to the same sum.

The Corollary 2 is useful when the convergence type of is unknown: the convergence type of is the same as that of the original series.

Examples

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An important class of permutations is infinite compositions of permutations in which each constituent permutation acts only on its corresponding interval (with ). Since for , we only need to consider the behavior of as increases.

Bounded groups of consecutive terms

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When the sizes of all groups of consecutive terms are bounded by a constant, i.e., , and its inverse are Agnew permutations (with ), i.e., arbitrary reorderings can be applied within the groups with the convergence type preserved.

Unbounded groups of consecutive terms

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When the sizes of groups of consecutive terms grow without bounds, it is necessary to look at the behavior of .

Mirroring permutations and circular shift permutations, as well as their inverses, add at most 1 interval to the main interval , hence and its inverse are Agnew permutations (with ), i.e., mirroring and circular shifting can be applied within the groups with the convergence type preserved.

A block reordering permutation with B > 1 blocks[d] and its inverse add at most intervals (when is large) to the main interval , hence and its inverse are Agnew permutations, i.e., block reordering can be applied within the groups with the convergence type preserved.

Notes

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  1. ^ This terminology is used only in this article, to simplify the explanation.
  2. ^ a b Note that, unlike Agnew's theorem, the corollaries in this article do not specify equivalence, only implication.
  3. ^ Absolutely converging series turn into absolutely converging series, conditionally converging series turn into conditionally converging series (with the same sum), diverging series turn into diverging series.
  4. ^ The case of B = 2 is a circular shift.

References

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  1. ^ Schaefer, Paul (1981). "Sum-preserving rearrangements of infinite series" (PDF). Amer. Math. Monthly. 88 (1): 33–40.
  2. ^ Agnew, Ralph Palmer (1955). "Permutations preserving convergence of series" (PDF). Proc. Amer. Math. Soc. 6 (4): 563–564.