In mathematics, the Davenport constant D(G) is an invariant of a group studied in additive combinatorics, quantifying the size of nonunique factorizations. Given a finite abelian group G, D(G) is defined as the smallest number such that every sequence of elements of that length contains a non-empty subsequence adding up to 0. In symbols, this is[1]

Example

  • The Davenport constant for the cyclic group is n. To see this, note that the sequence of a fixed generator, repeated n 1 times, contains no subsequence with sum 0. Thus D(G) ≥ n. On the other hand, if is an arbitrary sequence, then two of the sums in the sequence are equal. The difference of these two sums also gives a subsequence with sum 0.[2]

Properties

The lower bound is proved by noting that the sequence "d11 copies of (1, 0, ..., 0), d2 1 copies of (0, 1, ..., 0), etc." contains no subsequence with sum 0.[3]
  • D = M for p-groups or for r =1,2.
  • D = M for certain groups including all groups of the form C2C2nC2nm and C3C3nC3nm.
  • There are infinitely many examples with r at least 4 where D does not equal M; it is not known whether there are any with r = 3.[3]
  • Let be the exponent of G. Then[4]

Applications

The original motivation for studying Davenport's constant was the problem of non-unique factorization in number fields. Let be the ring of integers in a number field, G its class group. Then every element , which factors into at least D(G) non-trivial ideals, is properly divisible by an element of . This observation implies that Davenport's constant determines by how much the lengths of different factorization of some element in can differ.[5]

The upper bound mentioned above plays an important role in Ahlford, Granville and Pomerance's proof of the existence of infinitely many Carmichael numbers.[4]

Variants

Olson's constant O(G) uses the same definition, but requires the elements of to be distinct.[6]

  • Balandraud proved that O(Cp) equals the smallest k such that .
  • For p > 6000 we have
.
On the other hand, if G = Cr
p
with rp, then Olson's constant equals the Davenport constant.[7]

References

  1. Geroldinger, Alfred (2009). "Additive group theory and non-unique factorizations". In Geroldinger, Alfred; Ruzsa, Imre Z. (eds.). Combinatorial number theory and additive group theory. Advanced Courses in Mathematics CRM Barcelona. Elsholtz, C.; Freiman, G.; Hamidoune, Y. O.; Hegyvári, N.; Károlyi, G.; Nathanson, M.; Sólymosi, J.; Stanchescu, Y. With a foreword by Javier Cilleruelo, Marc Noy and Oriol Serra (Coordinators of the DocCourse). Basel: Birkhäuser. pp. 1–86. doi:10.1007/978-3-7643-8962-8. ISBN 978-3-7643-8961-1. Zbl 1221.20045.
  2. Geroldinger 2009, p. 24.
  3. 1 2 Bhowmik, Gautami; Schlage-Puchta, Jan-Christoph (2007). "Davenport's constant for groups of the form 333d" (PDF). In Granville, Andrew; Nathanson, Melvyn B.; Solymosi, József (eds.). Additive combinatorics. CRM Proceedings and Lecture Notes. Vol. 43. Providence, RI: American Mathematical Society. pp. 307–326. ISBN 978-0-8218-4351-2. Zbl 1173.11012.
  4. 1 2 W. R. Alford; Andrew Granville; Carl Pomerance (1994). "There are Infinitely Many Carmichael Numbers" (PDF). Annals of Mathematics. 139 (3): 703–722. doi:10.2307/2118576. JSTOR 2118576.
  5. Olson, John E. (1969-01-01). "A combinatorial problem on finite Abelian groups, I". Journal of Number Theory. 1 (1): 8–10. Bibcode:1969JNT.....1....8O. doi:10.1016/0022-314X(69)90021-3. ISSN 0022-314X.
  6. Nguyen, Hoi H.; Vu, Van H. (2012-01-01). "A characterization of incomplete sequences in vector spaces". Journal of Combinatorial Theory, Series A. 119 (1): 33–41. arXiv:1112.0754. doi:10.1016/j.jcta.2011.06.012. ISSN 0097-3165.
  7. Ordaz, Oscar; Philipp, Andreas; Santos, Irene; Schmidt, Wolfgang A. (2011). "On the Olson and the Strong Davenport constants" (PDF). Journal de Théorie des Nombres de Bordeaux. 23 (3): 715–750. doi:10.5802/jtnb.784. S2CID 36303975 via NUMDAM.
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