Necklace problem

The necklace problem is a problem in recreational mathematics concerning the reconstruction of necklaces (cyclic arrangements of binary values) from partial information.

Formulation[edit]

The necklace problem involves the reconstruction of a necklace of ${\displaystyle n}$ beads, each of which is either black or white, from partial information. The information specifies how many copies the necklace contains of each possible arrangement of ${\displaystyle k}$ black beads. For instance, for ${\displaystyle k=2}$, the specified information gives the number of pairs of black beads that are separated by ${\displaystyle i}$ positions, for ${\displaystyle i=0,\dots ,\lfloor n/2-1\rfloor }$. This can be made formal by defining a ${\displaystyle k}$-configuration to be a necklace of ${\displaystyle k}$ black beads and ${\displaystyle n-k}$ white beads, and counting the number of ways of rotating a ${\displaystyle k}$-configuration so that each of its black beads coincides with one of the black beads of the given necklace.

The necklace problem asks: if ${\displaystyle n}$ is given, and the numbers of copies of each ${\displaystyle k}$-configuration are known up to some threshold ${\displaystyle k\leq K}$, how large does the threshold ${\displaystyle K}$ need to be before this information completely determines the necklace that it describes? Equivalently, if the information about ${\displaystyle k}$-configurations is provided in stages, where the ${\displaystyle k}$th stage provides the numbers of copies of each ${\displaystyle k}$-configuration, how many stages are needed (in the worst case) in order to reconstruct the precise pattern of black and white beads in the original necklace?

Upper bounds[edit]

Alon, Caro, Krasikov and Roditty showed that 1 + log₂(n) is sufficient, using a cleverly enhanced inclusion–exclusion principle.

Radcliffe and Scott showed that if n is prime, 3 is sufficient, and for any n, 9 times the number of prime factors of n is sufficient.

Pebody showed that for any n, 6 is sufficient and, in a followup paper, that for odd n, 4 is sufficient. He conjectured that 4 is again sufficient for even n greater than 10, but this remains unproven.

See also[edit]

• Necklace (combinatorics)
• Bracelet (combinatorics)
• Moreau's necklace-counting function
• Necklace splitting problem

References[edit]

• Alon, N.; Caro, Y.; Krasikov, I.; Roditty, Y. (1989). "Combinatorial reconstruction problems". J. Combin. Theory Ser. B. 47 (2): 153–161. CiteSeerX 10.1.1.300.9350. doi:10.1016/0095-8956(89)90016-6.
• Radcliffe, A. J.; Scott, A. D. (1998). "Reconstructing subsets of Z_n". J. Combin. Theory Ser. A. 83 (2): 169–187. doi:10.1006/jcta.1998.2870.
• Pebody, Luke (2004). "The reconstructibility of finite abelian groups". Combin. Probab. Comput. 13 (6): 867–892. doi:10.1017/S0963548303005807. S2CID 37756823.
• Pebody, Luke (2007). "Reconstructing Odd Necklaces". Combin. Probab. Comput. 16 (4): 503–514. doi:10.1017/S0963548306007875. S2CID 13278945.
• Paul K. Stockmeyer (1974). "The charm bracelet problem and its applications". In Bari, Ruth A.; Harary, Frank (eds.). Graphs and Combinatorics: Proceedings of the Capital Conference on Graph Theory and Combinatorics at the George Washington University, June 18–22, 1973. Lecture Notes in Mathematics. Vol. 406. pp. 339–349. doi:10.1007/BFb0066456. ISBN 978-3-540-06854-9.