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Bell Number

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The number of ways a set of πŸ‘ n
elements can be partitioned into nonempty subsets is called a Bell number and is denoted πŸ‘ B_n
(not to be confused with the Bernoulli number, which is also commonly denoted πŸ‘ B_n
).

For example, there are five ways the numbers πŸ‘ {1,2,3}
can be partitioned: πŸ‘ {{1},{2},{3}}
, πŸ‘ {{1,2},{3}}
, πŸ‘ {{1,3},{2}}
, πŸ‘ {{1},{2,3}}
, and πŸ‘ {{1,2,3}}
, so πŸ‘ B_3=5
.

πŸ‘ B_0=1
, and the first few Bell numbers for πŸ‘ n=1
, 2, ... are 1, 2, 5, 15, 52, 203, 877, 4140, 21147, 115975, ... (OEIS A000110). The numbers of digits in πŸ‘ B_(10^n)
for πŸ‘ n=0
, 1, ... are given by 1, 6, 116, 1928, 27665, ... (OEIS A113015).

Bell numbers are implemented in the Wolfram Language as [n].

Though Bell numbers have traditionally been attributed to E. T. Bell as a result of the general theory he developed in his 1934 paper (Bell 1934), the first systematic study of Bell numbers was made by Ramanujan in chapter 3 of his second notebook approximately 25-30 years prior to Bell's work (B. C. Berndt, pers. comm., Jan. 4 and 13, 2010).

The first few prime Bell numbers occur at indices πŸ‘ n=2
, 3, 7, 13, 42, 55, 2841, ... (OEIS A051130), with no others less than πŸ‘ 30447
(Weisstein, Apr. 23, 2006). These correspond to the numbers 2, 5, 877, 27644437, ... (OEIS A051131). πŸ‘ B_(2841)
was proved prime by I. Larrosa Canestro in 2004 after 17 months of computation using the elliptic curve primality proving program PRIMO.

Bell numbers are closely related to Catalan numbers. The diagram above shows the constructions giving πŸ‘ B_3=5
and πŸ‘ B_4=15
, with line segments representing elements in the same subset and dots representing subsets containing a single element (Dickau). The integers πŸ‘ B_n
can be defined by the sum

where πŸ‘ S(n,k)
is a Stirling number of the second kind, i.e., as the Stirling transform of the sequence 1, 1, 1, ....

The Bell numbers are given in terms of generalized hypergeometric functions by

(K. A. Penson, pers. comm., Jan. 14, 2007).

The Bell numbers can also be generated using the sum and recurrence relation

where πŸ‘ (a; b)
is a binomial coefficient, using the formula of Comtet (1974)

for πŸ‘ n>0
, where πŸ‘ [x]
denotes the ceiling function. DobiΕ„ski's formula gives the πŸ‘ n
th Bell number

A variation of DobiΕ„ski's formula gives

where πŸ‘ !n
is a subfactorial (Pitman 1997).

A double sum is given by

The Bell numbers are given by the generating function

and the exponential generating function

An amazing integral representation for πŸ‘ B_n
was given by CesΓ ro (1885),

(Becker and Browne 1941, Callan 2005), where πŸ‘ I[z]
denotes the imaginary part of πŸ‘ z
.

The Bell number πŸ‘ B_n
is also equal to πŸ‘ phi_n(1)
, where πŸ‘ phi_n(x)
is a Bell polynomial.

de Bruijn (1981) gave the asymptotic formula

LovΓ‘sz (1993) showed that this formula gives the asymptotic limit

where πŸ‘ lambda(n)
is given by

with πŸ‘ W(n)
the Lambert W-function (Graham et al. 1994, p. 493). Odlyzko (1995) gave

Touchard's congruence states

when πŸ‘ p
is prime. This gives as a special case for πŸ‘ k=0
the congruence

for πŸ‘ n
prime. It has been conjectured that

gives the minimum period of πŸ‘ B_n
(mod πŸ‘ p
). The sequence of Bell numbers πŸ‘ {B_1,B_2,...}
is periodic (Levine and Dalton 1962, Lunnon et al. 1979) with periods for moduli πŸ‘ m=1
, 2, ... given by 1, 3, 13, 12, 781, 39, 137257, 24, 39, 2343, 28531167061, 156, ... (OEIS A054767).

The Bell numbers also have the curious property that

(Lenard 1992), where the product is simply a superfactorial and πŸ‘ G(n)
is a Barnes G-function, the first few of which for πŸ‘ n=0
, 1, 2, ... are 1, 1, 2, 12, 288, 34560, 24883200, ... (OEIS A000178).

See also

Bell Polynomial, Bell Triangle, Complementary Bell Number, DobiΕ„ski's Formula, Integer Sequence Primes, Stirling Number of the Second Kind, Touchard's Congruence

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References

Becker, H. W. and Browne, D. E. "Problem E461 and Solution." Amer. Math. Monthly 48, 701-703, 1941.Bell, E. T. "Exponential Numbers." Amer. Math. Monthly 41, 411-419, 1934.Blasiak, P.; Penson, K. A.; and Solomon, A. I. "DobiΕ„ski-Type Relations and the Log-Normal Distribution." J. Phys. A: Math. Gen. 36, L273-278, 2003.Callan, D. "CesΓ ro's integral formula for the Bell numbers (corrected)." Oct. 3, 2005. http://www.stat.wisc.edu/~callan/papersother/cesaro/cesaro.pdf.CesΓ ro, M. E. "Sur une Γ©quation aux diffΓ©rences mΓͺlΓ©es." Nouv. Ann. Math. 4, 36-40, 1885.Comtet, L. Advanced Combinatorics: The Art of Finite and Infinite Expansions, rev. enl. ed. Dordrecht, Netherlands: Reidel, 1974.Conway, J. H. and Guy, R. K. In The Book of Numbers. New York: Springer-Verlag, pp. 91-94, 1996.de Bruijn, N. G. Asymptotic Methods in Analysis. New York: Dover, pp. 102-109, 1981.Dickau, R. M. "Bell Number Diagrams." http://mathforum.org/advanced/robertd/bell.html.Dickau, R. "Visualizing Combinatorial Enumeration." Mathematica in Educ. Res. 8, 11-18, 1999.Gardner, M. "The Tinkly Temple Bells." Ch. 2 in Fractal Music, Hypercards, and More Mathematical Recreations from Scientific American Magazine. New York: W. H. Freeman, pp. 24-38, 1992.Gould, H. W. Bell & Catalan Numbers: Research Bibliography of Two Special Number Sequences, 6th ed. Morgantown, WV: Math Monongliae, 1985.Graham, R. L.; Knuth, D. E.; and Patashnik, O. Concrete Mathematics: A Foundation for Computer Science, 2nd ed. Reading, MA: Addison-Wesley, 1994.Lenard, A. In Fractal Music, Hypercards, and More Mathematical Recreations from Scientific American Magazine. (M. Gardner). New York: W. H. Freeman, pp. 35-36, 1992.Larrosa Canestro, I. "Bell(2841) Is Prime." Feb. 13, 2004. http://groups.yahoo.com/group/primenumbers/message/14558.Levine, J. and Dalton, R. E. "Minimum Periods, Modulo πŸ‘ p
, of First Order Bell Exponential Integrals." Math. Comput. 16, 416-423, 1962.LovΓ‘sz, L. Combinatorial Problems and Exercises, 2nd ed. Amsterdam, Netherlands: North-Holland, 1993.Lunnon, W. F.; Pleasants, P. A. B.; and Stephens, N. M. "Arithmetic Properties of Bell Numbers to a Composite Modulus, I." Acta Arith. 35, 1-16, 1979.Odlyzko, A. M. "Asymptotic Enumeration Methods." In Handbook of Combinatorics, Vol. 2 (Ed. R. L. Graham, M. GrΓΆtschel, and L. LovΓ‘sz). Cambridge, MA: MIT Press, pp. 1063-1229, 1995. http://www.dtc.umn.edu/~odlyzko/doc/asymptotic.enum.pdf.Penson, K. A.; Blasiak, P.; Duchamp, G.; Horzela, A.; and Solomon, A. I. "Hierarchical DobiΕ„ski-Type Relations via Substitution and the Moment Problem." 26 Dec 2003. http://www.arxiv.org/abs/quant-ph/0312202/.Pitman, J. "Some Probabilistic Aspects of Set Partitions." Amer. Math. Monthly 104, 201-209, 1997.Rota, G.-C. "The Number of Partitions of a Set." Amer. Math. Monthly 71, 498-504, 1964.Sixdeniers, J.-M.; Penson, K. A.; and Solomon, A. I. "Extended Bell and Stirling Numbers from Hypergeometric Functions." J. Integer Sequences 4, No. 01.1.4, 2001. http://www.math.uwaterloo.ca/JIS/VOL4/SIXDENIERS/bell.html.Sloane, N. J. A. Sequences A000110/M1484, A000178/M2049, A051130, A051131, A054767, and A113015 in "The On-Line Encyclopedia of Integer Sequences."Stanley, R. P. Enumerative Combinatorics, Vol. 1. Cambridge, England: Cambridge University Press, pp. 33-34, 1999.Stanley, R. P. Enumerative Combinatorics, Vol. 2. Cambridge, England: Cambridge University Press, p. 13, 1999.Wilson, D. "Bell Number Question." mailing list. 16 Jul 2007.

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Bell Number

Cite this as:

Weisstein, Eric W. "Bell Number." From MathWorld--A Wolfram Resource. https://mathworld.wolfram.com/BellNumber.html

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