Bell number should not be confused with Pell number.
In combinatorial mathematics, the Bell numbers count the possible partitions of a set. These numbers have been studied by mathematicians since the 19th century, and their roots go back to medieval Japan. In an example of Stigler's law of eponymy, they are named after Eric Temple Bell, who wrote about them in the 1930s.
The Bell numbers are denoted
Bn
n
B0=B1=1
1,1,2,5,15,52,203,877,4140,...
Bn
n
Bn
n
As well as appearing in counting problems, these numbers have a different interpretation, as moments of probability distributions. In particular,
Bn
n
See main article: article and Partition of a set. In general,
Bn
n
S
S
S
B3=5
\{a,b,c\}
\{\{a\},\{b\},\{c\}\},
\{\{a\},\{b,c\}\},
\{\{b\},\{a,c\}\},
\{\{c\},\{a,b\}\},
\{\{a,b,c\}\}.
As suggested by the set notation above, the ordering of subsets within the family is not considered; ordered partitions are counted by a different sequence of numbers, the ordered Bell numbers.
B0
The partitions of a set correspond one-to-one with its equivalence relations. These are binary relations that are reflexive, symmetric, and transitive. The equivalence relation corresponding to a partition defines two elements as being equivalent when they belong to the same partition subset as each other. Conversely, every equivalence relation corresponds to a partition into equivalence classes.[1] Therefore, the Bell numbers also count the equivalence relations.
If a number
N
n
Bn
N
N
B3
30=2 x 15=3 x 10=5 x 6=2 x 3 x 5
The Bell numbers also count the rhyme schemes of an n-line poem or stanza. A rhyme scheme describes which lines rhyme with each other, and so may be interpreted as a partition of the set of lines into rhyming subsets. Rhyme schemes are usually written as a sequence of Roman letters, one per line, with rhyming lines given the same letter as each other, and with the first lines in each rhyming set labeled in alphabetical order. Thus, the 15 possible four-line rhyme schemes are AAAA, AAAB, AABA, AABB, AABC, ABAA, ABAB, ABAC, ABBA, ABBB, ABBC, ABCA, ABCB, ABCC, and ABCD.
The Bell numbers come up in a card shuffling problem mentioned in the addendum to . If a deck of n cards is shuffled by repeatedly removing the top card and reinserting it anywhere in the deck (including its original position at the top of the deck), with exactly n repetitions of this operation, then there are nn different shuffles that can be performed. Of these, the number that return the deck to its original sorted order is exactly Bn. Thus, the probability that the deck is in its original order after shuffling it in this way is Bn/nn, which is significantly larger than the 1/n! probability that would describe a uniformly random permutation of the deck.
Related to card shuffling are several other problems of counting special kinds of permutations that are also answered by the Bell numbers. For instance, the nth Bell number equals the number of permutations on n items in which no three values that are in sorted order have the last two of these three consecutive. In a notation for generalized permutation patterns where values that must be consecutive are written adjacent to each other, and values that can appear non-consecutively are separated by a dash, these permutations can be described as the permutations that avoid the pattern 1-23. The permutations that avoid the generalized patterns 12-3, 32-1, 3-21, 1-32, 3-12, 21-3, and 23-1 are also counted by the Bell numbers. The permutations in which every 321 pattern (without restriction on consecutive values) can be extended to a 3241 pattern are also counted by the Bell numbers. However, the Bell numbers grow too quickly to count the permutations that avoid a pattern that has not been generalized in this way: by the (now proven) Stanley–Wilf conjecture, the number of such permutations is singly exponential, and the Bell numbers have a higher asymptotic growth rate than that.
See main article: article and Bell triangle. The Bell numbers can easily be calculated by creating the so-called Bell triangle, also called Aitken's array or the Peirce triangle after Alexander Aitken and Charles Sanders Peirce.[3]
x0,1=1
xi,1\leftarrowxi-1,
(xi,j\leftarrowxi,j-1+xi-1,j-1)
j=r+1
Bi\leftarrowxi,1
Here are the first five rows of the triangle constructed by these rules:
\begin{array}{l} 1\\ 1&2\\ 2&3&5\\ 5&7&10&15\\ 15&20&27&37&52 \end{array}
The Bell numbers appear on both the left and right sides of the triangle.
The Bell numbers satisfy a recurrence relation involving binomial coefficients:
Bn+1
n | |
=\sum | |
k=0 |
\binom{n}{k}Bk.
\tbinom{n}{k}
A different summation formula represents each Bell number as a sum of Stirling numbers of the second kind
Bn=\sum
n | |
k=0 |
\left\{{n\atopk}\right\}.
\left\{{n\atopk}\right\}
has given a formula that combines both of these summations:
Bn+m=
n | |
\sum | |
k=0 |
m | |
\sum | |
j=0 |
\left\{{m\atopj}\right\}{n\choosek}jn-kBk.
which can be generalized in this manner:[4]
Other finite sum formulas using Stirling numbers of the first kind include
which simplifies down with
k=1
and with
a=1
b=k
which can be seen as the inversion formula for Stirling numbers applied to Spivey’s formula.
The exponential generating function of the Bell numbers is
B(x)=
infty | |
\sum | |
n=0 |
Bn | |
n! |
xn=
ex-1 | |
e |
.
One way to derive this result uses analytic combinatorics, a style of mathematical reasoning in which sets of mathematical objects are described by formulas explaining their construction from simpler objects, and then those formulas are manipulated to derive the combinatorial properties of the objects. In the language of analytic combinatorics, a set partition may be described as a set of nonempty urns into which elements labelled from 1 to n have been distributed, and the combinatorial class of all partitions (for all n) may be expressed by the notation
S\scriptstyleET(S\scriptstyleET\ge(l{Z})).
l{Z}
S\scriptstyleET\ge
S\scriptstyleET
S\scriptstyleET
B'(x)=exB(x)
The Bell numbers satisfy Dobinski's formula
B | ||||
|
infty | |
\sum | |
k=0 |
kn | |
k! |
.
The nth Bell number is also the sum of the coefficients in the nth complete Bell polynomial, which expresses the nth moment of any probability distribution as a function of the first n cumulants.
The Bell numbers obey Touchard's congruence: If p is any prime number then
Bp+n\equivBn+Bn+1\pmodp
B | |
pm+n |
\equivmBn+Bn+1\pmodp.
Because of Touchard's congruence, the Bell numbers are periodic modulo p, for every prime number p; for instance, for p = 2, the Bell numbers repeat the pattern odd-odd-even with period three. The period of this repetition, for an arbitrary prime number p, must be a divisor of
pp-1 | |
p-1 |
p\leq101
p=113,163,167
173
The period of the Bell numbers to modulo n are
1, 3, 13, 12, 781, 39, 137257, 24, 39, 2343, 28531167061, 156, 25239592216021, 411771, 10153, 48, 51702516367896047761, 39, 109912203092239643840221, 9372, 1784341, 85593501183, 949112181811268728834319677753, 312, 3905, 75718776648063, 117, 1647084, 91703076898614683377208150526107718802981, 30459, 568972471024107865287021434301977158534824481, 96, 370905171793, 155107549103688143283, 107197717, 156, ...
An application of Cauchy's integral formula to the exponential generating function yields the complex integral representation
Bn=
n! | |
2\piie |
\int\gamma
| |||||
zn+1 |
dz.
Some asymptotic representations can then be derived by a standard application of the method of steepest descent.[5]
The Bell numbers form a logarithmically convex sequence. Dividing them by the factorials, Bn/n!, gives a logarithmically concave sequence.
Several asymptotic formulas for the Bell numbers are known. In the following bounds were established:
Bn<\left(
0.792n | |
ln(n+1) |
\right)n
n
\varepsilon>0
n>n0(\varepsilon)
Bn<\left(
e-0.6n | |
ln(n+1) |
\right)n
~n0(\varepsilon)=max\left\{e4,d-1(\varepsilon)\right\}~
~d(x):=lnln(x+1)-lnlnx+
1+e-1 | |
lnx |
.
Bn\sim
1 | |
\sqrt{n |
established the expansion
Bn+h=
(n+h)! | |
W(n)n+h |
x
\exp(eW(n)-1) | |
(2\piB)1/2 |
x \left(1+
| |||||||||||||
eW(n) |
+
| |||||||||||||||||||||||||
e2W(n) |
+O(e-3W(n))\right)
h=O(ln(n))
n → infty
B
Pi
Qi
W(n)
The asymptotic expression
\begin{align} | lnBn |
n |
&=lnn-lnlnn-1+
lnlnn | |
lnn |
+
1 | |
lnn |
+
1 | \left( | |
2 |
lnlnn | |
lnn |
\right)2+O\left(
lnlnn | |
(lnn)2 |
\right)\\ &{} asn\toinfty \end{align}
was established by .
raised the question of whether infinitely many Bell numbers are also prime numbers. These are called Bell primes. The first few Bell primes are:
2, 5, 877, 27644437, 35742549198872617291353508656626642567, 359334085968622831041960188598043661065388726959079837 corresponding to the indices 2, 3, 7, 13, 42 and 55 . The next Bell prime is B2841, which is approximately 9.30740105 × 106538.
The Bell numbers are named after Eric Temple Bell, who wrote about them in 1938, following up a 1934 paper in which he studied the Bell polynomials. Bell did not claim to have discovered these numbers; in his 1938 paper, he wrote that the Bell numbers "have been frequently investigated" and "have been rediscovered many times". Bell cites several earlier publications on these numbers, beginning with which gives Dobiński's formula for the Bell numbers. Bell called these numbers "exponential numbers"; the name "Bell numbers" and the notation Bn for these numbers was given to them by .[7]
The first exhaustive enumeration of set partitions appears to have occurred in medieval Japan, where (inspired by the popularity of the book The Tale of Genji) a parlor game called genji-ko sprang up,in which guests were given five packets of incense to smell and were asked to guess which ones were the same as each other and which were different. The 52 possible solutions, counted by the Bell number B5, were recorded by 52 different diagrams, which were printed above the chapter headings in some editions of The Tale of Genji.[8]
In Srinivasa Ramanujan's second notebook, he investigated both Bell polynomials and Bell numbers.Early references for the Bell triangle, which has the Bell numbers on both of its sides, include and .
|