Integer partition

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In number theory and combinatorics, a partition of a non-negative integer n, also called an integer partition, is a way of writing n as a sum of positive integers. Two sums that differ only in the order of their summands are considered the same partition. (If order matters, the sum becomes a composition.) For example, 4 can be partitioned in five distinct ways:

Young diagrams associated to the partitions of the positive integers 1 through 8. They are arranged so that images under the reflection about the main diagonal of the square are conjugate partitions.
Partitions of n with largest part k
4
3 + 1
2 + 2
2 + 1 + 1
1 + 1 + 1 + 1

The only partition of zero is the empty sum, having no parts.

The order-dependent composition 1 + 3 is the same partition as 3 + 1, and the two distinct compositions 1 + 2 + 1 and 1 + 1 + 2 represent the same partition as 2 + 1 + 1.

An individual summand in a partition is called a part. The number of partitions of n is given by the partition function p(n). So p(4) = 5. The notation λn means that λ is a partition of n.

Partitions can be graphically visualized with Young diagrams or Ferrers diagrams. They occur in a number of branches of mathematics and physics, including the study of symmetric polynomials and of the symmetric group and in group representation theory in general.

Examples

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The seven partitions of 5 are

  • 5
  • 4 + 1
  • 3 + 2
  • 3 + 1 + 1
  • 2 + 2 + 1
  • 2 + 1 + 1 + 1
  • 1 + 1 + 1 + 1 + 1

Some authors treat a partition as a decreasing sequence of summands, rather than an expression with plus signs. For example, the partition 2 + 2 + 1 might instead be written as the tuple (2, 2, 1) or in the even more compact form (22, 1) where the superscript indicates the number of repetitions of a part.

This multiplicity notation for a partition can be written alternatively as  , where m1 is the number of 1's, m2 is the number of 2's, etc. (Components with mi = 0 may be omitted.) For example, in this notation, the partitions of 5 are written  , and  .

Diagrammatic representations of partitions

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There are two common diagrammatic methods to represent partitions: as Ferrers diagrams, named after Norman Macleod Ferrers, and as Young diagrams, named after Alfred Young. Both have several possible conventions; here, we use English notation, with diagrams aligned in the upper-left corner.

Ferrers diagram

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The partition 6 + 4 + 3 + 1 of the number 14 can be represented by the following diagram:

      
    
   
 

The 14 circles are lined up in 4 rows, each having the size of a part of the partition. The diagrams for the 5 partitions of the number 4 are shown below:

        
 
  
  
  
 
 
 
 
 
 
4 = 3 + 1 = 2 + 2 = 2 + 1 + 1 = 1 + 1 + 1 + 1

Young diagram

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An alternative visual representation of an integer partition is its Young diagram (often also called a Ferrers diagram). Rather than representing a partition with dots, as in the Ferrers diagram, the Young diagram uses boxes or squares. Thus, the Young diagram for the partition 5 + 4 + 1 is

 

while the Ferrers diagram for the same partition is

     
    
 

While this seemingly trivial variation does not appear worthy of separate mention, Young diagrams turn out to be extremely useful in the study of symmetric functions and group representation theory: filling the boxes of Young diagrams with numbers (or sometimes more complicated objects) obeying various rules leads to a family of objects called Young tableaux, and these tableaux have combinatorial and representation-theoretic significance.[1] As a type of shape made by adjacent squares joined together, Young diagrams are a special kind of polyomino.[2]

Partition function

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Using Euler's method to find p(40): A ruler with plus and minus signs (grey box) is slid downwards, the relevant parts added or subtracted. The positions of the signs are given by differences of alternating natural (blue) and odd (orange) numbers. In the SVG file, hover over the image to move the ruler.

The partition function   counts the partitions of a non-negative integer  . For instance,   because the integer   has the five partitions  ,  ,  ,  , and  . The values of this function for   are:

1, 1, 2, 3, 5, 7, 11, 15, 22, 30, 42, 56, 77, 101, 135, 176, 231, 297, 385, 490, 627, 792, 1002, 1255, 1575, 1958, 2436, 3010, 3718, 4565, 5604, ... (sequence A000041 in the OEIS).

The generating function of   is

 

No closed-form expression for the partition function is known, but it has both asymptotic expansions that accurately approximate it and recurrence relations by which it can be calculated exactly. It grows as an exponential function of the square root of its argument.,[3] as follows:

  as  

In 1937, Hans Rademacher found a way to represent the partition function   by the convergent series

  where

  and   is the Dedekind sum.

The multiplicative inverse of its generating function is the Euler function; by Euler's pentagonal number theorem this function is an alternating sum of pentagonal number powers of its argument.

 

Srinivasa Ramanujan discovered that the partition function has nontrivial patterns in modular arithmetic, now known as Ramanujan's congruences. For instance, whenever the decimal representation of   ends in the digit 4 or 9, the number of partitions of   will be divisible by 5.[4]

Restricted partitions

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In both combinatorics and number theory, families of partitions subject to various restrictions are often studied.[5] This section surveys a few such restrictions.

Conjugate and self-conjugate partitions

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If we flip the diagram of the partition 6 + 4 + 3 + 1 along its main diagonal, we obtain another partition of 14:

      
    
   
 
    
   
   
  
 
 
6 + 4 + 3 + 1 = 4 + 3 + 3 + 2 + 1 + 1

By turning the rows into columns, we obtain the partition 4 + 3 + 3 + 2 + 1 + 1 of the number 14. Such partitions are said to be conjugate of one another.[6] In the case of the number 4, partitions 4 and 1 + 1 + 1 + 1 are conjugate pairs, and partitions 3 + 1 and 2 + 1 + 1 are conjugate of each other. Of particular interest are partitions, such as 2 + 2, which have themselves as conjugate. Such partitions are said to be self-conjugate.[7]

Claim: The number of self-conjugate partitions is the same as the number of partitions with distinct odd parts.

Proof (outline): The crucial observation is that every odd part can be "folded" in the middle to form a self-conjugate diagram:

        ↔      
 
 

One can then obtain a bijection between the set of partitions with distinct odd parts and the set of self-conjugate partitions, as illustrated by the following example:

         
       
   

     
     
    
   
  
9 + 7 + 3 = 5 + 5 + 4 + 3 + 2
Dist. odd self-conjugate

Odd parts and distinct parts

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Among the 22 partitions of the number 8, there are 6 that contain only odd parts:

  • 7 + 1
  • 5 + 3
  • 5 + 1 + 1 + 1
  • 3 + 3 + 1 + 1
  • 3 + 1 + 1 + 1 + 1 + 1
  • 1 + 1 + 1 + 1 + 1 + 1 + 1 + 1

Alternatively, we could count partitions in which no number occurs more than once. Such a partition is called a partition with distinct parts. If we count the partitions of 8 with distinct parts, we also obtain 6:

  • 8
  • 7 + 1
  • 6 + 2
  • 5 + 3
  • 5 + 2 + 1
  • 4 + 3 + 1

This is a general property. For each positive number, the number of partitions with odd parts equals the number of partitions with distinct parts, denoted by q(n).[8][9] This result was proved by Leonhard Euler in 1748[10] and later was generalized as Glaisher's theorem.

For every type of restricted partition there is a corresponding function for the number of partitions satisfying the given restriction. An important example is q(n) (partitions into distinct parts). The first few values of q(n) are (starting with q(0)=1):

1, 1, 1, 2, 2, 3, 4, 5, 6, 8, 10, ... (sequence A000009 in the OEIS).

The generating function for q(n) is given by[11]

 

The pentagonal number theorem gives a recurrence for q:[12]

q(k) = ak + q(k − 1) + q(k − 2) − q(k − 5) − q(k − 7) + q(k − 12) + q(k − 15) − q(k − 22) − ...

where ak is (−1)m if k = 3m2m for some integer m and is 0 otherwise.

Restricted part size or number of parts

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By taking conjugates, the number pk(n) of partitions of n into exactly k parts is equal to the number of partitions of n in which the largest part has size k. The function pk(n) satisfies the recurrence

pk(n) = pk(nk) + pk−1(n − 1)

with initial values p0(0) = 1 and pk(n) = 0 if n ≤ 0 or k ≤ 0 and n and k are not both zero.[13]

One recovers the function p(n) by

 

One possible generating function for such partitions, taking k fixed and n variable, is

 

More generally, if T is a set of positive integers then the number of partitions of n, all of whose parts belong to T, has generating function

 

This can be used to solve change-making problems (where the set T specifies the available coins). As two particular cases, one has that the number of partitions of n in which all parts are 1 or 2 (or, equivalently, the number of partitions of n into 1 or 2 parts) is

 

and the number of partitions of n in which all parts are 1, 2 or 3 (or, equivalently, the number of partitions of n into at most three parts) is the nearest integer to (n + 3)2 / 12.[14]

Partitions in a rectangle and Gaussian binomial coefficients

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One may also simultaneously limit the number and size of the parts. Let p(N, M; n) denote the number of partitions of n with at most M parts, each of size at most N. Equivalently, these are the partitions whose Young diagram fits inside an M × N rectangle. There is a recurrence relation   obtained by observing that   counts the partitions of n into exactly M parts of size at most N, and subtracting 1 from each part of such a partition yields a partition of nM into at most M parts.[15]

The Gaussian binomial coefficient is defined as:   The Gaussian binomial coefficient is related to the generating function of p(N, M; n) by the equality  

Rank and Durfee square

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The rank of a partition is the largest number k such that the partition contains at least k parts of size at least k. For example, the partition 4 + 3 + 3 + 2 + 1 + 1 has rank 3 because it contains 3 parts that are ≥ 3, but does not contain 4 parts that are ≥ 4. In the Ferrers diagram or Young diagram of a partition of rank r, the r × r square of entries in the upper-left is known as the Durfee square:

    
   
   
  
 
 

The Durfee square has applications within combinatorics in the proofs of various partition identities.[16] It also has some practical significance in the form of the h-index.

A different statistic is also sometimes called the rank of a partition (or Dyson rank), namely, the difference   for a partition of k parts with largest part  . This statistic (which is unrelated to the one described above) appears in the study of Ramanujan congruences.

Young's lattice

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There is a natural partial order on partitions given by inclusion of Young diagrams. This partially ordered set is known as Young's lattice. The lattice was originally defined in the context of representation theory, where it is used to describe the irreducible representations of symmetric groups Sn for all n, together with their branching properties, in characteristic zero. It also has received significant study for its purely combinatorial properties; notably, it is the motivating example of a differential poset.

Random partitions

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There is a deep theory of random partitions chosen according to the uniform probability distribution on the symmetric group via the Robinson–Schensted correspondence. In 1977, Logan and Shepp, as well as Vershik and Kerov, showed that the Young diagram of a typical large partition becomes asymptotically close to the graph of a certain analytic function minimizing a certain functional. In 1988, Baik, Deift and Johansson extended these results to determine the distribution of the longest increasing subsequence of a random permutation in terms of the Tracy–Widom distribution.[17] Okounkov related these results to the combinatorics of Riemann surfaces and representation theory.[18][19]

See also

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Notes

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  1. ^ Andrews 1976, p. 199.
  2. ^ Josuat-Vergès, Matthieu (2010), "Bijections between pattern-avoiding fillings of Young diagrams", Journal of Combinatorial Theory, Series A, 117 (8): 1218–1230, arXiv:0801.4928, doi:10.1016/j.jcta.2010.03.006, MR 2677686, S2CID 15392503.
  3. ^ Andrews 1976, p. 69.
  4. ^ Hardy & Wright 2008, p. 380.
  5. ^ Alder, Henry L. (1969). "Partition identities - from Euler to the present". American Mathematical Monthly. 76 (7): 733–746. doi:10.2307/2317861. JSTOR 2317861.
  6. ^ Hardy & Wright 2008, p. 362.
  7. ^ Hardy & Wright 2008, p. 368.
  8. ^ Hardy & Wright 2008, p. 365.
  9. ^ Notation follows Abramowitz & Stegun 1964, p. 825
  10. ^ Andrews, George E. (1971). Number Theory. Philadelphia: W. B. Saunders Company. pp. 149–50.
  11. ^ Abramowitz & Stegun 1964, p. 825, 24.2.2 eq. I(B)
  12. ^ Abramowitz & Stegun 1964, p. 826, 24.2.2 eq. II(A)
  13. ^ Richard Stanley, Enumerative Combinatorics, volume 1, second edition. Cambridge University Press, 2012. Chapter 1, section 1.7.
  14. ^ Hardy, G.H. (1920). Some Famous Problems of the Theory of Numbers. Clarendon Press.
  15. ^ Andrews 1976, pp. 33–34.
  16. ^ see, e.g., Stanley 1999, p. 58
  17. ^ Romik, Dan (2015). The surprising mathematics of longest increasing subsequences. Institute of Mathematical Statistics Textbooks. New York: Cambridge University Press. ISBN 978-1-107-42882-9.
  18. ^ Okounkov, Andrei (2000). "Random matrices and random permutations". International Mathematics Research Notices. 2000 (20): 1043. doi:10.1155/S1073792800000532. S2CID 14308256.
  19. ^ Okounkov, A. (2001-04-01). "Infinite wedge and random partitions". Selecta Mathematica. 7 (1): 57–81. arXiv:math/9907127. doi:10.1007/PL00001398. ISSN 1420-9020. S2CID 119176413.

References

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