Partition (mathematics): Difference between revisions
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In [[mathematics]], '''partition''' refers to two related concepts, in [[set theory]] and [[number theory]]. | In [[mathematics]], '''partition''' refers to two related concepts, in [[set theory]] and [[number theory]]. | ||
==Partition (set theory)== | ==Partition (set theory)== | ||
A ''partition'' of a set ''X'' is a collection <math>\mathcal{P}</math> of subsets of ''X'' such that every element of ''X'' is in exactly one of the subsets in <math>\mathcal{P}</math>. | A ''partition'' of a set ''X'' is a collection <math>\mathcal{P}</math> of non-empty subsets ("parts") of ''X'' such that every element of ''X'' is in exactly one of the subsets in <math>\mathcal{P}</math>. | ||
Hence a three-element set {''a'',''b'',''c''} has 5 partitions: | Hence a three-element set {''a'',''b'',''c''} has 5 partitions: | ||
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*{''b'',''c''}, {''a''} | *{''b'',''c''}, {''a''} | ||
*{''a''}, {''b''}, {''c''} | *{''a''}, {''b''}, {''c''} | ||
Partitions and [[equivalence relation]]s give the same data: the [[equivalence class]]es of an equivalence relation on a set ''X'' form a partition of the set ''X'', and a partition <math>\mathcal{P}</math> gives rise to an equivalence relation where two elements are equivalent if they are in the same part from <math>\mathcal{P}</math>. | |||
The number of partitions of a finite set of size ''n'' into ''k'' parts is given by a [[Stirling number]] of the second kind; | |||
===Bell numbers=== | |||
The total number of partitions of a set of size ''n'' is given by the ''n''-th '''Bell number''', denoted ''B''<sub>''n''</sub>. These may be obtained by the [[recurrence relation]] | |||
:<math>B_n=\sum_{k=0}^{n-1} \binom{m-1}{k} B_k .</math> | |||
They have an [[exponential generating function]] | |||
:<math> e^{e^x-1} = \sum_{n=0}^\infty \frac{B_n}{n!} x^n . </math> | |||
Asymptotically, | |||
:<math> B_n \sim \frac{n!}{\sqrt{2\pi W^2(n)e^{W(n)}}}\frac{e^{e^{W(n)}-1}}{W^n(n)},</math> | |||
where ''W'' denotes the [[Lambert W function]]. | |||
==Partition (number theory)== | ==Partition (number theory)== | ||
A ''partition'' of an [[integer]] ''n'' is an expression of ''n'' as a sum of [[positive integer]]s, with the order of the terms in the sum being disregarded. | A ''partition'' of an [[integer]] ''n'' is an expression of ''n'' as a sum of [[positive integer]]s ("parts"), with the order of the terms in the sum being disregarded. | ||
Hence the number 3 has 3 partitions: | Hence the number 3 has 3 partitions: | ||
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* 2+1 | * 2+1 | ||
* 1+1+1 | * 1+1+1 | ||
The number of partitions of ''n'' is given by the [[partition function (number theory)|partition function]] ''p''(''n''). | |||
==References== | |||
* {{cite book | author=Chen Chuan-Chong | coauthors=Koh Khee-Meng | title=Principles and Techniques of Combinatorics | publisher=[[World Scientific]] | year=1992 | isbn=981-02-1139-2 }}[[Category:Suggestion Bot Tag]] |
Latest revision as of 16:00, 1 October 2024
In mathematics, partition refers to two related concepts, in set theory and number theory.
Partition (set theory)
A partition of a set X is a collection of non-empty subsets ("parts") of X such that every element of X is in exactly one of the subsets in .
Hence a three-element set {a,b,c} has 5 partitions:
- {a,b,c}
- {a,b}, {c}
- {a,c}, {b}
- {b,c}, {a}
- {a}, {b}, {c}
Partitions and equivalence relations give the same data: the equivalence classes of an equivalence relation on a set X form a partition of the set X, and a partition gives rise to an equivalence relation where two elements are equivalent if they are in the same part from .
The number of partitions of a finite set of size n into k parts is given by a Stirling number of the second kind;
Bell numbers
The total number of partitions of a set of size n is given by the n-th Bell number, denoted Bn. These may be obtained by the recurrence relation
They have an exponential generating function
Asymptotically,
where W denotes the Lambert W function.
Partition (number theory)
A partition of an integer n is an expression of n as a sum of positive integers ("parts"), with the order of the terms in the sum being disregarded.
Hence the number 3 has 3 partitions:
- 3
- 2+1
- 1+1+1
The number of partitions of n is given by the partition function p(n).
References
- Chen Chuan-Chong; Koh Khee-Meng (1992). Principles and Techniques of Combinatorics. World Scientific. ISBN 981-02-1139-2.