Difference between revisions of "Partition"

2020 Mathematics Subject Classification: Primary: 54B [MSN][ZBL]

Of a topological space

A closed set $E$ in a topological space $X$ that partitions $X$ between two given sets $P$ and $Q$ (or, in other words, separates $P$ and $Q$ in $X$), i.e. such that $X \setminus E = H_1 \cup H_2$, where $H_1$ and $H_2$ are disjoint and open in $X \setminus E$, $P \subseteq H_1$, $Q \subseteq H_2$ ($P$ and $Q$ are open in all of $X$). A partition is called fine if its interior is empty. Any binary decomposition (i.e. a partition consisting of two elements) $\alpha = (A_1,A_2)$ of a space $X$ defines a fine partition in $X$: $B$ is the boundary of $A_1$, which is the boundary of $A_2$, where $X\setminus B = O_1 \cup O_2$, in which $O_i$ is the interior of $A_i$, $i=1,2$. The converse is also true. In essence, the concept of a partition between sets leads to the concept of connectedness. The converse also applies: A space $X$ is disconnected if $\emptyset$ is a partition between non-empty sets.

Comments

Related notions in this context are those of a separator and of a cut.

If $A$ and $B$ are disjoint subsets of a space $X$, then a separator between$A$ and $B$ is a set $S$ such that $X \setminus S = V \cup W$ with $V$ and $W$ disjoint and open in $X \setminus S$, and $A \subseteq V$ and $B \subseteq W$. So a partition is a closed separator.

A set $C$ is a cut between $A$ and $B$ if $C$ intersects every continuum that intersects both $A$ and $B$.

One readily sees that every partition is a separator and that every separator is a cut, and the following examples show that the notions are in general distinct: the open interval $(0,1)$ is a separator between $\{0\}$ and $\{1\}$ in the interval $[0,1]$, but not a partition; in the well-known subspace $\{0\} \times [-1,1] \cup \{ (x,\sin(1/x)) : 0 < x \le 1 \}$ of the Euclidean space, the point $(0,0)$ is a cut but not a separator between the points $(0,1)$ and $(1,\sin 1)$.

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2020 Mathematics Subject Classification: Primary: 11P [MSN][ZBL]

Of a positive integer

A partition of a positive integer $n$ is a decomposition of $n$ as a sum of positive integers. For example, the partitions of $4$ read: $4$, $3+1$, $2+2$, $2+1+1$, $1+1+1+1$. The partition function $p(n)$ gives the number of different partitions of $n$. So, $p(4) = 5$. L. Euler gave a non-trivial recurrence relation for $p(n)$ (see [a1]) and Ramanujan discovered the surprising congruences $p(5n+4) \equiv 0 \pmod 5$, $p(7m+5) \equiv 0 \pmod 7$, $p(11m+6) \equiv 0 \pmod{11}$, and others. He also found the asymptotic relation $$ p(n) \sim \frac{e^{K\sqrt n}}{4n\sqrt3}\ \ \ \text{as}\ n\rightarrow \infty $$ where $K=\pi\sqrt{2/3}$. Later this was completed to an exact series expansion by H. Rademacher (see [a2]).

One can also distinguish other partitions, having particular properties, such as the numbers in the decomposition being distinct (see [a3]). See also Additive number theory; Additive problems.

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Of a set

Expression of a set $Y$ as a disjoint union of subsets: a family of subsets $X_\lambda \subseteq Y$ for $\lambda \in \Lambda$, for some index set $\Lambda$, which are pairwise disjoint, $\lambda \neq \mu \Rightarrow X_\lambda \cap X_\mu = \emptyset$ and such that the union $\bigcup_{\lambda \in \Lambda} X_\lambda = Y$. The classes of an equivalence relation on $Y$ form a partition of $Y$, as does the kernel of a function; conversely a partition defines an equivalence relation and a function giving rise to that partition. See also Decomposition.

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