On The Number Of Topologies On A Finite Set
We denote the number of distinct topologies which can be defined on a set $X$ with $n$ elements by $T(n)$. Similarly, $T_0(n)$ denotes the number of distinct $T_0$ topologies on the set $X$. In the present paper, we prove that for any prime $p$, $T(p^k)\equiv k+1 \ (mod \ p)$, and that for each natu...
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| Main Author | |
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| Format | Journal Article |
| Language | English |
| Published |
28.03.2015
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| Subjects | |
| Online Access | Get full text |
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| Summary: | We denote the number of distinct topologies which can be defined on a set $X$
with $n$ elements by $T(n)$. Similarly, $T_0(n)$ denotes the number of distinct
$T_0$ topologies on the set $X$. In the present paper, we prove that for any
prime $p$, $T(p^k)\equiv k+1 \ (mod \ p)$, and that for each natural number $n$
there exists a unique $k$ such that $T(p+n)\equiv k \ (mod \ p)$. We calculate
$k$ for $n=0,1,2,3,4$. We give an alternative proof for a result of Z. I.
Borevich to the effect that $T_0(p+n)\equiv T_0(n+1) \ (mod \ p)$. |
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| DOI: | 10.48550/arxiv.1503.08359 |