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In general topology, a polytopological space consists of a set $X$ together with a family $\{\tau _{i}\}_{i\in I}$ of topologies on $X$ that is linearly ordered by the inclusion relation where $I$ is an arbitrary index set. It is usually assumed that the topologies are in non-decreasing order.^[1]^[2] However some authors prefer the associated closure operators $\{k_{i}\}_{i\in I}$ to be in non-decreasing order where $k_{i}\leq k_{j}$ if and only if $k_{i}A\subseteq k_{j}A$ for all $A\subseteq X$ . This requires non-increasing topologies.^[3]

Formal definitions

An $L$ -topological space $(X,\tau )$ is a set $X$ together with a monotone map $\tau :L\to$ Top $(X)$ where $(L,\leq )$ is a partially ordered set and Top $(X)$ is the set of all possible topologies on $X,$ ordered by inclusion. When the partial order $\leq$ is a linear order then $(X,\tau )$ is called a polytopological space. Taking $L$ to be the ordinal number $n=\{0,1,\dots ,n-1\},$ an $n$ -topological space $(X,\tau _{0},\dots ,\tau _{n-1})$ can be thought of as a set $X$ with topologies $\tau _{0}\subseteq \dots \subseteq \tau _{n-1}$ on it. More generally a multitopological space $(X,\tau )$ is a set $X$ together with an arbitrary family $\tau$ of topologies on it.^[2]

History

Polytopological spaces were introduced in 2008 by the philosopher Thomas Icard for the purpose of defining a topological model of Japaridze's polymodal logic (GLP).^[1] They were later used to generalize variants of Kuratowski's closure-complement problem.^[2]^[3] For example Taras Banakh et al. proved that under operator composition the $n$ closure operators and complement operator on an arbitrary $n$ -topological space can together generate at most $2\cdot K(n)$ distinct operators^[2] where $K(n)=\sum _{i,j=0}^{n}{\tbinom {i+j}{i}}\cdot {\tbinom {i+j}{j}}.$ In 1965 the Finnish logician Jaakko Hintikka found this bound for the case $n=2$ and claimed^[4] it "does not appear to obey any very simple law as a function of $n$ ".

References

^ ^a ^b Icard, III, Thomas F. (2008). Models of the Polymodal Provability Logic (PDF) (Master's thesis). University of Amsterdam.
^ ^a ^b ^c ^d Banakh, Taras; Chervak, Ostap; Martynyuk, Tetyana; Pylypovych, Maksym; Ravsky, Alex; Simkiv, Markiyan (2018). "Kuratowski Monoids of $n$ -Topological Spaces". Topological Algebra and Its Applications. 6 (1): 1–25. arXiv:1508.07703. doi:10.1515/taa-2018-0001.
^ ^a ^b Canilang, Sara; Cohen, Michael P.; Graese, Nicolas; Seong, Ian (2021). "The closure-complement-frontier problem in saturated polytopological spaces". New Zealand Journal of Mathematics. 51: 3–27. arXiv:1907.08203. doi:10.53733/151. MR 4374156.
^ Hintikka, Jaakko (1965). "A closure and complement result for nested topologies". Fundamenta Mathematicae. 57: 97–106. MR 0195034.

[Icard2008-1] Icard, III, Thomas F. (2008). Models of the Polymodal Provability Logic (PDF) (Master's thesis). University of Amsterdam.

[Banakh2018-2] Banakh, Taras; Chervak, Ostap; Martynyuk, Tetyana; Pylypovych, Maksym; Ravsky, Alex; Simkiv, Markiyan (2018). "Kuratowski Monoids of $n$ -Topological Spaces". Topological Algebra and Its Applications. 6 (1): 1–25. arXiv:1508.07703. doi:10.1515/taa-2018-0001.

[Canilang2019-3] Canilang, Sara; Cohen, Michael P.; Graese, Nicolas; Seong, Ian (2021). "The closure-complement-frontier problem in saturated polytopological spaces". New Zealand Journal of Mathematics. 51: 3–27. arXiv:1907.08203. doi:10.53733/151. MR 4374156.

[Hintikka1965-4] Hintikka, Jaakko (1965). "A closure and complement result for nested topologies". Fundamenta Mathematicae. 57: 97–106. MR 0195034.

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+In [[general topology]], a '''polytopological space''' consists of a [[set (mathematics)|set]] <math>X</math> together with a [[family of sets|family]] <math>\{\tau_i\}_{i\in I}</math> of [[Topological_space#Definition_via_open_sets|topologies]] on <math>X</math> that is [[Total order|linearly ordered]] by the [[Subset|inclusion relation]] where <math>I</math> is an arbitrary [[index set]]. It is usually assumed that the topologies are in non-decreasing order.<ref name=Icard2008>{{cite thesis
-{{AFC submission|t||ts=20191025005949|u=Mathematrucker|ns=118|demo=}}<!-- Important, do not remove this line before article has been created. -->
+ | last1 = Icard, III
+ | first1 = Thomas F.
+ | title = Models of the Polymodal Provability Logic
+ | date = 2008
+ | type = Master's thesis
+ | url = https://www.illc.uva.nl/Research/Publications/Reports/MoL-2008-06.text.pdf
+ | publisher = University of Amsterdam }}</ref><ref name=Banakh2018>{{cite journal
+ | last1 = Banakh
+ | first1 = Taras
+ | last2 = Chervak
+ | first2 = Ostap
+ | last3 = Martynyuk
+ | first3 = Tetyana
+ | last4 = Pylypovych
+ | first4 = Maksym
+ | last5 = Ravsky
+ | first5 = Alex
+ | last6 = Simkiv
+ | first6 = Markiyan
+ | title = Kuratowski Monoids of <math>n</math>-Topological Spaces
+ | journal = Topological Algebra and Its Applications
+ | date = 2018
+ | volume = 6
+ | issue = 1
+ | pages = 1–25
+ | doi = 10.1515/taa-2018-0001
+ | doi-access = free
+ | arxiv = 1508.07703 }}</ref> However some authors prefer the associated [[closure (topology)|closure]] [[operator (mathematics)|operators]] <math>\{k_i\}_{i\in I}</math> to be in non-decreasing order where <math>k_i\leq k_j</math> if and only if <math>k_iA\subseteq k_jA</math> for all <math>A\subseteq X</math>. This requires non-increasing topologies.<ref name=Canilang2019>{{cite journal
+ | last1 = Canilang | first1 = Sara
+ | last2 = Cohen | first2 = Michael P.
+ | last3 = Graese | first3 = Nicolas
+ | last4 = Seong | first4 = Ian
+ | arxiv = 1907.08203
+ | journal = New Zealand Journal of Mathematics
+ | mr = 4374156
+ | pages = 3–27
+ | doi = 10.53733/151
+ | doi-access = free
+ | title = The closure-complement-frontier problem in saturated polytopological spaces
+ | volume = 51
+ | year = 2021}}</ref>
+== Formal definitions ==
-In [[general topology]], a '''polytopological space''' consists of a [[set (mathematics)|set]] <math>X</math> together with a [[family of sets|family]] <math>\{\tau_i\}_{i\in I}</math> (the set <math>I</math> is an arbitrary [[index set]]) of [[Topological_space#Definition_via_open_sets|topologies]] on <math>X</math> that is [[Total order|linearly ordered]] by the [[Subset|inclusion relation]]. It is usually assumed that the topologies are in non-decreasing order,<ref name=Icard2008>{{cite journal |last1=Icard, III |first1=Thomas F. |title=Models of the Polymodal Provability Logic |date=2008 |volume=Master's thesis |url=https://www.illc.uva.nl/Research/Publications/Reports/MoL-2008-06.text.pdf |publisher=University of Amsterdam}}</ref><ref name=Banakh2018>{{cite journal |last1=Banakh |first1=Taras |last2=Chervak |first2=Ostap |last3=Martynyuk |first3=Tetyana |last4=Pylypovych |first4=Maksym |last5=Ravsky |first5=Alex |last6=Simkiv |first6=Markiyan |title=Kuratowski Monoids of n-Topological Spaces |journal=Topological Algebra and its Applications |date=2018 |volume=6 |issue=1 |doi=10.1515/taa-2018-0001 |url=https://www.degruyter.com/view/j/taa.2018.6.issue-1/taa-2018-0001/taa-2018-0001.xml}}</ref> but some authors prefer to put the associated [[closure (topology)|closure]] [[operator (mathematics)|operators]] <math>\{c_i\}_{i\in I}</math> in non-decreasing order, where <math>c_i\leq c_j</math> if and only if <math>c_iA\leq c_jA</math> for all <math>A\subset X;</math> to achieve this, the topologies must be non-increasing.<ref name=Canilang2019>{{cite journal |last1=Canilang |first1=Sara |last2=Cohen |first2=Michael P. |last3=Graese |first3=Nicolas |last4=Seong |first4=Ian |title=The Closure-Complement-Frontier Problem in Saturated Polytopological Spaces |date=2019 |volume=arXiv:1907.08203 [math.GN] |page=3 |url=https://arxiv.org/abs/1907.08203}}</ref>
+An <math>L</math>'''-topological space''' <math>(X,\tau)</math>
-Polytopological spaces were introduced in 2008 by the philosopher [[Thomas Icard]] for the purpose of defining a topological [[Model theory|model]] of [[Japaridze's polymodal logic|Japaridze's polymodal logic (GLP)]].<ref name=Icard2008 /> They subsequently became an object of study in their own right, specifically in connection with [[Kuratowski's closure-complement problem]].<ref name=Banakh2018 /><ref name=Canilang2019 />
+is a set <math>X</math> together with a [[monotonic function|monotone map]] <math>\tau:L\to</math> '''Top'''<math>(X)</math> where <math>(L,\leq)</math> is a [[partially ordered set]] and '''Top'''<math>(X)</math> is the set of all possible topologies on <math>X,</math> ordered by inclusion. When the partial order <math>\leq</math> is a linear order then <math>(X,\tau)</math> is called a '''polytopological space'''. Taking <math>L</math> to be the [[ordinal number#Von_Neumann_definition_of_ordinals|ordinal number]] <math>n=\{0,1,\dots,n-1\},</math> an [[N-topological space|<math>n</math>'''-topological space''']] <math>(X,\tau_0,\dots,\tau_{n-1})</math> can be thought of as a set <math>X</math> with topologies <math>\tau_0\subseteq\dots\subseteq\tau_{n-1}</math> on it.  More generally a '''multitopological space''' <math>(X,\tau)</math> is a set <math>X</math> together with an arbitrary family <math>\tau</math> of topologies on it.<ref name=Banakh2018 />
-== Definition ==
+== History ==
+Polytopological spaces were introduced in 2008 by the philosopher [[Thomas Icard]] for the purpose of defining a topological [[Model theory|model]] of [[Japaridze's polymodal logic|Japaridze's polymodal logic (GLP)]].<ref name=Icard2008 /> They were later used to generalize variants of [[Kuratowski's closure-complement problem]].<ref name=Banakh2018 /><ref name=Canilang2019 /> For example Taras Banakh et al. proved that under operator composition the <math>n</math> closure operators and complement operator on an arbitrary <math>n</math>-topological space can together generate at most <math>2\cdot K(n)</math> distinct operators<ref name=Banakh2018 /> where <math display=block>K(n)=\sum_{i,j=0}^n\tbinom{i+j}{i} \cdot \tbinom{i+j}{j}.</math>In 1965 the Finnish logician [[Jaakko Hintikka]] found this bound for the case <math>n=2</math> and claimed<ref name=Hintikka1965>{{cite journal
-An <math>L</math>'''&#8209;topological space''' <math>(X,\tau)</math>
+ | last1 = Hintikka | first1 = Jaakko
-is a set <math>X</math> together with a [[monotonic function|monotone map]] <math>\tau:L\to</math> '''Top'''<math>(X)</math> where <math>(L,\leq)</math> is a [[partially ordered set]] and '''Top'''<math>(X)</math> is the set of all possible topologies on <math>X,</math> ordered by inclusion. When the partial order <math>\leq</math> is a linear order, then <math>(X,\tau)</math> is called a '''polytopological space'''. Taking <math>L</math> to be the [[ordinal number#Von_Neumann_definition_of_ordinals|ordinal number]] <math>n=\{0,1,\dots,n-1\},</math> an <math>n</math>'''&#8209;topological space''' <math>(X,\tau_0,\dots,\tau_{n-1})</math> can be thought of as a set <math>X</math> together with <math>n</math> topologies <math>\tau_0\subset\dots\subset\tau_{n-1}</math> on it (or <math>\tau_0\supset\dots\supset\tau_{n-1},</math> depending on preference).  More generally, a set <math>X</math> together with an arbitrary family of topologies on it is called a '''multitopological space'''.<ref name=Banakh2018 />
+ | journal = Fundamenta Mathematicae
+ | mr = 0195034
+ | pages = 97-106
+ | title = A closure and complement result for nested topologies
+ | volume = 57
+ | year = 1965
+ | url = https://bibliotekanauki.pl/articles/1381954 }}</ref> it "does not appear to obey any very simple law as a function of <math>n</math>".
+== See also ==
+* [[Bitopological space]]
 == References ==
@@ Line 14: / Line 66: @@
 {{reflist}}
+[[Category:Topology]]
-{{AFC submission|||ts=20191025010538|u=Mathematrucker|ns=118}}