{"docId":3234,"paperId":3198,"url":"https:\/\/lmcs.episciences.org\/3198","doi":"10.23638\/LMCS-13(1:18)2017","journalName":"Logical Methods in Computer Science","issn":"","eissn":"1860-5974","volume":[{"vid":299,"name":"Volume 13, Issue 1"}],"section":[],"repositoryName":"arXiv","repositoryIdentifier":"1703.05212","repositoryVersion":2,"repositoryLink":"https:\/\/arxiv.org\/abs\/1703.05212v2","dateSubmitted":"2017-03-30 18:22:58","dateAccepted":"2017-03-30 18:26:37","datePublished":"2017-03-30 18:30:51","titles":["Existence of strongly proper dyadic subbases"],"authors":["Tsukamoto, Yasuyuki"],"abstracts":["We consider a topological space with its subbase which induces a coding for each point. Every second-countable Hausdorff space has a subbase that is the union of countably many pairs of disjoint open subsets. A dyadic subbase is such a subbase with a fixed enumeration. If a dyadic subbase is given, then we obtain a domain representation of the given space. The properness and the strong properness of dyadic subbases have been studied, and it is known that every strongly proper dyadic subbase induces an admissible domain representation regardless of its enumeration. We show that every locally compact separable metric space has a strongly proper dyadic subbase.","Comment: 11 pages"],"keywords":["Mathematics - General Topology","I.1.1","F.3.2","F.4.1"]}