Maximal set (computability theory): Difference between revisions

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Line 1: In [[computability theory]], a '''maximal set''' is a coinfinite [[computably enumerable set\|computably enumerable subset]] ''A'' of the [[natural number]]s such that for every further computably enumerable subset ''B'' of the natural numbers, either ''B'' is [[cofinite]] or ''B'' is a finite variant of ''A'' or ''B'' is not a superset of ''A''. This gives an easy definition within the [[lattice (order)\|lattice]] of the computably enumerable sets. ~~{{wikify\|date=July 2007}}~~ In [[recursion theory]], the mathematical theory of computability, '''maximal set''' is a coinfinite [[recursive]]ly enumerable (r.e.) subset ''A'' of the natural numbers such that for every further r.e. subset ''B'' of the natural numbers, either ''B'' is cofinite or ''B'' is a finite variant of ''A'' or ''B'' is not a superset of ''A''. This gives an easy definition within the lattic of the r.e. sets. Maximal sets have many interesting properties: they are [[simple set\|simple]], [[hypersimple set\|hypersimple]], [[hyperhypersimple]] and r-maximal; the latter property says that every ~~recursive~~computable set ''R'' contains either only finitely many elements of the complement of ''A'' or almost all elements of the complement of ''A''. There are r-maximal sets that are not maximal; some of them do even not have maximal supersets. Myhill (1956)~~<!-- I DON'T SEE A PAPER BY MYHILL CITED HERE. -->~~ asked whether maximal sets ~~exists~~exist and ~~Frieberg~~Friedberg (1958) ~~constrcuted~~constructed one. Soare (1974)~~<!-- SAME COMMENT HERE. -->~~ showed that the maximal sets form an orbit with respect to [[automorphism]] of the ~~recursively~~computably enumerable sets under inclusion ([[Modulo (jargon)\|modulo]] finite sets). On the one hand, every automorphism maps a maximal set ''A'' to another maximal set ''B''; on the other hand, for every two maximal sets ''A'', ''B'' there is an automorphism of the ~~recursively~~computably enumerable sets such that ''A'' is mapped to ''B''. ==References== ~~{{unreferenced\|date=August 2007}}~~ * {{Citation \| last1=Friedberg \| first1=Richard M. \| title=Three theorems on recursive enumeration. I. Decomposition. II. Maximal set. III. Enumeration without duplication \|mr=0109125 \| year=1958 \| journal=The Journal of Symbolic Logic \| volume=23 \| pages=309–316 \| doi=10.2307/2964290 \| issue=3 \| publisher=Association for Symbolic Logic \| jstor=2964290\| s2cid=25834814 }} [[Category:Set theory]]▼ * {{Citation \| last1=Myhill \| first1=John \| title=Solution of a problem of Tarski \|mr=0075894 \| year=1956 \| journal=The Journal of Symbolic Logic \| volume=21 \| pages=49–51 \| doi=10.2307/2268485 \| issue=1 \| publisher=Association for Symbolic Logic \| jstor=2268485\| s2cid=19695459 }} * H. Rogers, Jr., 1967. ''The Theory of Recursive Functions and Effective Computability'', second edition 1987, MIT Press. {{isbn\|0-262-68052-1}} (paperback), {{isbn\|0-07-053522-1}}. * {{Citation \| last1=Soare \| first1=Robert I. \| title=Automorphisms of the lattice of recursively enumerable sets. I. Maximal sets \| doi=10.2307/1970842 \|mr=0360235 \| year=1974 \| journal=[[Annals of Mathematics]] \|series=Second Series \| volume=100 \| pages=80–120 \| issue=1 \| publisher=Annals of Mathematics \| jstor=1970842}} <br /> ▲[[Category:~~Set~~Computability theory]] {{mathlogic-stub}}