scholarly journals Definable Encodings in the Computably Enumerable Sets

2000 ◽  
Vol 6 (2) ◽  
pp. 185-196 ◽  
Author(s):  
Peter A. Cholak ◽  
Leo A. Harrington
Keyword(s):  
Computability Theory ◽  
Finite Sets ◽  
Warm Up ◽  
Computably Enumerable Sets ◽  
Disjoint Sets ◽  
New Form ◽  
Historical Remarks ◽  
Equivalent Class ◽  
The Ideal ◽  
Computably Enumerable

The purpose of this communication is to announce some recent results on the computably enumerable sets. There are two disjoint sets of results; the first involves invariant classes and the second involves automorphisms of the computably enumerable sets. What these results have in common is that the guts of the proofs of these theorems uses a new form of definable coding for the computably enumerable sets.We will work in the structure of the computably enumerable sets. The language is just inclusion, ⊆. This structure is called ε.All sets will be computably enumerable non-computable sets and all degrees will be computably enumerable and non-computable, unless otherwise noted. Our notation and definitions are standard and follow Soare [1987]; however we will warm up with some definitions and notation issues so the reader need not consult Soare [1987]. Some historical remarks follow in Section 2.1 and throughout Section 3.We will also consider the quotient structure ε modulo the ideal of finite sets, ε*. ε* is a definable quotient structure of ε since “Χ is finite” is definable in ε; “Χ is finite” iff all subsets of Χ are computable (it takes a little computability theory to show if Χ is infinite then Χ has an infinite non-computable subset). We use A* to denote the equivalent class of A under the ideal of finite sets.

scholarly journals Randomness and Computability

2021 ◽  
Author(s):  
◽  
Adam Richard Day
Keyword(s):  
Computability Theory ◽  
Binary Sequences ◽  
Cantor Space ◽  
Computably Enumerable Sets ◽  
Schnorr Randomness ◽  
Separation Result ◽  
The Difference ◽  
Deep Relationship ◽  
Scott Set ◽  
Computably Enumerable

<p>This thesis establishes significant new results in the area of algorithmic randomness. These results elucidate the deep relationship between randomness and computability. A number of results focus on randomness for finite strings. Levin introduced two functions which measure the randomness of finite strings. One function is derived from a universal monotone machine and the other function is derived from an optimal computably enumerable semimeasure. Gacs proved that infinitely often, the gap between these two functions exceeds the inverse Ackermann function (applied to string length). This thesis improves this result to show that infinitely often the difference between these two functions exceeds the double logarithm. Another separation result is proved for two different kinds of process machine. Information about the randomness of finite strings can be used as a computational resource. This information is contained in the overgraph. Muchnik and Positselsky asked whether there exists an optimal monotone machine whose overgraph is not truth-table complete. This question is answered in the negative. Related results are also established. This thesis makes advances in the theory of randomness for infinite binary sequences. A variant of process machines is used to characterise computable randomness, Schnorr randomness and weak randomness. This result is extended to give characterisations of these types of randomness using truthtable reducibility. The computable Lipschitz reducibility measures both the relative randomness and the relative computational power of real numbers. It is proved that the computable Lipschitz degrees of computably enumerable sets are not dense. Infinite binary sequences can be regarded as elements of Cantor space. Most research in randomness for Cantor space has been conducted using the uniform measure. However, the study of non-computable measures has led to interesting results. This thesis shows that the two approaches that have been used to define randomness on Cantor space for non-computable measures: that of Reimann and Slaman, along with the uniform test approach first introduced by Levin and also used by Gacs, Hoyrup and Rojas, are equivalent. Levin established the existence of probability measures for which all infinite sequences are random. These measures are termed neutral measures. It is shown that every PA degree computes a neutral measure. Work of Miller is used to show that the set of atoms of a neutral measure is a countable Scott set and in fact any countable Scott set is the set of atoms of some neutral measure. Neutral measures are used to prove new results in computability theory. For example, it is shown that the low computable enumerable sets are precisely the computably enumerable sets bounded by PA degrees strictly below the halting problem. This thesis applies ideas developed in the study of randomness to computability theory by examining indifferent sets for comeager classes in Cantor space. A number of results are proved. For example, it is shown that there exist 1-generic sets that can compute their own indifferent sets.</p>

scholarly journals Randomness and Computability

2021 ◽  
Author(s):  
◽  
Adam Richard Day
Keyword(s):  
Computability Theory ◽  
Binary Sequences ◽  
Cantor Space ◽  
Computably Enumerable Sets ◽  
Schnorr Randomness ◽  
Separation Result ◽  
The Difference ◽  
Deep Relationship ◽  
Scott Set ◽  
Computably Enumerable

<p>This thesis establishes significant new results in the area of algorithmic randomness. These results elucidate the deep relationship between randomness and computability. A number of results focus on randomness for finite strings. Levin introduced two functions which measure the randomness of finite strings. One function is derived from a universal monotone machine and the other function is derived from an optimal computably enumerable semimeasure. Gacs proved that infinitely often, the gap between these two functions exceeds the inverse Ackermann function (applied to string length). This thesis improves this result to show that infinitely often the difference between these two functions exceeds the double logarithm. Another separation result is proved for two different kinds of process machine. Information about the randomness of finite strings can be used as a computational resource. This information is contained in the overgraph. Muchnik and Positselsky asked whether there exists an optimal monotone machine whose overgraph is not truth-table complete. This question is answered in the negative. Related results are also established. This thesis makes advances in the theory of randomness for infinite binary sequences. A variant of process machines is used to characterise computable randomness, Schnorr randomness and weak randomness. This result is extended to give characterisations of these types of randomness using truthtable reducibility. The computable Lipschitz reducibility measures both the relative randomness and the relative computational power of real numbers. It is proved that the computable Lipschitz degrees of computably enumerable sets are not dense. Infinite binary sequences can be regarded as elements of Cantor space. Most research in randomness for Cantor space has been conducted using the uniform measure. However, the study of non-computable measures has led to interesting results. This thesis shows that the two approaches that have been used to define randomness on Cantor space for non-computable measures: that of Reimann and Slaman, along with the uniform test approach first introduced by Levin and also used by Gacs, Hoyrup and Rojas, are equivalent. Levin established the existence of probability measures for which all infinite sequences are random. These measures are termed neutral measures. It is shown that every PA degree computes a neutral measure. Work of Miller is used to show that the set of atoms of a neutral measure is a countable Scott set and in fact any countable Scott set is the set of atoms of some neutral measure. Neutral measures are used to prove new results in computability theory. For example, it is shown that the low computable enumerable sets are precisely the computably enumerable sets bounded by PA degrees strictly below the halting problem. This thesis applies ideas developed in the study of randomness to computability theory by examining indifferent sets for comeager classes in Cantor space. A number of results are proved. For example, it is shown that there exist 1-generic sets that can compute their own indifferent sets.</p>

scholarly journals Definable properties of the computably enumerable sets

1998 ◽  
Vol 94 (1-3) ◽  
pp. 97-125 ◽  
Author(s):  
Leo Harrington ◽  
Robert I. Soare
Keyword(s):  
Computably Enumerable Sets ◽  
Computably Enumerable

Truth-Table Complete Computably Enumerable Sets

2003 ◽  
pp. 1-10 ◽  
Author(s):  
Marat M. Arslanov
Keyword(s):  
Truth Table ◽  
Computably Enumerable Sets ◽  
Computably Enumerable

Some properties of the upper semilattice of computable families of computably enumerable sets

2021 ◽  
Vol 60 (2) ◽  
pp. 195-209
Author(s):  
M. Kh. Faizrakhmanov
Keyword(s):  
Computably Enumerable Sets ◽  
Upper Semilattice ◽  
Computably Enumerable

scholarly journals Extension theorems, orbits, and automorphisms of the computably enumerable sets

2007 ◽  
Vol 360 (04) ◽  
pp. 1759-1792 ◽  
Author(s):  
Peter A. Cholak ◽  
Leo A. Harrington
Keyword(s):  
Extension Theorems ◽  
Computably Enumerable Sets ◽  
Computably Enumerable

Continuum-many Boolean algebras of the form Borel

2004 ◽  
Vol 69 (3) ◽  
pp. 799-816 ◽  
Author(s):  
Michael Ray Oliver
Keyword(s):  
Equivalence Relation ◽  
Continuum Hypothesis ◽  
Boolean Algebras ◽  
New Technique ◽  
Finite Sets ◽  
A New Technique ◽  
Borel Ideals ◽  
Forcing Axiom ◽  
The Continuum ◽  
The Ideal

Abstract.We examine the question of how many Boolean algebras, distinct up to isomorphism, that are quotients of the powerset of the naturals by Borel ideals, can be proved to exist in ZFC alone. The maximum possible value is easily seen to be the cardinality of the continuum ; earlier work by Ilijas Farah had shown that this was the value in models of Martin's Maximum or some similar forcing axiom, but it was open whether there could be fewer in models of the Continuum Hypothesis.We develop and apply a new technique for constructing many ideals whose quotients must be nonisomorphic in any model of ZFC. The technique depends on isolating a kind of ideal, called shallow, that can be distinguished from the ideal of all finite sets even after any isomorphic embedding, and then piecing together various copies of the ideal of all finite sets using distinct shallow ideals. In this way we are able to demonstrate that there are continuum-many distinct quotients by Borel ideals, indeed by analytic P-ideals, and in fact that there is in an appropriate sense a Borel embedding of the Vitali equivalence relation into the equivalence relation of isomorphism of quotients by analytic P-ideals. We also show that there is an uncountable definable wellordered collection of Borel ideals with distinct quotients.

scholarly journals The computable Lipschitz degrees of computably enumerable sets are not dense

2010 ◽  
Vol 161 (12) ◽  
pp. 1588-1602 ◽  
Author(s):  
Adam R. Day
Keyword(s):  
Computably Enumerable Sets ◽  
Computably Enumerable

scholarly journals Pesantren Virtual: Dinamisasi atau Disrupsi Pesantren?

2021 ◽  
Vol 10 (1) ◽  
pp. 153-168
Author(s):  
Hatta Fakhrurrozi
Keyword(s):  
Industrial Revolution ◽  
Boarding Schools ◽  
Online Media ◽  
Library Research ◽  
The World ◽  
New Form ◽  
Cultural Base ◽  
Adaptive Step ◽  
Open Nature ◽  
The Ideal

The industrial revolution that penetrated the world of education forced Islamic boarding schools (Pesantren), as part of education, to mutate in new form to find the ideal format as an adaptive step to keep up to date. Pesantren which have a cultural base of traditional society make various efforts to make acculturation with technology. The efforts of these pesantren can be seen from the number of pesantren websites, which provide information about pesantren and religious programs online. On the other hand, virtual pesantren have also emerged, which do not have a real pesantren institutional base in the community, using online media as an operational base. Some of these virtual Islamic boarding schools have strong buildings in cyberspace, with a wider reach than Islamic boarding schools. Its flexible and open nature makes virtual pesantren have their own community in cyberspace. Furthermore, problems arise when virtual Islamic boarding schools intersect with conventional Pesantren in cyberspace. This research is a library research that uses printed and online media as data sources. This study aims to find differences in the characteristics of virtual pesantren, and their relationship with the dynamics of pesantren in the era 4.0. From the content analysis conducted at several virtual pesantren, it was found that some of them used the same name as real pesantren, thus creating ambiguity of virtual pesantren

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