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== Properties == Each Chaitin constant {{math|Ω}} has the following properties: * It is [[algorithmic randomness|algorithmically random]] (also known as Martin-LΓΆf random or 1-random).{{sfn|Downey|Hirschfeldt|2010|loc=Theorem 6.1.3}} This means that the shortest program to output the first {{mvar|n}} bits of {{math|Ω}} must be of size at least {{math|''n'' β O(1)}}. This is because, as in the Goldbach example, those {{mvar|n}} bits enable us to find out exactly which programs halt among all those of length at most {{mvar|n}}. * As a consequence, it is a [[normal number]], which means that its digits are equidistributed as if they were generated by tossing a fair coin. * It is not a [[computable number]]; there is no computable function that enumerates its binary expansion, as discussed below. * The set of [[rational number]]s {{mvar|q}} such that {{math|''q'' < Ω}} is [[computably enumerable set|computably enumerable]];{{sfn|Downey|Hirschfeldt|2010|loc=Theorem 5.1.11}} a real number with such a property is called a left-c.e. real number in [[recursion theory]]. * The set of rational numbers {{mvar|q}} such that {{math|''q'' > Ω}} is not computably enumerable. (Reason: every left-c.e. real with this property is computable, which {{math|Ω}} is not.) * It is an [[arithmetical number]]. * It is [[Turing degree|Turing equivalent]] to the [[halting problem]] and thus at level {{math|{{SubSup|{{noitalic|Δ}}|2|0}}}} of the [[arithmetical hierarchy]]. Not every set that is Turing equivalent to the halting problem is a halting probability. A [[equivalence relation#Comparing equivalence relations|finer]] equivalence relation, Solovay equivalence, can be used to characterize the halting probabilities among the left-c.e. reals.{{sfn|Downey|Hirschfeldt|2010|p=405}} One can show that a real number in {{math|[0,1]}} is a Chaitin constant (i.e. the halting probability of some prefix-free universal computable function) if and only if it is left-c.e. and algorithmically random.{{sfn|Downey|Hirschfeldt|2010|p=405}} {{math|Ω}} is among the few [[Definable real number|definable]] algorithmically random numbers and is the best-known algorithmically random number, but it is not at all typical of all algorithmically random numbers.{{sfn|Downey|Hirschfeldt|2010|pp=228β229}}
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