Difference between revisions of "Kleene-Mostowski classification"
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where $ \exists $ | where $ \exists $ | ||
is the existential [[Quantifier|quantifier]] and $ R( y , x _ {1} \dots x _ {n} ) $ | is the existential [[Quantifier|quantifier]] and $ R( y , x _ {1} \dots x _ {n} ) $ | ||
− | is a predicate in the class $ \Pi _ {k-} | + | is a predicate in the class $ \Pi _ {k-1}$, |
while the class $ \Pi _ {k} $ | while the class $ \Pi _ {k} $ | ||
is defined as the class of predicates expressible in the form $ \forall y R( y, x _ {1} \dots x _ {n} ) $, | is defined as the class of predicates expressible in the form $ \forall y R( y, x _ {1} \dots x _ {n} ) $, | ||
where $ \forall $ | where $ \forall $ | ||
is the universal quantifier and the predicate $ R ( y , x _ {1} \dots x _ {n} ) $ | is the universal quantifier and the predicate $ R ( y , x _ {1} \dots x _ {n} ) $ | ||
− | belongs to the class $ \Sigma _ {k-} | + | belongs to the class $ \Sigma _ {k-1}$. |
In this way a double sequence of classes is obtained: | In this way a double sequence of classes is obtained: | ||
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i.e. $ \Sigma _ {1} \cap \Pi _ {1} = \Sigma _ {0} = \Pi _ {0} $. | i.e. $ \Sigma _ {1} \cap \Pi _ {1} = \Sigma _ {0} = \Pi _ {0} $. | ||
If $ k > 0 $, | If $ k > 0 $, | ||
− | then $ ( \Sigma _ {k+} | + | then $ ( \Sigma _ {k+1} \cap \Pi _ {k+1} ) \setminus ( \Sigma _ {k} \cup \Pi _ {k} ) \neq \emptyset $. |
The classification of sets defined in the language of formal arithmetic is based on the classification of predicates: A set $ M $ | The classification of sets defined in the language of formal arithmetic is based on the classification of predicates: A set $ M $ | ||
− | belongs to $ \Pi _ {k} $( | + | belongs to $ \Pi _ {k} $ (or $ \Sigma _ {k} $) |
− | or $ \Sigma _ {k} $) | + | if the predicate "$x \in M$" belongs to this class. |
− | if the predicate "x M" belongs to this class. | ||
====References==== | ====References==== | ||
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====Comments==== | ====Comments==== | ||
− | $ \Pi _ {j} \cap \Sigma _ {j} $ | + | $ \Pi _ {j} \cap \Sigma _ {j} $ is commonly denoted by $ \Delta _ {j} $. |
− | is commonly denoted by $ \Delta _ {j} $. | ||
One usually speaks of the arithmetical hierarchy (rather than the Kleene–Mostowski classification). | One usually speaks of the arithmetical hierarchy (rather than the Kleene–Mostowski classification). | ||
====References==== | ====References==== | ||
<table><TR><TD valign="top">[a1]</TD> <TD valign="top"> H.B. Enderton, "Elements of recursion theory" J. Barwise (ed.) , ''Handbook of mathematical logic'' , North-Holland (1977) pp. 527–566</TD></TR></table> | <table><TR><TD valign="top">[a1]</TD> <TD valign="top"> H.B. Enderton, "Elements of recursion theory" J. Barwise (ed.) , ''Handbook of mathematical logic'' , North-Holland (1977) pp. 527–566</TD></TR></table> |
Latest revision as of 15:41, 22 June 2020
A classification of number-theoretic predicates, introduced independently by S.C. Kleene [1] and A. Mostowski [2]. The class of all recursive predicates is denoted simultaneously by $ \Pi _ {0} $
and $ \Sigma _ {0} $.
For each $ k > 0 $
the class $ \Sigma _ {k} $
is defined as the class of all predicates expressible in the form $ \exists y R ( y , x _ {1} \dots x _ {n} ) $,
where $ \exists $
is the existential quantifier and $ R( y , x _ {1} \dots x _ {n} ) $
is a predicate in the class $ \Pi _ {k-1}$,
while the class $ \Pi _ {k} $
is defined as the class of predicates expressible in the form $ \forall y R( y, x _ {1} \dots x _ {n} ) $,
where $ \forall $
is the universal quantifier and the predicate $ R ( y , x _ {1} \dots x _ {n} ) $
belongs to the class $ \Sigma _ {k-1}$.
In this way a double sequence of classes is obtained:
$$ \Sigma _ {0} = \Pi _ {0} \ \begin{array}{cccc} \Sigma _ {1} &\Sigma _ {2} &\Sigma _ {3} &\dots \\ \Pi _ {1} &\Pi _ {2} &\Pi _ {3} &\dots \\ \end{array} . $$
If a predicate belongs to $ \Sigma _ {k} $ or $ \Pi _ {k} $, then it belongs to the classes $ \Pi _ {j} $ and $ \Sigma _ {j} $ for any $ j > k $, that is, $ \Sigma _ {k} \subseteq \Sigma _ {j} \cap \Pi _ {j} $ and $ \Pi _ {k} \subseteq \Sigma _ {j} \cap \Pi _ {j} $ for any $ j > k $. If $ k > 0 $, then there exist predicates in $ \Sigma _ {k} $ not belonging to $ \Pi _ {k} $ and also predicates in $ \Pi _ {k} $ not belonging to $ \Sigma _ {k} $, that is, $ \Sigma _ {k} \setminus \Pi _ {k} \neq \emptyset $ and $ \Pi _ {k} \setminus \Sigma _ {k} \neq \emptyset $. A predicate belongs to one of the classes $ \Sigma _ {k} $ or $ \Pi _ {k} $ if and only if it is expressible in the language of formal arithmetic (cf. Arithmetic, formal). If a predicate $ Q ( x _ {1} \dots x _ {n} ) $ belongs to $ \Sigma _ {k} $( or $ \Pi _ {k} $) then $ \neg Q ( x _ {1} \dots x _ {n} ) $, where $ \neg $ is the negation sign, belongs to $ \Pi _ {k} $( respectively, $ \Sigma _ {k} $). A predicate $ Q ( x _ {1} \dots x _ {n} ) $ is recursive (cf. Recursive predicate) if and only if $ Q ( x _ {1} \dots x _ {n} ) $ and $ \neg Q ( x _ {1} \dots x _ {n} ) $ belong to $ \Sigma _ {1} $, i.e. $ \Sigma _ {1} \cap \Pi _ {1} = \Sigma _ {0} = \Pi _ {0} $. If $ k > 0 $, then $ ( \Sigma _ {k+1} \cap \Pi _ {k+1} ) \setminus ( \Sigma _ {k} \cup \Pi _ {k} ) \neq \emptyset $.
The classification of sets defined in the language of formal arithmetic is based on the classification of predicates: A set $ M $ belongs to $ \Pi _ {k} $ (or $ \Sigma _ {k} $) if the predicate "$x \in M$" belongs to this class.
References
[1] | S.C. Kleene, "Recursive predicates and quantifiers" Trans. Amer. Math. Soc. , 53 (1943) pp. 41–73 |
[2] | A. Mostowski, "On definable sets of positive integers" Fund. Math. , 34 (1947) pp. 81–112 |
Comments
$ \Pi _ {j} \cap \Sigma _ {j} $ is commonly denoted by $ \Delta _ {j} $. One usually speaks of the arithmetical hierarchy (rather than the Kleene–Mostowski classification).
References
[a1] | H.B. Enderton, "Elements of recursion theory" J. Barwise (ed.) , Handbook of mathematical logic , North-Holland (1977) pp. 527–566 |
Kleene-Mostowski classification. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Kleene-Mostowski_classification&oldid=49804