Alpha recursion theory

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In recursion theory, the mathematical theory of computability, alpha recursion (often written α recursion) is a generalisation of recursion theory to subsets of admissible ordinals $α$ . An admissible ordinal is closed under $Σ 1 (L α)$ functions. Admissible ordinals are models of Kripke–Platek set theory. In what follows $α$ is considered to be fixed.

The objects of study in $α$ recursion are subsets of $α$ . A is said to be $α$ recursively enumerable if it it is $Σ 1$ definable over $L α$ . A is recursive if both A and $α / A$ (its complement in $α$ ) are recursively enumerable.

Members of $L α$ are called $α$ finite and play a similar role to the finite numbers in classical recursion theory.

We say R is a reduction procedure if it is recursively enumerable and every member of R is of the form $\langle H,J,K\rangle$ where H, J, K are all α-finite.

A is said to be α-recusive in B if there exist $R 0, R 1$ reduction procedures such that:

$K \subseteq A \leftrightarrow \exists H: \exists J:[<H,J,K> \in R_0 \wedge H \subseteq B \wedge J \subseteq \alpha / B ],$

$K \subseteq \alpha / A \leftrightarrow \exists H: \exists J:[<H,J,K> \in R_1 \wedge H \subseteq B \wedge J \subseteq \alpha / B ].$

If A is recursive in B this is written $\scriptstyle A \le_\alpha B$ . By this definition A is recursive in $\scriptstyle\varnothing$ (the empty set) if and only if A is recursive. However it should be noted that A being recursive in B is not equivalent to A being $Σ 1 (L α [B])$ .

We say A is regular if $\forall \beta \in \alpha: A \cap \beta \in L_\alpha$ or in other words if every initial portion of A is α-finite.

[edit] Results in $α$ recursion

Shore's splitting theorem: Let A be $α$ recursively enumerable and regular. There exist $α$ recursively enumerable $B 0, B 1$ such that $A=B_0 \cup B_1 \wedge B_0 \cap B_1 = \varnothing \wedge A \not\le_\alpha B_i (i<2).$

Shore's density theorem: Let A, C be α-regular recursively enumerable sets such that $\scriptstyle A <_\alpha C$ then there exists a regular α-recursively enumerable set B such that $\scriptstyle A <_\alpha B <_\alpha C$ .

[edit] References

Gerald Sacks, Higher recursion theory, Springer Verlag, 1990
Robert Soare, Recursively Enumerable Sets and Degrees, Springer Verlag, 1987

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