Alpha recursion theory

In recursion theory, α recursion theory is a generalisation of recursion theory to subsets of admissible ordinals $\alpha$ . An admissible set is closed under $\Sigma _{1}(L_{\alpha })$ functions, where $L_{\xi }$ denotes a rank of Godel's constructible hierarchy. $\alpha$ is an admissible ordinal if $L_{\alpha }$ is a model of Kripke–Platek set theory. In what follows $\alpha$ is considered to be fixed.

The objects of study in $\alpha$ recursion are subsets of $\alpha$ . These sets are said to have some properties:

A set $A\subseteq \alpha$ is said to be $\alpha$ -recursively-enumerable if it is $\Sigma _{1}$ definable over $L_{\alpha }$ , possibly with parameters from $L_{\alpha }$ in the definition.^[1]
A is $\alpha$ -recursive if both A and $\alpha \setminus A$ (its relative complement in $\alpha$ ) are $\alpha$ -recursively-enumerable. It's of note that $\alpha$ -recursive sets are members of $L_{\alpha +1}$ by definition of $L$ .
Members of $L_{\alpha }$ are called $\alpha$ -finite and play a similar role to the finite numbers in classical recursion theory.

There are also some similar definitions for functions mapping $\alpha$ to $\alpha$ :^[2]

A function mapping $\alpha$ to $\alpha$ is $\alpha$ -recursively-enumerable iff its graph is $\Sigma _{1}$ -definable in $(L_{\alpha },\in )$ .
A function mapping $\alpha$ to $\alpha$ is $\alpha$ -recursive iff its graph is $\Delta _{1}$ -definable in $(L_{\alpha },\in )$ .
Additionally, a function mapping $\alpha$ to $\alpha$ is $\alpha$ -arithmetical iff there exists some $n\in \omega$ such that the function's graph is $\Sigma _{n}$ -definable in $(L_{\alpha },\in )$ .

Additional connections between recursion theory and α recursion theory can be drawn, although explicit definitions may not have yet been written to formalize them:

The functions $\Delta _{0}$ -definable in $(L_{\alpha },\in )$ play a role similar to those of the primitive recursive functions.^[2]

We say R is a reduction procedure if it is $\alpha$ 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-recursive in B if there exist $R_{0},R_{1}$ reduction procedures such that:

K\subseteq A\leftrightarrow \exists H:\exists J:[\langle H,J,K\rangle \in R_{0}\wedge H\subseteq B\wedge J\subseteq \alpha /B],

K\subseteq \alpha /A\leftrightarrow \exists H:\exists J:[\langle H,J,K\rangle \in R_{1}\wedge H\subseteq B\wedge J\subseteq \alpha /B].

If A is recursive in B this is written $\scriptstyle A\leq _{\alpha }B$ . By this definition A is recursive in $\scriptstyle \varnothing$ (the empty set) if and only if A is recursive. However A being recursive in B is not equivalent to A being $\Sigma _{1}(L_{\alpha }[B])$ .

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.

Results in α recursion

Shore's splitting theorem: Let A be $\alpha$ recursively enumerable and regular. There exist $\alpha$ recursively enumerable $B_{0},B_{1}$ such that $A=B_{0}\cup B_{1}\wedge B_{0}\cap B_{1}=\varnothing \wedge A\not \leq _{\alpha }B_{i}(i<2).$

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 $\scriptstyle A<_{\alpha }B<_{\alpha }C$ .

Barwise has proved that the sets $\Sigma _{1}$ -definable on $L_{\alpha ^{+}}$ are exactly the sets $\Pi _{1}^{1}$ -definable on $L_{\alpha }$ , where $\alpha ^{+}$ denotes the next admissible ordinal above $\alpha$ , and $\Sigma$ is from the Levy hierarchy.^[3]

Relationship to analysis

Some results in $\alpha$ -recursion can be translated into similar results about second-order arithmetic. This is because of the relationship $L$ has with the ramified analytic hierarchy, an analog of $L$ for the language of second-order arithmetic, that consists of sets of integers.^[4]

In fact, when dealing with first-order logic only, the correspondence can be close enough that for some results on $L_{\omega }={\textrm {HF}}$ , the arithmetical and Levy hierarchies can become interchangeable. For example, a set of natural numbers is definable by a $\Sigma _{1}^{0}$ formula iff it's $\Sigma _{1}$ -definable on $L_{\omega }$ , where $\Sigma _{1}$ is a level of the Levy hierarchy.^[5]

References

Gerald Sacks, Higher recursion theory, Springer Verlag, 1990 https://projecteuclid.org/euclid.pl/1235422631
Robert Soare, Recursively Enumerable Sets and Degrees, Springer Verlag, 1987 https://projecteuclid.org/euclid.bams/1183541465
Keith J. Devlin, An introduction to the fine structure of the constructible hierarchy (p.38), North-Holland Publishing, 1974
J. Barwise, Admissible Sets and Structures. 1975

Inline references

^ P. Koepke, B. Seyfferth, Ordinal machines and admissible recursion theory (preprint) (2009, p.315). Accessed October 12, 2021
^ ^a ^b Srebrny, Marian, Relatively constructible transitive models (1975, p.165). Accessed 21 October 2021.
^ T. Arai, Proof theory for theories of ordinals - I: recursively Mahlo ordinals (1998). p.2
^ P. D. Welch, The Ramified Analytical Hierarchy using Extended Logics (2018, p.4). Accessed 8 August 2021.
^ G. E. Sacks, Higher Recursion Theory (p.152). "Perspectives in Logic", Association for Symbolic Logic.

[1] P. Koepke, B. Seyfferth, Ordinal machines and admissible recursion theory (preprint) (2009, p.315). Accessed October 12, 2021

[relconstr-2] Srebrny, Marian, Relatively constructible transitive models (1975, p.165). Accessed 21 October 2021.

[3] T. Arai, Proof theory for theories of ordinals - I: recursively Mahlo ordinals (1998). p.2

[4] P. D. Welch, The Ramified Analytical Hierarchy using Extended Logics (2018, p.4). Accessed 8 August 2021.

[5] G. E. Sacks, Higher Recursion Theory (p.152). "Perspectives in Logic", Association for Symbolic Logic.

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