Computable set

In computability theory, a set of natural numbers is computable (or decidable or recursive) if there is an algorithm that computes the membership of every natural number in a finite number of steps. A set is noncomputable (or undecidable) if it is not computable.

Definition

A subset $S$ of the natural numbers is computable if there exists a total computable function $f$ such that:

f(x)=1

if

x\in S

f(x)=0

if

x\notin S

.

In other words, the set $S$ is computable if and only if the indicator function $\mathbb {1} _{S}$ is computable.

Examples

Every recursive language is computable.
Every finite or cofinite subset of the natural numbers is computable.
- The empty set is computable.
- The entire set of natural numbers is computable.
- Every natural number is computable.^{[note 1]}
The subset of prime numbers is computable.
The set of Gödel numbers is computable.^{[note 2]}

Non-examples

The set of Turing machines that halt is not computable.
The set of pairs of homeomorphic finite simplicial complexes is not computable.^[1]
The set of busy beaver champions is not computable.
Hilbert's tenth problem is not computable.

Properties

Both A, B are sets in this section.

If A is computable then the complement of A is computable.
If A and B are computable then:
- A ∩ B is computable.
- A ∪ B is computable.
- The image of A × B under the Cantor pairing function is computable.

In general, the image of a computable set under a computable function is computably enumerable, but possibly not computable.

A is computable if and only if A and the complement of A are both computably enumerable(c.e.).
The preimage of a computable set under a total computable function is computable.
The image of a computable set under a total computable bijection is computable.

A is computable if and only if it is at level $\Delta _{1}^{0}$ of the arithmetical hierarchy.

A is computable if and only if it is either the image (or range) of a nondecreasing total computable function, or the empty set.

Notes

↑ That is, under the Set-theoretic definition of natural numbers, the set of natural numbers less than a given natural number is computable.
↑ c.f. Gödel's incompleteness theorems; "On formally undecidable propositions of Principia Mathematica and related systems I" by Kurt Gödel.

References

↑ Markov, A. (1958). "The insolubility of the problem of homeomorphy". Doklady Akademii Nauk SSSR. 121: 218–220. MR 0097793.

Bibliography

Cutland, N. Computability. Cambridge University Press, Cambridge-New York, 1980. ISBN 0-521-22384-9; ISBN 0-521-29465-7
Rogers, H. The Theory of Recursive Functions and Effective Computability, MIT Press. ISBN 0-262-68052-1; ISBN 0-07-053522-1
Soare, R. Recursively enumerable sets and degrees. Perspectives in Mathematical Logic. Springer-Verlag, Berlin, 1987. ISBN 3-540-15299-7

External links

Sakharov, Alex. "Recursive Set". MathWorld.

[set-natural-number-1] That is, under the Set-theoretic definition of natural numbers, the set of natural numbers less than a given natural number is computable.

[Gödel-numbers-2] .f. Gödel's incompleteness theorems; "On formally undecidable propositions of Principia Mathematica and related systems I" by Kurt Gödel.

[3] Markov, A. (1958). "The insolubility of the problem of homeomorphy". Doklady Akademii Nauk SSSR. 121: 218–220. MR 0097793.

[note 1]

[note 2]

[1]