Realizability

Example: realizability by numbers

Kleene's original version of realizability uses natural numbers as realizers for formulas in Heyting arithmetic. The following clauses are used to define a relation "n realizes A" between natural numbers n and formulas A in the language of Heyting arithmetic. A few pieces of notation are required: first, an ordered pair (n,m) is treated as a single number using a fixed effective pairing function; second, for each natural number n, φ_n is the computable function with index n.

A number n realizes an atomic formula s=t if and only if s=t is true. Thus every number realizes a true equation, and no number realizes a false equation.

A pair (n,m) realizes a formula A∧B if and only if n realizes A and m realizes B. Thus a realizer for a conjunction is a pair of realizers for the conjuncts.

A pair (n,m) realizes a formula A∨B if and only if the following hold: n is 0 or 1; and if n is 0 then m realizes A; and if n is 1 then m realizes B. Thus a realizer for a disjunction explicitly picks one of the disjuncts (with n) and provides a realizer for it (with m).

A number n realizes a formula A→B if and only if, for every m that realizes A, φ_n(m) realizes B. Thus a realizer for an implication is a computable function that takes a realizer for the hypothesis and produces a realizer for the conclusion.

A pair (n,m) realizes a formula (∃ x)A(x) if and only if m is a realizer for A(n). Thus a realizer for an existential formula produces an explicit witness for the quantifier along with a realizer for the formula instantiated with that witness.

A number n realizes a formula (∀ x)A(x) if and only if, for all m, φ_n(m) is defined and realizes A(m). Thus a realizer for a universal statement is a computable function that produces, for each m, a witness for the formula instantiated with m.

With this definition, the following theorem is obtained:

Let A be a sentence of Heyting arithmetic (HA). If HA proves A then there is an n such that n realizes A.

On the other hand, there are formulas that are realized but which are not provable in HA, a fact first established by Rose.

Further analysis of the method can be used to prove that HA has the "disjunction and existence properties":

If HA proves a sentence (∃ x)A(x), then there is an n such that HA proves A(n)

If HA proves a sentence A∨B, then HA proves A or HA proves B.

Later developments

Kreisel introduced modified realizability, which uses typed lambda calculus as the language of realizers. Modified realizability is one way to show that Markov's principle is not derivable in intuitionistic logic. On the contrary, it allows to constructively justify the principle of independence of premiss:

( A → ∃ x P ( x ) ) → ∃ x ( A → P ( x ) ) .

Relative realizability is an intuitionist analysis of recursive or recursively enumerable elements of data structures that are not necessarily computable, such as computable operations on all real numbers when reals can be only approximated on digital computer systems.

Applications

Realizability is one of the methods used in proof mining to extract concrete "programs" from seemingly nonconstructive mathematical proof. Program extraction using realizability is implemented in some proof assistants such as Coq.