Rosser's trick
In mathematical logic, Rosser's trick is a method for proving Gödel's incompleteness theorems without the assumption that the theory being considered is ω-consistent (Smorynski 1977, p. 840; Mendelson 1977, p. 160). This method was introduced by J. Barkley Rosser in 1936, as an improvement of Gödel's original proof of the incompleteness theorems that was published in 1931.
- For the theorem about the sparseness of prime numbers, see Rosser's theorem. For a general introduction to the incompleteness theorems, see Gödel's incompleteness theorems.
While Gödel's original proof uses a sentence that says (informally) "This sentence is not provable", Rosser's trick uses a formula that says "If this sentence is provable, there is a shorter proof of its negation".
Background
Rosser's trick begins with the assumptions of Gödel's incompleteness theorem. A theory T is selected which is effective, consistent, and includes a sufficient fragment of elementary arithmetic.
Gödel's proof shows that for any such theory there is a formula ProofT(x,y) which has the intended meaning that y is a natural number code (a Gödel number) for a formula and x is the Gödel number for a proof, from the axioms of T, of the formula encoded by y. (In the remainder of this article, no distinction is made between the number y and the formula encoded by y, and the number coding a formula φ is denoted #φ). Furthermore, the formula PvblT(y) is defined as ∃x ProofT(x,y). It is intended to define the set of formulas provable from T.
The assumptions on T also show that it is able to define a negation function neg(y), with the property that if y is a code for a formula φ then neg(y) is a code for the formula ¬φ. The negation function may take any value whatsoever for inputs that are not codes of formulas.
The Gödel sentence of the theoryT is a formula φ, sometimes denoted GT such that T proves φ ↔ ¬PvblT(#φ). Gödel's proof shows that if T is consistent then it cannot prove its Gödel sentence; but in order to show that the negation of the Gödel sentence is also not provable, it is necessary to add a stronger assumption that the theory is ω-consistent, not merely consistent. For example, the theory T=PA+¬GPA proves ¬GT. Rosser (1936) constructed a different self-referential sentence that can be used to replace the Gödel sentence in Gödel's proof, removing the need to assume ω-consistency.
The Rosser sentence
For a fixed arithmetical theory T, let ProofT(x,y) and neg(x) be the associated proof predicate and negation function.
A modified proof predicate ProofRT(x,y) is defined as:
which means that
This modified proof predicate is used to define a modified provability predicate PvblRT(y):
Informally, PvblRT(y) is the claim that y is provable via some coded proof x such that there is no smaller coded proof of the negation of y. Under the assumption that T is consistent, for each formula φ the formula PvblRT(#φ) will hold if and only if PvblT(#φ) holds, because if there is a code for the proof of φ, then (follwoing the consistency of T) there is no code for the proof of ¬φ. However, PvblT and PvblRT have different properties from the point of view of provability in T.
An immediate consequence of the definition is that if T includes enough arithmetic, then it can prove that for every formula φ, PvblRT(φ) implies ¬PvblRT(neg(φ)). This is because otherwise, there are two numbers n,m, coding for the proofs of φ and ¬φ, respectively, satisfying both n<m and m<n. (In fact T only needs to prove that such a situation cannot hold for any two numbers, as well as to include some first-order logic)
Using the diagonal lemma, let ρ be a formula such that T proves ρ ↔ ¬ PvblRT(#ρ). The formula ρ is the Rosser sentence of the theory T.
Rosser's theorem
Let T be an effective, consistent theory including a sufficient amount of arithmetic, with Rosser sentence ρ. Then the following hold (Mendelson 1977, p. 160):
- T does not prove ρ
- T does not prove ¬ρ.
In order to prove this, one first shows that for a formula y and a number e, if ProofRT(e,y) holds, then T proves ProofRT(e,y). This is shown in a similar manner to what is done in Gödel's proof of the first incompleteness theorem: T proves ProofT(e,y), a relation between two concrete natural numbers; one then goes over all the natural numbers z smaller than e one by one, and for each z, T proves ¬ProofT(z,neg(y)), again, a relation between two concrete numbers.
The assumption that T includes enough arithmetic (in fact, what is required is basic first-order logic) ensures that T also proves PvblRT(y) in that case.
Furthermore, if T is consistent and proves φ, then there is a number e coding for its proof in T, and there is no number coding for the proof of the negation of φ in T. Therefore ProofRT(e,y) holds, and thus T proves PvblRT(#φ).
The proof of (1) is similar to that in Gödel's proof of the first incompleteness theorem: Assume T proves ρ; then it follows, by the previous elaboration, that T proves PvblRT(#ρ). Thus T also proves ¬ρ. But we assumed T proves ρ, and this is impossible if T is consistent. We are forced to conclude that T does not prove ρ.
The proof of (2) also uses the particular form of ProofRT. Assume T proves ¬ρ; then it follows, by the previous elaboration, that T proves PvblRT(neg(#ρ)). But by the immedeate consequence of the definition of Rosser's provability predicate, mentioned in the previous section, it follows that T proves ¬PvblRT(#ρ). Thus T also proves ρ. But we assumed T proves ¬ρ, and this is impossible if T is consistent. We are forced to conclude that T does not prove ¬ρ.
References
- Mendelson (1977), Introduction to Mathematical Logic
- Smorynski (1977), "The incompleteness theorems", in Handbook of Mathematical Logic, Jon Barwise, Ed., North Holland, 1982, ISBN 0-444-86388-5
- Rosser (1936), "Extensions of some theorems of Gödel and Church", Journal of Symbolic Logic, v. 1, pp. 87–91.
External links
- Avigad (2007), "Computability and Incompleteness", lecture notes.