nLab double negation translation

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Contents

Idea
Construction

Propositional case

Glivenko’s Theorem

First-order case
Higher-order case

References

Idea

Double negation translation is a method for converting propositions valid in classical logic into propositions valid in intuitionistic logic. It can be used to establish relative consistency results. For example, it may be possible to show that the proof of a contradiction in a classical theory could be translated to the proof of a contradiction in a constructive theory. Kurt Gödel used this technique to show that Peano arithmetic and Heyting arithmetic are equiconsistent.

Double negation translation was discovered independently by a number of mathematicians including Kurt Gödel, Gerhard Gentzen, and Andrey Kolmogorov, and is also called the Gödel–Gentzen negative translation.

Construction

The traditional descriptions are highly syntactic, but can be motivated by recalling some conceptual relationships between Boolean algebras (which are algebras for classical propositional logic) and Heyting algebras (which are algebras for intuitionistic propositional logic).

Propositional case

Recall from the article Heyting algebra that the left adjoint $F$ to the forgetful functor

U \colon Bool \to Heyt

is given objectwise by taking a Heyting algebra $L$ to the poset $L_{\neg\neg}$ of regular elements $x \in L$ , i.e., those that are fixed by double negation: $x = \neg \neg x$ . It was shown that $L_{\neg\neg}$ is a Boolean algebra, and $\neg \neg \colon L \to L_{\neg\neg}$ is a Heyting algebra homomorphism which is universal among Heyting algebra maps $L \to U B$ into Boolean algebras.

In particular, if $Heyt(S)$ is the free Heyting algebra on a set of variables $S$ , it follows by composing left adjoints

Set \stackrel{free}{\to} Heyt \stackrel{F}{\to} Bool

that $Heyt(S)_{\neg\neg}$ is the free Boolean algebra on $S$ .

Furthermore, it was shown in Heyting algebra that for Heyting algebras $L$ ,

$\neg\neg \colon L \to L$ preserves finite meets;
$\neg\neg \colon L \to L$ preserves the implication operation $\Rightarrow$ .

Consequently, the inclusion of regular elements $L_{\neg\neg} \to L$ also preserves meets and implications, strictly. This gives the following result.

Glivenko’s Theorem

If $p \Rightarrow q$ is a tautology in classical propositional logic, then $(\neg \neg p) \Rightarrow (\neg \neg q)$ is a tautology in intuitionistic propositional logic, and conversely.

Proof

Here $p$ and $q$ are term expressions in variables $x_i \in S$ over the signature $(0, 1, \vee, \wedge, \Rightarrow)$ . To say $p \Rightarrow q$ is a classical tautology means that $1 \leq (p \Rightarrow q)$ holds when interpreted in $Bool(S)$ . But since $Bool(S) = Heyt(S)_{\neg\neg}$ , this is equivalent to saying that

1 \leq \neg\neg(p \Rightarrow q) = (\neg\neg p) \Rightarrow (\neg\neg q)

when interpreted in $Heyt(S)$ , which is to say that $(\neg \neg p) \Rightarrow (\neg\neg q)$ is an intuitionistic tautology.

Continuing this thought: the join $\vee$ in $Bool(S) = Heyt_{\neg\neg}$ is computed as

a \vee_{Bool} b = \neg\neg(a \vee_{Heyt} b)

since $\neg\neg \colon Heyt(S) \to Heyt(S)_{\neg\neg}$ preserves joins (it is a left adjoint). Putting all this together, because $\neg\neg \colon Heyt(S) \to Heyt(S)_{\neg\neg}$ preserves Heyting algebra structure, we arrive at the following syntactic translation.

Definition

The double-negation translation $p \mapsto p^{N}$ on term expressions in the theory of Heyting algebras $L$ is defined by induction as follows.

$x^N = \neg\neg x$ for variables $x$ .
$0^N = 0$ (since $\neg\neg \colon L \to L$ preserves $0$ )
$1^N = 1$ (since $\neg\neg \colon L \to L$ preserves $1$ )
$(p \wedge q)^N = p^N \wedge q^N$ (since $\neg\neg \colon L \to L$ preserves the meet operation)
$(p \Rightarrow q)^N = p^N \Rightarrow q^N$ (since $\neg\neg \colon L \to L$ preserves the implication operation)
$(p \vee q)^N = \neg\neg(p^N \vee q^N)$ .

Thus, by Glivenko’s theorem, $p$ is a classical tautology if and only if $p^N$ is an intuitionistic tautology. This result may be extended to theories as well: suppose $L$ is an intuitionistic theory or Heyting algebra, given by a presentation as a coequalizer in $Heyt$ :

Heyt(T) \stackrel{\to}{\to} Heyt(S) \to L.

Then, since the functor $L \mapsto L_{\neg\neg}$ is a left adjoint, it takes this coequalizer to a coequalizer

Bool(T) \stackrel{\to}{\to} Bool(S) \to L_{\neg\neg}

so that an term expression $p$ is a theorem in the classical theory $L_{\neg\neg}$ if and only if $p^N$ is a theorem in the intuitionistic theory $L$ .

First-order case

Double negation translation for a formula, $\phi$ , of a first-order language is defined inductively by the following clauses:

$\phi^N = \neg \neg \phi$ , for atomic $\phi$ .
$(\phi \wedge \psi)^N = \phi^N \wedge \psi^N$ .
$(\phi \vee \psi)^N = \neg(\neg \phi^N \wedge \neg \psi^N)$ (or equivalently, $\neg \neg (\phi^N \vee \psi^N)$ )
$(\phi \to \psi)^N = \phi^N \to \psi^N$ .
$(\neg \phi)^N = \neg \phi^N$ .
$(\forall x \phi)^N = \forall x \phi^N$ .
$(\exists x \phi)^N = \neg \forall x \neg \phi^N$ (or equivalently, $\neg \neg \exists x \phi^N$ ).

Higher-order case

The basic idea here is that any topos $E$ gives rise to a Boolean topos $E_{\neg\neg}$ .

References

Informal exposition of a tiny aspect of this double negation business is in

Andrej Bauer, Intuitionistic mathematics for physics, 2008

Last revised on May 10, 2017 at 08:09:12. See the history of this page for a list of all contributions to it.