User:IssaRice/Computability and logic/Eliezer Yudkowsky's Löb's theorem puzzle: Difference between revisions

Revision as of 03:26, 10 February 2019

original link: https://web.archive.org/web/20160319050228/http://lesswrong.com/lw/t6/the_cartoon_guide_to_l%C3%B6bs_theorem/

current LW link: https://www.lesswrong.com/posts/ALCnqX6Xx8bpFMZq3/the-cartoon-guide-to-loeb-s-theorem

Translating the puzzle using logic notation

Löb's theorem shows that if ${\mathsf {PA}}\vdash \Box C\to C$ , then ${\mathsf {PA}}\vdash C$ .

The deduction theorem says that if ${\mathsf {PA}}\cup \{H\}\vdash F$ , then ${\mathsf {PA}}\vdash H\to F$ .

Applying the deduction theorem to Löb's theorem gives us ${\mathsf {PA}}\vdash (\Box C\to C)\to C$ .

When translating to logic notation, it becomes obvious that the application of the deduction theorem is illegitimate, because we don't actually have ${\mathsf {PA}}\cup \{\Box C\to C\}\vdash C$ . This is the initial answer that Larry D'Anna gives in comments.

But now, suppose we define ${\mathsf {PA}}':={\mathsf {PA}}\cup \{\Box C\to C\}\vdash C$ , and walk through the proof of Löb's theorem for this new theory ${\mathsf {PA}}'$ . Then we would obtain the following implication: if ${\mathsf {PA}}'\vdash \Box C\to C$ , then ${\mathsf {PA}}'\vdash C$ . But clearly, ${\mathsf {PA}}'\vdash \Box C\to C$ since $\Box C\to C$ is one of the axioms of ${\mathsf {PA}}'$ . Therefore by modus ponens, we have ${\mathsf {PA}}'\vdash C$ , i.e. ${\mathsf {PA}}\cup \{\Box C\to C\}\vdash C$ . Now we can apply the deduction theorem to obtain ${\mathsf {PA}}\vdash (\Box C\to C)\to C$ .

Translating the Löb's theorem back to logic

http://yudkowsky.net/assets/44/LobsTheorem.pdf

Since the solution to the puzzle refers back to the proof of Löb's theorem, we first translate the proof from the cartoon version back to logic:

${\mathsf {PA}}\vdash \Box L\leftrightarrow \Box (\Box L\to C)$
${\mathsf {PA}}\vdash \Box C\to C$
${\mathsf {PA}}\vdash \Box (\Box L\to C)\to (\Box \Box L\to \Box C)$
${\mathsf {PA}}\vdash \Box L\to (\Box \Box L\to \Box C)$
${\mathsf {PA}}\vdash \Box L\to \Box \Box L$
${\mathsf {PA}}\vdash \Box L\to \Box C$
${\mathsf {PA}}\vdash \Box L\to C$
${\mathsf {PA}}\vdash \Box (\Box L\to C)$
${\mathsf {PA}}\vdash \Box L$
${\mathsf {PA}}\vdash C$

@@ Line 12: / Line 12: @@
 When translating to logic notation, it becomes obvious that the application of the deduction theorem is illegitimate, because we don't actually have <math>\mathsf{PA} \cup \{\Box C \to C\} \vdash C</math>. This is the initial answer that Larry D'Anna gives in comments.
+But now, suppose we define <math>\mathsf{PA}' := \mathsf{PA} \cup \{\Box C \to C\} \vdash C</math>, and walk through the proof of Löb's theorem for this new theory <math>\mathsf{PA}'</math>. Then we would obtain the following implication: if <math>\mathsf{PA}' \vdash \Box C \to C</math>, then <math>\mathsf{PA}' \vdash C</math>. But clearly, <math>\mathsf{PA}' \vdash \Box C \to C</math> since <math>\Box C \to C</math> is one of the axioms of <math>\mathsf{PA}'</math>. Therefore by modus ponens, we have <math>\mathsf{PA}' \vdash C</math>, i.e. <math>\mathsf{PA}\cup\{\Box C \to C\} \vdash C</math>. Now we can apply the deduction theorem to obtain <math>\mathsf{PA} \vdash (\Box C \to C) \to C</math>.
 ==Translating the Löb's theorem back to logic==