some theorem schemas of normal modal logic

1. 1.

   From tautologies $A\wedge B\to A$ and $A\wedge B\to B$ and meta-theorem 1, we get $⊢\mathrm{\square }(A\wedge B)\to \mathrm{\square }A$ and $⊢\mathrm{\square }(A\wedge B)\to \mathrm{\square }B$. So $⊢\mathrm{\square }(A\wedge B)\to \mathrm{\square }A\wedge \mathrm{\square }B$.

2. 2.

   From tautology $A\to (B\to (A\wedge B))$ and meta-theorem 1, we get

   $$⊢\mathrm{\square }A\to \mathrm{\square }(B\to (A\wedge B)).$$

   From the K instance

   $$\mathrm{\square }(B\to (A\wedge B))\to (\mathrm{\square }B\to \mathrm{\square }(A\wedge B))$$

   and the tautology

   $$(p\to q)\to ((q\to (r\to s))\to ((p\wedge r)\to s))$$

   substituting $p$ for $\mathrm{\square }A$, $q$ for $\mathrm{\square }(B\to (A\wedge B))$, $r$ for $\mathrm{\square }B$, and $s$ for $\mathrm{\square }(A\wedge B)$, and applying modus ponens twice, we get the result.

3. 3.

   From the tautology $\mathrm{\neg }⟂$, we have the result by necessitation.

4. 4.

   All we need is $⊢\mathrm{\square }A\to \mathrm{\neg }\diamond \mathrm{\neg }A$. From tautology $A\to \mathrm{\neg }\mathrm{\neg }A$, we get $⊢\mathrm{\square }A\to \mathrm{\square }\mathrm{\neg }\mathrm{\neg }A$ by meta-theorem 1. From tautology $\mathrm{\square }\mathrm{\neg }\mathrm{\neg }A\to \mathrm{\neg }\mathrm{\neg }\mathrm{\square }\mathrm{\neg }\mathrm{\neg }A$ and the definition of $\diamond$, we get $⊢\mathrm{\square }A\to \mathrm{\neg }\diamond \mathrm{\neg }A$.

5. 5.

   To show $\mathrm{\square }(A\to B)\to (\diamond A\to \diamond B)$, it is enough to show $\mathrm{\square }(A\to B)\to (\mathrm{\square }\mathrm{\neg }A\vee \diamond B)$, which is enough to show $\mathrm{\square }(A\to B)\to (\mathrm{\square }\mathrm{\neg }B\to \mathrm{\square }\mathrm{\neg }A)$, which is enough to show $\mathrm{\square }(\mathrm{\neg }B\to \mathrm{\neg }A)\to (\mathrm{\square }\mathrm{\neg }B\to \mathrm{\square }\mathrm{\neg }A)$, which is just an instance of K.

6. 6.

   To show $\diamond (A\to B)\to (\mathrm{\square }A\to \diamond B)$, it is enough to show $\mathrm{\neg }\mathrm{\square }(A\wedge \mathrm{\neg }B)\to (\mathrm{\square }A\to \diamond B)$, which is enough to show $\mathrm{\neg }(\mathrm{\square }A\wedge \mathrm{\square }\mathrm{\neg }B)\to (\mathrm{\square }A\to \diamond B)$ by 1 and 2, which is enough to show $\mathrm{\neg }\mathrm{\square }A\vee \diamond B\to (\mathrm{\square }A\to \diamond B)$, which is just $(\mathrm{\square }A\to \diamond B)\to (\mathrm{\square }A\to \diamond B)$.

7. 7.

   To show $\diamond A\wedge \mathrm{\square }B\to \diamond (A\wedge B)$, it is enough to show $\mathrm{\neg }\mathrm{\square }\mathrm{\neg }A\wedge \mathrm{\square }B\to \diamond (A\wedge B)$, which is enough to show $\mathrm{\neg }(\mathrm{\neg }\mathrm{\square }B\vee \mathrm{\square }\mathrm{\neg }A)\to \diamond (A\wedge B)$, which is enough to show $\mathrm{\neg }(\mathrm{\square }B\to \mathrm{\square }\mathrm{\neg }A)\to \mathrm{\neg }\mathrm{\square }\mathrm{\neg }(A\wedge B)$, which is enough to show $\mathrm{\square }\mathrm{\neg }(A\wedge B)\to (\mathrm{\square }B\to \mathrm{\square }\mathrm{\neg }A)$, which is enough to show $\mathrm{\square }(\mathrm{\neg }A\vee \mathrm{\neg }B)\to (\mathrm{\square }B\to \mathrm{\square }\mathrm{\neg }A)$, which is enough to show $\mathrm{\square }(B\to \mathrm{\neg }A)\to (\mathrm{\square }B\to \mathrm{\square }\mathrm{\neg }A)$, which is an instance of K.

8. 8.

   Since $⊢A\to A\vee B$ and $B⊢A\vee B$, $\mathrm{\square }A\to \mathrm{\square }(A\vee B)$ and $\mathrm{\square }B\to \mathrm{\square }(A\vee B)$, and therefore $\mathrm{\square }A\vee \mathrm{\square }B\to \mathrm{\square }(A\vee B)$.

9. 9.

   By 8, $\mathrm{\square }\mathrm{\neg }A\vee \mathrm{\square }\mathrm{\neg }B\to \mathrm{\square }(\mathrm{\neg }A\vee \mathrm{\neg }B)$, so $\mathrm{\neg }\mathrm{\square }(\mathrm{\neg }A\vee \mathrm{\neg }B)\to \mathrm{\neg }(\mathrm{\square }\mathrm{\neg }A\vee \mathrm{\square }\mathrm{\neg }B)$, whence $\diamond (A\wedge B)\to \diamond A\wedge \diamond B$.

10. 10.

    To show $\mathrm{\square }(A\vee B)\to \mathrm{\square }A\vee \diamond B$, it is enough to show $\mathrm{\square }(\mathrm{\neg }B\to A)\to \mathrm{\square }A\vee \diamond B$, which is enough to show $\mathrm{\square }(\mathrm{\neg }B\to A)\to \mathrm{\neg }\mathrm{\square }\mathrm{\neg }B\vee \mathrm{\square }A$, or $\mathrm{\square }(\mathrm{\neg }B\to A)\to \mathrm{\square }\mathrm{\neg }B\to \mathrm{\square }A$, an instance of K.

11. 11.

    From $A\to A\vee B$ and $B\to A\vee B$, we get $\diamond A\to \diamond (A\vee B)$ and $\diamond B\to \diamond (A\vee B)$, so that $\diamond A\vee \diamond B\to \diamond (A\vee B)$. On the other hand, from $\mathrm{\square }\mathrm{\neg }A\wedge \mathrm{\square }\mathrm{\neg }B\to \mathrm{\square }(\mathrm{\neg }A\wedge \mathrm{\neg }B)$, we get $\mathrm{\neg }\mathrm{\square }(\mathrm{\neg }A\wedge \mathrm{\neg }B)\to \mathrm{\neg }(\mathrm{\square }\mathrm{\neg }A\wedge \mathrm{\square }\mathrm{\neg }B)$, or $\diamond (A\vee B)\to \diamond A\vee \diamond B$, and the result follows.

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