Theorem iff_intror_imp ≪ | index | src | ≫

\iff右引入\imp

theorem iff_intror_imp (A B C: wff):
  $ (A \iff B) \imp (A \imp C \iff B \imp C) $;

Step	Hyp	Ref	Expression
1		iff_comp	((A \imp C) \imp B \imp C) \imp ((B \imp C) \imp A \imp C) \imp (A \imp C \iff B \imp C)
2	1	_hyp_null_complete	(A \iff B) \imp ((A \imp C) \imp B \imp C) \imp ((B \imp C) \imp A \imp C) \imp (A \imp C \iff B \imp C)
3		imp_introrevr_imp	(B \imp A) \imp (A \imp C) \imp B \imp C
4	3	_hyp_null_complete	(A \iff B) \imp (B \imp A) \imp (A \imp C) \imp B \imp C
5		iff_decompbwd	(A \iff B) \imp B \imp A
6	5	_hyp_null_complete	(A \iff B) \imp (A \iff B) \imp B \imp A
7		_hyp_null_intro	(A \iff B) \imp (A \iff B)
8	6, 7	_hyp_mp	(A \iff B) \imp B \imp A
9	4, 8	_hyp_mp	(A \iff B) \imp (A \imp C) \imp B \imp C
10	2, 9	_hyp_mp	(A \iff B) \imp ((B \imp C) \imp A \imp C) \imp (A \imp C \iff B \imp C)
11		imp_introrevr_imp	(A \imp B) \imp (B \imp C) \imp A \imp C
12	11	_hyp_null_complete	(A \iff B) \imp (A \imp B) \imp (B \imp C) \imp A \imp C
13		iff_decomp	(A \iff B) \imp A \imp B
14	13	_hyp_null_complete	(A \iff B) \imp (A \iff B) \imp A \imp B
15	14, 7	_hyp_mp	(A \iff B) \imp A \imp B
16	12, 15	_hyp_mp	(A \iff B) \imp (B \imp C) \imp A \imp C
17	10, 16	_hyp_mp	(A \iff B) \imp (A \imp C \iff B \imp C)

Axiom use

Logic (ax_mp, ax_1, ax_2, ax_3)