disjpr2

Description: Two completely distinct unordered pairs are disjoint. (Contributed by Alexander van der Vekens, 11-Nov-2017) (Proof shortened by JJ, 23-Jul-2021)

		Ref	Expression
	Assertion	disjpr2	$⊢ ((A \neq C \land B \neq C) \land (A \neq D \land B \neq D)) \to \{A, B\} \cap \{C, D\} = \emptyset$

Proof

Step	Hyp	Ref	Expression
1		df-pr	$⊢ \{C, D\} = \{C\} \cup \{D\}$
2	1	ineq2i	$⊢ \{A, B\} \cap \{C, D\} = \{A, B\} \cap (\{C\} \cup \{D\})$
3		indi	$⊢ \{A, B\} \cap (\{C\} \cup \{D\}) = (\{A, B\} \cap \{C\}) \cup (\{A, B\} \cap \{D\})$
4	2 3	eqtri	$⊢ \{A, B\} \cap \{C, D\} = (\{A, B\} \cap \{C\}) \cup (\{A, B\} \cap \{D\})$
5		df-pr	$⊢ \{A, B\} = \{A\} \cup \{B\}$
6	5	ineq1i	$⊢ \{A, B\} \cap \{C\} = (\{A\} \cup \{B\}) \cap \{C\}$
7		indir	$⊢ (\{A\} \cup \{B\}) \cap \{C\} = (\{A\} \cap \{C\}) \cup (\{B\} \cap \{C\})$
8	6 7	eqtri	$⊢ \{A, B\} \cap \{C\} = (\{A\} \cap \{C\}) \cup (\{B\} \cap \{C\})$
9		disjsn2	$⊢ A \neq C \to \{A\} \cap \{C\} = \emptyset$
10		disjsn2	$⊢ B \neq C \to \{B\} \cap \{C\} = \emptyset$
11	9 10	anim12i	$⊢ (A \neq C \land B \neq C) \to (\{A\} \cap \{C\} = \emptyset \land \{B\} \cap \{C\} = \emptyset)$
12		un00	$⊢ (\{A\} \cap \{C\} = \emptyset \land \{B\} \cap \{C\} = \emptyset) \leftrightarrow (\{A\} \cap \{C\}) \cup (\{B\} \cap \{C\}) = \emptyset$
13	11 12	sylib	$⊢ (A \neq C \land B \neq C) \to (\{A\} \cap \{C\}) \cup (\{B\} \cap \{C\}) = \emptyset$
14	8 13	eqtrid	$⊢ (A \neq C \land B \neq C) \to \{A, B\} \cap \{C\} = \emptyset$
15	14	adantr	$⊢ ((A \neq C \land B \neq C) \land (A \neq D \land B \neq D)) \to \{A, B\} \cap \{C\} = \emptyset$
16	5	ineq1i	$⊢ \{A, B\} \cap \{D\} = (\{A\} \cup \{B\}) \cap \{D\}$
17		indir	$⊢ (\{A\} \cup \{B\}) \cap \{D\} = (\{A\} \cap \{D\}) \cup (\{B\} \cap \{D\})$
18	16 17	eqtri	$⊢ \{A, B\} \cap \{D\} = (\{A\} \cap \{D\}) \cup (\{B\} \cap \{D\})$
19		disjsn2	$⊢ A \neq D \to \{A\} \cap \{D\} = \emptyset$
20		disjsn2	$⊢ B \neq D \to \{B\} \cap \{D\} = \emptyset$
21	19 20	anim12i	$⊢ (A \neq D \land B \neq D) \to (\{A\} \cap \{D\} = \emptyset \land \{B\} \cap \{D\} = \emptyset)$
22		un00	$⊢ (\{A\} \cap \{D\} = \emptyset \land \{B\} \cap \{D\} = \emptyset) \leftrightarrow (\{A\} \cap \{D\}) \cup (\{B\} \cap \{D\}) = \emptyset$
23	21 22	sylib	$⊢ (A \neq D \land B \neq D) \to (\{A\} \cap \{D\}) \cup (\{B\} \cap \{D\}) = \emptyset$
24	18 23	eqtrid	$⊢ (A \neq D \land B \neq D) \to \{A, B\} \cap \{D\} = \emptyset$
25	24	adantl	$⊢ ((A \neq C \land B \neq C) \land (A \neq D \land B \neq D)) \to \{A, B\} \cap \{D\} = \emptyset$
26	15 25	uneq12d	$⊢ ((A \neq C \land B \neq C) \land (A \neq D \land B \neq D)) \to (\{A, B\} \cap \{C\}) \cup (\{A, B\} \cap \{D\}) = \emptyset \cup \emptyset$
27		un0	$⊢ \emptyset \cup \emptyset = \emptyset$
28	26 27	eqtrdi	$⊢ ((A \neq C \land B \neq C) \land (A \neq D \land B \neq D)) \to (\{A, B\} \cap \{C\}) \cup (\{A, B\} \cap \{D\}) = \emptyset$
29	4 28	eqtrid	$⊢ ((A \neq C \land B \neq C) \land (A \neq D \land B \neq D)) \to \{A, B\} \cap \{C, D\} = \emptyset$

Metamath Proof Explorer

Theorem disjpr2

Proof