afv2orxorb

Description: If a set is in the range of a function, the alternate function value at a class A equals this set or is not in the range of the function iff the alternate function value at the class A either equals this set or is not in the range of the function. If B e/ ran F , both disjuncts of the exclusive or can be true: ( F '''' A ) = B -> ( F '''' A ) e/ ran F . (Contributed by AV, 11-Sep-2022)

		Ref	Expression
	Assertion	afv2orxorb	$⊢ B \in ran F \to (((F'''' A) = B \lor (F'''' A) \notin ran F) \leftrightarrow ((F'''' A) = B ⊻ (F'''' A) \notin ran F))$

Proof

Step	Hyp	Ref	Expression
1		eleq1	$⊢ B = (F'''' A) \to (B \in ran F \leftrightarrow (F'''' A) \in ran F)$
2	1	eqcoms	$⊢ (F'''' A) = B \to (B \in ran F \leftrightarrow (F'''' A) \in ran F)$
3	2	biimpa	$⊢ ((F'''' A) = B \land B \in ran F) \to (F'''' A) \in ran F$
4		nnel	$⊢ \neg (F'''' A) \notin ran F \leftrightarrow (F'''' A) \in ran F$
5	3 4	sylibr	$⊢ ((F'''' A) = B \land B \in ran F) \to \neg (F'''' A) \notin ran F$
6	5	a1d	$⊢ ((F'''' A) = B \land B \in ran F) \to ((F'''' A) = B \to \neg (F'''' A) \notin ran F)$
7		simpl	$⊢ ((F'''' A) = B \land B \in ran F) \to (F'''' A) = B$
8	7	a1d	$⊢ ((F'''' A) = B \land B \in ran F) \to (\neg (F'''' A) \notin ran F \to (F'''' A) = B)$
9	6 8	jca	$⊢ ((F'''' A) = B \land B \in ran F) \to (((F'''' A) = B \to \neg (F'''' A) \notin ran F) \land (\neg (F'''' A) \notin ran F \to (F'''' A) = B))$
10	9	ex	$⊢ (F'''' A) = B \to (B \in ran F \to (((F'''' A) = B \to \neg (F'''' A) \notin ran F) \land (\neg (F'''' A) \notin ran F \to (F'''' A) = B)))$
11		eleq1	$⊢ (F'''' A) = B \to ((F'''' A) \in ran F \leftrightarrow B \in ran F)$
12	11	anbi2d	$⊢ (F'''' A) = B \to (((F'''' A) \notin ran F \land (F'''' A) \in ran F) \leftrightarrow ((F'''' A) \notin ran F \land B \in ran F))$
13		elnelall	$⊢ (F'''' A) \in ran F \to ((F'''' A) \notin ran F \to \neg (F'''' A) \notin ran F)$
14	13	impcom	$⊢ ((F'''' A) \notin ran F \land (F'''' A) \in ran F) \to \neg (F'''' A) \notin ran F$
15	12 14	syl6bir	$⊢ (F'''' A) = B \to (((F'''' A) \notin ran F \land B \in ran F) \to \neg (F'''' A) \notin ran F)$
16	15	com12	$⊢ ((F'''' A) \notin ran F \land B \in ran F) \to ((F'''' A) = B \to \neg (F'''' A) \notin ran F)$
17		pm2.24	$⊢ (F'''' A) \notin ran F \to (\neg (F'''' A) \notin ran F \to (F'''' A) = B)$
18	17	adantr	$⊢ ((F'''' A) \notin ran F \land B \in ran F) \to (\neg (F'''' A) \notin ran F \to (F'''' A) = B)$
19	16 18	jca	$⊢ ((F'''' A) \notin ran F \land B \in ran F) \to (((F'''' A) = B \to \neg (F'''' A) \notin ran F) \land (\neg (F'''' A) \notin ran F \to (F'''' A) = B))$
20	19	ex	$⊢ (F'''' A) \notin ran F \to (B \in ran F \to (((F'''' A) = B \to \neg (F'''' A) \notin ran F) \land (\neg (F'''' A) \notin ran F \to (F'''' A) = B)))$
21	10 20	jaoi	$⊢ ((F'''' A) = B \lor (F'''' A) \notin ran F) \to (B \in ran F \to (((F'''' A) = B \to \neg (F'''' A) \notin ran F) \land (\neg (F'''' A) \notin ran F \to (F'''' A) = B)))$
22	21	com12	$⊢ B \in ran F \to (((F'''' A) = B \lor (F'''' A) \notin ran F) \to (((F'''' A) = B \to \neg (F'''' A) \notin ran F) \land (\neg (F'''' A) \notin ran F \to (F'''' A) = B)))$
23		df-xor	$⊢ ((F'''' A) = B ⊻ (F'''' A) \notin ran F) \leftrightarrow \neg ((F'''' A) = B \leftrightarrow (F'''' A) \notin ran F)$
24		xor3	$⊢ \neg ((F'''' A) = B \leftrightarrow (F'''' A) \notin ran F) \leftrightarrow ((F'''' A) = B \leftrightarrow \neg (F'''' A) \notin ran F)$
25		dfbi2	$⊢ ((F'''' A) = B \leftrightarrow \neg (F'''' A) \notin ran F) \leftrightarrow (((F'''' A) = B \to \neg (F'''' A) \notin ran F) \land (\neg (F'''' A) \notin ran F \to (F'''' A) = B))$
26	23 24 25	3bitri	$⊢ ((F'''' A) = B ⊻ (F'''' A) \notin ran F) \leftrightarrow (((F'''' A) = B \to \neg (F'''' A) \notin ran F) \land (\neg (F'''' A) \notin ran F \to (F'''' A) = B))$
27	22 26	syl6ibr	$⊢ B \in ran F \to (((F'''' A) = B \lor (F'''' A) \notin ran F) \to ((F'''' A) = B ⊻ (F'''' A) \notin ran F))$
28		xoror	$⊢ ((F'''' A) = B ⊻ (F'''' A) \notin ran F) \to ((F'''' A) = B \lor (F'''' A) \notin ran F)$
29	27 28	impbid1	$⊢ B \in ran F \to (((F'''' A) = B \lor (F'''' A) \notin ran F) \leftrightarrow ((F'''' A) = B ⊻ (F'''' A) \notin ran F))$

Metamath Proof Explorer

Theorem afv2orxorb

Proof