fin23lem14

Description: Lemma for fin23 . U will never evolve to an empty set if it did not start with one. (Contributed by Stefan O'Rear, 1-Nov-2014)

		Ref	Expression
	Hypothesis	fin23lem.a	$⊢ U = {seq}_{ω} ((i \in ω, u \in V ⟼ if (t (i) \cap u = \emptyset, u, t (i) \cap u)), ⋃ ran t)$
	Assertion	fin23lem14	$⊢ (A \in ω \land ⋃ ran t \neq \emptyset) \to U (A) \neq \emptyset$

Proof

Step	Hyp	Ref	Expression
1		fin23lem.a	$⊢ U = {seq}_{ω} ((i \in ω, u \in V ⟼ if (t (i) \cap u = \emptyset, u, t (i) \cap u)), ⋃ ran t)$
2		fveq2	$⊢ a = \emptyset \to U (a) = U (\emptyset)$
3	2	neeq1d	$⊢ a = \emptyset \to (U (a) \neq \emptyset \leftrightarrow U (\emptyset) \neq \emptyset)$
4	3	imbi2d	$⊢ a = \emptyset \to ((⋃ ran t \neq \emptyset \to U (a) \neq \emptyset) \leftrightarrow (⋃ ran t \neq \emptyset \to U (\emptyset) \neq \emptyset))$
5		fveq2	$⊢ a = b \to U (a) = U (b)$
6	5	neeq1d	$⊢ a = b \to (U (a) \neq \emptyset \leftrightarrow U (b) \neq \emptyset)$
7	6	imbi2d	$⊢ a = b \to ((⋃ ran t \neq \emptyset \to U (a) \neq \emptyset) \leftrightarrow (⋃ ran t \neq \emptyset \to U (b) \neq \emptyset))$
8		fveq2	$⊢ a = suc b \to U (a) = U (suc b)$
9	8	neeq1d	$⊢ a = suc b \to (U (a) \neq \emptyset \leftrightarrow U (suc b) \neq \emptyset)$
10	9	imbi2d	$⊢ a = suc b \to ((⋃ ran t \neq \emptyset \to U (a) \neq \emptyset) \leftrightarrow (⋃ ran t \neq \emptyset \to U (suc b) \neq \emptyset))$
11		fveq2	$⊢ a = A \to U (a) = U (A)$
12	11	neeq1d	$⊢ a = A \to (U (a) \neq \emptyset \leftrightarrow U (A) \neq \emptyset)$
13	12	imbi2d	$⊢ a = A \to ((⋃ ran t \neq \emptyset \to U (a) \neq \emptyset) \leftrightarrow (⋃ ran t \neq \emptyset \to U (A) \neq \emptyset))$
14		vex	$⊢ t \in V$
15	14	rnex	$⊢ ran t \in V$
16	15	uniex	$⊢ ⋃ ran t \in V$
17	1	seqom0g	$⊢ ⋃ ran t \in V \to U (\emptyset) = ⋃ ran t$
18	16 17	mp1i	$⊢ ⋃ ran t \neq \emptyset \to U (\emptyset) = ⋃ ran t$
19		id	$⊢ ⋃ ran t \neq \emptyset \to ⋃ ran t \neq \emptyset$
20	18 19	eqnetrd	$⊢ ⋃ ran t \neq \emptyset \to U (\emptyset) \neq \emptyset$
21	1	fin23lem12	$⊢ b \in ω \to U (suc b) = if (t (b) \cap U (b) = \emptyset, U (b), t (b) \cap U (b))$
22	21	adantr	$⊢ (b \in ω \land U (b) \neq \emptyset) \to U (suc b) = if (t (b) \cap U (b) = \emptyset, U (b), t (b) \cap U (b))$
23		iftrue	$⊢ t (b) \cap U (b) = \emptyset \to if (t (b) \cap U (b) = \emptyset, U (b), t (b) \cap U (b)) = U (b)$
24	23	adantr	$⊢ (t (b) \cap U (b) = \emptyset \land (b \in ω \land U (b) \neq \emptyset)) \to if (t (b) \cap U (b) = \emptyset, U (b), t (b) \cap U (b)) = U (b)$
25		simprr	$⊢ (t (b) \cap U (b) = \emptyset \land (b \in ω \land U (b) \neq \emptyset)) \to U (b) \neq \emptyset$
26	24 25	eqnetrd	$⊢ (t (b) \cap U (b) = \emptyset \land (b \in ω \land U (b) \neq \emptyset)) \to if (t (b) \cap U (b) = \emptyset, U (b), t (b) \cap U (b)) \neq \emptyset$
27		iffalse	$⊢ \neg t (b) \cap U (b) = \emptyset \to if (t (b) \cap U (b) = \emptyset, U (b), t (b) \cap U (b)) = t (b) \cap U (b)$
28	27	adantr	$⊢ (\neg t (b) \cap U (b) = \emptyset \land (b \in ω \land U (b) \neq \emptyset)) \to if (t (b) \cap U (b) = \emptyset, U (b), t (b) \cap U (b)) = t (b) \cap U (b)$
29		neqne	$⊢ \neg t (b) \cap U (b) = \emptyset \to t (b) \cap U (b) \neq \emptyset$
30	29	adantr	$⊢ (\neg t (b) \cap U (b) = \emptyset \land (b \in ω \land U (b) \neq \emptyset)) \to t (b) \cap U (b) \neq \emptyset$
31	28 30	eqnetrd	$⊢ (\neg t (b) \cap U (b) = \emptyset \land (b \in ω \land U (b) \neq \emptyset)) \to if (t (b) \cap U (b) = \emptyset, U (b), t (b) \cap U (b)) \neq \emptyset$
32	26 31	pm2.61ian	$⊢ (b \in ω \land U (b) \neq \emptyset) \to if (t (b) \cap U (b) = \emptyset, U (b), t (b) \cap U (b)) \neq \emptyset$
33	22 32	eqnetrd	$⊢ (b \in ω \land U (b) \neq \emptyset) \to U (suc b) \neq \emptyset$
34	33	ex	$⊢ b \in ω \to (U (b) \neq \emptyset \to U (suc b) \neq \emptyset)$
35	34	imim2d	$⊢ b \in ω \to ((⋃ ran t \neq \emptyset \to U (b) \neq \emptyset) \to (⋃ ran t \neq \emptyset \to U (suc b) \neq \emptyset))$
36	4 7 10 13 20 35	finds	$⊢ A \in ω \to (⋃ ran t \neq \emptyset \to U (A) \neq \emptyset)$
37	36	imp	$⊢ (A \in ω \land ⋃ ran t \neq \emptyset) \to U (A) \neq \emptyset$

Metamath Proof Explorer

Theorem fin23lem14

Proof