bnj611

Description: Technical lemma for bnj852 . This lemma may no longer be used or have become an indirect lemma of the theorem in question (i.e. a lemma of a lemma... of the theorem). (Contributed by Jonathan Ben-Naim, 3-Jun-2011) (New usage is discouraged.)

	Ref	Expression
Hypotheses	bnj611.1	$⊢ ψ \leftrightarrow \forall i \in ω (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))$
	bnj611.2	No typesetting found for \|- ( ps" <-> [. G / f ]. ps ) with typecode \|-
	bnj611.3	$⊢ G \in V$
Assertion	bnj611	Could not format assertion : No typesetting found for \|- ( ps" <-> A. i e. _om ( suc i e. N -> ( G ` suc i ) = U_ y e. ( G ` i ) _pred ( y , A , R ) ) ) with typecode \|-

Proof

Step	Hyp	Ref	Expression
1		bnj611.1	$⊢ ψ \leftrightarrow \forall i \in ω (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))$
2		bnj611.2	Could not format ( ps" <-> [. G / f ]. ps ) : No typesetting found for \|- ( ps" <-> [. G / f ]. ps ) with typecode \|-
3		bnj611.3	$⊢ G \in V$
4		df-ral	$⊢ \forall i \in ω (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)) \leftrightarrow \forall i (i \in ω \to (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)))$
5	4	bicomi	$⊢ \forall i (i \in ω \to (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))) \leftrightarrow \forall i \in ω (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))$
6	5	sbcbii	$⊢ \underset{˙}{[} G / f \underset{˙}{]} \forall i (i \in ω \to (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))) \leftrightarrow \underset{˙}{[} G / f \underset{˙}{]} \forall i \in ω (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))$
7		nfv	$⊢ Ⅎ f i \in ω$
8	7	sbc19.21g	$⊢ G \in V \to (\underset{˙}{[} G / f \underset{˙}{]} (i \in ω \to (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))) \leftrightarrow (i \in ω \to \underset{˙}{[} G / f \underset{˙}{]} (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))))$
9	3 8	ax-mp	$⊢ \underset{˙}{[} G / f \underset{˙}{]} (i \in ω \to (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))) \leftrightarrow (i \in ω \to \underset{˙}{[} G / f \underset{˙}{]} (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)))$
10		nfv	$⊢ Ⅎ f suc i \in N$
11	10	sbc19.21g	$⊢ G \in V \to (\underset{˙}{[} G / f \underset{˙}{]} (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)) \leftrightarrow (suc i \in N \to \underset{˙}{[} G / f \underset{˙}{]} f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)))$
12	3 11	ax-mp	$⊢ \underset{˙}{[} G / f \underset{˙}{]} (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)) \leftrightarrow (suc i \in N \to \underset{˙}{[} G / f \underset{˙}{]} f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))$
13		fveq1	$⊢ f = G \to f (suc i) = G (suc i)$
14		fveq1	$⊢ f = G \to f (i) = G (i)$
15	14	bnj1113	$⊢ f = G \to ⋃_{y \in f (i)} pred (y, A, R) = ⋃_{y \in G (i)} pred (y, A, R)$
16	13 15	eqeq12d	$⊢ f = G \to (f (suc i) = ⋃_{y \in f (i)} pred (y, A, R) \leftrightarrow G (suc i) = ⋃_{y \in G (i)} pred (y, A, R))$
17		fveq1	$⊢ f = e \to f (suc i) = e (suc i)$
18		fveq1	$⊢ f = e \to f (i) = e (i)$
19	18	bnj1113	$⊢ f = e \to ⋃_{y \in f (i)} pred (y, A, R) = ⋃_{y \in e (i)} pred (y, A, R)$
20	17 19	eqeq12d	$⊢ f = e \to (f (suc i) = ⋃_{y \in f (i)} pred (y, A, R) \leftrightarrow e (suc i) = ⋃_{y \in e (i)} pred (y, A, R))$
21		fveq1	$⊢ e = G \to e (suc i) = G (suc i)$
22		fveq1	$⊢ e = G \to e (i) = G (i)$
23	22	bnj1113	$⊢ e = G \to ⋃_{y \in e (i)} pred (y, A, R) = ⋃_{y \in G (i)} pred (y, A, R)$
24	21 23	eqeq12d	$⊢ e = G \to (e (suc i) = ⋃_{y \in e (i)} pred (y, A, R) \leftrightarrow G (suc i) = ⋃_{y \in G (i)} pred (y, A, R))$
25	3 16 20 24	bnj610	$⊢ \underset{˙}{[} G / f \underset{˙}{]} f (suc i) = ⋃_{y \in f (i)} pred (y, A, R) \leftrightarrow G (suc i) = ⋃_{y \in G (i)} pred (y, A, R)$
26	25	imbi2i	$⊢ (suc i \in N \to \underset{˙}{[} G / f \underset{˙}{]} f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)) \leftrightarrow (suc i \in N \to G (suc i) = ⋃_{y \in G (i)} pred (y, A, R))$
27	12 26	bitri	$⊢ \underset{˙}{[} G / f \underset{˙}{]} (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)) \leftrightarrow (suc i \in N \to G (suc i) = ⋃_{y \in G (i)} pred (y, A, R))$
28	27	imbi2i	$⊢ (i \in ω \to \underset{˙}{[} G / f \underset{˙}{]} (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))) \leftrightarrow (i \in ω \to (suc i \in N \to G (suc i) = ⋃_{y \in G (i)} pred (y, A, R)))$
29	9 28	bitri	$⊢ \underset{˙}{[} G / f \underset{˙}{]} (i \in ω \to (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))) \leftrightarrow (i \in ω \to (suc i \in N \to G (suc i) = ⋃_{y \in G (i)} pred (y, A, R)))$
30	29	albii	$⊢ \forall i \underset{˙}{[} G / f \underset{˙}{]} (i \in ω \to (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))) \leftrightarrow \forall i (i \in ω \to (suc i \in N \to G (suc i) = ⋃_{y \in G (i)} pred (y, A, R)))$
31		sbcal	$⊢ \underset{˙}{[} G / f \underset{˙}{]} \forall i (i \in ω \to (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))) \leftrightarrow \forall i \underset{˙}{[} G / f \underset{˙}{]} (i \in ω \to (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)))$
32		df-ral	$⊢ \forall i \in ω (suc i \in N \to G (suc i) = ⋃_{y \in G (i)} pred (y, A, R)) \leftrightarrow \forall i (i \in ω \to (suc i \in N \to G (suc i) = ⋃_{y \in G (i)} pred (y, A, R)))$
33	30 31 32	3bitr4ri	$⊢ \forall i \in ω (suc i \in N \to G (suc i) = ⋃_{y \in G (i)} pred (y, A, R)) \leftrightarrow \underset{˙}{[} G / f \underset{˙}{]} \forall i (i \in ω \to (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)))$
34	1	sbcbii	$⊢ \underset{˙}{[} G / f \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} G / f \underset{˙}{]} \forall i \in ω (suc i \in N \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))$
35	6 33 34	3bitr4ri	$⊢ \underset{˙}{[} G / f \underset{˙}{]} ψ \leftrightarrow \forall i \in ω (suc i \in N \to G (suc i) = ⋃_{y \in G (i)} pred (y, A, R))$
36	2 35	bitri	Could not format ( ps" <-> A. i e. _om ( suc i e. N -> ( G ` suc i ) = U_ y e. ( G ` i ) _pred ( y , A , R ) ) ) : No typesetting found for \|- ( ps" <-> A. i e. _om ( suc i e. N -> ( G ` suc i ) = U_ y e. ( G ` i ) _pred ( y , A , R ) ) ) with typecode \|-

Metamath Proof Explorer

Theorem bnj611

Proof