Metamath Proof Explorer

Theorem bnj92

Description: First-order logic and set theory. (Contributed by Jonathan Ben-Naim, 3-Jun-2011) (New usage is discouraged.)

		Ref	Expression
	Hypotheses	bnj92.1	$⊢ ψ \leftrightarrow \forall i \in ω (suc i \in n \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))$
		bnj92.2	$⊢ Z \in V$
	Assertion	bnj92	$⊢ \underset{˙}{[} Z / n \underset{˙}{]} ψ \leftrightarrow \forall i \in ω (suc i \in Z \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))$

Proof

Step	Hyp	Ref	Expression
1		bnj92.1	$⊢ ψ \leftrightarrow \forall i \in ω (suc i \in n \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))$
2		bnj92.2	$⊢ Z \in V$
3	1	sbcbii	$⊢ \underset{˙}{[} Z / n \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} Z / n \underset{˙}{]} \forall i \in ω (suc i \in n \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))$
4	2	bnj538	$⊢ \underset{˙}{[} Z / n \underset{˙}{]} \forall i \in ω (suc i \in n \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)) \leftrightarrow \forall i \in ω \underset{˙}{[} Z / n \underset{˙}{]} (suc i \in n \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))$
5		sbcimg	$⊢ Z \in V \to (\underset{˙}{[} Z / n \underset{˙}{]} (suc i \in n \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)) \leftrightarrow (\underset{˙}{[} Z / n \underset{˙}{]} suc i \in n \to \underset{˙}{[} Z / n \underset{˙}{]} f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)))$
6	2 5	ax-mp	$⊢ \underset{˙}{[} Z / n \underset{˙}{]} (suc i \in n \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)) \leftrightarrow (\underset{˙}{[} Z / n \underset{˙}{]} suc i \in n \to \underset{˙}{[} Z / n \underset{˙}{]} f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))$
7		sbcel2gv	$⊢ Z \in V \to (\underset{˙}{[} Z / n \underset{˙}{]} suc i \in n \leftrightarrow suc i \in Z)$
8	2 7	ax-mp	$⊢ \underset{˙}{[} Z / n \underset{˙}{]} suc i \in n \leftrightarrow suc i \in Z$
9	2	bnj525	$⊢ \underset{˙}{[} Z / n \underset{˙}{]} f (suc i) = ⋃_{y \in f (i)} pred (y, A, R) \leftrightarrow f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)$
10	8 9	imbi12i	$⊢ (\underset{˙}{[} Z / n \underset{˙}{]} suc i \in n \to \underset{˙}{[} Z / n \underset{˙}{]} f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)) \leftrightarrow (suc i \in Z \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))$
11	6 10	bitri	$⊢ \underset{˙}{[} Z / n \underset{˙}{]} (suc i \in n \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)) \leftrightarrow (suc i \in Z \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))$
12	11	ralbii	$⊢ \forall i \in ω \underset{˙}{[} Z / n \underset{˙}{]} (suc i \in n \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R)) \leftrightarrow \forall i \in ω (suc i \in Z \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))$
13	3 4 12	3bitri	$⊢ \underset{˙}{[} Z / n \underset{˙}{]} ψ \leftrightarrow \forall i \in ω (suc i \in Z \to f (suc i) = ⋃_{y \in f (i)} pred (y, A, R))$