csboprabg

Description: Move class substitution in and out of class abstractions of nested ordered pairs. (Contributed by ML, 25-Oct-2020)

		Ref	Expression
	Assertion	csboprabg	$⊢ A \in V \to ⦋ A / x ⦌ \{⟨⟨y, z⟩, d⟩ \| φ\} = \{⟨⟨y, z⟩, d⟩ \| \underset{˙}{[} A / x \underset{˙}{]} φ\}$

Proof

Step	Hyp	Ref	Expression
1		csbab	$⊢ ⦋ A / x ⦌ \{c \| \exists y \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land φ)\} = \{c \| \underset{˙}{[} A / x \underset{˙}{]} \exists y \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land φ)\}$
2		sbcex2	$⊢ \underset{˙}{[} A / x \underset{˙}{]} \exists y \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land φ) \leftrightarrow \exists y \underset{˙}{[} A / x \underset{˙}{]} \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land φ)$
3		sbcex2	$⊢ \underset{˙}{[} A / x \underset{˙}{]} \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land φ) \leftrightarrow \exists z \underset{˙}{[} A / x \underset{˙}{]} \exists d (c = ⟨⟨y, z⟩, d⟩ \land φ)$
4		sbcex2	$⊢ \underset{˙}{[} A / x \underset{˙}{]} \exists d (c = ⟨⟨y, z⟩, d⟩ \land φ) \leftrightarrow \exists d \underset{˙}{[} A / x \underset{˙}{]} (c = ⟨⟨y, z⟩, d⟩ \land φ)$
5		sbcan	$⊢ \underset{˙}{[} A / x \underset{˙}{]} (c = ⟨⟨y, z⟩, d⟩ \land φ) \leftrightarrow (\underset{˙}{[} A / x \underset{˙}{]} c = ⟨⟨y, z⟩, d⟩ \land \underset{˙}{[} A / x \underset{˙}{]} φ)$
6		sbcg	$⊢ A \in V \to (\underset{˙}{[} A / x \underset{˙}{]} c = ⟨⟨y, z⟩, d⟩ \leftrightarrow c = ⟨⟨y, z⟩, d⟩)$
7	6	anbi1d	$⊢ A \in V \to ((\underset{˙}{[} A / x \underset{˙}{]} c = ⟨⟨y, z⟩, d⟩ \land \underset{˙}{[} A / x \underset{˙}{]} φ) \leftrightarrow (c = ⟨⟨y, z⟩, d⟩ \land \underset{˙}{[} A / x \underset{˙}{]} φ))$
8	5 7	syl5bb	$⊢ A \in V \to (\underset{˙}{[} A / x \underset{˙}{]} (c = ⟨⟨y, z⟩, d⟩ \land φ) \leftrightarrow (c = ⟨⟨y, z⟩, d⟩ \land \underset{˙}{[} A / x \underset{˙}{]} φ))$
9	8	exbidv	$⊢ A \in V \to (\exists d \underset{˙}{[} A / x \underset{˙}{]} (c = ⟨⟨y, z⟩, d⟩ \land φ) \leftrightarrow \exists d (c = ⟨⟨y, z⟩, d⟩ \land \underset{˙}{[} A / x \underset{˙}{]} φ))$
10	4 9	syl5bb	$⊢ A \in V \to (\underset{˙}{[} A / x \underset{˙}{]} \exists d (c = ⟨⟨y, z⟩, d⟩ \land φ) \leftrightarrow \exists d (c = ⟨⟨y, z⟩, d⟩ \land \underset{˙}{[} A / x \underset{˙}{]} φ))$
11	10	exbidv	$⊢ A \in V \to (\exists z \underset{˙}{[} A / x \underset{˙}{]} \exists d (c = ⟨⟨y, z⟩, d⟩ \land φ) \leftrightarrow \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land \underset{˙}{[} A / x \underset{˙}{]} φ))$
12	3 11	syl5bb	$⊢ A \in V \to (\underset{˙}{[} A / x \underset{˙}{]} \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land φ) \leftrightarrow \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land \underset{˙}{[} A / x \underset{˙}{]} φ))$
13	12	exbidv	$⊢ A \in V \to (\exists y \underset{˙}{[} A / x \underset{˙}{]} \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land φ) \leftrightarrow \exists y \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land \underset{˙}{[} A / x \underset{˙}{]} φ))$
14	2 13	syl5bb	$⊢ A \in V \to (\underset{˙}{[} A / x \underset{˙}{]} \exists y \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land φ) \leftrightarrow \exists y \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land \underset{˙}{[} A / x \underset{˙}{]} φ))$
15	14	abbidv	$⊢ A \in V \to \{c \| \underset{˙}{[} A / x \underset{˙}{]} \exists y \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land φ)\} = \{c \| \exists y \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land \underset{˙}{[} A / x \underset{˙}{]} φ)\}$
16	1 15	syl5eq	$⊢ A \in V \to ⦋ A / x ⦌ \{c \| \exists y \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land φ)\} = \{c \| \exists y \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land \underset{˙}{[} A / x \underset{˙}{]} φ)\}$
17		df-oprab	$⊢ \{⟨⟨y, z⟩, d⟩ \| φ\} = \{c \| \exists y \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land φ)\}$
18	17	csbeq2i	$⊢ ⦋ A / x ⦌ \{⟨⟨y, z⟩, d⟩ \| φ\} = ⦋ A / x ⦌ \{c \| \exists y \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land φ)\}$
19		df-oprab	$⊢ \{⟨⟨y, z⟩, d⟩ \| \underset{˙}{[} A / x \underset{˙}{]} φ\} = \{c \| \exists y \exists z \exists d (c = ⟨⟨y, z⟩, d⟩ \land \underset{˙}{[} A / x \underset{˙}{]} φ)\}$
20	16 18 19	3eqtr4g	$⊢ A \in V \to ⦋ A / x ⦌ \{⟨⟨y, z⟩, d⟩ \| φ\} = \{⟨⟨y, z⟩, d⟩ \| \underset{˙}{[} A / x \underset{˙}{]} φ\}$

Metamath Proof Explorer

Theorem csboprabg

Proof