csbima12gALTVD

Description: Virtual deduction proof of csbima12 . The following User's Proof is a Virtual Deduction proof completed automatically by the tools program completeusersproof.cmd, which invokes Mel L. O'Cat's mmj2 and Norm Megill's Metamath Proof Assistant. csbima12 is csbima12gALTVD without virtual deductions and was automatically derived from csbima12gALTVD .

		Ref	Expression
	Assertion	csbima12gALTVD	$⊢ A \in C \to ⦋ A / x ⦌ F [B] = ⦋ A / x ⦌ F [⦋ A / x ⦌ B]$

Proof

Step	Hyp	Ref	Expression
1		idn1	$⊢ (A \in C \to A \in C)$
2		csbres	$⊢ ⦋ A / x ⦌ ({F ↾}_{B}) = {⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B}$
3	2	a1i	$⊢ A \in C \to ⦋ A / x ⦌ ({F ↾}_{B}) = {⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B}$
4	1 3	e1a	$⊢ (A \in C \to ⦋ A / x ⦌ ({F ↾}_{B}) = {⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B})$
5		rneq	$⊢ ⦋ A / x ⦌ ({F ↾}_{B}) = {⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B} \to ran ⦋ A / x ⦌ ({F ↾}_{B}) = ran ({⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B})$
6	4 5	e1a	$⊢ (A \in C \to ran ⦋ A / x ⦌ ({F ↾}_{B}) = ran ({⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B}))$
7		csbrn	$⊢ ⦋ A / x ⦌ ran ({F ↾}_{B}) = ran ⦋ A / x ⦌ ({F ↾}_{B})$
8	7	a1i	$⊢ A \in C \to ⦋ A / x ⦌ ran ({F ↾}_{B}) = ran ⦋ A / x ⦌ ({F ↾}_{B})$
9	1 8	e1a	$⊢ (A \in C \to ⦋ A / x ⦌ ran ({F ↾}_{B}) = ran ⦋ A / x ⦌ ({F ↾}_{B}))$
10		eqeq2	$⊢ ran ⦋ A / x ⦌ ({F ↾}_{B}) = ran ({⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B}) \to (⦋ A / x ⦌ ran ({F ↾}_{B}) = ran ⦋ A / x ⦌ ({F ↾}_{B}) \leftrightarrow ⦋ A / x ⦌ ran ({F ↾}_{B}) = ran ({⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B}))$
11	10	biimpd	$⊢ ran ⦋ A / x ⦌ ({F ↾}_{B}) = ran ({⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B}) \to (⦋ A / x ⦌ ran ({F ↾}_{B}) = ran ⦋ A / x ⦌ ({F ↾}_{B}) \to ⦋ A / x ⦌ ran ({F ↾}_{B}) = ran ({⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B}))$
12	6 9 11	e11	$⊢ (A \in C \to ⦋ A / x ⦌ ran ({F ↾}_{B}) = ran ({⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B}))$
13		df-ima	$⊢ F [B] = ran ({F ↾}_{B})$
14	13	ax-gen	$⊢ \forall x F [B] = ran ({F ↾}_{B})$
15		csbeq2	$⊢ \forall x F [B] = ran ({F ↾}_{B}) \to ⦋ A / x ⦌ F [B] = ⦋ A / x ⦌ ran ({F ↾}_{B})$
16	15	a1i	$⊢ A \in C \to (\forall x F [B] = ran ({F ↾}_{B}) \to ⦋ A / x ⦌ F [B] = ⦋ A / x ⦌ ran ({F ↾}_{B}))$
17	1 14 16	e10	$⊢ (A \in C \to ⦋ A / x ⦌ F [B] = ⦋ A / x ⦌ ran ({F ↾}_{B}))$
18		eqeq2	$⊢ ⦋ A / x ⦌ ran ({F ↾}_{B}) = ran ({⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B}) \to (⦋ A / x ⦌ F [B] = ⦋ A / x ⦌ ran ({F ↾}_{B}) \leftrightarrow ⦋ A / x ⦌ F [B] = ran ({⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B}))$
19	18	biimpd	$⊢ ⦋ A / x ⦌ ran ({F ↾}_{B}) = ran ({⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B}) \to (⦋ A / x ⦌ F [B] = ⦋ A / x ⦌ ran ({F ↾}_{B}) \to ⦋ A / x ⦌ F [B] = ran ({⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B}))$
20	12 17 19	e11	$⊢ (A \in C \to ⦋ A / x ⦌ F [B] = ran ({⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B}))$
21		df-ima	$⊢ ⦋ A / x ⦌ F [⦋ A / x ⦌ B] = ran ({⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B})$
22		eqeq2	$⊢ ⦋ A / x ⦌ F [⦋ A / x ⦌ B] = ran ({⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B}) \to (⦋ A / x ⦌ F [B] = ⦋ A / x ⦌ F [⦋ A / x ⦌ B] \leftrightarrow ⦋ A / x ⦌ F [B] = ran ({⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B}))$
23	22	biimprcd	$⊢ ⦋ A / x ⦌ F [B] = ran ({⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B}) \to (⦋ A / x ⦌ F [⦋ A / x ⦌ B] = ran ({⦋ A / x ⦌ F ↾}_{⦋ A / x ⦌ B}) \to ⦋ A / x ⦌ F [B] = ⦋ A / x ⦌ F [⦋ A / x ⦌ B])$
24	20 21 23	e10	$⊢ (A \in C \to ⦋ A / x ⦌ F [B] = ⦋ A / x ⦌ F [⦋ A / x ⦌ B])$
25	24	in1	$⊢ A \in C \to ⦋ A / x ⦌ F [B] = ⦋ A / x ⦌ F [⦋ A / x ⦌ B]$

1::	\|- (. A e. C ->. A e. C ).
2:1:	` \|- (. A e. C ->. [_ A / x ]_ ( F \|`B ) = ( ` [_ A / x ]_ F \|`[_ A / x ]_ B ) ).
3:2:	\|- (. A e. C ->. ` ran [_ A / x ]_ ( F \|`B ) ` = ran ( [_ A / x ]_ F \|`[_ A / x ]_ B ) ).
4:1:	\|- (. A e. C ->. ` [_ A / x ]_ ran ( F \|`B ) ` = ran [_ A / x ]_ ( F \|`B ) ).
5:3,4:	\|- (. A e. C ->. ` [_ A / x ]_ ran ( F \|`B ) ` = ran ( [_ A / x ]_ F \|`[_ A / x ]_ B ) ).
6::	` \|- ( F " B ) = ran ( F \|`B )
7:6:	` \|- A. x ( F " B ) = ran ( F \|`B )
8:1,7:	\|- (. A e. C ->. [_ A / x ]_ ( F " B ) = [_ ` A / x ]_ ran ( F \|`B ) ).
9:5,8:	\|- (. A e. C ->. [_ A / x ]_ ( F " B ) = ` ran ( [_ A / x ]_ F \|`[_ A / x ]_ B ) ).
10::	\|- ( [_ A / x ]_ F " [_ A / x ]_ B ) = ran ` ( [_ A / x ]_ F \|`[_ A / x ]_ B )
11:9,10:	\|- (. A e. C ->. [_ A / x ]_ ( F " B ) = ( [_ A / x ]_ F " [_ A / x ]_ B ) ).
qed:11:	\|- ( A e. C -> [_ A / x ]_ ( F " B ) = ( [_ A / x ]_ F " [_ A / x ]_ B ) )

Metamath Proof Explorer

Theorem csbima12gALTVD

Proof