dff13f

Description: A one-to-one function in terms of function values. Compare Theorem 4.8(iv) of Monk1 p. 43. (Contributed by NM, 31-Jul-2003)

	Ref	Expression
Hypotheses	dff13f.1	$⊢ \underline{Ⅎ} x F$
	dff13f.2	$⊢ \underline{Ⅎ} y F$
Assertion	dff13f	$⊢ F : A \underset{1-1}{⟶} B \leftrightarrow (F : A ⟶ B \land \forall x \in A \forall y \in A (F (x) = F (y) \to x = y))$

Proof

Step	Hyp	Ref	Expression
1		dff13f.1	$⊢ \underline{Ⅎ} x F$
2		dff13f.2	$⊢ \underline{Ⅎ} y F$
3		dff13	$⊢ F : A \underset{1-1}{⟶} B \leftrightarrow (F : A ⟶ B \land \forall w \in A \forall v \in A (F (w) = F (v) \to w = v))$
4		nfcv	$⊢ \underline{Ⅎ} y w$
5	2 4	nffv	$⊢ \underline{Ⅎ} y F (w)$
6		nfcv	$⊢ \underline{Ⅎ} y v$
7	2 6	nffv	$⊢ \underline{Ⅎ} y F (v)$
8	5 7	nfeq	$⊢ Ⅎ y F (w) = F (v)$
9		nfv	$⊢ Ⅎ y w = v$
10	8 9	nfim	$⊢ Ⅎ y (F (w) = F (v) \to w = v)$
11		nfv	$⊢ Ⅎ v (F (w) = F (y) \to w = y)$
12		fveq2	$⊢ v = y \to F (v) = F (y)$
13	12	eqeq2d	$⊢ v = y \to (F (w) = F (v) \leftrightarrow F (w) = F (y))$
14		equequ2	$⊢ v = y \to (w = v \leftrightarrow w = y)$
15	13 14	imbi12d	$⊢ v = y \to ((F (w) = F (v) \to w = v) \leftrightarrow (F (w) = F (y) \to w = y))$
16	10 11 15	cbvralw	$⊢ \forall v \in A (F (w) = F (v) \to w = v) \leftrightarrow \forall y \in A (F (w) = F (y) \to w = y)$
17	16	ralbii	$⊢ \forall w \in A \forall v \in A (F (w) = F (v) \to w = v) \leftrightarrow \forall w \in A \forall y \in A (F (w) = F (y) \to w = y)$
18		nfcv	$⊢ \underline{Ⅎ} x A$
19		nfcv	$⊢ \underline{Ⅎ} x w$
20	1 19	nffv	$⊢ \underline{Ⅎ} x F (w)$
21		nfcv	$⊢ \underline{Ⅎ} x y$
22	1 21	nffv	$⊢ \underline{Ⅎ} x F (y)$
23	20 22	nfeq	$⊢ Ⅎ x F (w) = F (y)$
24		nfv	$⊢ Ⅎ x w = y$
25	23 24	nfim	$⊢ Ⅎ x (F (w) = F (y) \to w = y)$
26	18 25	nfralw	$⊢ Ⅎ x \forall y \in A (F (w) = F (y) \to w = y)$
27		nfv	$⊢ Ⅎ w \forall y \in A (F (x) = F (y) \to x = y)$
28		fveqeq2	$⊢ w = x \to (F (w) = F (y) \leftrightarrow F (x) = F (y))$
29		equequ1	$⊢ w = x \to (w = y \leftrightarrow x = y)$
30	28 29	imbi12d	$⊢ w = x \to ((F (w) = F (y) \to w = y) \leftrightarrow (F (x) = F (y) \to x = y))$
31	30	ralbidv	$⊢ w = x \to (\forall y \in A (F (w) = F (y) \to w = y) \leftrightarrow \forall y \in A (F (x) = F (y) \to x = y))$
32	26 27 31	cbvralw	$⊢ \forall w \in A \forall y \in A (F (w) = F (y) \to w = y) \leftrightarrow \forall x \in A \forall y \in A (F (x) = F (y) \to x = y)$
33	17 32	bitri	$⊢ \forall w \in A \forall v \in A (F (w) = F (v) \to w = v) \leftrightarrow \forall x \in A \forall y \in A (F (x) = F (y) \to x = y)$
34	33	anbi2i	$⊢ (F : A ⟶ B \land \forall w \in A \forall v \in A (F (w) = F (v) \to w = v)) \leftrightarrow (F : A ⟶ B \land \forall x \in A \forall y \in A (F (x) = F (y) \to x = y))$
35	3 34	bitri	$⊢ F : A \underset{1-1}{⟶} B \leftrightarrow (F : A ⟶ B \land \forall x \in A \forall y \in A (F (x) = F (y) \to x = y))$

Metamath Proof Explorer

Theorem dff13f

Proof