ajmoi

Description: Every operator has at most one adjoint. (Contributed by NM, 25-Jan-2008) (New usage is discouraged.)

	Ref	Expression
Hypotheses	ip2eqi.1	$⊢ X = BaseSet (U)$
	ip2eqi.7	$⊢ P = \cdot_{𝑖OLD} (U)$
	ip2eqi.u	$⊢ U \in {CPreHil}_{OLD}$
Assertion	ajmoi	$⊢ \exists^{*} s (s : Y ⟶ X \land \forall x \in X \forall y \in Y T (x) Q y = x P s (y))$

Proof

Step	Hyp	Ref	Expression
1		ip2eqi.1	$⊢ X = BaseSet (U)$
2		ip2eqi.7	$⊢ P = \cdot_{𝑖OLD} (U)$
3		ip2eqi.u	$⊢ U \in {CPreHil}_{OLD}$
4		r19.26-2	$⊢ \forall x \in X \forall y \in Y (T (x) Q y = x P s (y) \land T (x) Q y = x P t (y)) \leftrightarrow (\forall x \in X \forall y \in Y T (x) Q y = x P s (y) \land \forall x \in X \forall y \in Y T (x) Q y = x P t (y))$
5		eqtr2	$⊢ (T (x) Q y = x P s (y) \land T (x) Q y = x P t (y)) \to x P s (y) = x P t (y)$
6	5	2ralimi	$⊢ \forall x \in X \forall y \in Y (T (x) Q y = x P s (y) \land T (x) Q y = x P t (y)) \to \forall x \in X \forall y \in Y x P s (y) = x P t (y)$
7	4 6	sylbir	$⊢ (\forall x \in X \forall y \in Y T (x) Q y = x P s (y) \land \forall x \in X \forall y \in Y T (x) Q y = x P t (y)) \to \forall x \in X \forall y \in Y x P s (y) = x P t (y)$
8	1 2 3	phoeqi	$⊢ (s : Y ⟶ X \land t : Y ⟶ X) \to (\forall x \in X \forall y \in Y x P s (y) = x P t (y) \leftrightarrow s = t)$
9	8	biimpa	$⊢ ((s : Y ⟶ X \land t : Y ⟶ X) \land \forall x \in X \forall y \in Y x P s (y) = x P t (y)) \to s = t$
10	7 9	sylan2	$⊢ ((s : Y ⟶ X \land t : Y ⟶ X) \land (\forall x \in X \forall y \in Y T (x) Q y = x P s (y) \land \forall x \in X \forall y \in Y T (x) Q y = x P t (y))) \to s = t$
11	10	an4s	$⊢ ((s : Y ⟶ X \land \forall x \in X \forall y \in Y T (x) Q y = x P s (y)) \land (t : Y ⟶ X \land \forall x \in X \forall y \in Y T (x) Q y = x P t (y))) \to s = t$
12	11	gen2	$⊢ \forall s \forall t (((s : Y ⟶ X \land \forall x \in X \forall y \in Y T (x) Q y = x P s (y)) \land (t : Y ⟶ X \land \forall x \in X \forall y \in Y T (x) Q y = x P t (y))) \to s = t)$
13		feq1	$⊢ s = t \to (s : Y ⟶ X \leftrightarrow t : Y ⟶ X)$
14		fveq1	$⊢ s = t \to s (y) = t (y)$
15	14	oveq2d	$⊢ s = t \to x P s (y) = x P t (y)$
16	15	eqeq2d	$⊢ s = t \to (T (x) Q y = x P s (y) \leftrightarrow T (x) Q y = x P t (y))$
17	16	2ralbidv	$⊢ s = t \to (\forall x \in X \forall y \in Y T (x) Q y = x P s (y) \leftrightarrow \forall x \in X \forall y \in Y T (x) Q y = x P t (y))$
18	13 17	anbi12d	$⊢ s = t \to ((s : Y ⟶ X \land \forall x \in X \forall y \in Y T (x) Q y = x P s (y)) \leftrightarrow (t : Y ⟶ X \land \forall x \in X \forall y \in Y T (x) Q y = x P t (y)))$
19	18	mo4	$⊢ \exists^{*} s (s : Y ⟶ X \land \forall x \in X \forall y \in Y T (x) Q y = x P s (y)) \leftrightarrow \forall s \forall t (((s : Y ⟶ X \land \forall x \in X \forall y \in Y T (x) Q y = x P s (y)) \land (t : Y ⟶ X \land \forall x \in X \forall y \in Y T (x) Q y = x P t (y))) \to s = t)$
20	12 19	mpbir	$⊢ \exists^{*} s (s : Y ⟶ X \land \forall x \in X \forall y \in Y T (x) Q y = x P s (y))$

Metamath Proof Explorer

Theorem ajmoi

Proof