Metamath Proof Explorer

Theorem archiexdiv

Description: In an Archimedean group, given two positive elements, there exists a "divisor" n . (Contributed by Thierry Arnoux, 30-Jan-2018)

		Ref	Expression
	Hypotheses	archiexdiv.b	$⊢ B = {Base}_{W}$
		archiexdiv.0	$⊢ \underset{˙}{0} = 0_{W}$
		archiexdiv.i	$⊢ \underset{˙}{<} = <_{W}$
		archiexdiv.x	$⊢ \underset{˙}{\cdot} = \cdot_{W}$
	Assertion	archiexdiv	$⊢ ((W \in oGrp \land W \in Archi) \land (X \in B \land Y \in B) \land \underset{˙}{0} \underset{˙}{<} X) \to \exists n \in ℕ Y \underset{˙}{<} (n \underset{˙}{\cdot} X)$

Proof

Step	Hyp	Ref	Expression
1		archiexdiv.b	$⊢ B = {Base}_{W}$
2		archiexdiv.0	$⊢ \underset{˙}{0} = 0_{W}$
3		archiexdiv.i	$⊢ \underset{˙}{<} = <_{W}$
4		archiexdiv.x	$⊢ \underset{˙}{\cdot} = \cdot_{W}$
5	1 2 3 4	isarchi3	$⊢ W \in oGrp \to (W \in Archi \leftrightarrow \forall x \in B \forall y \in B (\underset{˙}{0} \underset{˙}{<} x \to \exists n \in ℕ y \underset{˙}{<} (n \underset{˙}{\cdot} x)))$
6	5	biimpa	$⊢ (W \in oGrp \land W \in Archi) \to \forall x \in B \forall y \in B (\underset{˙}{0} \underset{˙}{<} x \to \exists n \in ℕ y \underset{˙}{<} (n \underset{˙}{\cdot} x))$
7	6	3ad2ant1	$⊢ ((W \in oGrp \land W \in Archi) \land (X \in B \land Y \in B) \land \underset{˙}{0} \underset{˙}{<} X) \to \forall x \in B \forall y \in B (\underset{˙}{0} \underset{˙}{<} x \to \exists n \in ℕ y \underset{˙}{<} (n \underset{˙}{\cdot} x))$
8		simp3	$⊢ ((W \in oGrp \land W \in Archi) \land (X \in B \land Y \in B) \land \underset{˙}{0} \underset{˙}{<} X) \to \underset{˙}{0} \underset{˙}{<} X$
9		breq2	$⊢ x = X \to (\underset{˙}{0} \underset{˙}{<} x \leftrightarrow \underset{˙}{0} \underset{˙}{<} X)$
10		oveq2	$⊢ x = X \to n \underset{˙}{\cdot} x = n \underset{˙}{\cdot} X$
11	10	breq2d	$⊢ x = X \to (y \underset{˙}{<} (n \underset{˙}{\cdot} x) \leftrightarrow y \underset{˙}{<} (n \underset{˙}{\cdot} X))$
12	11	rexbidv	$⊢ x = X \to (\exists n \in ℕ y \underset{˙}{<} (n \underset{˙}{\cdot} x) \leftrightarrow \exists n \in ℕ y \underset{˙}{<} (n \underset{˙}{\cdot} X))$
13	9 12	imbi12d	$⊢ x = X \to ((\underset{˙}{0} \underset{˙}{<} x \to \exists n \in ℕ y \underset{˙}{<} (n \underset{˙}{\cdot} x)) \leftrightarrow (\underset{˙}{0} \underset{˙}{<} X \to \exists n \in ℕ y \underset{˙}{<} (n \underset{˙}{\cdot} X)))$
14		breq1	$⊢ y = Y \to (y \underset{˙}{<} (n \underset{˙}{\cdot} X) \leftrightarrow Y \underset{˙}{<} (n \underset{˙}{\cdot} X))$
15	14	rexbidv	$⊢ y = Y \to (\exists n \in ℕ y \underset{˙}{<} (n \underset{˙}{\cdot} X) \leftrightarrow \exists n \in ℕ Y \underset{˙}{<} (n \underset{˙}{\cdot} X))$
16	15	imbi2d	$⊢ y = Y \to ((\underset{˙}{0} \underset{˙}{<} X \to \exists n \in ℕ y \underset{˙}{<} (n \underset{˙}{\cdot} X)) \leftrightarrow (\underset{˙}{0} \underset{˙}{<} X \to \exists n \in ℕ Y \underset{˙}{<} (n \underset{˙}{\cdot} X)))$
17	13 16	rspc2v	$⊢ (X \in B \land Y \in B) \to (\forall x \in B \forall y \in B (\underset{˙}{0} \underset{˙}{<} x \to \exists n \in ℕ y \underset{˙}{<} (n \underset{˙}{\cdot} x)) \to (\underset{˙}{0} \underset{˙}{<} X \to \exists n \in ℕ Y \underset{˙}{<} (n \underset{˙}{\cdot} X)))$
18	17	3ad2ant2	$⊢ ((W \in oGrp \land W \in Archi) \land (X \in B \land Y \in B) \land \underset{˙}{0} \underset{˙}{<} X) \to (\forall x \in B \forall y \in B (\underset{˙}{0} \underset{˙}{<} x \to \exists n \in ℕ y \underset{˙}{<} (n \underset{˙}{\cdot} x)) \to (\underset{˙}{0} \underset{˙}{<} X \to \exists n \in ℕ Y \underset{˙}{<} (n \underset{˙}{\cdot} X)))$
19	7 8 18	mp2d	$⊢ ((W \in oGrp \land W \in Archi) \land (X \in B \land Y \in B) \land \underset{˙}{0} \underset{˙}{<} X) \to \exists n \in ℕ Y \underset{˙}{<} (n \underset{˙}{\cdot} X)$