supxrunb2

Description: The supremum of an unbounded-above set of extended reals is plus infinity. (Contributed by NM, 19-Jan-2006)

		Ref	Expression
	Assertion	supxrunb2	$⊢ A \subseteq ℝ^{} \to (\forall x \in ℝ \exists y \in A x < y \leftrightarrow sup (A ℝ^{} <) = +∞)$

Proof

Step	Hyp	Ref	Expression
1		ssel	$⊢ A \subseteq ℝ^{} \to (z \in A \to z \in ℝ^{})$
2		pnfnlt	$⊢ z \in ℝ^{*} \to \neg +∞ < z$
3	1 2	syl6	$⊢ A \subseteq ℝ^{*} \to (z \in A \to \neg +∞ < z)$
4	3	ralrimiv	$⊢ A \subseteq ℝ^{*} \to \forall z \in A \neg +∞ < z$
5	4	adantr	$⊢ (A \subseteq ℝ^{*} \land \forall x \in ℝ \exists y \in A x < y) \to \forall z \in A \neg +∞ < z$
6		breq1	$⊢ x = z \to (x < y \leftrightarrow z < y)$
7	6	rexbidv	$⊢ x = z \to (\exists y \in A x < y \leftrightarrow \exists y \in A z < y)$
8	7	rspcva	$⊢ (z \in ℝ \land \forall x \in ℝ \exists y \in A x < y) \to \exists y \in A z < y$
9	8	adantrr	$⊢ (z \in ℝ \land (\forall x \in ℝ \exists y \in A x < y \land A \subseteq ℝ^{*})) \to \exists y \in A z < y$
10	9	ancoms	$⊢ ((\forall x \in ℝ \exists y \in A x < y \land A \subseteq ℝ^{*}) \land z \in ℝ) \to \exists y \in A z < y$
11	10	exp31	$⊢ \forall x \in ℝ \exists y \in A x < y \to (A \subseteq ℝ^{*} \to (z \in ℝ \to \exists y \in A z < y))$
12	11	a1dd	$⊢ \forall x \in ℝ \exists y \in A x < y \to (A \subseteq ℝ^{*} \to (z < +∞ \to (z \in ℝ \to \exists y \in A z < y)))$
13	12	com4r	$⊢ z \in ℝ \to (\forall x \in ℝ \exists y \in A x < y \to (A \subseteq ℝ^{*} \to (z < +∞ \to \exists y \in A z < y)))$
14	13	com13	$⊢ A \subseteq ℝ^{*} \to (\forall x \in ℝ \exists y \in A x < y \to (z \in ℝ \to (z < +∞ \to \exists y \in A z < y)))$
15	14	imp	$⊢ (A \subseteq ℝ^{*} \land \forall x \in ℝ \exists y \in A x < y) \to (z \in ℝ \to (z < +∞ \to \exists y \in A z < y))$
16	15	ralrimiv	$⊢ (A \subseteq ℝ^{*} \land \forall x \in ℝ \exists y \in A x < y) \to \forall z \in ℝ (z < +∞ \to \exists y \in A z < y)$
17	5 16	jca	$⊢ (A \subseteq ℝ^{*} \land \forall x \in ℝ \exists y \in A x < y) \to (\forall z \in A \neg +∞ < z \land \forall z \in ℝ (z < +∞ \to \exists y \in A z < y))$
18		pnfxr	$⊢ +∞ \in ℝ^{*}$
19		supxr	$⊢ ((A \subseteq ℝ^{} \land +∞ \in ℝ^{}) \land (\forall z \in A \neg +∞ < z \land \forall z \in ℝ (z < +∞ \to \exists y \in A z < y))) \to sup (A ℝ^{*} <) = +∞$
20	18 19	mpanl2	$⊢ (A \subseteq ℝ^{} \land (\forall z \in A \neg +∞ < z \land \forall z \in ℝ (z < +∞ \to \exists y \in A z < y))) \to sup (A ℝ^{} <) = +∞$
21	17 20	syldan	$⊢ (A \subseteq ℝ^{} \land \forall x \in ℝ \exists y \in A x < y) \to sup (A ℝ^{} <) = +∞$
22	21	ex	$⊢ A \subseteq ℝ^{} \to (\forall x \in ℝ \exists y \in A x < y \to sup (A ℝ^{} <) = +∞)$
23		rexr	$⊢ x \in ℝ \to x \in ℝ^{*}$
24	23	ad2antlr	$⊢ ((A \subseteq ℝ^{} \land x \in ℝ) \land sup (A ℝ^{} <) = +∞) \to x \in ℝ^{*}$
25		ltpnf	$⊢ x \in ℝ \to x < +∞$
26		breq2	$⊢ sup (A ℝ^{} <) = +∞ \to (x < sup (A ℝ^{} <) \leftrightarrow x < +∞)$
27	25 26	syl5ibr	$⊢ sup (A ℝ^{} <) = +∞ \to (x \in ℝ \to x < sup (A ℝ^{} <))$
28	27	impcom	$⊢ (x \in ℝ \land sup (A ℝ^{} <) = +∞) \to x < sup (A ℝ^{} <)$
29	28	adantll	$⊢ ((A \subseteq ℝ^{} \land x \in ℝ) \land sup (A ℝ^{} <) = +∞) \to x < sup (A ℝ^{*} <)$
30		xrltso	$⊢ < Or ℝ^{*}$
31	30	a1i	$⊢ ((A \subseteq ℝ^{} \land x \in ℝ) \land sup (A ℝ^{} <) = +∞) \to < Or ℝ^{*}$
32		xrsupss	$⊢ A \subseteq ℝ^{} \to \exists z \in ℝ^{} (\forall w \in A \neg z < w \land \forall w \in ℝ^{*} (w < z \to \exists y \in A w < y))$
33	32	ad2antrr	$⊢ ((A \subseteq ℝ^{} \land x \in ℝ) \land sup (A ℝ^{} <) = +∞) \to \exists z \in ℝ^{} (\forall w \in A \neg z < w \land \forall w \in ℝ^{} (w < z \to \exists y \in A w < y))$
34	31 33	suplub	$⊢ ((A \subseteq ℝ^{} \land x \in ℝ) \land sup (A ℝ^{} <) = +∞) \to ((x \in ℝ^{} \land x < sup (A ℝ^{} <)) \to \exists y \in A x < y)$
35	24 29 34	mp2and	$⊢ ((A \subseteq ℝ^{} \land x \in ℝ) \land sup (A ℝ^{} <) = +∞) \to \exists y \in A x < y$
36	35	exp31	$⊢ A \subseteq ℝ^{} \to (x \in ℝ \to (sup (A ℝ^{} <) = +∞ \to \exists y \in A x < y))$
37	36	com23	$⊢ A \subseteq ℝ^{} \to (sup (A ℝ^{} <) = +∞ \to (x \in ℝ \to \exists y \in A x < y))$
38	37	ralrimdv	$⊢ A \subseteq ℝ^{} \to (sup (A ℝ^{} <) = +∞ \to \forall x \in ℝ \exists y \in A x < y)$
39	22 38	impbid	$⊢ A \subseteq ℝ^{} \to (\forall x \in ℝ \exists y \in A x < y \leftrightarrow sup (A ℝ^{} <) = +∞)$

Metamath Proof Explorer

Theorem supxrunb2

Proof