ipoglb

Description: The GLB of the inclusion poset. (hypotheses "ipolub.s" and "ipoglb.t" could be eliminated with S e. dom G .) Could be significantly shortened if posglbdg is in quantified form. mrelatglb could potentially be shortened using this. See mrelatglbALT . (Contributed by Zhi Wang, 29-Sep-2024)

	Ref	Expression
Hypotheses	ipolub.i	$⊢ I = toInc (F)$
	ipolub.f	$⊢ φ \to F \in V$
	ipolub.s	$⊢ φ \to S \subseteq F$
	ipoglb.g	$⊢ φ \to G = glb (I)$
	ipoglbdm.t	$⊢ φ \to T = ⋃ \{x \in F \| x \subseteq ⋂ S\}$
	ipoglb.t	$⊢ φ \to T \in F$
Assertion	ipoglb	$⊢ φ \to G (S) = T$

Proof

Step	Hyp	Ref	Expression
1		ipolub.i	$⊢ I = toInc (F)$
2		ipolub.f	$⊢ φ \to F \in V$
3		ipolub.s	$⊢ φ \to S \subseteq F$
4		ipoglb.g	$⊢ φ \to G = glb (I)$
5		ipoglbdm.t	$⊢ φ \to T = ⋃ \{x \in F \| x \subseteq ⋂ S\}$
6		ipoglb.t	$⊢ φ \to T \in F$
7		eqid	$⊢ \leq_{I} = \leq_{I}$
8	1	ipobas	$⊢ F \in V \to F = {Base}_{I}$
9	2 8	syl	$⊢ φ \to F = {Base}_{I}$
10	1	ipopos	$⊢ I \in Poset$
11	10	a1i	$⊢ φ \to I \in Poset$
12		breq2	$⊢ y = v \to (T \leq_{I} y \leftrightarrow T \leq_{I} v)$
13		unilbeu	$⊢ T \in F \to ((T \subseteq ⋂ S \land \forall z \in F (z \subseteq ⋂ S \to z \subseteq T)) \leftrightarrow T = ⋃ \{x \in F \| x \subseteq ⋂ S\})$
14	13	biimpar	$⊢ (T \in F \land T = ⋃ \{x \in F \| x \subseteq ⋂ S\}) \to (T \subseteq ⋂ S \land \forall z \in F (z \subseteq ⋂ S \to z \subseteq T))$
15	6 5 14	syl2anc	$⊢ φ \to (T \subseteq ⋂ S \land \forall z \in F (z \subseteq ⋂ S \to z \subseteq T))$
16	1 2 3 7	ipoglblem	$⊢ (φ \land T \in F) \to ((T \subseteq ⋂ S \land \forall z \in F (z \subseteq ⋂ S \to z \subseteq T)) \leftrightarrow (\forall y \in S T \leq_{I} y \land \forall z \in F (\forall y \in S z \leq_{I} y \to z \leq_{I} T)))$
17	6 16	mpdan	$⊢ φ \to ((T \subseteq ⋂ S \land \forall z \in F (z \subseteq ⋂ S \to z \subseteq T)) \leftrightarrow (\forall y \in S T \leq_{I} y \land \forall z \in F (\forall y \in S z \leq_{I} y \to z \leq_{I} T)))$
18	15 17	mpbid	$⊢ φ \to (\forall y \in S T \leq_{I} y \land \forall z \in F (\forall y \in S z \leq_{I} y \to z \leq_{I} T))$
19	18	simpld	$⊢ φ \to \forall y \in S T \leq_{I} y$
20	19	adantr	$⊢ (φ \land v \in S) \to \forall y \in S T \leq_{I} y$
21		simpr	$⊢ (φ \land v \in S) \to v \in S$
22	12 20 21	rspcdva	$⊢ (φ \land v \in S) \to T \leq_{I} v$
23		breq1	$⊢ z = w \to (z \leq_{I} y \leftrightarrow w \leq_{I} y)$
24	23	ralbidv	$⊢ z = w \to (\forall y \in S z \leq_{I} y \leftrightarrow \forall y \in S w \leq_{I} y)$
25		breq2	$⊢ y = v \to (w \leq_{I} y \leftrightarrow w \leq_{I} v)$
26	25	cbvralvw	$⊢ \forall y \in S w \leq_{I} y \leftrightarrow \forall v \in S w \leq_{I} v$
27	24 26	bitrdi	$⊢ z = w \to (\forall y \in S z \leq_{I} y \leftrightarrow \forall v \in S w \leq_{I} v)$
28		breq1	$⊢ z = w \to (z \leq_{I} T \leftrightarrow w \leq_{I} T)$
29	27 28	imbi12d	$⊢ z = w \to ((\forall y \in S z \leq_{I} y \to z \leq_{I} T) \leftrightarrow (\forall v \in S w \leq_{I} v \to w \leq_{I} T))$
30	18	simprd	$⊢ φ \to \forall z \in F (\forall y \in S z \leq_{I} y \to z \leq_{I} T)$
31	30	adantr	$⊢ (φ \land w \in F) \to \forall z \in F (\forall y \in S z \leq_{I} y \to z \leq_{I} T)$
32		simpr	$⊢ (φ \land w \in F) \to w \in F$
33	29 31 32	rspcdva	$⊢ (φ \land w \in F) \to (\forall v \in S w \leq_{I} v \to w \leq_{I} T)$
34	33	3impia	$⊢ (φ \land w \in F \land \forall v \in S w \leq_{I} v) \to w \leq_{I} T$
35	7 9 4 11 3 6 22 34	posglbdg	$⊢ φ \to G (S) = T$

Metamath Proof Explorer

Theorem ipoglb

Proof