infnsuprnmpt

Description: The indexed infimum of real numbers is the negative of the indexed supremum of the negative values. (Contributed by Glauco Siliprandi, 23-Oct-2021)

	Ref	Expression
Hypotheses	infnsuprnmpt.x	\|- F/ x ph
	infnsuprnmpt.a	\|- ( ph -> A =/= (/) )
	infnsuprnmpt.b	\|- ( ( ph /\ x e. A ) -> B e. RR )
	infnsuprnmpt.l	\|- ( ph -> E. y e. RR A. x e. A y <_ B )
Assertion	infnsuprnmpt	\|- ( ph -> inf ( ran ( x e. A \|-> B ) , RR , < ) = -u sup ( ran ( x e. A \|-> -u B ) , RR , < ) )

Proof

Step	Hyp	Ref	Expression
1		infnsuprnmpt.x	\|- F/ x ph
2		infnsuprnmpt.a	\|- ( ph -> A =/= (/) )
3		infnsuprnmpt.b	\|- ( ( ph /\ x e. A ) -> B e. RR )
4		infnsuprnmpt.l	\|- ( ph -> E. y e. RR A. x e. A y <_ B )
5		eqid	\|- ( x e. A \|-> B ) = ( x e. A \|-> B )
6	1 5 3	rnmptssd	\|- ( ph -> ran ( x e. A \|-> B ) C_ RR )
7	1 3 5 2	rnmptn0	\|- ( ph -> ran ( x e. A \|-> B ) =/= (/) )
8	4	rnmptlb	\|- ( ph -> E. y e. RR A. z e. ran ( x e. A \|-> B ) y <_ z )
9		infrenegsup	\|- ( ( ran ( x e. A \|-> B ) C_ RR /\ ran ( x e. A \|-> B ) =/= (/) /\ E. y e. RR A. z e. ran ( x e. A \|-> B ) y <_ z ) -> inf ( ran ( x e. A \|-> B ) , RR , < ) = -u sup ( { w e. RR \| -u w e. ran ( x e. A \|-> B ) } , RR , < ) )
10	6 7 8 9	syl3anc	\|- ( ph -> inf ( ran ( x e. A \|-> B ) , RR , < ) = -u sup ( { w e. RR \| -u w e. ran ( x e. A \|-> B ) } , RR , < ) )
11		eqid	\|- ( x e. A \|-> -u B ) = ( x e. A \|-> -u B )
12		rabidim2	\|- ( w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } -> -u w e. ran ( x e. A \|-> B ) )
13	12	adantl	\|- ( ( ph /\ w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } ) -> -u w e. ran ( x e. A \|-> B ) )
14		negex	\|- -u w e. _V
15	5	elrnmpt	\|- ( -u w e. _V -> ( -u w e. ran ( x e. A \|-> B ) <-> E. x e. A -u w = B ) )
16	14 15	ax-mp	\|- ( -u w e. ran ( x e. A \|-> B ) <-> E. x e. A -u w = B )
17	13 16	sylib	\|- ( ( ph /\ w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } ) -> E. x e. A -u w = B )
18		nfcv	\|- F/_ x w
19	18	nfneg	\|- F/_ x -u w
20		nfmpt1	\|- F/_ x ( x e. A \|-> B )
21	20	nfrn	\|- F/_ x ran ( x e. A \|-> B )
22	19 21	nfel	\|- F/ x -u w e. ran ( x e. A \|-> B )
23		nfcv	\|- F/_ x RR
24	22 23	nfrabw	\|- F/_ x { w e. RR \| -u w e. ran ( x e. A \|-> B ) }
25	18 24	nfel	\|- F/ x w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) }
26	1 25	nfan	\|- F/ x ( ph /\ w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } )
27		rabidim1	\|- ( w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } -> w e. RR )
28	27	adantl	\|- ( ( ph /\ w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } ) -> w e. RR )
29		negeq	\|- ( -u w = B -> -u -u w = -u B )
30	29	eqcomd	\|- ( -u w = B -> -u B = -u -u w )
31	30	3ad2ant3	\|- ( ( ( ph /\ w e. RR ) /\ x e. A /\ -u w = B ) -> -u B = -u -u w )
32		simp1r	\|- ( ( ( ph /\ w e. RR ) /\ x e. A /\ -u w = B ) -> w e. RR )
33		recn	\|- ( w e. RR -> w e. CC )
34	33	negnegd	\|- ( w e. RR -> -u -u w = w )
35	32 34	syl	\|- ( ( ( ph /\ w e. RR ) /\ x e. A /\ -u w = B ) -> -u -u w = w )
36	31 35	eqtr2d	\|- ( ( ( ph /\ w e. RR ) /\ x e. A /\ -u w = B ) -> w = -u B )
37	36	3exp	\|- ( ( ph /\ w e. RR ) -> ( x e. A -> ( -u w = B -> w = -u B ) ) )
38	28 37	syldan	\|- ( ( ph /\ w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } ) -> ( x e. A -> ( -u w = B -> w = -u B ) ) )
39	26 38	reximdai	\|- ( ( ph /\ w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } ) -> ( E. x e. A -u w = B -> E. x e. A w = -u B ) )
40	17 39	mpd	\|- ( ( ph /\ w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } ) -> E. x e. A w = -u B )
41		simpr	\|- ( ( ph /\ w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } ) -> w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } )
42	11 40 41	elrnmptd	\|- ( ( ph /\ w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } ) -> w e. ran ( x e. A \|-> -u B ) )
43	42	ex	\|- ( ph -> ( w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } -> w e. ran ( x e. A \|-> -u B ) ) )
44		vex	\|- w e. _V
45	11	elrnmpt	\|- ( w e. _V -> ( w e. ran ( x e. A \|-> -u B ) <-> E. x e. A w = -u B ) )
46	44 45	ax-mp	\|- ( w e. ran ( x e. A \|-> -u B ) <-> E. x e. A w = -u B )
47	46	bilani	\|- ( ( ph /\ w e. ran ( x e. A \|-> -u B ) ) -> E. x e. A w = -u B )
48	18 23	nfel	\|- F/ x w e. RR
49	48 22	nfan	\|- F/ x ( w e. RR /\ -u w e. ran ( x e. A \|-> B ) )
50		simp3	\|- ( ( ph /\ x e. A /\ w = -u B ) -> w = -u B )
51	3	renegcld	\|- ( ( ph /\ x e. A ) -> -u B e. RR )
52	51	3adant3	\|- ( ( ph /\ x e. A /\ w = -u B ) -> -u B e. RR )
53	50 52	eqeltrd	\|- ( ( ph /\ x e. A /\ w = -u B ) -> w e. RR )
54		simp2	\|- ( ( ph /\ x e. A /\ w = -u B ) -> x e. A )
55	50	negeqd	\|- ( ( ph /\ x e. A /\ w = -u B ) -> -u w = -u -u B )
56	3	recnd	\|- ( ( ph /\ x e. A ) -> B e. CC )
57	56	negnegd	\|- ( ( ph /\ x e. A ) -> -u -u B = B )
58	57	3adant3	\|- ( ( ph /\ x e. A /\ w = -u B ) -> -u -u B = B )
59	55 58	eqtrd	\|- ( ( ph /\ x e. A /\ w = -u B ) -> -u w = B )
60		rspe	\|- ( ( x e. A /\ -u w = B ) -> E. x e. A -u w = B )
61	54 59 60	syl2anc	\|- ( ( ph /\ x e. A /\ w = -u B ) -> E. x e. A -u w = B )
62	14	a1i	\|- ( ( ph /\ x e. A /\ w = -u B ) -> -u w e. _V )
63	5 61 62	elrnmptd	\|- ( ( ph /\ x e. A /\ w = -u B ) -> -u w e. ran ( x e. A \|-> B ) )
64	53 63	jca	\|- ( ( ph /\ x e. A /\ w = -u B ) -> ( w e. RR /\ -u w e. ran ( x e. A \|-> B ) ) )
65	64	3exp	\|- ( ph -> ( x e. A -> ( w = -u B -> ( w e. RR /\ -u w e. ran ( x e. A \|-> B ) ) ) ) )
66	1 49 65	rexlimd	\|- ( ph -> ( E. x e. A w = -u B -> ( w e. RR /\ -u w e. ran ( x e. A \|-> B ) ) ) )
67	66	imp	\|- ( ( ph /\ E. x e. A w = -u B ) -> ( w e. RR /\ -u w e. ran ( x e. A \|-> B ) ) )
68	47 67	syldan	\|- ( ( ph /\ w e. ran ( x e. A \|-> -u B ) ) -> ( w e. RR /\ -u w e. ran ( x e. A \|-> B ) ) )
69		rabid	\|- ( w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } <-> ( w e. RR /\ -u w e. ran ( x e. A \|-> B ) ) )
70	68 69	sylibr	\|- ( ( ph /\ w e. ran ( x e. A \|-> -u B ) ) -> w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } )
71	70	ex	\|- ( ph -> ( w e. ran ( x e. A \|-> -u B ) -> w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } ) )
72	43 71	impbid	\|- ( ph -> ( w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } <-> w e. ran ( x e. A \|-> -u B ) ) )
73	72	alrimiv	\|- ( ph -> A. w ( w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } <-> w e. ran ( x e. A \|-> -u B ) ) )
74		nfrab1	\|- F/_ w { w e. RR \| -u w e. ran ( x e. A \|-> B ) }
75		nfcv	\|- F/_ w ran ( x e. A \|-> -u B )
76	74 75	cleqf	\|- ( { w e. RR \| -u w e. ran ( x e. A \|-> B ) } = ran ( x e. A \|-> -u B ) <-> A. w ( w e. { w e. RR \| -u w e. ran ( x e. A \|-> B ) } <-> w e. ran ( x e. A \|-> -u B ) ) )
77	73 76	sylibr	\|- ( ph -> { w e. RR \| -u w e. ran ( x e. A \|-> B ) } = ran ( x e. A \|-> -u B ) )
78	77	supeq1d	\|- ( ph -> sup ( { w e. RR \| -u w e. ran ( x e. A \|-> B ) } , RR , < ) = sup ( ran ( x e. A \|-> -u B ) , RR , < ) )
79	78	negeqd	\|- ( ph -> -u sup ( { w e. RR \| -u w e. ran ( x e. A \|-> B ) } , RR , < ) = -u sup ( ran ( x e. A \|-> -u B ) , RR , < ) )
80		eqidd	\|- ( ph -> -u sup ( ran ( x e. A \|-> -u B ) , RR , < ) = -u sup ( ran ( x e. A \|-> -u B ) , RR , < ) )
81	10 79 80	3eqtrd	\|- ( ph -> inf ( ran ( x e. A \|-> B ) , RR , < ) = -u sup ( ran ( x e. A \|-> -u B ) , RR , < ) )

Metamath Proof Explorer

Theorem infnsuprnmpt

Proof