dalem25

Description: Lemma for dath . Show that the dummy center of perspectivity c is different from auxiliary atom G . (Contributed by NM, 3-Aug-2012)

	Ref	Expression
Hypotheses	dalem.ph	$⊢ φ \leftrightarrow (((K \in HL \land C \in {Base}_{K}) \land (P \in A \land Q \in A \land R \in A) \land (S \in A \land T \in A \land U \in A)) \land (Y \in O \land Z \in O) \land ((\neg C \underset{˙}{\leq} (P \underset{˙}{\lor} Q) \land \neg C \underset{˙}{\leq} (Q \underset{˙}{\lor} R) \land \neg C \underset{˙}{\leq} (R \underset{˙}{\lor} P)) \land (\neg C \underset{˙}{\leq} (S \underset{˙}{\lor} T) \land \neg C \underset{˙}{\leq} (T \underset{˙}{\lor} U) \land \neg C \underset{˙}{\leq} (U \underset{˙}{\lor} S)) \land (C \underset{˙}{\leq} (P \underset{˙}{\lor} S) \land C \underset{˙}{\leq} (Q \underset{˙}{\lor} T) \land C \underset{˙}{\leq} (R \underset{˙}{\lor} U))))$
	dalem.l	$⊢ \underset{˙}{\leq} = \leq_{K}$
	dalem.j	$⊢ \underset{˙}{\lor} = join (K)$
	dalem.a	$⊢ A = Atoms (K)$
	dalem.ps	$⊢ ψ \leftrightarrow ((c \in A \land d \in A) \land \neg c \underset{˙}{\leq} Y \land (d \neq c \land \neg d \underset{˙}{\leq} Y \land C \underset{˙}{\leq} (c \underset{˙}{\lor} d)))$
	dalem23.m	$⊢ \underset{˙}{\land} = meet (K)$
	dalem23.o	$⊢ O = LPlanes (K)$
	dalem23.y	$⊢ Y = (P \underset{˙}{\lor} Q) \underset{˙}{\lor} R$
	dalem23.z	$⊢ Z = (S \underset{˙}{\lor} T) \underset{˙}{\lor} U$
	dalem23.g	$⊢ G = (c \underset{˙}{\lor} P) \underset{˙}{\land} (d \underset{˙}{\lor} S)$
Assertion	dalem25	$⊢ (φ \land Y = Z \land ψ) \to c \neq G$

Proof

Step	Hyp	Ref	Expression
1		dalem.ph	$⊢ φ \leftrightarrow (((K \in HL \land C \in {Base}_{K}) \land (P \in A \land Q \in A \land R \in A) \land (S \in A \land T \in A \land U \in A)) \land (Y \in O \land Z \in O) \land ((\neg C \underset{˙}{\leq} (P \underset{˙}{\lor} Q) \land \neg C \underset{˙}{\leq} (Q \underset{˙}{\lor} R) \land \neg C \underset{˙}{\leq} (R \underset{˙}{\lor} P)) \land (\neg C \underset{˙}{\leq} (S \underset{˙}{\lor} T) \land \neg C \underset{˙}{\leq} (T \underset{˙}{\lor} U) \land \neg C \underset{˙}{\leq} (U \underset{˙}{\lor} S)) \land (C \underset{˙}{\leq} (P \underset{˙}{\lor} S) \land C \underset{˙}{\leq} (Q \underset{˙}{\lor} T) \land C \underset{˙}{\leq} (R \underset{˙}{\lor} U))))$
2		dalem.l	$⊢ \underset{˙}{\leq} = \leq_{K}$
3		dalem.j	$⊢ \underset{˙}{\lor} = join (K)$
4		dalem.a	$⊢ A = Atoms (K)$
5		dalem.ps	$⊢ ψ \leftrightarrow ((c \in A \land d \in A) \land \neg c \underset{˙}{\leq} Y \land (d \neq c \land \neg d \underset{˙}{\leq} Y \land C \underset{˙}{\leq} (c \underset{˙}{\lor} d)))$
6		dalem23.m	$⊢ \underset{˙}{\land} = meet (K)$
7		dalem23.o	$⊢ O = LPlanes (K)$
8		dalem23.y	$⊢ Y = (P \underset{˙}{\lor} Q) \underset{˙}{\lor} R$
9		dalem23.z	$⊢ Z = (S \underset{˙}{\lor} T) \underset{˙}{\lor} U$
10		dalem23.g	$⊢ G = (c \underset{˙}{\lor} P) \underset{˙}{\land} (d \underset{˙}{\lor} S)$
11	1 2 3 4	dalemcnes	$⊢ φ \to C \neq S$
12	11	3ad2ant1	$⊢ (φ \land Y = Z \land ψ) \to C \neq S$
13	5	dalemclccjdd	$⊢ ψ \to C \underset{˙}{\leq} (c \underset{˙}{\lor} d)$
14	13	3ad2ant3	$⊢ (φ \land Y = Z \land ψ) \to C \underset{˙}{\leq} (c \underset{˙}{\lor} d)$
15	14	adantr	$⊢ ((φ \land Y = Z \land ψ) \land c = G) \to C \underset{˙}{\leq} (c \underset{˙}{\lor} d)$
16		simpr	$⊢ ((φ \land Y = Z \land ψ) \land c = G) \to c = G$
17	1	dalemkelat	$⊢ φ \to K \in Lat$
18	17	3ad2ant1	$⊢ (φ \land Y = Z \land ψ) \to K \in Lat$
19	1	dalemkehl	$⊢ φ \to K \in HL$
20	19	3ad2ant1	$⊢ (φ \land Y = Z \land ψ) \to K \in HL$
21	5	dalemccea	$⊢ ψ \to c \in A$
22	21	3ad2ant3	$⊢ (φ \land Y = Z \land ψ) \to c \in A$
23	1	dalempea	$⊢ φ \to P \in A$
24	23	3ad2ant1	$⊢ (φ \land Y = Z \land ψ) \to P \in A$
25		eqid	$⊢ {Base}_{K} = {Base}_{K}$
26	25 3 4	hlatjcl	$⊢ (K \in HL \land c \in A \land P \in A) \to c \underset{˙}{\lor} P \in {Base}_{K}$
27	20 22 24 26	syl3anc	$⊢ (φ \land Y = Z \land ψ) \to c \underset{˙}{\lor} P \in {Base}_{K}$
28	5	dalemddea	$⊢ ψ \to d \in A$
29	28	3ad2ant3	$⊢ (φ \land Y = Z \land ψ) \to d \in A$
30	1	dalemsea	$⊢ φ \to S \in A$
31	30	3ad2ant1	$⊢ (φ \land Y = Z \land ψ) \to S \in A$
32	25 3 4	hlatjcl	$⊢ (K \in HL \land d \in A \land S \in A) \to d \underset{˙}{\lor} S \in {Base}_{K}$
33	20 29 31 32	syl3anc	$⊢ (φ \land Y = Z \land ψ) \to d \underset{˙}{\lor} S \in {Base}_{K}$
34	25 2 6	latmle2	$⊢ (K \in Lat \land c \underset{˙}{\lor} P \in {Base}_{K} \land d \underset{˙}{\lor} S \in {Base}_{K}) \to ((c \underset{˙}{\lor} P) \underset{˙}{\land} (d \underset{˙}{\lor} S)) \underset{˙}{\leq} (d \underset{˙}{\lor} S)$
35	18 27 33 34	syl3anc	$⊢ (φ \land Y = Z \land ψ) \to ((c \underset{˙}{\lor} P) \underset{˙}{\land} (d \underset{˙}{\lor} S)) \underset{˙}{\leq} (d \underset{˙}{\lor} S)$
36	10 35	eqbrtrid	$⊢ (φ \land Y = Z \land ψ) \to G \underset{˙}{\leq} (d \underset{˙}{\lor} S)$
37	3 4	hlatjcom	$⊢ (K \in HL \land d \in A \land S \in A) \to d \underset{˙}{\lor} S = S \underset{˙}{\lor} d$
38	20 29 31 37	syl3anc	$⊢ (φ \land Y = Z \land ψ) \to d \underset{˙}{\lor} S = S \underset{˙}{\lor} d$
39	36 38	breqtrd	$⊢ (φ \land Y = Z \land ψ) \to G \underset{˙}{\leq} (S \underset{˙}{\lor} d)$
40	39	adantr	$⊢ ((φ \land Y = Z \land ψ) \land c = G) \to G \underset{˙}{\leq} (S \underset{˙}{\lor} d)$
41	16 40	eqbrtrd	$⊢ ((φ \land Y = Z \land ψ) \land c = G) \to c \underset{˙}{\leq} (S \underset{˙}{\lor} d)$
42	2 3 4	hlatlej2	$⊢ (K \in HL \land S \in A \land d \in A) \to d \underset{˙}{\leq} (S \underset{˙}{\lor} d)$
43	20 31 29 42	syl3anc	$⊢ (φ \land Y = Z \land ψ) \to d \underset{˙}{\leq} (S \underset{˙}{\lor} d)$
44	43	adantr	$⊢ ((φ \land Y = Z \land ψ) \land c = G) \to d \underset{˙}{\leq} (S \underset{˙}{\lor} d)$
45	5 4	dalemcceb	$⊢ ψ \to c \in {Base}_{K}$
46	45	3ad2ant3	$⊢ (φ \land Y = Z \land ψ) \to c \in {Base}_{K}$
47	25 4	atbase	$⊢ d \in A \to d \in {Base}_{K}$
48	28 47	syl	$⊢ ψ \to d \in {Base}_{K}$
49	48	3ad2ant3	$⊢ (φ \land Y = Z \land ψ) \to d \in {Base}_{K}$
50	25 3 4	hlatjcl	$⊢ (K \in HL \land S \in A \land d \in A) \to S \underset{˙}{\lor} d \in {Base}_{K}$
51	20 31 29 50	syl3anc	$⊢ (φ \land Y = Z \land ψ) \to S \underset{˙}{\lor} d \in {Base}_{K}$
52	25 2 3	latjle12	$⊢ (K \in Lat \land (c \in {Base}_{K} \land d \in {Base}_{K} \land S \underset{˙}{\lor} d \in {Base}_{K})) \to ((c \underset{˙}{\leq} (S \underset{˙}{\lor} d) \land d \underset{˙}{\leq} (S \underset{˙}{\lor} d)) \leftrightarrow (c \underset{˙}{\lor} d) \underset{˙}{\leq} (S \underset{˙}{\lor} d))$
53	18 46 49 51 52	syl13anc	$⊢ (φ \land Y = Z \land ψ) \to ((c \underset{˙}{\leq} (S \underset{˙}{\lor} d) \land d \underset{˙}{\leq} (S \underset{˙}{\lor} d)) \leftrightarrow (c \underset{˙}{\lor} d) \underset{˙}{\leq} (S \underset{˙}{\lor} d))$
54	53	adantr	$⊢ ((φ \land Y = Z \land ψ) \land c = G) \to ((c \underset{˙}{\leq} (S \underset{˙}{\lor} d) \land d \underset{˙}{\leq} (S \underset{˙}{\lor} d)) \leftrightarrow (c \underset{˙}{\lor} d) \underset{˙}{\leq} (S \underset{˙}{\lor} d))$
55	41 44 54	mpbi2and	$⊢ ((φ \land Y = Z \land ψ) \land c = G) \to (c \underset{˙}{\lor} d) \underset{˙}{\leq} (S \underset{˙}{\lor} d)$
56	1 4	dalemceb	$⊢ φ \to C \in {Base}_{K}$
57	56	3ad2ant1	$⊢ (φ \land Y = Z \land ψ) \to C \in {Base}_{K}$
58	25 3 4	hlatjcl	$⊢ (K \in HL \land c \in A \land d \in A) \to c \underset{˙}{\lor} d \in {Base}_{K}$
59	20 22 29 58	syl3anc	$⊢ (φ \land Y = Z \land ψ) \to c \underset{˙}{\lor} d \in {Base}_{K}$
60	25 2	lattr	$⊢ (K \in Lat \land (C \in {Base}_{K} \land c \underset{˙}{\lor} d \in {Base}_{K} \land S \underset{˙}{\lor} d \in {Base}_{K})) \to ((C \underset{˙}{\leq} (c \underset{˙}{\lor} d) \land (c \underset{˙}{\lor} d) \underset{˙}{\leq} (S \underset{˙}{\lor} d)) \to C \underset{˙}{\leq} (S \underset{˙}{\lor} d))$
61	18 57 59 51 60	syl13anc	$⊢ (φ \land Y = Z \land ψ) \to ((C \underset{˙}{\leq} (c \underset{˙}{\lor} d) \land (c \underset{˙}{\lor} d) \underset{˙}{\leq} (S \underset{˙}{\lor} d)) \to C \underset{˙}{\leq} (S \underset{˙}{\lor} d))$
62	61	adantr	$⊢ ((φ \land Y = Z \land ψ) \land c = G) \to ((C \underset{˙}{\leq} (c \underset{˙}{\lor} d) \land (c \underset{˙}{\lor} d) \underset{˙}{\leq} (S \underset{˙}{\lor} d)) \to C \underset{˙}{\leq} (S \underset{˙}{\lor} d))$
63	15 55 62	mp2and	$⊢ ((φ \land Y = Z \land ψ) \land c = G) \to C \underset{˙}{\leq} (S \underset{˙}{\lor} d)$
64	1 7	dalemyeb	$⊢ φ \to Y \in {Base}_{K}$
65	64	3ad2ant1	$⊢ (φ \land Y = Z \land ψ) \to Y \in {Base}_{K}$
66	25 2 6	latmlem1	$⊢ (K \in Lat \land (C \in {Base}_{K} \land S \underset{˙}{\lor} d \in {Base}_{K} \land Y \in {Base}_{K})) \to (C \underset{˙}{\leq} (S \underset{˙}{\lor} d) \to (C \underset{˙}{\land} Y) \underset{˙}{\leq} ((S \underset{˙}{\lor} d) \underset{˙}{\land} Y))$
67	18 57 51 65 66	syl13anc	$⊢ (φ \land Y = Z \land ψ) \to (C \underset{˙}{\leq} (S \underset{˙}{\lor} d) \to (C \underset{˙}{\land} Y) \underset{˙}{\leq} ((S \underset{˙}{\lor} d) \underset{˙}{\land} Y))$
68	67	adantr	$⊢ ((φ \land Y = Z \land ψ) \land c = G) \to (C \underset{˙}{\leq} (S \underset{˙}{\lor} d) \to (C \underset{˙}{\land} Y) \underset{˙}{\leq} ((S \underset{˙}{\lor} d) \underset{˙}{\land} Y))$
69	63 68	mpd	$⊢ ((φ \land Y = Z \land ψ) \land c = G) \to (C \underset{˙}{\land} Y) \underset{˙}{\leq} ((S \underset{˙}{\lor} d) \underset{˙}{\land} Y)$
70	1 2 3 4 7 8 9	dalem17	$⊢ (φ \land Y = Z) \to C \underset{˙}{\leq} Y$
71	70	3adant3	$⊢ (φ \land Y = Z \land ψ) \to C \underset{˙}{\leq} Y$
72	25 2 6	latleeqm1	$⊢ (K \in Lat \land C \in {Base}_{K} \land Y \in {Base}_{K}) \to (C \underset{˙}{\leq} Y \leftrightarrow C \underset{˙}{\land} Y = C)$
73	18 57 65 72	syl3anc	$⊢ (φ \land Y = Z \land ψ) \to (C \underset{˙}{\leq} Y \leftrightarrow C \underset{˙}{\land} Y = C)$
74	71 73	mpbid	$⊢ (φ \land Y = Z \land ψ) \to C \underset{˙}{\land} Y = C$
75	74	adantr	$⊢ ((φ \land Y = Z \land ψ) \land c = G) \to C \underset{˙}{\land} Y = C$
76	1 2 3 4 9	dalemsly	$⊢ (φ \land Y = Z) \to S \underset{˙}{\leq} Y$
77	76	3adant3	$⊢ (φ \land Y = Z \land ψ) \to S \underset{˙}{\leq} Y$
78	5	dalem-ddly	$⊢ ψ \to \neg d \underset{˙}{\leq} Y$
79	78	3ad2ant3	$⊢ (φ \land Y = Z \land ψ) \to \neg d \underset{˙}{\leq} Y$
80	25 2 3 6 4	2atjm	$⊢ (K \in HL \land (S \in A \land d \in A \land Y \in {Base}_{K}) \land (S \underset{˙}{\leq} Y \land \neg d \underset{˙}{\leq} Y)) \to (S \underset{˙}{\lor} d) \underset{˙}{\land} Y = S$
81	20 31 29 65 77 79 80	syl132anc	$⊢ (φ \land Y = Z \land ψ) \to (S \underset{˙}{\lor} d) \underset{˙}{\land} Y = S$
82	81	adantr	$⊢ ((φ \land Y = Z \land ψ) \land c = G) \to (S \underset{˙}{\lor} d) \underset{˙}{\land} Y = S$
83	69 75 82	3brtr3d	$⊢ ((φ \land Y = Z \land ψ) \land c = G) \to C \underset{˙}{\leq} S$
84		hlatl	$⊢ K \in HL \to K \in AtLat$
85	19 84	syl	$⊢ φ \to K \in AtLat$
86	1 2 3 4 7 8	dalemcea	$⊢ φ \to C \in A$
87	2 4	atcmp	$⊢ (K \in AtLat \land C \in A \land S \in A) \to (C \underset{˙}{\leq} S \leftrightarrow C = S)$
88	85 86 30 87	syl3anc	$⊢ φ \to (C \underset{˙}{\leq} S \leftrightarrow C = S)$
89	88	3ad2ant1	$⊢ (φ \land Y = Z \land ψ) \to (C \underset{˙}{\leq} S \leftrightarrow C = S)$
90	89	adantr	$⊢ ((φ \land Y = Z \land ψ) \land c = G) \to (C \underset{˙}{\leq} S \leftrightarrow C = S)$
91	83 90	mpbid	$⊢ ((φ \land Y = Z \land ψ) \land c = G) \to C = S$
92	91	ex	$⊢ (φ \land Y = Z \land ψ) \to (c = G \to C = S)$
93	92	necon3d	$⊢ (φ \land Y = Z \land ψ) \to (C \neq S \to c \neq G)$
94	12 93	mpd	$⊢ (φ \land Y = Z \land ψ) \to c \neq G$

Metamath Proof Explorer

Theorem dalem25

Proof