hdmap1l6d

	Ref	Expression
Hypotheses	hdmap1l6.h	$⊢ H = LHyp (K)$
	hdmap1l6.u	$⊢ U = DVecH (K) (W)$
	hdmap1l6.v	$⊢ V = {Base}_{U}$
	hdmap1l6.p	$⊢ \underset{˙}{+} = +_{U}$
	hdmap1l6.s	$⊢ \underset{˙}{-} = -_{U}$
	hdmap1l6c.o	$⊢ \underset{˙}{0} = 0_{U}$
	hdmap1l6.n	$⊢ N = LSpan (U)$
	hdmap1l6.c	$⊢ C = LCDual (K) (W)$
	hdmap1l6.d	$⊢ D = {Base}_{C}$
	hdmap1l6.a	$⊢ \underset{˙}{✚} = +_{C}$
	hdmap1l6.r	$⊢ R = -_{C}$
	hdmap1l6.q	$⊢ Q = 0_{C}$
	hdmap1l6.l	$⊢ L = LSpan (C)$
	hdmap1l6.m	$⊢ M = mapd (K) (W)$
	hdmap1l6.i	$⊢ I = HDMap1 (K) (W)$
	hdmap1l6.k	$⊢ φ \to (K \in HL \land W \in H)$
	hdmap1l6.f	$⊢ φ \to F \in D$
	hdmap1l6cl.x	$⊢ φ \to X \in (V ∖ \{\underset{˙}{0}\})$
	hdmap1l6.mn	$⊢ φ \to M (N (\{X\})) = L (\{F\})$
	hdmap1l6d.xn	$⊢ φ \to \neg X \in N (\{Y, Z\})$
	hdmap1l6d.yz	$⊢ φ \to N (\{Y\}) = N (\{Z\})$
	hdmap1l6d.y	$⊢ φ \to Y \in (V ∖ \{\underset{˙}{0}\})$
	hdmap1l6d.z	$⊢ φ \to Z \in (V ∖ \{\underset{˙}{0}\})$
	hdmap1l6d.w	$⊢ φ \to w \in (V ∖ \{\underset{˙}{0}\})$
	hdmap1l6d.wn	$⊢ φ \to \neg w \in N (\{X, Y\})$
Assertion	hdmap1l6d	$⊢ φ \to I (⟨X, F, w \underset{˙}{+} (Y \underset{˙}{+} Z)⟩) = I (⟨X, F, w⟩) \underset{˙}{✚} I (⟨X, F, Y \underset{˙}{+} Z⟩)$

Proof

Step	Hyp	Ref	Expression
1		hdmap1l6.h	$⊢ H = LHyp (K)$
2		hdmap1l6.u	$⊢ U = DVecH (K) (W)$
3		hdmap1l6.v	$⊢ V = {Base}_{U}$
4		hdmap1l6.p	$⊢ \underset{˙}{+} = +_{U}$
5		hdmap1l6.s	$⊢ \underset{˙}{-} = -_{U}$
6		hdmap1l6c.o	$⊢ \underset{˙}{0} = 0_{U}$
7		hdmap1l6.n	$⊢ N = LSpan (U)$
8		hdmap1l6.c	$⊢ C = LCDual (K) (W)$
9		hdmap1l6.d	$⊢ D = {Base}_{C}$
10		hdmap1l6.a	$⊢ \underset{˙}{✚} = +_{C}$
11		hdmap1l6.r	$⊢ R = -_{C}$
12		hdmap1l6.q	$⊢ Q = 0_{C}$
13		hdmap1l6.l	$⊢ L = LSpan (C)$
14		hdmap1l6.m	$⊢ M = mapd (K) (W)$
15		hdmap1l6.i	$⊢ I = HDMap1 (K) (W)$
16		hdmap1l6.k	$⊢ φ \to (K \in HL \land W \in H)$
17		hdmap1l6.f	$⊢ φ \to F \in D$
18		hdmap1l6cl.x	$⊢ φ \to X \in (V ∖ \{\underset{˙}{0}\})$
19		hdmap1l6.mn	$⊢ φ \to M (N (\{X\})) = L (\{F\})$
20		hdmap1l6d.xn	$⊢ φ \to \neg X \in N (\{Y, Z\})$
21		hdmap1l6d.yz	$⊢ φ \to N (\{Y\}) = N (\{Z\})$
22		hdmap1l6d.y	$⊢ φ \to Y \in (V ∖ \{\underset{˙}{0}\})$
23		hdmap1l6d.z	$⊢ φ \to Z \in (V ∖ \{\underset{˙}{0}\})$
24		hdmap1l6d.w	$⊢ φ \to w \in (V ∖ \{\underset{˙}{0}\})$
25		hdmap1l6d.wn	$⊢ φ \to \neg w \in N (\{X, Y\})$
26	1 8 16	lcdlmod	$⊢ φ \to C \in LMod$
27	1 2 16	dvhlvec	$⊢ φ \to U \in LVec$
28	24	eldifad	$⊢ φ \to w \in V$
29	18	eldifad	$⊢ φ \to X \in V$
30	22	eldifad	$⊢ φ \to Y \in V$
31	3 7 27 28 29 30 25	lspindpi	$⊢ φ \to (N (\{w\}) \neq N (\{X\}) \land N (\{w\}) \neq N (\{Y\}))$
32	31	simpld	$⊢ φ \to N (\{w\}) \neq N (\{X\})$
33	32	necomd	$⊢ φ \to N (\{X\}) \neq N (\{w\})$
34	1 2 3 6 7 8 9 13 14 15 16 17 19 33 18 28	hdmap1cl	$⊢ φ \to I (⟨X, F, w⟩) \in D$
35	9 10 12	lmod0vrid	$⊢ (C \in LMod \land I (⟨X, F, w⟩) \in D) \to I (⟨X, F, w⟩) \underset{˙}{✚} Q = I (⟨X, F, w⟩)$
36	26 34 35	syl2anc	$⊢ φ \to I (⟨X, F, w⟩) \underset{˙}{✚} Q = I (⟨X, F, w⟩)$
37	36	adantr	$⊢ (φ \land Y \underset{˙}{+} Z = \underset{˙}{0}) \to I (⟨X, F, w⟩) \underset{˙}{✚} Q = I (⟨X, F, w⟩)$
38		oteq3	$⊢ Y \underset{˙}{+} Z = \underset{˙}{0} \to ⟨X, F, Y \underset{˙}{+} Z⟩ = ⟨X, F, \underset{˙}{0}⟩$
39	38	fveq2d	$⊢ Y \underset{˙}{+} Z = \underset{˙}{0} \to I (⟨X, F, Y \underset{˙}{+} Z⟩) = I (⟨X, F, \underset{˙}{0}⟩)$
40	1 2 3 6 8 9 12 15 16 17 29	hdmap1val0	$⊢ φ \to I (⟨X, F, \underset{˙}{0}⟩) = Q$
41	39 40	sylan9eqr	$⊢ (φ \land Y \underset{˙}{+} Z = \underset{˙}{0}) \to I (⟨X, F, Y \underset{˙}{+} Z⟩) = Q$
42	41	oveq2d	$⊢ (φ \land Y \underset{˙}{+} Z = \underset{˙}{0}) \to I (⟨X, F, w⟩) \underset{˙}{✚} I (⟨X, F, Y \underset{˙}{+} Z⟩) = I (⟨X, F, w⟩) \underset{˙}{✚} Q$
43		oveq2	$⊢ Y \underset{˙}{+} Z = \underset{˙}{0} \to w \underset{˙}{+} (Y \underset{˙}{+} Z) = w \underset{˙}{+} \underset{˙}{0}$
44	1 2 16	dvhlmod	$⊢ φ \to U \in LMod$
45	3 4 6	lmod0vrid	$⊢ (U \in LMod \land w \in V) \to w \underset{˙}{+} \underset{˙}{0} = w$
46	44 28 45	syl2anc	$⊢ φ \to w \underset{˙}{+} \underset{˙}{0} = w$
47	43 46	sylan9eqr	$⊢ (φ \land Y \underset{˙}{+} Z = \underset{˙}{0}) \to w \underset{˙}{+} (Y \underset{˙}{+} Z) = w$
48	47	oteq3d	$⊢ (φ \land Y \underset{˙}{+} Z = \underset{˙}{0}) \to ⟨X, F, w \underset{˙}{+} (Y \underset{˙}{+} Z)⟩ = ⟨X, F, w⟩$
49	48	fveq2d	$⊢ (φ \land Y \underset{˙}{+} Z = \underset{˙}{0}) \to I (⟨X, F, w \underset{˙}{+} (Y \underset{˙}{+} Z)⟩) = I (⟨X, F, w⟩)$
50	37 42 49	3eqtr4rd	$⊢ (φ \land Y \underset{˙}{+} Z = \underset{˙}{0}) \to I (⟨X, F, w \underset{˙}{+} (Y \underset{˙}{+} Z)⟩) = I (⟨X, F, w⟩) \underset{˙}{✚} I (⟨X, F, Y \underset{˙}{+} Z⟩)$
51	16	adantr	$⊢ (φ \land Y \underset{˙}{+} Z \neq \underset{˙}{0}) \to (K \in HL \land W \in H)$
52	17	adantr	$⊢ (φ \land Y \underset{˙}{+} Z \neq \underset{˙}{0}) \to F \in D$
53	18	adantr	$⊢ (φ \land Y \underset{˙}{+} Z \neq \underset{˙}{0}) \to X \in (V ∖ \{\underset{˙}{0}\})$
54	19	adantr	$⊢ (φ \land Y \underset{˙}{+} Z \neq \underset{˙}{0}) \to M (N (\{X\})) = L (\{F\})$
55	24	adantr	$⊢ (φ \land Y \underset{˙}{+} Z \neq \underset{˙}{0}) \to w \in (V ∖ \{\underset{˙}{0}\})$
56	23	eldifad	$⊢ φ \to Z \in V$
57	3 4	lmodvacl	$⊢ (U \in LMod \land Y \in V \land Z \in V) \to Y \underset{˙}{+} Z \in V$
58	44 30 56 57	syl3anc	$⊢ φ \to Y \underset{˙}{+} Z \in V$
59	58	anim1i	$⊢ (φ \land Y \underset{˙}{+} Z \neq \underset{˙}{0}) \to (Y \underset{˙}{+} Z \in V \land Y \underset{˙}{+} Z \neq \underset{˙}{0})$
60		eldifsn	$⊢ Y \underset{˙}{+} Z \in (V ∖ \{\underset{˙}{0}\}) \leftrightarrow (Y \underset{˙}{+} Z \in V \land Y \underset{˙}{+} Z \neq \underset{˙}{0})$
61	59 60	sylibr	$⊢ (φ \land Y \underset{˙}{+} Z \neq \underset{˙}{0}) \to Y \underset{˙}{+} Z \in (V ∖ \{\underset{˙}{0}\})$
62	3 7 27 29 30 56 20	lspindpi	$⊢ φ \to (N (\{X\}) \neq N (\{Y\}) \land N (\{X\}) \neq N (\{Z\}))$
63	62	simpld	$⊢ φ \to N (\{X\}) \neq N (\{Y\})$
64	3 4 6 7 27 18 22 23 24 21 63 25	mapdindp1	$⊢ φ \to N (\{X\}) \neq N (\{Y \underset{˙}{+} Z\})$
65	3 4 6 7 27 18 22 23 24 21 63 25	mapdindp2	$⊢ φ \to \neg w \in N (\{X, Y \underset{˙}{+} Z\})$
66	3 6 7 27 18 58 28 64 65	lspindp1	$⊢ φ \to (N (\{w\}) \neq N (\{Y \underset{˙}{+} Z\}) \land \neg X \in N (\{w, Y \underset{˙}{+} Z\}))$
67	66	simprd	$⊢ φ \to \neg X \in N (\{w, Y \underset{˙}{+} Z\})$
68	67	adantr	$⊢ (φ \land Y \underset{˙}{+} Z \neq \underset{˙}{0}) \to \neg X \in N (\{w, Y \underset{˙}{+} Z\})$
69	31	simprd	$⊢ φ \to N (\{w\}) \neq N (\{Y\})$
70	3 6 7 27 24 30 69	lspsnne1	$⊢ φ \to \neg w \in N (\{Y\})$
71		eqid	$⊢ LSSum (U) = LSSum (U)$
72	3 7 71 44 30 56	lsmpr	$⊢ φ \to N (\{Y, Z\}) = N (\{Y\}) LSSum (U) N (\{Z\})$
73	21	oveq2d	$⊢ φ \to N (\{Y\}) LSSum (U) N (\{Y\}) = N (\{Y\}) LSSum (U) N (\{Z\})$
74		eqid	$⊢ LSubSp (U) = LSubSp (U)$
75	3 74 7	lspsncl	$⊢ (U \in LMod \land Y \in V) \to N (\{Y\}) \in LSubSp (U)$
76	44 30 75	syl2anc	$⊢ φ \to N (\{Y\}) \in LSubSp (U)$
77	74	lsssubg	$⊢ (U \in LMod \land N (\{Y\}) \in LSubSp (U)) \to N (\{Y\}) \in SubGrp (U)$
78	44 76 77	syl2anc	$⊢ φ \to N (\{Y\}) \in SubGrp (U)$
79	71	lsmidm	$⊢ N (\{Y\}) \in SubGrp (U) \to N (\{Y\}) LSSum (U) N (\{Y\}) = N (\{Y\})$
80	78 79	syl	$⊢ φ \to N (\{Y\}) LSSum (U) N (\{Y\}) = N (\{Y\})$
81	72 73 80	3eqtr2d	$⊢ φ \to N (\{Y, Z\}) = N (\{Y\})$
82	70 81	neleqtrrd	$⊢ φ \to \neg w \in N (\{Y, Z\})$
83	3 4 7 44 30 56 28 82	lspindp4	$⊢ φ \to \neg w \in N (\{Y, Y \underset{˙}{+} Z\})$
84	3 7 27 28 30 58 83	lspindpi	$⊢ φ \to (N (\{w\}) \neq N (\{Y\}) \land N (\{w\}) \neq N (\{Y \underset{˙}{+} Z\}))$
85	84	simprd	$⊢ φ \to N (\{w\}) \neq N (\{Y \underset{˙}{+} Z\})$
86	85	adantr	$⊢ (φ \land Y \underset{˙}{+} Z \neq \underset{˙}{0}) \to N (\{w\}) \neq N (\{Y \underset{˙}{+} Z\})$
87		eqidd	$⊢ (φ \land Y \underset{˙}{+} Z \neq \underset{˙}{0}) \to I (⟨X, F, w⟩) = I (⟨X, F, w⟩)$
88		eqidd	$⊢ (φ \land Y \underset{˙}{+} Z \neq \underset{˙}{0}) \to I (⟨X, F, Y \underset{˙}{+} Z⟩) = I (⟨X, F, Y \underset{˙}{+} Z⟩)$
89	1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 51 52 53 54 55 61 68 86 87 88	hdmap1l6a	$⊢ (φ \land Y \underset{˙}{+} Z \neq \underset{˙}{0}) \to I (⟨X, F, w \underset{˙}{+} (Y \underset{˙}{+} Z)⟩) = I (⟨X, F, w⟩) \underset{˙}{✚} I (⟨X, F, Y \underset{˙}{+} Z⟩)$
90	50 89	pm2.61dane	$⊢ φ \to I (⟨X, F, w \underset{˙}{+} (Y \underset{˙}{+} Z)⟩) = I (⟨X, F, w⟩) \underset{˙}{✚} I (⟨X, F, Y \underset{˙}{+} Z⟩)$

Metamath Proof Explorer

Theorem hdmap1l6d

Proof