mapdpglem26

Description: Lemma for mapdpg . Baer p. 45 line 14: "Consequently there exist numbers u,v in G neither of which is 0 such that y = uy'' and..." (We scope $d u ph locally to avoid clashes with later substitutions into ph .) (Contributed by NM, 22-Mar-2015)

	Ref	Expression
Hypotheses	mapdpg.h	$⊢ H = LHyp (K)$
	mapdpg.m	$⊢ M = mapd (K) (W)$
	mapdpg.u	$⊢ U = DVecH (K) (W)$
	mapdpg.v	$⊢ V = {Base}_{U}$
	mapdpg.s	$⊢ \underset{˙}{-} = -_{U}$
	mapdpg.z	$⊢ \underset{˙}{0} = 0_{U}$
	mapdpg.n	$⊢ N = LSpan (U)$
	mapdpg.c	$⊢ C = LCDual (K) (W)$
	mapdpg.f	$⊢ F = {Base}_{C}$
	mapdpg.r	$⊢ R = -_{C}$
	mapdpg.j	$⊢ J = LSpan (C)$
	mapdpg.k	$⊢ φ \to (K \in HL \land W \in H)$
	mapdpg.x	$⊢ φ \to X \in (V ∖ \{\underset{˙}{0}\})$
	mapdpg.y	$⊢ φ \to Y \in (V ∖ \{\underset{˙}{0}\})$
	mapdpg.g	$⊢ φ \to G \in F$
	mapdpg.ne	$⊢ φ \to N (\{X\}) \neq N (\{Y\})$
	mapdpg.e	$⊢ φ \to M (N (\{X\})) = J (\{G\})$
	mapdpgem25.h1	$⊢ φ \to (h \in F \land (M (N (\{Y\})) = J (\{h\}) \land M (N (\{X \underset{˙}{-} Y\})) = J (\{G R h\})))$
	mapdpgem25.i1	$⊢ φ \to (i \in F \land (M (N (\{Y\})) = J (\{i\}) \land M (N (\{X \underset{˙}{-} Y\})) = J (\{G R i\})))$
	mapdpglem26.a	$⊢ A = Scalar (U)$
	mapdpglem26.b	$⊢ B = {Base}_{A}$
	mapdpglem26.t	$⊢ \underset{˙}{\cdot} = \cdot_{C}$
	mapdpglem26.o	$⊢ O = 0_{A}$
Assertion	mapdpglem26	$⊢ φ \to \exists u \in (B ∖ \{O\}) h = u \underset{˙}{\cdot} i$

Proof

Step	Hyp	Ref	Expression
1		mapdpg.h	$⊢ H = LHyp (K)$
2		mapdpg.m	$⊢ M = mapd (K) (W)$
3		mapdpg.u	$⊢ U = DVecH (K) (W)$
4		mapdpg.v	$⊢ V = {Base}_{U}$
5		mapdpg.s	$⊢ \underset{˙}{-} = -_{U}$
6		mapdpg.z	$⊢ \underset{˙}{0} = 0_{U}$
7		mapdpg.n	$⊢ N = LSpan (U)$
8		mapdpg.c	$⊢ C = LCDual (K) (W)$
9		mapdpg.f	$⊢ F = {Base}_{C}$
10		mapdpg.r	$⊢ R = -_{C}$
11		mapdpg.j	$⊢ J = LSpan (C)$
12		mapdpg.k	$⊢ φ \to (K \in HL \land W \in H)$
13		mapdpg.x	$⊢ φ \to X \in (V ∖ \{\underset{˙}{0}\})$
14		mapdpg.y	$⊢ φ \to Y \in (V ∖ \{\underset{˙}{0}\})$
15		mapdpg.g	$⊢ φ \to G \in F$
16		mapdpg.ne	$⊢ φ \to N (\{X\}) \neq N (\{Y\})$
17		mapdpg.e	$⊢ φ \to M (N (\{X\})) = J (\{G\})$
18		mapdpgem25.h1	$⊢ φ \to (h \in F \land (M (N (\{Y\})) = J (\{h\}) \land M (N (\{X \underset{˙}{-} Y\})) = J (\{G R h\})))$
19		mapdpgem25.i1	$⊢ φ \to (i \in F \land (M (N (\{Y\})) = J (\{i\}) \land M (N (\{X \underset{˙}{-} Y\})) = J (\{G R i\})))$
20		mapdpglem26.a	$⊢ A = Scalar (U)$
21		mapdpglem26.b	$⊢ B = {Base}_{A}$
22		mapdpglem26.t	$⊢ \underset{˙}{\cdot} = \cdot_{C}$
23		mapdpglem26.o	$⊢ O = 0_{A}$
24	1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19	mapdpglem25	$⊢ φ \to (J (\{h\}) = J (\{i\}) \land J (\{G R h\}) = J (\{G R i\}))$
25	24	simpld	$⊢ φ \to J (\{h\}) = J (\{i\})$
26		eqid	$⊢ Scalar (C) = Scalar (C)$
27		eqid	$⊢ {Base}_{Scalar (C)} = {Base}_{Scalar (C)}$
28		eqid	$⊢ 0_{Scalar (C)} = 0_{Scalar (C)}$
29	1 8 12	lcdlvec	$⊢ φ \to C \in LVec$
30	18	simpld	$⊢ φ \to h \in F$
31	19	simpld	$⊢ φ \to i \in F$
32	9 26 27 28 22 11 29 30 31	lspsneq	$⊢ φ \to (J (\{h\}) = J (\{i\}) \leftrightarrow \exists u \in ({Base}_{Scalar (C)} ∖ \{0_{Scalar (C)}\}) h = u \underset{˙}{\cdot} i)$
33	1 3 20 21 8 26 27 12	lcdsbase	$⊢ φ \to {Base}_{Scalar (C)} = B$
34	1 3 20 23 8 26 28 12	lcd0	$⊢ φ \to 0_{Scalar (C)} = O$
35	34	sneqd	$⊢ φ \to \{0_{Scalar (C)}\} = \{O\}$
36	33 35	difeq12d	$⊢ φ \to {Base}_{Scalar (C)} ∖ \{0_{Scalar (C)}\} = B ∖ \{O\}$
37	36	rexeqdv	$⊢ φ \to (\exists u \in ({Base}_{Scalar (C)} ∖ \{0_{Scalar (C)}\}) h = u \underset{˙}{\cdot} i \leftrightarrow \exists u \in (B ∖ \{O\}) h = u \underset{˙}{\cdot} i)$
38	32 37	bitrd	$⊢ φ \to (J (\{h\}) = J (\{i\}) \leftrightarrow \exists u \in (B ∖ \{O\}) h = u \underset{˙}{\cdot} i)$
39	25 38	mpbid	$⊢ φ \to \exists u \in (B ∖ \{O\}) h = u \underset{˙}{\cdot} i$

Metamath Proof Explorer

Theorem mapdpglem26

Proof