lcfrlem21

	Ref	Expression
Hypotheses	lcfrlem17.h	$⊢ H = LHyp (K)$
	lcfrlem17.o	$⊢ \underset{˙}{⊥} = ocH (K) (W)$
	lcfrlem17.u	$⊢ U = DVecH (K) (W)$
	lcfrlem17.v	$⊢ V = {Base}_{U}$
	lcfrlem17.p	$⊢ \underset{˙}{+} = +_{U}$
	lcfrlem17.z	$⊢ \underset{˙}{0} = 0_{U}$
	lcfrlem17.n	$⊢ N = LSpan (U)$
	lcfrlem17.a	$⊢ A = LSAtoms (U)$
	lcfrlem17.k	$⊢ φ \to (K \in HL \land W \in H)$
	lcfrlem17.x	$⊢ φ \to X \in (V ∖ \{\underset{˙}{0}\})$
	lcfrlem17.y	$⊢ φ \to Y \in (V ∖ \{\underset{˙}{0}\})$
	lcfrlem17.ne	$⊢ φ \to N (\{X\}) \neq N (\{Y\})$
Assertion	lcfrlem21	$⊢ φ \to N (\{X, Y\}) \cap \underset{˙}{⊥} (\{X \underset{˙}{+} Y\}) \in A$

Proof

Step	Hyp	Ref	Expression
1		lcfrlem17.h	$⊢ H = LHyp (K)$
2		lcfrlem17.o	$⊢ \underset{˙}{⊥} = ocH (K) (W)$
3		lcfrlem17.u	$⊢ U = DVecH (K) (W)$
4		lcfrlem17.v	$⊢ V = {Base}_{U}$
5		lcfrlem17.p	$⊢ \underset{˙}{+} = +_{U}$
6		lcfrlem17.z	$⊢ \underset{˙}{0} = 0_{U}$
7		lcfrlem17.n	$⊢ N = LSpan (U)$
8		lcfrlem17.a	$⊢ A = LSAtoms (U)$
9		lcfrlem17.k	$⊢ φ \to (K \in HL \land W \in H)$
10		lcfrlem17.x	$⊢ φ \to X \in (V ∖ \{\underset{˙}{0}\})$
11		lcfrlem17.y	$⊢ φ \to Y \in (V ∖ \{\underset{˙}{0}\})$
12		lcfrlem17.ne	$⊢ φ \to N (\{X\}) \neq N (\{Y\})$
13	9	adantr	$⊢ (φ \land \neg X \in \underset{˙}{⊥} (\{X \underset{˙}{+} Y\})) \to (K \in HL \land W \in H)$
14	10	adantr	$⊢ (φ \land \neg X \in \underset{˙}{⊥} (\{X \underset{˙}{+} Y\})) \to X \in (V ∖ \{\underset{˙}{0}\})$
15	11	adantr	$⊢ (φ \land \neg X \in \underset{˙}{⊥} (\{X \underset{˙}{+} Y\})) \to Y \in (V ∖ \{\underset{˙}{0}\})$
16	12	adantr	$⊢ (φ \land \neg X \in \underset{˙}{⊥} (\{X \underset{˙}{+} Y\})) \to N (\{X\}) \neq N (\{Y\})$
17		simpr	$⊢ (φ \land \neg X \in \underset{˙}{⊥} (\{X \underset{˙}{+} Y\})) \to \neg X \in \underset{˙}{⊥} (\{X \underset{˙}{+} Y\})$
18	1 2 3 4 5 6 7 8 13 14 15 16 17	lcfrlem20	$⊢ (φ \land \neg X \in \underset{˙}{⊥} (\{X \underset{˙}{+} Y\})) \to N (\{X, Y\}) \cap \underset{˙}{⊥} (\{X \underset{˙}{+} Y\}) \in A$
19	1 3 9	dvhlmod	$⊢ φ \to U \in LMod$
20	10	eldifad	$⊢ φ \to X \in V$
21	11	eldifad	$⊢ φ \to Y \in V$
22	4 5	lmodcom	$⊢ (U \in LMod \land X \in V \land Y \in V) \to X \underset{˙}{+} Y = Y \underset{˙}{+} X$
23	19 20 21 22	syl3anc	$⊢ φ \to X \underset{˙}{+} Y = Y \underset{˙}{+} X$
24	23	sneqd	$⊢ φ \to \{X \underset{˙}{+} Y\} = \{Y \underset{˙}{+} X\}$
25	24	fveq2d	$⊢ φ \to \underset{˙}{⊥} (\{X \underset{˙}{+} Y\}) = \underset{˙}{⊥} (\{Y \underset{˙}{+} X\})$
26	25	eleq2d	$⊢ φ \to (Y \in \underset{˙}{⊥} (\{X \underset{˙}{+} Y\}) \leftrightarrow Y \in \underset{˙}{⊥} (\{Y \underset{˙}{+} X\}))$
27	26	biimprd	$⊢ φ \to (Y \in \underset{˙}{⊥} (\{Y \underset{˙}{+} X\}) \to Y \in \underset{˙}{⊥} (\{X \underset{˙}{+} Y\}))$
28	27	con3dimp	$⊢ (φ \land \neg Y \in \underset{˙}{⊥} (\{X \underset{˙}{+} Y\})) \to \neg Y \in \underset{˙}{⊥} (\{Y \underset{˙}{+} X\})$
29		prcom	$⊢ \{X, Y\} = \{Y, X\}$
30	29	fveq2i	$⊢ N (\{X, Y\}) = N (\{Y, X\})$
31	30	a1i	$⊢ φ \to N (\{X, Y\}) = N (\{Y, X\})$
32	31 25	ineq12d	$⊢ φ \to N (\{X, Y\}) \cap \underset{˙}{⊥} (\{X \underset{˙}{+} Y\}) = N (\{Y, X\}) \cap \underset{˙}{⊥} (\{Y \underset{˙}{+} X\})$
33	32	adantr	$⊢ (φ \land \neg Y \in \underset{˙}{⊥} (\{Y \underset{˙}{+} X\})) \to N (\{X, Y\}) \cap \underset{˙}{⊥} (\{X \underset{˙}{+} Y\}) = N (\{Y, X\}) \cap \underset{˙}{⊥} (\{Y \underset{˙}{+} X\})$
34	9	adantr	$⊢ (φ \land \neg Y \in \underset{˙}{⊥} (\{Y \underset{˙}{+} X\})) \to (K \in HL \land W \in H)$
35	11	adantr	$⊢ (φ \land \neg Y \in \underset{˙}{⊥} (\{Y \underset{˙}{+} X\})) \to Y \in (V ∖ \{\underset{˙}{0}\})$
36	10	adantr	$⊢ (φ \land \neg Y \in \underset{˙}{⊥} (\{Y \underset{˙}{+} X\})) \to X \in (V ∖ \{\underset{˙}{0}\})$
37	12	necomd	$⊢ φ \to N (\{Y\}) \neq N (\{X\})$
38	37	adantr	$⊢ (φ \land \neg Y \in \underset{˙}{⊥} (\{Y \underset{˙}{+} X\})) \to N (\{Y\}) \neq N (\{X\})$
39		simpr	$⊢ (φ \land \neg Y \in \underset{˙}{⊥} (\{Y \underset{˙}{+} X\})) \to \neg Y \in \underset{˙}{⊥} (\{Y \underset{˙}{+} X\})$
40	1 2 3 4 5 6 7 8 34 35 36 38 39	lcfrlem20	$⊢ (φ \land \neg Y \in \underset{˙}{⊥} (\{Y \underset{˙}{+} X\})) \to N (\{Y, X\}) \cap \underset{˙}{⊥} (\{Y \underset{˙}{+} X\}) \in A$
41	33 40	eqeltrd	$⊢ (φ \land \neg Y \in \underset{˙}{⊥} (\{Y \underset{˙}{+} X\})) \to N (\{X, Y\}) \cap \underset{˙}{⊥} (\{X \underset{˙}{+} Y\}) \in A$
42	28 41	syldan	$⊢ (φ \land \neg Y \in \underset{˙}{⊥} (\{X \underset{˙}{+} Y\})) \to N (\{X, Y\}) \cap \underset{˙}{⊥} (\{X \underset{˙}{+} Y\}) \in A$
43	1 2 3 4 5 6 7 8 9 10 11 12	lcfrlem19	$⊢ φ \to (\neg X \in \underset{˙}{⊥} (\{X \underset{˙}{+} Y\}) \lor \neg Y \in \underset{˙}{⊥} (\{X \underset{˙}{+} Y\}))$
44	18 42 43	mpjaodan	$⊢ φ \to N (\{X, Y\}) \cap \underset{˙}{⊥} (\{X \underset{˙}{+} Y\}) \in A$

Metamath Proof Explorer

Theorem lcfrlem21

Proof