paddass

Description: Projective subspace sum is associative. Equation 16.2.1 of MaedaMaeda p. 68. In our version, the subspaces do not have to be nonempty. (Contributed by NM, 29-Dec-2011)

	Ref	Expression
Hypotheses	paddass.a	$⊢ A = Atoms (K)$
	paddass.p	$⊢ \underset{˙}{+} = +_{𝑃} (K)$
Assertion	paddass	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to (X \underset{˙}{+} Y) \underset{˙}{+} Z = X \underset{˙}{+} (Y \underset{˙}{+} Z)$

Proof

Step	Hyp	Ref	Expression
1		paddass.a	$⊢ A = Atoms (K)$
2		paddass.p	$⊢ \underset{˙}{+} = +_{𝑃} (K)$
3		simpl	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to K \in HL$
4		simpr3	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to Z \subseteq A$
5		simpr2	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to Y \subseteq A$
6		simpr1	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to X \subseteq A$
7	1 2	paddasslem18	$⊢ (K \in HL \land (Z \subseteq A \land Y \subseteq A \land X \subseteq A)) \to Z \underset{˙}{+} (Y \underset{˙}{+} X) \subseteq (Z \underset{˙}{+} Y) \underset{˙}{+} X$
8	3 4 5 6 7	syl13anc	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to Z \underset{˙}{+} (Y \underset{˙}{+} X) \subseteq (Z \underset{˙}{+} Y) \underset{˙}{+} X$
9		hllat	$⊢ K \in HL \to K \in Lat$
10	1 2	paddcom	$⊢ (K \in Lat \land X \subseteq A \land Y \subseteq A) \to X \underset{˙}{+} Y = Y \underset{˙}{+} X$
11	9 10	syl3an1	$⊢ (K \in HL \land X \subseteq A \land Y \subseteq A) \to X \underset{˙}{+} Y = Y \underset{˙}{+} X$
12	11	3adant3r3	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to X \underset{˙}{+} Y = Y \underset{˙}{+} X$
13	12	oveq1d	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to (X \underset{˙}{+} Y) \underset{˙}{+} Z = (Y \underset{˙}{+} X) \underset{˙}{+} Z$
14	1 2	paddssat	$⊢ (K \in HL \land Y \subseteq A \land X \subseteq A) \to Y \underset{˙}{+} X \subseteq A$
15	3 5 6 14	syl3anc	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to Y \underset{˙}{+} X \subseteq A$
16	1 2	paddcom	$⊢ (K \in Lat \land Y \underset{˙}{+} X \subseteq A \land Z \subseteq A) \to (Y \underset{˙}{+} X) \underset{˙}{+} Z = Z \underset{˙}{+} (Y \underset{˙}{+} X)$
17	9 16	syl3an1	$⊢ (K \in HL \land Y \underset{˙}{+} X \subseteq A \land Z \subseteq A) \to (Y \underset{˙}{+} X) \underset{˙}{+} Z = Z \underset{˙}{+} (Y \underset{˙}{+} X)$
18	3 15 4 17	syl3anc	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to (Y \underset{˙}{+} X) \underset{˙}{+} Z = Z \underset{˙}{+} (Y \underset{˙}{+} X)$
19	13 18	eqtrd	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to (X \underset{˙}{+} Y) \underset{˙}{+} Z = Z \underset{˙}{+} (Y \underset{˙}{+} X)$
20	1 2	paddcom	$⊢ (K \in Lat \land Y \subseteq A \land Z \subseteq A) \to Y \underset{˙}{+} Z = Z \underset{˙}{+} Y$
21	9 20	syl3an1	$⊢ (K \in HL \land Y \subseteq A \land Z \subseteq A) \to Y \underset{˙}{+} Z = Z \underset{˙}{+} Y$
22	21	3adant3r1	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to Y \underset{˙}{+} Z = Z \underset{˙}{+} Y$
23	22	oveq2d	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to X \underset{˙}{+} (Y \underset{˙}{+} Z) = X \underset{˙}{+} (Z \underset{˙}{+} Y)$
24	1 2	paddssat	$⊢ (K \in HL \land Z \subseteq A \land Y \subseteq A) \to Z \underset{˙}{+} Y \subseteq A$
25	3 4 5 24	syl3anc	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to Z \underset{˙}{+} Y \subseteq A$
26	1 2	paddcom	$⊢ (K \in Lat \land X \subseteq A \land Z \underset{˙}{+} Y \subseteq A) \to X \underset{˙}{+} (Z \underset{˙}{+} Y) = (Z \underset{˙}{+} Y) \underset{˙}{+} X$
27	9 26	syl3an1	$⊢ (K \in HL \land X \subseteq A \land Z \underset{˙}{+} Y \subseteq A) \to X \underset{˙}{+} (Z \underset{˙}{+} Y) = (Z \underset{˙}{+} Y) \underset{˙}{+} X$
28	3 6 25 27	syl3anc	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to X \underset{˙}{+} (Z \underset{˙}{+} Y) = (Z \underset{˙}{+} Y) \underset{˙}{+} X$
29	23 28	eqtrd	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to X \underset{˙}{+} (Y \underset{˙}{+} Z) = (Z \underset{˙}{+} Y) \underset{˙}{+} X$
30	8 19 29	3sstr4d	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to (X \underset{˙}{+} Y) \underset{˙}{+} Z \subseteq X \underset{˙}{+} (Y \underset{˙}{+} Z)$
31	1 2	paddasslem18	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to X \underset{˙}{+} (Y \underset{˙}{+} Z) \subseteq (X \underset{˙}{+} Y) \underset{˙}{+} Z$
32	30 31	eqssd	$⊢ (K \in HL \land (X \subseteq A \land Y \subseteq A \land Z \subseteq A)) \to (X \underset{˙}{+} Y) \underset{˙}{+} Z = X \underset{˙}{+} (Y \underset{˙}{+} Z)$

Metamath Proof Explorer

Theorem paddass

Proof