pclunN

Description: The projective subspace closure of the union of two sets of atoms equals the closure of their projective sum. (Contributed by NM, 12-Sep-2013) (New usage is discouraged.)

	Ref	Expression
Hypotheses	pclun.a	$⊢ A = Atoms (K)$
	pclun.p	$⊢ \underset{˙}{+} = +_{𝑃} (K)$
	pclun.c	$⊢ U = PCl (K)$
Assertion	pclunN	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to U (X \cup Y) = U (X \underset{˙}{+} Y)$

Proof

Step	Hyp	Ref	Expression
1		pclun.a	$⊢ A = Atoms (K)$
2		pclun.p	$⊢ \underset{˙}{+} = +_{𝑃} (K)$
3		pclun.c	$⊢ U = PCl (K)$
4		simp1	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to K \in V$
5	1 2	paddunssN	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to X \cup Y \subseteq X \underset{˙}{+} Y$
6	1 2	paddssat	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to X \underset{˙}{+} Y \subseteq A$
7	1 3	pclssN	$⊢ (K \in V \land X \cup Y \subseteq X \underset{˙}{+} Y \land X \underset{˙}{+} Y \subseteq A) \to U (X \cup Y) \subseteq U (X \underset{˙}{+} Y)$
8	4 5 6 7	syl3anc	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to U (X \cup Y) \subseteq U (X \underset{˙}{+} Y)$
9		unss	$⊢ (X \subseteq A \land Y \subseteq A) \leftrightarrow X \cup Y \subseteq A$
10	9	biimpi	$⊢ (X \subseteq A \land Y \subseteq A) \to X \cup Y \subseteq A$
11	10	3adant1	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to X \cup Y \subseteq A$
12	1 3	pclssidN	$⊢ (K \in V \land X \cup Y \subseteq A) \to X \cup Y \subseteq U (X \cup Y)$
13	4 11 12	syl2anc	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to X \cup Y \subseteq U (X \cup Y)$
14		unss	$⊢ (X \subseteq U (X \cup Y) \land Y \subseteq U (X \cup Y)) \leftrightarrow X \cup Y \subseteq U (X \cup Y)$
15	13 14	sylibr	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to (X \subseteq U (X \cup Y) \land Y \subseteq U (X \cup Y))$
16		simp2	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to X \subseteq A$
17		simp3	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to Y \subseteq A$
18		eqid	$⊢ PSubSp (K) = PSubSp (K)$
19	1 18 3	pclclN	$⊢ (K \in V \land X \cup Y \subseteq A) \to U (X \cup Y) \in PSubSp (K)$
20	4 11 19	syl2anc	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to U (X \cup Y) \in PSubSp (K)$
21	1 18 2	paddss	$⊢ (K \in V \land (X \subseteq A \land Y \subseteq A \land U (X \cup Y) \in PSubSp (K))) \to ((X \subseteq U (X \cup Y) \land Y \subseteq U (X \cup Y)) \leftrightarrow X \underset{˙}{+} Y \subseteq U (X \cup Y))$
22	4 16 17 20 21	syl13anc	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to ((X \subseteq U (X \cup Y) \land Y \subseteq U (X \cup Y)) \leftrightarrow X \underset{˙}{+} Y \subseteq U (X \cup Y))$
23	15 22	mpbid	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to X \underset{˙}{+} Y \subseteq U (X \cup Y)$
24	1 18	psubssat	$⊢ (K \in V \land U (X \cup Y) \in PSubSp (K)) \to U (X \cup Y) \subseteq A$
25	4 20 24	syl2anc	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to U (X \cup Y) \subseteq A$
26	1 3	pclssN	$⊢ (K \in V \land X \underset{˙}{+} Y \subseteq U (X \cup Y) \land U (X \cup Y) \subseteq A) \to U (X \underset{˙}{+} Y) \subseteq U (U (X \cup Y))$
27	4 23 25 26	syl3anc	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to U (X \underset{˙}{+} Y) \subseteq U (U (X \cup Y))$
28	18 3	pclidN	$⊢ (K \in V \land U (X \cup Y) \in PSubSp (K)) \to U (U (X \cup Y)) = U (X \cup Y)$
29	4 20 28	syl2anc	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to U (U (X \cup Y)) = U (X \cup Y)$
30	27 29	sseqtrd	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to U (X \underset{˙}{+} Y) \subseteq U (X \cup Y)$
31	8 30	eqssd	$⊢ (K \in V \land X \subseteq A \land Y \subseteq A) \to U (X \cup Y) = U (X \underset{˙}{+} Y)$

Metamath Proof Explorer

Theorem pclunN

Proof