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Theorem ud3lem1 552

Description: Lemma for unified disjunction.

**Assertion**
Ref	Expression
ud3lem1	((a →₃b) →₃(b →₃a)) = (a ∪ (a^⊥ ∩ b^⊥ ))

**Proof of Theorem ud3lem1**
Step	Hyp	Ref	Expression
1		df-i3 45	. 2 ((a →₃b) →₃(b →₃a)) = ((((a →₃b)^⊥ ∩ (b →₃a)) ∪ ((a →₃b)^⊥ ∩ (b →₃a)^⊥ )) ∪ ((a →₃b) ∩ ((a →₃b)^⊥ ∪ (b →₃a))))
2		ud3lem1a 548	. . . . . 6 ((a →₃b)^⊥ ∩ (b →₃a)) = (a ∩ b^⊥ )
3		ud3lem1b 549	. . . . . 6 ((a →₃b)^⊥ ∩ (b →₃a)^⊥ ) = 0
4	2, 3	2or 67	. . . . 5 (((a →₃b)^⊥ ∩ (b →₃a)) ∪ ((a →₃b)^⊥ ∩ (b →₃a)^⊥ )) = ((a ∩ b^⊥ ) ∪ 0)
5		or0 94	. . . . 5 ((a ∩ b^⊥ ) ∪ 0) = (a ∩ b^⊥ )
6	4, 5	ax-r2 35	. . . 4 (((a →₃b)^⊥ ∩ (b →₃a)) ∪ ((a →₃b)^⊥ ∩ (b →₃a)^⊥ )) = (a ∩ b^⊥ )
7		ud3lem1d 551	. . . 4 ((a →₃b) ∩ ((a →₃b)^⊥ ∪ (b →₃a))) = ((a^⊥ ∩ b^⊥ ) ∪ (a ∩ (a^⊥ ∪ b)))
8	6, 7	2or 67	. . 3 ((((a →₃b)^⊥ ∩ (b →₃a)) ∪ ((a →₃b)^⊥ ∩ (b →₃a)^⊥ )) ∪ ((a →₃b) ∩ ((a →₃b)^⊥ ∪ (b →₃a)))) = ((a ∩ b^⊥ ) ∪ ((a^⊥ ∩ b^⊥ ) ∪ (a ∩ (a^⊥ ∪ b))))
9		coman1 177	. . . . . . 7 (a ∩ b^⊥ ) C a
10	9	comcom2 175	. . . . . . . 8 (a ∩ b^⊥ ) C a^⊥
11		coman2 178	. . . . . . . . 9 (a ∩ b^⊥ ) C b^⊥
12	11	comcom7 442	. . . . . . . 8 (a ∩ b^⊥ ) C b
13	10, 12	com2or 465	. . . . . . 7 (a ∩ b^⊥ ) C (a^⊥ ∪ b)
14	9, 13	fh3 453	. . . . . 6 ((a ∩ b^⊥ ) ∪ (a ∩ (a^⊥ ∪ b))) = (((a ∩ b^⊥ ) ∪ a) ∩ ((a ∩ b^⊥ ) ∪ (a^⊥ ∪ b)))
15		ax-a2 30	. . . . . . . . 9 ((a ∩ b^⊥ ) ∪ a) = (a ∪ (a ∩ b^⊥ ))
16		a5b 112	. . . . . . . . 9 (a ∪ (a ∩ b^⊥ )) = a
17	15, 16	ax-r2 35	. . . . . . . 8 ((a ∩ b^⊥ ) ∪ a) = a
18		ax-a2 30	. . . . . . . . 9 ((a ∩ b^⊥ ) ∪ (a^⊥ ∪ b)) = ((a^⊥ ∪ b) ∪ (a ∩ b^⊥ ))
19		anor1 80	. . . . . . . . . . 11 (a ∩ b^⊥ ) = (a^⊥ ∪ b)^⊥
20	19	lor 66	. . . . . . . . . 10 ((a^⊥ ∪ b) ∪ (a ∩ b^⊥ )) = ((a^⊥ ∪ b) ∪ (a^⊥ ∪ b)^⊥ )
21		df-t 40	. . . . . . . . . . 11 1 = ((a^⊥ ∪ b) ∪ (a^⊥ ∪ b)^⊥ )
22	21	ax-r1 34	. . . . . . . . . 10 ((a^⊥ ∪ b) ∪ (a^⊥ ∪ b)^⊥ ) = 1
23	20, 22	ax-r2 35	. . . . . . . . 9 ((a^⊥ ∪ b) ∪ (a ∩ b^⊥ )) = 1
24	18, 23	ax-r2 35	. . . . . . . 8 ((a ∩ b^⊥ ) ∪ (a^⊥ ∪ b)) = 1
25	17, 24	2an 72	. . . . . . 7 (((a ∩ b^⊥ ) ∪ a) ∩ ((a ∩ b^⊥ ) ∪ (a^⊥ ∪ b))) = (a ∩ 1)
26		an1 98	. . . . . . 7 (a ∩ 1) = a
27	25, 26	ax-r2 35	. . . . . 6 (((a ∩ b^⊥ ) ∪ a) ∩ ((a ∩ b^⊥ ) ∪ (a^⊥ ∪ b))) = a
28	14, 27	ax-r2 35	. . . . 5 ((a ∩ b^⊥ ) ∪ (a ∩ (a^⊥ ∪ b))) = a
29	28	lor 66	. . . 4 ((a^⊥ ∩ b^⊥ ) ∪ ((a ∩ b^⊥ ) ∪ (a ∩ (a^⊥ ∪ b)))) = ((a^⊥ ∩ b^⊥ ) ∪ a)
30		or12 73	. . . 4 ((a ∩ b^⊥ ) ∪ ((a^⊥ ∩ b^⊥ ) ∪ (a ∩ (a^⊥ ∪ b)))) = ((a^⊥ ∩ b^⊥ ) ∪ ((a ∩ b^⊥ ) ∪ (a ∩ (a^⊥ ∪ b))))
31		ax-a2 30	. . . 4 (a ∪ (a^⊥ ∩ b^⊥ )) = ((a^⊥ ∩ b^⊥ ) ∪ a)
32	29, 30, 31	3tr1 60	. . 3 ((a ∩ b^⊥ ) ∪ ((a^⊥ ∩ b^⊥ ) ∪ (a ∩ (a^⊥ ∪ b)))) = (a ∪ (a^⊥ ∩ b^⊥ ))
33	8, 32	ax-r2 35	. 2 ((((a →₃b)^⊥ ∩ (b →₃a)) ∪ ((a →₃b)^⊥ ∩ (b →₃a)^⊥ )) ∪ ((a →₃b) ∩ ((a →₃b)^⊥ ∪ (b →₃a)))) = (a ∪ (a^⊥ ∩ b^⊥ ))
34	1, 33	ax-r2 35	1 ((a →₃b) →₃(b →₃a)) = (a ∪ (a^⊥ ∩ b^⊥ ))

Colors of variables: term

Syntax hints: = wb 1 ^⊥ wn 4 ∪ wo 6 ∩ wa 7 1wt 9 0wf 10 →₃wi3 15

This theorem is referenced by: ud3 579 u3lem11a 769

This theorem was proved from axioms: ax-a1 29 ax-a2 30 ax-a3 31 ax-a4 32 ax-a5 33 ax-r1 34 ax-r2 35 ax-r4 36 ax-r5 37 ax-r3 421

This theorem depends on definitions: df-b 38 df-a 39 df-t 40 df-f 41 df-i3 45 df-le1 122 df-le2 123 df-c1 124 df-c2 125

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