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Theorem mlaconjo 868

Description: OML proof of Mladen's conjecture.

**Assertion**
Ref	Expression
mlaconjo	((a ≡ b) ∩ ((a ≡ c) ∪ (b ≡ c))) ≤ (a ≡ c)

**Proof of Theorem mlaconjo**
Step	Hyp	Ref	Expression
1		dfb 86	. . . 4 (a ≡ b) = ((a ∩ b) ∪ (a^⊥ ∩ b^⊥ ))
2	1	bile 134	. . 3 (a ≡ b) ≤ ((a ∩ b) ∪ (a^⊥ ∩ b^⊥ ))
3		mlaconjolem 867	. . 3 ((a ≡ c) ∪ (b ≡ c)) ≤ ((c ∩ (a ∪ b)) ∪ (c^⊥ ∩ (a^⊥ ∪ b^⊥ )))
4	2, 3	le2an 161	. 2 ((a ≡ b) ∩ ((a ≡ c) ∪ (b ≡ c))) ≤ (((a ∩ b) ∪ (a^⊥ ∩ b^⊥ )) ∩ ((c ∩ (a ∪ b)) ∪ (c^⊥ ∩ (a^⊥ ∪ b^⊥ ))))
5		lea 152	. . . . 5 (a ∩ b) ≤ a
6		lea 152	. . . . 5 (c ∩ (a ∪ b)) ≤ c
7	5, 6	le2an 161	. . . 4 ((a ∩ b) ∩ (c ∩ (a ∪ b))) ≤ (a ∩ c)
8		lea 152	. . . . 5 (a^⊥ ∩ b^⊥ ) ≤ a^⊥
9		lea 152	. . . . 5 (c^⊥ ∩ (a^⊥ ∪ b^⊥ )) ≤ c^⊥
10	8, 9	le2an 161	. . . 4 ((a^⊥ ∩ b^⊥ ) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ ))) ≤ (a^⊥ ∩ c^⊥ )
11	7, 10	le2or 160	. . 3 (((a ∩ b) ∩ (c ∩ (a ∪ b))) ∪ ((a^⊥ ∩ b^⊥ ) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ )))) ≤ ((a ∩ c) ∪ (a^⊥ ∩ c^⊥ ))
12		leao1 154	. . . . . . . 8 (a ∩ b) ≤ (a ∪ b)
13		oran 79	. . . . . . . 8 (a ∪ b) = (a^⊥ ∩ b^⊥ )^⊥
14	12, 13	lbtr 131	. . . . . . 7 (a ∩ b) ≤ (a^⊥ ∩ b^⊥ )^⊥
15	14	lecom 172	. . . . . 6 (a ∩ b) C (a^⊥ ∩ b^⊥ )^⊥
16	15	comcom7 442	. . . . 5 (a ∩ b) C (a^⊥ ∩ b^⊥ )
17		leor 151	. . . . . . . 8 (a ∩ b) ≤ (c ∪ (a ∩ b))
18		df-a 39	. . . . . . . . . 10 (a ∩ b) = (a^⊥ ∪ b^⊥ )^⊥
19	18	lor 66	. . . . . . . . 9 (c ∪ (a ∩ b)) = (c ∪ (a^⊥ ∪ b^⊥ )^⊥ )
20		oran1 83	. . . . . . . . 9 (c ∪ (a^⊥ ∪ b^⊥ )^⊥ ) = (c^⊥ ∩ (a^⊥ ∪ b^⊥ ))^⊥
21	19, 20	ax-r2 35	. . . . . . . 8 (c ∪ (a ∩ b)) = (c^⊥ ∩ (a^⊥ ∪ b^⊥ ))^⊥
22	17, 21	lbtr 131	. . . . . . 7 (a ∩ b) ≤ (c^⊥ ∩ (a^⊥ ∪ b^⊥ ))^⊥
23	22	lecom 172	. . . . . 6 (a ∩ b) C (c^⊥ ∩ (a^⊥ ∪ b^⊥ ))^⊥
24	23	comcom7 442	. . . . 5 (a ∩ b) C (c^⊥ ∩ (a^⊥ ∪ b^⊥ ))
25		lear 153	. . . . . . . 8 (c ∩ (a ∪ b)) ≤ (a ∪ b)
26	25, 13	lbtr 131	. . . . . . 7 (c ∩ (a ∪ b)) ≤ (a^⊥ ∩ b^⊥ )^⊥
27	26	lecom 172	. . . . . 6 (c ∩ (a ∪ b)) C (a^⊥ ∩ b^⊥ )^⊥
28	27	comcom7 442	. . . . 5 (c ∩ (a ∪ b)) C (a^⊥ ∩ b^⊥ )
29		leao1 154	. . . . . . . 8 (c ∩ (a ∪ b)) ≤ (c ∪ (a^⊥ ∪ b^⊥ )^⊥ )
30	29, 20	lbtr 131	. . . . . . 7 (c ∩ (a ∪ b)) ≤ (c^⊥ ∩ (a^⊥ ∪ b^⊥ ))^⊥
31	30	lecom 172	. . . . . 6 (c ∩ (a ∪ b)) C (c^⊥ ∩ (a^⊥ ∪ b^⊥ ))^⊥
32	31	comcom7 442	. . . . 5 (c ∩ (a ∪ b)) C (c^⊥ ∩ (a^⊥ ∪ b^⊥ ))
33	16, 24, 28, 32	mh 861	. . . 4 (((a ∩ b) ∪ (a^⊥ ∩ b^⊥ )) ∩ ((c ∩ (a ∪ b)) ∪ (c^⊥ ∩ (a^⊥ ∪ b^⊥ )))) = ((((a ∩ b) ∩ (c ∩ (a ∪ b))) ∪ ((a ∩ b) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ )))) ∪ (((a^⊥ ∩ b^⊥ ) ∩ (c ∩ (a ∪ b))) ∪ ((a^⊥ ∩ b^⊥ ) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ )))))
34		an12 74	. . . . . . . 8 ((a ∩ b) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ ))) = (c^⊥ ∩ ((a ∩ b) ∩ (a^⊥ ∪ b^⊥ )))
35		oran3 85	. . . . . . . . . . 11 (a^⊥ ∪ b^⊥ ) = (a ∩ b)^⊥
36	35	lan 70	. . . . . . . . . 10 ((a ∩ b) ∩ (a^⊥ ∪ b^⊥ )) = ((a ∩ b) ∩ (a ∩ b)^⊥ )
37		dff 93	. . . . . . . . . . 11 0 = ((a ∩ b) ∩ (a ∩ b)^⊥ )
38	37	ax-r1 34	. . . . . . . . . 10 ((a ∩ b) ∩ (a ∩ b)^⊥ ) = 0
39	36, 38	ax-r2 35	. . . . . . . . 9 ((a ∩ b) ∩ (a^⊥ ∪ b^⊥ )) = 0
40	39	lan 70	. . . . . . . 8 (c^⊥ ∩ ((a ∩ b) ∩ (a^⊥ ∪ b^⊥ ))) = (c^⊥ ∩ 0)
41		an0 100	. . . . . . . 8 (c^⊥ ∩ 0) = 0
42	34, 40, 41	3tr 62	. . . . . . 7 ((a ∩ b) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ ))) = 0
43	42	lor 66	. . . . . 6 (((a ∩ b) ∩ (c ∩ (a ∪ b))) ∪ ((a ∩ b) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ )))) = (((a ∩ b) ∩ (c ∩ (a ∪ b))) ∪ 0)
44		or0 94	. . . . . 6 (((a ∩ b) ∩ (c ∩ (a ∪ b))) ∪ 0) = ((a ∩ b) ∩ (c ∩ (a ∪ b)))
45	43, 44	ax-r2 35	. . . . 5 (((a ∩ b) ∩ (c ∩ (a ∪ b))) ∪ ((a ∩ b) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ )))) = ((a ∩ b) ∩ (c ∩ (a ∪ b)))
46		an12 74	. . . . . . . 8 ((a^⊥ ∩ b^⊥ ) ∩ (c ∩ (a ∪ b))) = (c ∩ ((a^⊥ ∩ b^⊥ ) ∩ (a ∪ b)))
47	13	lan 70	. . . . . . . . . 10 ((a^⊥ ∩ b^⊥ ) ∩ (a ∪ b)) = ((a^⊥ ∩ b^⊥ ) ∩ (a^⊥ ∩ b^⊥ )^⊥ )
48		dff 93	. . . . . . . . . . 11 0 = ((a^⊥ ∩ b^⊥ ) ∩ (a^⊥ ∩ b^⊥ )^⊥ )
49	48	ax-r1 34	. . . . . . . . . 10 ((a^⊥ ∩ b^⊥ ) ∩ (a^⊥ ∩ b^⊥ )^⊥ ) = 0
50	47, 49	ax-r2 35	. . . . . . . . 9 ((a^⊥ ∩ b^⊥ ) ∩ (a ∪ b)) = 0
51	50	lan 70	. . . . . . . 8 (c ∩ ((a^⊥ ∩ b^⊥ ) ∩ (a ∪ b))) = (c ∩ 0)
52		an0 100	. . . . . . . 8 (c ∩ 0) = 0
53	46, 51, 52	3tr 62	. . . . . . 7 ((a^⊥ ∩ b^⊥ ) ∩ (c ∩ (a ∪ b))) = 0
54	53	ax-r5 37	. . . . . 6 (((a^⊥ ∩ b^⊥ ) ∩ (c ∩ (a ∪ b))) ∪ ((a^⊥ ∩ b^⊥ ) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ )))) = (0 ∪ ((a^⊥ ∩ b^⊥ ) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ ))))
55		or0r 95	. . . . . 6 (0 ∪ ((a^⊥ ∩ b^⊥ ) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ )))) = ((a^⊥ ∩ b^⊥ ) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ )))
56	54, 55	ax-r2 35	. . . . 5 (((a^⊥ ∩ b^⊥ ) ∩ (c ∩ (a ∪ b))) ∪ ((a^⊥ ∩ b^⊥ ) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ )))) = ((a^⊥ ∩ b^⊥ ) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ )))
57	45, 56	2or 67	. . . 4 ((((a ∩ b) ∩ (c ∩ (a ∪ b))) ∪ ((a ∩ b) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ )))) ∪ (((a^⊥ ∩ b^⊥ ) ∩ (c ∩ (a ∪ b))) ∪ ((a^⊥ ∩ b^⊥ ) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ ))))) = (((a ∩ b) ∩ (c ∩ (a ∪ b))) ∪ ((a^⊥ ∩ b^⊥ ) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ ))))
58	33, 57	ax-r2 35	. . 3 (((a ∩ b) ∪ (a^⊥ ∩ b^⊥ )) ∩ ((c ∩ (a ∪ b)) ∪ (c^⊥ ∩ (a^⊥ ∪ b^⊥ )))) = (((a ∩ b) ∩ (c ∩ (a ∪ b))) ∪ ((a^⊥ ∩ b^⊥ ) ∩ (c^⊥ ∩ (a^⊥ ∪ b^⊥ ))))
59		dfb 86	. . 3 (a ≡ c) = ((a ∩ c) ∪ (a^⊥ ∩ c^⊥ ))
60	11, 58, 59	le3tr1 132	. 2 (((a ∩ b) ∪ (a^⊥ ∩ b^⊥ )) ∩ ((c ∩ (a ∪ b)) ∪ (c^⊥ ∩ (a^⊥ ∪ b^⊥ )))) ≤ (a ≡ c)
61	4, 60	letr 129	1 ((a ≡ b) ∩ ((a ≡ c) ∪ (b ≡ c))) ≤ (a ≡ c)

Colors of variables: term

Syntax hints: ≤ wle 2 ^⊥ wn 4 ≡ tb 5 ∪ wo 6 ∩ wa 7 0wf 10

This theorem is referenced by: distid 869

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-i1 43 df-i2 44 df-le1 122 df-le2 123 df-c1 124 df-c2 125

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