oa4uto4 - Quantum Logic Explorer

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Theorem oa4uto4 977

Description: Derivation of standard 4-variable proper OA law from "universal" variant oa4to4u2 974.

**Hypothesis**
Ref	Expression
oa4uto4.1	((a →₁d) ∩ ((a^⊥ →₁d) ∪ ((b^⊥ →₁d) ∩ ((((a →₁d) ∩ (b →₁d)) ∪ ((a^⊥ →₁d) ∩ (b^⊥ →₁d))) ∪ ((((a →₁d) ∩ (c →₁d)) ∪ ((a^⊥ →₁d) ∩ (c^⊥ →₁d))) ∩ (((b →₁d) ∩ (c →₁d)) ∪ ((b^⊥ →₁d) ∩ (c^⊥ →₁d)))))))) ≤ d

**Assertion**
Ref	Expression
oa4uto4	((a →₁d) ∩ (a ∪ (b ∩ (((a ∩ b) ∪ ((a →₁d) ∩ (b →₁d))) ∪ (((a ∩ c) ∪ ((a →₁d) ∩ (c →₁d))) ∩ ((b ∩ c) ∪ ((b →₁d) ∩ (c →₁d)))))))) ≤ d

**Proof of Theorem oa4uto4**
Step	Hyp	Ref	Expression
1		u1lem9a 777	. . . . 5 (a^⊥ →₁d)^⊥ ≤ a^⊥
2	1	lecon1 155	. . . 4 a ≤ (a^⊥ →₁d)
3		u1lem9a 777	. . . . . 6 (b^⊥ →₁d)^⊥ ≤ b^⊥
4	3	lecon1 155	. . . . 5 b ≤ (b^⊥ →₁d)
5		ax-a2 31	. . . . . . 7 ((a ∩ b) ∪ ((a →₁d) ∩ (b →₁d))) = (((a →₁d) ∩ (b →₁d)) ∪ (a ∩ b))
6	2, 4	le2an 169	. . . . . . . 8 (a ∩ b) ≤ ((a^⊥ →₁d) ∩ (b^⊥ →₁d))
7	6	lelor 166	. . . . . . 7 (((a →₁d) ∩ (b →₁d)) ∪ (a ∩ b)) ≤ (((a →₁d) ∩ (b →₁d)) ∪ ((a^⊥ →₁d) ∩ (b^⊥ →₁d)))
8	5, 7	bltr 138	. . . . . 6 ((a ∩ b) ∪ ((a →₁d) ∩ (b →₁d))) ≤ (((a →₁d) ∩ (b →₁d)) ∪ ((a^⊥ →₁d) ∩ (b^⊥ →₁d)))
9		ax-a2 31	. . . . . . . 8 ((a ∩ c) ∪ ((a →₁d) ∩ (c →₁d))) = (((a →₁d) ∩ (c →₁d)) ∪ (a ∩ c))
10		u1lem9a 777	. . . . . . . . . . 11 (c^⊥ →₁d)^⊥ ≤ c^⊥
11	10	lecon1 155	. . . . . . . . . 10 c ≤ (c^⊥ →₁d)
12	2, 11	le2an 169	. . . . . . . . 9 (a ∩ c) ≤ ((a^⊥ →₁d) ∩ (c^⊥ →₁d))
13	12	lelor 166	. . . . . . . 8 (((a →₁d) ∩ (c →₁d)) ∪ (a ∩ c)) ≤ (((a →₁d) ∩ (c →₁d)) ∪ ((a^⊥ →₁d) ∩ (c^⊥ →₁d)))
14	9, 13	bltr 138	. . . . . . 7 ((a ∩ c) ∪ ((a →₁d) ∩ (c →₁d))) ≤ (((a →₁d) ∩ (c →₁d)) ∪ ((a^⊥ →₁d) ∩ (c^⊥ →₁d)))
15		ax-a2 31	. . . . . . . 8 ((b ∩ c) ∪ ((b →₁d) ∩ (c →₁d))) = (((b →₁d) ∩ (c →₁d)) ∪ (b ∩ c))
16	4, 11	le2an 169	. . . . . . . . 9 (b ∩ c) ≤ ((b^⊥ →₁d) ∩ (c^⊥ →₁d))
17	16	lelor 166	. . . . . . . 8 (((b →₁d) ∩ (c →₁d)) ∪ (b ∩ c)) ≤ (((b →₁d) ∩ (c →₁d)) ∪ ((b^⊥ →₁d) ∩ (c^⊥ →₁d)))
18	15, 17	bltr 138	. . . . . . 7 ((b ∩ c) ∪ ((b →₁d) ∩ (c →₁d))) ≤ (((b →₁d) ∩ (c →₁d)) ∪ ((b^⊥ →₁d) ∩ (c^⊥ →₁d)))
19	14, 18	le2an 169	. . . . . 6 (((a ∩ c) ∪ ((a →₁d) ∩ (c →₁d))) ∩ ((b ∩ c) ∪ ((b →₁d) ∩ (c →₁d)))) ≤ ((((a →₁d) ∩ (c →₁d)) ∪ ((a^⊥ →₁d) ∩ (c^⊥ →₁d))) ∩ (((b →₁d) ∩ (c →₁d)) ∪ ((b^⊥ →₁d) ∩ (c^⊥ →₁d))))
20	8, 19	le2or 168	. . . . 5 (((a ∩ b) ∪ ((a →₁d) ∩ (b →₁d))) ∪ (((a ∩ c) ∪ ((a →₁d) ∩ (c →₁d))) ∩ ((b ∩ c) ∪ ((b →₁d) ∩ (c →₁d))))) ≤ ((((a →₁d) ∩ (b →₁d)) ∪ ((a^⊥ →₁d) ∩ (b^⊥ →₁d))) ∪ ((((a →₁d) ∩ (c →₁d)) ∪ ((a^⊥ →₁d) ∩ (c^⊥ →₁d))) ∩ (((b →₁d) ∩ (c →₁d)) ∪ ((b^⊥ →₁d) ∩ (c^⊥ →₁d)))))
21	4, 20	le2an 169	. . . 4 (b ∩ (((a ∩ b) ∪ ((a →₁d) ∩ (b →₁d))) ∪ (((a ∩ c) ∪ ((a →₁d) ∩ (c →₁d))) ∩ ((b ∩ c) ∪ ((b →₁d) ∩ (c →₁d)))))) ≤ ((b^⊥ →₁d) ∩ ((((a →₁d) ∩ (b →₁d)) ∪ ((a^⊥ →₁d) ∩ (b^⊥ →₁d))) ∪ ((((a →₁d) ∩ (c →₁d)) ∪ ((a^⊥ →₁d) ∩ (c^⊥ →₁d))) ∩ (((b →₁d) ∩ (c →₁d)) ∪ ((b^⊥ →₁d) ∩ (c^⊥ →₁d))))))
22	2, 21	le2or 168	. . 3 (a ∪ (b ∩ (((a ∩ b) ∪ ((a →₁d) ∩ (b →₁d))) ∪ (((a ∩ c) ∪ ((a →₁d) ∩ (c →₁d))) ∩ ((b ∩ c) ∪ ((b →₁d) ∩ (c →₁d))))))) ≤ ((a^⊥ →₁d) ∪ ((b^⊥ →₁d) ∩ ((((a →₁d) ∩ (b →₁d)) ∪ ((a^⊥ →₁d) ∩ (b^⊥ →₁d))) ∪ ((((a →₁d) ∩ (c →₁d)) ∪ ((a^⊥ →₁d) ∩ (c^⊥ →₁d))) ∩ (((b →₁d) ∩ (c →₁d)) ∪ ((b^⊥ →₁d) ∩ (c^⊥ →₁d)))))))
23	22	lelan 167	. 2 ((a →₁d) ∩ (a ∪ (b ∩ (((a ∩ b) ∪ ((a →₁d) ∩ (b →₁d))) ∪ (((a ∩ c) ∪ ((a →₁d) ∩ (c →₁d))) ∩ ((b ∩ c) ∪ ((b →₁d) ∩ (c →₁d)))))))) ≤ ((a →₁d) ∩ ((a^⊥ →₁d) ∪ ((b^⊥ →₁d) ∩ ((((a →₁d) ∩ (b →₁d)) ∪ ((a^⊥ →₁d) ∩ (b^⊥ →₁d))) ∪ ((((a →₁d) ∩ (c →₁d)) ∪ ((a^⊥ →₁d) ∩ (c^⊥ →₁d))) ∩ (((b →₁d) ∩ (c →₁d)) ∪ ((b^⊥ →₁d) ∩ (c^⊥ →₁d))))))))
24		oa4uto4.1	. 2 ((a →₁d) ∩ ((a^⊥ →₁d) ∪ ((b^⊥ →₁d) ∩ ((((a →₁d) ∩ (b →₁d)) ∪ ((a^⊥ →₁d) ∩ (b^⊥ →₁d))) ∪ ((((a →₁d) ∩ (c →₁d)) ∪ ((a^⊥ →₁d) ∩ (c^⊥ →₁d))) ∩ (((b →₁d) ∩ (c →₁d)) ∪ ((b^⊥ →₁d) ∩ (c^⊥ →₁d)))))))) ≤ d
25	23, 24	letr 137	1 ((a →₁d) ∩ (a ∪ (b ∩ (((a ∩ b) ∪ ((a →₁d) ∩ (b →₁d))) ∪ (((a ∩ c) ∪ ((a →₁d) ∩ (c →₁d))) ∩ ((b ∩ c) ∪ ((b →₁d) ∩ (c →₁d)))))))) ≤ d

Colors of variables: term

Syntax hints: ≤ wle 2 ^⊥ wn 4 ∪ wo 6 ∩ wa 7 →₁wi1 12

This theorem was proved from axioms: ax-a1 30 ax-a2 31 ax-a3 32 ax-a5 34 ax-r1 35 ax-r2 36 ax-r4 37 ax-r5 38

This theorem depends on definitions: df-a 40 df-t 41 df-f 42 df-i1 44 df-le1 130 df-le2 131

This theorem is referenced by: d6oa 997 axoa4 1034

W3C validator