mndind

Description: Induction in a monoid. In this theorem, ps ( x ) is the "generic" proposition to be be proved (the first four hypotheses tell its values at y, y+z, 0, A respectively). The two induction hypotheses mndind.i1 and mndind.i2 tell that it is true at 0, that if it is true at y then it is true at y+z (provided z is in G ). The hypothesis mndind.k tells that G is generating. (Contributed by SO, 14-Jul-2018)

	Ref	Expression
Hypotheses	mndind.ch	$⊢ x = y \to (ψ \leftrightarrow χ)$
	mndind.th	$⊢ x = y \underset{˙}{+} z \to (ψ \leftrightarrow θ)$
	mndind.ta	$⊢ x = \underset{˙}{0} \to (ψ \leftrightarrow τ)$
	mndind.et	$⊢ x = A \to (ψ \leftrightarrow η)$
	mndind.0g	$⊢ \underset{˙}{0} = 0_{M}$
	mndind.pg	$⊢ \underset{˙}{+} = +_{M}$
	mndind.b	$⊢ B = {Base}_{M}$
	mndind.m	$⊢ φ \to M \in Mnd$
	mndind.g	$⊢ φ \to G \subseteq B$
	mndind.k	$⊢ φ \to B = mrCls (SubMnd (M)) (G)$
	mndind.i1	$⊢ φ \to τ$
	mndind.i2	$⊢ ((φ \land y \in B \land z \in G) \land χ) \to θ$
	mndind.a	$⊢ φ \to A \in B$
Assertion	mndind	$⊢ φ \to η$

Proof

Step	Hyp	Ref	Expression
1		mndind.ch	$⊢ x = y \to (ψ \leftrightarrow χ)$
2		mndind.th	$⊢ x = y \underset{˙}{+} z \to (ψ \leftrightarrow θ)$
3		mndind.ta	$⊢ x = \underset{˙}{0} \to (ψ \leftrightarrow τ)$
4		mndind.et	$⊢ x = A \to (ψ \leftrightarrow η)$
5		mndind.0g	$⊢ \underset{˙}{0} = 0_{M}$
6		mndind.pg	$⊢ \underset{˙}{+} = +_{M}$
7		mndind.b	$⊢ B = {Base}_{M}$
8		mndind.m	$⊢ φ \to M \in Mnd$
9		mndind.g	$⊢ φ \to G \subseteq B$
10		mndind.k	$⊢ φ \to B = mrCls (SubMnd (M)) (G)$
11		mndind.i1	$⊢ φ \to τ$
12		mndind.i2	$⊢ ((φ \land y \in B \land z \in G) \land χ) \to θ$
13		mndind.a	$⊢ φ \to A \in B$
14	7 5	mndidcl	$⊢ M \in Mnd \to \underset{˙}{0} \in B$
15	8 14	syl	$⊢ φ \to \underset{˙}{0} \in B$
16	3	sbcieg	$⊢ \underset{˙}{0} \in B \to (\underset{˙}{[} \underset{˙}{0} / x \underset{˙}{]} ψ \leftrightarrow τ)$
17	15 16	syl	$⊢ φ \to (\underset{˙}{[} \underset{˙}{0} / x \underset{˙}{]} ψ \leftrightarrow τ)$
18	11 17	mpbird	$⊢ φ \to \underset{˙}{[} \underset{˙}{0} / x \underset{˙}{]} ψ$
19		dfsbcq	$⊢ a = \underset{˙}{0} \to (\underset{˙}{[} a / x \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} \underset{˙}{0} / x \underset{˙}{]} ψ)$
20		oveq1	$⊢ a = \underset{˙}{0} \to a \underset{˙}{+} A = \underset{˙}{0} \underset{˙}{+} A$
21	20	sbceq1d	$⊢ a = \underset{˙}{0} \to (\underset{˙}{[} (a \underset{˙}{+} A) / x \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} (\underset{˙}{0} \underset{˙}{+} A) / x \underset{˙}{]} ψ)$
22	19 21	imbi12d	$⊢ a = \underset{˙}{0} \to ((\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} A) / x \underset{˙}{]} ψ) \leftrightarrow (\underset{˙}{[} \underset{˙}{0} / x \underset{˙}{]} ψ \to \underset{˙}{[} (\underset{˙}{0} \underset{˙}{+} A) / x \underset{˙}{]} ψ))$
23	7	submacs	$⊢ M \in Mnd \to SubMnd (M) \in ACS (B)$
24	8 23	syl	$⊢ φ \to SubMnd (M) \in ACS (B)$
25	24	acsmred	$⊢ φ \to SubMnd (M) \in Moore (B)$
26		eleq1w	$⊢ y = a \to (y \in B \leftrightarrow a \in B)$
27	26	anbi2d	$⊢ y = a \to (((φ \land b \in G) \land y \in B) \leftrightarrow ((φ \land b \in G) \land a \in B))$
28		vex	$⊢ y \in V$
29	28 1	sbcie	$⊢ \underset{˙}{[} y / x \underset{˙}{]} ψ \leftrightarrow χ$
30		dfsbcq	$⊢ y = a \to (\underset{˙}{[} y / x \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} a / x \underset{˙}{]} ψ)$
31	29 30	bitr3id	$⊢ y = a \to (χ \leftrightarrow \underset{˙}{[} a / x \underset{˙}{]} ψ)$
32		oveq1	$⊢ y = a \to y \underset{˙}{+} b = a \underset{˙}{+} b$
33	32	sbceq1d	$⊢ y = a \to (\underset{˙}{[} (y \underset{˙}{+} b) / x \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ)$
34	31 33	imbi12d	$⊢ y = a \to ((χ \to \underset{˙}{[} (y \underset{˙}{+} b) / x \underset{˙}{]} ψ) \leftrightarrow (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ))$
35	27 34	imbi12d	$⊢ y = a \to ((((φ \land b \in G) \land y \in B) \to (χ \to \underset{˙}{[} (y \underset{˙}{+} b) / x \underset{˙}{]} ψ)) \leftrightarrow (((φ \land b \in G) \land a \in B) \to (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ)))$
36		eleq1w	$⊢ z = b \to (z \in G \leftrightarrow b \in G)$
37	36	anbi2d	$⊢ z = b \to ((φ \land z \in G) \leftrightarrow (φ \land b \in G))$
38	37	anbi1d	$⊢ z = b \to (((φ \land z \in G) \land y \in B) \leftrightarrow ((φ \land b \in G) \land y \in B))$
39		ovex	$⊢ y \underset{˙}{+} z \in V$
40	39 2	sbcie	$⊢ \underset{˙}{[} (y \underset{˙}{+} z) / x \underset{˙}{]} ψ \leftrightarrow θ$
41		oveq2	$⊢ z = b \to y \underset{˙}{+} z = y \underset{˙}{+} b$
42	41	sbceq1d	$⊢ z = b \to (\underset{˙}{[} (y \underset{˙}{+} z) / x \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} (y \underset{˙}{+} b) / x \underset{˙}{]} ψ)$
43	40 42	bitr3id	$⊢ z = b \to (θ \leftrightarrow \underset{˙}{[} (y \underset{˙}{+} b) / x \underset{˙}{]} ψ)$
44	43	imbi2d	$⊢ z = b \to ((χ \to θ) \leftrightarrow (χ \to \underset{˙}{[} (y \underset{˙}{+} b) / x \underset{˙}{]} ψ))$
45	38 44	imbi12d	$⊢ z = b \to ((((φ \land z \in G) \land y \in B) \to (χ \to θ)) \leftrightarrow (((φ \land b \in G) \land y \in B) \to (χ \to \underset{˙}{[} (y \underset{˙}{+} b) / x \underset{˙}{]} ψ)))$
46	12	ex	$⊢ (φ \land y \in B \land z \in G) \to (χ \to θ)$
47	46	3expa	$⊢ ((φ \land y \in B) \land z \in G) \to (χ \to θ)$
48	47	an32s	$⊢ ((φ \land z \in G) \land y \in B) \to (χ \to θ)$
49	45 48	chvarvv	$⊢ ((φ \land b \in G) \land y \in B) \to (χ \to \underset{˙}{[} (y \underset{˙}{+} b) / x \underset{˙}{]} ψ)$
50	35 49	chvarvv	$⊢ ((φ \land b \in G) \land a \in B) \to (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ)$
51	50	ralrimiva	$⊢ (φ \land b \in G) \to \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ)$
52	9 51	ssrabdv	$⊢ φ \to G \subseteq \{b \in B \| \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ)\}$
53	7 6 5	mndrid	$⊢ (M \in Mnd \land a \in B) \to a \underset{˙}{+} \underset{˙}{0} = a$
54	8 53	sylan	$⊢ (φ \land a \in B) \to a \underset{˙}{+} \underset{˙}{0} = a$
55	54	sbceq1d	$⊢ (φ \land a \in B) \to (\underset{˙}{[} (a \underset{˙}{+} \underset{˙}{0}) / x \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} a / x \underset{˙}{]} ψ)$
56	55	biimprd	$⊢ (φ \land a \in B) \to (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} \underset{˙}{0}) / x \underset{˙}{]} ψ)$
57	56	ralrimiva	$⊢ φ \to \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} \underset{˙}{0}) / x \underset{˙}{]} ψ)$
58		simprrl	$⊢ (φ \land ((c \in B \land d \in B) \land (\forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} c) / x \underset{˙}{]} ψ) \land \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} d) / x \underset{˙}{]} ψ)))) \to \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} c) / x \underset{˙}{]} ψ)$
59	8	ad2antrr	$⊢ ((φ \land (c \in B \land d \in B)) \land b \in B) \to M \in Mnd$
60		simpr	$⊢ ((φ \land (c \in B \land d \in B)) \land b \in B) \to b \in B$
61		simplrl	$⊢ ((φ \land (c \in B \land d \in B)) \land b \in B) \to c \in B$
62	7 6	mndcl	$⊢ (M \in Mnd \land b \in B \land c \in B) \to b \underset{˙}{+} c \in B$
63	59 60 61 62	syl3anc	$⊢ ((φ \land (c \in B \land d \in B)) \land b \in B) \to b \underset{˙}{+} c \in B$
64		simpr	$⊢ (((φ \land (c \in B \land d \in B)) \land b \in B) \land a = b \underset{˙}{+} c) \to a = b \underset{˙}{+} c$
65	64	sbceq1d	$⊢ (((φ \land (c \in B \land d \in B)) \land b \in B) \land a = b \underset{˙}{+} c) \to (\underset{˙}{[} a / x \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} (b \underset{˙}{+} c) / x \underset{˙}{]} ψ)$
66		oveq1	$⊢ a = b \underset{˙}{+} c \to a \underset{˙}{+} d = (b \underset{˙}{+} c) \underset{˙}{+} d$
67		simplrr	$⊢ ((φ \land (c \in B \land d \in B)) \land b \in B) \to d \in B$
68	7 6	mndass	$⊢ (M \in Mnd \land (b \in B \land c \in B \land d \in B)) \to (b \underset{˙}{+} c) \underset{˙}{+} d = b \underset{˙}{+} (c \underset{˙}{+} d)$
69	59 60 61 67 68	syl13anc	$⊢ ((φ \land (c \in B \land d \in B)) \land b \in B) \to (b \underset{˙}{+} c) \underset{˙}{+} d = b \underset{˙}{+} (c \underset{˙}{+} d)$
70	66 69	sylan9eqr	$⊢ (((φ \land (c \in B \land d \in B)) \land b \in B) \land a = b \underset{˙}{+} c) \to a \underset{˙}{+} d = b \underset{˙}{+} (c \underset{˙}{+} d)$
71	70	sbceq1d	$⊢ (((φ \land (c \in B \land d \in B)) \land b \in B) \land a = b \underset{˙}{+} c) \to (\underset{˙}{[} (a \underset{˙}{+} d) / x \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} (b \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ)$
72	65 71	imbi12d	$⊢ (((φ \land (c \in B \land d \in B)) \land b \in B) \land a = b \underset{˙}{+} c) \to ((\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} d) / x \underset{˙}{]} ψ) \leftrightarrow (\underset{˙}{[} (b \underset{˙}{+} c) / x \underset{˙}{]} ψ \to \underset{˙}{[} (b \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ))$
73	63 72	rspcdv	$⊢ ((φ \land (c \in B \land d \in B)) \land b \in B) \to (\forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} d) / x \underset{˙}{]} ψ) \to (\underset{˙}{[} (b \underset{˙}{+} c) / x \underset{˙}{]} ψ \to \underset{˙}{[} (b \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ))$
74	73	ralrimdva	$⊢ (φ \land (c \in B \land d \in B)) \to (\forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} d) / x \underset{˙}{]} ψ) \to \forall b \in B (\underset{˙}{[} (b \underset{˙}{+} c) / x \underset{˙}{]} ψ \to \underset{˙}{[} (b \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ))$
75	74	impr	$⊢ (φ \land ((c \in B \land d \in B) \land \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} d) / x \underset{˙}{]} ψ))) \to \forall b \in B (\underset{˙}{[} (b \underset{˙}{+} c) / x \underset{˙}{]} ψ \to \underset{˙}{[} (b \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ)$
76		oveq1	$⊢ b = a \to b \underset{˙}{+} c = a \underset{˙}{+} c$
77	76	sbceq1d	$⊢ b = a \to (\underset{˙}{[} (b \underset{˙}{+} c) / x \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} (a \underset{˙}{+} c) / x \underset{˙}{]} ψ)$
78		oveq1	$⊢ b = a \to b \underset{˙}{+} (c \underset{˙}{+} d) = a \underset{˙}{+} (c \underset{˙}{+} d)$
79	78	sbceq1d	$⊢ b = a \to (\underset{˙}{[} (b \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} (a \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ)$
80	77 79	imbi12d	$⊢ b = a \to ((\underset{˙}{[} (b \underset{˙}{+} c) / x \underset{˙}{]} ψ \to \underset{˙}{[} (b \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ) \leftrightarrow (\underset{˙}{[} (a \underset{˙}{+} c) / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ))$
81	80	cbvralvw	$⊢ \forall b \in B (\underset{˙}{[} (b \underset{˙}{+} c) / x \underset{˙}{]} ψ \to \underset{˙}{[} (b \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ) \leftrightarrow \forall a \in B (\underset{˙}{[} (a \underset{˙}{+} c) / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ)$
82	75 81	sylib	$⊢ (φ \land ((c \in B \land d \in B) \land \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} d) / x \underset{˙}{]} ψ))) \to \forall a \in B (\underset{˙}{[} (a \underset{˙}{+} c) / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ)$
83	82	adantrrl	$⊢ (φ \land ((c \in B \land d \in B) \land (\forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} c) / x \underset{˙}{]} ψ) \land \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} d) / x \underset{˙}{]} ψ)))) \to \forall a \in B (\underset{˙}{[} (a \underset{˙}{+} c) / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ)$
84		imim1	$⊢ (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} c) / x \underset{˙}{]} ψ) \to ((\underset{˙}{[} (a \underset{˙}{+} c) / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ) \to (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ))$
85	84	ral2imi	$⊢ \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} c) / x \underset{˙}{]} ψ) \to (\forall a \in B (\underset{˙}{[} (a \underset{˙}{+} c) / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ) \to \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ))$
86	58 83 85	sylc	$⊢ (φ \land ((c \in B \land d \in B) \land (\forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} c) / x \underset{˙}{]} ψ) \land \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} d) / x \underset{˙}{]} ψ)))) \to \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ)$
87		oveq2	$⊢ b = \underset{˙}{0} \to a \underset{˙}{+} b = a \underset{˙}{+} \underset{˙}{0}$
88	87	sbceq1d	$⊢ b = \underset{˙}{0} \to (\underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} (a \underset{˙}{+} \underset{˙}{0}) / x \underset{˙}{]} ψ)$
89	88	imbi2d	$⊢ b = \underset{˙}{0} \to ((\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ) \leftrightarrow (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} \underset{˙}{0}) / x \underset{˙}{]} ψ))$
90	89	ralbidv	$⊢ b = \underset{˙}{0} \to (\forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ) \leftrightarrow \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} \underset{˙}{0}) / x \underset{˙}{]} ψ))$
91		oveq2	$⊢ b = c \to a \underset{˙}{+} b = a \underset{˙}{+} c$
92	91	sbceq1d	$⊢ b = c \to (\underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} (a \underset{˙}{+} c) / x \underset{˙}{]} ψ)$
93	92	imbi2d	$⊢ b = c \to ((\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ) \leftrightarrow (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} c) / x \underset{˙}{]} ψ))$
94	93	ralbidv	$⊢ b = c \to (\forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ) \leftrightarrow \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} c) / x \underset{˙}{]} ψ))$
95		oveq2	$⊢ b = d \to a \underset{˙}{+} b = a \underset{˙}{+} d$
96	95	sbceq1d	$⊢ b = d \to (\underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} (a \underset{˙}{+} d) / x \underset{˙}{]} ψ)$
97	96	imbi2d	$⊢ b = d \to ((\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ) \leftrightarrow (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} d) / x \underset{˙}{]} ψ))$
98	97	ralbidv	$⊢ b = d \to (\forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ) \leftrightarrow \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} d) / x \underset{˙}{]} ψ))$
99		oveq2	$⊢ b = c \underset{˙}{+} d \to a \underset{˙}{+} b = a \underset{˙}{+} (c \underset{˙}{+} d)$
100	99	sbceq1d	$⊢ b = c \underset{˙}{+} d \to (\underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} (a \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ)$
101	100	imbi2d	$⊢ b = c \underset{˙}{+} d \to ((\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ) \leftrightarrow (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ))$
102	101	ralbidv	$⊢ b = c \underset{˙}{+} d \to (\forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ) \leftrightarrow \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} (c \underset{˙}{+} d)) / x \underset{˙}{]} ψ))$
103	7 6 5 8 57 86 90 94 98 102	issubmd	$⊢ φ \to \{b \in B \| \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ)\} \in SubMnd (M)$
104		eqid	$⊢ mrCls (SubMnd (M)) = mrCls (SubMnd (M))$
105	104	mrcsscl	$⊢ (SubMnd (M) \in Moore (B) \land G \subseteq \{b \in B \| \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ)\} \land \{b \in B \| \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ)\} \in SubMnd (M)) \to mrCls (SubMnd (M)) (G) \subseteq \{b \in B \| \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ)\}$
106	25 52 103 105	syl3anc	$⊢ φ \to mrCls (SubMnd (M)) (G) \subseteq \{b \in B \| \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ)\}$
107	10 106	eqsstrd	$⊢ φ \to B \subseteq \{b \in B \| \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ)\}$
108	107 13	sseldd	$⊢ φ \to A \in \{b \in B \| \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ)\}$
109		oveq2	$⊢ b = A \to a \underset{˙}{+} b = a \underset{˙}{+} A$
110	109	sbceq1d	$⊢ b = A \to (\underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} (a \underset{˙}{+} A) / x \underset{˙}{]} ψ)$
111	110	imbi2d	$⊢ b = A \to ((\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ) \leftrightarrow (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} A) / x \underset{˙}{]} ψ))$
112	111	ralbidv	$⊢ b = A \to (\forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ) \leftrightarrow \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} A) / x \underset{˙}{]} ψ))$
113	112	elrab	$⊢ A \in \{b \in B \| \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ)\} \leftrightarrow (A \in B \land \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} A) / x \underset{˙}{]} ψ))$
114	113	simprbi	$⊢ A \in \{b \in B \| \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} b) / x \underset{˙}{]} ψ)\} \to \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} A) / x \underset{˙}{]} ψ)$
115	108 114	syl	$⊢ φ \to \forall a \in B (\underset{˙}{[} a / x \underset{˙}{]} ψ \to \underset{˙}{[} (a \underset{˙}{+} A) / x \underset{˙}{]} ψ)$
116	22 115 15	rspcdva	$⊢ φ \to (\underset{˙}{[} \underset{˙}{0} / x \underset{˙}{]} ψ \to \underset{˙}{[} (\underset{˙}{0} \underset{˙}{+} A) / x \underset{˙}{]} ψ)$
117	18 116	mpd	$⊢ φ \to \underset{˙}{[} (\underset{˙}{0} \underset{˙}{+} A) / x \underset{˙}{]} ψ$
118	7 6 5	mndlid	$⊢ (M \in Mnd \land A \in B) \to \underset{˙}{0} \underset{˙}{+} A = A$
119	8 13 118	syl2anc	$⊢ φ \to \underset{˙}{0} \underset{˙}{+} A = A$
120	119	sbceq1d	$⊢ φ \to (\underset{˙}{[} (\underset{˙}{0} \underset{˙}{+} A) / x \underset{˙}{]} ψ \leftrightarrow \underset{˙}{[} A / x \underset{˙}{]} ψ)$
121	4	sbcieg	$⊢ A \in B \to (\underset{˙}{[} A / x \underset{˙}{]} ψ \leftrightarrow η)$
122	13 121	syl	$⊢ φ \to (\underset{˙}{[} A / x \underset{˙}{]} ψ \leftrightarrow η)$
123	120 122	bitrd	$⊢ φ \to (\underset{˙}{[} (\underset{˙}{0} \underset{˙}{+} A) / x \underset{˙}{]} ψ \leftrightarrow η)$
124	117 123	mpbid	$⊢ φ \to η$

Metamath Proof Explorer

Theorem mndind

Proof