no3inds

Description: Triple induction over surreal numbers. (Contributed by Scott Fenton, 9-Oct-2024)

	Ref	Expression
Hypotheses	no3inds.1	$⊢ a = d \to (φ \leftrightarrow ψ)$
	no3inds.2	$⊢ b = e \to (ψ \leftrightarrow χ)$
	no3inds.3	$⊢ c = f \to (χ \leftrightarrow θ)$
	no3inds.4	$⊢ a = d \to (τ \leftrightarrow θ)$
	no3inds.5	$⊢ b = e \to (η \leftrightarrow τ)$
	no3inds.6	$⊢ b = e \to (ζ \leftrightarrow θ)$
	no3inds.7	$⊢ c = f \to (σ \leftrightarrow τ)$
	no3inds.8	$⊢ a = X \to (φ \leftrightarrow ρ)$
	no3inds.9	$⊢ b = Y \to (ρ \leftrightarrow μ)$
	no3inds.10	$⊢ c = Z \to (μ \leftrightarrow λ)$
	no3inds.i	$⊢ (a \in No \land b \in No \land c \in No) \to (((\forall d \in (L (a) \cup R (a)) \forall e \in (L (b) \cup R (b)) \forall f \in (L (c) \cup R (c)) θ \land \forall d \in (L (a) \cup R (a)) \forall e \in (L (b) \cup R (b)) χ \land \forall d \in (L (a) \cup R (a)) \forall f \in (L (c) \cup R (c)) ζ) \land (\forall d \in (L (a) \cup R (a)) ψ \land \forall e \in (L (b) \cup R (b)) \forall f \in (L (c) \cup R (c)) τ \land \forall e \in (L (b) \cup R (b)) σ) \land \forall f \in (L (c) \cup R (c)) η) \to φ)$
Assertion	no3inds	$⊢ (X \in No \land Y \in No \land Z \in No) \to λ$

Proof

Step	Hyp	Ref	Expression
1		no3inds.1	$⊢ a = d \to (φ \leftrightarrow ψ)$
2		no3inds.2	$⊢ b = e \to (ψ \leftrightarrow χ)$
3		no3inds.3	$⊢ c = f \to (χ \leftrightarrow θ)$
4		no3inds.4	$⊢ a = d \to (τ \leftrightarrow θ)$
5		no3inds.5	$⊢ b = e \to (η \leftrightarrow τ)$
6		no3inds.6	$⊢ b = e \to (ζ \leftrightarrow θ)$
7		no3inds.7	$⊢ c = f \to (σ \leftrightarrow τ)$
8		no3inds.8	$⊢ a = X \to (φ \leftrightarrow ρ)$
9		no3inds.9	$⊢ b = Y \to (ρ \leftrightarrow μ)$
10		no3inds.10	$⊢ c = Z \to (μ \leftrightarrow λ)$
11		no3inds.i	$⊢ (a \in No \land b \in No \land c \in No) \to (((\forall d \in (L (a) \cup R (a)) \forall e \in (L (b) \cup R (b)) \forall f \in (L (c) \cup R (c)) θ \land \forall d \in (L (a) \cup R (a)) \forall e \in (L (b) \cup R (b)) χ \land \forall d \in (L (a) \cup R (a)) \forall f \in (L (c) \cup R (c)) ζ) \land (\forall d \in (L (a) \cup R (a)) ψ \land \forall e \in (L (b) \cup R (b)) \forall f \in (L (c) \cup R (c)) τ \land \forall e \in (L (b) \cup R (b)) σ) \land \forall f \in (L (c) \cup R (c)) η) \to φ)$
12		eqid	$⊢ \{⟨x, y⟩ \| x \in (L (y) \cup R (y))\} = \{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}$
13	12	lrrecfr	$⊢ \{⟨x, y⟩ \| x \in (L (y) \cup R (y))\} Fr No$
14	12	lrrecpo	$⊢ \{⟨x, y⟩ \| x \in (L (y) \cup R (y))\} Po No$
15	12	lrrecse	$⊢ \{⟨x, y⟩ \| x \in (L (y) \cup R (y))\} Se No$
16	12	lrrecpred	$⊢ a \in No \to Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) = L (a) \cup R (a)$
17	16	3ad2ant1	$⊢ (a \in No \land b \in No \land c \in No) \to Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) = L (a) \cup R (a)$
18	12	lrrecpred	$⊢ b \in No \to Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) = L (b) \cup R (b)$
19	18	3ad2ant2	$⊢ (a \in No \land b \in No \land c \in No) \to Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) = L (b) \cup R (b)$
20	12	lrrecpred	$⊢ c \in No \to Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) = L (c) \cup R (c)$
21	20	3ad2ant3	$⊢ (a \in No \land b \in No \land c \in No) \to Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) = L (c) \cup R (c)$
22	21	raleqdv	$⊢ (a \in No \land b \in No \land c \in No) \to (\forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) θ \leftrightarrow \forall f \in (L (c) \cup R (c)) θ)$
23	19 22	raleqbidv	$⊢ (a \in No \land b \in No \land c \in No) \to (\forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) \forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) θ \leftrightarrow \forall e \in (L (b) \cup R (b)) \forall f \in (L (c) \cup R (c)) θ)$
24	17 23	raleqbidv	$⊢ (a \in No \land b \in No \land c \in No) \to (\forall d \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) \forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) \forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) θ \leftrightarrow \forall d \in (L (a) \cup R (a)) \forall e \in (L (b) \cup R (b)) \forall f \in (L (c) \cup R (c)) θ)$
25	19	raleqdv	$⊢ (a \in No \land b \in No \land c \in No) \to (\forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) χ \leftrightarrow \forall e \in (L (b) \cup R (b)) χ)$
26	17 25	raleqbidv	$⊢ (a \in No \land b \in No \land c \in No) \to (\forall d \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) \forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) χ \leftrightarrow \forall d \in (L (a) \cup R (a)) \forall e \in (L (b) \cup R (b)) χ)$
27	21	raleqdv	$⊢ (a \in No \land b \in No \land c \in No) \to (\forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) ζ \leftrightarrow \forall f \in (L (c) \cup R (c)) ζ)$
28	17 27	raleqbidv	$⊢ (a \in No \land b \in No \land c \in No) \to (\forall d \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) \forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) ζ \leftrightarrow \forall d \in (L (a) \cup R (a)) \forall f \in (L (c) \cup R (c)) ζ)$
29	24 26 28	3anbi123d	$⊢ (a \in No \land b \in No \land c \in No) \to ((\forall d \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) \forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) \forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) θ \land \forall d \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) \forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) χ \land \forall d \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) \forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) ζ) \leftrightarrow (\forall d \in (L (a) \cup R (a)) \forall e \in (L (b) \cup R (b)) \forall f \in (L (c) \cup R (c)) θ \land \forall d \in (L (a) \cup R (a)) \forall e \in (L (b) \cup R (b)) χ \land \forall d \in (L (a) \cup R (a)) \forall f \in (L (c) \cup R (c)) ζ))$
30	17	raleqdv	$⊢ (a \in No \land b \in No \land c \in No) \to (\forall d \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) ψ \leftrightarrow \forall d \in (L (a) \cup R (a)) ψ)$
31	21	raleqdv	$⊢ (a \in No \land b \in No \land c \in No) \to (\forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) τ \leftrightarrow \forall f \in (L (c) \cup R (c)) τ)$
32	19 31	raleqbidv	$⊢ (a \in No \land b \in No \land c \in No) \to (\forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) \forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) τ \leftrightarrow \forall e \in (L (b) \cup R (b)) \forall f \in (L (c) \cup R (c)) τ)$
33	19	raleqdv	$⊢ (a \in No \land b \in No \land c \in No) \to (\forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) σ \leftrightarrow \forall e \in (L (b) \cup R (b)) σ)$
34	30 32 33	3anbi123d	$⊢ (a \in No \land b \in No \land c \in No) \to ((\forall d \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) ψ \land \forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) \forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) τ \land \forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) σ) \leftrightarrow (\forall d \in (L (a) \cup R (a)) ψ \land \forall e \in (L (b) \cup R (b)) \forall f \in (L (c) \cup R (c)) τ \land \forall e \in (L (b) \cup R (b)) σ))$
35	21	raleqdv	$⊢ (a \in No \land b \in No \land c \in No) \to (\forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) η \leftrightarrow \forall f \in (L (c) \cup R (c)) η)$
36	29 34 35	3anbi123d	$⊢ (a \in No \land b \in No \land c \in No) \to (((\forall d \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) \forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) \forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) θ \land \forall d \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) \forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) χ \land \forall d \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) \forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) ζ) \land (\forall d \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) ψ \land \forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) \forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) τ \land \forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) σ) \land \forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) η) \leftrightarrow ((\forall d \in (L (a) \cup R (a)) \forall e \in (L (b) \cup R (b)) \forall f \in (L (c) \cup R (c)) θ \land \forall d \in (L (a) \cup R (a)) \forall e \in (L (b) \cup R (b)) χ \land \forall d \in (L (a) \cup R (a)) \forall f \in (L (c) \cup R (c)) ζ) \land (\forall d \in (L (a) \cup R (a)) ψ \land \forall e \in (L (b) \cup R (b)) \forall f \in (L (c) \cup R (c)) τ \land \forall e \in (L (b) \cup R (b)) σ) \land \forall f \in (L (c) \cup R (c)) η))$
37	36 11	sylbid	$⊢ (a \in No \land b \in No \land c \in No) \to (((\forall d \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) \forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) \forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) θ \land \forall d \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) \forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) χ \land \forall d \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) \forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) ζ) \land (\forall d \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, a) ψ \land \forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) \forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) τ \land \forall e \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, b) σ) \land \forall f \in Pred (\{⟨x, y⟩ \| x \in (L (y) \cup R (y))\}, No, c) η) \to φ)$
38	13 14 15 13 14 15 13 14 15 1 2 3 4 5 6 7 8 9 10 37	xpord3ind	$⊢ (X \in No \land Y \in No \land Z \in No) \to λ$

Metamath Proof Explorer

Theorem no3inds

Proof