cnfcom3c

Description: Wrap the construction of cnfcom3 into an existential quantifier. For any _om C_ b , there is a bijection from b to some power of _om . Furthermore, this bijection iscanonical , which means that we can find a single function g which will give such bijections for every b less than some arbitrarily large bound A . (Contributed by Mario Carneiro, 30-May-2015)

		Ref	Expression
	Assertion	cnfcom3c	$⊢ A \in On \to \exists g \forall b \in A (ω \subseteq b \to \exists w \in (On ∖ 1_{𝑜}) g (b) : b \underset{1-1 onto}{⟶} ω ↑_{𝑜} w)$

Proof

Step	Hyp	Ref	Expression
1		eqid	$⊢ dom (ω CNF A) = dom (ω CNF A)$
2		eqid	$⊢ {(ω CNF A)}^{-1} (b) = {(ω CNF A)}^{-1} (b)$
3		eqid	$⊢ OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) = OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset)$
4		eqid	$⊢ {seq}_{ω} ((k \in V, z \in V ⟼ ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) +_{𝑜} z), \emptyset) = {seq}_{ω} ((k \in V, z \in V ⟼ ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) +_{𝑜} z), \emptyset)$
5		eqid	$⊢ {seq}_{ω} ((k \in V, f \in V ⟼ (x \in ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) ⟼ dom f +_{𝑜} x) \cup {(x \in dom f ⟼ ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) +_{𝑜} x)}^{-1}), \emptyset) = {seq}_{ω} ((k \in V, f \in V ⟼ (x \in ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) ⟼ dom f +_{𝑜} x) \cup {(x \in dom f ⟼ ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) +_{𝑜} x)}^{-1}), \emptyset)$
6		eqid	$⊢ (ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) = (ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))$
7		eqid	$⊢ (x \in ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) ⟼ dom f +_{𝑜} x) \cup {(x \in dom f ⟼ ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) +_{𝑜} x)}^{-1} = (x \in ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) ⟼ dom f +_{𝑜} x) \cup {(x \in dom f ⟼ ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) +_{𝑜} x)}^{-1}$
8		eqid	$⊢ OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset)) = OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))$
9		eqid	$⊢ (u \in {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))), v \in (ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) ⟼ ({(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) \cdot_{𝑜} v) +_{𝑜} u) = (u \in {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))), v \in (ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) ⟼ ({(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) \cdot_{𝑜} v) +_{𝑜} u)$
10		eqid	$⊢ (u \in {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))), v \in (ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) ⟼ ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) \cdot_{𝑜} u) +_{𝑜} v) = (u \in {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))), v \in (ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) ⟼ ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) \cdot_{𝑜} u) +_{𝑜} v)$
11		eqid	$⊢ ((u \in {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))), v \in (ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) ⟼ ({(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) \cdot_{𝑜} v) +_{𝑜} u) \circ {(u \in {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))), v \in (ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) ⟼ ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) \cdot_{𝑜} u) +_{𝑜} v)}^{-1}) \circ {seq}_{ω} ((k \in V, f \in V ⟼ (x \in ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) ⟼ dom f +_{𝑜} x) \cup {(x \in dom f ⟼ ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) +_{𝑜} x)}^{-1}), \emptyset) (dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset)) = ((u \in {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))), v \in (ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) ⟼ ({(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) \cdot_{𝑜} v) +_{𝑜} u) \circ {(u \in {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))), v \in (ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) ⟼ ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) \cdot_{𝑜} u) +_{𝑜} v)}^{-1}) \circ {seq}_{ω} ((k \in V, f \in V ⟼ (x \in ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) ⟼ dom f +_{𝑜} x) \cup {(x \in dom f ⟼ ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) +_{𝑜} x)}^{-1}), \emptyset) (dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))$
12		eqid	$⊢ (b \in (ω ↑_{𝑜} A) ⟼ ((u \in {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))), v \in (ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) ⟼ ({(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) \cdot_{𝑜} v) +_{𝑜} u) \circ {(u \in {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))), v \in (ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) ⟼ ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) \cdot_{𝑜} u) +_{𝑜} v)}^{-1}) \circ {seq}_{ω} ((k \in V, f \in V ⟼ (x \in ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) ⟼ dom f +_{𝑜} x) \cup {(x \in dom f ⟼ ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) +_{𝑜} x)}^{-1}), \emptyset) (dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) = (b \in (ω ↑_{𝑜} A) ⟼ ((u \in {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))), v \in (ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) ⟼ ({(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) \cdot_{𝑜} v) +_{𝑜} u) \circ {(u \in {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))), v \in (ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) ⟼ ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (⋃ dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset))) \cdot_{𝑜} u) +_{𝑜} v)}^{-1}) \circ {seq}_{ω} ((k \in V, f \in V ⟼ (x \in ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) ⟼ dom f +_{𝑜} x) \cup {(x \in dom f ⟼ ((ω ↑_{𝑜} OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k)) \cdot_{𝑜} {(ω CNF A)}^{-1} (b) (OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset) (k))) +_{𝑜} x)}^{-1}), \emptyset) (dom OrdIso (E, {(ω CNF A)}^{-1} (b) supp \emptyset)))$
13	1 2 3 4 5 6 7 8 9 10 11 12	cnfcom3clem	$⊢ A \in On \to \exists g \forall b \in A (ω \subseteq b \to \exists w \in (On ∖ 1_{𝑜}) g (b) : b \underset{1-1 onto}{⟶} ω ↑_{𝑜} w)$

Metamath Proof Explorer

Theorem cnfcom3c

Proof