tfrlem10

Description: Lemma for transfinite recursion. We define class C by extending recs with one ordered pair. We will assume, falsely, that domain of recs is a member of, and thus not equal to, On . Using this assumption we will prove facts about C that will lead to a contradiction in tfrlem14 , thus showing the domain of recs does in fact equal On . Here we show (under the false assumption) that C is a function extending the domain of recs ( F ) by one. (Contributed by NM, 14-Aug-1994) (Revised by Mario Carneiro, 9-May-2015)

	Ref	Expression
Hypotheses	tfrlem.1	$⊢ A = \{f \| \exists x \in On (f Fn x \land \forall y \in x f (y) = F ({f ↾}_{y}))\}$
	tfrlem.3	$⊢ C = recs (F) \cup \{⟨dom recs (F), F (recs (F))⟩\}$
Assertion	tfrlem10	$⊢ dom recs (F) \in On \to C Fn suc dom recs (F)$

Proof

Step	Hyp	Ref	Expression
1		tfrlem.1	$⊢ A = \{f \| \exists x \in On (f Fn x \land \forall y \in x f (y) = F ({f ↾}_{y}))\}$
2		tfrlem.3	$⊢ C = recs (F) \cup \{⟨dom recs (F), F (recs (F))⟩\}$
3		fvex	$⊢ F (recs (F)) \in V$
4		funsng	$⊢ (dom recs (F) \in On \land F (recs (F)) \in V) \to Fun \{⟨dom recs (F), F (recs (F))⟩\}$
5	3 4	mpan2	$⊢ dom recs (F) \in On \to Fun \{⟨dom recs (F), F (recs (F))⟩\}$
6	1	tfrlem7	$⊢ Fun recs (F)$
7	5 6	jctil	$⊢ dom recs (F) \in On \to (Fun recs (F) \land Fun \{⟨dom recs (F), F (recs (F))⟩\})$
8	3	dmsnop	$⊢ dom \{⟨dom recs (F), F (recs (F))⟩\} = \{dom recs (F)\}$
9	8	ineq2i	$⊢ dom recs (F) \cap dom \{⟨dom recs (F), F (recs (F))⟩\} = dom recs (F) \cap \{dom recs (F)\}$
10	1	tfrlem8	$⊢ Ord dom recs (F)$
11		orddisj	$⊢ Ord dom recs (F) \to dom recs (F) \cap \{dom recs (F)\} = \emptyset$
12	10 11	ax-mp	$⊢ dom recs (F) \cap \{dom recs (F)\} = \emptyset$
13	9 12	eqtri	$⊢ dom recs (F) \cap dom \{⟨dom recs (F), F (recs (F))⟩\} = \emptyset$
14		funun	$⊢ ((Fun recs (F) \land Fun \{⟨dom recs (F), F (recs (F))⟩\}) \land dom recs (F) \cap dom \{⟨dom recs (F), F (recs (F))⟩\} = \emptyset) \to Fun (recs (F) \cup \{⟨dom recs (F), F (recs (F))⟩\})$
15	7 13 14	sylancl	$⊢ dom recs (F) \in On \to Fun (recs (F) \cup \{⟨dom recs (F), F (recs (F))⟩\})$
16	8	uneq2i	$⊢ dom recs (F) \cup dom \{⟨dom recs (F), F (recs (F))⟩\} = dom recs (F) \cup \{dom recs (F)\}$
17		dmun	$⊢ dom (recs (F) \cup \{⟨dom recs (F), F (recs (F))⟩\}) = dom recs (F) \cup dom \{⟨dom recs (F), F (recs (F))⟩\}$
18		df-suc	$⊢ suc dom recs (F) = dom recs (F) \cup \{dom recs (F)\}$
19	16 17 18	3eqtr4i	$⊢ dom (recs (F) \cup \{⟨dom recs (F), F (recs (F))⟩\}) = suc dom recs (F)$
20		df-fn	$⊢ (recs (F) \cup \{⟨dom recs (F), F (recs (F))⟩\}) Fn suc dom recs (F) \leftrightarrow (Fun (recs (F) \cup \{⟨dom recs (F), F (recs (F))⟩\}) \land dom (recs (F) \cup \{⟨dom recs (F), F (recs (F))⟩\}) = suc dom recs (F))$
21	15 19 20	sylanblrc	$⊢ dom recs (F) \in On \to (recs (F) \cup \{⟨dom recs (F), F (recs (F))⟩\}) Fn suc dom recs (F)$
22	2	fneq1i	$⊢ C Fn suc dom recs (F) \leftrightarrow (recs (F) \cup \{⟨dom recs (F), F (recs (F))⟩\}) Fn suc dom recs (F)$
23	21 22	sylibr	$⊢ dom recs (F) \in On \to C Fn suc dom recs (F)$

Metamath Proof Explorer

Theorem tfrlem10

Proof