topdifinf

Description: Part of Exercise 3 of Munkres p. 83. The topology of all subsets x of A such that the complement of x in A is infinite, or x is the empty set, or x is all of A , is a topology if and only if A is finite, in which case it is the trivial topology. (Contributed by ML, 17-Jul-2020)

		Ref	Expression
	Hypothesis	topdifinf.t	$⊢ T = \{x \in 𝒫 A \| (\neg A ∖ x \in Fin \lor (x = \emptyset \lor x = A))\}$
	Assertion	topdifinf	$⊢ ((T \in TopOn (A) \leftrightarrow A \in Fin) \land (T \in TopOn (A) \to T = \{\emptyset, A\}))$

Proof

Step	Hyp	Ref	Expression
1		topdifinf.t	$⊢ T = \{x \in 𝒫 A \| (\neg A ∖ x \in Fin \lor (x = \emptyset \lor x = A))\}$
2	1	topdifinffin	$⊢ T \in TopOn (A) \to A \in Fin$
3	1	topdifinfindis	$⊢ A \in Fin \to T = \{\emptyset, A\}$
4		indistopon	$⊢ A \in Fin \to \{\emptyset, A\} \in TopOn (A)$
5	3 4	eqeltrd	$⊢ A \in Fin \to T \in TopOn (A)$
6	2 5	impbii	$⊢ T \in TopOn (A) \leftrightarrow A \in Fin$
7	2 3	syl	$⊢ T \in TopOn (A) \to T = \{\emptyset, A\}$
8	6 7	pm3.2i	$⊢ ((T \in TopOn (A) \leftrightarrow A \in Fin) \land (T \in TopOn (A) \to T = \{\emptyset, A\}))$

Metamath Proof Explorer

Theorem topdifinf

Proof