hlimcaui

Description: If a sequence in Hilbert space subset converges to a limit, it is a Cauchy sequence. (Contributed by NM, 17-Aug-1999) (Proof shortened by Mario Carneiro, 14-May-2014) (New usage is discouraged.)

		Ref	Expression
	Assertion	hlimcaui	⊢ ( 𝐹 ⇝_𝑣 𝐴 → 𝐹 ∈ Cauchy )

Proof

Step	Hyp	Ref	Expression
1		eqid	⊢ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ = ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩
2		eqid	⊢ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) = ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ )
3		eqid	⊢ ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) = ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) )
4	1 2 3	hhlm	⊢ ⇝_𝑣 = ( ( ⇝_𝑡 ‘ ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) ) ↾ ( ℋ ↑_m ℕ ) )
5		resss	⊢ ( ( ⇝_𝑡 ‘ ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) ) ↾ ( ℋ ↑_m ℕ ) ) ⊆ ( ⇝_𝑡 ‘ ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) )
6	4 5	eqsstri	⊢ ⇝_𝑣 ⊆ ( ⇝_𝑡 ‘ ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) )
7		dmss	⊢ ( ⇝_𝑣 ⊆ ( ⇝_𝑡 ‘ ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) ) → dom ⇝_𝑣 ⊆ dom ( ⇝_𝑡 ‘ ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) ) )
8	6 7	ax-mp	⊢ dom ⇝_𝑣 ⊆ dom ( ⇝_𝑡 ‘ ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) )
9	1 2	hhxmet	⊢ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ∈ ( ∞Met ‘ ℋ )
10	3	lmcau	⊢ ( ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ∈ ( ∞Met ‘ ℋ ) → dom ( ⇝_𝑡 ‘ ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) ) ⊆ ( Cau ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) )
11	9 10	ax-mp	⊢ dom ( ⇝_𝑡 ‘ ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) ) ⊆ ( Cau ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) )
12	8 11	sstri	⊢ dom ⇝_𝑣 ⊆ ( Cau ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) )
13	4	dmeqi	⊢ dom ⇝_𝑣 = dom ( ( ⇝_𝑡 ‘ ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) ) ↾ ( ℋ ↑_m ℕ ) )
14		dmres	⊢ dom ( ( ⇝_𝑡 ‘ ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) ) ↾ ( ℋ ↑_m ℕ ) ) = ( ( ℋ ↑_m ℕ ) ∩ dom ( ⇝_𝑡 ‘ ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) ) )
15	13 14	eqtri	⊢ dom ⇝_𝑣 = ( ( ℋ ↑_m ℕ ) ∩ dom ( ⇝_𝑡 ‘ ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) ) )
16		inss1	⊢ ( ( ℋ ↑_m ℕ ) ∩ dom ( ⇝_𝑡 ‘ ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) ) ) ⊆ ( ℋ ↑_m ℕ )
17	15 16	eqsstri	⊢ dom ⇝_𝑣 ⊆ ( ℋ ↑_m ℕ )
18	12 17	ssini	⊢ dom ⇝_𝑣 ⊆ ( ( Cau ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) ∩ ( ℋ ↑_m ℕ ) )
19	1 2	hhcau	⊢ Cauchy = ( ( Cau ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) ∩ ( ℋ ↑_m ℕ ) )
20	18 19	sseqtrri	⊢ dom ⇝_𝑣 ⊆ Cauchy
21		relres	⊢ Rel ( ( ⇝_𝑡 ‘ ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) ) ↾ ( ℋ ↑_m ℕ ) )
22	4	releqi	⊢ ( Rel ⇝_𝑣 ↔ Rel ( ( ⇝_𝑡 ‘ ( MetOpen ‘ ( IndMet ‘ ⟨ ⟨ +_ℎ , ·_ℎ ⟩ , norm_ℎ ⟩ ) ) ) ↾ ( ℋ ↑_m ℕ ) ) )
23	21 22	mpbir	⊢ Rel ⇝_𝑣
24	23	releldmi	⊢ ( 𝐹 ⇝_𝑣 𝐴 → 𝐹 ∈ dom ⇝_𝑣 )
25	20 24	sselid	⊢ ( 𝐹 ⇝_𝑣 𝐴 → 𝐹 ∈ Cauchy )

Metamath Proof Explorer

Theorem hlimcaui

Proof