ocvval

Description: Value of the orthocomplement of a subset (normally a subspace) of a pre-Hilbert space. (Contributed by NM, 7-Oct-2011) (Revised by Mario Carneiro, 13-Oct-2015)

	Ref	Expression
Hypotheses	ocvfval.v	$⊢ V = {Base}_{W}$
	ocvfval.i	$⊢ \underset{˙}{,} = \cdot_{𝑖} (W)$
	ocvfval.f	$⊢ F = Scalar (W)$
	ocvfval.z	$⊢ \underset{˙}{0} = 0_{F}$
	ocvfval.o	$⊢ \underset{˙}{⊥} = ocv (W)$
Assertion	ocvval	$⊢ S \subseteq V \to \underset{˙}{⊥} (S) = \{x \in V \| \forall y \in S x \underset{˙}{,} y = \underset{˙}{0}\}$

Proof

Step	Hyp	Ref	Expression
1		ocvfval.v	$⊢ V = {Base}_{W}$
2		ocvfval.i	$⊢ \underset{˙}{,} = \cdot_{𝑖} (W)$
3		ocvfval.f	$⊢ F = Scalar (W)$
4		ocvfval.z	$⊢ \underset{˙}{0} = 0_{F}$
5		ocvfval.o	$⊢ \underset{˙}{⊥} = ocv (W)$
6	1	fvexi	$⊢ V \in V$
7	6	elpw2	$⊢ S \in 𝒫 V \leftrightarrow S \subseteq V$
8	1 2 3 4 5	ocvfval	$⊢ W \in V \to \underset{˙}{⊥} = (s \in 𝒫 V ⟼ \{x \in V \| \forall y \in s x \underset{˙}{,} y = \underset{˙}{0}\})$
9	8	fveq1d	$⊢ W \in V \to \underset{˙}{⊥} (S) = (s \in 𝒫 V ⟼ \{x \in V \| \forall y \in s x \underset{˙}{,} y = \underset{˙}{0}\}) (S)$
10		raleq	$⊢ s = S \to (\forall y \in s x \underset{˙}{,} y = \underset{˙}{0} \leftrightarrow \forall y \in S x \underset{˙}{,} y = \underset{˙}{0})$
11	10	rabbidv	$⊢ s = S \to \{x \in V \| \forall y \in s x \underset{˙}{,} y = \underset{˙}{0}\} = \{x \in V \| \forall y \in S x \underset{˙}{,} y = \underset{˙}{0}\}$
12		eqid	$⊢ (s \in 𝒫 V ⟼ \{x \in V \| \forall y \in s x \underset{˙}{,} y = \underset{˙}{0}\}) = (s \in 𝒫 V ⟼ \{x \in V \| \forall y \in s x \underset{˙}{,} y = \underset{˙}{0}\})$
13	6	rabex	$⊢ \{x \in V \| \forall y \in S x \underset{˙}{,} y = \underset{˙}{0}\} \in V$
14	11 12 13	fvmpt	$⊢ S \in 𝒫 V \to (s \in 𝒫 V ⟼ \{x \in V \| \forall y \in s x \underset{˙}{,} y = \underset{˙}{0}\}) (S) = \{x \in V \| \forall y \in S x \underset{˙}{,} y = \underset{˙}{0}\}$
15	9 14	sylan9eq	$⊢ (W \in V \land S \in 𝒫 V) \to \underset{˙}{⊥} (S) = \{x \in V \| \forall y \in S x \underset{˙}{,} y = \underset{˙}{0}\}$
16		0fv	$⊢ \emptyset (S) = \emptyset$
17		fvprc	$⊢ \neg W \in V \to ocv (W) = \emptyset$
18	5 17	eqtrid	$⊢ \neg W \in V \to \underset{˙}{⊥} = \emptyset$
19	18	fveq1d	$⊢ \neg W \in V \to \underset{˙}{⊥} (S) = \emptyset (S)$
20		ssrab2	$⊢ \{x \in V \| \forall y \in S x \underset{˙}{,} y = \underset{˙}{0}\} \subseteq V$
21		fvprc	$⊢ \neg W \in V \to {Base}_{W} = \emptyset$
22	1 21	eqtrid	$⊢ \neg W \in V \to V = \emptyset$
23		sseq0	$⊢ (\{x \in V \| \forall y \in S x \underset{˙}{,} y = \underset{˙}{0}\} \subseteq V \land V = \emptyset) \to \{x \in V \| \forall y \in S x \underset{˙}{,} y = \underset{˙}{0}\} = \emptyset$
24	20 22 23	sylancr	$⊢ \neg W \in V \to \{x \in V \| \forall y \in S x \underset{˙}{,} y = \underset{˙}{0}\} = \emptyset$
25	16 19 24	3eqtr4a	$⊢ \neg W \in V \to \underset{˙}{⊥} (S) = \{x \in V \| \forall y \in S x \underset{˙}{,} y = \underset{˙}{0}\}$
26	25	adantr	$⊢ (\neg W \in V \land S \in 𝒫 V) \to \underset{˙}{⊥} (S) = \{x \in V \| \forall y \in S x \underset{˙}{,} y = \underset{˙}{0}\}$
27	15 26	pm2.61ian	$⊢ S \in 𝒫 V \to \underset{˙}{⊥} (S) = \{x \in V \| \forall y \in S x \underset{˙}{,} y = \underset{˙}{0}\}$
28	7 27	sylbir	$⊢ S \subseteq V \to \underset{˙}{⊥} (S) = \{x \in V \| \forall y \in S x \underset{˙}{,} y = \underset{˙}{0}\}$

Metamath Proof Explorer

Theorem ocvval

Proof