pjdifnormii

Description: Theorem 4.5(v)<->(vi) of Beran p. 112. (Contributed by NM, 13-Aug-2000) (New usage is discouraged.)

	Ref	Expression
Hypotheses	pjidm.1	$⊢ H \in C_{ℋ}$
	pjidm.2	$⊢ A \in ℋ$
	pjsslem.1	$⊢ G \in C_{ℋ}$
Assertion	pjdifnormii	$⊢ 0 \leq ({proj}_{ℎ} (G) (A) -_{ℎ} {proj}_{ℎ} (H) (A)) \cdot_{ih} A \leftrightarrow {norm}_{ℎ} ({proj}_{ℎ} (H) (A)) \leq {norm}_{ℎ} ({proj}_{ℎ} (G) (A))$

Proof

Step	Hyp	Ref	Expression
1		pjidm.1	$⊢ H \in C_{ℋ}$
2		pjidm.2	$⊢ A \in ℋ$
3		pjsslem.1	$⊢ G \in C_{ℋ}$
4	3 2	pjhclii	$⊢ {proj}_{ℎ} (G) (A) \in ℋ$
5	4	normcli	$⊢ {norm}_{ℎ} ({proj}_{ℎ} (G) (A)) \in ℝ$
6	5	resqcli	$⊢ {{norm}_{ℎ} ({proj}_{ℎ} (G) (A))}^{2} \in ℝ$
7	1 2	pjhclii	$⊢ {proj}_{ℎ} (H) (A) \in ℋ$
8	7	normcli	$⊢ {norm}_{ℎ} ({proj}_{ℎ} (H) (A)) \in ℝ$
9	8	resqcli	$⊢ {{norm}_{ℎ} ({proj}_{ℎ} (H) (A))}^{2} \in ℝ$
10	6 9	subge0i	$⊢ 0 \leq {{norm}_{ℎ} ({proj}_{ℎ} (G) (A))}^{2} - {{norm}_{ℎ} ({proj}_{ℎ} (H) (A))}^{2} \leftrightarrow {{norm}_{ℎ} ({proj}_{ℎ} (H) (A))}^{2} \leq {{norm}_{ℎ} ({proj}_{ℎ} (G) (A))}^{2}$
11		his2sub	$⊢ ({proj}_{ℎ} (G) (A) \in ℋ \land {proj}_{ℎ} (H) (A) \in ℋ \land A \in ℋ) \to ({proj}_{ℎ} (G) (A) -_{ℎ} {proj}_{ℎ} (H) (A)) \cdot_{ih} A = ({proj}_{ℎ} (G) (A) \cdot_{ih} A) - ({proj}_{ℎ} (H) (A) \cdot_{ih} A)$
12	4 7 2 11	mp3an	$⊢ ({proj}_{ℎ} (G) (A) -_{ℎ} {proj}_{ℎ} (H) (A)) \cdot_{ih} A = ({proj}_{ℎ} (G) (A) \cdot_{ih} A) - ({proj}_{ℎ} (H) (A) \cdot_{ih} A)$
13	3 2	pjinormii	$⊢ {proj}_{ℎ} (G) (A) \cdot_{ih} A = {{norm}_{ℎ} ({proj}_{ℎ} (G) (A))}^{2}$
14	1 2	pjinormii	$⊢ {proj}_{ℎ} (H) (A) \cdot_{ih} A = {{norm}_{ℎ} ({proj}_{ℎ} (H) (A))}^{2}$
15	13 14	oveq12i	$⊢ ({proj}_{ℎ} (G) (A) \cdot_{ih} A) - ({proj}_{ℎ} (H) (A) \cdot_{ih} A) = {{norm}_{ℎ} ({proj}_{ℎ} (G) (A))}^{2} - {{norm}_{ℎ} ({proj}_{ℎ} (H) (A))}^{2}$
16	12 15	eqtri	$⊢ ({proj}_{ℎ} (G) (A) -_{ℎ} {proj}_{ℎ} (H) (A)) \cdot_{ih} A = {{norm}_{ℎ} ({proj}_{ℎ} (G) (A))}^{2} - {{norm}_{ℎ} ({proj}_{ℎ} (H) (A))}^{2}$
17	16	breq2i	$⊢ 0 \leq ({proj}_{ℎ} (G) (A) -_{ℎ} {proj}_{ℎ} (H) (A)) \cdot_{ih} A \leftrightarrow 0 \leq {{norm}_{ℎ} ({proj}_{ℎ} (G) (A))}^{2} - {{norm}_{ℎ} ({proj}_{ℎ} (H) (A))}^{2}$
18		normge0	$⊢ {proj}_{ℎ} (H) (A) \in ℋ \to 0 \leq {norm}_{ℎ} ({proj}_{ℎ} (H) (A))$
19	7 18	ax-mp	$⊢ 0 \leq {norm}_{ℎ} ({proj}_{ℎ} (H) (A))$
20		normge0	$⊢ {proj}_{ℎ} (G) (A) \in ℋ \to 0 \leq {norm}_{ℎ} ({proj}_{ℎ} (G) (A))$
21	4 20	ax-mp	$⊢ 0 \leq {norm}_{ℎ} ({proj}_{ℎ} (G) (A))$
22	8 5	le2sqi	$⊢ (0 \leq {norm}_{ℎ} ({proj}_{ℎ} (H) (A)) \land 0 \leq {norm}_{ℎ} ({proj}_{ℎ} (G) (A))) \to ({norm}_{ℎ} ({proj}_{ℎ} (H) (A)) \leq {norm}_{ℎ} ({proj}_{ℎ} (G) (A)) \leftrightarrow {{norm}_{ℎ} ({proj}_{ℎ} (H) (A))}^{2} \leq {{norm}_{ℎ} ({proj}_{ℎ} (G) (A))}^{2})$
23	19 21 22	mp2an	$⊢ {norm}_{ℎ} ({proj}_{ℎ} (H) (A)) \leq {norm}_{ℎ} ({proj}_{ℎ} (G) (A)) \leftrightarrow {{norm}_{ℎ} ({proj}_{ℎ} (H) (A))}^{2} \leq {{norm}_{ℎ} ({proj}_{ℎ} (G) (A))}^{2}$
24	10 17 23	3bitr4i	$⊢ 0 \leq ({proj}_{ℎ} (G) (A) -_{ℎ} {proj}_{ℎ} (H) (A)) \cdot_{ih} A \leftrightarrow {norm}_{ℎ} ({proj}_{ℎ} (H) (A)) \leq {norm}_{ℎ} ({proj}_{ℎ} (G) (A))$

Metamath Proof Explorer

Theorem pjdifnormii

Proof