nmopadjlem

Description: Lemma for nmopadji . (Contributed by NM, 22-Feb-2006) (New usage is discouraged.)

		Ref	Expression
	Hypothesis	nmopadjle.1	$⊢ T \in BndLinOp$
	Assertion	nmopadjlem	$⊢ {norm}_{op} ({adj}_{h} (T)) \leq {norm}_{op} (T)$

Proof

Step	Hyp	Ref	Expression
1		nmopadjle.1	$⊢ T \in BndLinOp$
2		adjbdln	$⊢ T \in BndLinOp \to {adj}_{h} (T) \in BndLinOp$
3		bdopf	$⊢ {adj}_{h} (T) \in BndLinOp \to {adj}_{h} (T) : ℋ ⟶ ℋ$
4	1 2 3	mp2b	$⊢ {adj}_{h} (T) : ℋ ⟶ ℋ$
5		bdopf	$⊢ T \in BndLinOp \to T : ℋ ⟶ ℋ$
6		nmopxr	$⊢ T : ℋ ⟶ ℋ \to {norm}_{op} (T) \in ℝ^{*}$
7	1 5 6	mp2b	$⊢ {norm}_{op} (T) \in ℝ^{*}$
8		nmopub	$⊢ ({adj}_{h} (T) : ℋ ⟶ ℋ \land {norm}_{op} (T) \in ℝ^{*}) \to ({norm}_{op} ({adj}_{h} (T)) \leq {norm}_{op} (T) \leftrightarrow \forall y \in ℋ ({norm}_{ℎ} (y) \leq 1 \to {norm}_{ℎ} ({adj}_{h} (T) (y)) \leq {norm}_{op} (T)))$
9	4 7 8	mp2an	$⊢ {norm}_{op} ({adj}_{h} (T)) \leq {norm}_{op} (T) \leftrightarrow \forall y \in ℋ ({norm}_{ℎ} (y) \leq 1 \to {norm}_{ℎ} ({adj}_{h} (T) (y)) \leq {norm}_{op} (T))$
10	4	ffvelrni	$⊢ y \in ℋ \to {adj}_{h} (T) (y) \in ℋ$
11		normcl	$⊢ {adj}_{h} (T) (y) \in ℋ \to {norm}_{ℎ} ({adj}_{h} (T) (y)) \in ℝ$
12	10 11	syl	$⊢ y \in ℋ \to {norm}_{ℎ} ({adj}_{h} (T) (y)) \in ℝ$
13	12	adantr	$⊢ (y \in ℋ \land {norm}_{ℎ} (y) \leq 1) \to {norm}_{ℎ} ({adj}_{h} (T) (y)) \in ℝ$
14		nmopre	$⊢ T \in BndLinOp \to {norm}_{op} (T) \in ℝ$
15	1 14	ax-mp	$⊢ {norm}_{op} (T) \in ℝ$
16		normcl	$⊢ y \in ℋ \to {norm}_{ℎ} (y) \in ℝ$
17		remulcl	$⊢ ({norm}_{op} (T) \in ℝ \land {norm}_{ℎ} (y) \in ℝ) \to {norm}_{op} (T) {norm}_{ℎ} (y) \in ℝ$
18	15 16 17	sylancr	$⊢ y \in ℋ \to {norm}_{op} (T) {norm}_{ℎ} (y) \in ℝ$
19	18	adantr	$⊢ (y \in ℋ \land {norm}_{ℎ} (y) \leq 1) \to {norm}_{op} (T) {norm}_{ℎ} (y) \in ℝ$
20		1re	$⊢ 1 \in ℝ$
21	15 20	remulcli	$⊢ {norm}_{op} (T) \cdot 1 \in ℝ$
22	21	a1i	$⊢ (y \in ℋ \land {norm}_{ℎ} (y) \leq 1) \to {norm}_{op} (T) \cdot 1 \in ℝ$
23	1	nmopadjlei	$⊢ y \in ℋ \to {norm}_{ℎ} ({adj}_{h} (T) (y)) \leq {norm}_{op} (T) {norm}_{ℎ} (y)$
24	23	adantr	$⊢ (y \in ℋ \land {norm}_{ℎ} (y) \leq 1) \to {norm}_{ℎ} ({adj}_{h} (T) (y)) \leq {norm}_{op} (T) {norm}_{ℎ} (y)$
25		nmopge0	$⊢ T : ℋ ⟶ ℋ \to 0 \leq {norm}_{op} (T)$
26	1 5 25	mp2b	$⊢ 0 \leq {norm}_{op} (T)$
27	15 26	pm3.2i	$⊢ ({norm}_{op} (T) \in ℝ \land 0 \leq {norm}_{op} (T))$
28		lemul2a	$⊢ (({norm}_{ℎ} (y) \in ℝ \land 1 \in ℝ \land ({norm}_{op} (T) \in ℝ \land 0 \leq {norm}_{op} (T))) \land {norm}_{ℎ} (y) \leq 1) \to {norm}_{op} (T) {norm}_{ℎ} (y) \leq {norm}_{op} (T) \cdot 1$
29	27 28	mp3anl3	$⊢ (({norm}_{ℎ} (y) \in ℝ \land 1 \in ℝ) \land {norm}_{ℎ} (y) \leq 1) \to {norm}_{op} (T) {norm}_{ℎ} (y) \leq {norm}_{op} (T) \cdot 1$
30	20 29	mpanl2	$⊢ ({norm}_{ℎ} (y) \in ℝ \land {norm}_{ℎ} (y) \leq 1) \to {norm}_{op} (T) {norm}_{ℎ} (y) \leq {norm}_{op} (T) \cdot 1$
31	16 30	sylan	$⊢ (y \in ℋ \land {norm}_{ℎ} (y) \leq 1) \to {norm}_{op} (T) {norm}_{ℎ} (y) \leq {norm}_{op} (T) \cdot 1$
32	13 19 22 24 31	letrd	$⊢ (y \in ℋ \land {norm}_{ℎ} (y) \leq 1) \to {norm}_{ℎ} ({adj}_{h} (T) (y)) \leq {norm}_{op} (T) \cdot 1$
33	15	recni	$⊢ {norm}_{op} (T) \in ℂ$
34	33	mulid1i	$⊢ {norm}_{op} (T) \cdot 1 = {norm}_{op} (T)$
35	32 34	breqtrdi	$⊢ (y \in ℋ \land {norm}_{ℎ} (y) \leq 1) \to {norm}_{ℎ} ({adj}_{h} (T) (y)) \leq {norm}_{op} (T)$
36	35	ex	$⊢ y \in ℋ \to ({norm}_{ℎ} (y) \leq 1 \to {norm}_{ℎ} ({adj}_{h} (T) (y)) \leq {norm}_{op} (T))$
37	9 36	mprgbir	$⊢ {norm}_{op} ({adj}_{h} (T)) \leq {norm}_{op} (T)$

Metamath Proof Explorer

Theorem nmopadjlem

Proof