Metamath Proof Explorer

Theorem nmoprepnf

Description: The norm of a Hilbert space operator is either real or plus infinity. (Contributed by NM, 5-Feb-2006) (New usage is discouraged.)

		Ref	Expression
	Assertion	nmoprepnf	$⊢ T : ℋ ⟶ ℋ \to ({norm}_{op} (T) \in ℝ \leftrightarrow {norm}_{op} (T) \neq +∞)$

Proof

Step	Hyp	Ref	Expression
1		nmopsetretHIL	$⊢ T : ℋ ⟶ ℋ \to \{x \| \exists y \in ℋ ({norm}_{ℎ} (y) \leq 1 \land x = {norm}_{ℎ} (T (y)))\} \subseteq ℝ$
2		nmopsetn0	$⊢ {norm}_{ℎ} (T (0_{ℎ})) \in \{x \| \exists y \in ℋ ({norm}_{ℎ} (y) \leq 1 \land x = {norm}_{ℎ} (T (y)))\}$
3	2	ne0ii	$⊢ \{x \| \exists y \in ℋ ({norm}_{ℎ} (y) \leq 1 \land x = {norm}_{ℎ} (T (y)))\} \neq \emptyset$
4		supxrre2	$⊢ (\{x \| \exists y \in ℋ ({norm}_{ℎ} (y) \leq 1 \land x = {norm}_{ℎ} (T (y)))\} \subseteq ℝ \land \{x \| \exists y \in ℋ ({norm}_{ℎ} (y) \leq 1 \land x = {norm}_{ℎ} (T (y)))\} \neq \emptyset) \to (sup (\{x \| \exists y \in ℋ ({norm}_{ℎ} (y) \leq 1 \land x = {norm}_{ℎ} (T (y)))\} ℝ^{} <) \in ℝ \leftrightarrow sup (\{x \| \exists y \in ℋ ({norm}_{ℎ} (y) \leq 1 \land x = {norm}_{ℎ} (T (y)))\} ℝ^{} <) \neq +∞)$
5	1 3 4	sylancl	$⊢ T : ℋ ⟶ ℋ \to (sup (\{x \| \exists y \in ℋ ({norm}_{ℎ} (y) \leq 1 \land x = {norm}_{ℎ} (T (y)))\} ℝ^{} <) \in ℝ \leftrightarrow sup (\{x \| \exists y \in ℋ ({norm}_{ℎ} (y) \leq 1 \land x = {norm}_{ℎ} (T (y)))\} ℝ^{} <) \neq +∞)$
6		nmopval	$⊢ T : ℋ ⟶ ℋ \to {norm}_{op} (T) = sup (\{x \| \exists y \in ℋ ({norm}_{ℎ} (y) \leq 1 \land x = {norm}_{ℎ} (T (y)))\} ℝ^{*} <)$
7	6	eleq1d	$⊢ T : ℋ ⟶ ℋ \to ({norm}_{op} (T) \in ℝ \leftrightarrow sup (\{x \| \exists y \in ℋ ({norm}_{ℎ} (y) \leq 1 \land x = {norm}_{ℎ} (T (y)))\} ℝ^{*} <) \in ℝ)$
8	6	neeq1d	$⊢ T : ℋ ⟶ ℋ \to ({norm}_{op} (T) \neq +∞ \leftrightarrow sup (\{x \| \exists y \in ℋ ({norm}_{ℎ} (y) \leq 1 \land x = {norm}_{ℎ} (T (y)))\} ℝ^{*} <) \neq +∞)$
9	5 7 8	3bitr4d	$⊢ T : ℋ ⟶ ℋ \to ({norm}_{op} (T) \in ℝ \leftrightarrow {norm}_{op} (T) \neq +∞)$