adjbdlnb

Description: An operator is bounded and linear iff its adjoint is. (Contributed by NM, 19-Feb-2006) (New usage is discouraged.)

		Ref	Expression
	Assertion	adjbdlnb	$⊢ T \in BndLinOp \leftrightarrow {adj}_{h} (T) \in BndLinOp$

Step	Hyp	Ref	Expression
1		adjbdln	$⊢ T \in BndLinOp \to {adj}_{h} (T) \in BndLinOp$
2		bdopadj	$⊢ {adj}_{h} (T) \in BndLinOp \to {adj}_{h} (T) \in dom {adj}_{h}$
3		dmadjrnb	$⊢ T \in dom {adj}_{h} \leftrightarrow {adj}_{h} (T) \in dom {adj}_{h}$
4	2 3	sylibr	$⊢ {adj}_{h} (T) \in BndLinOp \to T \in dom {adj}_{h}$
5		cnvadj	$⊢ {adj}_{h}^{-1} = {adj}_{h}$
6	5	fveq1i	$⊢ {adj}_{h}^{-1} ({adj}_{h} (T)) = {adj}_{h} ({adj}_{h} (T))$
7		adj1o	$⊢ {adj}_{h} : dom {adj}_{h} \underset{1-1 onto}{⟶} dom {adj}_{h}$
8		simpl	$⊢ (T \in dom {adj}_{h} \land {adj}_{h} (T) \in BndLinOp) \to T \in dom {adj}_{h}$
9		f1ocnvfv1	$⊢ ({adj}_{h} : dom {adj}_{h} \underset{1-1 onto}{⟶} dom {adj}_{h} \land T \in dom {adj}_{h}) \to {adj}_{h}^{-1} ({adj}_{h} (T)) = T$
10	7 8 9	sylancr	$⊢ (T \in dom {adj}_{h} \land {adj}_{h} (T) \in BndLinOp) \to {adj}_{h}^{-1} ({adj}_{h} (T)) = T$
11	6 10	eqtr3id	$⊢ (T \in dom {adj}_{h} \land {adj}_{h} (T) \in BndLinOp) \to {adj}_{h} ({adj}_{h} (T)) = T$
12		adjbdln	$⊢ {adj}_{h} (T) \in BndLinOp \to {adj}_{h} ({adj}_{h} (T)) \in BndLinOp$
13	12	adantl	$⊢ (T \in dom {adj}_{h} \land {adj}_{h} (T) \in BndLinOp) \to {adj}_{h} ({adj}_{h} (T)) \in BndLinOp$
14	11 13	eqeltrrd	$⊢ (T \in dom {adj}_{h} \land {adj}_{h} (T) \in BndLinOp) \to T \in BndLinOp$
15	4 14	mpancom	$⊢ {adj}_{h} (T) \in BndLinOp \to T \in BndLinOp$
16	1 15	impbii	$⊢ T \in BndLinOp \leftrightarrow {adj}_{h} (T) \in BndLinOp$

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