Metamath Proof Explorer

Theorem ajfun

Description: The adjoint function is a function. This is not immediately apparent from df-aj but results from the uniqueness shown by ajmoi . (Contributed by NM, 26-Jan-2008) (New usage is discouraged.)

		Ref	Expression
	Hypothesis	ajfun.5	$⊢ A = U adj W$
	Assertion	ajfun	$⊢ (U \in {CPreHil}_{OLD} \land W \in NrmCVec) \to Fun A$

Proof

Step	Hyp	Ref	Expression
1		ajfun.5	$⊢ A = U adj W$
2		oveq1	$⊢ U = if (U \in {CPreHil}_{OLD}, U, ⟨⟨+ \times⟩, abs⟩) \to U adj W = if (U \in {CPreHil}_{OLD}, U, ⟨⟨+ \times⟩, abs⟩) adj W$
3	1 2	syl5eq	$⊢ U = if (U \in {CPreHil}_{OLD}, U, ⟨⟨+ \times⟩, abs⟩) \to A = if (U \in {CPreHil}_{OLD}, U, ⟨⟨+ \times⟩, abs⟩) adj W$
4	3	funeqd	$⊢ U = if (U \in {CPreHil}_{OLD}, U, ⟨⟨+ \times⟩, abs⟩) \to (Fun A \leftrightarrow Fun (if (U \in {CPreHil}_{OLD}, U, ⟨⟨+ \times⟩, abs⟩) adj W))$
5		oveq2	$⊢ W = if (W \in NrmCVec, W, ⟨⟨+ \times⟩, abs⟩) \to if (U \in {CPreHil}_{OLD}, U, ⟨⟨+ \times⟩, abs⟩) adj W = if (U \in {CPreHil}_{OLD}, U, ⟨⟨+ \times⟩, abs⟩) adj if (W \in NrmCVec, W, ⟨⟨+ \times⟩, abs⟩)$
6	5	funeqd	$⊢ W = if (W \in NrmCVec, W, ⟨⟨+ \times⟩, abs⟩) \to (Fun (if (U \in {CPreHil}_{OLD}, U, ⟨⟨+ \times⟩, abs⟩) adj W) \leftrightarrow Fun (if (U \in {CPreHil}_{OLD}, U, ⟨⟨+ \times⟩, abs⟩) adj if (W \in NrmCVec, W, ⟨⟨+ \times⟩, abs⟩)))$
7		eqid	$⊢ if (U \in {CPreHil}_{OLD}, U, ⟨⟨+ \times⟩, abs⟩) adj if (W \in NrmCVec, W, ⟨⟨+ \times⟩, abs⟩) = if (U \in {CPreHil}_{OLD}, U, ⟨⟨+ \times⟩, abs⟩) adj if (W \in NrmCVec, W, ⟨⟨+ \times⟩, abs⟩)$
8		elimphu	$⊢ if (U \in {CPreHil}_{OLD}, U, ⟨⟨+ \times⟩, abs⟩) \in {CPreHil}_{OLD}$
9		elimnvu	$⊢ if (W \in NrmCVec, W, ⟨⟨+ \times⟩, abs⟩) \in NrmCVec$
10	7 8 9	ajfuni	$⊢ Fun (if (U \in {CPreHil}_{OLD}, U, ⟨⟨+ \times⟩, abs⟩) adj if (W \in NrmCVec, W, ⟨⟨+ \times⟩, abs⟩))$
11	4 6 10	dedth2h	$⊢ (U \in {CPreHil}_{OLD} \land W \in NrmCVec) \to Fun A$