kbass2

Description: Dirac bra-ket associative law ( <. A | B >. ) <. C | = <. A | ( | B >. <. C | ) , i.e., the juxtaposition of an inner product with a bra equals a ket juxtaposed with an outer product. (Contributed by NM, 23-May-2006) (New usage is discouraged.)

		Ref	Expression
	Assertion	kbass2	$⊢ (A \in ℋ \land B \in ℋ \land C \in ℋ) \to bra (A) (B) \cdot_{fn} bra (C) = bra (A) \circ (B ketbra C)$

Proof

Step	Hyp	Ref	Expression
1		ovex	$⊢ bra (A) (B) bra (C) (x) \in V$
2		eqid	$⊢ (x \in ℋ ⟼ bra (A) (B) bra (C) (x)) = (x \in ℋ ⟼ bra (A) (B) bra (C) (x))$
3	1 2	fnmpti	$⊢ (x \in ℋ ⟼ bra (A) (B) bra (C) (x)) Fn ℋ$
4		bracl	$⊢ (A \in ℋ \land B \in ℋ) \to bra (A) (B) \in ℂ$
5		brafn	$⊢ C \in ℋ \to bra (C) : ℋ ⟶ ℂ$
6		hfmmval	$⊢ (bra (A) (B) \in ℂ \land bra (C) : ℋ ⟶ ℂ) \to bra (A) (B) \cdot_{fn} bra (C) = (x \in ℋ ⟼ bra (A) (B) bra (C) (x))$
7	4 5 6	syl2an	$⊢ ((A \in ℋ \land B \in ℋ) \land C \in ℋ) \to bra (A) (B) \cdot_{fn} bra (C) = (x \in ℋ ⟼ bra (A) (B) bra (C) (x))$
8	7	3impa	$⊢ (A \in ℋ \land B \in ℋ \land C \in ℋ) \to bra (A) (B) \cdot_{fn} bra (C) = (x \in ℋ ⟼ bra (A) (B) bra (C) (x))$
9	8	fneq1d	$⊢ (A \in ℋ \land B \in ℋ \land C \in ℋ) \to ((bra (A) (B) \cdot_{fn} bra (C)) Fn ℋ \leftrightarrow (x \in ℋ ⟼ bra (A) (B) bra (C) (x)) Fn ℋ)$
10	3 9	mpbiri	$⊢ (A \in ℋ \land B \in ℋ \land C \in ℋ) \to (bra (A) (B) \cdot_{fn} bra (C)) Fn ℋ$
11		brafn	$⊢ A \in ℋ \to bra (A) : ℋ ⟶ ℂ$
12		kbop	$⊢ (B \in ℋ \land C \in ℋ) \to (B ketbra C) : ℋ ⟶ ℋ$
13		fco	$⊢ (bra (A) : ℋ ⟶ ℂ \land (B ketbra C) : ℋ ⟶ ℋ) \to (bra (A) \circ (B ketbra C)) : ℋ ⟶ ℂ$
14	11 12 13	syl2an	$⊢ (A \in ℋ \land (B \in ℋ \land C \in ℋ)) \to (bra (A) \circ (B ketbra C)) : ℋ ⟶ ℂ$
15	14	3impb	$⊢ (A \in ℋ \land B \in ℋ \land C \in ℋ) \to (bra (A) \circ (B ketbra C)) : ℋ ⟶ ℂ$
16	15	ffnd	$⊢ (A \in ℋ \land B \in ℋ \land C \in ℋ) \to (bra (A) \circ (B ketbra C)) Fn ℋ$
17		simpl1	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to A \in ℋ$
18		simpl2	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to B \in ℋ$
19		braval	$⊢ (A \in ℋ \land B \in ℋ) \to bra (A) (B) = B \cdot_{ih} A$
20	17 18 19	syl2anc	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to bra (A) (B) = B \cdot_{ih} A$
21		simpl3	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to C \in ℋ$
22		simpr	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to x \in ℋ$
23		braval	$⊢ (C \in ℋ \land x \in ℋ) \to bra (C) (x) = x \cdot_{ih} C$
24	21 22 23	syl2anc	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to bra (C) (x) = x \cdot_{ih} C$
25	20 24	oveq12d	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to bra (A) (B) bra (C) (x) = (B \cdot_{ih} A) (x \cdot_{ih} C)$
26		hicl	$⊢ (B \in ℋ \land A \in ℋ) \to B \cdot_{ih} A \in ℂ$
27	18 17 26	syl2anc	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to B \cdot_{ih} A \in ℂ$
28	20 27	eqeltrd	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to bra (A) (B) \in ℂ$
29	21 5	syl	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to bra (C) : ℋ ⟶ ℂ$
30		hfmval	$⊢ (bra (A) (B) \in ℂ \land bra (C) : ℋ ⟶ ℂ \land x \in ℋ) \to (bra (A) (B) \cdot_{fn} bra (C)) (x) = bra (A) (B) bra (C) (x)$
31	28 29 22 30	syl3anc	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to (bra (A) (B) \cdot_{fn} bra (C)) (x) = bra (A) (B) bra (C) (x)$
32		hicl	$⊢ (x \in ℋ \land C \in ℋ) \to x \cdot_{ih} C \in ℂ$
33	22 21 32	syl2anc	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to x \cdot_{ih} C \in ℂ$
34		ax-his3	$⊢ (x \cdot_{ih} C \in ℂ \land B \in ℋ \land A \in ℋ) \to ((x \cdot_{ih} C) \cdot_{ℎ} B) \cdot_{ih} A = (x \cdot_{ih} C) (B \cdot_{ih} A)$
35	33 18 17 34	syl3anc	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to ((x \cdot_{ih} C) \cdot_{ℎ} B) \cdot_{ih} A = (x \cdot_{ih} C) (B \cdot_{ih} A)$
36	12	3adant1	$⊢ (A \in ℋ \land B \in ℋ \land C \in ℋ) \to (B ketbra C) : ℋ ⟶ ℋ$
37		fvco3	$⊢ ((B ketbra C) : ℋ ⟶ ℋ \land x \in ℋ) \to (bra (A) \circ (B ketbra C)) (x) = bra (A) ((B ketbra C) (x))$
38	36 37	sylan	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to (bra (A) \circ (B ketbra C)) (x) = bra (A) ((B ketbra C) (x))$
39		kbval	$⊢ (B \in ℋ \land C \in ℋ \land x \in ℋ) \to (B ketbra C) (x) = (x \cdot_{ih} C) \cdot_{ℎ} B$
40	18 21 22 39	syl3anc	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to (B ketbra C) (x) = (x \cdot_{ih} C) \cdot_{ℎ} B$
41	40	fveq2d	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to bra (A) ((B ketbra C) (x)) = bra (A) ((x \cdot_{ih} C) \cdot_{ℎ} B)$
42		hvmulcl	$⊢ (x \cdot_{ih} C \in ℂ \land B \in ℋ) \to (x \cdot_{ih} C) \cdot_{ℎ} B \in ℋ$
43	33 18 42	syl2anc	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to (x \cdot_{ih} C) \cdot_{ℎ} B \in ℋ$
44		braval	$⊢ (A \in ℋ \land (x \cdot_{ih} C) \cdot_{ℎ} B \in ℋ) \to bra (A) ((x \cdot_{ih} C) \cdot_{ℎ} B) = ((x \cdot_{ih} C) \cdot_{ℎ} B) \cdot_{ih} A$
45	17 43 44	syl2anc	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to bra (A) ((x \cdot_{ih} C) \cdot_{ℎ} B) = ((x \cdot_{ih} C) \cdot_{ℎ} B) \cdot_{ih} A$
46	38 41 45	3eqtrd	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to (bra (A) \circ (B ketbra C)) (x) = ((x \cdot_{ih} C) \cdot_{ℎ} B) \cdot_{ih} A$
47	27 33	mulcomd	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to (B \cdot_{ih} A) (x \cdot_{ih} C) = (x \cdot_{ih} C) (B \cdot_{ih} A)$
48	35 46 47	3eqtr4d	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to (bra (A) \circ (B ketbra C)) (x) = (B \cdot_{ih} A) (x \cdot_{ih} C)$
49	25 31 48	3eqtr4d	$⊢ ((A \in ℋ \land B \in ℋ \land C \in ℋ) \land x \in ℋ) \to (bra (A) (B) \cdot_{fn} bra (C)) (x) = (bra (A) \circ (B ketbra C)) (x)$
50	10 16 49	eqfnfvd	$⊢ (A \in ℋ \land B \in ℋ \land C \in ℋ) \to bra (A) (B) \cdot_{fn} bra (C) = bra (A) \circ (B ketbra C)$

Metamath Proof Explorer

Theorem kbass2

Proof