efi4p

Description: Separate out the first four terms of the infinite series expansion of the exponential function. (Contributed by Paul Chapman, 19-Jan-2008) (Revised by Mario Carneiro, 30-Apr-2014)

		Ref	Expression
	Hypothesis	efi4p.1	$⊢ F = (n \in ℕ_{0} ⟼ \frac{{i A}^{n}}{n!})$
	Assertion	efi4p	$⊢ A \in ℂ \to e^{i A} = (1 - (\frac{A^{2}}{2})) + i (A - (\frac{A^{3}}{6})) + \sum_{k \in ℤ_{\geq 4}} F (k)$

Proof

Step	Hyp	Ref	Expression
1		efi4p.1	$⊢ F = (n \in ℕ_{0} ⟼ \frac{{i A}^{n}}{n!})$
2		ax-icn	$⊢ i \in ℂ$
3		mulcl	$⊢ (i \in ℂ \land A \in ℂ) \to i A \in ℂ$
4	2 3	mpan	$⊢ A \in ℂ \to i A \in ℂ$
5	1	ef4p	$⊢ i A \in ℂ \to e^{i A} = (1 + i A + (\frac{{i A}^{2}}{2})) + (\frac{{i A}^{3}}{6}) + \sum_{k \in ℤ_{\geq 4}} F (k)$
6	4 5	syl	$⊢ A \in ℂ \to e^{i A} = (1 + i A + (\frac{{i A}^{2}}{2})) + (\frac{{i A}^{3}}{6}) + \sum_{k \in ℤ_{\geq 4}} F (k)$
7		ax-1cn	$⊢ 1 \in ℂ$
8		addcl	$⊢ (1 \in ℂ \land i A \in ℂ) \to 1 + i A \in ℂ$
9	7 4 8	sylancr	$⊢ A \in ℂ \to 1 + i A \in ℂ$
10	4	sqcld	$⊢ A \in ℂ \to {i A}^{2} \in ℂ$
11	10	halfcld	$⊢ A \in ℂ \to \frac{{i A}^{2}}{2} \in ℂ$
12		3nn0	$⊢ 3 \in ℕ_{0}$
13		expcl	$⊢ (i A \in ℂ \land 3 \in ℕ_{0}) \to {i A}^{3} \in ℂ$
14	4 12 13	sylancl	$⊢ A \in ℂ \to {i A}^{3} \in ℂ$
15		6cn	$⊢ 6 \in ℂ$
16		6re	$⊢ 6 \in ℝ$
17		6pos	$⊢ 0 < 6$
18	16 17	gt0ne0ii	$⊢ 6 \neq 0$
19		divcl	$⊢ ({i A}^{3} \in ℂ \land 6 \in ℂ \land 6 \neq 0) \to \frac{{i A}^{3}}{6} \in ℂ$
20	15 18 19	mp3an23	$⊢ {i A}^{3} \in ℂ \to \frac{{i A}^{3}}{6} \in ℂ$
21	14 20	syl	$⊢ A \in ℂ \to \frac{{i A}^{3}}{6} \in ℂ$
22	9 11 21	addassd	$⊢ A \in ℂ \to (1 + i A) + (\frac{{i A}^{2}}{2}) + (\frac{{i A}^{3}}{6}) = 1 + i A + (\frac{{i A}^{2}}{2}) + (\frac{{i A}^{3}}{6})$
23	7	a1i	$⊢ A \in ℂ \to 1 \in ℂ$
24	23 4 11 21	add4d	$⊢ A \in ℂ \to 1 + i A + (\frac{{i A}^{2}}{2}) + (\frac{{i A}^{3}}{6}) = 1 + (\frac{{i A}^{2}}{2}) + i A + (\frac{{i A}^{3}}{6})$
25		2nn0	$⊢ 2 \in ℕ_{0}$
26		mulexp	$⊢ (i \in ℂ \land A \in ℂ \land 2 \in ℕ_{0}) \to {i A}^{2} = i^{2} A^{2}$
27	2 25 26	mp3an13	$⊢ A \in ℂ \to {i A}^{2} = i^{2} A^{2}$
28		i2	$⊢ i^{2} = - 1$
29	28	oveq1i	$⊢ i^{2} A^{2} = -1 A^{2}$
30	29	a1i	$⊢ A \in ℂ \to i^{2} A^{2} = -1 A^{2}$
31		sqcl	$⊢ A \in ℂ \to A^{2} \in ℂ$
32	31	mulm1d	$⊢ A \in ℂ \to -1 A^{2} = - A^{2}$
33	27 30 32	3eqtrd	$⊢ A \in ℂ \to {i A}^{2} = - A^{2}$
34	33	oveq1d	$⊢ A \in ℂ \to \frac{{i A}^{2}}{2} = \frac{- A^{2}}{2}$
35		2cn	$⊢ 2 \in ℂ$
36		2ne0	$⊢ 2 \neq 0$
37		divneg	$⊢ (A^{2} \in ℂ \land 2 \in ℂ \land 2 \neq 0) \to - \frac{A^{2}}{2} = \frac{- A^{2}}{2}$
38	35 36 37	mp3an23	$⊢ A^{2} \in ℂ \to - \frac{A^{2}}{2} = \frac{- A^{2}}{2}$
39	31 38	syl	$⊢ A \in ℂ \to - \frac{A^{2}}{2} = \frac{- A^{2}}{2}$
40	34 39	eqtr4d	$⊢ A \in ℂ \to \frac{{i A}^{2}}{2} = - \frac{A^{2}}{2}$
41	40	oveq2d	$⊢ A \in ℂ \to 1 + (\frac{{i A}^{2}}{2}) = 1 + (- \frac{A^{2}}{2})$
42	31	halfcld	$⊢ A \in ℂ \to \frac{A^{2}}{2} \in ℂ$
43		negsub	$⊢ (1 \in ℂ \land \frac{A^{2}}{2} \in ℂ) \to 1 + (- \frac{A^{2}}{2}) = 1 - (\frac{A^{2}}{2})$
44	7 42 43	sylancr	$⊢ A \in ℂ \to 1 + (- \frac{A^{2}}{2}) = 1 - (\frac{A^{2}}{2})$
45	41 44	eqtrd	$⊢ A \in ℂ \to 1 + (\frac{{i A}^{2}}{2}) = 1 - (\frac{A^{2}}{2})$
46		mulexp	$⊢ (i \in ℂ \land A \in ℂ \land 3 \in ℕ_{0}) \to {i A}^{3} = i^{3} A^{3}$
47	2 12 46	mp3an13	$⊢ A \in ℂ \to {i A}^{3} = i^{3} A^{3}$
48		i3	$⊢ i^{3} = - i$
49	48	oveq1i	$⊢ i^{3} A^{3} = (- i) A^{3}$
50	47 49	eqtrdi	$⊢ A \in ℂ \to {i A}^{3} = (- i) A^{3}$
51	50	oveq1d	$⊢ A \in ℂ \to \frac{{i A}^{3}}{6} = \frac{(- i) A^{3}}{6}$
52		expcl	$⊢ (A \in ℂ \land 3 \in ℕ_{0}) \to A^{3} \in ℂ$
53	12 52	mpan2	$⊢ A \in ℂ \to A^{3} \in ℂ$
54		negicn	$⊢ - i \in ℂ$
55	15 18	pm3.2i	$⊢ (6 \in ℂ \land 6 \neq 0)$
56		divass	$⊢ (- i \in ℂ \land A^{3} \in ℂ \land (6 \in ℂ \land 6 \neq 0)) \to \frac{(- i) A^{3}}{6} = (- i) (\frac{A^{3}}{6})$
57	54 55 56	mp3an13	$⊢ A^{3} \in ℂ \to \frac{(- i) A^{3}}{6} = (- i) (\frac{A^{3}}{6})$
58	53 57	syl	$⊢ A \in ℂ \to \frac{(- i) A^{3}}{6} = (- i) (\frac{A^{3}}{6})$
59		divcl	$⊢ (A^{3} \in ℂ \land 6 \in ℂ \land 6 \neq 0) \to \frac{A^{3}}{6} \in ℂ$
60	15 18 59	mp3an23	$⊢ A^{3} \in ℂ \to \frac{A^{3}}{6} \in ℂ$
61	53 60	syl	$⊢ A \in ℂ \to \frac{A^{3}}{6} \in ℂ$
62		mulneg12	$⊢ (i \in ℂ \land \frac{A^{3}}{6} \in ℂ) \to (- i) (\frac{A^{3}}{6}) = i (- \frac{A^{3}}{6})$
63	2 61 62	sylancr	$⊢ A \in ℂ \to (- i) (\frac{A^{3}}{6}) = i (- \frac{A^{3}}{6})$
64	51 58 63	3eqtrd	$⊢ A \in ℂ \to \frac{{i A}^{3}}{6} = i (- \frac{A^{3}}{6})$
65	64	oveq2d	$⊢ A \in ℂ \to i A + (\frac{{i A}^{3}}{6}) = i A + i (- \frac{A^{3}}{6})$
66	61	negcld	$⊢ A \in ℂ \to - \frac{A^{3}}{6} \in ℂ$
67		adddi	$⊢ (i \in ℂ \land A \in ℂ \land - \frac{A^{3}}{6} \in ℂ) \to i (A + (- \frac{A^{3}}{6})) = i A + i (- \frac{A^{3}}{6})$
68	2 67	mp3an1	$⊢ (A \in ℂ \land - \frac{A^{3}}{6} \in ℂ) \to i (A + (- \frac{A^{3}}{6})) = i A + i (- \frac{A^{3}}{6})$
69	66 68	mpdan	$⊢ A \in ℂ \to i (A + (- \frac{A^{3}}{6})) = i A + i (- \frac{A^{3}}{6})$
70		negsub	$⊢ (A \in ℂ \land \frac{A^{3}}{6} \in ℂ) \to A + (- \frac{A^{3}}{6}) = A - (\frac{A^{3}}{6})$
71	61 70	mpdan	$⊢ A \in ℂ \to A + (- \frac{A^{3}}{6}) = A - (\frac{A^{3}}{6})$
72	71	oveq2d	$⊢ A \in ℂ \to i (A + (- \frac{A^{3}}{6})) = i (A - (\frac{A^{3}}{6}))$
73	65 69 72	3eqtr2d	$⊢ A \in ℂ \to i A + (\frac{{i A}^{3}}{6}) = i (A - (\frac{A^{3}}{6}))$
74	45 73	oveq12d	$⊢ A \in ℂ \to 1 + (\frac{{i A}^{2}}{2}) + i A + (\frac{{i A}^{3}}{6}) = 1 - (\frac{A^{2}}{2}) + i (A - (\frac{A^{3}}{6}))$
75	22 24 74	3eqtrd	$⊢ A \in ℂ \to (1 + i A) + (\frac{{i A}^{2}}{2}) + (\frac{{i A}^{3}}{6}) = 1 - (\frac{A^{2}}{2}) + i (A - (\frac{A^{3}}{6}))$
76	75	oveq1d	$⊢ A \in ℂ \to (1 + i A + (\frac{{i A}^{2}}{2})) + (\frac{{i A}^{3}}{6}) + \sum_{k \in ℤ_{\geq 4}} F (k) = (1 - (\frac{A^{2}}{2})) + i (A - (\frac{A^{3}}{6})) + \sum_{k \in ℤ_{\geq 4}} F (k)$
77	6 76	eqtrd	$⊢ A \in ℂ \to e^{i A} = (1 - (\frac{A^{2}}{2})) + i (A - (\frac{A^{3}}{6})) + \sum_{k \in ℤ_{\geq 4}} F (k)$

Metamath Proof Explorer

Theorem efi4p

Proof