chpval2

Description: Express the second Chebyshev function directly as a sum over the primes less than A (instead of indirectly through the von Mangoldt function). (Contributed by Mario Carneiro, 8-Apr-2016)

		Ref	Expression
	Assertion	chpval2	\|- ( A e. RR -> ( psi ` A ) = sum_ p e. ( ( 0 [,] A ) i^i Prime ) ( ( log ` p ) x. ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) )

Proof

Step	Hyp	Ref	Expression
1		chpval	\|- ( A e. RR -> ( psi ` A ) = sum_ n e. ( 1 ... ( \|_ ` A ) ) ( Lam ` n ) )
2		fveq2	\|- ( n = ( p ^ k ) -> ( Lam ` n ) = ( Lam ` ( p ^ k ) ) )
3		id	\|- ( A e. RR -> A e. RR )
4		elfznn	\|- ( n e. ( 1 ... ( \|_ ` A ) ) -> n e. NN )
5	4	adantl	\|- ( ( A e. RR /\ n e. ( 1 ... ( \|_ ` A ) ) ) -> n e. NN )
6		vmacl	\|- ( n e. NN -> ( Lam ` n ) e. RR )
7	5 6	syl	\|- ( ( A e. RR /\ n e. ( 1 ... ( \|_ ` A ) ) ) -> ( Lam ` n ) e. RR )
8	7	recnd	\|- ( ( A e. RR /\ n e. ( 1 ... ( \|_ ` A ) ) ) -> ( Lam ` n ) e. CC )
9		simprr	\|- ( ( A e. RR /\ ( n e. ( 1 ... ( \|_ ` A ) ) /\ ( Lam ` n ) = 0 ) ) -> ( Lam ` n ) = 0 )
10	2 3 8 9	fsumvma2	\|- ( A e. RR -> sum_ n e. ( 1 ... ( \|_ ` A ) ) ( Lam ` n ) = sum_ p e. ( ( 0 [,] A ) i^i Prime ) sum_ k e. ( 1 ... ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) ( Lam ` ( p ^ k ) ) )
11		simpr	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> p e. ( ( 0 [,] A ) i^i Prime ) )
12	11	elin2d	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> p e. Prime )
13		elfznn	\|- ( k e. ( 1 ... ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) -> k e. NN )
14		vmappw	\|- ( ( p e. Prime /\ k e. NN ) -> ( Lam ` ( p ^ k ) ) = ( log ` p ) )
15	12 13 14	syl2an	\|- ( ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) /\ k e. ( 1 ... ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) ) -> ( Lam ` ( p ^ k ) ) = ( log ` p ) )
16	15	sumeq2dv	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> sum_ k e. ( 1 ... ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) ( Lam ` ( p ^ k ) ) = sum_ k e. ( 1 ... ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) ( log ` p ) )
17		fzfid	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> ( 1 ... ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) e. Fin )
18		prmuz2	\|- ( p e. Prime -> p e. ( ZZ>= ` 2 ) )
19		eluzelre	\|- ( p e. ( ZZ>= ` 2 ) -> p e. RR )
20		eluz2gt1	\|- ( p e. ( ZZ>= ` 2 ) -> 1 < p )
21	19 20	rplogcld	\|- ( p e. ( ZZ>= ` 2 ) -> ( log ` p ) e. RR+ )
22	12 18 21	3syl	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> ( log ` p ) e. RR+ )
23	22	rpcnd	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> ( log ` p ) e. CC )
24		fsumconst	\|- ( ( ( 1 ... ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) e. Fin /\ ( log ` p ) e. CC ) -> sum_ k e. ( 1 ... ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) ( log ` p ) = ( ( # ` ( 1 ... ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) ) x. ( log ` p ) ) )
25	17 23 24	syl2anc	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> sum_ k e. ( 1 ... ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) ( log ` p ) = ( ( # ` ( 1 ... ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) ) x. ( log ` p ) ) )
26		ppisval	\|- ( A e. RR -> ( ( 0 [,] A ) i^i Prime ) = ( ( 2 ... ( \|_ ` A ) ) i^i Prime ) )
27		inss1	\|- ( ( 2 ... ( \|_ ` A ) ) i^i Prime ) C_ ( 2 ... ( \|_ ` A ) )
28	26 27	eqsstrdi	\|- ( A e. RR -> ( ( 0 [,] A ) i^i Prime ) C_ ( 2 ... ( \|_ ` A ) ) )
29	28	sselda	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> p e. ( 2 ... ( \|_ ` A ) ) )
30		elfzuz2	\|- ( p e. ( 2 ... ( \|_ ` A ) ) -> ( \|_ ` A ) e. ( ZZ>= ` 2 ) )
31	29 30	syl	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> ( \|_ ` A ) e. ( ZZ>= ` 2 ) )
32		simpl	\|- ( ( A e. RR /\ ( \|_ ` A ) e. ( ZZ>= ` 2 ) ) -> A e. RR )
33		0red	\|- ( ( A e. RR /\ ( \|_ ` A ) e. ( ZZ>= ` 2 ) ) -> 0 e. RR )
34		2re	\|- 2 e. RR
35	34	a1i	\|- ( ( A e. RR /\ ( \|_ ` A ) e. ( ZZ>= ` 2 ) ) -> 2 e. RR )
36		2pos	\|- 0 < 2
37	36	a1i	\|- ( ( A e. RR /\ ( \|_ ` A ) e. ( ZZ>= ` 2 ) ) -> 0 < 2 )
38		eluzle	\|- ( ( \|_ ` A ) e. ( ZZ>= ` 2 ) -> 2 <_ ( \|_ ` A ) )
39		2z	\|- 2 e. ZZ
40		flge	\|- ( ( A e. RR /\ 2 e. ZZ ) -> ( 2 <_ A <-> 2 <_ ( \|_ ` A ) ) )
41	39 40	mpan2	\|- ( A e. RR -> ( 2 <_ A <-> 2 <_ ( \|_ ` A ) ) )
42	38 41	syl5ibr	\|- ( A e. RR -> ( ( \|_ ` A ) e. ( ZZ>= ` 2 ) -> 2 <_ A ) )
43	42	imp	\|- ( ( A e. RR /\ ( \|_ ` A ) e. ( ZZ>= ` 2 ) ) -> 2 <_ A )
44	33 35 32 37 43	ltletrd	\|- ( ( A e. RR /\ ( \|_ ` A ) e. ( ZZ>= ` 2 ) ) -> 0 < A )
45	32 44	elrpd	\|- ( ( A e. RR /\ ( \|_ ` A ) e. ( ZZ>= ` 2 ) ) -> A e. RR+ )
46	31 45	syldan	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> A e. RR+ )
47	46	relogcld	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> ( log ` A ) e. RR )
48	47 22	rerpdivcld	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> ( ( log ` A ) / ( log ` p ) ) e. RR )
49		1red	\|- ( ( A e. RR /\ ( \|_ ` A ) e. ( ZZ>= ` 2 ) ) -> 1 e. RR )
50		1lt2	\|- 1 < 2
51	50	a1i	\|- ( ( A e. RR /\ ( \|_ ` A ) e. ( ZZ>= ` 2 ) ) -> 1 < 2 )
52	49 35 32 51 43	ltletrd	\|- ( ( A e. RR /\ ( \|_ ` A ) e. ( ZZ>= ` 2 ) ) -> 1 < A )
53	31 52	syldan	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> 1 < A )
54		rplogcl	\|- ( ( A e. RR /\ 1 < A ) -> ( log ` A ) e. RR+ )
55	53 54	syldan	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> ( log ` A ) e. RR+ )
56	55 22	rpdivcld	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> ( ( log ` A ) / ( log ` p ) ) e. RR+ )
57	56	rpge0d	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> 0 <_ ( ( log ` A ) / ( log ` p ) ) )
58		flge0nn0	\|- ( ( ( ( log ` A ) / ( log ` p ) ) e. RR /\ 0 <_ ( ( log ` A ) / ( log ` p ) ) ) -> ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) e. NN0 )
59	48 57 58	syl2anc	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) e. NN0 )
60		hashfz1	\|- ( ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) e. NN0 -> ( # ` ( 1 ... ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) ) = ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) )
61	59 60	syl	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> ( # ` ( 1 ... ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) ) = ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) )
62	61	oveq1d	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> ( ( # ` ( 1 ... ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) ) x. ( log ` p ) ) = ( ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) x. ( log ` p ) ) )
63	59	nn0cnd	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) e. CC )
64	63 23	mulcomd	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> ( ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) x. ( log ` p ) ) = ( ( log ` p ) x. ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) )
65	25 62 64	3eqtrd	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> sum_ k e. ( 1 ... ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) ( log ` p ) = ( ( log ` p ) x. ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) )
66	16 65	eqtrd	\|- ( ( A e. RR /\ p e. ( ( 0 [,] A ) i^i Prime ) ) -> sum_ k e. ( 1 ... ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) ( Lam ` ( p ^ k ) ) = ( ( log ` p ) x. ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) )
67	66	sumeq2dv	\|- ( A e. RR -> sum_ p e. ( ( 0 [,] A ) i^i Prime ) sum_ k e. ( 1 ... ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) ( Lam ` ( p ^ k ) ) = sum_ p e. ( ( 0 [,] A ) i^i Prime ) ( ( log ` p ) x. ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) )
68	1 10 67	3eqtrd	\|- ( A e. RR -> ( psi ` A ) = sum_ p e. ( ( 0 [,] A ) i^i Prime ) ( ( log ` p ) x. ( \|_ ` ( ( log ` A ) / ( log ` p ) ) ) ) )

Metamath Proof Explorer

Theorem chpval2

Proof