oexpreposd

Description: Lemma for dffltz . For a more standard version, see expgt0b . TODO-SN?: This can be used to show exp11d holds for all integers when the exponent is odd. (Contributed by SN, 4-Mar-2023)

	Ref	Expression
Hypotheses	oexpreposd.n	\|- ( ph -> N e. RR )
	oexpreposd.m	\|- ( ph -> M e. NN )
	oexpreposd.1	\|- ( ph -> -. ( M / 2 ) e. NN )
Assertion	oexpreposd	\|- ( ph -> ( 0 < N <-> 0 < ( N ^ M ) ) )

Proof

Step	Hyp	Ref	Expression
1		oexpreposd.n	\|- ( ph -> N e. RR )
2		oexpreposd.m	\|- ( ph -> M e. NN )
3		oexpreposd.1	\|- ( ph -> -. ( M / 2 ) e. NN )
4	1	adantr	\|- ( ( ph /\ 0 < N ) -> N e. RR )
5	2	nnzd	\|- ( ph -> M e. ZZ )
6	5	adantr	\|- ( ( ph /\ 0 < N ) -> M e. ZZ )
7		simpr	\|- ( ( ph /\ 0 < N ) -> 0 < N )
8		expgt0	\|- ( ( N e. RR /\ M e. ZZ /\ 0 < N ) -> 0 < ( N ^ M ) )
9	4 6 7 8	syl3anc	\|- ( ( ph /\ 0 < N ) -> 0 < ( N ^ M ) )
10	9	ex	\|- ( ph -> ( 0 < N -> 0 < ( N ^ M ) ) )
11		0red	\|- ( ph -> 0 e. RR )
12	11 1	lttrid	\|- ( ph -> ( 0 < N <-> -. ( 0 = N \/ N < 0 ) ) )
13	12	notbid	\|- ( ph -> ( -. 0 < N <-> -. -. ( 0 = N \/ N < 0 ) ) )
14		notnotr	\|- ( -. -. ( 0 = N \/ N < 0 ) -> ( 0 = N \/ N < 0 ) )
15		0re	\|- 0 e. RR
16	15	ltnri	\|- -. 0 < 0
17	2	0expd	\|- ( ph -> ( 0 ^ M ) = 0 )
18	17	breq2d	\|- ( ph -> ( 0 < ( 0 ^ M ) <-> 0 < 0 ) )
19	16 18	mtbiri	\|- ( ph -> -. 0 < ( 0 ^ M ) )
20	19	adantr	\|- ( ( ph /\ 0 = N ) -> -. 0 < ( 0 ^ M ) )
21		simpr	\|- ( ( ph /\ 0 = N ) -> 0 = N )
22	21	eqcomd	\|- ( ( ph /\ 0 = N ) -> N = 0 )
23	22	oveq1d	\|- ( ( ph /\ 0 = N ) -> ( N ^ M ) = ( 0 ^ M ) )
24	23	breq2d	\|- ( ( ph /\ 0 = N ) -> ( 0 < ( N ^ M ) <-> 0 < ( 0 ^ M ) ) )
25	20 24	mtbird	\|- ( ( ph /\ 0 = N ) -> -. 0 < ( N ^ M ) )
26	25	ex	\|- ( ph -> ( 0 = N -> -. 0 < ( N ^ M ) ) )
27	1	renegcld	\|- ( ph -> -u N e. RR )
28	27	adantr	\|- ( ( ph /\ 0 < -u N ) -> -u N e. RR )
29	5	adantr	\|- ( ( ph /\ 0 < -u N ) -> M e. ZZ )
30		simpr	\|- ( ( ph /\ 0 < -u N ) -> 0 < -u N )
31		expgt0	\|- ( ( -u N e. RR /\ M e. ZZ /\ 0 < -u N ) -> 0 < ( -u N ^ M ) )
32	28 29 30 31	syl3anc	\|- ( ( ph /\ 0 < -u N ) -> 0 < ( -u N ^ M ) )
33	32	ex	\|- ( ph -> ( 0 < -u N -> 0 < ( -u N ^ M ) ) )
34	1	recnd	\|- ( ph -> N e. CC )
35		simpr	\|- ( ( ph /\ ( M / 2 ) e. ZZ ) -> ( M / 2 ) e. ZZ )
36		zq	\|- ( ( M / 2 ) e. ZZ -> ( M / 2 ) e. QQ )
37	36	adantl	\|- ( ( ph /\ ( M / 2 ) e. ZZ ) -> ( M / 2 ) e. QQ )
38		qden1elz	\|- ( ( M / 2 ) e. QQ -> ( ( denom ` ( M / 2 ) ) = 1 <-> ( M / 2 ) e. ZZ ) )
39	37 38	syl	\|- ( ( ph /\ ( M / 2 ) e. ZZ ) -> ( ( denom ` ( M / 2 ) ) = 1 <-> ( M / 2 ) e. ZZ ) )
40	35 39	mpbird	\|- ( ( ph /\ ( M / 2 ) e. ZZ ) -> ( denom ` ( M / 2 ) ) = 1 )
41	40	oveq2d	\|- ( ( ph /\ ( M / 2 ) e. ZZ ) -> ( ( M / 2 ) x. ( denom ` ( M / 2 ) ) ) = ( ( M / 2 ) x. 1 ) )
42		qmuldeneqnum	\|- ( ( M / 2 ) e. QQ -> ( ( M / 2 ) x. ( denom ` ( M / 2 ) ) ) = ( numer ` ( M / 2 ) ) )
43	37 42	syl	\|- ( ( ph /\ ( M / 2 ) e. ZZ ) -> ( ( M / 2 ) x. ( denom ` ( M / 2 ) ) ) = ( numer ` ( M / 2 ) ) )
44	35	zcnd	\|- ( ( ph /\ ( M / 2 ) e. ZZ ) -> ( M / 2 ) e. CC )
45	44	mulridd	\|- ( ( ph /\ ( M / 2 ) e. ZZ ) -> ( ( M / 2 ) x. 1 ) = ( M / 2 ) )
46	41 43 45	3eqtr3rd	\|- ( ( ph /\ ( M / 2 ) e. ZZ ) -> ( M / 2 ) = ( numer ` ( M / 2 ) ) )
47	2	nnred	\|- ( ph -> M e. RR )
48		2re	\|- 2 e. RR
49	48	a1i	\|- ( ph -> 2 e. RR )
50	2	nngt0d	\|- ( ph -> 0 < M )
51		2pos	\|- 0 < 2
52	51	a1i	\|- ( ph -> 0 < 2 )
53	47 49 50 52	divgt0d	\|- ( ph -> 0 < ( M / 2 ) )
54		qgt0numnn	\|- ( ( ( M / 2 ) e. QQ /\ 0 < ( M / 2 ) ) -> ( numer ` ( M / 2 ) ) e. NN )
55	36 53 54	syl2anr	\|- ( ( ph /\ ( M / 2 ) e. ZZ ) -> ( numer ` ( M / 2 ) ) e. NN )
56	46 55	eqeltrd	\|- ( ( ph /\ ( M / 2 ) e. ZZ ) -> ( M / 2 ) e. NN )
57	3 56	mtand	\|- ( ph -> -. ( M / 2 ) e. ZZ )
58		evend2	\|- ( M e. ZZ -> ( 2 \|\| M <-> ( M / 2 ) e. ZZ ) )
59	5 58	syl	\|- ( ph -> ( 2 \|\| M <-> ( M / 2 ) e. ZZ ) )
60	57 59	mtbird	\|- ( ph -> -. 2 \|\| M )
61		oexpneg	\|- ( ( N e. CC /\ M e. NN /\ -. 2 \|\| M ) -> ( -u N ^ M ) = -u ( N ^ M ) )
62	34 2 60 61	syl3anc	\|- ( ph -> ( -u N ^ M ) = -u ( N ^ M ) )
63	62	breq2d	\|- ( ph -> ( 0 < ( -u N ^ M ) <-> 0 < -u ( N ^ M ) ) )
64	63	biimpd	\|- ( ph -> ( 0 < ( -u N ^ M ) -> 0 < -u ( N ^ M ) ) )
65	2	nnnn0d	\|- ( ph -> M e. NN0 )
66	1 65	reexpcld	\|- ( ph -> ( N ^ M ) e. RR )
67	66	renegcld	\|- ( ph -> -u ( N ^ M ) e. RR )
68	11 67	lttrid	\|- ( ph -> ( 0 < -u ( N ^ M ) <-> -. ( 0 = -u ( N ^ M ) \/ -u ( N ^ M ) < 0 ) ) )
69		pm2.46	\|- ( -. ( 0 = -u ( N ^ M ) \/ -u ( N ^ M ) < 0 ) -> -. -u ( N ^ M ) < 0 )
70	68 69	biimtrdi	\|- ( ph -> ( 0 < -u ( N ^ M ) -> -. -u ( N ^ M ) < 0 ) )
71	33 64 70	3syld	\|- ( ph -> ( 0 < -u N -> -. -u ( N ^ M ) < 0 ) )
72	1	lt0neg1d	\|- ( ph -> ( N < 0 <-> 0 < -u N ) )
73	66	lt0neg2d	\|- ( ph -> ( 0 < ( N ^ M ) <-> -u ( N ^ M ) < 0 ) )
74	73	notbid	\|- ( ph -> ( -. 0 < ( N ^ M ) <-> -. -u ( N ^ M ) < 0 ) )
75	71 72 74	3imtr4d	\|- ( ph -> ( N < 0 -> -. 0 < ( N ^ M ) ) )
76	26 75	jaod	\|- ( ph -> ( ( 0 = N \/ N < 0 ) -> -. 0 < ( N ^ M ) ) )
77	14 76	syl5	\|- ( ph -> ( -. -. ( 0 = N \/ N < 0 ) -> -. 0 < ( N ^ M ) ) )
78	13 77	sylbid	\|- ( ph -> ( -. 0 < N -> -. 0 < ( N ^ M ) ) )
79	10 78	impcon4bid	\|- ( ph -> ( 0 < N <-> 0 < ( N ^ M ) ) )

Metamath Proof Explorer

Theorem oexpreposd

Proof